)

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(51) International Patent Classification: (74) Agent: DOYLE, Kathryn et al.; Saul Ewing Arnstein & C12N 9/22 (2006.01) Cl 2N 15/85 (2006.01) Lehr LLP, 1500 Market Street, 38th Floor, Philadelphia, C12N 15/63 (2006.01) Cl 2N 15/86 (2006.01) Pennsylvania 19102 (US). C12N 15/79 (2006.01) (81) Designated States (unless otherwise indicated, for every (21) International Application Number: kind of national protection av ailable) . AE, AG, AL, AM, PCT/US20 19/027956 AO, AT, AU, AZ, BA, BB, BG, BH, BN, BR, BW, BY, BZ, CA, CH, CL, CN, CO, CR, CU, CZ, DE, DJ, DK, DM, DO, (22) International Filing Date: DZ, EC, EE, EG, ES, FI, GB, GD, GE, GH, GM, GT, HN, 17 April 2019 (17.04.2019) HR, HU, ID, IL, IN, IR, IS, JO, JP, KE, KG, KH, KN, KP, (25) Filing Language: English KR, KW, KZ, LA, LC, LK, LR, LS, LU, LY, MA, MD, ME, MG, MK, MN, MW, MX, MY, MZ, NA, NG, NI, NO, NZ, (26) Publication Language: English OM, PA, PE, PG, PH, PL, PT, QA, RO, RS, RU, RW, SA, (30) Priority Data: SC, SD, SE, SG, SK, SL, SM, ST, SV, SY, TH, TJ, TM, TN, 62/659,543 18 April 2018 (18.04.2018) US TR, TT, TZ, UA, UG, US, UZ, VC, VN, ZA, ZM, ZW. 62/743,990 10 October 2018 (10. 10.2018) US (84) Designated States (unless otherwise indicated, for every (71) Applicant: YALE UNIVERSITY [US/US]; Two Whitney kind of regional protection available) . ARIPO (BW, GH, Avenue, New Haven, Connecticut 065 10 (US). GM, KE, LR, LS, MW, MZ, NA, RW, SD, SL, ST, SZ, TZ, UG, ZM, ZW), Eurasian (AM, AZ, BY, KG, KZ, RU, TJ, (72) Inventors: CHEN, Sidi; 433 Swanson Crescent, Milford, TM), European (AL, AT, BE, BG, CH, CY, CZ, DE, DK, Connecticut 06461 (US). CHOW, Ryan D.; 123 1 Quail EE, ES, FI, FR, GB, GR, HR, HU, IE, IS, IT, LT, LU, LV, Creek Circle, San Jose, California 95 120 (US). WANG, MC, MK, MT, NL, NO, PL, PT, RO, RS, SE, SI, SK, SM, Guangchuan; 470 Prospect Street, Apt. 17, New Haven, Connecticut 065 11 (US).

(54) Title: COMPOSITIONS AND METHODS FOR MULTIPLEXED TUMOR VACCINATION WITH ENDOGENOUS GENE ACTIVATION

FIG. 1A

(57) Abstract: The present invention includes compositions and methods for treating or preventing cancer. Embodiments include cell- based and viral vector-based vaccines that utilize gene expression activation systems to augment the product of endogenous genes to treat or prevent cancer.

[Continued on nextpage] W O 2019/204503 A 1

TR), OAPI (BF, BJ, CF, CG, Cl, CM, GA, GN, GQ, GW, KM, ML, MR, NE, SN, TD, TG).

Declarations under Rule 4.17: of inventorship (Rule 4. 7(iv)) Published: with international search report (Art. 21(3)) before the expiration of the time limit for amending the claims and to be republished in the event of receipt of amendments (Rule 48.2(h)) with sequence listing part of description (Rule 5.2(a)) TITLE OF THE INVENTION Compositions and Methods for Multiplexed Tumor Vaccination with Endogenous Gene Activation

CROSS-REFERENCE TO RELATED APPLICATION The present application is entitled to priority under 35 U.S.C. § 119(e) to U.S. Provisional Patent Application No. 62/659,543, filed April 18, 2018, and U S . Provisional Patent Application No. 62/743,990, filed October 10, 2018, which are hereby incorporated by reference in their entireties herein.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT This invention was made with government support under CA238295, CA231 112 and CA209992 awarded by the National Institutes of Health; and under W81XWH-17-1- 0235 awarded by the United States Army Medical Research and Material Command. The government has certain rights in the invention.

BACKGROUND OF THE INVENTION Immunotherapy has transformed cancer treatment by leveraging the patient’s own immune system against the tumor, thereby turning several previously lethal cancers into manageable diseases for a subset of patients Major types of immunotherapy include checkpoint blockade, adoptive cell transfer, human recombinant cytokines, and cancer vaccines. Although antigen recognition is a key process in the anti-tumor immune response, there has been limited success using cancer vaccines in the clinic over the past several decades. Traditional cancer vaccines are often dendritic cell-based vaccines such as sipuleucel-T. Recent advances of peptide- and RNA-based vaccines showed that targeted delivery of multiple mutated neoantigens can generate a strong anti-tumor effect, providing direct clinical evidence of effective cancer vaccines against late-stage melanoma. Tumor cells harbor a multitude of mutations that frequently encode mutated, partially truncated, or amplified genes that are immunogenic. However, many of these mutations might not be expressed at levels sufficient to elicit an effective T-cell-mediated response. Synthesis of these peptides or transcripts is possible with parallel protein- or RNA-synthesis, but the cost of this approach is proportional to the number of mutations identified. A need exists for new types of cancer vaccines that can elicit strong, durable, and specific immune responses against cancer antigens, while maintaining efficacy, versatility, and cost-effectiveness. The present invention satisfies this need.

SUMMARY OF THE INVENTION As described herein, the present invention relates to compositions and methods for or treating or vaccinating against cancer via multiplexed activation of endogenous genes by the CRISPRa system. In one aspect, the invention includes a method of vaccinating against cancer in a subject. The method comprises contacting a cell with a composition comprising a CRISPR activation (CRISPRa) system, wherein the CRISPRa system increases expression of at least one endogenous gene resulting in a modified cell. A therapeutically effective amount of a composition comprising the modified cell i administered to the subject, thereby vaccinating against cancer in the subject. In another aspect, the invention includes a method of treating cancer in a subject in need thereof. The method comprises contacting a cell with a composition comprising a CRISPRa system, wherein the CRISPRa system increases expression of at least one endogenous gene resulting in a modified cell. A therapeutically effective amount of a composition comprising the modified cell is administered to the subject, thereby treating the cancer in the subject. In yet another aspect, the invention includes a method of vaccinating against cancer in a subject in need thereof. The method comprises administering to the subject a therapeutically effective amount of a composition comprising a vector comprising a CRISPRa system. The CRISPRa system increases expression of at least one endogenous gene in the subject, thereby vaccinating against cancer in the subject. In still another aspect, the invention includes a method of treating cancer in a subject in need thereof. The method comprises administering to the subject a therapeutically effective amount of a composition comprising a vector comprising a CRISPRa system. The CRISPRa system increases expression of at least one endogenous gene in the subj ect, thereby treating the cancer in the subj ect. Another aspect of the invention includes a method of vaccinating against cancer in a subject in need thereof. The method comprises obtaining a cancer cell from the subject, determining at least one mutated endogenous gene, and designing a CRISPRa system comprising an sgRNA library specific for the at least one mutated endogenous gene. A therapeutically effective amount of a composition comprising the CRISPRa system is administered to the subject, thereby vaccinating against cancer in the subject. Yet another aspect of the invention includes a method of vaccinating against cancer in a subject in need thereof. The method comprises obtaining a cancer cell from the subject, determining at least one mutated endogenous gene, and designing a CRISPRa system comprising an sgRNA library specific for the at least one mutated endogenous gene. A cell is contacted with a composition comprising the CRISPRa system, wherein the CRISPRa system increases expression of the at least one mutated endogenous gene resulting in a modified cell. A therapeutically effective amount of a composition comprising the modified cell is administered to the subject, thereby vaccinating against cancer in the subj ect. Still another aspect of the invention includes a method of treating cancer in a subject in need thereof. The method comprises obtaining a cancer cell from the subject, determining at least one mutated endogenous gene, and designing a CRISPRa system comprising an sgRNA library specific for the at least one mutated endogenous gene. A therapeutically effective amount of a composition comprising the CRISPRa system is administered to the subject, thereby treating the cancer in the subject. In another aspect, the invention includes a method of treating cancer in a subject in need thereof. The method comprises obtaining a cancer cell from the subject, determining at least one mutated endogenous gene, and designing a CRISPRa system comprising an sgRNA library specific for the at least one mutated endogenous gene. A cell is contacted with a composition comprising the CRISPRa system. The CRISPRa system increases expression of the at least one mutated endogenous gene resulting in a modified cell. A therapeutically effective amount of a composition comprising the modified cell is administered to the subject, thereby treating the cancer in the subject. In another aspect, the invention includes a method of generating an anti-tumor response in a subject. The method comprises contacting a cell with a composition comprising a CRISPRa system. The CRISPRa system increases expression of a plurality of endogenous genes resulting in a modified cell. A therapeutically effective amount of a composition comprising the modified cell is administered to the subject, thereby generating an anti-tumor response. In yet another aspect, the invention includes a composition comprising a cancer vaccine comprising a modified cell comprising a CRISPRa system capable of increasing expression of a plurality of endogenous genes. In yet another aspect, the invention includes a composition comprising an AAV vector comprising a CRISPRa system capable of increasing expression of a plurality of endogenous genes. Another aspect of the invention includes a vector comprising two sgRNA cassettes in a CRISPRa system, wherein the first sgRNA cassette is used for activation of antigen presentation machinery, and the second sgRNA cassette is used for activation of patient-specific mutated endogenous genes, either in single gene or pooled format Yet another aspect of the invention includes a method of treating cancer in a subject in need thereof. The method comprises administering to the subject a therapeutically effective amount of a composition comprising a vector comprising a CRISPRa system. The CRISPRa system increases expression of at least one antigen presentation gene in the subject, thereby treating the cancer in the subject. Still another aspect of the invention includes a composition comprising an sgRNA library, wherein the sgRNA library comprises a plurality of sgRNAs that target a plurality genes in the cell. In another aspect, the invention includes a vector comprising the nucleic acid sequence of SEQ ID NO: 24,105. In yet another aspect, the invention includes a vector comprising the nucleic acid sequence of SEQ D NO: 24,106. In still another aspect, the invention includes a method treating cancer in a subject in need thereof. The method comprises contacting a cell with a first AAV vector comprising a CRISPRa system, and a second AAV vector comprising dCas9. The CRISPRa system increases expression of at least one endogenous gene resulting in a modified cell. A therapeutically effective amount of a composition comprising the modified cell is administered to the subject, thereby treating the cancer in the subject. In various embodiments of the above aspects or any other aspect of the invention delineated herein, the CRISPRa system comprises an sgRNA library. In certain embodiments, the CRISPRa system comprises an sgRNA library comprising a plurality of sgRNAs. In certain embodiments, the sgRNA library comprises at least one sgRNA that targets at least one endogenous gene in the cell. In certain embodiments, the sgRNA library comprises a plurality of sgRNAs that target a plurality of endogenous genes in the cell. In certain embodiments, the sgRNA library comprises a plurality of sgRNAs that target a plurality of antigen presentation genes in the cell. In certain embodiments, the sgRNAs are customized. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ED NOs. 1-37. In certain embodiments, at least one of the sgRNAs comprises a nucleotide sequence selected from the group consisting of SEQ D NOs: 23,886-24,104. In certain embodiments, the plurality of sgRNAs comprise at least one sgRNA selected from the group consisting of SEQ ED NOs: 23,886-24,104. In certain embodiments, the plurality of sgRNAs comprise the nucleotide sequences consisting of SEQ ID NOs: 23,886-24,104. In certain embodiments, the plurality of sgRNAs comprise at least one sgRNA selected from the group consisting of SEQ ED NOs: 51-259. In certain embodiments, the plurality of sgRNAs comprise the nucleotide sequences consisting of SEQ ID NOs: 51-259. In certain embodiments, the plurality of sgRNAs comprise at least one sgRNA selected from the group consisting of SEQ ID NOs: 260-348. In certain embodiments, the plurality of sgRNAs comprise the nucleotide sequences consisting of SEQ ID NOs: 260-348. In certain embodiments, the plurality of sgRNAs comprise at least one sgRNA selected from the group consisting of SEQ ID NOs: 349-4,187. In certain embodiments, the plurality of sgRNAs comprise the nucleotide sequences consisting of SEQ ID NOs: 349-4,187. In certain embodiments, the plurality of sgRNAs comprise at least one sgRNA selected from the group consisting of SEQ ID NOs: 4,188-7,980. In certain embodiments, the plurality of sgRNAs comprise the nucleotide sequences consisting of SEQ ID NOs: 4,188-7,980 In certain embodiments, the plurality of sgRNAs comprise at least one sgRNA selected from the group consisting of SEQ ED NOs: 7,981-1 1,808. In certain embodiments, the plurality of sgRNAs comprise the nucleotide sequences consisting of SEQ ID NOs: 7,981-1 1,808. In certain embodiments, the plurality of sgRNAs comprise at least one sgRNA selected from the group consisting of SEQ ID NOs: 11,809-23,776. In certain embodiments, the plurality of sgRNAs comprise the nucleotide sequences consisting of SEQ ID NOs: 11,809-23,776. In certain embodiments, the plurality of sgRNAs comprise at least one sgRNA selected from the group consisting of SEQ ED NOs: 23,779-23,885. In certain embodiments, the plurality of sgRNAs comprise the nucleotide sequences consisting of SEQ ID NOs: 23,779-23,885. In certain embodiments, the CRISPRa system comprises a nucleic acid encoding dCas9-VP64, and a nucleic acid encoding MS2-p65-HSFl and a genome-scale lentiviral SAM CRISPRa sgRNA library. In certain embodiments, the CRISPRa system comprises a nucleic acid encoding dCas9-VP64, a nucleic acid encoding MS2-p65-HSFl, and a nucleic acid encoding a genome-scale lentiviral SAM CRISPRa sgRNA library. In certain embodiments, the cell is from a cancer cell line. In certain embodiments, the cell is from the subject. In certain embodiments, the cell from the subject is a cancer cell. In certain embodiments, the subject is a mammal. In certain embodiments, the subject is a human. In certain embodiments, administering the therapeutically effective amount of the composition comprises a one dose, a two dose, a three dose, a four dose, or a multi-dose treatment. In certain embodiments, the method further comprises contacting the cell with a substance that induces senescence in the cell prior to administering to the subject. In certain embodiments, the substance that induces senescence in the cell is mitomycin. In certain embodiments, the cancer is selected from the group consisting of breast cancer, lung cancer, pancreatic cancer, melanoma, glioma, hepatoma, colon cancer, pancreatic cancer and brain cancer. In certain embodiments, the method further comprises administering an additional treatment. In certain embodiments, the additional treatment is selected from the group consisting of chemotherapy, radiation, surgery, an immune checkpoint inhibitor, and an immune checkpoint blockade (ICB) antibody. In certain embodiments, the immune checkpoint inhibitor blocks CTLA-4 or PD1 or other immune checkpoint targets. In certain embodiments, the immune checkpoint inhibitor is a monoclonal antibody selected from the group consisting of anti-CTLA4 and anti-PD 1. In certain embodiments, administering the composition alters the tumor microenvironment. In certain embodiments, administering the composition augments host immune responses against established tumors. In certain embodiments, the composition is administered intratumorally. In certain embodiments, the composition comprises a vector. In certain embodiments, the sgRNA library is cloned and packaged into an AAV vector. In certain embodiments, the CRISPRa system is in an AAV vector, a lentiviral vector, or an adenoviral vector. In certain embodiments, the AAV vector is AAV2, AAV8, AAV9, AAV-DI, or other AAV serotypes. In certain embodiments, the cell comprises a plurality of mutated endogenous genes, and the activation system comprises an sgRNA library specific for the plurality of mutated endogenous genes and increases expression of the plurality of mutated endogenous genes. In certain embodiments, determining the subject-specific mutated endogenous gene or genes comprises whole-exome sequencing of the cancer cell and whole-exome sequencing of a non-cancer cell from the subject. The sequencing data from the cancer cell is compared to sequencing data from the non-cancer cell and at least one mutation is determined. Thereby, the subject-specific mutated endogenous gene or genes is determined. In certain embodiments, the mutation is selected from the group consisting of a single nucleotide polymorphism (SNP), an insertion, a deletion, a frameshift, and a rearrangement. In certain embodiments, the endogenous genes contain detected somatic mutations. In certain embodiments, the vector comprises the nucleic acid of SEQ ID NO: 38. In certain embodiments, the first AAV vector comprises the nucleic acid sequence of SEQ ID NO: 38 or SEQ ID NO: 49. In certain embodiments, the second AAV vector comprises the nucleic acid sequence of SEQ ID NO 24, 105 or SEQ D NO 24, 106.

BRIEF DESCRIPTION OF THE DRAWINGS The following detailed description of specific embodiments of the invention will be better understood when read in conjunction with the appended drawings. For the purpose of illustrating the invention, there are shown in the drawings exemplary embodiments. It should be understood, however, that the invention is not limited to the precise arrangements and instrumentalities of the embodiments shown in the drawings. FIGs. 1A-1K illustrate CRISPRa based endogenous gene activation as prophylactic and therapeutic vaccines. FIG 1A is a schematic of the experimental design for cell-based endogenous gene tumor vaccination used in this study. The E0771 version of CRISPR activation based vaccine (E077l-CAVac, or CAVac for short) was generated by transducing E0771 cells with lentiviral vectors carrying CRISPRa machinery and a genome-scale CRISPR activation sgRNA library, then treating the cells with mitomycin. For prophylactic vaccination, C57BL/6J mice were pre-inoculated with cell-based CAVac, and then challenged by transplanting syngeneic tumors with identical cell of origin or tumors with different cell of origin. For therapeutic vaccination, syngeneic orthotopic breast tumors were established by intra-mammary transplantation of E0771 cells into C57BL/6J mice. After transplantation, tumor-bearing mice were treated with PBS, or E0771-CAVac at indicated times. Tumor sizes along time were measured to assess the therapeutic effects. FIG. IB shows prophylactic efficacy of E0771-CAVac against syngeneic tumors with identical cell of origin. Growth curves of orthotopic transplanted tumors of E0771 in C57BL/6J mice pre-inoculated with PBS or E0771- CAVac. (PBS treated mice, n = 7; E0771-CAVac treated mice at indicated dates prior to tumor induction. CAVac@-dl4, CAVac treatment at dpi = -14 (n = 5); CAVac@-d7, dpi = -7 (n = 6); CAVac@-d3, dpi = -3 (n = 6)). Two-way ANOVA using Sidak’s multiple comparisons test for the following comparisons on study endpoint (dpi = 23): CAVac@- dl4 vs. PBS, p < 0.0001; CAVac@-d7 vs. PBS, p < 0.0001; CAVac@-d3 vs. PBS, p < 0.0001 . Two-sided Kolmogorov-Smimov (KS) test of whole-curves for the following comparisons: CAVac@-dl4 vs. PBS, p < 2.2e-16; CAVac@-d7 vs. PBS, p < 2.2e-16; CAVac@-d3 vs PBS, p = 9.62e-ll FIG 1C shows therapeutic efficacy of E0771- CAVac against established orthotopic tumors. 2xl0 6 E0771 cells were transplanted into the mammary fatpad of syngeneic C57BL/6J mice. Tumor-bearing mice were treated with PBS or E0771-CAVac at indicated times (arrows), and tumor sizes were measured after these treatments. (PBS treated mice, n = 11; E0771-CAVac, n = 8). Two-way ANOVA using Sidak’s multiple comparisons test for the following comparisons on the last two time points (dpi = 24 and 28): CAVac vs. PBS, p = 0.0009 & 0 0488 respectively. Two- sided KS test of late-stage curves (13 dpi onward) of CAVac vs. PBS, p = 0.016. FIG. ID shows Haemotoxylin and Eosin (H&E) staining of representative end-point tumor sections from PBS and E0771 -CAVac treated mice. Arrows point to inflamed tumor regions with lymphocyte infiltration. FIG. IE shows CD8 immunohistochemistry (IHC) staining of representative end-point tumor sections from PBS and E0771 -CAVac treated mice. Arrows point to inflamed tumor regions with CD8 cells. FIGs. 1F-1G show results from ELISPOT experiments for CAVac. Tumor-specific immune responses in tumor bearing C57BL/6J mice in different treatment groups were assessed by measuring the ratios of tumor- stimulated IFNy-producing splenocytes with ELISPOT assay, using mitomycin-treated tumor cells as the stimulants. Spots were counted using CTL Immunospot Analyzer. FIG. IF shows representative pictures of spots obtained from triplicates per mouse with three mice for each treatment group. FIG. 1G shows quantification of ELISPOT experiment of PBS (n = 4), cell lysate (n = 4) or CAVac (n = 5). Two sided unpaired t-test for the following comparisons: PBS vs. cell lysate not significant; CAVac vs. PBS, p = 0.0159; CAVac vs. cell lysates, p = 0.0317. Results were shown from an average of 2 independent experiments. FIG. 1H is a schematic of an experiment to test the combinatory therapeutic effects of CAVac plus immune checkpoint blockade or CD4+ T cells depletion. FIG. II shows combinatorial therapeutic efficacy of CAVac plus anti-CTLA4 or anti-CD4 against established breast tumors of E0771. Experiment in (FIG. II) is also plotted separately for anti-CTLA4 (FIG. 1J) and anti-CD4 (FIG. UK) respectively for better visualization and statistics of data. (PBS treated mice, n = 8; E0771 -CAVac treated mice, n = 8; anti-CTLA4 treated mice; n = 6; CAVac+anti- CTLA4 combination treated mice, n = 4; anti-CD4 treated mice; n = 3; CAVac+anti-CD4 combination treated mice, n = 6). FIG. 1J shows combinatorial therapeutic efficacy of CAVac plus anti-CTLA4 against established breast tumors of E0771. Tumor growth curves in syngeneic C57BL6J mice that were treated by PBS, E0771-CAVac, anti- CLTA4, or the combination with scheme indicated in FIG. 1H. Two-sided KS test of whole-curves for the following comparisons: CAVac vs. PBS, p = 0.5899; anti-CTLA4 vs. PBS, p = 0.00537; Combination vs. PBS p = 1.068e-08; Combination vs. anti-CTLA4, = 3.437e-05; Combination vs. CAVac, = 1.375e-08. Two-way ANOVA using Turkey’s multiple comparisons test at last time point (dpi = 27) for the following comparisons: E0771-CAVac vs. PBS, p < 0.0001; anti-CTLA4 vs. PBS, p < 0.0001; Combination vs. PBS, p < 0.0001; Combination vs. anti-CTLA4, p = 0.016; Combination vs. CAVac, p < 0.0001. FIG. IK shows combinatorial therapy efficacy of CAVac plus anti-CD4 against established syngeneic tumors. Tumor growth curves in C57BL/6J mice treated by PBS, E0771-CAVac, anti-CD4, or the combination administrated as indicated. Two-sided KS test of whole-curves for the following comparisons: anti-CD4 vs. PBS, p = 2.02e-5; Combination vs. PBS p = 6.89e-6; Combination vs. anti-CD4, = 0.81; Combination vs. CAVac, = 1.49e-05. Two-way ANOVA using Turkey’s multiple comparisons test at last time point (dpi = 27) for the following comparisons: E0771-CAVac vs. PBS, p < 0.0001; anti-CD4 vs. PBS, p < 0.0001; Combination vs. PBS p < 0.0001; Combination vs. anti- CD4, p = 0.05; Combination vs. CAVac, p < 0.0001. Error bars: All data points in this figure were presented as mean ± s.e.m. Asterisks: * p < 0.05, * p < 0.01, *** p < 0.001. FIGs. 2A-2G illustrate AAV-carried CRISPR activation system (AAV-CAVac) as a therapeutic treatment agent against established tumors. FIG. 2A shows schematics of an experimental design used in the study. AAV-CAVac was generated by cloning of a genome-scale activation sgRNA library mSAM into AAV-CRISPRa vector, followed by pooled viral packaging into AAV9. C57BL/6J mice with established tumor(s) were treated with AAV-CAVac. FIG. 2B shows therapeutic efficacy of AAV-CAVac against established orthotopic syngeneic E0771 tumors by intratumoral administration. Growth curves of orthotopic transplanted E0771 tumors in C57BL/6J mice treated with PBS, AAV-Vector, and AAV-CAVac at indicated times (arrows). (PBS treated mice, n = 8; AAV-Vector treated mice, n = 6; AAV-CAVac treated mice, n = 6). Two-way ANOVA using Turkey’s multiple comparisons test at last time point (dpi = 31) for the following comparisons: AAV-CAVac vs. PBS, p < 0.0001; AAV-CAVac vs. AAV-Vector, p = 0.0224. Two-sided KS test of whole-curves for the following comparisons: PBS vs AAV-Vector, p = 0.26; AAV-CAVac vs. PBS, p = 0.00014; AAV-CAVac vs. AAV- Vector, p = 0.0048. FIG. 2C shows therapeutic efficacy of AAV-CAVac against established orthotopic syngeneic B16F10 tumors by intratumoral administration. Growth curves of orthotopic transplanted B16F10 tumors in C57BL/6J mice treated with PBS and AAV-CAVac at indicated times (arrows). (PBS treated mice, n = 8; AAV-vector treated mice, n = 4; AAV-CAVac treated mice, n = 4). Two-way ANOVA using Turkey’s multiple comparisons test at last two time points (dpi = 2 1 and 25) for the following comparisons: AAV-CAVac vs. PBS, p < 0.0001 for both time points; AAV-CAVac vs. AAV-Vector, p = 0.0008 at dpi =21. FIG. 2D shows H&E staining of representative end point E0771 syngeneic tumor sections from PBS, AAV-Vector, and AAV-CAVac treated mice. Arrows point to inflamed tumor regions with lymphocyte infiltration. FIG. 2E shows CD8 IHC staining of representative end-point E0771 syngeneic tumor sections from PBS, AAV-Vector, and AAV-CAVac treated mice. Arrows point to inflamed tumor regions with CD8+ cells FIGs. 2F-2G show results from ELISPOT experiments for AAV-CAVac. Tumor-specific immune responses in tumor-bearing C57BL/6J mice in different treatment groups were assessed by measuring the ratios of tumor-stimulated IFNy-producing splenocytes with ELISpot assay, using mitomycin-treated tumor cells as the stimulants. Spots were counted using CTL Immunospot Analyzer. FIG. 2F shows representative pictures of spots obtained from triplicates per mouse with four mice for each treatment group (PBS, AAV-Vector and AAV-CAVac). FIG. 2G shows quantification of ELISPOT experiment of PBS (n = 4) , AAV-Vector (n = 7) and AAV- CAVac (n = 9) Datapoints from all mice from FIG. 2F were shown. Two sided Mann- Whitney test for AAV-CAVac vs. PBS, p = 0.0028; AAV-CAVac vs. AAV-Vector, p = 0.005. Results were shown from the combination of 2 independent experiments. Error bars: All data points in this figure were presented as mean ± s.e.m. Asterisks: * p < 0.05, ** p < 0.01, *** p < 0.001. FIGs. 3A-3E illustrate results from interrogation of immune cell population, repertoire shift, and gene expression changes upon therapeutic CAVac treatment using single cell RNA-seq. FIG. 3A is a schematic of the experimental design. Syngeneic orthotopic E0771 tumor bearing mice were treated with PBS or AAV-CAVac. Whole immune population within the tumor microenvironment was purified by anti-CD45 enrichments by FACS (CD45+ tumor infiltrating immune cells, Fils), and subjected to single cell RNA-seq. FIG. 3B shows a t-SNE based dimensional reduction plot showing the clustering patterns of immune cell populations from all Tils sequenced. Clusters 0 to 10 have 1,256, 1,215, 1213, 964, 901, 870, 302, 266, 181, 180, and 101 cells, respectively. FIG. 3C shows a t-SNE based dimensional reduction plot showing the clustering patterns of immune cell populations based on Tils scRNAseq data from mice treated with PBS (n = 5,383 cells) or AAV-CAVac (n = 2,075 cells). FIG. 3D is a bar plot showing proportions of cells in each of the 11 clusters of the whole CD45+ immune cells from mice treated with PBS and AAV-CAVac, respectively. Differences in cluster- specific proportions were assessed by two-sided Fischer’s exact test (***, p < 0.0001). FIG 3E is a heat map of cluster-specific markers identified from scRNA-seq. Of note, cluster 0 is marked by MHC-II molecules, cluster 1 is marked by Ifit family genes, and cluster 9 is marked by T cell specific markers including Cd3d, Cd3g and Gzmb. FIGs. 4A-4Q illustrate exome-guided AAV-CRISPRa based mutated gene set activation as precision multiplexed tumor vaccination (AAV-PCAVac or p-MAEGI, which are used interchangeably herein) against established tumors. FIG. 4A is a schematic of the experimental design. Genomic DNA of cancer cells and normal tissues were extracted, purified, and subjected to whole-exome sequencing. Somatic SNPs and indels in cancer cells were identified by comparison to matched normal tissues, and the CRISPRa sgRNAs targeting these mutants were designed. The mutated gene set customized sgRNA library was synthesized and pool-cloned into the AAV-CRISRPa vector, which was packaged into AAV9 to generate AAV-PCAVac. FIG. 4B shows whole-exome sequencing identified top genomic mutations in E0771 cells, as shown over their positions in the mouse genome. Genes were colored by the presence or absence of SNPs and/or indels. FIG. 4C is a scatter plot showing the number of mutations as SNPs or indels per gene. Genes were filtered by a minimum number of total mutations in E0771 cells compared to wildtype mammary fatpad. Examples of most highly mutated genes are

Tekt2, Hmmr, Acer2, G3bpl, Rsclal, Slu7, and Skint3. A total of 1, 116 genes were used in customized library design. FIG. 4D shows representative images of mice at treatment end-point from PBS and AAV-PCAVac groups in the E0771 syngeneic tumor model. FIG 4E illustrates the therapeutic efficacy of AAV-PCAVac against established E0771 syngeneic tumors by intratumoral administration at indicated times (arrows). PBS treated mice, n = 20; AAV-Vector treated mice, n = 15; AAV-PCAVac (AAV-p-MAEGI) treated mice, n = 20. Tumor growth curves of E0771 syngeneic tumors in mice treated by PBS, AAV-Vector, or AAV-PCAVac. Two-way ANOVA: AAV-Vector vs. PBS, p < 0 0001; AAV-p-MAEGI vs. PBS,p < 0.0001; AAV-PCAVac (AAV-p-MAEGI) vs. AAV-Vector, p < 0.0001. FIG. 4F is a spider plot of tumor growth curves of E0771 syngeneic tumors treated by PBS, AAV-Vector, or AAV-PCAVac (AAV-p-MAEGI). Mice whose tumors had undergone complete response by AAV-PCAVac (AAV-p-MAEGI) (n = 9) were subjected to tumor re-challenges (arrows). No tumors grew with re-challenge, indicating that AAV-p-MAEGI induced long-term anti-tumor effects in mice. Treatment days are indicated by arrows. FIG 4G shows representative pictures of spots obtained from quadruple per mouse with five mice for each treatment group (PBS, AAV-Vector, and AAV-CAVac). FIG 4H shows quantification of ELISPOT experiments of PBS (n = 7), AAV-Vector (n = 6) and AAV-CAVac (n = 9). Two sided Mann-Whitney test for AAV- CAVac vs. PBS, p = 0.002; AAV-CAVac vs. AAV-Vector, p = 0.002. Results were shown from the combination of 2 independent experiments. Error bars: All data points in this figure were presented as mean ± s.e.m. Asterisks: * p < 0.05, ** p < 0.01, *** p <

0.001. FIG. 41 shows representative flow cytometry plots and gating of CD45 +, CD3+, CD4+, and CD8+ T cell populations in the spleens (splenocytes) from tumor-bearing mice treated with PBS or AAV-PCAVac. FIG. 4J shows quantification of CD4+ and CD8+ T cell populations from splenocytes of tumor-bearing mice treated with PBS or AAV- PCAVac. From left to right, bar-dot plots with two-sided unpaired t test for the following comparisons: Fraction of CD4+ T cells in all cells in spleen (absolute fraction); AAV- PCAVac vs. PBS, p = 0.0046. Fraction of CD4+ T cells in all CD45+ immune cells in spleen (relative fraction); AAV-PCAVac vs PBS, p = 0.0017. Fraction of CD8+ T cells in all cells in spleen (absolute fraction); AAV-PCAVac vs. PBS, p = 0.0059. Fraction of CD8+ T cells in all CD45+ immune cells in spleen (relative fraction); AAV-PCAVac vs. PBS, p = 0.0007. FIG. 4K shows representative flow cytometry plots and gating of CD45+, CD3+, CD47 and CD8+ T cell populations in the tumor (TILs) from tumor bearing mice treated with PBS or AAV-PCAVac. FIG. 4L shows quantification of CD4+ and CD8+ T cell populations from TILs of tumor-bearing mice treated with PBS or AAV- PCAVac. From left to right, bar-dot plots with two-sided unpaired t test for the following comparisons: Fraction of CD4+ T cells in all cells in tumor (absolute fraction); AAV- PCAVac vs. PBS, p = 0.025. Fraction of CD4+ T cells in all CD45+ immune cells in tumor (relative fraction); AAV-PCAVac vs. PBS, p = 0.0035. Fraction of CD8+ T cells in all cells in tumor (absolute fraction); AAV-PCAVac vs. PBS, p p = 0.039. Fraction of CD8+ T cells in all CD45+ immune cells in tumor (relative fraction); AAV-PCAVac vs. PBS, p = 0.019. Error bars: All data points in this figure were presented as mean + s e.m. Asterisks: * p < 0.05, ** p < 0.01, *** p < 0.001. FIG. 4M shows response rates for PBS, AAV-Vector, or AAV-PCAVac (AAV-p-MAEGI) treatments, categorized by near- complete or complete response (nCR/CR), partial response (PR), or stable/progressive disease (SD/PD). FIG 4N shows growth curves of E0771 syngeneic tumors in Ragl mice treated by PBS (n = 6), AAV-Vector (n = 5), or AAV-PCAVac (AAV-p-MAEGI) (n = 6). AAV-PCAVac (AAV-p-MAEGI) was ineffective against established E0771 tumors in immunodeficient Rag 1 mice by intratumoral administration at indicated times (arrows). Two-way ANOVA: AAV-Vector vs. PBS, = 0.0653; AAV-PCAVac vs. PBS, p = 0.6982; AAV-p-MAEGI vs. AAV-Vector, p = 0.0634. FIG. 40 is a schematic of an experimental design for evaluating the induction of systemic anti-tumor immunity by AAV-p-MAEGI. 2xl0 6 or 0.25x10s E0771 tumor cells were respectively transplanted into the left or right flank of C57BL/6J mice to model a local and a distant tumor. AAV- p-MAEGI was administered only into the local tumors at the indicated times (arrows). FIGs. 4P-4Q are growth curves of E0771 local (FIG. 4P) and distant (FIG. 4Q) tumors in mice treated by AAV-Vector (n = 18), or AAV-PCAVac (AAV-p-MAEGI) (n = 18). Inset, pie charts detailing the response rates for each treatment. (FIG. 4P) Two-way ANOVA: AAV-p-MAEGI vs. AAV-Vector, p < 0.0001. (FIG. 4Q) Two-way ANOVA: AAV-p-MAEGI vs. AAV-Vector, p = 0.0003 . Error bars: All data points in this figure are presented as mean ± s e.m. Asterisks: *p < . 5, ** < 0.01, ***p < 0.001. FIGs. 5A-5D illustrate library representation of mouse CRISPRa library transduced E0771 cells. FIG. 5A shows library representation of genome-scale CRISPRa library (mouse SAM) transduced E0771 cells from 6 infection replicates from two independent experiments. Out of the 66,749 sgRNAs in the library, the six replicates cover from 99.44% to 99.69% of the total sgRNAs. FIG. 5B is a heat map of pairwise Spearman correlations of library representation of mSAM transduced E0771 cells between the 6 infection replicates from two independent experiments. Pairwise correlation coefficients range from 0.88 to 0.93 between infection replicates, indicating high reproducibility FIG. 5C shows the expression of dCas9 protein in dCas9-VP64 transduced cell lines E0771-dCas9 and E0771-dCas9-MPH confirmed by western blot using monoclonal antibody against Cas9. Anti-GAPDH was used as an internal control. FIG 5D shows quantification of gene activation by CRISPRa at mRNA level based on qPCR assay for genes including Cd70, Cd80, Cd86, Ijha4, If f l, and Ifny. Two-sided unpaired t test for the following comparisons, each gene vs. vector: Cd70, p < 0.0001; Cd80, p < 0.001; Cd86, p < 0.05; Ijha4, p < 0.001; Ι βΐ , p < 0 001; Ifny, p < 0.0001. FIGs. 6A-6H illustrate the finding that genome-scale activation of endogenous genes leads to robust immune rejection of syngeneic tumors. FIG. 6A shows growth curves of SAM activated E0771 cell induced syngeneic orthotopic tumor As compared to vector transduced cells (n = 8), SAM transduced E0771 cells (n = 50) generated tumors were often quickly rej ected by the C57BL/6J host. As compared to vector transduced cells (n = 8), SAM transduced E0771 cells (n = 50) generated tumors were often quickly rejected by the C57BL/6J host. Two-sided KS test, p < 2.2e-16 FIG. 6B shows spider plot growth curves of SAM activated (n = 50) E0771 cell induced syngeneic orthotopic tumor. Most (42/50, 84%) of SAM E0771 tumors were rejected by C57BL/6J mice; None (0/8) of vector E0771 tumors were rejected. FIG. 6C shows growth curves of SAM activated E0771 cell induced orthotopic tumor in syngeneic immunocompetent mice (C57BL/6J, n = 5) and two strains of immunodeficient mice (Nu/Nu , n = 4; Rag , n = 5). Two-sided KS test for the following comparisons of full-curve: C57BL6/J vs. Nu/Nu, p = 3.2e-06; C57BL6/J vs. RagF , p = 1.97e-07; Nu/Nu vs. RagF , p = 0.22; Two-sided KS test for the following comparisons of late-stage curve (14 dpi onward): C57BL6/J vs. Nu/Nu, p = 3.2e-06; C57BL6/J vs. RagF / p = 6.1e-07; Nu/Nu vs. RagF , p = 0.022; Two-way ANOVA using Tukey's multiple comparisons test for the last timepoint (20 dpi) of the following comparisons: C57BL6/J vs. Nu/Nu, p < 0.0001; C57BL6/J vs. RagF , p < 0.0001; Nu/Nu vs. RagF , p < 0.0001. FIGs. 6D-6F show spider plot growth curves of SAM activated (n = 50) E0771 cell induced syngeneic orthotopic tumor. Most (4/5, 80%) of SAM E0771 tumors were rejected by (FIG. 6D) C57BL/6J mice; None (0/9) of SAM E0771 tumors were rejected by (FIG. 6E) Nu/Nu (0/4) or (FIG. 6F) RagF (0/5) mice. FIG 6G shows growth curves of SAM activated E0771 cell induced syngeneic orthotopic tumor under T cell depletion. SAM transduced E0771 cells (n = 11) generated tumors were quickly rejected by the C57BL/6J host if the mice were not treated. Depleting T cells by treating mice with both anti-CD4 and anti-CD8 (n = 4) rendered the tumors capable to grow rapidly C57BL/6J host. Two-sided KS test, untreated vs anti-CD4+anti-

CD8 treated p < 7 9e-10. FIG. 6F1 shows spider plot growth curves of SAM activated E0771 cell induced syngeneic orthotopic tumor under T cell depletion. All (11/11, 100%) of SAM E0771 tumors were rejected by C57BL/6J mice untreated; None (0/4) of vector E0771 tumors were rejected by C57BL/6J mice treated with both anti-CD4 and anti-CD8. Error bars: All data points in this figure were presented as mean ± s.e.m. Asterisks: * p < 0.05, ** p < 0.01, *** p < 0.001. FIGs. 7A-7D illustrate the finding that tumors from E0771 with genome-scale activation of endogenous genes are sensitive to checkpoint blockade FIG. 7A shows growth curves of E0771-SAM escaper tumors in C57BL/6J mice, either untreated (n =

13), or treated by checkpoint blockade antibodies anti-PDl (n = 11) or anti-CTLA4 (n = 11). When treated with either anti-PDl (n = 11) or anti-CTLA4 (n = 11), all E0771-SAM transplanted C57BL/6J mice rejected the tumors. Two-sided KS test for these comparisons: anti-PDl vs untreated, p = 6.008e-06; anti-CTLA4 vs untreated, p = 2.853e- 06. FIGs. 7B-7D show spider plot growth curves of E0771-SAM tumors in C57BL/6J mice, either (FIG. 7B) untreated (n = 13), or treated by checkpoint blockade antibodies (FIG. 7C) anti-PDl (n —I ) or (FIG. 7D) anti-CTLA4 (n - 11). In the duration of study

(28 dpi), of the 13 E0771-SAM transplanted mice in untreated group, 5/13 completely rejected tumor, and 8/13 either grew larger or remained sizable tumor; All anti-PDl

( 11/1 1) and anti-CTLA4 ( 11/1 1) treated mice completely rejected E0771-SAM tumors. Error bars: All data points in this figure were presented as mean ± s.e.m. Asterisks: * p < 0.05, * p < 0.01, *** p < 0.001. FIGs. 8A-8G illustrate additional spider plots of growth curves of cell-based CAVac and combinatorial treatments. FIGs. 8A-8F are spider plots of tumor growth curves of the experiment shown in FIGs. 1A-1F. FIGs. 8A-8B illustrate the therapeutic effect of CAVac on syngeneic orthotopic E0771 tumors in C57BL/6J mice. FIG. 8A shows growth curves of PBS treated E0771 tumors. FIG. 8B shows growth curves of CAVac treated E0771 tumors. FIGs. 8C-8F show growth curves of synergistic effect testing of CAVac and CTLA4 blockade or CD4+ T cell depletion on syngeneic orthotopic E0771 tumors in C57BL/6J mice. FIG. 8C is a spider plot of tumor growth curves of PBS treated E0771 tumors. FIG. 8D is a spider plot of tumor growth curves of CAVac treated E0771 tumors. FIG. 8E is a spider plot of tumor growth curves of anti-CTLA4 and anti- CTLA4+CAVac treated E0771 tumors. FIG. 8F is a spider plot of tumor growth curves of anti-CD4 and anti-CD4+CAVac treated E0771 tumors. FIG. 8G is a spider plot of anti- CTLA4+CAVac treated E0771 tumors with data of long-time points after tumor rejection. Data from PBS-treated tumors in FIG. 8C was used as a control. Arrowhead points out that no tumor relapse was observed in these mice after 90 days, indicating the anti-tumor responses induced by combining CAVac and anti-CTLA4 were long-lasting. FIGs. 9A-9D illustrate results from additional testing of cell-based CAVac. FIG. 9A shows results from testing the effect of untransduced E0771 lysate against established syngeneic orthotopic E0771 tumors. Tumor-bearing mice were treated with PBS or E0771 lysate at indicated times (arrows). (PBS treated mice, n = 6; E0771 lysate, n = 10). Two-sided KS test for E0771 lysate . PBS, p = 0.77. FIG. 9B shows results from testing the effect of active CAVac and inactivated CAVac against established syngeneic orthotopic E0771 tumors (PBS treated mice, n = 4; CAVac, n = 3; CAVac lysate, n = 3). Tumor-bearing mice were treated with PBS, CAVac, or CAVac lysate at indicated times (arrows). Two-sided KS test of late-stage curves (17 dpi onward) of the following comparisons: CAVac vs. PBS, p = 0.004; CAVac lysate vs. PBS, p = 0.97. Two-way ANOVA using Tukey's multiple comparisons test for the last timepoint after tumor induction (24 dpi) of the following comparisons: CAVac vs. PBS, p = 0.0004; CAVac lysate vs. PBS, p = 0.21 15. FIG. 9C shows the single dose effect of CAVac against established syngeneic orthotopic E0771 tumors. Tumor-bearing mice were treated with PBS or CAVac at +3 dpi (arrows). (PBS treated mice, n = 6; CAVac@d3 (CAVac at +3 dpi), n = 5). Two-way ANOVA using Sidak's multiple comparisons test for the last two timepoint after tumor induction (dpi = 24 or 28) of the following comparisons: CAVac@d3 vs. PBS, p = 0.013 and p = 0.003 respectively. Two-sided KS test of late- stage curves (17 dpi onward) of CAVac . PBS, p = 0.0078. FIG. 9D shows CD8+ T cell depletion abolished the effect of CAVac against established syngeneic orthotopic E0771 tumors. Tumor-bearing mice were treated with PBS (n = 5) or CAVac+anti-CD8 (n = 3) at indicated days (upward arrows for CAVac, downward arrows for anti-CD8). Of note, the data of the PBS-treated mice here were same as the five PBS-treated mice (experiment 2) used in FIG 1I-K, as these treatments were done together. Two-sided KS test of CAVac+anti-CD8 vs. PBS, p = 0.78 Error bars: All data points in this figure were presented as mean ± s e.m. Asterisks: * p < 0.05, ** p < 0.01, * p < 0.001. FIGs. 10A-10G illustrate additional spider plot growth curves of AAV-CAVac and combinatorial treatments. FIG. 10A shows quantification of AAV-CRISPRa mediated gene activation at mRNA level based on qPCR assay for genes in minipool, including Cd70, Cd80, Cd86. Two-sided unpaired t test for the following comparisons, each gene vs. vector: Cd70, p < 0.0001; Cd80, p < 0.001; Cd86, p = 0.0054. FIG. 10B is a spider plot of tumor growth curves of PBS treated E0771 tumors. FIG. 10C is a spider plot of tumor growth curves of AAV-Vector treated E0771 tumors. FIG. 10D is a spider plot of tumor growth curves of AAV-CAVac treated E0771 tumors. FIG. 10E is a spider plot of tumor growth curves of PBS treated B16F 10 tumors. FIG. 1OF is a spider plot of tumor growth curves of AAV-Vector treated B16F10 tumors FIG. 10G is a spider plot of tumor growth curves of AAV-CAVac treated B16F10 tumors. FIGs. 11A-11C are a series of Violin plots of representative cluster-specific differentially expressed genes in the scRNA-seq of TILs between AAV-CAVac and PBS treated mice. FIG. 11A are a series of Violin plots of representative cluster #0 specific differentially expressed genes between AAV-CAVac and PBS treated mice. Ccl8 and Ccl7 were more highly expressed in AAV-CAVac treated mice (adjusted p = 1.6e-33 and p = 2.73e-10), whereas Pkm and Aldoa were more highly expressed in PBS treated mice (adjusted p = 8.57e-22 and p = 4.85e-19) FIG. 11B are a set of Violin plots of representative cluster # 1 specific differentially expressed genes between AAV-CAVac and PBS treated mice. Ccl8 was more highly expressed in AAV-CAVac treated mice (adjusted p = 6.65e-20), whereas Pkm was more highly expressed in PBS treated mice (adjusted p = 3.03e-14. FIG. 11C are a series of Violin plots of representative cluster #9 specific differentially expressed genes between AAV-CAVac and PBS treated mice. Ccl8 and Gm26917 were more highly expressed in AAV-CAVac treated mice (adjusted p = 1.73e-12 and p = 1.46e-6), whereas mt-Nd2 and Hmoxl were more highly expressed in PBS treated mice (adjusted p = 5.97e-6 and p = 9.79e-5). FIGs. 12A-12E illustrate interrogation of the T cell repertoire in CAVac or AAV- CAVac treated mice using TCR sequencing. FIG. 12A is a schematics of the TCR-seq experimental design. Mice were treated with PBS, CAVac, or AAV-CAVac. Samples including spleens and tumors were harvested from mice for genomic DNA extraction, and subjected to RT-based TCRa/TCRb capture followed by Illumina sequencing. FIG. 12B is a global occupied clonal homeostasis plot showing clone size patterns of TCRseq data from T cell populations in tumors or in spleens. Hyperexpanded clones are shown in black. FIG. 12C is a global clonal proportion plot showing the relative frequency of the top N clones. FIG. 12D is a scatterplot demonstrating positive correlation between endpoint tumor size and Gini-Simpson index of clonal distribution of the TCR repertoire of all TIL samples from CAVac and AAV-CAVac treated mice. Spearman correlation coefficient R = 0.5433,/» = 0 03632. FIG. 12E shows CDR3 amino acid sequences from major (top 3) clones from three example TIL samples from CAVac and AAV-CAVac treated mice. FIGs. 13A-13B illustrate FACS gating of representative spleen and tumor samples. Single cell suspension from samples were gated by FSC, SSC and then CD45 +, CD3 , CD4+, and CD8+ T cell populations in the spleen (top) or tumor (bottom). FIG. 14 illustrates a simplified model of action for vaccination by multiplexed endogenous gene activation. Left, the unvaccinated tumor microenvironment. In a setting of low neoantigen expression, CD8+ T cells detect rare mutant peptides presented on MHC-I by tumor cells and initiate weak tumor killing. Right, the vaccinated tumor microenvironment. Using CRISPRa, mutated genes in tumor cells are overexpressed, leading to amplified production and presentation of neoantigens to CD8+ T cells. With enhanced engagement of the TCR, CD8+ T cells initiate more robust killing in the vaccinated microenvironment. FIGs. 15A-15D illustrates CD4+ and CD8+ T cells in the spleen and tumors of mice treated with PBS, AAV-Vector, or AAV-PCAVac. FIG. 15A shows representative flow cytometry pictures and gating of CD45+, CD3+, CD4+, and CD8+ T cell populations in the spleens (splenocytes) from tumor-bearing mice treated with PBS or AAV-PCAVac. FIG 15B shows quantification of CD4 and CD8+ T cell populations from splenocytes of tumor-bearing mice treated with PBS, AAV-Vector, or AAV-PCAVac. From left to right, bar-dot plots with Mann Whitney test for the following comparisons: Fraction of CD4+ T cells in all cells in spleen (absolute fraction); AAV-PCAVac vs. PBS, p = 0.0003; AAV- PCAVac vs. AAV-Vector, p = 0.0028. Fraction of CD4+ T cells in all CD45+ immune cells in spleen (relative fraction); AAV-PCAVac vs. PBS, p = 0.0007; AAV-PCAVac vs. AAV-Vector, p = 0.0048. Fraction of CD8+ T cells in all cells in spleen (absolute fraction); AAV-PCAVac vs. PBS, p = 0.0032; AAV-PCAVac vs. AAV-Vector, p = 0.0016. Fraction of CD8+ T cells in all CD45+ immune cells in spleen (relative fraction); AAV-PCAVac vs. PBS, p = 0.0012; AAV-PCAVac vs. AAV-Vector, p = 0.0016. FIG 15C shows representative flow cytometry pictures and gating of CD45+, CD3L CD4+, and CD8+ T cell populations in the tumor from tumor-bearing mice treated with PBS or AAV-PCAVac FIG. 15D shows quantification of CD4+ and CD8+ T cell populations of the tumors from mice treated with PBS or AAV-PCAVac. From left to right, bar-dot plots with Mann Whitney test for the following comparisons: Fraction of CD4+ T cells in all cells in tumor (absolute fraction); AAV-PCAVac vs. PBS, p = 0.0007; AAV-PCAVac vs. AAV-Vector, p = 0.0256. Fraction of C 4 T cells in all CD45+ immune cells in tumor (relative fraction); AAV-PCAVac vs. PBS, p = 0.01 15; AAV- PCAVac vs. AAV-Vector, p = 0.0256. Fraction of CD8+ T cells in all cells in tumor (absolute fraction); AAV-PCAVac vs. PBS, p = 0.0047; AAV-PCAVac vs. AAV-Vector, p = 0.0332. Fraction of CD8+ T cells in all CD45 + immune cells in tumor (relative fraction); AAV-PCAVac vs. PBS, p = 0.0161, AAV-PCAVac vs. AAV-Vector, p = 0.0248. Error bars: All data points in this figure were presented as mean ± s.e.m. Asterisks: * p < 0.05, ** p < 0.01, *** p < 0.001. FIGs. 16A-16G illustrate boosting the expression levels of single genes or a small set of genes in tumor cells with CRISPRa resulted in tumor rejection in mice. FIG 16A shows growth curves of Arhgap30 or Nolcl activated E0771 cell induced syngeneic orthotopic tumor. As compared to vector transduced cells, sg-Arhgap30 or sg-Nolcl transduced E0771 cells generated tumors that grew slower and often got rejected by the C57B1/6J host. Two-way ANOVA using Tukey's multiple comparisons test for the following comparisons: sg-Arhgap30 vs. vector, p = 0.0003 and p < 0.0001 for dpi 20 and 23, respectively; sg-Nolcl vs. vector, p = 0.0123 and p = 0.0002 for dpi 20 and 23, respectively. Two-sided Kolmogorov-Smirnov (KS) test for the following comparisons: sg-Arhgap30 vs. vector, p = 0.003; sg-Nolcl vs. vector, p = 0.02. FIGs. 16B-16D show spider plot growth curves of Arhgap30 or Nolcl activated E0771 cell induced syngeneic orthotopic tumor in vector (n = 7) (FIG. 16B), sg-Arhgap30 (n = 3) (FIG. 16C), and sg- Nolcl (n = 3) (FIG. 16D). All (3/3) of sg-Arhgap30 E0771 tumors were rejected by C57BL/6J mice; 2/3 of sg-Nolcl E0771 tumors were rejected; None (0/7) of vector E0771 tumors were rejected. FIG. 16E shows quantification of gene activation by CRISPRa at mRNA level based on qPCR assay for genes used in minipools experiment, including Cd70, Cd80, Cd86, Ifna4, Ι ηβ ΐ , and Ifny. Two-sided unpaired t test for the following comparisons, each gene vs. vector: Cd70, p < 0.0001; Cd80, p < 0.001; Cd86, p < 0.05; Ifna4, p < 0.001; Ι ηβ ΐ , p < 0.001; Ifny, p < 0.0001. FIG. 16F shows growth curves of minipool (sg-Cd70, sg-Cd80, sg-Cd86, sg-Ifna4, sg-ΙΓηβΙ , and sg-Ifny) activated E0771 cell induced syngeneic orthotopic tumor. As compared to vector transduced cells, minipool transduced E0771 cells generated tumors were all quickly rejected by the C57BL/6J host. Two-sided KS test, p = 3.5 le-8 FIG. 16G shows spider plot growth curves of minipool activated (n = 5) and vector control (n = 5) E0771 cell induced syngeneic orthotopic tumor. All (5/5) of minipool E0771 tumors were rejected by C57BL/6J mice; None (0/5) of vector E0771 tumors were rejected. Error bars: All data points in this figure were presented as mean +/- s.e.m. Asterisks: * p < 0.05, * p < 0.01, *** p < 0.001. FIGs. 17A-17C illustrate concepts for two modes of multiplexed vaccination with endogenous gene activation using the CRISPRa system. FIG. 17A is a schematic illustrating mutated antigen presentation and T cell recognition in the unvaccinated tumor microenvironment. FIG. 17B is a schematic illustrating augmentation of the immune response by CRISPRa amplification of mutated endogenous genes in cancer cells. FIG. 17C is a schematic illustrating augmentation of the immune response by CRISPRa amplification of genes encoding antigen-presentation machinery in cancer cells.

FIG. 18 illustrates the Precision (“Personalized”) AAV-PCAVac system as a therapeutic vaccine against triple-negative breast cancer (TNBC). Efficacy of AAV- PCAVac multiplexed endogeneous gene activation is demonstrated in a syngeneic orthotopic model in C57BL/6J host. Shown is a survival curve of E0771 TNBC engrafted in the mammary fatpad of C57BL/6J female mice, treated with PBS, AAV-Vector, or AAV-PCAVac library, which targets a set of most highly mutated genes in E0771 cells as compared to normal mammary fatpad of C57BL/6J female mice. Efficacy is seen in both AAV-Vector and AAV- PCAVac, where AAV- PCAVac has stronger anti-tumor effect. Log-rank test p values were shown for comparison of survival curves. FIG. 19 is a table showing a summary of treatment responses of PBS, AAV- Vector, and AAV-PCAVac in E0771 TNBC syngeneic orthotopic model in C57BL/6J host. FIG. 20 is a table showing a summary of treatment responses of PBS, AAV- Vector, and AAV-PCAVac in a two-side tumor induction E0771 TNBC syngeneic orthotopic model in C57BL/6J host. FIG. 2 1 is a table showing a summary of E0771 tumor re-challenge after complete regression of first E0771 tumor with AAV-treatment in a syngeneic orthotopic TNBC model in C57BL/6J host. FIG. 22 illustrates the Precision (“Personalized”) AAV-PCAVac system as a therapeutic vaccine against TNBC. Efficacy of AAV-PCAVac multiplexed endogenous gene activation was demonstrated in a syngeneic orthotopic model in C57BL/6J host. Survival curve of E0771 TNBC engrafted in the mammary fatpad of C57BL/6J female mice, treated with PBS, AAV-Vector, AAV-Emutl 1 library or AAV-PCAVac library. The Emutl 1 library targets a set of top 11 mutated genes in E0771 cells. Efficacy is seen in both AAV-Vector, AAV-Emutl 1 and AAV- PCAVac, where AAV- PCAVac has strongest anti-tumor effect. Log-rank test p values were shown for comparison of tumor growth curves to PBS group. * p < 0.05; * p < 0.01; *** p < 0.001. FIG. 23 illustrates an off-the-shelf AAV-APCM system as a therapeutic vaccine. Efficacy of AAV-APCM multiplexed endogenous gene activation is demonstrated in a syngeneic orthotopic model in C57BL/6J host. Shown is a tumor growth curve of E0771 TNBC engrafted in the mammary fatpad of C57BL/6J female mice, treated with PBS, AAV-Vector, or AAV-Apcm library, which targets a small set of genes chosen to elicit immune response (36 genes, 107 sgRNAs). Efficacy is seen in both AAV-Vector and AAV-Apcm, where AAV-Apcm has stronger anti-tumor effect Log-rank test, * p < 0 05; ** p < 0.01. FIG. 24 illustrates an off-the-shelf whole-genome AAV-CAVac system as a therapeutic vaccine against melanoma. Therapeutic efficacy of whole-genome gene activation AAV-CAVac (i.e. AAV-SAM) against established orthotopic syngeneic B16F10 tumors by intratumoral administration is demonstrated. Growth curves of orthotopic transplanted B16F 10 tumors in C57BL/6J mice treated with PBS and AAV- CAVac at indicated times (arrows) are shown. Log-rank test, * p < 0.05; ** p < 0.01. FIG. 25 illustrates an off-the-shelf whole-genome AAV-CAVac system as a therapeutic vaccine against pancreatic cancer. Therapeutic efficacy of whole-genome gene activation AAV-CAVac (also referred to as AAV-g-MAEGI) against established orthotopic syngeneic Pan02 tumors by intratumoral administration is demonstrated Growth curves of subcutaneous transplanted Pan02 tumors in C57BL/6J mice treated with PBS, AAV-Vector and AAV-CAVac (AAV-g-MAEGI ) at indicated times (arrows) are shown. (PBS treated mice, n = 4; AAV-vector treated mice, n = 5; AAV-g-MAEGI treated mice, n = 5). Two-way ANOVA: AAV-Vector vs. PBS,/? < 0.0001; AAV-g- MAEGI vs. PBS, ?< 0.0001; AAV-g-MAEGI vs. AAV-Vector,/? < 0.0001. Asterisks: * p < 0.05; ** p < 0.01, ***/? < 0.001. FIG. 26 illustrates an off-the-shelf AAV-SingleCAVac system as a prophylatic vaccine. Efficacy of AAV-SingleCAVac endogenous gene activation in a syngeneic orthotopic model in C57BL/6J host is demonstrated. Shown are growth curves of Arhgap30 or Nolcl activated E0771 cell induced syngeneic orthotopic tumor. As compared to vector transduced cells, sg-Arhgap30 or sg-Nolcl transduced E0771 cells generated tumors that grew slower and often got rejected by the C57B1/6J host. Two-way ANOVA using Tukey's multiple comparisons test for the following comparisons: sg- Arhgap30 vs. vector, p = 0.0003 and p < 0.0001 for dpi 20 and 23, respectively; sg-Nolcl vs. vector, p = 0.0123 and p = 0.0002 for dpi 20 and 23, respectively. Two-sided Kolmogorov-Smirnov (KS) test for the following comparisons: sg-Arhgap30 vs. vector, p = 0.003; sg-Nolcl vs. vector, p = 0.02. * p < 0.05; ** p < 0.01. FIG. 27 is a table illustrating the sgRNA sequences for an AAV-Apcm library (SEQ ID NOs: 23,779-23,885). FIGs. 28A-28B are a set of tables illustrating the sgRNA sequences of an AAV- Apch library (SEQ ID NOs: 23,886-24,104). FIGs. 29A-29D illustrate multiplexed activation of endogenous genes as an immunotherapy (MAEGI) in a cellular formulation. FIG. 29A shows schematics for generating genome-scale CRISPR activation (SAM) sgRNA library-transduced cells and analysis of tumorigenic capacity. FIG. 29B shows tumor growth curves of Vector or SAM transduced E0771-dCas9-VP64-MPH cells (E0771-Vector or E0771-SAM). As compared to vector transduced cells (n = 8), orthotopic tumors from E0771-SAM cells (n = 50) were robustly rejected by the C57BL/6J host. Two-way ANOVA: p < 0.0001. FIG. 29C shows tumor growth curves of E0771-SAM cells in syngeneic immunocompetent mice (C57BL/6J, n = 5) and two strains of immunodeficient mice (Nu/Nu, n = 4; RagF n = 5). Two-way ANOVA: C57BL/6J vs Nu/Nu, p < 0.0001; C57BL/6J vs. RagF ,p < 0.0001, Nu/Nu vs. RagF ,p < 0.0001. FIG 29D shows tumor growth curves of E0771- SAM cells under T cell depletion. Whereas tumors from E0771-SAM cells (n = 11) were quickly rejected in C57BL/6J mice, depletion of T cells by a-CD4 and a-CD8 (n = 4) enabled rapid tumor growth. Two-way ANOVA test, untreated vs. a-CD4 + a-CD8 treated,/» < 0.0001. FIGs. 30A-30G illustrate characterization of cells transduced with the CRISPRa system, and escaper tumors formed by CRISPRa library-transduced cells are sensitive to checkpoint antibodies FIG. 30A shows the expression of dCas9 protein in E0771-dCas9- VP64 and E0771-dCas9-VP64-MPH cell lines confirmed by western blot using a monoclonal antibody against Cas9 Anti-GAPDH was used as an internal control. FIG. 30B shows tumor growth curves of parental E0771 cells compared to E0771 cells transduced to express dCas9-VP64. Two-way ANOVA: p = 0 0023. FIG. 30C shows library representation of genome-scale mouse CRISPRa (SAM) library-transduced E0771 cells from 6 infection replicates from two independent experiments. Out of the 66,749 sgRNAs in the library, the six replicates cover from 99.44% to 99.69% of the total sgRNAs. FIG. 30D shows growth curves ofE0771-SAM escaper tumors in C57BL/6J mice, either PBS-treated (n = 13), or treated by checkpoint blockade antibodies -PDl (n

= 11) or a-CTLA4 (n = 11). Arrows indicate time points of treatment. When treated with either α-PDl (n = 11) or a-CTLA4 (n = 11), all E0771-SAM transplanted C57BL/6J mice rejected the tumors. Two-way ANOVA: p = 0.0003 for PBS vs. α-PDl or a-CTLA4. (FIGs. 30E-30G) (Related to FIG. 30D) show spider plot growth curves of E0771-SAM escaper tumors in C57BL/6J mice, either (FIG. 30E) PBS-treated (n = 13), or treated by checkpoint blockade antibodies (FIG. 30F) -PDl (n = 11) or (FIG. 30G) a-CTLA4 (n = 11). Arrows indicate time points of treatment. Over the duration of study (28 dpi), 5/13 E0771-SAM escaper tumors were eventually rejected by PBS-treated mice, while 8/13 either grew larger or remained sizable tumors. All -PDl (11/11) and a-CTLA4 ( 1 1/1 1) treated mice completely rejected E0771 -SAM tumors. Error bars: All data points in this figure were presented as mean ± s.e.m. Asterisks: *p < 0.05, **p < 0.01, ***/> < 0.001. FIGs. 31A-31G illustrate thermally-induced cell lysis or CD8+ T cell depletion abolishes the therapeutic effect of c-MAEGI. FIG. 31A shows results from testing the therapeutic effect of heat-induced cell lysates from non-transduced E0771 against established syngeneic orthotopic E0771 tumors. Tumor-bearing mice were treated with PBS or E0771 lysate at indicated times (arrows). (PBS treated mice, n = 6; E0771 lysate, n = 10). Two-way ANOVA: p = 0.8916 FIG. 3IB shows a comparison of the therapeutic effects of c-MAEGI and heat-induced lysates of c-MAEGI against established syngeneic E0771 tumors. Tumor-bearing mice were treated with PBS, c-MAEGI, or c-MAEGI lysates at indicated times (arrows). (PBS treated mice, n = 4; c-MAEGI, n = 3; c-MAEGI lysates, n = 3). Two-way ANOVA: PBS vs. c-MAEGI,p = 0 0004; PBS vs. c-MAEGI lysates, = 0.8856; c-MAEGI lysates vs. c-MAEGI,/ = 0.0007 FIG. 31C shows tumor growth curves of E0771- Vector derived tumors that were treated with PBS, a-CD8, or c- MAEGI + a-CD8. Dark grey arrows: c-MAEGI treatment; ligh grey arrows: a-CD8 treatment. CD8+ T cell depletion abolished the effect of c-MAEGI against established syngeneic E0771 tumors. Two-way ANOVA: PBS vs a-CD8,/> = 0.9744; PBS vs c- MAEGI + a-CD8,/> = 0.6037; a-CD8 vs. c-MAEGI + a-CD8,/> = 0.705. FIG. 31D shows representative peripheral blood flow cytometry analysis of CD8+ T cells after PBS or a- CD8 treatment, gated on CD45+CD3 + cells Top row, PBS treatment; bottom row, a-CD8 treatment. Left column, DPI = 14; right column, DPI = 21. X-axis of scatterplots, CD4; Y-axis of scatterplots, CD8a. Percentages are noted in each quadrant. Over 50,000 PBMCs were analyzed for each sample. FIG. 3IE is a bar plot detailing the % of CD8+ T cells among CD45 + PBMCs, 14 days after PBS or a-CD8 treatment. Two-tailed unpaired + t-test: PBS vs. a-CD8,/ ? < 0.0001. FIG. 3IF is a bar plot detailing the % of CD8 T cells among CD45+ PBMCs, 2 1 days after PBS or a-CD8 treatment. Two-tailed unpaired t-test: PBS vs. -CD8, >< 0.0001. FIG. 31G is a spider plot of tumor growth curves of syngeneic orthotopic E0771 tumors in C57BL/6J mice, evaluating the combination of c- MAEGI and CTLA4 blockade with extended follow-up and tumor re-challenges. Arrowheads indicate time points of tumor re-challenge, indicating that the anti-tumor responses induced by combining c-MAEGI and a-CTLA4 were long-lasting. Error bars: All data in this figure are presented as mean ± s.e.m., with individual data points shown. Asterisks: *p < 0.05, ** p < 0.01, ***/? < 0.001. FIGs. 32A-32C illustrate the finding that AAV-CRISPRa system specifically enhances gene expression and cell surface presentation of antigens. FIG. 32A shows AAV-CRISPRa activation of multiple endogenous genes in a pooled manner. The transcript levels of Cd70, Cd80, Cd86 were quantified by qRT-PCR after transducing E0771-dCas9-VP64 cells with either AAV-Vector or AAV-sgRNA-miniLib. Two-sided unpaired t-test for sgRNAs vs. vector: Cd70,p < 0.0001; Cd80,p = 0.0005, Cd86,p < 0.0001. FIGs. 32B-32C show AAV-CRISPRa specifically enhances the cell surface presentation of a model antigen in the form of peptide-MHC-I complexes. In cells transduced with lentivirus to express ovalbumin (Ova) under a PGK promoter, AAV- CRISPRa targeted to the PGK promoter augments the presentation of Ova-derived SLINFEKL-MHC-I complex on cell surface. FIG. 32B shows representative flow cytometry analysis of surface staining for SIINFEKL-H-2K complex on cells treated with AAV-Vector or AAV-sgRNAs. FIG. 32C shows quantitative analysis of mean fluorescence intensity (MFI) of PE-SIINFEKL-H-2K on cells treated with AAV-Vector or AAV-sgRNAs with data from 4 independent experiments. Two sided Mann-Whitney test: SIINFEKL-H-2K staining vs. isotype in AAV-Vector,/? = 0.0146; SIINFEKL-H- 2K staining vs. isotype in AAV-sgRNAs,/? = 0.0006; SIINFEKL-H-2K staining in AAV-sgRNAs vs. AAV-Vector,/? = 0.0484. FIGs. 33A-33D illustrate additional characterization of AAV-MAEGI. FIGs. 33A-33B show H&E (FIG. 33A) or CD8 (FIG. 33B) staining of E0771 tumors in mice treated with PBS, AAV-Vector, or AAV-g-MAEGI. (Tumor harvest dpi = 31). Scale bars of zoomed-out images and insets = 200 pm. FIGs. 33C-33D show AAV infection efficiency assessed by intratumoral delivery of GFP-expressing AAVs and flow cytometry analysis. FIG 33C shows percentages of GFP+ cells within tumors from mice 4 days after intratumoral injection of PBS (n = 3) or AAV-GFP (n = 12), grouped by CD45+ and CD45 cells. The background GFP fluorescence was set as the maximum % GFP positivity in PBS samples, denoted by a dashed line. Fractions above AAV conditions denote the number of samples with % GFP positivity above background in the indicated cell population. FIG. 33D shows percentages of GFP+ cells in various organs after intratumoral injection of AAV-GFP (n = 6). Error bars: All data in this figure are presented as mean ± s e.m., with individual data points shown. Asterisks: *p < 0 05, ** p

< 0.01, ***p < 0.001 . FIGs. 34A-34D illustrate histological characterization of E0771 tumors treated with AAV-p-MAEGI. FIGs. 34A-34C showH&E (FIG. 34A), CD8 (FIG. 34B), or Ki67 (FIG. 34C), staining of E0771 tumors collected from mice treated with PBS, AAV- Vector, or AAV-p-MAEGI. (Tumor harvest dpi = 36). FIG. 34D illustrates quantification of % Ki67 positivity in E0771 tumors collected from mice treated with PBS, AAV- Vector, or AAV-p-MAEGI. Scale bars of zoomed-out images and insets = 200 pm. FIGs. 35A-35C illustrate representative flow cytometry gating and CDR3 amino acid sequences from major tumor-infiltrating T cell clones. FIG. 35A shows representative flow cytometry gating of CD45 CD3 +, CD4+, and CD8+ cell populations within tumors from mice treated with PBS, AAV-Vector or AAV-p-MAEGI. FIG 35B shows representative flow cytometry gating of monocytes, neutrophils, MHCIE cells, dendritic cells, and macrophages in tumors from mice treated with PBS, AAV-Vector, or AAV-p-MAEGI, 19 days after tumor induction. FIG. 35C shows CDR3 amino acid sequences from major (top 3) clones in three example TIL samples from PBS, AAV- Vector, AAV-g-MAEGI, and AAV-p-MAEGI treated mice. FIGs. 36A-36N illustrate the finding that AAV-p-MAEGI treatment promotes infiltration of tumor-reactive immune populations. FIG. 36A shows AAV-p-MAEGI treatment is associated with increased CD4+ T cell abundance in the tumor microenvironment. Flow cytometry time-course quantification of CD4+ T cells out of total tumor cells from mice treated with PBS, AAV-Vector, or AAV-p-MAEGI. Two- tailed Mann-Whitney test: AAV-p-MAEGI vs. PBS at dpi 9 p = 0.6857), dpi 19 p = 0.0047), dpi 29 p = 0 0048), and dpi 36 (p = 0.0015); AAV-p-MAEGI vs. AAV-Vector at dpi 9 p = 0.2000), dpi 19 p = 0.2569), dpi 29 (p = 0.0159), and dpi 36 (p = 0.0422); FIG 36B shows AAV-p-MAEGI treatment is associated with increased CD8+ T cell abundance in the tumor microenvironment. Flow cytometry time-course quantification of CD8+ T cells out of total tumor cells from mice treated with PBS, AAV-Vector, or AAV- p-MAEGI. Two-tailed Mann-Whitney test: AAV-p-MAEGI vs. PBS at dpi 9 (p = 0.6857), dpi 19 p = 0 0047), dpi 29 p = 0.0005), and dpi 36 p = 0.0014); AAV-p- MAEGI vs. AAV-Vector at dpi 9 (p = 0.4857), dpi 19 p = 0.2569), dpi 29 (p = 0.0064), and dpi 36 (p = 0.0200). FIG. 36C shows percentage of CD45+MHC-II + antigen presenting cells in tumors from mice treated with PBS, AAV-Vector, or AAV-PCAVac. Two-tailed Mann-Whitney test: AAV-Vector vs. PBS. p = 0.0225; AAV-PCAVac vs. PBS,/? = 0.0001; AAV-PCAVac vs. AAV-Vector, p = 0.0147. FIG. 36D shows percentage of dendritic cells in tumors from mice treated with PBS, AAV-Vector, or AAV- PCAVac. Two-tailed Mann-Whitney test: AAV-Vector vs. PBS,/? = 0.0075; AAV-PCAVac vs. PBS,/? = 0.0008; AAV-PCAVac vs. AAV-Vector ,p = 0.0692. FIG. 36E shows percentage of macrophages in tumors from mice treated with PBS, AAV- Vector, or AAV- PCAVac. Two-tailed Mann-Whitney test: AAV-Vector vs. PBS,/? = 0.6353; AAV-PCAVac vs. PBS,/? = 0.5532; AAV-PCAVac vs. AAV-Vector,/? = 0.9229. FIG 36F shows percentage of monocytes in tumors from mice treated with PBS, AAV- Vector, or AAV- PCAVac. Two-tailed Mann-Whitney test: AAV-Vector vs. PBS,/? = 0.1471; AAV-PCAVac vs. PBS,/? = 0.5533; AAV-PCAVac vs. AAV-Vector,/? = 0.0426. FIG 36G shows percentage of neutrophils in tumor from mice treated with PBS, AAV- Vector, or AAV- PCAVac. Two-tailed Mann-Whitney test: AAV-Vector vs. PBS,/? = 0.0559; AAV-PCAVac vs. PBS,/? = 0.6165; AAV-PCAVac vs. AAV-Vector,/? = 0.4176. FIG 36H is a schematic of an experimental design to assess anti-tumor specificity of the immune response elicited by AAV-p-MAEGI. FIG. 361 shows representative images of ERNy ELISPOTs on splenocytes obtained from five E0771 tumor-bearing mice for each treatment group (PBS, AAV-Vector, and AAV-p-MAEGI). FIG. 36J shows quantification of IFNy ELISPOTs on splenocytes from PBS (n = 7), AAV-Vector (n = 6) and AAV-g-MAEGI (n = 9) treated mice bearing E0771 tumors Two sided unpaired t- test: AAV-Vector vs. PBS,/? = 0.1499; AAV-g-MAEGI vs. PBS,/? = 0.0006; AAV-g- MAEGI vs. AAV-Vector, p = 0.001 1. Results shown are from the aggregation of 2 independent experiments. FIG. 36K shows representative images of EFNy ELISPOTs on splenocytes from AAV-Vector or AAV-p-MAEGI treated mice bearing E0771 tumors, stimulated with either normal primary cells from wildtype C57BL/6J fat pad tissue (Normal) or E0771 cells (Cancer). FIG. 36L shows quantification of FN ELISPOTs on splenocytes from AAV-Vector (n = 9) or AAV-p-MAEGI (n = 9) treated mice bearing E0771 tumors that were stimulated with primary C57BL/6J normal cells or cancer cells. Two sided unpaired t-test: AAV-p-MAEGI vs. AAV-Vector stimulated by normal cells,/? = 0.1667; AAV-p-MAEGI vs. AAV-Vector stimulated by E0771 cancer cells,/? = 0.0057; Cancer vs. Normal cells stimulation within AAV-Vector group,/? = 0.0004; Cancer vs. Normal cells stimulation within AAV-p-MAEGI group,/? = 0.0002. Results shown are aggregated from 2 independent experiments. FIG. 36M shows representative images of IFNy ELISPOTs on tumor-infiltrating immune cells (TIICs) from AAV-Vector or AAV-p-MAEGI treated mice bearing E0771 tumors, stimulated with either primary cells from wildtype C57BL/6I fat pad tissue (Normal) or E0771 cells (Cancer). FIG. 36N shows quantification of FN ELISPOTs for TIICs from AAV-Vector (n = 6) or AAV-p- MAEGI (n = 6) treated mice bearing E0771 tumors that were stimulated with primary C57BL/6J normal cells or cancer cells. Two-sided unpaired t-test: AAV-p-MAEGI vs. AAV-Vector stimulated by Normal cells,/? = 0.0577; AAV-p-MAEGI vs. AAV-Vector stimulated by cancer cells,/? < 0.0001; Cancer vs. Normal cells stimulation for AAV- Vector group, p = 0.0175; Cancer vs. Normal cells stimulation for AAV-p-MAEGI group, p < 0.0001. Error bars: All data points in this figure are presented as mean ± s.e.m. Asterisks: */? < 0.05, **/? < 0.01, ***/? < 0.001. FIGs. 37A-37F illustrate interrogation of the T cell repertoire in MAEGI-treated mice by TCR sequencing. FIG. 37A is a schematic of a TCR-seq experiment design Mice bearing E0771 tumors were treated with PBS, AAV-Vector, AAV-g-MAEGI (genome-wide), or AAV-p-MAEGI (exome-guided). Spleens and tumors were harvested from mice for genomic DNA extraction, and subjected to RT-based TCRa/TCRp capture followed by Illumina sequencing. FIG. 37B is a global clonal proportion plot showing the relative frequencies of the top N clones. FIG. 37C is a boxplot of Chaol indices (TCR diversity) for each sample. Statistical significance was assessed by unpaired two-tailed Mann-Whitney test. FIG. 37D is a boxplot of Gini-Simpson indices (TCR evenness) for each sample. Statistical significance was assessed by unpaired two-tailed Mann-Whitney test. FIGs. 37E-37F are dot plots of the number of unique clonotypes identified (TCR richness) in each spleen sample (FIG. 37E) or TIL sample (FIG. 37F), compared across treatment conditions. Statistical significance was assessed by unpaired two-tailed t-test. FIGs. 38A-38F illustrate single cell RNAseq profiling of immune populations in the tumor microenvironment. FIG. 38A is a schematic of an experimental design for single cell RNAseq (scRNAseq) analysis of immune populations in AAV-Vector (n = 3) or AAV-p-MAEGI treated mice (n = 3). Cells from replicate mice were pooled together for scRNAseq library preparation. FIG. 38B is a scatter plot of t-SNE dimensional reduction, with cells colored by k-means cluster. Putative cell types associated with each cluster are annotated on the plot. Cluster 7 (k7) is composed of CD45 cells and was excluded from further analyses (see FIGs. 39A-39F). The number of cells in each cluster is noted to the right. FIG. 38C is a scatter plot of t-SNE dimensional reduction as in (FIG. 38B) but colored by treatment group. scRNAseq cell numbers after preprocessing: AAV- p-MAEGI, n = 4,065 cells; AAV-Vector, n = 2,799 cells. FIG 38D shows identification of T cell populations from scRNAseq. Left, t-SNE dimensional reduction, with cells colored by Cd3e expression. Right, zoomed-in view of clusters k6 and k9, colored by Cd8a expression (top) or Cd4 expression (bottom). Triangles correspond to cells from AAV-p-MAEGI, while circles correspond to cells from AAV-Vector. FIG. 38E shows quantification of T cell populations in k6 and k9. AAV-p-MAEGI mice have a higher proportion of CD3 + T cells, CD8+ T cells, and CD4+ T cells out of total TIICs. Two-sided Fisher’s exact test, AAV-p-MAEGI vs AAV-Vector: p < 0.0001 for CD3e+ T cells, CD8+ T cells, and CD4+ T cells. FIG. 38F shows quantification of CD4 T cell subpopulations in k6 and k9. AAV-p-MAEGI mice have a higher proportion of Tbx21+ cells, Ifiig cells, and Tbx21+Ifng+ cells out of total CD4+ T cells. Two-sided Fisher’s exact test, AAV-p-

MAEGI vs AAV-Vector: p < 0.0001 for Tbx21+ cells,/? = 0.01 11 for Ifng cells, and p = 0.0109 for Tbx21+lftrg+ cells. Error bars: All data points in this figure are presented as mean + s.e.m.Asterisks: *p < 0.05, ** p < 0.01, *** p < 0.001. FIGs. 39A-39F illustrate processing of scRNAseq data to exclude CD45 cells and characteristic markers of each scRNAseq cluster. FIG. 39A shows t-SNE of all single cells passing the filtering criteria, colored by k-means clustering. FIG. 39B shows Violin plots of Ptprc (encoding CD45) expression, grouped k-means cluster. Cluster 7 is largely absent for Ptprc expression. FIG. 3 C shows Violin plots of Cd3e, Cd4, CD8a, 117r, and Gzmb expression, defining different T cells FIG. 39D show Violin plots of Cdl9, Cd20, Pax5, Jchain, and Ly6d expression, defining different B cells. FIG. 39E shows Violin plots of by 7 , Batf3, CleclOa, and CD209a expression, defining different dendritic cells. FIG 39F shows Violin plots of Cdl4, Fcgrl, and Adgrel (encoding F4/80) expression, defining macrophages and monocytes. FIGs. 40A-40D illustrate the finding that AAV-p-MAEGI treatment is associated with transcriptional changes in tumor-infiltrating T cells. FIGs. 40A-40C show in the top panel, volcano plots of CD8+ T cells in k6 (FIG. 40A), CD8+ T cells in k9 (FIG. 40B), and CD4+ T cells in k6 and k9 (FIG. 40C), comparing AAV-p-MAEGI to AAV-Vector. Bottom panel shows gene ontology enrichment analysis of upregulated genes in T cells from AAV-p-MAEGI mice. FIG. 40D shows a simplified model of action for multiplexed activation of endogenous genes as an immunotherapy (MAEGI). Left panel: the untreated tumor microenvironment. In a setting of low neoantigen expression, CD8+ T cells detect rare mutant peptides presented on MHC-I by tumor cells and initiate weak tumor killing. Right panel: the MAEGI-treated tumor microenvironment. Using CRISPRa, mutated genes in tumor cells are overexpressed from endogenous loci, leading to amplified production and presentation of neoantigens to CD8+ T cells, thereby resulting in a robust anti-tumor response. FIG. 4 1 illustrates that while AAV-MAEGI is highly efficacious (left panel), intratumoral delivery of the predicted top 20 mutant mini-ORFs by AAV (AAV- 20MutORF) is not more effective than AAV-Vector alone (left, same as FIG. 4E). Right panel: treatment of E0771 tumor on C57BL/6 mice with PBS, AAV-Vector, or AAV- 20MutORF, where the top 20 predicted most antigenic neoantigens were selected based on their the mutational profile in E0771 cells and concatenated as an ORF to be expressed in AAV as a transgene. FIG. 42 illustrates data from treatment of B16F10 tumors on C57BL/6 mice with PBS, AAV-Vector, AAV-g-MAEGI (genome-wide library) or AAV-mini-MAEGI, where the 15 genes were selected based on their ranking of the mutational profile in B16F10 cells.

FIG. 43 illustrates reduced efficacy with Emutl 1, as compared to strong efficacy with E0771-p-MAEGI carrying an sgRNA library targeting 1,116 mutant genes. Left panel: same as FIG. 4M). Right panel: treatment of E0771 tumor on C57BL/6 mice with

PBS, AAV-Vector, or AAV-Emutl 1, where the top 11 genes were selected based on their ranking of the mutational profile in E0771 cells, and their activation was driven by a small sgRNA library targeting the promoter of these genes. FIGs 44A-44B illustrate dual AAV delivery for activation of an endogenous gene in E0771 cells using AAV-dCas9 and AAV-sgRNA, both packaged in AAV9. FIG 44A is a schematic of dual AAV delivery. FIG. 44B shows dual AAV activation of Pmel FIG. 45 illustrates Dual AAV delivery for activation of an endogenous gene in E0771 cells using AAV-dCas9 (either PZB2 (SEQ ID NO: X)or pGWOl lb vector) and AAV-sgRNA, both packaged in AAV-DJ. FIG. 46 illustrates dual-AAV delivery of a personalized library (AAV-PCAVac, i.e. AAV-p-MAEGI) into fully un-modified parental E0771 cells can mediate anti-tumor activity in vivo in C57BL/6 mice. Top panel: schematic of dual-AAV delivery of personalized library (AAV-PCAVac, i.e. AAV-p-MAEGI) into fully un-modified parental E0771 cells. Bottom panel: tumor growth curves showing Vector or MAEGI mediated anti-tumor activity in vivo on C57BL/6 mice. **, p < 0.01, ***, p < 0.001 by two-way ANOVA. FIG. 47 illustrates tumor growth curves showing dual AAV delivery of an APCM library into fully un-modified parental E0771 cells mediates anti-tumor activity in vivo in C57BL/6 mice. pGWOl lb+5 APCM group (APCM treated mice) vs pGWOl lb+pGW05 group (vector treated mice), two-way ANOVA p = 0.003. FIG. 48 illustrates AAV infection efficiency across serotypes assessed by intratumoral delivery of GFP-expressing AAVs and flow cytometry analysis. Percentage of GFP+ cells within tumors from mice 4 days after intratumoral injection of PBS (n = 3) or AAV-GFP (n = 12), grouped by CD45+ and CD45 cells. The background GFP fluorescence was set as the maximum % GFP positivity in PBS samples, denoted by a dashed line. Fractions above AAV conditions denote the number of samples with % GFP positivity above background in the indicated cell population.

DETAILED DESCRIPTION Definitions Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the invention pertains. Although any methods and materials similar or equivalent to those described herein can be used in the practice for testing of the present invention, the preferred materials and methods are described herein. In describing and claiming the present invention, the following terminology will be used. It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to be limiting. The articles “a” and “an” are used herein to refer to one or to more than one (i.e., to at least one) of the grammatical object of the article. By way of example, “an element” means one element or more than one element. “About” as used herein when referring to a measurable value such as an amount, a temporal duration, and the like, is meant to encompass variations of ±20% or ±10%, more preferably ±5%, even more preferably ±1%, and still more preferably ±0.1% from the As used herein, the term “autologous” is meant to refer to any material derived from the same individual to which it is later to be re-introduced into the individual. “Allogeneic” refers to any material derived from a different animal of the same species. As used herein, the term “bp” refers to base pair. The term “complementary” refers to the degree of anti-parallel alignment between two nucleic acid strands. Complete complementarity requires that each nucleotide be across from its opposite. No complementarity requires that each nucleotide is not across from its opposite. The degree of complementarity determines the stability of the sequences to be together or anneal/hybridize. Furthermore various DNA repair functions as well as regulatory functions are based on base pair complementarity. The term “CRISPR/Cas” or “clustered regularly interspaced short palindromic repeats” or “CRISPR” refers to DNA loci containing short repetitions of base sequences followed by short segments of spacer DNA from previous exposures to a virus or plasmid. Bacteria and archaea have evolved adaptive immune defenses termed CRISPR/CRISPR-associated (Cas) systems that use short RNA to direct degradation of foreign nucleic acids. In bacteria, the CRISPR system provides acquired immunity against invading foreign DNA via RNA-guided DNA cleavage The “CRISPR/Cas9” system or “CRISPR/Cas9-mediated gene editing” refers to a type II CRISPR/Cas system that has been modified for genome editing/engineering. It is typically comprised of a “guide” RNA (gRNA) and a non-specific CRISPR-associated endonuclease (Cas9). “Guide RNA (gRNA)” is used interchangeably herein with “short guide RNA (sgRNA)” or “single guide RNA (sgRNA). The sgRNA is a short synthetic RNA composed of a “scaffold” sequence necessary for Cas9-binding and a user-defined ~20 nucleotide “spacer” or “targeting” sequence which defines the genomic target to be modified. The genomic target of Cas9 can be changed by changing the targeting sequence present in the sgRNA. “CRISPRa” system refers to a modification of the CRISPR-Cas9 system that functions to activate or increase gene expression. In certain embodiments, the CRISPRa system is comprised of a catalytically dead RNA/DNA guided endonuclease, such as dCas9, dCasl2a/dCpfl, dCasl2b/dC2cl, dCasl2c/dC2c3, dCasl2d/dCasY, dCasl2e/dCasX, dCasl3a/dC2c2, dCasl3b, dCasl3c, dead Cascade complex, or others; at least one transcriptional activator; and at least one sgRNA that functions to increase expression of at least one gene of interest. The term “activation” as used herein refers to an increase in gene expression of one or more genes. “dCas9” as used herein refers to a catalytically dead Cas9 protein that lacks endonuclease activity. A “disease” is a state of health of an animal wherein the animal cannot maintain homeostasis, and wherein if the disease is not ameliorated then the animal’s health continues to deteriorate. In contrast, a “disorder” in an animal is a state of health in which the animal is able to maintain homeostasis, but in which the animal’s state of health is less favorable than it would be in the absence of the disorder. Left untreated, a disorder does not necessarily cause a further decrease in the animal’s state of health. The term “downregulation” as used herein refers to the decrease or elimination of gene expression of one or more genes. “Effective amount” or “therapeutically effective amount” are used interchangeably herein, and refer to an amount of a compound, formulation, material, or composition, as described herein effective to achieve a particular biological result or provides a therapeutic or prophylactic benefit. Such results may include, but are not limited to, anti-tumor activity as determined by any means suitable in the art. “Encoding” refers to the inherent property of specific sequences of nucleotides in a polynucleotide, such as a gene, a cDNA, or an mRNA, to serve as templates for synthesis of other polymers and macromolecules in biological processes having either a defined sequence of nucleotides (i.e., rRNA, tRNA and mRNA) or a defined sequence of amino acids and the biological properties resulting therefrom. Thus, a gene encodes a protein if transcription and translation of mRNA corresponding to that gene produces the protein in a cell or other biological system. Both the coding strand, the nucleotide sequence of which is identical to the mRNA sequence and is usually provided in sequence listings, and the non-coding strand, used as the template for transcription of a gene or cDNA, can be referred to as encoding the protein or other product of that gene or cDNA. As used herein “endogenous” refers to any material from or produced inside an organism, cell, tissue or system. As used herein, the term “exogenous” refers to any material introduced from or produced outside an organism, cell, tissue or system. The term “expression” as used herein is defined as the transcription and/or translation of a particular nucleotide sequence driven by its promoter. “Expression vector” refers to a vector comprising a recombinant polynucleotide comprising expression control sequences operatively linked to a nucleotide sequence to be expressed. An expression vector comprises sufficient cis-acting elements for expression; other elements for expression can be supplied by the host cell or in an in vitro expression system. Expression vectors include all those known in the art, such as cosmids, plasmids (e.g., naked or contained in liposomes) and viruses (e.g., Sendai viruses, lentiviruses, retroviruses, adenoviruses, and adeno-associated viruses) that incorporate the recombinant polynucleotide. “Homologous” as used herein, refers to the subunit sequence identity between two polymeric molecules, e.g, between two nucleic acid molecules, such as, two DNA molecules or two RNA molecules, or between two polypeptide molecules. When a subunit position in both of the two molecules is occupied by the same monomeric subunit; e.g., if a position in each of two DNA molecules is occupied by adenine, then they are homologous at that position. The homology between two sequences is a direct function of the number of matching or homologous positions; e.g, if half (e.g., five positions in a polymer ten subunits in length) of the positions in two sequences are homologous, the two sequences are 50% homologous; if 90% of the positions (e.g. , 9 of 10), are matched or homologous, the two sequences are 90% homologous. “Identity” as used herein refers to the subunit sequence identity between two polymeric molecules particularly between two amino acid molecules, such as, between two polypeptide molecules. When two amino acid sequences have the same residues at the same positions; e.g., if a position in each of two polypeptide molecules is occupied by an Arginine, then they are identical at that position. The identity or extent to which two amino acid sequences have the same residues at the same positions in an alignment is often expressed as a percentage. The identity between two amino acid sequences i a direct function of the number of matching or identical positions; e.g., if half (e.g., five positions in a polymer ten amino acids in length) of the positions in two sequences are identical, the two sequences are 50% identical; if 90% of the positions (e.g, 9 of 10), are matched or identical, the two amino acids sequences are 90% identical. As used herein, an “instructional material” includes a publication, a recording, a diagram, or any other medium of expression which can be used to communicate the usefulness of the compositions and methods of the invention. The instructional material of the kit of the invention may, for example, be affixed to a container which contains the nucleic acid, peptide, and/or composition of the invention or be shipped together with a container which contains the nucleic acid, peptide, and/or composition. Alternatively, the instructional material may be shipped separately from the container with the intention that the instructional material and the compound be used cooperatively by the recipient. “Isolated” means altered or removed from the natural state. For example, a nucleic acid or a peptide naturally present in a living animal is not “isolated,” but the same nucleic acid or peptide partially or completely separated from the coexisting materials of its natural state is “isolated.” An isolated nucleic acid or protein can exist in substantially purified form, or can exist in a non-native environment such as, for example, a host cell. The term “knockdown” as used herein refers to a decrease in gene expression of one or more genes. The term “knockout” as used herein refers to the ablation of gene expression of one or more genes. A “lentivirus” as used herein refers to a genus of the Retroviridae family. Lentiviruses are unique among the retroviruses in being able to infect non-dividing cells; they can deliver a significant amount of genetic information into the DNA of the host cell, so they are one of the most efficient vectors for gene delivery. HIV, SIV, and FIV are all examples of lentiviruses. Vectors derived from lentiviruses offer the means to achieve significant levels of gene transfer in vivo. By the term “modified” as used herein, is meant a changed state or structure of a molecule or cell of the invention. Molecules may be modified in many ways, including chemically, structurally, and functionally. Cells may be modified through the introduction of nucleic acids. By the term “modulating,” as used herein, is meant mediating a detectable increase or decrease in the level of a response in a subject compared with the level of a response in the subject in the absence of a treatment or compound, and/or compared with the level of a response in an otherwise identical but untreated subject. The term encompasses perturbing and/or affecting a native signal or response thereby mediating a beneficial therapeutic response in a subject, preferably, a human. A “mutation” as used herein is a change in a DNA sequence resulting in an alteration from a given reference sequence (which may be, for example, an earlier collected DNA sample from the same subject). The mutation can comprise deletion and/or insertion and/or duplication and/or substitution of at least one deoxyribonucleic acid base such as a purine (adenine and/or thymine) and/or a pyrimidine (guanine and/or cytosine). Mutations may or may not produce discernible changes in the observable characteristics (phenotype) of an organism (subject). By “nucleic acid” is meant any nucleic acid, whether composed of deoxyribonucleosides or ribonucleosides, and whether composed of phosphodiester linkages or modified linkages such as phosphotriester, phosphoramidate, siloxane, carbonate, carboxymethylester, acetamidate, carbamate, thioether, bridged phosphoramidate, bridged methylene phosphonate, phosphorothioate, methylphosphonate, phosphorodithioate, bridged phosphorothioate or sulfone linkages, and combinations of such linkages. The term nucleic acid also specifically includes nucleic acids composed of bases other than the five biologically occurring bases (adenine, guanine, thymine, cytosine and uracil). In the context of the present invention, the following abbreviations for the commonly occurring nucleic acid bases are used. “A” refers to adenosine, “C” refers to cytosine, “G” refers to guanosine, “T” refers to thymidine, and “U” refers to uridine. Unless otherwise specified, a “nucleotide sequence encoding an amino acid sequence” includes all nucleotide sequences that are degenerate versions of each other and that encode the same amino acid sequence. The phrase nucleotide sequence that encodes a protein or an RNA may also include introns to the extent that the nucleotide sequence encoding the protein may in some version contain an intron(s). The term “oligonucleotide” typically refers to short polynucleotides, generally no greater than about 60 nucleotides. It will be understood that when a nucleotide sequence is represented by a DNA sequence (i.e., A, T, G, C), this also includes an RNA sequence (i.e., A, U, G, C) in which “U” replaces “T”. As used herein, the terms “peptide,” “polypeptide,” and “protein” are used interchangeably, and refer to a compound comprised of amino acid residues covalently linked by peptide bonds. A protein or peptide must contain at least two amino acids, and no limitation is placed on the maximum number of amino acids that can comprise a protein’s or peptide’s sequence. Polypeptides include any peptide or protein comprising two or more amino acids joined to each other by peptide bonds As used herein, the term refers to both short chains, which also commonly are referred to in the art as peptides, oligopeptides and oligomers, for example, and to longer chains, which generally are referred to in the art as proteins, of which there are many types. “Polypeptides” include, for example, biologically active fragments, substantially homologous polypeptides, oligopeptides, homodimers, heterodimers, variants of polypeptides, modified polypeptides, derivatives, analogs, fusion proteins, among others. The polypeptides include natural peptides, recombinant peptides, synthetic peptides, or a combination thereof. “Parenteral” administration of an immunogenic composition includes, e.g., subcutaneous (s.c.), intravenous (i.v.), intramuscular (i.m.), or intrasternal injection, or infusion techniques. As used herein, the terms “peptide,” “polypeptide,” and “protein” are used interchangeably, and refer to a compound comprised of amino acid residues covalently linked by peptide bonds. A protein or peptide must contain at least two amino acids, and no limitation is placed on the maximum number of amino acids that can comprise a protein’s or peptide’s sequence. Polypeptides include any peptide or protein comprising two or more amino acids joined to each other by peptide bonds As used herein, the term refers to both short chains, which also commonly are referred to in the art as peptides, oligopeptides and oligomers, for example, and to longer chains, which generally are referred to in the art as proteins, of which there are many types. “Polypeptides” include, for example, biologically active fragments, substantially homologous polypeptides, oligopeptides, homodimers, heterodimers, variants of polypeptides, modified polypeptides, derivatives, analogs, fusion proteins, among others. The polypeptides include natural peptides, recombinant peptides, synthetic peptides, or a combination thereof. The term “polynucleotide” as used herein is defined as a chain of nucleotides. Furthermore, nucleic acids are polymers of nucleotides. Thus, nucleic acids and polynucleotides as used herein are interchangeable. One skilled in the art has the general knowledge that nucleic acids are polynucleotides, which can be hydrolyzed into the monomeric “nucleotides.” The monomeric nucleotides can be hydrolyzed into nucleosides. As used herein polynucleotides include, but are not limited to, all nucleic acid sequences which are obtained by any means available in the art, including, without limitation, recombinant means, i.e., the cloning of nucleic acid sequences from a recombinant library or a cell genome, using ordinary cloning technology and PCR™, and the like, and by synthetic means. Conventional notation is used herein to describe polynucleotide sequences: the left-hand end of a single-stranded polynucleotide sequence is the 5’- end; the left-hand direction of a double-stranded polynucleotide sequence is referred to as the 5’-direction. A “sample” or “biological sample” as used herein means a biological material from a subject, including but is not limited to organ, tissue, exosome, blood, plasma, saliva, urine and other body fluid. A sample can be any source of material obtained from a subj ect. The term “subject” is intended to include living organisms in which an immune response can be elicited (e.g., mammals). A “subject” or “patient,” as used therein, may be a human or non-human mammal Non-human mammals include, for example, livestock and pets, such as ovine, bovine, porcine, canine, feline and murine mammals. Preferably, the subject is human. As used herein, a “substantially purified” cell is a cell that is essentially free of other cell types. A substantially purified cell also refers to a cell which has been separated from other cell types with which it is normally associated in its naturally occurring state. In some instances, a population of substantially purified cells refers to a homogenous population of cells. In other instances, this term refers simply to cell that have been separated from the cells with which they are naturally associated in their natural state. In some embodiments, the cells are cultured in vitro. In other embodiments, the cells are not cultured in vitro. A “target site” or “target sequence” refers to a genomic nucleic acid sequence that defines a portion of a nucleic acid to which a binding molecule may specifically bind under conditions sufficient for binding to occur. The term “therapeutic” as used herein means a treatment and/or prophylaxis. A therapeutic effect is obtained by suppression, remission, or eradication of a disease state. The term “transfected” or “transformed” or “transduced” as used herein refers to a process by which exogenous nucleic acid is transferred or introduced into the host cell. A “transfected” or “transformed” or “transduced” cell is one which has been transfected, transformed or transduced with exogenous nucleic acid. The cell includes the primary subject cell and its progeny. To “treat” a disease as the term is used herein, means to reduce the frequency or severity of at least one sign or symptom of a disease or disorder experienced by a subject. As used herein, “vaccinating” means administering a substance to a subject that induces an immune response against a disease. A “vector” is a composition of matter which comprises an isolated nucleic acid and which can be used to deliver the isolated nucleic acid to the interior of a cell. Numerous vectors are known in the art including, but not limited to, linear polynucleotides, polynucleotides associated with ionic or amphiphilic compounds, plasmids, and viruses. Thus, the term “vector” includes an autonomously replicating plasmid or a virus. The term should also be construed to include non-plasmid and non- viral compounds which facilitate transfer of nucleic acid into cells, such as, for example, polylysine compounds, liposomes, and the like. Examples of viral vectors include, but are not limited to, Sendai viral vectors, adenoviral vectors, adeno-associated virus vectors, retroviral vectors, lentiviral vectors, and the like. Ranges: throughout this disclosure, various aspects of the invention can be presented in a range format. It should be understood that the description in range format is merely for convenience and brevity and should not be construed as an inflexible limitation on the scope of the invention. Accordingly, the description of a range should be considered to have specifically disclosed all the possible subranges as well as individual numerical values within that range. For example, description of a range such as from 1 to 6 should be considered to have specifically disclosed subranges such as from 1 to 3, from 1 to 4, from 1to 5, from 2 to 4, from 2 to 6, from 3 to 6 etc., as well as individual numbers within that range, for example, 1, 2, 2.7, 3, 4, 5, 5.3, and 6. This applies regardless of the breadth of the range.

Description The present invention includes compositions and methods for treating or preventing cancer. In certain embodiments, the invention includes methods for treating or preventing cancer using a cell-based or an AAV-based composition that utilizes the CRISPR activation (CRISPRa) system to activate endogenous genes. It was discovered herein that direct activation of endogenous genes is an effective means to amplify tumor-associated antigens to enhance anti-tumor immune responses. Highly multiplexed and customizable endogenous neoantigen activation has not yet been demonstrated prior to this disclosure. The present invention demonstrates the feasibility of using CRISPR technologies with RNA-guided precise genetic manipulations. The CRISPR activation (CRISPRa) system, based on dead Cas9 without nuclease activity (dCas9) (Qi et al.{20131) Cell 152, 1173-1183), enables simple and flexible regulation of gene expression with dCas9 - transcriptional activation domain fusion (Gilbert etal. (2013) Cell 154, 442-451), which is further augmented by the recruitment of synergistic activation mediators (SAM) (Konermann, etal. (2015) Nature 517, 583-588; Chavez, et al. (2015) Nat Methods 12, 326-328; Tanenbaum, etal. (2014) Cell 159, 635-646). Herein, the CRISPRa system was harnessed to manipulate endogenous gene expression to magnify anti-tumor immune responses. The approach was developed into multiplexed tumor vaccination strategies. Another aspect of the invention includes compositions and methods of both off- the-shelf and customizable endogenous gene vaccination cancer vaccines. The off-the- shelf versions have fixed components, which can have multiple forms, including single component or multi-component vaccines The customizable versions have variable forms, which are generally multi-component vaccines in which the components are based on mutated genes in a cancer, particularly a patients’ mutated genes. The compositions of these forms of cancer vaccines and their pre-clinical efficacy showed that they can be an effective means of prophylactic and therapeutic agents.

CRISPR activation (CRISPRa) system The CRISPR activation (CRISPRa) system is comprised of a catalytically inactive RNA-guided endonuclease or other endonucleases, such as but not limited to dCas9, dCasl2a/dCpfl, dCasl2b/dC2cl, dCasl2c/dC2c3, dCasl2d/dCasY, dCasl2e/dCasX, dCasl3a/dC2c2, dCasl3b, dCasl3c, dead Cascade complex, or others, The CRISPRa system also comprises at least one transcriptional activator, and at least one sgRNA that functions to increase expression of at least one gene of interest. Like a standard CRISPR- Cas9 system, CRISPRa systems rely on sgRNAs to guide Cas9 to intended targets. However, while a standard CRISPR-Cas9 system creates breaks in DNA through the endonuclease activity of Cas9 and then manipulates DNA repair mechanisms for gene editing, CRISPRa systems are modified and employ transcriptional activators to increase expression of genes of interest. “dCas9” refers to a catalytically dead Cas9 protein that lacks endonuclease activity. This can be accomplished by introducing point mutations in the two catalytic residues (D10A and H840A) of the gene encoding Cas9. In doing so, dCas9 is unable to cleave dsDNA but retains the ability to target and bind DNA. This alone is often enough to attenuate if not outright block transcription of the targeted gene if the gRNA positions dCas9 in a way that prevents transcriptional factors and RNA polymerase from accessing the DNA. However, this ability to bind DNA can also be exploited for activation since dCas9 has modifiable regions, typically the N and C terminus of the protein, that can be used to attach transcriptional activators. Targeting specificity is determined by complementary base-pairing of a small guide RNA (sgRNA) to the genomic loci. sgRNA is a chimeric noncoding RNA that can be subdivided into three regions: a base-pairing sequence, a dCas9-binding hairpin and a terminator. When designing a synthetic sgRNA, only the base-pairing sequence is modified. Secondary variables must also be considered: off-target effects (for which a simple BLAST run of the base-pairing sequence is required), maintenance of the dCas9-binding hairpin structure, and ensuring that no restriction sites are present in the modified sgRNA, as this may pose a problem in downstream cloning steps. Due to the simplicity of sgRNA design, this technology is amenable to genome-wide scaling. dCas9 can be derived, for example, from S. pyogenes , S. aureus, N . meningiditis, S. thermopilus, F. novicida, C.jejuni, B . laterosporus, or from other species. Transcriptional activators are protein domains or whole proteins that can be linked to dCas9 or sgRNAs and assist in the recruitment of important co-factors as well as RNA Polymerase for transcription of the gene(s) targeted by the system. Transcriptional activators have a DNA binding domain and a domain for activation of transcription. The activation domain can recmit general transcription factors or RNA polymerase to the gene sequence. Activation domains can also function by facilitating transcription by stalled RNA polymerases, and in eukaryotes can act to move nucleosomes on the DNA or modify histones to increase gene expression. These activators can be introduced into the system through attachment to dCas9 or to the sgRNA. Transcriptional activators can be either mammalian cellular endogenous proteins that have activator function, activators from other species such as viruses, microbials or plants, their partial or mutant variants, engineered activators, or other forms of activators that can increase gene expression. A list of applicable viral activators include but are not limited to: VP16, VP32, VP64, VP160, HBx, NS proteins, and VMW65. A list of applicable microbial activators include but are not limited to: Lac operons and GALA A list of applicable mammalian cellular transcriptional activators include but are not limited to: CAP, ACTN1, ACTN2, ACTN2, ACTN4, ACTN4, ANKRD1, APEX1, ARID5B, ARL2BP, ASCC1, ASXL1, ATN1, ATXN7L3, ATXN7L3, ATXN7L3, BCL9, BCL9L, BCL10, BCL10, BICRA, BIRC2, BRCA1, BRD7, CALCOCOl, CALCOCOl, CALCOCOl, CALCOCOl, CARM1, CARM1, CARM1, CBFB, CCAR1, CCAR1, CCAR1, CCAR1, CCAR2, CCDC62,

CEBPA, CENPJ, CITED 1, CITED 1, CITED2, CITED2, CITED2, CITED2, CITED2, CITED4, CITED4, CITED4, COPS5, CREBBP, CREBBP, CREBBP, CTBP2, CTNNB1, CTNNB1, CTNNB1, CTNNB1, CTNNB1, DAXX, DAXX, DCAF6, DCC, DDX17, DHX9, DR1, DYRK1B, EDF1, ELF 3, ELOB, ENY2, ENY2, ENY2, EP300, EP300, EP300, FAM129B, FGF2, FHL5, FOXC1, GATA3, GATA3, GATA3, GATA4, GM20517, GMEB1 GMEB2, GPS2, GPS2, GTF2A2, GTF2A2, HAND1, HCFC1, HCFC1, HELZ2, HIF3A, HINFP, HIPK2, HMGA1, HMGA1, HMGA1B, HMGB2, HYAL2, ING4, ISL1, JADE1, JMJD6, JMY, JMY, JUN, JUN, JUNB, JUND, JUP, J P, KAT2A, KAT2B, KAT2B, KAT5, KAT5, KAT6A, KDM1A, KDM5A, KMT2C, KMT2D, LPIN1, LPIN1, LPIN2, LPIN2, LPIN3, MAGED1, MAK, MAML1, MAML1, MAML1, MAML1, MAML2, MAML2, MAML3, MAML3, MAML3, MCIDAS, MED1, MED1, MED1, MED1, MED1, MED1, MED6, MED 12, MED 12, MED 12, MED12L, MED 13, MED 14, MED 16, MED 17, MED 17, MED20, MED21, MED24, MED27, MED31, MEF2A, MMS19, MRTFA, MRTFB, MRTFB, MTA1, MTA1, MTA1, MTA1, MTA2, MTA3, MTDH, MYCBP, MYOCD, MYOD1, MYSM1, MYT1L, NACA, NCOA1, NCOA1, NCOA1, NCOA1, NCOA1, NCOA2, C A2, NCOA2, NCOA2, NCOA2, NCOA2, NCOA3, NCOA3, NCOA3, NCOA3, NCOA3, NCOA6, NCOA6, NCOA7, NEUROD1, NEUROG3, NFE2L1, NKX2-2, NME2, NPAT, NPM1, NR1D1, NR1D2, NR1H2, NR1H3, NR1H3, NR1H4, NR1H5, NR1I2, NR1I3, NR3C1, NRBF2, NRIP1, NRIP1, NRIP1, NRL, NSD3, NUP98, NUPR1, PARK7, PCBD1, PDLIM1, PER2, PHF2, PKN1, PMF1, PMF1, PML, PML, PML, POU2AF1, POU3F1, POU3F2, POU3F2, POU4F1, POU4F2, POU5F1, PPARA, PPARD, PPARD, PPARG, PPARG, PPARG, PPARGC1A, PPARGC1A, PPARGC1A, PPARGC1A, PPARGC1A, PPARGC1A, PPARGC1B, PPARGC1B, PPRC1, PRDM16, PRKCB, PRMT2, PRPF6, PRRX1, PSIP1, PSMC3EP, PSMC3IP, PSMD9, PSMD9, PUS1, RAP2C, RARA, RARA, RARB, RARG, RBM14, RBM14, RBM39, RBPMS, RERE, REX04, RNF20, RRPIB, RUVBL1, RXRB, SCAND1, SERTAD2, SETD3, SFR1, SFR1, SIX3, SLC30A9, SLC30A9, SMARCA2, SMARCA4, SMARCB1, SMARCB1,

SMARCD3, SNW1, SNW1, SOX4, SOX1 1, SOX11, SOX12, SOX17, SP4, SRA1, SRA1, SRA1, SRA1, SRA1, SRA1, SS18, SS18, SS18L1, SS18L2, SUB1, SUB1, SUPT3, SUPT7L, TADA1, TADA1, TADA2A, TADA2B, TADA3, TADA3, TADA3, TAF1, TAF5L, TAF6L, TAF6L, TAF7, TAF7, TAF7L, TAF9, TAF11, TAF11, TAF12, TCF3, TDRD3, TFAP2A, TFAP2A, TFAP2A, TFAP2B, TFAP2B, TFAP2B, TGFB1I1, THRA, THRAP3, THRAP3, THRAP3, THRB, TRIM24, TRIM24, TRIM28, TRIP4, TRIP4, TRRAP, TSG101, UBE2L3, UBE3A, USP16, USP21, USP22, USP22, UTF1, UTF1, VDR, VGLL2, WBP2, WBP2, WBP2NL, WDR77, WNT3A, WWC1, WWOX, WWTR1, WWTR1, YAF2, YAP1, YAP1, ZBTB18, ZCCHC12, ZCCHC12, ZCCHC18, ZMIZ2. Applicable CRISPRa systems demonstrated to be capable of activating transcription in mammalian species include but are not limited to: VP64-p65-Rta (VPR), Synergistic Activation Mediator (SAM), Suntag, p300, and VP160. One example of a transcriptional activator (or transactivator domain) is VP64. VP64 is made up of four copies of VP 16, a viral protein sequence of 16 amino acids that is used for transcriptional activation Embodiments of the invention include various forms of VP64, for example a nucleic acid comprising dCas9 and/or VP64, or plasmids or vectors that encode the dCas9 and/or VP64 genes. One non-limiting example includes pcDNA-dCas9-VP64 (Plasmid #47107, from Addgene). Additional elements can be present in the nucleic acid encoding dCas9 and/or VP64, as in for example lenti vector EFla-NLS-dCas9(N863)-VP64-2A-Blast-WPRE (Plasmid #61425 from Addgene), which additionally encodes a 2A Blast resistance marker. Another non-limiting example includes plasmid pLVhUbC-VP64 dCas9 VP64-T2A-GFP (Plasmid #59791 from Addgene) that co-expresses human optimized S. pyogenes dCas9 fused to two copies of VP64 and GFP. Certain embodiments of the invention utilize the VP64-p65-Rta, or VPR, in which a VP64 transcriptional activator is joined to the C terminus of dCas9. In the dCas9-VPR protein, the transcription factors p65 and Rta are added to the C terminus of dCas9-VP64. Therefore, all three transcription factors are targeted to the same gene. The use of three transcription factors, as opposed to solely VP64, results in increased expression of targeted genes. dCas9-VPR can be used to increase expression of multiple genes within the same cell by putting multiple sgRNAs into the same cell. In certain embodiments, the invention utilizes the Synergistic Activation Mediator (SAM) system. SAM makes use of not only VP64 but also sgRNA 2.0, which contains a sequence to recruit a viral protein fused to even more effectors (p65-hsfl). In one embodiment the SAM complex comprises dCas9-VP64, sgRNA, MS2-p65HSF-l. In one embodiment, the CRISPRa system comprises a nucleic acid encoding dCas9-VP64, a nucleic acid encoding MS2-p65-HSFl, and a genome-scale lentiviral SAM CRISPRa sgRNA library. Administering this type of CRISPRa system to a plurality of cells results in a highly diverse population of cells encompassing the entire sgRNA library The invention should be construed to work with any alternative activator, such as VP16, VP160, p65 D, p300 or any other transcriptional activator. The invention should also be construed to work with any dCas9/CRISPRa system or any other adaptor system known in the art, including but not limited to: 1) RNA Scaffolds, which also utilizes sgRNA 2.0 and recruits 3 viral proteins fused to VP64. 2) Suntag, which sports a protruding chain of 10 peptide epitopes that are recognized by an entourage of antibodies fused to VP64. 3) The epigenetic editor p300, which deposits activating H3K27ac. 4) VP160, which is also known as CRISPR-on and has ten times the VPs of VP 16. 5) VP64-dCas9-BFP-VP64, which makes use of that much neglected N- terminus.

Methods of Treatment A. Cell-Based: The present invention includes methods for treating or preventing cancer in a subject comprising administering to the subject a cell that has been modified by the CRISPR activation (CRISPRa) system to induce expression of endogenous genes. This type of cell-based vaccine/composition can be utilized as a prophylactic treatment, a therapeutic treatment, a personalized, subject-specific treatment, and/or a method of turning ‘cold’ tumor into a ‘hot’ tumor, thus making it more susceptible to immunotherapy. In one aspect, the invention includes a method of preventing cancer in a subject comprising contacting a cell with a composition comprising a CRISPR activation (CRISPRa) system, wherein the CRISPRa system increases expression of a plurality of endogenous genes. A therapeutically effective amount of a composition comprising the cell is administered to the subject, thus preventing cancer in the subject. This method is considered a type of prophylactic cancer treatment, or a method of protecting a subject from developing cancer, or a method of preventing the development of cancer in a subject, or a method of generating an anti-tumor response in a subject. In another aspect, the invention includes a method of treating cancer in a subject in need thereof. The method comprises contacting a cell with a composition comprising a CRISPRa system, wherein the CRISPRa system increases expression of a plurality of endogenous genes, and administering a therapeutically effective amount of a composition comprising the cell to the subject, thus treating the cancer in the subject. Another aspect of the invention includes a method of treating cancer in a subject in need thereof. The method comprises obtaining a first cancer cell from the subject and determining at least one mutated endogenous gene, then designing a CRISPRa system comprising an sgRNA library specific for the mutated endogenous gene. A second cancer cell from the subject is then contacted with a composition comprising the CRISPRa system, wherein the CRISPRa system increases expression of the mutated endogenous gene. A therapeutically effective amount of a composition comprising the cell is administered to the subject, thus treating the cancer in the subject. In certain embodiments, the cell comprises a plurality of mutated endogenous genes, and the activation system comprises an sgRNA library specific for the plurality of mutated endogenous genes, and increases expression of the plurality of mutated endogenous genes. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ D NOs. 1-37. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 51-259. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 260-348. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ D NOs. 349-4,187. En certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ED NOs. 4,188-7,980. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ED NOs. 7,981-1 1,808. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ED NOs. 11,809-23,776. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 23,779-23,885. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 23,886-24,104. With regard to any and all sgRNA libraries disclosed herein, it should be understood by one of ordinary skill in the art that when it is stated that the library comprises at least one sgRNA, it should be construed that the library can comprise one or more sgRNAs, all sgRNAs in the library, and and all integer values and numerical ranges of sgRNAs there between. For example, an sgRNA library comprising a total of 219 sgRNAs (e.g. SEQ ID NOs. 23,886-24,104) can comprise one sgRNA, all 219 sgRNAs, or and any and all integer values between 1 and 219. In other words, the library could include 1, 10, 20, 50, 100, 150, 200, or 219 sgRNAs and any and all values in between.

B. Vector-Based: The invention also includes a vector-based vaccine/composition useful for treating or preventing cancer. The vector comprises the CRISPR activation (CRISPRa) system used to induce expression of endogenous genes and the vector provides a delivery vehicle for administration to a subject. This type of vector-based vaccine/composition can be utilized as a prophylactic treatment, a therapeutic treatment, a personalized, subject- specific treatment, and a method of turning ‘cold’ tumor into a ‘hot’ tumor, thus making it more susceptible to immunotherapy. One aspect of the invention includes a method of treating cancer in a subject in need thereof comprising administering to the subject a therapeutically effective amount of a composition comprising a vector comprising a CRISPRa system, wherein the CRISPRa system increases expression of at least one endogenous gene, thus treating the cancer in the subj ect. The vector can be any vector that can carry the gene, including but not limited to, standard viral vectors, chimeric viral vectors, other viral vectors, bacterial vectors, yeast vectors, DNA vectors, mRNA, protein carriers, nanomaterials, or other delivery vehicles. Applicable standard viral vectors for delivery include the vectors from the following types of viruses: dsDNA viruses (e.g. Adenoviruses, Herpesviruses, Poxviruses), ssDNA viruses (+ strand or "sense") DNA (e.g. Parvoviruses), dsRNA viruses (e.g. Reoviruses), (+)ssRNA viruses (+ strand or sense) RNA (e.g. Picomaviruses, Togaviruses), (-)ssRNA viruses (- strand or antisense) RNA (e.g. Orthomyxoviruses, Rhabdoviruses), ssRNA-RT viruses (+ strand or sense) RNA with DNA intermediate in life-cycle (e.g. Retroviruses), and dsDNA-RT viruses DNA with RNA intermediate in life-cycle (e.g. Hepadnaviruses). In certain embodiments of the invention, the cells are packaged into an AAV vector. Applicable AAV serotypes include, but are not limited to, AAV1, AAV2, AAV3, AAV4, AAV5, AAV6, AAV7, AAV8, AAV9, AAV10, AAV11, AAV 12, artificial variants such as AAVrhlO, AAV.rh32/33, AAV.rh43, AAV.rh64Rl, rAAV2-retro, AAV- DJ, AAV-PHP.B, AAV-PHP.S, AAV-PHP.eB, or other engineered versions of AAV. In one embodiment, the AAV vector is AAV9. In one embodiment, the CRISPRa system is cloned into an AAV vector. In certain embodiments of the invention, the CRISPRa system comprises an sgRNA library, wherein the sgRNA library comprises a plurality of sgRNAs that target endogenous genes in the cell. In certain embodiments, the CRISPRa system comprises a nucleic acid encoding dCas9-VP64, a nucleic acid encoding MS2-p65-HSFl, and a genome-scale lentiviral SAM CRISPRa sgRNA library. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 1-37. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 51-259. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ D NOs. 260-348. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 349- 4,187. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 4,188-7,980. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 7,981-1 1,808. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 11,809-23,776. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 23,779-23,885. In certain embodiments, the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 23,886-24,104. The cell or cells utilized in the invention can be from any source known to one of ordinary skill in the art The cells of the invention may be autologous, allogeneic or xenogeneic with respect to the subject undergoing treatment. In some embodiments, the cell is from a cancer cell line. In some embodiments, the cell is from the subject. In some embodiments, the cell from the subject is a cancer cell. In further embodiments, the cancer cell is from a tumor. In some embodiments, the subject is a mammal. In further embodiments, the subject is a human. The cells or vectors of the present invention may be administered in a manner appropriate to the disease to be treated or prevented. The quantity and frequency of administration will be determined by such factors as the condition of the patient, and the type and severity of the patient’s disease, although appropriate dosages may be determined by clinical trials. Cells or vectors of the invention can be administered in dosages and routes and at times to be determined in appropriate pre-clinical and clinical experimentation and trials. Cell and vector compositions may be administered multiple times at various dosages. Administration of the cells or vectors of the invention may be combined with other methods useful to treat the desired disease or condition as determined by those of skill in the art. In one embodiment, administering the therapeutically effective amount of the composition comprises a one dose, a two dose, a three dose, a four dose, or a multi-dose treatment. The administration of the modified cells or vectors of the invention may be carried out in any convenient manner known to those of skill in the art. In one embodiment, the cells are administered intratumorally. Certain embodiments of the invention further comprise contacting the cell with a substance that induces senescence in the cell prior to administering to the subject. In one embodiment, the substance that induces senescence in the cell is mitomycin. The invention includes compositions and methods for treating cancer Types of cancer that can be treated include, but are not limited to, Acute Lymphoblastic Leukemia (ALL), Acute Myeloid Leukemia (AML), Adrenocortical Carcinoma, AIDS-Related Cancers, Kaposi Sarcoma, AIDS-Related Lymphoma, Primary CNS Lymphoma, Anal Cancer, Appendix Cancer (Gastrointestinal Carcinoid Tumors), Astrocytomas, Atypical Teratoid/Rhabdoid Tumor, Brain Cancer, Basal Cell Carcinoma of the Skin, Bile Duct Cancer, Bladder Cancer, Bone Cancer (includes Ewing Sarcoma and Osteosarcoma and Malignant Fibrous Histiocytoma), Brain Tumors, Breast Cancer, Bronchial Tumors, Burkitt Lymphoma, Non-Hodgkin Lymphoma, Carcinoid Tumors, Carcinoma of Unknown Primary, Cardiac (Heart) Tumors, Embryonal Tumors, Germ Cell Tumor, Primary CNS Lymphoma, Cervical Cancer, Cholangiocarcinoma, Chordoma, Chronic Lymphocytic Leukemia (CLL), Chronic Myelogenous Leukemia (CML), Chronic Myeloproliferative Neoplasms, Colorectal Cancer, Craniopharyngioma, Cutaneous T-Cell Lymphoma (Mycosis Fungoides and Sezary Syndrome), Ductal Carcinoma In Situ (DCIS), Endometrial Cancer, Ependymoma, Esophageal Cancer, Esthesioneuroblastoma, Ewing Sarcoma, Extracranial Germ Cell Tumor, Eye Cancer, Intraocular Melanoma, Fallopian Tube Cancer, Fibrous Histiocytoma of Bone, Osteosarcoma, Gallbladder Cancer, Gastric Cancer, Stomach Cancer, Gastrointestinal Carcinoid Tumor, Gastrointestinal Stromal Tumors (GIST), Central Nervous System Germ Cell Tumors, Extracranial Germ Cell Tumors, Extragonadal Germ Cell Tumors, Ovarian Germ Cell Tumors, Testicular Cancer, Gestational Trophoblastic Disease, Hairy Cell Leukemia, Head and Neck Cancer, Heart Tumors, Hepatocellular (Liver) Cancer, Histiocytosis (Langerhans Cell), Hodgkin Lymphoma, Hypopharyngeal Cancer, Intraocular Melanoma, Islet Cell Tumors, Pancreatic Neuroendocrine Tumors, Kidney Cancer, Renal Cell Cancer, Langerhans Cell Histiocytosis, Laryngeal Cancer, Leukemia, Lip and Oral Cavity Cancer, Liver Cancer, Lung Cancer (Non-Small Cell and Small Cell), Lymphoma, Male Breast Cancer, Malignant Fibrous Histiocytoma of Bone and Osteosarcoma, Melanoma, Intraocular (Eye) Melanoma, Merkel Cell Carcinoma (Skin Cancer), Malignant Mesothelioma, Metastatic Cancer, Metastatic Squamous Neck Cancer with Occult Primary, Midline Tract Carcinoma With NUT Gene Changes, Mouth Cancer, Multiple Endocrine Neoplasia Syndromes, Multiple Myeloma/Plasma Cell Neoplasms, Mycosis Fungoides (Lymphoma), Myelodysplastic Syndromes, Myelodysplastic/ Myeloproliferative Neoplasms, Nasal Cavity and Paranasal Sinus Cancer, Nasopharyngeal Cancer, Neuroblastoma, Non-Small Cell Lung Cancer, Oral Cancer, and Oropharyngeal Cancer, Ovarian Cancer, Pancreatic Cancer, Papillomatosis, Paraganglioma, Paranasal Sinus and Nasal Cavity Cancer, Parathyroid Cancer, Penile Cancer, Pharyngeal Cancer, Pheochromocytoma, Pituitary Tumor, Plasma Cell Neoplasm/Multiple Myeloma, Pleuropulmonary Blastoma, Primary Central Nervous System (CNS) Lymphoma, Primary Peritoneal Cancer, Prostate Cancer, Rectal Cancer Recurrent Cancer, Retinoblastoma, Rhabdomyosarcoma, Salivary Gland Cancer, Sarcoma, Vascular Tumors, Uterine Sarcoma, Sezary Syndrome (Lymphoma), Small Cell Lung Cancer, Small Intestine Cancer, Soft Tissue Sarcoma, Squamous Cell Carcinoma, Stomach (Gastric) Cancer, Throat Cancer, Thymoma, Thymic Carcinoma, Thyroid Cancer, Transitional Cell Cancer of the Renal Pelvis and Ureter, Carcinoma of Unknown Primary, Ureter and Renal Pelvis, Transitional Cell Cancer, Urethral Cancer, Uterine Cancer, Vaginal Cancer, Vulvar Cancer, Wilms Tumor, and combinations thereof. Certain embodiments of the invention further comprise administering an additional treatment to the subject. Certain embodiments of the invention include treating the subject with a combination of a composition of the present invention and an additional treatment. Examples of additional treatments include but are not limited to, chemotherapy, radiation, surgery, medication, immune checkpoint inhibitors, immune checkpoint blockade (ICB) antibodies, immune checkpoint inhibitors that block CTLA-4 orPDl, anti-CTLA4 monoclonal antibody, anti-PDl monoclonal antibody, anti-PD-Ll monoclonal antibody, adoptive ce l transfer, human recombinant cytokines, cancer vaccines, immunotherapy, targeted therapy, hormone therapy, stem cell transplant, precision medicine, non-specific immunotherapy ( .g cytokines and chemokines, such as

EL-2, IFNa, IFNb, IFNg), oncolytic virus therapy, T-cell therapy (e g. adoptive transfer of TILs, TCR-T, CAR-T), cancer vaccines (e.g. conventional DC vaccine), Ipilimumab (Yervoy), Nivolumab (Opdivo), Pembrolizumab (Keytruda), Atezolizumab (Tecentriq), Avelumab (Bavencio), Durvalumab (Imfinzi), Anti-LAG-3, anti-TIMl, Anti-TIM3, Anti- CSF-R, IDO inhibitor, OX-40 agonist, GITR agonist, CD80 agonist, CD86 agonist, ICOS agonist, ICOSLG agonist, CD276 agonist, VTCN1 agonist, TNFSF14 agonist, TNFSF9 agonist, TNFSF4 agonist, CD70 agonist, CD40 agonist, LGALS9 agonist, CD80 inhibitor, CD86 inhibitor, ICOS inhibitor, ICOSLG inhibitor, CD276 inhibitor, VTCN1 inhibitor, TNFSF14 inhibitor, TNFSF9 inhibitor, TNFSF4 inhibitor, CD70 inhibitor, CD40 inhibitor, LGALS9 inhibitor, TLR9 agonist, CD20 antibody, CD80 antibody, TIGIT antibody, B7-H1 antibody, B7-H2 antibody, B7-H3 antibody, B7-H4 antibody, CD28 antibody, CD47 antibody, anti-BTLA, anti-Galetin9, anti-IL15R, anti-GD2. In some embodiments the monoclonal antibody is fully human, humanized or chimeric. In certain embodiments, administering a composition of the present invention alters the tumor microenvironment. In certain embodiments, administering the composition augments host immune responses against established tumors. Certain aspects of the invention include determining subject-specific, or individualized mutations in a gene or genes of the subject. This determination can be carried out by any means known to one of ordinary skill in the art. For example, whole- genome-sequencing (WGS) and/or molecular inversion probe sequencing (MIPS) (Chow et al. 2018) provide other non-limiting ways of determining the subject-specific mutated endogenous gene or genes. In one embodiment, determining the subject-specific mutated endogenous gene or genes comprises whole-exome sequencing of a cancer cell and whole-exome sequencing of a non-cancer cell from the subject. The sequencing data from the cancer cell and the non-cancer cell are compared, determining at least one mutation. By this, the subject-specific mutated endogenous gene or genes are determined. Any type of mutation can be determined, including but not limited to single nucleotide polymorphisms (SNP), insertions, deletions, frameshifts, and rearrangements. Certain aspects of the invention include activating or increasing expression of a subset of endogenous genes, for example, but not limited to those enhancing immune cell functions such as antigen-presentation. In certain embodiments sgRNAs are designed against the aforementioned endogenous genes or a subset of these genes. In certain embodiments the sgRNAs are selected from a minipool of 6 selected human antigen presentation genes, with multiple sgRNAs per gene. In one embodiment the sgRNAs are selected from the group consisting of SEQ D NOs: 1-37. In one embodiment the sgRNAs are selected from the group consisting of SEQ ID NOs: 51-259. In certain embodiments the sgRNAs are selected from a minipool of 29 selected immune function genes related to antigen presentation. In certain embodiments the sgRNAs are selected from the group consisting of SEQ ID NOs: 260-348. In certain embodiments the sgRNAs are selected from the group consisting of 23,779-23,885. In certain embodiments the sgRNAs are selected from the group consisting of 23,886-24,104. In certain embodiments, the sgRNAs are designed to target endogeneous mutant genes present in a variety of cancers (e.g. melanoma, glioma, hepatoma, colon cancer, and pancreatic cancer). In certain embodiments the sgRNAs are selected from the group consisting of SEQ ID NOs. 11,809 - 23,776. These “off the shelf’ sgRNA pools and minipools can be administered to a subject in conjunction with compositions and methods of the present invention, without the need for sequencing individualized tumors. Alternatively, personalized sgRNA minipools can be designed wherein a subject’s tumor is sequenced, and sgRNAs are designed specific to that subject’s cancer type/mutations. Examples of personalized sgRNA minipools described herein include: E0771 (TNBC) exome based PCAVac sgRNAs (SEQ ID NOs: 349-4,187), GL261 (GBM) exome based PCAVac sgRNAs (SEQ ID NOs: 7,981-1 1,808), and Lewis (Lung) exome based PCAVac sgRNAs (SEQ ID NOs: 4,188-7,980).

Table 1 : sgRNAs selected from a minipool of human antigen presentation genes Gene Transcript TSS Guide Top/ SEQ Name ID Distance_ Sequence_ Bottom ID NO: CD70 NM_001252 145 GGCGGGGAGGGGTTGGGGGC b 1 CD70 NM_001252 166 ATGTCTCCTGCCTGAAGGTC b 2 CD70 NM_001252 103 CAGGATGCAGGCAGTGGCCC t 3 CD70 NM 001252 82 CAACTGCCTCCACCCACTTT b 4 CD70 NM_001252 2 ATGTCCGGCCGGTCGAGGGG t 5 CD70 NM_001252 55 TCAGACTGGCAGCGGTTGGA b 6 CD70 NM_001252 124 GGCAACTCTGAGGCTCACCC b 7 CD70 NM_001252 23 GGGACTTGAGCAATTGGCGA t 8 CD80 NM_005191 153 TTCTCCTCCCCTAGGCCGCC b 9 CD80 NM 005191 100 GCCTCCCTCACCACCGTGCA t 10 CD80 NM 005191 6 1 GCTTTTGTAGAGGCTGTGGC t 1 1 CD80 NM_005191 7 CAAACACCCTGTCCAACTCC b 12 CD80 NM 005191 38 TAGAAGAAGACGGCAGCAGA b 13 CD80 NM 005191 174 AATGGTGCCCGAGAAGAGTG t 14 CD80 NM_005191 132 CATGAAACACCACGAGCACC t 15 CD86 NM_00 1206924 7 TTAAAGAAAGTTAGCTGGGT t 16 CD86 NM_00 1206924 87 GAGTTTAAACTGCAAGGAAA t 17 CD86 NM_00 1206924 4 1 TCAAAATCTGTAGAGAAAAG t 18 CD86 NM_00 1206924 64 TTAAATTTCTTCCTCAAGTG t 19 CD86 ΝΜ 1206924 162 GCTCATCTTAACGTCATGTC t 20 CD86 NM 006889 134 CTCCCTTTGGGGGTTTCCCA t 2 1 CD86 NM 006889 8 AGAGAAACAACACCACAGCC b 22 CD86 NM_006889 157 CTTTGTCATGTTTGTGGATG t 23 CD86 NM_006889 29 CCAAGCAAGAGCACTGTCCC t 24 CD86 NM_006889 50 TCCAAATAACTTCTGCCGGC b 25 CD86 NM_006889 85 TTTGTAGTCATTCTCATCAG t 26 CD86 NM_006889 112 GCTTTACACTCATGCTCCGA t 27 IFNA4 NM_021068 0 GAAGACTTTGCTCTGTGCAT t 28 IFNA4 NM_021068 152 29 IFNA4 NM_021068 5 1 CAACTAGGGAATTTAGAAAA b 30 IFNB1 NM_002176 64 TGAAAGGGAGAAGTGAAAGT b 3 1 IFNB1 NM_002176 33 ATGGTCCTCTCTCTATTCAG t 32 IFNG NM_000619 155 AGAGTTTCCTTTAGACTCCT t 33 IFNG NM_000619 8 TAAATACCAGCAGCCAGAGG b 34 IFNG NM_000619 33 ATCCTCAGGAGACTTCAATT b 35 IFNG NM_000619 121 AACTAAGGTTTTGTGGCATT t 36 IFNG NM 000619 75 AAGATGAGATGGTGACAGAT t 37

Additional sequences for cloning synthesized libraries into:

Subpool amplification (SPA) primers: SPA 1F CGGGTTCCGTGGAAAGG (SEQ ID NO: 38) SPA_lRms2 ttctattctaagcCTCATGTTggcc (SEQ ID NO: 39) SPA 2F GTTT ATCGGGC GGA AAGG (SEQ ID NO: 40) SPA_2Rms2 GGTACAGTAAGTCTCATGTTggcc (SEQ ID NO: 41) SPA_3F aCCGATGTTGACGGAAAGG (SEQ ID NO: 42) SPA_3Rms2 GCTATTACGAGCTCATGTTggcc (SEQ ID NO: 43) SPA 4F GAGGT CTTT CAT GCGGAAAGG (SEQ ID NO: 44) SPA 4Rms2 TATGTTGTGCTCATGTTggcc (SEQ ID NO: 45)

AF taacttgaaagtatttcgatttcttggctttatatatcttGTGGAAAGGACGAAACACCg (SEQ ID NO: 46) A actttttcaagttgataacggactagccttattttaacttgctaTTTCtagctctaaaac (SEQ ID NO: 47) ARms2 attttaacttgctaggccCTGCAGACATGGGTGATCCTCATGTTggcctagctctaaaac (SEQ ID NO: 48)

Table 2 : sgRNAs selected from a minipool of immune function genes SE ID SE ID Gene sgRNA Sequence_ CD70 CAGTCTGAAGATCCTAAAGT 51 CD80 TACTTGTCAGTGCCAGGAGT 156 CD70 TCTGAAGATCCTAAAGTGGG 52 CD80 TTTTGTAGAGGCTGTGGCTG 157 CD70 AATCCCTAATAAATGTGCAG 53 CD80 CAGATGCCCCTCACTCTTCT 158 CD70 TACTTGCTTCAACCTGTCAG 54 CD80 CGAGAAGAGTGAGGGGCATC 159 CD70 GGACTTGAGCAATTGGCGAG 55 CD80 GCCTCCCTCACCACCGTGCA 160 CD70 CCACTTTAGGATCTTCAGAC 56 CD80 GGCCTAGGGGAGGAGAAGAA 161 CD70 GAAGATCCTAAAGTGGGTGG 57 CD80 GCTTTTGTAGAGGCTGTGGC 162 CD70 TCCCCGCCCGACCTTCAGGC 58 CD80 GGGAGGCCAGCTTCATGGGC 163 CD70 TCAGACTGGCAGCGGTTGGA 59 CD80 TGGGCTGGCTGTTTCTGTGC 164 CD70 ATCTTCAGACTGGCAGCGGT 60 CD80 AGTTGCTTTTGTAGAGGCTG 165 CD70 TGGGCCCCAGAAGAATGAGG 61 CD80 TTCTCCTCCCCTAGGCCGCC 166 CD70 GCAACTCTGAGGCTCACCCG 62 CD80 AGATGCCCCTCACTCTTCTC 167 CD70 CTCTCCACCTCATTCTTCTG 63 CD80 GTGATGGGAGGCCAGCTTCA 168 CD70 CGGGGCCACTGCCTGCATCC 64 CD86 CAGTTTAAACTCATTGACGT 169 CD70 TCTCCTGCCTGAAGGTCGGG 65 CD86 ACAGATTTTGACCACACTTG 170 CD70 GGCCGGACATCCCCAGAGAG 66 CD70 GGGACTTGAGCAATTGGCGA 67 CD86 TCAAAATCTGTAGAGAAAAG 172 CD70 ATTGAATGTCTCCTGCCTGA 68 CD86 TTAAATTTCTTCCTCAAGTG 173 CD70 CCCTAATAAATGTGCAGTGG 69 CD86 GCTCATCTTAACGTCATGTC 174 CD70 GAATGGGCCCCAGAAGAATG 70 CD86 ATTCTATTTTGTTGCTGCGG 175 CD70 AGGGACTTGAGCAATTGGCG 71 CD86 TTTTTGAGGGAATTTCAAGA 176 CD70 GGGCAGGCTGGTCCCCTGAC 72 CD86 TTTATTCTATTTTGTTGCTG 177 CD70 GGGGATGTCCGGCCGGTCGA 73 CD86 TTTTGAGGGAATTTCAAGAG 178 CD70 TTCAGACTGGCAGCGGTTGG 74 CD86 AGCAACAAAATAGAATAAAG 179 CD70 CCAGTCTGAAGATCCTAAAG 75 CD86 TGAGTTTAAACTGCAAGGAA 180 CD70 CCGGCCGGACATCCCCAGAG 76 CD86 TTCTCTTAAAGAAAGTTAGC 181 CD70 AGGCAACTCTGAGGCTCACC 77 CD86 AGAGGGGAGATTTTTTATTC 182 CD70 CCTCTCTGGGGATGTCCGGC 78 CD86 TCTCTTAAAGAAAGTTAGCT 183 CD70 CTCAAGTCCCTCCCCTCGAC 79 CD86 GTCAATGAGTTTAAACTGCA 184 CD70 TCCTGCCTGAAGGTCGGGCG 80 CD86 GAGTTTAAACTGCAAGGAAA 185 CD70 AGTCCCTCCCCTCGACCGGC 81 CD86 TTATTTTCTAGGTTTTTTGA 186 CD70 CGGCCGGACATCCCCAGAGA 82 CD86 TTAAAGAAAGTTAGCTGGGT 187 CD70 GGGATGTCCGGCCGGTCGAG 83 CD86 TTTATTTTCTAGGTTTTTTG 188 CD70 CCCAGAAGAATGAGGTGGAG 84 CD86 TTCTAATTATTTTATTTTCT 189 CD70 GACCAGCCTGCCCCTCTCTG 85 IFNA4 AGAGATAGAAAGTACAACTA 190 CD70 AGTGGGTGGAGGCAGTTGCC 86 IFNA4 CAGAGATAGAAAGTACAACT 191 CD70 ATGTCTCCTGCCTGAAGGTC 87 IFNA4 TATTTTTCACCTGCACTCAA 192 CD70 TCTACTTGCTTCAACCTGTC 88 IFNA4 CCATAAAAGCCTTTGAGTGC 193 CD70 CAGAAGAATGAGGTGGAGAG 89 IFNA4 CAACTAGGGAATTTAGAAAA 194 CD70 TGCCCCTCTCTGGGGATGTC 90 IFNA4 CCTGCACTCAAAGGCTTTTA 195 CD70 CTACTTGCTTCAACCTGTCA 91 IFNA4 GAAGACTTTGCTCTGTGCAT 196 CD70 CCCCTCCCCGCCCGACCTTC 92 IFNA4 TTTGAGTGCAGGTGAAAAAT 197 CD70 AATGTCTCCTGCCTGAAGGT 93 IFNA4 AGTTTTTATCTGTGAAGTAG 198 CD70 GGAGGCAGTTGCCAGGATGC 94 IFNA4 AAATTTTAATAACACAGATT 199 CD70 AGGATGCAGGCAGTGGCCCC 95 IFNB1 ATATAAATAGGCCATACCCA 200 CD70 TAGGATCTTCAGACTGGCAG 96 IFNB1 AAATTCCTCTGAATAGAGAG 201 CD70 CTCCTGCCTGAAGGTCGGGC 97 IFNB1 TAGGCCATACCCATGGAGAA 202 CD70 CCCTCTCCACCTCATTCTTC 98 IFNB1 CAAGACTT GGGAGAAAGCAA 203 CD70 CCAGAAGAATGAGGTGGAGA 99 IFNB1 AAAAAGATTTACAAACTGTG 204 CD70 TGTCCGGCCGGTCGAGGGGA 100 IFNB1 GTTAGAATGTCCTTTCTCCA 205 CD70 CCTCTCCACCTCATTCTTCT 101 IFNB1 ATGGTCCTCTCTCTATTCAG 206 CD70 AGTTGCCAGGATGCAGGCAG 102 IFNB1 TATTATATATATCATAAGAT 207 CD70 TGGGGATGTCCGGCCGGTCG 103 IFNB1 TACTAAAATGTAAATGACAT 208 CD70 GGGACCAGCCTGCCCCTCTC 104 IFNB1 ATGACATAGGAAAACTGAAA 209 CD70 AGGTTTGTTGAATAAATGAA 105 IFNB1 CAAATTGTAAAACAAGACTT 210 CD70 GGACATCCCCAGAGAGGGGC 106 IFNB1 TTAGAATGTCCTTTCTCCAT 2 11 CD70 GTTGGGGGCAGGCAACTCTG 107 IFNB1 GAGGACCATCTCATATAAAT 212 CD70 GGTTTGTTGAATAAATGAAT 108 IFNB1 TATGGCCTATTTATATGAGA 213 CD70 ATGTCCGGCCGGTCGAGGGG 109 IFNB1 AATGACATAGGAAAACTGAA 214 CD70 GGCAACTCTGAGGCTCACCC 110 IFNB1 ATGTCCTTTCTCCATGGGTA 215 CD70 CCTGAAGGTCGGGCGGGGAG 111 IFNB1 TGAAAGGGAGAAGTGAAAGT 216 CD70 GCCTGAAGGTCGGGCGGGGA 112 IFNB1 TTTGAGGTTCTTGAATTCTC 217 CD70 AGGGGAGGGACTTGAGCAAT 113 IFNB1 CTGAAAGGGAGAAGTGAAAG 218 CD70 ATCCCCAGAGAGGGGCAGGC 114 IFNB1 CTGTATCTTTTAGTGTTTTG 219 CD70 TGCCTGAAGGTCGGGCGGGG 115 IFNB1 ATCTTATGATATATATAATA 220 CD70 GGTCGGGCGGGGAGGGGTTG 116 IFNB1 TATCTTATGATATATATAAT 221 CD70 CAACTGCCTCCACCCACTTT 117 IFNB1 GCAAATTGTAAAACAAGACT 222 CD70 GTCGGGCGGGGAGGGGTTGG 118 IFNG CATTTTACCAGGGCGAAGTG 223 CD70 CAGGATGCAGGCAGTGGCCC 119 IFNG TGGGTCTGTCTCATCGTCAA 224 CD70 GGCGGGGAGGGGTTGGGGGC 120 IFNG TTCAAAGAATCCCACCAGAA 225 CD70 AATGAGGTGGAGAGGGGAAT 121 IFNG TACCTAATTGAAGTCTCCTG 226 CD70 GGACCAGCCTGCCCCTCTCT 122 IFNG AACATTTTACCAGGGCGAAG 227 CD70 AGGTCGGGCGGGGAGGGGTT 123 IFNG TGTGAAAATACGTAATCCTC 228 CD70 AAGGTCGGGCGGGGAGGGGT 124 IFNG GAATCCCACCAGAATGGCAC 229 CD80 GTTTGTTAGTCCATGCACGG 125 IFNG ACATTTTACCAGGGCGAAGT 230 CD80 TCAGTGCCAGGAGTTGGACA 126 IFNG TCTCATCGTCAAAGGACCCA 231 CD80 TGGTGCCCGAGAAGAGTGAG 127 IFNG CCCACCAGAATGGCACAGGT 232 CD80 TAGAAGAAGACGGCAGCAGA 128 IFNG GAGATGGTGACAGATAGGCA 233 CD80 TAGTCCATGCACGGTGGTGA 129 IFNG AAAGGACCCAAGGAGTCTAA 234 CD80 ATGGTGCCCGAGAAGAGTGA 130 IFNG ATCCTCAGGAGACTTCAATT 235 CD80 ACGAGCACCAGGCGGCCTAG 131 IFNG GTATAAATACCAGCAGCCAG 236 CD80 CATGAAACACCACGAGCACC 132 IFNG AAGATGAGATGGTGACAGAT 237 CD80 GAAACACCACGAGCACCAGG 133 IFNG ATAGTTTGTATTAATAACTA 238 CD80 CAAACACCCTGTCCAACTCC 134 IFNG ATGGCACAGGTGGGCATAAT 239 CD80 CATGTTTGTTAGTCCATGCA 135 IFNG TAAATACCAGCAGCCAGAGG 240 CD80 TAGCCTTGCTGTGTGATGGG 136 IFNG TGAGATGGTGACAGATAGGC 241 CD80 ACTCAGTACTTGTCAGTGCC 137 IFNG GAGTTTCCTTTAGACTCCTT 242 CD80 TCTTCTAGTTGCTTTTGTAG 138 IFNG TCCCACCAGAATGGCACAGG 243 CD80 TGGCCTCCCATCACACAGCA 139 IFNG AAAAATTTCCAGTCCTTGAA 244 CD80 TTAGTCCATGCACGGTGGTG 140 IFNG ACTTCACACCATTCAAGGAC 245 CD80 AATGGTGCCCGAGAAGAGTG 141 IFNG TTTACCAGGGCGAAGTGGGG 246 CD80 GGCTAGCCTTGCTGTGTGAT 142 IFNG GCCCACCTGTGCCATTCTGG 247 CD80 TCCATGCACGGTGGTGAGGG 143 IFNG TATTAATAACTAAGGTTTTG 248 CD80 TGATGGGAGGCCAGCTTCAT 144 IFNG AACTAAGGTTTTGTGGCATT 249 CD80 TGGCTAGCCTTGCTGTGTGA 145 IFNG ACTAAGGTTTTGTGGCATTT 250 CD80 CCTAGGCCGCCTGGTGCTCG 146 IFNG CCCACCTGTGCCATTCTGGT 251 CD80 CTAGAAGAAGACGGCAGCAG 147 IFNG ACAAGTTTTTTAAGATGAGA 252 CD80 CACCATTCTTCTCCTCCCCT 148 IFNG ACAATGTGCTGCACCTCCTC 253 CD80 AAACAGCCAGCCCATGAAGC 149 IFNG TATGCCCACCTGTGCCATTC 254 CD80 CAAAAGCAACTAGAAGAAGA 150 IFNG CTTTTACTTCACACCATTCA 255 CD80 CTTTTGTAGAGGCTGTGGCT 151 IFNG AATGGCACAGGTGGGCATAA 256 CD80 AGCACCAGGCGGCCTAGGGG 152 IFNG GCTGCACCTCCTCTGGCTGC 257 CD80 CACGAGCACCAGGCGGCCTA 153 IFNG AGAGTTTCCTTTAGACTCCT 258 CD80 CCACGAGCACCAGGCGGCCT 154 IFNG ATTCTGGTGGGATTCTTTGA 259 CD80 GTCAGTGCCAGGAGTTGGAC 155

Table 3 : sgRNAs selected from a mimpool of 29 selected immune function genes related to antigen presentation SEQ SEQ ID ID Gene Name Guide Sequence NO: Gene Name Guide Sequence NO: CD70F1 GCTTCAGTTTGTCTGTGGGA 260 TAP1F2 TTCACGCAAGCAAGTTAAGG 305 CD70F2 ATTCACTGAGCATCTATTAG 261 TAP1F3 CGTGCCGTTCTACCAGCATT 306 CD70F3 ATCAGGAAGCATCCGCATCC 262 B2M-F1 ACGACCTCCGGATCTGAGTC 307 CD80F1 GAGAGTTCTGAATCAGGGTG 263 B2M-F2 CCGTGATATTTCAAACAGCC 308 CD80F2 TCCAGGCCTGTTCTGAGCAC 264 B2M-F3 AGCATCAACAGCTAGGAGAC 309 CD80F3 GGACCTTTGAGTTGCCCTCA 265 CXCL9-F1 AAACCCTACTCTCAGATCCC 310 CD83F1 CCAAGTCCGCGTTGCTGCTG 266 CXCL9-F2 TAGTTCTTCTAGGTCAGCTG 311 CD83F2 ATCTGCATGACCCACTCGAT 267 CXCL9-F3 TAACCACAAATTGATCGTCC 312 CD83F3 GTTTGAGGGTCATCTAGCTG 268 CXCL10-F1 ACTTTGGAGATGACTCAGCA 313 CD86F1 GCAGGCAGGAGTGGGTGGGT 269 CXCL10-F2 TTTATTGTGACCC ATGAACT 3 14 CD86F2 CTTTGTAGATT ATTCGAGTT 270 CXCL10-F3 GCAATGCCCTCGGTTTACAG 315 CD86F3 GAGTTCGGTTTCAGTCTTGA 271 Tsn-Fl GCGGAGTCTAGGCTGATAAA 3 16 IFNa4F 1 AAAGAGAATTGGAAAGCAAG 272 Tsn-F2 GGTCTGGGAACGCGGGAGTG 3 17 EFNa4F2 TGTGTACATCTCTCTTAAAT 273 Tsn-F3 TATTTATTGGTCACTTCACT 3 18 IFNa4F3 CAGGCTCTCAGAGAACCTGT 27 TAPBPRF1 CTCCAGCCCT CTCATAGTTG 19 EFNblFl GAAATTCCTCTGAGGCAGAA 275 TAPBPRF2 AGGATTTAACATGGACTGAA 320 IFNblF2 CCTGT GCTATTTATAAGGGA 276 TAPBPRF3 CTGTGATCGAACAGACGAGA 321 EFNblF3 GTGAGAATGATCTTCCTTCA 277 PDIA3-F1 GCAGTGTGGCAGCCGCCGAT 322 IFNgFl AGAGTTTCCTTTCGACTCCT 278 PDIA3-F2 AACAGCTGGTAACTGCCGAT 323 EFNgF2 TTAAGATGGTGACAGATAGG 279 PDIA3-F3 CTGCGTCACGCAGC GTCGGG 324 EFNgF3 ATACCTGATCGAAGGCTCCT 280 CalR-Fl GGTCGCACTATGGGCCAATG 325 OX40LF1 AAGT CACTCAATTC ATAACT 281 CalR-F2 GTAGGTCTAAACCAGTCAAA 326 OX40LF2 CAACTCCCTGTTAGCCCGGA 282 CalR-F3 GGGTCGACCACGCGTTGTGG 327 GITRLF1 AGTGCTTAGCAGTGTTCCAA 283 ERAP1-F1 TGATAGGGAATGCATTCTCC 328 GITRLF2 GCACCAGGCCAAACATACAA 284 ERAP1-F2 ACTTTGAGTTCCCGAAGCCC 329 GITRLF3 CACTACAAGGGAAGTTCAGA 285 ERAP1-F3 CAAGCCTAAGGGATCTAGCC 330 Flt3LFl CGCCACCTAGTGGTAACAAG 286 NLRC5-F1 AGCTGGCCGTGCAGAGAGGA 331 FH3LF2 GGGCCCTGAAAGGATAGCGA 287 NLRC5-F2 TCATCTGGGAGATGAGCCTC 332 FU3LF3 TTCTACATACACTTCGAAGC 288 NLRC5-F3 TTCGGTTGGCATTCGGCTAA 333 LIGHT-F1 TGTGACTCAGGTGGGATGGA 289 TAP2F1 GGGTCTGAGATGCTTTGAAA 334 LIGHT-F2 GAGGAGGT ACGT GAGGAAAG 290 TAP2F2 GGCGCCTGTCAATTTGCGGG 335 LIGHT-F3 CAGTGAGAGTGATCGACCGG 291 TAP2F3 TTGCTAGTAGCGGCCTTGGA 336 ICOSL-F1 GAGACTTGGGCAT GAGTTAC 292 Hmmr-Fl CCTTCCGATTGGGCGGCGGT 337 ICOSL-F2 AACCCAATCGGCTGCTGAGC 293 Hmmr-F2 AGCTGTTTGCGGCGACGATC 338 ICOSL-F3 CCGCCTGTGCCCAATTAGCC 294 Hmmr-F3 AATCTAGTGCGCATGCTCTT 339 4-1BBL-F1 CCCTCCCTCCCTTCCCTCCC 295 Trp53-Fl GTCTAAGATATAGAGCTGTG 340 4-1BBL-F2 ACAGGGCCTGGACAGGGAAG 296 Trp53-F2 GATAGTCGCCATAACAAGTA 341 4-1BBL-F3 AGAAAGTTCCGGGAGTCGAG 297 Trp53-F3 TTGTGCCAGGAGTCTCGCGG 342 TL1A-F1 CAGAGGGCTGTCAGAGGGAG 298 Tlr9-Fl TTGTGGGGTGGGGAGGAGAG 343 TL1A-F2 AACTTGGTTTCTGTTGTAGG 299 Tlr9-F2 GAAAGAGGAAGGGGTTGAGG 344 TL1A-F3 ATTCC CTAGCC GGGCAGGGC 300 Tlr9-F3 CCACAGCTCTTTGGGGGGTG 345 CD30L-F1 AATTGTAGCGAGATAGACGA 301 Tlr9-F4 TGTCCCTACCCTGAAAGAGC 346 CD30L-F2 GTGGTTGGT GTACACTC ACG 302 Tlr9-F5 ACATCATTTGCATAGTCAGA 347 CD30L-F3 CGTTCTGTGGCTGAGCCTAA 303 Tlr9-F6 GGGGCATATGTGATACCCTT 348 TAP IF 1 TGCAGGCAACTTGC AGACT G 304

Compositions Certain aspects of the invention include compositions comprising the cells or vectors of the present invention. One aspect of the invention includes a composition comprising a cancer vaccine, comprising a modified cell comprising a CRISPRa system capable of increasing expression of a plurality of endogenous genes. In certain embodiments, the cell is packaged in an AAV vector. In certain embodiments, the CRISPRa system comprises an sgRNA library. In certain embodiments, the composition comprises an sgRNA library. In one embodiment, the sgRNA library comprises sequences selected from the group consisting of SEQ ED NOs: 1-37. In one embodiment the sgRNA library comprises sequences selected from the group consisting of SEQ ED NOs: 51-259. In one embodiment the sgRNA library comprises sequences selected from the group consisting of SEQ ID NOs: 260-348.. In one embodiment the sgRNA library comprises sequences selected from the group consisting of SEQ ID NOs: 349-4,187. In one embodiment the sgRNA library comprises sequences selected from the group consisting of SEQ ID NOs: 4,188-7,980. In one embodiment the sgRNA library comprises sequences selected from the group consisting of SEQ ED NOs: 7,981-1 1,808. In one embodiment the sgRNA library comprises sequences selected from the group consisting of SEQ ID NOs: 11,809-23,776. In one embodiment the sgRNA library comprises sequences selected from the group consisting of SEQ ED NOs: 23,779-23,885. In one embodiment the sgRNA library comprises sequences selected from the group consisting of SEQ ID NOs: 23,886-24,104. In one embodiment, the invention comprises a vector comprising a U6-sgRNA and a EFS-MPH (activator). In one embodiment, the invention comprises a vector comprising two sgRNA cassettes in a CRISPRa system, wherein the first sgRNA cassette is used for activation of antigen presentation machinery, and the second sgRNA cassette is used for activation of patient-specific mutated endogenous genes, either in single gene or pooled format. In one embodiment, the vector comprises SEQ ID NO: 49. In one embodiment, the vector comprises SEQ ID NO: 50. In one embodiment, the invention comprises a vector comprising SEQ ID NO: 24.105. In one embodiment, the invention comprises a vector comprising SEQ ID NO: 24.106. Tolerable variations of the any one of the vectors will be known to those of skill in the art. For example, in some embodiments the vector comprises a nucleic acid sequence that has at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99% sequence identity to the nucleic acid sequence set forth in SEQ ID NO: 49, SEQ ID NO: 50, SEQ ID NO: 49, SEQ ID NO: 24,105, or SEQ ID NO: 24,106.

CRISPRa AAV vector: pGWOO5_pAAV-U6sgbbBsmB I(MS2)-EF 1a-MPH-sP A2 (SEQ ID NO: 49) 1 cctgcaggca gctgcgcgct cgctcgctca ctgaggccgc ccgggcaaag cccgggcgtc 6 1 gggcgacct tggtcgcccg gcctcagtga gcgagcgagc gcgcagagag ggagtggcca 121 actccatcac taggggttcc tgcggccgca gggacccaga gagggcctat ttcccatgat 181 tccttcatat ttgcatatac gatacaaggc tgttagagag ataattagaa ttaatttgac 241 tgtaaacaca aagatattag tacaaaatac gtgacgtaga aagtaataat ttcttgggta 301 gtttgcagtt taaaatat gtttaaaat ggactatcat atgcttaccg taacttgaaa 361 gtatttcgat ttcttggctt tatatatctt gtggaaagga cgaaacaccg gaagagcgag 421 ctcttctgtt ttagagctag gccaacatga ggatcaccca tgtctgcagg gcctagcaag 481 ttaaaataag gctagtccgt tatcaacttg gccaacatga ggatcaccca tgtctgcagg 541 gccaagtggc accgagtcgg tgcttttttg gatccaagct tggcgtaact agatcttgag 601 acaaatggga cagcagagat ccagtttggt taattagcta gctgcaaaga tggataaagt 661 tttaaacaga gaggaatctt tgcagctaat ggaccttcta ggtcttgaaa ggagtgggaa 721 ttggctccgg tgcccgtcag tgggcagagc gcacatcgcc cacagtcccc gagaagttgg 781 ggggaggggt cggcaattga accggtgcct agagaaggtg gcgcggggta aactgggaaa 841 gtgatgtcgt gtactggctc cgcctttttc ccgagggtgg gggagaaccg tatataagtg 901 cagtagtcgc cgtgaacgtt ctttttcgca acgggtttgc cgccagaaca caggtaagtg 961 ccgtgtgtgg ttcccgcggg cctggcctct ttacgggta tggcccttgc gtgccttgaa 1021 ttacttccac ctggctgcag tacgtgattc ttgatcccga gcttcgggtt ggaagtgggt 1081 gggagagttc gaggccttgc gcttaaggag ccccttcgcc tcgtgcttga gttgaggcct 1141 ggcctgggcg ctggggccgc cgcgtgcgaa tctggtggca ccttcgcgcc tgtctcgctg 1201 ctttcgataa gtctctagcc atttaaaatt tttgatgacc tgctgcgacg ctttttttct 1261 ggcaagatag tcttgtaaat gcgggccaag atctgcacac tggtatttcg gtttttgggg 1321 ccgcgggcgg cgacggggcc cgtgcgtccc agcgcacatg ttcggcgagg cggggcctgc 1381 gagcgcggcc accgagaatc ggacgggggt agtctcaagc tggccggcct gctctggtgc 1441 ctggcctcgc gccgccgtgt atcgccccgc cctgggcggc aaggctggcc cggtcggcac 1501 cagttgcgtg agcggaaaga tggccgcttc ccggccctgc tgcagggagc tcaaaatgaa 1561 ggacgcggcg ctcgggagag cgggcgggtg agtcacccac acaaaggaaa agggcctttc 1621 cgtcctcagc cgtcgcttca tgtgactcca cggagtaccg ggcgccgtcc aggcacctcg 1681 attagttctc gagcttttgg agtacgtcgt ctttaggtg gggggagggg tttatgcga 1741 tggagtttcc ccacactgag tgggtggaga ctgaagttag gccagcttgg cacttgatgt 1801 aattctcctt ggaatttgcc ctttttgagt ttggatcttg gttcattctc aagcctcaga 1861 cagtggttca aagttttttt cttccatttc aggtgtcgtg acgtacggcc accatggctt 1921 caaactttac tcagttcgtg ctcgtggaca atggtgggac aggggatgtg acagtggctc 1981 cttctaattt cgctaatggg gtggcagagt ggatcagctc caactcacgg agccaggcct 204 1 acaaggtgac atgcagcgtc aggcagtcta gtgcccagaa gagaaagtat accatcaagg 2101 tggaggtccc caaagtggct acccagacag tgggcggagt cgaactgcct gtcgccgctt 2161 ggaggtccta cctgaacatg gagctcacta tcccaatttt cgctaccaat tctgactgtg 222 1 aactcatcgt gaaggcaatg caggggctcc tcaaagacgg taatcctatc ccttccgcca 2281 tcgccgctaa ctcaggtatc tacagcgctg gaggaggtgg aagcggagga ggaggaagcg 2341 gaggaggagg tagcggacct aagaaaaaga ggaaggtggc ggccgctgga tccccttcag 240 1 ggcagatcag caaccaggcc ctggctctgg cccctagctc cgctccagtg ctggcccaga 246 1 ctatggtgcc ctctagtgct atggtgcctc tggcccagcc acctgctcca gcccctgtgc 2521 tgaccccagg accaccccag tcactgagcg ctccagtgcc caagtctaca caggccggcg 2581 aggggactct gagtgaagct ctgctgcacc tgcagttcga cgctgatgag gacctgggag 264 1 ctctgctggg gaacagcacc gatcccggag tgttcacaga tctggcctcc gtggacaact 2701 ctgagtttca gcagctgctg aatcagggcg tgtccatgtc tcatagtaca gccgaaccaa 2761 tgctgatgga gtaccccgaa gccattaccc ggctggtgac cggcagccag cggccccccg 2821 accccgctcc aactcccctg ggaaccagcg gcctgcctaa tgggctgtcc ggagatgaag 2881 acttctcaag catcgctgat atggacttta gtgccctgct gtcacagatt tcctctagtg 294 1 ggcagggagg aggtggaagc ggcttcagcg tggacaccag tgccctgctg gacctgttca 3001 gcccctcggt gaccgtgccc gacatgagcc tgcctgacct tgacagcagc ctggccagta 3061 tccaagagct cctgtctccc caggagcccc ccaggcctcc cgaggcagag aacagcagcc 3121 cggattcagg gaagcagctg gtgcactaca cagcgcagcc gctgttcctg ctggaccccg 3181 gctccgtgga caccgggagc aacgacctgc cggtgctgtt tgagctggga gagggctcct 3241 acttctccga aggggacggc ttcgccgagg accccaccat ctccctgctg acaggctcgg 3301 agcctcccaa agccaaggac cccactgtct cctaagaatt cgatatcaag cttaataaaa 3361 gatctttatt ttcattagat ctgtgtgttg gttttttgtg tggtaaccac gtgcggaccg 3421 agcggccgca ggaaccccta gtgatggagt tggccactcc ctctctgcgc gctcgctcgc 3481 tcactgaggc cgggcgacca aaggtcgccc gacgcccggg ctttgcccgg gcggcctcag 3541 tgagcgagcg agcgcgcagc tgcctgcagg ggcgcctgat gcggtatttt ctccttacgc 3601 atctgtgcgg tatttcacac cgcatacgtc aaagcaacca tagtacgcgc cctgtagcgg 3661 cgcattaagc gcggcgggtg tggtggttac gcgcagcgtg accgctacac ttgccagcgc 3721 cctagcgccc gctcctttcg ctttcttccc ttcctttctc gccacgttcg ccggctttcc 3781 ccgtcaagct ctaaatcggg ggctcccttt agggttccga tttagtgctt tacggcacct 3841 cgaccccaaa aaacttgatt tgggtgatgg ttcacgtagt gggccatcgc cctgatagac 3901 ggtttttcgc cctttgacgt tggagtccac gttcttaat agtggactct tgttccaaac 3961 tggaacaaca ctcaacccta tctcgggcta ttcttttgat ttataaggga ttttgccgat 402 1ttcggcctat tggttaaaaa atgagctgat ttaacaaaaa tttaacgcga attttaacaa 4081 aatattaacg tttacaattt tatggtgcac tctcagtaca atctgctctg atgccgcata 4141 gttaagccag ccccgacacc cgccaacacc cgctgacgcg ccctgacggg cttgtctgct 420 1 cccggcatcc gcttacagac aagctgtgac cgtctccggg agctgcatgt gtcagaggtt 426 1 ttcaccgtca tcaccgaaac gcgcgagacg aaagggcctc gtgatacgcc tatttttata 4321 ggtaatgtc atgataataa tggtttctta gacgtcaggt ggcactttc ggggaaatgt 4381 gcgcggaacc cctatttgtt tattttcta aatacattca aatatgtatc cgctcatgag 444 1 acaataaccc tgataaatgc ttcaataata ttgaaaaagg aagagtatga gtattcaaca 4501 tttccgtgtc gcccttattc cctttttgc ggcatttgc cttcctgttt ttgctcaccc 4561 agaaacgctg gtgaaagtaa aagatgctga agatcagttg ggtgcacgag tgggttacat 462 1 cgaactggat ctcaacagcg gtaagatcct tgagagtttt cgccccgaag aacgttttcc 4681 aatgatgagc acttttaaag ttctgctatg tggcgcggta ttatcccgta tgacgccgg 4741 gcaagagcaa ctcggtcgcc gcatacacta ttctcagaat gacttggtg agtactcacc 4801 agtcacagaa aagcatcta cggatggcat gacagtaaga gaattatgca gtgctgccat 4861 aaccatgagt gataacactg cggccaactt acttctgaca acgatcggag gaccgaagga 4921 gctaaccgct tttttgcaca acatggggga tcatgtaact cgccttgatc gttgggaacc 4981 ggagctgaat gaagccatac caaacgacga gcgtgacacc acgatgcctg tagcaatggc 5041 aacaacgttg cgcaaactat taactggcga actacttact ctagcttccc ggcaacaatt 5101 aatagactgg atggaggcgg ataaagttgc aggaccactt ctgcgctcgg cccttccggc 5161 tggctggttt attgctgata aatctggagc cggtgagcgt gggtctcgcg gtatcattgc 5221 agcactgggg ccagatggta agccctcccg tatcgtagtt atctacacga cggggagtca 5281 ggcaactatg gatgaacgaa atagacagat cgctgagata ggtgcctcac tgattaagca 5341 ttggtaactg tcagaccaag tttactcata tatacttag attgatttaa aacttcatt 5401 ttaatttaaa aggatctagg tgaagatcct tttgataat ctcatgacca aaatccctta 5461 acgtgagttt tcgttccact gagcgtcaga ccccgtagaa aagatcaaag gatcttctg 5521 agatcctttt tttctgcgcg taatctgctg cttgcaaaca aaaaaaccac cgctaccagc 5581 ggtggtttgt ttgccggatc aagagctacc aactcttttt ccgaaggtaa ctggcttcag 5641 cagagcgcag ataccaaata ctgtccttct agtgtagccg tagttaggcc accacttcaa 5701 gaactctgta gcaccgccta catacctcgc tctgctaatc ctgttaccag tggctgctgc 5761 cagtggcgat aagtcgtgtc ttaccgggtt ggactcaaga cgatagttac cggataaggc 5821 gcagcggtcg ggctgaacgg ggggttcgtg cacacagccc agcttggagc gaacgaccta 5881 caccgaactg agatacctac agcgtgagct atgagaaagc gccacgcttc ccgaagggag 5941 aaaggcggac aggtatccgg taagcggcag ggtcggaaca ggagagcgca cgagggagct 6001 tccaggggga aacgcctggt atctttatag tcctgtcggg tttcgccacc tctgacttga 606 1 gcgtcgattt tgtgatgct cgtcaggggg gcggagccta tggaaaaacg ccagcaacgc 6121 ggccttttta cggttcctgg ccttttgctg gccttttgct cacatgt pAAV-U6sgbbBsmBI(MS2)-U6CD80MS2-EFla-MPH-sPA (SEQ ID NO: 50) 1 cctgcaggca gctgcgcgct cgctcgctca ctgaggccgc ccgggcaaag cccgggcgtc 6 1 gggcgacctt tggtcgcccg gcctcagtga gcgagcgagc gcgcagagag ggagtggcca 121 actccatcac taggggttcc tgcggccgca cgcgttctag aagagggcct atttcccatg 181 attccttcat atttgcatat acgatacaag gctgttagag agataatgg aattaatttg 241 actgtaaaca caaagatatt agtacaaaat acgtgacgta gaaagtaata atttcttggg 301 tagtttgcag ttttaaaatt atgtttaaa atggactatc atatgcttac cgtaacttga 361 aagtatttcg atttcttggc tttatatatc ttgtggaaag gacgaaacac cggaagagcg 421 agctcttctg ttttagagct aggccaacat gaggatcacc catgtctgca gggcctagca 481 agttaaaata aggctagtcc gtatcaact tggccaacat gaggatcacc catgtctgca 541 gggccaagtg gcaccgagtc ggtgctttt tggatccaag cttggcgtaa ctagatcttg 601 agacaaatgg gacagcagag atccagtttg gttaattagg gacccagaga gggcctattt 661 cccatgattc cttcatattt gcatatacga tacaaggctg ttagagagat aattagaatt 721 aatttgactg taaacacaaa gatattagta caaaatacgt gacgtagaaa gtaataattt 781 cttgggtagt ttgcagtttt aaaattatgt tttaaaatgg actatcatat gcttaccgta 841 acttgaaagt atttcgattt cttggcttta tatatcttgt ggaaaggacg aaacaccgag 901 agttctgaat cagggtggtt ttagagctag gccaacatga ggatcaccca tgtctgcagg 961 gcctagcaag ttaaaataag gctagtccgt tatcaacttg gccaacatga ggatcaccca 1021 tgtctgcagg gccaagtggc accgagtcgg tgcttttttg gatccaagct tggcgtaact 1081 agatcttgag acaaatggct agctgcaaag atggataaag ttttaaacag agaggaatct 1141 ttgcagctaa tggaccttct aggtcttgaa aggagtggga attggctccg gtgcccgtca 1201 gtgggcagag cgcacatcgc ccacagtccc cgagaagttg gggggagggg tcggcaattg 1261 aaccggtgcc tagagaaggt ggcgcggggt aaactgggaa agtgatgtcg tgtactggct 1321 ccgccttttt cccgagggtg ggggagaacc gtatataagt gcagtagtcg ccgtgaacgt 1381 tctttttcgc aacgggtttg ccgccagaac acaggtaagt gccgtgtgtg gttcccgcgg 1441 gcctggcctc tttacgggtt atggcccttg cgtgccttga attacttcca cctggctgca 1501 gtacgtgatt ctgatcccg agcttcgggt tggaagtggg tgggagagtt cgaggccttg 1561 cgcttaagga gccccttcgc ctcgtgcttg agttgaggcc tggcctgggc gctggggccg 1621 ccgcgtgcga atctggtggc accttcgcgc ctgtctcgct gctttcgata agtctctagc 1681 cattaaaat ttttgatgac ctgctgcgac gctttttttc tggcaagata gtctgtaaa 1741 tgcgggccaa gatctgcaca ctggtatttc ggttttggg gccgcgggcg gcgacggggc 1801 ccgtgcgtcc cagcgcacat gttcggcgag gcggggcctg cgagcgcggc caccgagaat 1861 cggacggggg tagtctcaag ctggccggcc tgctctggtg cctggcctcg cgccgccgtg 19 1 tatcgccccg ccctgggcgg caaggctggc ccggtcggca ccagttgcgt gagcggaaag 1981 atggccgctt cccggccctg ctgcagggag ctcaaaatga aggacgcggc gctcgggaga 204 1 gcgggcgggt gagtcaccca cacaaaggaa aagggccttt ccgtcctcag ccgtcgcttc 2101 atgtgactcc acggagtacc gggcgccgtc caggcacctc gattagttct cgagcttttg 2161 gagtacgtcg tctttaggtt ggggggaggg gttttatgcg atggagtttc cccacactga 2221 gtgggtggag actgaagtta ggccagcttg gcactgatg taattctcct tggaattgc 2281 cctttgag tttggatctt ggttcattct caagcctcag acagtggttc aaagtttt 2341 tcttccattt caggtgtcgt gacgtacggc caccatggct tcaaacttta ctcagttcgt 240 1 gctcgtggac aatggtggga caggggatgt gacagtggct ccttctaatt tcgctaatgg 246 1 ggtggcagag tggatcagct ccaactcacg gagccaggcc tacaaggtga catgcagcgt 2521 caggcagtct agtgcccaga agagaaagla taccatcaag gtggaggtcc ccaaagtggc 2581 tacccagaca gtgggcggag tcgaactgcc tgtcgccgct tggaggtcct acctgaacat 264 1 ggagctcact atcccaattt tcgctaccaa ttctgactgt gaactcatcg tgaaggcaat 2701 gcaggggctc ctcaaagacg gtaatcctat cccttccgcc atcgccgcta actcaggtat 2761 ctacagcgct ggaggaggtg gaagcggagg aggaggaagc ggaggaggag gtagcggacc 2821 taagaaaaag aggaaggtgg cggccgctgg atccccttca gggcagatca gcaaccaggc 2881 cctggctctg gcccctagct ccgctccagt gctggcccag actatggtgc cctctagtgc 2941 tatggtgcct ctggcccagc cacctgctcc agcccctgtg ctgaccccag gaccacccca 3001 gtcactgagc gctccagtgc ccaagtctac acaggccggc gaggggactc tgagtgaagc 3061 tctgctgcac ctgcagttcg acgctgatga ggacctggga gctctgctgg ggaacagcac 3121 cgatcccgga gtgttcacag atctggcctc cgtggacaac tctgagtttc agcagctgct 3181 gaatcagggc gtgtccatgt ctcatagtac agccgaacca atgctgatgg agtaccccga 3241 agccattacc cggctggtga ccggcagcca gcggcccccc gaccccgctc caactcccct 3301 gggaaccagc ggcctgccta atgggctgtc cggagatgaa gacttctcaa gcatcgctga 3361 tatggacttt agtgccctgc tgtcacagat ttcctctagt gggcagggag gaggtggaag 3421 cggcttcagc gtggacacca gtgccctgct ggacctgttc agcccctcgg tgaccgtgcc 3481 cgacatgagc ctgcctgacc ttgacagcag cctggccagt atccaagagc tcctgtctcc 3541 ccaggagccc cccaggcctc ccgaggcaga gaacagcagc ccggattcag ggaagcagct 3601 ggtgcactac acagcgcagc cgctgttcct gctggacccc ggctccgtgg acaccgggag 3661 caacgacctg ccggtgctgt ttgagctggg agagggctcc tacttctccg aaggggacgg 3721 cttcgccgag gaccccacca tctccctgct gacaggctcg gagcctccca aagccaagga 3781 ccccactgtc tcctaagaat tcgatatcaa gctaataaa agatctttat ttcattaga 3841 tctgtgtgtt ggttttttgt gtggtaacca cgtgcggacc gagcggccgc aggaacccct 3901 agtgatggag ttggccactc cctctctgcg cgctcgctcg ctcactgagg ccgggcgacc 3961 aaaggtcgcc cgacgcccgg gctttgcccg ggcggcctca gtgagcgagc gagcgcgcag 402 1 ctgcctgcag gggcgcctga tgcggtattt tctccttacg catctgtgcg gtatttcaca 4081 ccgcatacgt caaagcaacc atagtacgcg ccctgtagcg gcgcattaag cgcggcgggt 4141 gtggtggtta cgcgcagcgt gaccgctaca cttgccagcg ccctagcgcc cgctcctttc 420 1 gctttcttcc cttcctttct cgccacgttc gccggctttc cccgtcaagc tctaaatcgg 426 1 gggctccctt tagggttccg atttagtgct ttacggcacc tcgaccccaa aaaacttgat 4321 ttgggtgatg gttcacgtag tgggccatcg ccctgataga cggtttttcg cccttgacg 4381 ttggagtcca cgttctttaa tagtggactc tgttccaaa ctggaacaac actcaaccct 444 1 atctcgggct attcttttga tttataaggg attttgccga tttcggccta ttggttaaaa 4501 aatgagctga tttaacaaaa atttaacgcg aattttaaca aaatattaac gtttacaatt 4561 ttatggtgca ctctcagtac aatctgctct gatgccgcat agttaagcca gccccgacac 462 1 ccgccaacac ccgctgacgc gccctgacgg gcttgtctgc tcccggcatc cgcttacaga 4681 caagctgtga ccgtctccgg gagctgcatg tgtcagaggt tttcaccgtc atcaccgaaa 4741 cgcgcgagac gaaagggcct cgtgatacgc ctatttttat aggttaatgt catgataata 4801 atggtttctt agacgtcagg tggcactttt cggggaaatg tgcgcggaac ccctatttgt 4861 ttattttct aaatacattc aaatatgtat ccgctcatga gacaataacc ctgataaatg 4921 cttcaataat attgaaaaag gaagagtatg agtattcaac atttccgtgt cgcccttatt 4981 cccttttttg cggcattttg ccttcctgtt tttgctcacc cagaaacgct ggtgaaagta 5041 aaagatgctg aagatcagtt gggtgcacga gtgggtaca tcgaactgga tctcaacagc 5101 ggtaagatcc ttgagagttt tcgccccgaa gaacgtttc caatgatgag cacttttaaa 5161 gttctgctat gtggcgcggt attatcccgt attgacgccg ggcaagagca actcggtcgc 5221 cgcatacact attctcagaa tgactggtt gagtactcac cagtcacaga aaagcatctt 5281 acggatggca tgacagtaag agaattatgc agtgctgcca taaccatgag tgataacact 5341 gcggccaact tacttctgac aacgatcgga ggaccgaagg agctaaccgc ttttttgcac 5401 aacatggggg atcatgtaac tcgccttgat cgttgggaac cggagctgaa tgaagccata 5461 ccaaacgacg agcgtgacac cacgatgcct gtagcaatgg caacaacgtt gcgcaaacta 5521 ttaactggcg aactacttac tctagcttcc cggcaacaat taatagactg gatggaggcg 5581 gataaagtg caggaccact tctgcgctcg gcccttccgg ctggctggtt tatgctgat 5641 aaatctggag ccggtgagcg tgggtctcgc ggtatcatg cagcactggg gccagatggt 5701 aagccctccc gtatcgtagt tatctacacg acggggagtc aggcaactat ggatgaacga 5761 aatagacaga tcgctgagat aggtgcctca ctgattaagc atggtaact gtcagaccaa 5821 gtttactcat atatacttta gattgattta aaacttcatt tttaatttaa aaggatctag 5881 gtgaagatcc tttttgataa tctcatgacc aaaatccctt aacgtgagtt ttcgttccac 5941 tgagcgtcag accccgtaga aaagatcaaa ggatcttctt gagatccttt ttttctgcgc 600 1 gtaatctgct gctgcaaac aaaaaaacca ccgctaccag cggtggtttg ttgccggat 606 1 caagagctac caactctttt tccgaaggta actggcttca gcagagcgca gataccaaat 6121 actgtccttc tagtgtagcc gtagttaggc caccacttca agaactctgt agcaccgcct 6181 acatacctcg ctctgctaat cctgttacca gtggctgctg ccagtggcga taagtcgtgt 6241 cttaccgggt tggactcaag acgatagtta ccggataagg cgcagcggtc gggctgaacg 6301 gggggttcgt gcacacagcc cagctggag cgaacgacct acaccgaact gagataccta 6361 cagcgtgagc tatgagaaag cgccacgctt cccgaaggga gaaaggcgga caggtatccg 6421 gtaagcggca gggtcggaac aggagagcgc acgagggagc ttccaggggg aaacgcctgg 6481 tatctttata gtcctgtcgg gtttcgccac ctctgacttg agcgtcgatt tttgtgatgc 6541 tcgtcagggg ggcggagcct atggaaaaac gccagcaacg cggccttttt acggttcctg 660 1 gccttttgct ggcctttgc tcacatgt

pZB2 EFS-LTR-dCas9 addgene-plasmid-106430 (SEP ID NO: 24.105 ) cctgcaggcagctgcgcgctcgctcgctcactgaggccgcccgggcgtcgggcgacctttggtcgcccggcctcagtgag cgagcgagcgcgcagagagggagtggccaactccatcactaggggttcctgcggcctctagaaaggatctgcgatcgctc cggtgcccgtcagtgggcagagcgcacatcgcccacagtccccgagaagttggggggaggggtcggcaattgaacgggtg cctagagaaggtggcgcggggtaaactgggaaagtgatgtcgtgtactggctccgcctttttcccgagggtgggggagaa ccgtatataagtgcagtagtcgccgtgaacgttctttttcgcaacgggttgccgccagaacacagctgaagcttcgagg ggctcgcatctctccttcacgcgcccgccgccctacctgaggccgccatccacgccggtgagtcgcgttctgccgcctc ccgcctgtggtgcctcctgaactgcgtccgccgtctaggtaagtttaaagctcaggtcgagaccgggcctttgtccggcg ctcccttggagcctacctagactcagccggctctccacgctttgcctgaccctgcttgctcaactctacgtctttgtttc gttttctgttctgcgccgtacagatccaagctgtgaccggcgcctacaccggtgccaccatgtacccatacgatgttcc agattacgcttcgccgaagaaaaagcgcaaggtcgaagcgtccgacaagaagtactccattgggctcgctatcggcacaa acagcgtcggctgggccgtcattacggacgagtacaaggtgccgagcaaaaaattcaaagttctgggcaataccgatcgc cacagcataaagaagaacctcattggcgccctcctgttcgactccggggagacggccgaagccacgcggctcaaaagaac agcacggcgcagatatacccgcagaaagaatcggatctgctacctgcaggagatctttagtaatgagatggctaaggtgg atgactctttcttccataggctggaggagtccttttggtggaggaggataaaaagcacgagcgccacccaatctttggc aatatcgtggacgaggtggcgtaccatgaaaagtacccaaccatatatcatctgaggaagaagcttgtagacagtactga taaggctgacttgcggttgatctatctcgcgctggcgcatatgatcaaatttcggggacacttcctcatcgagggggacc tgaacccagacaacagcgatgtcgacaaactctttatccaactggttcagacttacaatcagcttttcgaagagaacccg atcaacgcatccggagttgacgccaaagcaatcctgagcgctaggctgtccaaatcccggcggctcgaaaacctcatcgc acagctccctggggagaagaagaacggcctgtttggtaatcttatcgccctgtcactcgggctgacccccaactttaaat ctaacttcgacctggccgaagatgccaagcttcaactgagcaaagacacctacgatgatgatctcgacaatctgctggcc cagatcggcgaccagtacgcagaccttttttggcggcaaagaacctgtcagacgccattctgctgagtgatattctgcg agtgaacacggagatcaccaaagctccgctgagcgctagtatgatcaagcgctatgatgagcaccaccaagacttgactt tgctgaaggcccttgtcagacagcaactgcctgagaagtacaaggaaattttcttcgatcagtctaaaaatggctacgcc ggatacattgacggcggagcaagccaggaggaattttacaaatttattaagcccatcttggaaaaaatggacggcaccga ggagctgctggtaaagcttaacagagaagatctgttgcgcaaacagcgcactttcgacaatggaagcatcccccaccaga ttcacctgggcgaactgcacgctatcctcaggcggcaagaggatttctacccctttttgaaagataacagggaaaagatt gagaaaatcctcacatttcggataccctactatgtaggccccctcgcccggggaaattccagattcgcgtggatgactcg caaatcagaagagaccatcactccctggaacttcgaggaagtcgtggataagggggcctctgcccagtccttcatcgaaa ggatgactaactttgataaaaatctgcctaacgaaaaggtgcttcctaaacactctctgctgtacgagtacttcacagtt tataacgagctcaccaaggtcaaatacgtcacagaagggatgagaaagccagcattcctgtctggagagcagaagaaagc tatcgtggacctcctcttcaagacgaaccggaaagttaccgtgaaacagctcaaagaagactatttcaaaaagattgaat gtttcgactctgtgaaatcagcggagtggaggatcgcttcaacgcatccctgggaacgtatcacgatctcctgaaaatc attaaagacaaggacttcctggacaatgaggagaacgaggacattctgaggacattgtcctcacccttacgttgtttga agatagggagatgatgaagaacgcttgaaaacttacgctcatctcttcgacgacaaagtcatgaaacagctcaagaggc gccgatatacaggatgggggcggctgtcaagaaaactgatcaatgggatccgagacaagcagagtggaaagacaatcctg gattttcttaagtccgatggatttgccaaccggaacttcatgcagttgatccatgatgactctctcacctttaaggagga catccagaaagcacaagtttctggccagggggacagtcttcacgagcacatcgctaatcttgcaggtagcccagctatca aaaagggaatactgcagaccgttaaggtcgtggatgaactcgtcaaagtaatgggaaggcataagcccgagaatatcgtt atcgagatggcccgagagaaccaaactacccagaagggacagaagaacagtagggaaaggatgaagaggattgaagaggg tataaaagaactggggtcccaaatccttaaggaacacccagttgaaaacacccagcttcagaatgagaagctctacctgt actacctgcagaacggcagggacatgtacgtggatcaggaactggacatcaatcggctctccgactacgacgtggctgct atcgtgccccagtcttttctcaaagatgattctattgataataaagtgttgacaagatccgataaagctagagggaagag tgataacgtcccctcagaagaagtgtcaagaaaatgaaaaattattggcggcagctgctgaacgccaaactgatcacac aacggaagttcgataatctgactaaggctgaacgaggtggcctgtctgagtggataaagccggcttcatcaaaaggcag cttgttgagacacgccagatcaccaagcacgtggcccaaattctcgattcacgcatgaacaccaagtacgatgaaaatga caaactgattcgagaggtgaaagttattactctgaagtctaagctggtctcagatttcagaaaggactttcagttttata aggtgagagagatcaacaattaccaccatgcgcatgatgcctacctgaatgcagtggtaggcactgcacttatcaaaaaa tatcccaagcttgaatctgaatttgtttacggagactataaagtgtacgatgttaggaaaatgatcgcaaagtctgagca ggaaataggcaaggccaccgctaagtacttcttttacagcaatattatgaattttttcaagaccgagattacactggcca atggagagattcggaagcgaccacttatcgaaacaaacggagaaacaggagaaatcgtgtgggacaagggtagggatttc gcgacagtccggaaggtcctgtccatgccgcaggtgaacatcgttaaaaagaccgaagtacagaccggaggcttctccaa ggaaagtatcctcccgaaaaggaacagcgacaagctgatcgcacgcaaaaaagattgggaccccaagaaatacggcggat tcgattctcctacagtcgcttacagtgtactggttgtggccaaagtggagaaagggaagtctaaaaaactcaaaagcgtc aaggaactgctgggcatcacaatcatggagcgatcaagcttcgaaaaaaaccccatcgactttctcgaggcgaaaggata taaagaggtcaaaaaagacctcatcattaagcttcccaagtactctctctttgagctgaaaacggccggaaacgaatgc tcgctagtgcgggcgagctgcagaaaggtaacgagctggcactgccctctaaatacgttaatttcttgtatctggccagc cactatgaaaagctcaaagggtctcccgaagataatgagcagaagcagctgttcgtggaacaacacaaacactacctga tgagatcatcgagcaaataagcgaattctccaaaagagtgatcctcgccgacgctaacctcgataaggtgctttctgctt acaataagcacagggataagcccatcagggagcaggcagaaaacattatccacttgtttactctgaccaacttgggcgcg cctgcagccttcaagtacttcgacaccaccatagacagaaagcggtacacctctacaaaggaggtcctggacgccacact gattcatcagtcaattacggggctctatgaaacaagaatcgacctctctcagctcggtggagacagccccaagaagaaga gaaaggtggaggccagctaagaattcaataaaagatctttattttcattagatctgtgtgttggttttttgtgtgcggcc gcaggaacccctagtgatggagttggccactccctctctgcgcgctcgctcgctcactgaggccgggcgaccaaaggtcg cccgacgcccgggctttgcccgggcggcctcagtgagcgagcgagcgcgcagctgcctgcaggggcgcctgatgcggtat tttctccttacgcatctgtgcggtatttcacaccgcatacgtcaaagcaaccatagtacgcgccctgtagcggcgcatta agcgcggcgggtgtggtggttacgcgcagcgtgaccgctacacttgccagcgccttagcgcccgctcctttcgctttctt cccttcctttctcgccacgttcgccggctttccccgtcaagctctaaatcgggggctccctttagggttccgatttagtg ctttacggcacctcgaccccaaaaaacttgatttgggtgatggttcacgtagtgggccatcgccctgatagacggttttt cgccctttgacgttggagtccacgttctttaatagtggactcttgttccaaactggaacaacactcaactctatctcggg ctattcttttgatttataagggattttgccgatttcggtctattggttaaaaaatgagctgatttaacaaaaatttaacg cgaattttaacaaaatattaacgtttacaattttatggtgcactctcagtacaatctgctctgatgccgcatagttaagc cagccccgacacccgccaacacccgctgacgcgccctgacgggcttgtctgctcccggcatccgcttacagacaagctgt gaccgtctccgggagctgcatgtgtcagaggttttcaccgtcatcaccgaaacgcgcgagacgaaagggcctcgtgatac gcctatttttataggttaatgtcatgataataatggtttcttagacgtcaggtggcacttttcggggaaatgtgcgcgga acccctatttgtttattttctaaatacattcaaatatgtatccgctcatgagacaataaccctgataaatgcttcaata atattgaaaaaggaagagtatgagtattcaacattccgtgtcgcccttattcccttttttgcggcattttgccttcctg tttttgctcacccagaaacgctggtgaaagtaaaagatgctgaagatcagttgggtgcacgagtgggttacatcgaactg gatctcaacagcggtaagatccttgagagttttcgccccgaagaacgttttccaatgatgagcactttaaagtctgct atgtggcgcggtattatcccgtatgacgccgggcaagagcaactcggtcgccgcatacactattctcagaatgacttgg ttgagtactcaccagtcacagaaaagcatcttacggatggcatgacagtaagagaatatgcagtgctgccataaccatg agtgataacactgcggccaacttacttctgacaacgatcggaggaccgaaggagctaaccgcttttttgcacaacatggg ggatcatgtaactcgccttgatcgtgggaaccggagctgaatgaagccataccaaacgacgagcgtgacaccacgatgc ctgtagcaatggcaacaacgttgcgcaaactattaactggcgaactacttactctagcttcccggcaacaattaatagac tggatggaggcggataaagttgcaggaccacttctgcgctcggcccttccggctggctggtttattgctgataaatctgg agccggtgagcgtggaagccgcggtatcattgcagcactggggccagatggtaagccctcccgtatcgtagttatctaca cgacggggagtcaggcaactatggatgaacgaaatagacagatcgctgagataggtgcctcactgattaagcattggtaa ctgtcagaccaagtttactcatatatactttagattgatttaaaacttcatttttaatttaaaaggatctaggtgaagat cctttttgataatctcatgaccaaaatcccttaacgtgagttttcgttccactgagcgtcagaccccgtagaaaagatca aaggatcttcttgagatccttttttctgcgcgtaatctgctgctgcaaacaaaaaaaccaccgctaccagcggtggtt tgtttgccggatcaagagctaccaactctttttccgaaggtaactggcttcagcagagcgcagataccaaatactgttct tctagtgtagccgtagttaggccaccacttcaagaactctgtagcaccgcctacatacctcgctctgctaatcctgttac cagtggctgctgccagtggcgataagtcgtgtcttaccgggttggactcaagacgatagttaccggataaggcgcagcgg tcgggctgaacggggggttcgtgcacacagcccagcttggagcgaacgacctacaccgaactgagatacctacagcgtga gctatgagaaagcgccacgcttcccgaagggagaaaggcggacaggtatccggtaagcggcagggtcggaacaggagagc gcacgagggagcttccagggggaaacgcctggtatctttatagtcctgtcgggtttcgccacctctgacttgagcgtcga tttttgtgatgctcgtcaggggggcggagcctatggaaaaacgccagcaacgcggcctttttacggttcctggccttttg ctggccttttgctcacatgt pGWOl lb pAAV-EFS-dCAS9-spA (SEP ID NO: 24 1061 cctgcaggcagctgcgcgctcgctcgctcactgaggccgcccgggcaaagcccgggcgtcgggcgacctttggtcgcccg gcctcagtgagcgagcgagcgcgcagagagggagtggccaactccatcactaggggttcctgcggccgcacgcgttctag gtcttgaaaggagtgggaattggctccggtgcccgtcagtgggcagagcgcacatcgcccacagtccccgagaagttggg gggaggggtcggcaattgatccggtgcctagagaaggtggcgcggggtaaactgggaaagtgatgtcgtgtactggctcc gcctttttcccgagggtgggggagaaccgtatataagtgcagtagtcgccgtgaacgttctttttcgcaacgggtttgccgccaga acacaggTGTCGTGACGCGcGTACGtaatacgactcactatagggccgccaccATGAAAAGGCCG GCGGCCACGAAAAAGGCCGGCCAGGCAAAAAAGAAAAAGGACAAGAAGTAC AGCATCGGCCTGGCCATCGGCACCAACTCTGTGGGCTGGGCCGTGATCACCG ACGAGTACAAGGTGCCCAGCAAGAAATTCAAGGTGCTGGGCAACACCGACCG GCACAGCATCAAGAAGAACCTGATCGGAGCCCTGCTGTTCGACAGCGGCGAA ACAGCCGAGGCCACCCGGCTGAAGAGAACCGCCAGAAGAAGATACACCAGA CGGAAGAACCGGATCTGCTATCTGCAAGAGATCTTCAGCAACGAGATGGCCA AGGTGGACGACAGCTTCTTCCACAGACTGGAAGAGTCCTTCCTGGTGGAAGA GGATAAGAAGCACGAGCGGCACCCCATCTTCGGCAACATCGTGGACGAGGTG GCCTACCACGAGAAGTACCCCACCATCTACCACCTGAGAAAGAAACTGGTGG ACAGCACCGACAAGGCCGACCTGCGGCTGATCTATCTGGCCCTGGCCCACAT GATCAAGTTCCGGGGCCACTTCCTGATCGAGGGCGACCTGAACCCCGACAAC AGCGACGTGGACAAGCTGTTCATCCAGCTGGTGCAGACCTACAACCAGCTGT TCGAGGAAAACCCCATCAACGCCAGCGGCGTGGACGCCAAGGCCATCCTGTC TGCCAGACTGAGCAAGAGCAGACGGCTGGAAAATCTGATCGCCCAGCTGCCC GGCGAGAAGAAGAATGGCCTGTTCGGCAACCTGATTGCCCTGAGCCTGGGCC TGACCCCCAACTTCAAGAGCAACTTCGACCTGGCCGAGGATGCCAAACTGCA GCTGAGCAAGGACACCTACGACGACGACCTGGACAACCTGCTGGCCCAGATC GGCGACCAGTACGCCGACCTGTTTCTGGCCGCCAAGAACCTGTCCGACGCCA TCCTGCTGAGCGACATCCTGAGAGTGAACACCGAGATCACCAAGGCCCCCCT GAGCGCCTCTATGATCAAGAGATACGACGAGCACCACCAGGACCTGACCCTG CTGAAAGCTCTCGTGCGGCAGCAGCTGCCTGAGAAGTACAAAGAGATTTTCT TCGACCAGAGCAAGAACGGCTACGCCGGCTACATTGACGGCGGAGCCAGCCA GGAAGAGTTCTACAAGTTCATCAAGCCCATCCTGGAAAAGATGGACGGCACC GAGGAACTGCTCGTGAAGCTGAACAGAGAGGACCTGCTGCGGAAGCAGCGG ACCTTCGACAACGGCAGCATCCCCCACCAGATCCACCTGGGAGAGCTGCACG CCATTCTGCGGCGGCAGGAAGATTTTTACCCATTCCTGAAGGACAACCGGGA AAAGATCGAGAAGATCCTGACCTTCCGCATCCCCTACTACGTGGGCCCTCTGG CCAGGGGAAACAGCAGATTCGCCTGGATGACCAGAAAGAGCGAGGAAACCA TCACCCCCTGGAACTTCGAGGAAGTGGTGGACAAGGGCGCTTCCGCCCAGAG CTTCATCGAGCGGATGACCAACTTCGATAAGAACCTGCCCAACGAGAAGGTG CTGCCCAAGCACAGCCTGCTGTACGAGTACTTCACCGTGTATAACGAGCTGA CCAAAGTGAAATACGTGACCGAGGGAATGAGAAAGCCCGCCTTCCTGAGCGG CGAGCAGAAAAAGGCCATCGTGGACCTGCTGTTCAAGACCAACCGGAAAGTG ACCGTGAAGCAGCTGAAAGAGGACTACTTCAAGAAAATCGAGTGCTTCGACT CCGTGGAAATCTCCGGCGTGGAAGATCGGTTCAACGCCTCCCTGGGCACATA CCACGATCTGCTGAAAATTATCAAGGACAAGGACTTCCTGGACAATGAGGAA AACGAGGACATTCTGGAAGATATCGTGCTGACCCTGACACTGTTTGAGGACA GAGAGATGATCGAGGAACGGCTGAAAACCTATGCCCACCTGTTCGACGACAA AGTGATGAAGCAGCTGAAGCGGCGGAGATACACCGGCTGGGGCAGGCTGAG CCGGAAGCTGATCAACGGCATCCGGGACAAGCAGTCCGGCAAGACAATCCTG GATTTCCTGAAGTCCGACGGCTTCGCCAACAGAAACTTCATGCAGCTGATCCA CGACGACAGCCTGACCTTTAAAGAGGACATCCAGAAAGCCCAGGTGTCCGGC CAGGGCGATAGCCTGCACGAGCACATTGCCAATCTGGCCGGCAGCCCCGCCA TTAAGAAGGGCATCCTGCAGACAGTGAAGGTGGTGGACGAGCTCGTGAAAGT GATGGGCCGGCACAAGCCCGAGAACATCGTGATCGAAATGGCCAGAGAGAA CCAGACCACCCAGAAGGGACAGAAGAACAGCCGCGAGAGAATGAAGCGGAT CGAAGAGGGCATCAAAGAGCTGGGCAGCCAGATCCTGAAAGAACACCCCGT GGAAAACACCCAGCTGCAGAACGAGAAGCTGTACCTGTACTACCTGCAGAA TGGGCGGGATATGTACGTGGACCAGGAACTGGACATCAACCGGCTGTCCGAC TACGATGTGGACCACATCGTGCCTCAGAGCTTTCTGAAGGACGACTCCATCGA CAACAAGGTGCTGACCAGAAGCGACAAGGCCCGGGGCAAGAGCGACAACGT GCCCTCCGAAGAGGTCGTGAAGAAGATGAAGAACTACTGGCGGCAGCTGCTG AACGCCAAGCTGATTACCCAGAGAAAGTTCGACAATCTGACCAAGGCCGAGA GAGGCGGCCTGAGCGAACTGGATAAGGCCGGCTTCATCAAGAGACAGCTGGT GGAAACCCGGCAGATCACAAAGCACGTGGCACAGATCCTGGACTCCCGGATG AACACTAAGTACGACGAGAATGACAAGCTGATCCGGGAAGTGAAAGTGATC ACCCTGAAGTCCAAGCTGGTGTCCGATTTCCGGAAGGATTTCCAGTTTTACAA AGTGCGCGAGATCAACAACTACCACCACGCCCACGACGCCTACCTGAACGCC GTCGTGGGAACCGCCCTGATCAAAAAGTACCCTAAGCTGGAAAGCGAGTTCG TGTACGGCGACTACAAGGTGTACGACGTGCGGAAGATGATCGCCAAGAGCGA GCAGGAAATCGGCAAGGCTACCGCCAAGTACTTCTTCTACAGCAACATCATG AACTTTTTCAAGACCGAGATTACCCTGGCCAACGGCGAGATCCGGAAGCGGC CTCTGATCGAGACAAACGGCGAAACCGGGGAGATCGTGTGGGATAAGGGCC GGGATTTTGCCACCGTGCGGAAAGTGCTGAGCATGCCCCAAGTGAATATCGT GAAAAAGACCGAGGTGCAGACAGGCGGCTTCAGCAAAGAGTCTATCCTGCCC AAGAGGAACAGCGATAAGCTGATCGCCAGAAAGAAGGACTGGGACCCTAAG AAGTACGGCGGCTTCGACAGCCCCACCGTGGCCTATTCTGTGCTGGTGGTGGC CAAAGTGGAAAAGGGCAAGTCCAAGAAACTGAAGAGTGTGAAAGAGCTGCT GGGGATCACCATCATGGAAAGAAGCAGCTTCGAGAAGAATCCCATCGACTTT CTGGAAGCCAAGGGCTACAAAGAAGTGAAAAAGGACCTGATCATCAAGCTG CCTAAGTACTCCCTGTTCGAGCTGGAAAACGGCCGGAAGAGAATGCTGGCCT CTGCCGGCGAACTGCAGAAGGGAAACGAACTGGCCCTGCCCTCCAAATATGT GAACTTCCTGTACCTGGCCAGCCACTATGAGAAGCTGAAGGGCTCCCCCGAG GATAATGAGCAGAAACAGCTGTTTGTGGAACAGCACAAGCACTACCTGGACG AGATCATCGAGCAGATCAGCGAGTTCTCCAAGAGAGTGATCCTGGCCGACGC TAATCTGGACAAAGTGCTGTCCGCCTACAACAAGCACCGGGATAAGCCCATC AGAGAGCAGGCCGAGAATATCATCCACCTGTTTACCCTGACCAATCTGGGAG CCCCTGCCGCCTTCAAGTACTTTGACACCACCATCGACCGGAAGAGGTACAC CAGCACCAAAGAGGTGCTGGACGCCACCCTGATCCACCAGAGCATCACCGGC CTGTACGAGACACGGATCGACCTGTCTCAGCTGGGAGGCGACagcgctGGAGGA GGTGGAAGCGGAGGAGGAGGAAGCGGAGGAGGAGGTAGCggacctaagaaaaagagg aaggtggcggccgctggatccGGACGGGCTGACGCATTGGACGATTTTGATCTGGATATG CTGGGAAGTGACGCCCTCGATGATTTTGACCTTGACATGCTTGGTTCGGATGC CCTTGATGACTTTGACCTCGACATGCTCGGCAGTGACGCCCTTGATGATTTCG ACCTGGACATGCTGATTTAACtgtacgaattcAATAAATAAAAGATCTTTATTTTCAT TAGATCTGTGTGTTGGTTTTTTGTGTGcggaccgagcggccgcaggaacccctagtgatggagttggc cactccctctctgcgcgctcgctcgctcactgaggccgggcgaccaaaggtcgcccgacgcccgggctttgcccgggcggcc tcagtgagcgagcgagcgcgcagctgcctgcaggggcgcctgatgcggtattttctccttacgcatctgtgcggtatttcacacc gcatacgtcaaagcaaccatagtacgcgccctgtagcggcgcattaagcgcggcgggtgtggtggttacgcgcagcgtgacc gctacacttgccagcgccctagcgcccgctcctttcgctttcttcccttcctttctcgccacgttcgccggctttccccgtcaagctct aaatcgggggctccctttagggttccgatttagtgctttacggcacctcgaccccaaaaaacttgatttgggtgatggttcacgtagt gggccatcgccctgatagacggtttttcgccctttgacgttggagtccacgttctttaatagtggactcttgttccaaactggaacaa cactcaaccctatctcgggctattcttttgatttataagggattttgccgatttcggcctattggttaaaaaatgagctgatttaacaaaa atttaacgcgaattttaacaaaatattaacgtttacaatttatggtgcactctcagtacaatctgctctgatgccgcatagttaagcca gccccgacacccgccaacacccgctgacgcgccctgacgggcttgtctgctcccggcatccgcttacagacaagctgtgaccg tctccgggagctgcatgtgtcagaggttttcaccgtcatcaccgaaacgcgcgagacgaaagggcctcgtgatacgcctattttta taggttaatgtcatgataataatggtttcttagacgtcaggtggcacttttcggggaaatgtgcgcggaacccctatttgtttatttttct aaatacattcaaatatgtatccgctcatgagacaataaccctgataaatgcttcaataatattgaaaaaggaagagtatgagtattca acatttccgtgtcgccctattcccttttttgcggcattttgccttcctgttttgctcacccagaaacgctggtgaaagtaaaagatgct gaagatcagtgggtgcacgagtgggttacatcgaactggatctcaacagcggtaagatccttgagagttttcgccccgaagaac gttttccaatgatgagcacttttaaagttctgctatgtggcgcggtattatcccgtattgacgccgggcaagagcaactcggtcgcc gcatacactattctcagaatgacttggttgagtactcaccagtcacagaaaagcatcttacggatggcatgacagtaagagaattat gcagtgctgccataaccatgagtgataacactgcggccaacttacttctgacaacgatcggaggaccgaaggagctaaccgcttt tttgcacaacatgggggatcatgtaactcgccttgatcgttgggaaccggagctgaatgaagccataccaaacgacgagcgtga caccacgatgcctgtagcaatggcaacaacgttgcgcaaactattaactggcgaactactactctagcttcccggcaacaattaa tagactggatggaggcggataaagttgcaggaccacttctgcgctcggcccttccggctggctggtttattgctgataaatctgga gccggtgagcgtgggtctcgcggtatcattgcagcactggggccagatggtaagccctcccgtatcgtagttatctacacgacg gggagtcaggcaactatggatgaacgaaatagacagatcgctgagataggtgcctcactgattaagcattggtaactgtcagacc aagtttactcatatatactttagattgatttaaaacttcatttttaatttaaaaggatctaggtgaagatcctttttgataatctcatgaccaa aatcccttaacgtgagttttcgttccactgagcgtcagaccccgtagaaaagatcaaaggatcttcttgagatcctttttttctgcgcg taatctgctgcttgcaaacaaaaaaaccaccgctaccagcggtggtttgtttgccggatcaagagctaccaactctttttccgaagg taactggcttcagcagagcgcagataccaaatactgtccttctagtgtagccgtagttaggccaccacttcaagaactctgtagca ccgcctacatacctcgctctgctaatcctgttaccagtggctgctgccagtggcgataagtcgtgtcttaccgggttggactcaaga cgatagttaccggataaggcgcagcggtcgggctgaacggggggttcgtgcacacagcccagcttggagcgaacgacctaca ccgaactgagatacctacagcgtgagctatgagaaagcgccacgcttcccgaagggagaaaggcggacaggtatccggtaag cggcagggtcggaacaggagagcgcacgagggagcttccagggggaaacgcctggtatctttatagtcctgtcgggtttcgcc acctctgactgagcgtcgatttttgtgatgctcgtcaggggggcggagcctatggaaaaacgccagcaacgcggcctttttacg gttcctggccttttgctggccttttgctca catgt

In one aspect, the invention provides a precision CAVac. Precision CAVac, or personalized CAVac, is a derivative of CAVac that is customized based on the genetic composition of an individual’s tumor, such as those identified from genomic profiling of a patient’s resected tumor or biopsy. In one aspect, the invention provides an off-the-shelf APCM, which is an approach of endogenous gene activation that targets a small set of genes regardless of patient’s tumor’s genetic identity. In one aspect, the invention provides methods of dual-AAV delivery comprising delivery of any one of the vectors described herein with sgRNAs or sgRNA pools cloned into them, together with the delivery of a second vector (e.g. an AAV-dCas9 vector such as pZB2 EFS-LTR-dCas9 addgene-plasmid- 106430 or pGWOl lb_pAAV-EFS-dCAS9- spA). Compositions comprising said dual-AAV delivery systems and methods of using said dual-delivery systems for treating cancer are also provided with the invention.

Generation of AAV-PCAVac:

I . Patient tumor sequencing For a personalized vaccine, genomic DNA is extracted from each patient’s tumor biopsy, along with matched normal sample such as peripheral blood. The gDNA is subjected to whole-exome sequencing (WES) and/or whole-genome sequencing (WGS). Mutations are identified from WES of tumor sample, and subtracted from matched normal to exclude background and germline variants, and associated to annotated genes. This will produce a personalized tumor mutation panel of genes (Patient-mutation- geneset).

II. Geneset choice This gene set can be further filtered by one or more of the filtering metrics: 1 Select for Immunogenicity, by prediction of immunogenic scores including but not limited to tools such as PVACseq 2 Select against Oncogenecity, by excluding known oncogenes and/or genes amplified in any types of cancer in cancer genomics datasets / databases including but not limited to TCGA, COSMIC, TARGET, cBioPortal. 3 Consider Coding capacity, by choosing coding genes only, or coding and non coding genes

The filtered (Patient-mutation-geneset-filt) or unfiltered gene set (Patient- mutation-geneset) will be subjected to library design. The gene set can be ranging from 1 to 20,000.

III. SgRNA design and library generation 1 SgRNAs are chosen from a pre-defmed sequence list for these genes, or designed ab initio using existing or customized codes. 2 An sgRNA library for each patient is synthesized using pooled oligo synthesis, using individual or commercial vendors including but not limited to Yale/Keck ISP, IDT, Thermofisher, Customarray, Agilent. 3 A synthesized sgRNA library is pool cloned into the AAV-CRISPRa vector, or derivatives, or similar vectors using other effectors, adaptors, Cas enzymes for the same purpose. 4 A cloned library is sequence verified using Sanger and/or Illumina sequencing using custom methods and primers as described herein. 5 Plasmid library is subjected to amplification for viral packaging

IV. Generation of AAV-PCAVac 1 An AAV library is generated by packaging the plasmid library into viral particles using various viral packaging systems including the one described herein 2 An AAV library is purified using methods including the one described herein 3 An AAV library is titered using methods including the one described herein such as qPCR 4 Additional GLP, GMP and/or cGMP methods of AAV production may be adopted

Carriers of the vaccine or personalized vaccine can be AAVs of different serotypes for different tissue-specificity / tropism, including but not limited to natural variants AAV1, AAV2, AAV3, AAV4, AAV5, AAV6, AAV7, AAV8, AAV9, AAV10, AAV11, AAV12, artificial variants such as AAV.rhlO, AAV.rh32/33, AAV.rh43, AAV.rh64Rl, rAAV2-retro, AAV-DJ, AAV-PHP.B, AAV-PHP S, AAV-PHP.eB, or other engineered versions of AAV, other novel AAV variants, or any combinations thereof. The invention should be construed to encompass any type of viral vector known to one of ordinary skill in the art. For example, the carrier of the vaccine or personalized vaccine can be AAV (described herein), but can also be other viral vectors including but not limited to adenovirus, retrovirus, lentivirus, hybrid viral vectors, or any combinations thereof.

Introduction of Nucleic Acids In certain embodiments an expression system is used for the introduction of gRNAs and (d)Cas9 proteins into the cells of interest. Typically employed options include but are not limited to plasmids and viral vectors such as adeno-associated virus (AAV) vector, adenoviral vector or lentivirus vector. Methods of introducing nucleic acids into a cell include physical, biological and chemical methods. Physical methods for introducing a polynucleotide, such as RNA, into a host cell include calcium phosphate precipitation, lipofection, particle bombardment, microinjection, electroporation, and the like. RNA can be introduced into target cells using commercially available methods which include electroporation (Amaxa Nucleofector-II (Amaxa Biosystems, Cologne, Germany)), (ECM 830 (BTX) (Harvard Instruments, Boston, Mass.) or the Gene Pulser II (BioRad, Denver, Colo.), Multiporator (Eppendort, Hamburg Germany). RNA can also be introduced into cells using cationic liposome mediated transfection using lipofection, using polymer encapsulation, using peptide mediated transfection, or using biolistic particle delivery systems such as “gene guns” (see, for example, Nishikawa, et al. Hum Gene Ther., 12(8):86l-70 (2001). Biological methods for introducing a polynucleotide of interest into a host cell include the use of DNA and RNA vectors. Viral vectors have become the most widely used method for introducing genes into mammalian, e.g ., human cells. Other viral vectors can include as listed above. See, for example, U.S. Pat. Nos. 5,350,674 and 5,585,362. Chemical means for introducing a polynucleotide into a host cell include colloidal dispersion systems, such as macromolecule complexes, nanocapsules, microspheres, beads, and lipid-based systems including oil-in-water emulsions, micelles, mixed micelles, and liposomes An exemplary colloidal system for use as a delivery vehicle in vitro and in vivo is a liposome (e g., an artificial membrane vesicle). Lipids suitable for use can be obtained from commercial sources. For example, dimyristyl phosphatidylcholine (“DMPC”) can be obtained from Sigma, St. Louis, MO; dicetyl phosphate (“DCP”) can be obtained from K & K Laboratories (Plainview, NY); cholesterol (“Choi”) can be obtained from Calbiochem-Behring; dimyristyl phosphatidylglycerol (“DMPG”) and other lipids may be obtained from Avanti Polar Lipids, Inc. (Birmingham, AL). Stock solutions of lipids in chloroform or chloroform/methanol can be stored at about -20°C. Chloroform is used as the only solvent since it is more readily evaporated than methanol. “Liposome” is a generic term encompassing a variety of single and multilamellar lipid vehicles formed by the generation of enclosed lipid bilayers or aggregates. Liposomes can be characterized as having vesicular structures with a phospholipid bilayer membrane and an inner aqueous medium. Multilamellar liposomes have multiple lipid layers separated by aqueous medium. They form spontaneously when phospholipids are suspended in an excess of aqueous solution. The lipid components undergo self-rearrangement before the formation of closed structures and entrap water and dissolved solutes between the lipid bilayers

(Ghosh et al., 1991 Glycobiology 5 : 505-10). However, compositions that have different stmctures in solution than the normal vesicular structure are also encompassed. For example, the lipids may assume a micellar structure or merely exist as nonuniform aggregates of lipid molecules. Also contemplated are lipofectamine-nucleic acid complexes. Regardless of the method used to introduce exogenous nucleic acids into a host cell or otherwise expose a cell to the inhibitor of the present invention, in order to confirm the presence of the nucleic acids in the host cell, a variety of assays may be performed. Such assays include, for example, “molecular biological” assays well known to those of skill in the art, such as Southern and Northern blotting, RT-PCR and PCR; “biochemical” assays, such as detecting the presence or absence of a particular peptide, e.g., by immunological means (ELISAs and Western blots) or by assays described herein to identify agents falling within the scope of the invention. Moreover, the nucleic acids may be introduced by any means, such as transducing the cells, transfecting the cells, and electroporating the cells. One nucleic acid may be introduced by one method and another nucleic acid may be introduced into the cell by a different method. RNA In one embodiment, the nucleic acids introduced into the cell are RNA. In another embodiment, the RNA is mRNA that comprises in vitro transcribed RNA or synthetic RNA. The RNA is produced by in vitro transcription using a polymerase chain reaction (PCR)-generated template. DNA of interest from any source can be directly converted by PCR into a template for in vitro mRNA synthesis using appropriate primers and RNA polymerase. The source of the DNA can be, for example, genomic DNA, plasmid DNA, phage DNA, cDNA, synthetic DNA sequence or any other appropriate source of DNA. PCR can be used to generate a template for in vitro transcription of mRNA which is then introduced into cells. Methods for performing PCR are well known in the art. Primers for use in PCR are designed to have regions that are substantially complementary to regions of the DNA to be used as a template for the PCR. “Substantially complementary”, as used herein, refers to sequences of nucleotides where a majority or all of the bases in the primer sequence are complementary, or one or more bases are non complementary, or mismatched. Substantially complementary sequences are able to anneal or hybridize with the intended DNA target under annealing conditions used for PCR. The primers can be designed to be substantially complementary to any portion of the DNA template. For example, the primers can be designed to amplify the portion of a gene that is normally transcribed in cells (the open reading frame), including 5' and 3' UTRs. The primers can also be designed to amplify a portion of a gene that encodes a particular domain of interest. In one embodiment, the primers are designed to amplify the coding region of a human cDNA, including all or portions of the 5' and 3' UTRs. Primers useful for PCR are generated by synthetic methods that are well known in the art. “Forward primers” are primers that contain a region of nucleotides that are substantially complementary to nucleotides on the DNA template that are upstream of the DNA sequence that is to be amplified. “Upstream” is used herein to refer to a location 5, to the DNA sequence to be amplified relative to the coding strand. “Reverse primers” are primers that contain a region of nucleotides that are substantially complementary to a double-stranded DNA template that are downstream of the DNA sequence that is to be amplified. “Downstream” is used herein to refer to a location 3' to the DNA sequence to be amplified relative to the coding strand. Chemical structures that have the ability to promote stability and/or translation efficiency of the RNA may also be used. The RNA preferably has 5' and 3' UTRs. In one embodiment, the 5' UTR is between zero and 3000 nucleotides in length. The length of 5' and 3' UTR sequences to be added to the coding region can be altered by different methods, including, but not limited to, designing primers for PCR that anneal to different regions of the UTRs. Using this approach, one of ordinary skill in the art can modify the 5' and 3' UTR lengths required to achieve optimal translation efficiency following transfection of the transcribed RNA. The 5' and 3' UTRs can be the naturally occurring, endogenous 5' and 3' UTRs for the gene of interest. Alternatively, UTR sequences that are not endogenous to the gene of interest can be added by incorporating the UTR sequences into the forward and reverse primers or by any other modifications of the template. The use of UTR sequences that are not endogenous to the gene of interest can be useful for modifying the stability and/or translation efficiency of the RNA. For example, it is known that AU-rich elements in 3

UTR sequences can decrease the stability of mRNA. Therefore, 3 UTRs can be selected or designed to increase the stability of the transcribed RNA based on properties of UTRs that are well known in the art. In one embodiment, the 5 UTR can contain the Kozak sequence of the endogenous gene. Alternatively, when a 5' UTR that is not endogenous to the gene of interest is being added by PCR as described above, a consensus Kozak sequence can be redesigned by adding the 5' UTR sequence. Kozak sequences can increase the efficiency of translation of some RNA transcripts, but does not appear to be required for all RNAs to enable efficient translation. The requirement for Kozak sequences for many mRNAs is known in the art. In other embodiments the 5' UTR can be derived from an RNA virus whose RNA genome is stable in cells. In other embodiments various nucleotide analogues can be used in the 3' or 5' UTR to impede exonuclease degradation of the mRNA. To enable synthesis of RNA from a DNA template, a promoter of transcription should be attached to the DNA template upstream of the sequence to be transcribed. When a sequence that functions as a promoter for an RNA polymerase is added to the 5' end of the forward primer, the RNA polymerase promoter becomes incorporated into the PCR product upstream of the open reading frame that is to be transcribed. In one embodiment, the promoter is a T7 polymerase promoter, as described elsewhere herein. Other useful promoters include, but are not limited to, T3 and SP6 RNA polymerase promoters. Consensus nucleotide sequences for T7, T3 and SP6 promoters are known in the art. In one embodiment, the mRNA has a cap on the 5' end and a 3' poly(A) tail which determine ribosome binding, initiation of translation and stability mRNA in the cell. On a circular DNA template, for instance, plasmid DNA, RNA polymerase produces a long concatameric product which may not be suitable for expression in eukaryotic cells. The transcription of plasmid DNA linearized at the end of the 3' UTR results in normal sized mRNA which may not be effective in eukaryotic transfection even if it is polyadenylated after transcription. On a linear DNA template, phage T7 RNA polymerase can extend the 3' end of the transcript beyond the last base of the template (Schenbom and Mierendorf, Nuc Acids Res., 13:6223-36 (1985); Nacheva and Berzal-Herranz, Eur. J Biochem., 270:1485-65 (2003). The conventional method of integration of polyA/T stretches into a DNA template is by molecular cloning. However polyA/T sequence integrated into plasmid DNA can cause plasmid instability, which is why plasmid DNA templates obtained from bacterial cells are often highly contaminated with deletions and other aberrations. This makes cloning procedures not only laborious and time consuming but often not reliable. That is why a method which allows construction of DNA templates with polyA/T 3' stretch without cloning highly desirable. The polyA/T segment of the transcriptional DNA template can be produced during PCR by using a reverse primer containing a polyT tail, such as 100T tail (size can be 50-5000 T), or after PCR by any other method, including, but not limited to, DNA ligation or in vitro recombination. Poly(A) tails also provide stability to RNAs and reduce their degradation. Generally, the length of a poly(A) tail positively correlates with the stability of the transcribed RNA. In one embodiment, the poly(A) tail is between 100 and 5000 adenosines. Poly(A) tails of RNAs can be further extended following in vitro transcription with the use of a poly(A) polymerase, such as E. coli polyA polymerase (E-PAP). In one embodiment, increasing the length of a poly(A) tail from 100 nucleotides to between 300 and 400 nucleotides results in about a two-fold increase in the translation efficiency of the RNA. Additionally, the attachment of different chemical groups to the 3' end can increase mRNA stability. Such attachment can contain modified/artificial nucleotides, aptamers and other compounds. For example, ATP analogs can be incorporated into the poly(A) tail using poly(A) polymerase. ATP analogs can further increase the stability of the RNA. 5' caps also provide stability to RNA molecules. In a preferred embodiment, RNAs produced by the methods disclosed herein include a 5' cap The 5' cap is provided using techniques known in the art and described herein (Cougot, et al., Trends in Biochem. Sci., 29:436-444 (2001); Stepinski, et a , RNA, 7:1468-95 (2001); Elango, et al., Biochim. Biophys Res. Commun., 330:958-966 (2005)). The RNAs produced by the methods disclosed herein can also contain an internal ribosome entry site (IRES) sequence. The IRES sequence may be any viral, chromosomal or artificially designed sequence which initiates cap-independent ribosome binding to mRNA and facilitates the initiation of translation. Any solutes suitable for cell electroporation, which can contain factors facilitating cellular permeability and viability such as sugars, peptides, lipids, proteins, antioxidants, and surfactants can be included. In some embodiments, the RNA is electroporated into the cells, such as in vitro transcribed RNA. The methods also provide the ability to control the level of expression over a wide range by changing, for example, the promoter or the amount of input RNA, making it possible to individually regulate the expression level. Furthermore, the PCR-based technique of mRNA production greatly facilitates the design of the mRNAs with different structures and combination of their domains. One advantage of RNA transfection methods of the invention is that RNA transfection is essentially transient and vector-free. A RNA transgene can be delivered to a lymphocyte and expressed therein following a brief in vitro cell activation, as a minimal expressing cassette without the need for any additional viral sequences. Under these conditions, integration of the transgene into the host cell genome is unlikely. Cloning of cells is not necessary because of the efficiency of transfection of the RNA and its ability to uniformly modify the entire lymphocyte population. Genetic modification of cells with in v r -transcri bed RNA (IVT-RNA) makes use of two different strategies both of which have been successively tested in various animal models. Cells are transfected with in -transcribed RNA by means of lipofection or electroporation. It is desirable to stabilize IVT-RNA using various modifications in order to achieve prolonged expression of transferred IVT-RNA. Some IVT vectors are known in the literature which are utilized in a standardized manner as template for in vitro transcription and which have been genetically modified in such a way that stabilized RNA transcripts are produced. Currently protocols used in the art are based on a plasmid vector with the following structure: a 5' RNA polymerase promoter enabling RNA transcription, followed by a gene of interest which is flanked either 3' and/or 5' by untranslated regions (UTR), and a 3' polyadenyl cassette containing 50-70 A nucleotides. Prior to in vitro transcription, the circular plasmid is linearized downstream of the polyadenyl cassette by type II restriction enzymes (recognition sequence corresponds to cleavage site). The polyadenyl cassette thus corresponds to the later poly(A) sequence in the transcript. As a result of this procedure, some nucleotides remain as part of the enzyme cleavage site after linearization and extend or mask the poly(A) sequence at the 3' end. It is not clear, whether this nonphysiological overhang affects the amount of protein produced intracellularly from such a construct. RNA has several advantages over more traditional plasmid or viral approaches. Gene expression from an RNA source does not require transcription and the protein product is produced rapidly after the transfection. Further, since the RNA has to only gain access to the cytoplasm, rather than the nucleus, and therefore typical transfection methods result in an extremely high rate of transfection. In addition, plasmid based approaches require that the promoter driving the expression of the gene of interest be active in the cells under study. In another aspect, the RNA construct is delivered into the cells by electroporation. See, e g., the formulations and methodology of electroporation of nucleic acid constructs into mammalian cells as taught in US 2004/0014645, US 2005/0052630A1, US 2005/0070841 Al, US 2004/0059285A1, US 2004/0092907A1. The various parameters including electric field strength required for electroporation of any known cell type are generally known in the relevant research literature as well as numerous patents and applications in the field. See e.g., U.S. Pat. No. 6,678,556, U.S. Pat. No. 7,171,264, and U.S. Pat. No. 7,173,116. Apparatus for therapeutic application of electroporation are available commercially, e.g., the MedPulser™ DNA Electroporation Therapy System (Inovio/Genetronics, San Diego, Calif.), and are described in patents such as U.S. Pat. No. 6,567,694; U.S. Pat. No. 6,516,223, U.S. Pat. No. 5,993,434, U.S. Pat. No. 6,181,964, U.S. Pat. No. 6,241,701, and U.S. Pat. No 6,233,482; electroporation may also be used for transfection of cells in vitro as described e.g. in US20070128708A1. Electroporation may also be utilized to deliver nucleic acids into cells in vitro. Accordingly, electroporation-mediated administration into cells of nucleic acids including expression constructs utilizing any of the many available devices and electroporation systems known to those of skill in the art presents an exciting new means for delivering an RNA of interest to a target cell.

Sources of Cells In one embodiment, cells are obtained from a subject. Non-limiting examples of subjects include humans, dogs, cats, mice, rats, pigs and transgenic species thereof. Preferably, the subject is a human. Cells can be obtained from a number of sources, including peripheral blood mononuclear cells, bone marrow, lymph node tissue, spleen tissue, umbilical cord, cancer cells and tumors. In certain embodiments, any number of cell lines available in the art, may be used. In certain embodiments, cells can be obtained from a unit of blood collected from a subject using any number of techniques known to the skilled artisan, such as Ficoll separation. In one embodiment, cells from the circulating blood of an individual are obtained by apheresis or leukapheresis. The apheresis product typically contains lymphocytes, including T cells, monocytes, granulocytes, B cells, other nucleated white blood cells, red blood cells, and platelets. The cells collected by apheresis may be washed to remove the plasma fraction and to place the cells in an appropriate buffer or media, such as phosphate buffered saline (PBS) or wash solution lacks calcium and may lack magnesium or may lack many if not all divalent cations, for subsequent processing steps. After washing, the cells may be resuspended in a variety of biocompatible buffers, such as, for example, Ca-free, Mg-free PBS. Alternatively, the undesirable components of the apheresis sample may be removed and the cells directly resuspended in culture media. In another embodiment, cells are isolated from peripheral blood. Alternatively, cells can be isolated from umbilical cord. In any event, a specific subpopulation of cells can be further isolated by positive or negative selection techniques. Cells can also be frozen. While many freezing solutions and parameters are known in the art and will be useful in this context, in a non-limiting example, one method involves using PBS containing 20% DMSO and 8% human serum albumin, or other suitable cell freezing media. The cells are then frozen to -80°C at a rate of 1° per minute and stored in the vapor phase of a liquid nitrogen storage tank. Other methods of controlled freezing may be used as well as uncontrolled freezing immediately at -20°C or in liquid nitrogen. Pharmaceutical compositions Pharmaceutical compositions of the present invention may comprise the modified cell as described herein, in combination with one or more pharmaceutically or physiologically acceptable carriers, diluents or excipients. Such compositions may comprise buffers such as neutral buffered saline, phosphate buffered saline and the like; carbohydrates such as glucose, mannose, sucrose or dextrans, mannitol; proteins; polypeptides or amino acids such as glycine; antioxidants; chelating agents such as EDTA or glutathione; adjuvants (e.g., aluminum hydroxide); and preservatives. Compositions of the present invention are preferably formulated for intravenous administration. Pharmaceutical compositions of the present invention may be administered in a manner appropriate to the disease to be treated (or prevented). The quantity and frequency of administration will be determined by such factors as the condition of the patient, and the type and severity of the patient’s disease, although appropriate dosages may be determined by clinical trials. It can generally be stated that a pharmaceutical composition comprising the modified cells described herein may be administered at a dosage of 104 to 109 cells/kg body weight, in some instances 10 5 to 106 cells/kg body weight, including all integer values within those ranges. Compositions of the invention may also be administered multiple times at these dosages. The cells or vectors can be administered by using infusion techniques that are commonly known in immunotherapy (see, e.g., Rosenberg et al., New Eng. J. of Med. 319:1676, 1988). The optimal dosage and treatment regime for a particular patient can readily be determined by one skilled in the art of medicine by monitoring the patient for signs of disease and adjusting the treatment accordingly. The administration of the modified cells or vectors of the invention may be carried out in any convenient manner known to those of skill in the art. The cells or vectors of the present invention may be administered to a subject by aerosol inhalation, injection, ingestion, transfusion, implantation or transplantation. The compositions described herein may be administered to a patient transarterially, subcutaneously, intradermally, intratumorally, intranodally, intramedullarly, intracystically intramuscularly, by intravenous (i.v.) injection, parenterally or intraperitoneally. In other instances, the cells of the invention are injected directly into a site of inflammation in the subject, a local disease site in the subject, a lymph node, an organ, a tumor, and the like. It should be understood that the method and compositions that would be useful in the present invention are not limited to the particular formulations set forth in the examples. The following examples are put forth so as to provide those of ordinary skill in the art with a complete disclosure and description of how to make and use the cells, expansion and culture methods, and therapeutic methods of the invention, and are not intended to limit the scope of what the inventors regard as their invention. The practice of the present invention employs, unless otherwise indicated, conventional techniques of molecular biology (including recombinant techniques), microbiology, cell biology, biochemistry and immunology, which are well within the purview of the skilled artisan. Such techniques are explained fully in the literature, such as, “Molecular Cloning: A Laboratory Manual”, fourth edition (Sambrook, 2012); “Oligonucleotide Synthesis” (Gait, 1984); “Culture of Animal Cells” (Freshney, 2010); “Methods in Enzymology” “Handbook of Experimental Immunology” (Weir, 1997); “Gene Transfer Vectors for Mammalian Cells” (Miller and Calos, 1987); “Short Protocols in Molecular Biology” (Ausubel, 2002); “Polymerase Chain Reaction: Principles, Applications and Troubleshooting”, (Babar, 2011); “Current Protocols in Immunology” (Coligan, 2002). These techniques are applicable to the production of the polynucleotides and polypeptides of the invention, and, as such, may be considered in making and practicing the invention. Particularly useful techniques for particular embodiments will be discussed in the sections that follow.

EXPERIMENTAL EXAMPLES The invention is now described with reference to the following Examples These Examples are provided for the purpose of illustration only, and the invention is not limited to these Examples, but rather encompasses all variations that are evident as a result of the teachings provided herein. The materials and methods employed in these experiments are now described. Lentiviral SAM library production: Mouse CRISPR activation plasmid libraries (lenti-U6-mSAM-EFS-Puro) were expanded by electroporation (Konermann etal. (2015) Nature 517, 583-588). An estimated library coverage of >100x (>100 colonies per sgRNA) was achieved in electroporation, and the coverage of sgRNAs was subsequently sequence-verified by Illumina sequencing For lentivirus production, 20 g of plasmids of lenti-EFla-NLS-dCas9-VP64-P2A-Blast, lenti-EFla-MS2-p65-HSFl-P2A-Hygro or lenti-U6-SAM-EFS-Puro library, together with 10 pg of pMD2.G and 15 pg of psPAX2 were co-transfected into HEK293FT cells in 150mm-dish at 80-90% confluency using 130 pg polyethyleneimine (PEI) as the transfection reagent. 6-12 hours later, the media was replaced by fresh DMEM+10%FBS. Virus supernatant was collected 48 h and 72 h post-transfection, centrifuged at 1500 g for 10 min and passed through 0.45-pm filter to remove the cell debris; aliquoted and stored at -80°C. Virus was titrated by infecting E0771 cells followed by the selection under 5 g/ml puromycin. Generation of cell-based A Vac: E0771 cells stably expressing dCas9-VP64 and MS2-P65-HSF1 (E0771-dCas9-MPH) were generated by transducing lentiviruses containing lenti-EFla-NLS-dCas9-VP64-2A-Blast and lenti-EFla-MS2-p65-HSFl-2A- Hygro into E0771 cells, followed by 7 days of selection under the pressure of 10 pg/ml blasticidin and 500 pg/ml hygromycin. Then, the E077l-dCas9-MPFl cells were transduced with mSAM-library -containing lentiviruses at an MOI of 0.2-0.3, with a minimal representation of 200x transduced cells per sgRNA as described previously

(Konermann etal. (2015) Nature 517, 583-588). Briefly, 1 x 108 cells were infected by lib-containing viruses at a calculated MOI of 0.2 and cultured at 37°C more than 1 day before replacing with 5 pg/ml puromycin containing media, and the transduced cells were drug-selected for 7 days before using. Sequencing confirmation of SAM sgRNA library representation: Library transduced cells were subjected to genomic DNA (gDNA) extraction using standard molecular biology protocols. The sgRNA library readout was performed using a two-step PCR strategy, where the first PCR includes enough genomic DNA to preserve full library complexity and the second PCR adds appropriate sequencing adapters to the products from the first PCR. PCR1 primers: Forward: AATGGACTATCATATGCTTACCGTAACTTGAAAGTATTTCG(SEQ ID NO: 23,777) Reverse: CTTTAGTTTGTATGTCTGTTGCTATTATGTCTACTATTCTTTCCC (SEQ ID NO: 23,778) PCR was performed using Phusion Flash High Fidelity Master Mix (PF) or DreamTaq Green PCR Master Mix (DT) (ThermoFisher). For reactions using PF, in PCR#1, the thermocycling parameters were: 98 °C for 1 min, 16-20 cycles of (98 °C for

Is, 62 °C for 5s, 72 °C for 30 s), and 72 °C for 2 min. For reactions using DT, the thermocycling parameters were adjusted according to manufacturer’s protocol In each PCR#1 reaction, 3 pg of total gDNA was used. A total of 8 to 12 of PCR# 1 reactions was used to capture the full representation of the library in the cells. PCR#1 products for each biological sample were pooled and used for amplification with barcoded second PCR primers. Barcoding second PCR primers used: SF5: AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACGCTCTTCCGATCT TCGATCGTTACCATCTTGTGGAAAGGACGAAACACCG (SEQ ID NO: 24, 107)

SF6: AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACGCTCTTCCGATCT ATCGATTCCTTGGTTCTTGTGGAAAGGACGAAACACCG (SEQ ID NO: 24,108)

SRI : CAAGCAGAAGACGGCATACGAGATAAGTAGAGGTGACTGGAGTTCAGACGTGTGCTC TTCCGATCTTTCTACTATTCTTTCCCCTGCACTGT (SEQ ID NO: 24,109)

SR2 : CAAGCAGAAGACGGCATACGAGATACACGATCGTGACTGGAGTTCAGACGTGTGCTC TTCCGATCTATTCTACTATTCTTTCCCCTGCACTGT (SEQ ID NO: 24,110)

SR3 : CAAGCAGAAGACGGCATACGAGATCGCGCGGTGTGACTGGAGTTCAGACGTGTGCTCTT CCGATCTGATTCTACTATTCTTTCCCCTGCACTGT (SEQ ID NO: 24,1111)

SR4 : CAAGCAGAAGACGGCATACGAGATCATGATCGGTGACTGGAGTTC AGACGTGTGCTC TTCCGATCTCGATTCTACTATTCTTTCCCCTGCACTGT (SEQ ID NO: 24, 112)

SR5 : CAAGCAGAAGACGGCATACGAGATCGTTACCAGTGACTGGAGTTCAGACGTGTGCTC TTCCGATCTCGATCTCTACTATTCTTTCCCCTGCACTGT (SEQ ID NO: 24,1 13)

SR6: CAAGCAGAAGACGGCATACGAGATTCCTTGGTGTGACTGGAGTTCAGACGTGTGCTCT TCCGATCTTTCTACTATTCTTTCCCCTGCACTGT (SEQ ID NO: 24,1 14)

For reactions using PF, in PCR#2, the thermocycling parameters were: 98 °C for lmin, 18-24 cycles of (98 °C for Is, 60 °C for 5s, 72 °C for 30s), and 72 °C for 2 min. Second PCR products were pooled and then normalized for each biological sample before combining uniquely barcoded separate biological samples. The pooled product was then gel purified from a 2% E-gel EX (Life Technologies) using the QiaQuick kit (Qiagen). The purified pooled library was then quantified with a gel-based method using the Low- Range Quantitative Ladder Life Technologies, dsDNA High-Sensitivity Qubit (Life Technologies), BioAnalyzer (Agilent) and/or qPCR. Diluted libraries with 5-20% PhiX were sequenced with MiSeq, HiSeq 2500 or HiSeq 4000 systems (Illumina). Raw single-end fastq read files were filtered and demultiplexed using Cutadapt (Martin etal. (201 1) EMBnet.journal 17, 10-12). To remove extra sequences downstream (i.e. 3 ’ end) of the sgRNA spacer sequences, the following settings were used: cutadapt — discard-untrimmed -a GTTTTAGAGCTAGGCCAAC (SEQ ID NO: 24, 115). As the forward PCR primers used to readout sgRNA representation were designed to have a variety of barcodes to facilitate multiplexed sequencing, these filtered reads were then demultiplexed with the following settings: cutadapt -g file:fbc fasta -no-trim, where fbc.fasta contained the 12 possible barcode sequences within the forward primers. Finally, to remove extra sequences upstream (i.e. 5’ end) of the sgRNA spacers, the following settings were used: cutadapt —discard-untrimmed - g GTGGAAAGGACGAAACACCG (SEQ ID NO: 24, 116). Through this procedure, the raw fastq read files could be pared down to the 20bp sgRNA spacer sequences. These 20 bp sgRNA spacer sequences from each demulitplexed sample were mapped the sgRNA spacers to the mSAM library using Bowtie 1.1.2 (Langmead etal. (2009) Genome Biol 10, R25): bowtie -v 1 —suppress 4,5,6,7 —chunkmbs 2000 -best. Using the resultant mapping output, the number of reads that had mapped to each sgRNA within the library were quantitated. To count sgRNA representation, a detection threshold of logirpm > 1 was set and the number of unique sgRNAs present in each sample was counted. Mice: All animal work was approved by IACUC and performed with approved protocols. Mice of both sexes, between 5-12 weeks of age were used for the study Various animals were used in this study. 5-10 week old C57BL/6J mice were used for experiments. Female mice were used for breast cancer models. Male mice were used for pancreatic adenocarcinoma (Pan02) models. A mix of both male and female mice were used for melanoma (B16F10) models. All animals were housed in standard individually ventilated, pathogen-free conditions, with 12h: 12h or 13h: 11h light cycle, room temperature (21-23°C) and 40-60% relative humidity. Sample size was determined based on number of animals used. Prior estimation of number of mice used was estimated based on similar tumor models in the field. When a cohort of animals receive multiple treatments, animals were randomized by 1) randomly assign animals to different groups using littermates, 2) random mixing of females prior to treatment, maximizing the evenness or representation of mice from different cages in each group, and/or 3) random assignment of mice to each group, in order to minimize the effect of litter, small difference in age, cage, housing position, where applicable. Tumorigenesis ofE0771-SAM in C57BL/6J, Nu/Nu, or Rugl mice: 5 x 106 of E0771-SAM or E0771-Vector tumor cells were injected into the orthotopic mammary fat pad of syngeneic 5-8 weeks old female C57BL/6J mice, Nu/Nu, or Ragf ~mice. Tumor sizes were measured every 3-4 days by caliper on the three diameters, and sizes were calculated as approximate spheroids with the formula: Vol = π/6 *x*y*z. Statistical significance of all tumor growth curves in the study was assessed by analysis of variance (2-way ANOVA), jointly considering the effect of treatment and the passage of time on tumor growth. For CD4 and CD8 T cell depletion, 200 ug a-CD4 (GK1.5, BioXcell) and 200 ug a-CD8 (YTS 169.4) were intraperitoneally injected into tumor-transplanted C57BL/6J mice at dpi 7 and dpi 14 to block the effect of T cells at an early stage of tumorigenesis. The successful depletion of CD8 T cells was confirmed by isolating PBMCs from mice at dpi 14 and 2 1 and analyzing the CD8+ T cell population with flow cytometry. Generation of cell-based MAEGI: Cell-based MAEGI (c-MAEGI) was produced by treating E0771-SAM cells (described above) with 10 ug/ml mitomycin for more than 2 hrs to restrain their proliferation ability while maintaining cellular integrity. In parallel, mitomycin-treated E077l-Vector (referred to as mock Cell-Vector) was used as control. The therapeutic effects of heat-inactivated lysates of the same numbers of E0771-mSAM and E0771-Vector cells were also used for comparison. Heat induced cell lysis of E0771 and c-MAEGI was performed by incubation at 65°C for 30 minutes followed by 3 freezing-thaw cycles, lysing the cells and disrupting the integrity of peptide-MHC complexes on the cell surface. Prophylactic application of CA Vac (c-MAEGI) in syngeneic tumor models: 5 x

106 mSAM-transduced E0771 tumor cells were injected orthotopically into mammary fatpad of syngeneic 5-8 weeks old female C57BL/6J mice. 3, 7, or 14 days after CAVac inoculation, 5 x 106 E0771 tumor cells were transplanted into the mammary fatpad in C57BL/6J mice. For the challenges with tumors derived from different cells of origin, 5 x 106 LCC cells were injected subcutaneously into flank of E077l-CAVac vaccinated C57BL/6J mice. The growth of tumors was continuously monitored and measured by caliper, twice per week Statistical significance was assessed by paired /-test and/or analysis of variance (ANOVA) where applicable. Therapeutic effects of CA Vac (c-MAEGI) in syngeneic tumor models:

Syngeneic orthotopic breast tumors were established by transplanting 2 x 106 or 5 x 10 E0771 cells into the mammary fatpad of 5-8 weeks old female C57BL/6J mice. 4, 8 and

14 days after transplantation, therapeutic CAVac made using 5 x 106- 1 x 107 mSAM- transduced E0771 cells was s.c. injected into left flank of tumor-bearing mice. Tumors were measured every 3-4 days using caliper and sizes were calculated with the formula: Vol = π/6 *x*y*z. Generation of AA V-CAVac (AA V-basedMAEGI): An AAV version of the CRISPR activation vector (AAV-CRISPRa vector, i.e. U6p-sgSapI-EFla-MS2-p65- HSF1-WPRE), and an AAV version of dCas9 vector (AAV-dCas9, i.e. EFS-dCas9- VP64-spA), were generated by restriction cloning and Gibson assembly. The sgRNA libraries of mSAM were cloned into the above CRISPRa plasmid by linearization with Sapl digestion and Gibson assembly. The purification and electroporation of Gibson products into Endura electrocompetent cells were performed as previously described (Joung, et al. (2017) Nat Protoc 12, 828-863), with at least lOOx coverage of colonies represented per sgRNA. AAV9 was produced by co-transfecting HEK293FT cells with above AAV plasmids of CRISPR activation vector or library (AAV-mSAM), AAV9 serotype plasmid and helper plasmid PDF6. Briefly, 5.2 g of AAV-vector or AAV- mSAM, 8.7 pg of AAV9 serotype plasmid and 10.4 pg of pDF6 were mixed with PEI, room temperature 10 min before drop-wisely adding them into HEK293FT cells in 150 mm-dish at 80-90% confluency. Replicates collected from multiple dishes were pooled to enhance production yield. Cells were collected 72 h post transfection. For AAV9 purification, 1/10 volume of chloroform was added and the mixture was vigorously shaken for 1 h at 37°C. NaCl was added to a final concentration of 1 M and the mixture was shaken until dissolved and then pelleted at 20,000 g at 4°C for 15 min. The aqueous layer was discarded while the chloroform layer was transferred to another tube. PEG8000 was added to 10% (w/v) and shaken until dissolved. The mixture was incubated at 4°C for 1 h and then spun at 20,000 g at 4°C for 15 min. The supernatant was discarded and the pellet was resuspended in DPBS plus Mg ' and treated with Benzonase (Sigma) and incubated at 37°C for 30 min. Chloroform ( 1:1 volume) was then added, shaken, and spun down at 12,000 g at 4°C for 15 min. The aqueous layer was isolated and passed through a 100 kDa MWCO (Millipore). The concentrated solution was washed with PBS and the filtration process was repeated. Genomic copy number (GC) of AAV was determined by real-time quantitative PCR using custom Taqman assays (ThermoFisher) targeted to the engineered U6 promoter. Combinatorial therapy using CA Vac (c-MAEGI) and monoclonal antibodies: To check the synergistic effect between therapeutic CAVac (c-MAEGI) and immune checkpoint blockade or CD4 depletion, 5 mg/kg anti-CTLA4 monoclonal antibody (9D9, BioXcell), 8 mg/kg anti-PD 1 monoclonal antibody (RMP1-14, BioXcell) or 200 pg per mouse anti-CD4 antibody (GK1.5, BioXcell) were administrated by i.p. injection at day 7 and day 14 with or without CAVac vaccination as described elsewhere herein. Two-way ANOVA was used to compare growth curves between treatment groups. Tumor re- challenge was done by injecting 5 x 106 E0771 cells into the contralateral fatpad of mice underwent complete response. ELISPOT assay: IFN-γ ELISPOT mouse kits (BD Biosciences) were used according to the manufacturer's instructions. Briefly, 96-well filtration plates were coated overnight at 4°C with capturing monoclonal antibody; the plates were then washed and blocked with RPMI-1640 medium containing 10% FBS for 2 h at room temperature

Splenocytes in RPMI-1640 ( 1 x 106 cells/well) were then added, and 5 x 104 mitomycin- treated E0771 cells was subsequently added as the stimulation antigen; the plates were cultured for approximately 45 hours at 37°C and 5% CO2. After washing once with DI water and three times with PBST, the plates were incubated with biotinylated detection antibody at room temperature for 2 h . Then, plates were incubated with HRP-conjugated streptavidin at room temperature for 1 h after washing three times with PBST. Spots were revealed using an AEC substrate reagent kit (BD Bioscience) at room temperature and counted using an Immunospot Reader (Cellular Technology). Therapeutic testing of AAV-CAVac (g-MAEGI) in syngeneic tumor models:

Syngeneic orthotopic breast tumors were established by transplanting 2 x 106 E0771- dCas9-VP64 cells into the mammary fatpad of 5-8 weeks old female C57BL/6J mice. 4,

10, 14, and 2 1 days after transplantation, 2-5 x 10 10 GCs of AAV-CAVac or PBS were injected intratumorally to tumor-bearing mice. For the B16F10 melanoma model, 5 x 105 dCas9-VP64 expressing cancer cells were injected subcutaneously into the flank of

C57BL/6J mice. 7, 10, 14, and 20 days after transplantation, 5-10 x 10 1 GCsof AAV- CAVac (AAV-g-MAEGI), AAV-Vector, or PBS were intratumorally administrated into tumor-bearing mice. For the pancreatic tumor model, 2 x 106 Pan02 cancer cells were injected subcutaneously into the flank of C57BL/6J mice. 5, 13, 21, and 35 days after transplantation, 5-10 x 10 10 GCs of AAV-CAVac or PBS were intratumorally administrated into tumor-bearing mice. Tumors were measured every 3-4 days using caliper and sizes were calculated with the formula: Vol = π/6 *x*y*z. Splenocytes and tumor infiltrating lymphocyte isolation: Syngeneic breast tumors were established by transplanting 2 x 106 E0771 cells into the mammary fatpad of 5-8 weeks old female C57BL/6J mice. Tumor-bearing mice were randomly assembled into different treatment group and treated with PBS, CAVac, ICB monoclonal antibodies, CAVac + ICB antibodies accordingly. Mice were euthanized 35 days’ post transplantation, tumors and spleens were collected and kept in ice-cold 2% FBS For spleens, they were placed in ice-cold 2% FBS and mashed through a 100 pm filter. Splenocytes were washed once with 2% FBS. RBCs were lysed with 1 ml of ACK Lysis Buffer (Lonza) per spleen by incubating 2 mins at room temperature, which was followed by the dilution with 10 ml 2% FBS and pass through a 40 pm filter. Splenocytes were resuspended in 2% FBS buffer, counted for flow cytometry staining or RNA isolation. Tumors were minced into 1-3 mm size pieces using scalper and then digested using 100 U/mL Collagenase IV for 30-60 min while stirred at 37°C. Tumor suspensions were filtered twice through 100 pm cell strainer, and once through 40 pm cell strainer to remove large bulk. Subsequently, single cell suspensions can be directly used for FACS staining, or further Ficoll purification to obtain tumor-infiltrating lymphocytes. For Ficoll-Paque purification, single cell suspensions at density of (~107 cells/ml) were carefully layered onto Ficoll-Paque media (GE Healthcare) and centrifuge at 400g for 30 min. Cells at the interface were carefully collected, and washed twice with 2% FBS, counted, and used for RNA isolation or flow cytometry staining. Flow cytometry: All antibodies were purchased from Biolegend. Single cell suspensions from tumors or spleens were prepared as previous described. For surface staining, cells were blocked with anti-Fc receptor anti-CD16/CD32 and surface stained with anti-CD45.2-APC/Cy7, anti-CD3-PE, anti-CD4-FITC, anti-CD8a-APC, in PBS+2%FBS on ice for 30 min. Samples were washed twice with PBS+2%FBS before analyzed or sorted on a BD FACSAria. The data was analyzed using FlowJo software on a MAC® workstation. Fluorescence-activated cell sorting (FACS) isolation of CD45+ cellsfrom tumors: Single tumor cell suspensions were prepared using the gentleMACS system with the method described in “Splenocytes and tumor infiltrating lymphocyte isolation”. Tumor cells were blocked using anti-Fc receptor anti-CD16/CD32. Live cells were distinguished from dead cells in flow cytometry by staining with LIVE/DEAD™ Fixable Near-IRDead Cell Stain Kit following manufacturer’s instructions. Cells at a density of l 07/ml were stained with DMSO dissolved live/dead staining dye and PerCP/Cy5.5 or APC conjugated CD45 antibody in PBS+2% FBS, and incubated on ice for 30 min Stained cells were washed three times before being analyzed and FACS isolated on a BD FACSAria. Tumor-infiltrating CD45+ pan-immune cells (TIICs) were isolated by gating on PerCP/Cy7+APC/Cy7 or APC+APC/Cy7 populations. Sorted TIICs were counted, and used for scRNAseq and ELISpot analysis. Immune cellprofiling by single-cell RNA-seq: Single cell suspensions from tumors were prepared as previously described. For CD45+ cell isolation, cells were blocked with anti-Fc receptor anti-CD16/CD32 and surface stained with anti-CD45.2 in PBS+2%FBS on ice for 30 min. Samples were washed twice with PBS+2%FBS, and CD45 cell populations in tumors were FACS sorted using a BD FACSAria. Sorted cells were collected in PBS+2%FBS, cell numbers and viabilities were assessed by trypan blue staining and counting in Countess II FL Automated Cell Counter (Thermo). 10,000 CD45+ cells isolated from tumors were used for single-cell RNAseq by following the protocol from lOx Genomics. Single cell RNA-seq data processing: Pan-immune cell scRNA-seq data was pre- processed using established and custom pipelines. Briefly, raw Illumina data files were processed by Cell Ranger 1.3 (lOx Genomics) (Zheng, etal. (2017) Nat Commun 8, 14049), using cellranger mkfastq to wrap Illumina's bcl2fastq to correctly demultiplex sequencing samples and to convert barcode and read data to FASTQ files. Then, cellranger count was used to take FASTQ files and perform alignments to the mouse genome (mmlO) (Dobin, et al. (2013) Bioinformatics 29, 15-21), filtering, and UMI counting. Using Seurat (Butler & Satija (2017) bioRxiv), cells passing the initial quality control metrics imposed by the Cell Ranger pipeline were further filtered by excluding all cells in which mitochondrial genes disproportionately comprised the total % of the library (empirically determined cutoff of 5% mitochondrial reads). With this filter, a final set of 7,458 cells was retained for further analysis (from initial of 7,492 cells). After log normalization, the 27,998 genes/features were filtered using a flat cutoff metric such that genes with low variance were excluded, leaving 1267 genes. The data were then scaled based on UMI total counts and the % of mitochondrial reads. Using the final normalized and processed dataset above, t-S E dimension reduction was performed (Maaten & Hinton (2008)7! Mach. Learn. Res. 9, 2579-2605; Maaten (2014)./. Mach. Learn. Res. 15, 3221-3245). Individual data points were colored based on the treatment condition for each cell, or based on unbiased k-means clustering performed in Seurat. Differential expression analyses between clusters and/or treatment conditions was performed by nonparametric Wilcoxon rank sum test. Multiple hypothesis correction was performed by the Benjamini-Hochberg method. Significantly differentially expressed genes were defined as having a Benjamini-Hochberg adjusted p < 0.05. RNA extraction, reverse transcription, and quantitative PCR: RNA in cells, splenocytes, and tumor infiltrating lymphocytes were extracted using TRIzol Reagent (Invitrogen) by following standard RNA extraction protocols. The first-strand cDNA of RNA was synthesized using Superscript™ IV Reverse Transcriptase (Invitrogen). After normalizing the concentrations of cDNA with nuclease-free water, quantitative PCR (qPCR) was performed by adding designated Taqman probe of interested genes, and GAPDH was used as an internal positive control. Western Blot: E0771, E0771-dCas9-VP64, and E0771-dCas9-VP64-MPH cells in 6-well plate were washed twice with ice cold PBS before lysis with 1x RIPA buffer which was kept on ice for 15 min. Cell lysates were centrifuged at 12,000 g for 15 min at 4°C and protein-containing supernatant was collected. Protein concentration was measured using a standard Bradford assay (BioRad) and 20 g of protein in each sample were loaded into SDS-PAGE gel. After electrophoresis, proteins separated in gel were transferred into nitrocellulose membranes. Membranes were blocked at room temperature for 1 h using 5% skim-milk in TBST, followed by the incubation with primary antibody in 4°C overnight. After washing three times with TBST, horseradish peroxidase (HRP)- conjugated secondary antibody was added and incubated at room temperature for 30 - 60 min. The chemiluminescent substrate (Clarity Western ECL Substrate, Bio-Rad) was added on top of blot membrane according to the manufacturer’s instructions. The signals were captured using a CCD camera-based imager (GE Healthcare). Histology and immunohistochemistry: At matched time points, tumors from different treatment group were collected and fixed in 10% neutral formalin for 2-5 days. Tissues were transferred into 70% ethanol for long-term storage Haematoxylin and eosin (H&E) staining or antibody staining were performed on 3-5 pm tissue sections using standard procedures. T cell receptor sequencing (TCR-seq): Mice in different treatment groups were euthanized at 30-40 days’ post-transplantation. Tumors and spleens were collected and kept in ice-cold 2% FBS before use. Single cell suspensions from tumors or spleens were prepared as previous described. The RNA from collected splenocytes and TELs were extracted using Trizol according to manufacturer’s instructions. TCR-seq data analysis: Raw fastq files from TCR-seq were processed to clonotypes using MiXCR following the author recommendations for 5 ’ RACE-based library protocols (Bolotin, etal. (2015) Nat Methods 12, 380-381). Specifically, the mixer align function was first used to align to the V segment transcript, followed by clonotype assembly using mixer assemble and mixer exportClones. Subsequently, TCR-seq data were analyzed using the tcR package (Nazarov, et al. (2015) BMC Bioinformatics 16, 175) to determine clonal proportions and occupied clonal homeostasis in each sample. Metrics of diversity were calculated using ecological diversity, Gini-Simpson, and Chao indices. Exome sequencing of E0771 and identification of all genic mutational spectrum: E0771 cells and freshly-dissected mammary fatpad from healthy, untreated 6- 8wk old female C57BL/6J mice were subjected to gDNA extraction following standard protocol. A total of 2 g of gDNA per sample were subjected to exome capture using mouse exome probes (Roche) and then Illumina library preparation following manufacturer’s protocols. Exome capture paired-end fastq files were mapped to the mmlO genome using Bowtie v2.2.9 (Langmead etal. (2009) Genome Biol 10, R25), and sorted by Samtools (Li et al. (2009) Bioinformatics 25, 2078-2079). VarScan v2.3.9 (Koboldt, D . C . et al. (2012) Genome Res 22, 568-576) was then used in somatic mode to call indels and SN s that were specific to E0771 cells and not found in wildtype C57BL/6J mammary fatpad tissue. Germline calls were subsequently filtered out. The remaining variants were collapsed to the gene level, and the number of indels or SNPs for each gene was tabulated. Generation of mutational spectrum guided precision AA V-CAVac (AA V- PCAVac/AAV-p-MAEGI): Genes were ranked by their number of somatic variants present in E0771 cells but not in healthy mammary fatpad. A set of 1,1 16 top mutated genes were chosen as differentially mutated genes in E0771 and 3 sgRNAs per gene (for the majority of genes) targeting promoter regions were chosen. A CRISPRa library consisting of 3,839 sgRNAs (SEQ ID NOs: 349-4,187) were designed for the E0771 top mutated gene set, pool-synthesized (Customarray), and cloned into the AAV-CRISPRa vector above. AAV library packaging was done as above to generate AAV-PCAVac for E0771. Therapeutic testing of AAV-PCAVac (p-MAEGI): Syngeneic TNBC were established by orthotopic transplantation of 2 x 106 E0771 cells into the mammary fat pad of 5-8 weeks old female C57BL/6J mice. 5, 12 and 18 days after tumor induction, 5 x

10 10 - 1 x 10 11 GCsof AAV-CAVac, AAV-Vector, or PBS were intratumorally administrated into tumor-bearing mice For testing of the abscopal effect, syngeneic

TNBC were established by orthotopic transplantation of 2 x 106 E0771 cells into an ipsilateral mammary fat pad, and 2.5 x 105 E0771 cells into the contralateral mammary fat pad. 4, 11, 18 and 24 days after tumor induction, 5 x 10 10 - 1 x 10 GCsof AAV-p- MAEGI or AAV-Vector were intratumorally administrated into the ipsilateral tumor. Tumors were measured every 3-4 days using caliper and sizes were calculated with the formula: Vol = π/6 *x*y*z. Two-way ANOVA was used to compare growth curves between treatment groups. Response to therapy was defined by a method similar to RECIST 1.1 criteria (CR, complete response, where endpoint tumor size = 0; Near-CR, near complete response, where tumor size < 50 mm3 for the last 2 measurements; PR, partial response, where tumor sizes decreased for at least 2 consecutive measurements; SD, stable disease, where tumor size is between 70-100% of initial tumor size at the first treatment; PD, progressive disease, where tumor size > initial tumor size at the first treatment).

The results of the experiments are now described. Example 1: Endogenous gene activation induces protective anti-tumor responses Mutation profiles can vary dramatically between patients. Thus, to investigate a generalized multiplexed tumor vaccination concept, experiments first tested whether an unbiased activation of all endogenous coding genes can lead to an enhanced anti-tumor response in vivo. A syngeneic mouse model of triple-negative breast cancer (TNBC) was used wherein E0771 cells were transplantated in the mammary fatpad of fully immunocompetent hosts. E0771 cells were transduced with lentiviral vectors expressing dCas9-VP64 and MS2-p65-HSFl (E077 1-dCas9-MPH) (FIG. 1A). After confirming robust endogenous gene activation with the CRISPRa system (FIG. 5B), a mouse genome-scale lentiviral SAM CRISPRa sgRNA library (mSAM, or SAM for short) (Konermann etal. (2015) Nature 517, 583-588) was transduced into E0771-dCas9-MPH cells, generating a highly diverse population of cells encompassing the entire library (E0771-SAM). This was confirmed by Illumina sequencing readout of library representation for all 6 independent replicates used in the in vivo experiments (FIGs. 5A- 5B). The E0771-SAM cell pool was transplanted into C57BL/6J mice to test their ability to form syngeneic tumors. In sharp contrast to vector transduced E0771 cells (0/8 rejection, i.e. 8/8 engrafted, all with large tumors), the E0771-SAM cell pool was rejected in most (42/50, 84%) of the mice, and the remaining 8/50 (16%) grew small tumors (p < 2.2e-16, FIGs. 6A-6B). Of note, the E0771-SAM outgrown tumors were sensitive to checkpoint blockade immunotherapy (CBI), with rapid complete regression under the treatment of monoclonal immune checkpoint blockade (ICB) antibodies against programmed death-1 (PD-1) or cytotoxic T-lymphocyte associated antigen-4 (CTLA-4) (p < le-5, FIGs. 7A-7D). To test the roles of innate and adaptive immune responses in tumor rejection responses, E0771-SAM cells were transplanted into the mammary fatpad of immune-deficient Nu/Nu and RagF mice. In sharp contrast to immunocompetent C57BL/6J hosts (2/5 with small modules, 3/5 tumor-free), all Nu/Nu (4/4) and Rag/ (5/5) mice grew large breast tumors from E0771-SAM (p < le-5, FIGs. 6C-6F). Notably, E0771-SAM formed significantly larger tumors in RagF mice compared to that in Nu/Nu mice (p < 0.0001, FIG. 6C). Furthermore, when both CD4+ and CD8+ T cells were pharmacologically depleted in C57BL/6J mice by treatment with both anti-CD4 + anti- CD8 monoclonal antibodies, all mice receiving E0771-SAM transplantation formed large tumors (4/4), again in sharp contrast to non-treated (0/1 1) (p < le-9, FIGs. 6G-6H). Together, these results indicated that activation of endogenous genes using the CRISPRa system in a genome-scale manner induced potent protective anti-tumor immune responses in vivo, leading to robust tumor rejection of syngeneic cancer cells by immunocompetent hosts.

Example 2 : Massively parallel gene activation as prophylactic and therapeutic cancer vaccines The observations thatE0771-SAM library cells were consistently rejected by the hosts led to the postulation that multiplexed activation of endogenous genes can stimulate broad anti-tumor immune responses to protect the host from the same type of tumor, thereby serving as prophylactic or therapeutic vaccines (FIG. 1A). To test the application of CRISPRa mediated endogenous gene activation as a vaccine (CAVac), E0771-CAVac was generated by transducing genome-scale CRISPRa sgRNA libraries into E0771- dCas9-MPH cells followed by mitomycin treatment to induce senescence, and then tested as a cell-based vaccine (E0771 -CAVac, or CAVac for short). To test the concept of a prophylactic vaccine, E0771-CAVac was inoculated into C57BL/6J mice prior to tumor induction (FIG 1A). In sharp contrast to unvaccinated mice (0% tumor free), vaccination with E0771-CAVac granted the host complete protection (100% tumor free) against a subsequent tumor challenge with the unmodified parental cancer cell line (E0771), across two vaccination regiments (7 or 14 days prior to tumor challenge) (p < 2.2e-16, 2.2e-16, respectively). Vaccination 3 days prior to tumor challenge also granted the host a close- to-complete protection (1/6 mouse with a small module, 5/6 tumor-free) (p < le-10) (FIG. IB). The results demonstrated that genome-scale activation of endogenous genes using CRISPRa is an effective approach to generate prophylactic vaccination against tumors with otherwise identical genetic backgrounds. To test CAVac as a therapeutic intervention, orthotopic syngeneic E0771 tumors were induced before treating the mice with CAVac (FIG. 1A). Following a three-dose treatment scheme, CAVac treated mice tumors were significantly smaller than those of PBS treated (p < 0.05, FIG. 1C, FIG. 8A-8B). The efficacy was not observed using the parental cell line without gene activation (p = 0.77, FIG. 9A) Moreover, the therapeutic effect was abolished if CAVac was heat-inactivated (p = 0.775, FIG. 9B). Of note, even a single dose CAVac treatment achieved comparable efficacy as the three dose treatment (p < 0.05, FIG. 9C) At the experimental endpoint, the histopathology of the tumors were analyzed and large inflamed areas with CD8+ lymphocytes and cancer cell death was observed in CAVac treated tumors, as compared to the rapidly proliferating PBS treated tumors with little inflammation and few CD8+ cells (FIG. 1D-1E). To examine whether the anti-tumor effect was mediated by cancer-specific T cell response (at least in part), enzyme-linked immunospot (ELISPOT) assays were performed. CAVac significantly augmented the tumor-specific interferon γ (Ι ηγ) production of vaccinated mice (p < 0.05, FIG 1F-1G). Furthermore, depletion of CD8+ T lymphocytes alone (but not CD4+ T lymphocytes) with anti-CD8 antibody abolished the therapeutic efficacy of CAVac (FIG. 9D), indicating that CD8+ T cells are essential for anti-tumor response elicited by CAVac. To test whether CAVac can be used in conjunction with other immunotherapy or immune modulation, CAVac treatment was tested in combination anti-CTLA4 (FIG. 1H). The combination of CAVac + anti-CTLA4 boosted the efficacy of both CAVac alone (p < le-7) and anti-CTLA4 alone (p < le-4) in the same E0771 TNBC syngeneic model, leading to complete regression of established tumors (FIGs. 1I-1J; FIGs. 8C-8E), without any relapse observed until day 90 as the experiment ended (FIG. 8G), suggesting long term protective memory in these mice. The immunosuppressive microenvironment is known to be a major contributing factor for dampened anti-tumor immune responses and checkpoint blockade immunotherapies, where CD4+ regulatory T lymphocytes often negatively regulate the cytotoxic effect of CD8+ T cells in breast cancer. For this reason, it was tested whether depletion of CD4+ T cells could influence the efficacy of CAVac. CD4+ depletion using monoclonal anti-CD4 antibody significantly boosted the efficacy of CAVac (p < le-4, FIGs. 1I-1K; FIGs. 8C-8D & 8F), where the combination of CAVac+anti-CD4 led to nearly complete regression of established tumors (FIG. IK; FIG. 8F).

Example 3 : Multiplexed in situ vaccination using AAV-CAVac against established tumors Because a live cell-based vaccine has clear limitations for clinical translation, a safer delivery vehicle to carry CAVac for direct in vivo tumor vaccination was investigated. Adeno-associated viruses (AAVs) are potent non-propagating viral vectors shown to mediate efficient transgene delivery into various organs in mouse models and humans. Because of these properties, AAVs have been commonly used in clinical trials for gene therapy, and recently received FDA approvals To enable direct delivery of CAVac, an AAV version of CAVac (AAV-CAVac) was devised by generating an AAV- CRISPRa vector and cloning SAM modules as well as the genome-scale sgRNA library, then pool-packageing into AAV9 (FIG. 2A) The effectiveness of pool-packaged AAV- CRISPRa in activating endogenous genes was confirmed by infecting tumor cells with AAVs carrying a small pool of sgRNAs targeting genes including Cd70, Cd80, and CD86 (FIG. 10A). C57BL/6J mice bearing syngeneic orthotopic E0771 tumors were treated with this form of vaccine by intratumoral administration (FIG. 2A). A strong effect of AAV-CAVac alone against these tumors was observed, with a fraction of mice (3/9, 33%) exhibiting complete or near complete regression (FIG. 10D) compared to PBS (p = 0.00014, FIG. 2B and FIGs. 10B-10D) and AAV- Vector (p = 0.0078, FIG. 2B and FIGs. 10B-10D). Of note, AAV-vector treatment showed a moderate, yet statistically insignificant effect against tumor in the E0771 model, but significantly weaker than that of AAV-CAVac (p = 0.26, FIG. 2B).. To test the broader utility of AAV-CAV, similar treatment was performed on a syngeneic metastatic melanoma mouse model (B16F10), which again demonstrated significant efficacy (FIG. 2C, FIGs. 10C-10D). At the endpoint of the experiment, the histopathology of the tumors were analyzed. Large inflamed areas with CD8+ lymphocytes and cancer cell death was observed in AAV-CAVac treated tumors, as compared to the rapid proliferation and rare CD8 + lymphocyte infiltration in PBS or AAV-Vector treated tumors (FIGs. 2D-2E). Using ELISPOT, it was confirmed that AAV-CAVac elicited much stronger anti-tumor T cell response (in terms of FN producing splenocytes) compared to PBS (p = 0.0028, FIG. 2F-2G) and to AAV-Vector (p = 0.005, FIGs. 2F-2G). No difference was observed in T cell FN response between PBS and AAV-Vector (FIGs. 2F-2G), suggesting the moderate anti-tumor effect from AAV-Vector is unlikely to be mediated by T cells. Retrospective comparison showed that AAV-CAVac has a stronger efficacy as compared to cell-based CAVac (unpaired t test, two sided, p = 0.016) in settings where PBS-treated tumors grew at similar dynamics (p = 0.3) These data showed that in situ vaccination by AAV-mediated delivery of CAVac can augment specific host immune responses against established tumors.

Example 4 : AAV-CAVac remodels the host tumor microenvironment To investigate the effect of AAV-CAVac on the host tumor microenvironment, single cell RNA sequencing (scRNA-seq) was performed to simultaneously profile the whole population of tumor-infiltrating immune cells (Tils) and their gene expression signatures (FIG 3A). From single cell suspension of end-point tumors, total Tils were isolated by fluorescence activated cell sorting (FACS) of CD45+ immune cells, then a total of 2,075 CD45+ cells from AAV-CAVac-treated mice, as well as 5,383 from PBS- treated mice were sequenced (FIGs. 3B-3C) Using clustering and dimensionality reduction, a total of 11 unique clusters of Tils were identified from both AAV-CAVac and PBS group (FIGs. 3B-3C). Strikingly, most (10/1 1) of these clusters exhibit strong shifts in AAV-CAVac as compared to PBS (p < 0.001, FIG. 3D). Cluster-specific expression analysis revealed the gene signatures specific to each cluster. Notably, the first cluster (cluster #0) was drastically increased in AAV-CAVac TII population as compared to PBS (54.75% vs. 2.23% of total cells, < 2.2 * 10 16, FIG. 3D). This population possessed high levels of MHC class II transcripts (such as H2-Aa, H2-AM and H2-Ebl), which is characteristic of antigen presenting cells (FIG. 3E). The second most abundant population (cluster #1) was reduced in AAV-CAVac TII population as compared to PBS (FIGs. 3D-3E). This population expressed genes associated innate immune cells such as the Ifit (Interferon inducedproteins with tetratricopeptide repeats) gene family. Interestingly, cluster #9, bearing resemblance to T cells due to the highly differentiating expression of Cd3d, Cd3g and Gzmb (Granzyme B) transcripts (FIG 3E), exhibited a significant proportional increase within the AAV-CAVac TII population (FIG. 3D). Differential expression analysis by cluster revealed significantly altered gene expression in each cell population. For example, Ccl7 and Ccl8 were significantly upregulated in cluster #0 of the AAV-CAVac ΤΠ population as compared to that of PBS, whereas Pkm and Aldoa were significantly downregulated (FIG. 11A). Tils in cluster # 1 also showed upregulation of Ccl8 and downregulation of Pkm (FIG. 1IB). The putative T cell cluster (#9) within the AAV-CAVac TII population showed elevated expression of genes such as Ccl8, mt-Nd2 (Mitochondrially Encoded NADH. Ubiquinone Oxidoreductase Core Subunit 2) and Gm2691 7 (an uncharacterized gene), and downregulated genes such as Hmoxl (Heme Oxygenase 1) (FIG 11C). T cell receptor sequencing (TCR-seq) was performed to profile the TCR repertoire in CAVac vaccinated, AAV-CAVac vaccinated and unvaccinated mice (FIG. 12A). While the spleens preserved a highly diverse TCR repertoire, clonal expansion of a subset of clones in tumor infiltrating lymphocytes (TILs) was observed (FIGs. 12B-12C). Interestingly, across all vaccinated animals, the Gini-Simpson index of clonal distribution significantly decreased as the tumor size decreased, where a smaller Gini-Simpson index denotes greater skewness in clone size distribution (R = 0.54, p = 0.036, FIG. 12D). This finding implied that enhanced anti-tumor activity is associated with more potent selection in vivo. Examination of the complementarity-determination region 3 (CDR3) peptide sequences of the TILs revealed the most dominant clones in CAVac and AAV-CAVac vaccinated tumors, in which some clones can reach ultra-high frequencies of up to 20.7% (FIG. 12E). These observations together revealed that vaccination by AAV-CAVac significantly altered the host tumor microenvironment.

Example 5 : Pool-activation of mutated senes as proof-of-concept multiplexed precision vaccination As each individual tumor has its unique profile of mutations, the AAV-CAVac system was also capable of activating a customized set of mutated endogenous genes, with the adaptation of a precise targeted library design (Precision AAV-CAVac, or AAV- PCAVac) (FIG. 4A). Customizing the AAV library for endogenous gene activation both enriched for potentially antigenic mutants and selectively excluded genes that potentially caused adverse effects. Whole-exome sequencing of the E0771 cancer cells was performed and all SNPs, insertions and deletions (indels) were called in all annotated genes, by comparison to healthy mammary fat pad from wildtype C57BL/6J mice (FIG. 4A). The whole E0771 -specific mutation profile was revealed (FIGs. 4B-4C). These data were fed into CRISPRa sgRNA library design, generating a library of 3,839 activating sgRNAs (SEQ ID NOs: 349-4,187) targeting 1,1 16 E0771 -mutated genes (FIGs. 4A & 4C). The library was synthesized and pool-cloned, generating an E0771 -specific precision vaccine (E0771 AAV-PCAVac) (FIG. 4A). C57BL/6J mice bearing E0771 syngeneic orthotopic TNBC were treated with the AAV-PCAVac and strong efficacy was observed (p < le-7, FIGs. 4D-4G). Of note, there was a moderate yet statistically insignificant effect in AAV-vector treated group (p = 0 25, FIG. 4E). In sharp contrast, all AAV- PCAVac treated tumors either fully regressed, decrease in size towards zero, or remained as small nodules within three weeks after treatment, as compared to large and rapidly growing tumors in all mice in the PBS treated group and most mice in the AAV-Vector group (FIGs. 4D-4F) The therapeutic benefit of AAV-PCAVac persists in the mice that underwent complete regression, as no sign of relapse was detected in longer-term observations (FIG. 4F). Using ELISPOT, it was observed that AAV-PCAVac significantly augmented tumor-specific Ifn producing splenocytes in vaccinated mice compared to PBS (p < 0.001) and AAV-vector (p < 0.01) (FIG 4G-4H). To examine the adaptive immune responses, FACS analysis was performed on T cell populations from both the spleen and tumor (FIGs. 13A-13B). In the splenocyte population, AAV-PCAVac treatment significantly increased CD4+ and CD8+ T cells’ abundance, in total cells and in CD45+- relative fractions (FIGs. 4H-4I, FIGs. 15A-15B). For example, AAV-PCAVac treated mice have greater than 2.4-fold increase of CD8+ T cells as compared to PBS and AAV- vector treated mice (p < 0.01, FIG. 41, FIG. 5B). These observations hold in the TIL population (FIGs. 4J-4K, FIGs. 15C-15D), for example, AAV-PCAVac treated tumors have an average 15-fold more CD8+ TILs as compared to PBS treated mice (p < 0 05, FIG 4K, FIG. 5D), consistent with the strong anti-tumor immune response induced by AAV-PCAVac treatment (FIGs. 4D-4G). These data together revealed that AAV- PCAVac is a potent means to stimulate specific anti-tumor immune responses resulting in significant regression or elimination of established tumors, which represents a proof-of- concept of a cost-effective precision multiplexed vaccination approach.

Example 6 : Discussion New technologies that have harnessed the immune system to destroy malignant tumor cells have transformed cancer therapeutics. The concept of cancer immunotherapy was first proposed over a century ago, and was subsequently revitalized when it was formally proposed that the immune system could recognize and eliminate tumor cells in the immune surveillance theory. However, it is now known that cancers can rapidly adapt to these immune pressures, acquif ng new alterations to escape immune elimination using many different mechanisms. Tumor cells can acquire mutations to reduce immune recognition or increase resistance to cytotoxic killing, and also foster immunosuppressive microenvironments in various different ways. Cytotoxic T lymphocytes (CTLs) play an essential role in anti-tumor immunity, most prominently by the specific killing of tumor cells in response to tumor-associated antigens (TAAs). Adoptive transfer of ex vivo expanded naturally occurring or engineered chimeric antigen T (CAR-T) cells has achieved success in immunotherapy of multiple types of liquid cancers. However, many factors including insufficient infiltration, anergy, exhaustion, and suppressive microenvironments can lead to non-responsiveness of T cell based treatments in solid tumors. Co-stimulatory and co-inhibitory receptors play a pivotal role in the status and fate of T cells. For example, CTLA-4 and PD-l are two important receptors on T cells designed to rheostat immune responses to avoid autoimmunity, but they can be manipulated by tumors to block anti-tumor immunity. Immune checkpoint blockade therapies by blocking CTLA-4 and PD-l with antibodies have yielded significant clinical benefits across many tumor types with durable responses even in metastatic and chemo- resistant tumors. Nevertheless, only a portion of patients show sustained clinical responses, demonstrating the need for other therapeutic approaches or combinatorial therapeutics. The present invention provides such an approach. Vaccination has achieved exceptional success in protecting hosts from infectious agents due to its efficacy in stimulating durable adaptive immune defenses. However, approved cancer therapies based on therapeutic vaccines are scarce. Tumor antigen recognition is key to T cell mediated tumor rejection, and the load of TAAs, especially neoantigens, has been shown to be correlated with cytolytic T cell activities and patients’ responsiveness to immune checkpoint blockade. However, spontaneous immune recognition of mutations and self-antigens is usually inefficient for effective tumor rejection, due to the complex in vivo cancer-immune evolution processes such as cancer immunoediting. This was also observed in a clinical setting where neoantigen landscape dynamics in human melanoma was shared by cancer cell - T cell interactions. Vaccination is potentially an effective approach to boost immune recognition of cancer specific mutants. However, many factors may contribute to the lack of efficacy of vaccines in mediating effective anti-tumor responses Most current vaccines cannot mediate effective anti-tumor responses by T cells, or encounter tumor escape by immunoediting and other mechanisms. In particular, low-affinity of invoked T cell receptors to the peptide-MHC class I (p-MHCI) complex and the shift of antigenic repertoire in advanced cancers are potential reasons underlying the lack of efficacy for many vaccine formulations, especially those with only one or a handful of polypeptides. With high-throughput exome sequencing, the notion of personalized immunotherapy targeting patient-specific mutations has become technologically feasible, and recent studies using peptide- and RNA- based vaccines have shown that targeted delivery of mutated neoantigens can generate strong anti-tumor effects. Large-scale screening and generation of effective peptides or RNAs is expensive and time consuming. Selection of a subset of RNAs or peptides may miss other immunogenic neoantigens in the full spectra of endogenous mutations, thereby leaving the door open for continued immune evasion through tumor evolution. Furthermore, both peptides and RNAs have relatively short half-lives. For longitudinal induction of effective anti-tumor immune responses, continuous expression of antigens may prove beneficial. Direct activation of endogenous genes overcomes these challenges by providing sustained and tunable overexpression of mutated genes to amplify the signal of neoantigens (FIG. 14). Pooled gene activation using CRISPRa libraries can be customized to augment the expression of any selected set of genes, or the whole genome, thereby boosting neoantigen presentation for T cell recognition. Although the mechanism of action underlying the anti-tumor responses observed here are likely more complicated than involving T cells alone, the data demonstrate that endogenous gene activation-based therapies, including CAVac, AAV-CAVac and AAV-PCAVac, offer an orthogonal vaccination approach for cancer immunotherapy that can function in concert with other established immunotherapeutic modalities.

Example 7 : Exome-guided AAV-CRISPRa based mutated gene set activation as precision multiplexed tumor vaccination (AAV-PCAVacl against human tumors

Step 1 - Patient tumor profiling: Genomic DNA of tumor samples from core biopsi(es) and normal samples (peripheral blood) is extracted, purified, and subjected to whole-ex ome sequencing Optional: RNA of tumor samples from core biopsi(es) and normal samples (peripheral blood) is extracted, purified, and subjected to RNA sequencing to detect gene expression, which will is also used for both mutation call and expression of potential antigenic mutants.

Step 2 - Mutation mapping and mutant gene ranking: Somatic SNPs and indels in cancer cells are identified by comparison to matched normal tissues, and the mutations are mapped to each gene. Step 3 - CRISPRa sgRNA library design: CRISPRa sgRNAs targeting thes mutants are designed. The mutated gene set customized sgRNA library is synthesized and pool-cloned into the AAV-CRISRPa vector, which is packaged into AAV9 to generate tumor-mutation matched (precision / personalized) AAV vaccine (AAV-PCAVac).

Step 4 - AAV GMP/cGMP: The AAV-PCAVac is subjected to GMP/cGMP for production and quality check.

Step 5a - AAV-PCAVac delivery into unresectable tumor: In a clinical trial or clinical treatment setting, clinicians deliver AAV-PCAVac to the primary or metastatic tumor site which is an unresectable disease, as a treatment to elicit immune response against the residue or potentially metastasized cancer cells harboring the particular mutated genes.

Step 5b - AAV-PCAVac delivery into tumor as an adjuvant of surgery: In a clinical trial or clinical treatment setting, clinicians deliver AAV-PCAVac to the residue tumor site after surgery as an adjuvant treatment to elicit an immune response against the residue or potentially metastasized cancer cells harboring the particular mutated genes.

Example 8 : Comparison with existing methods and discussion of the uniqueness and advantages of the present invention With high-throughput exome sequencing, the notion of personalized immunotherapy targeting patient-specific mutations has become technologically feasible, and recent studies using peptide- and RNA- based vaccines have shown that targeted delivery of mutated neoantigens can generate strong anti-tumor effects. However, large- scale screening and generation of effective peptides or RNAs is expensive and time consuming On the other hand, pre-selection of a subset of RNAs or peptides will likely miss other important immunogenic neoantigens within the full landscape of endogenous mutations, thereby leaving the door open for continued immune evasion through tumor evolution. Furthermore, both peptides and RNAs have relatively short half-lives, potentially limiting the durability of such interventions, or requires more frequent re- dosing. For longitudinal induction of effective anti-tumor immune responses, continuous expression of antigens has its advantages. As demonstrated herein, direct activation of endogenous genes overcomes these challenges by providing sustained and tunable overexpression of mutated genes to amplify the signal of neoantigens that may not be expressed at baseline (FIG. 14). Since CRISPR activation works on the endogenous genes themselves, if a new mutation encoding a potential neoantigen is acquired, the CRISPR activation library will automatically drive the expression of the new mutant gene. Due to the nature of endogenous gene activation, this vaccination approach will continue to evolve alongside the tumor itself, which will naturally lockdown mutated cancer cells and thereby eliminate an avenue of immune escape Importantly, pooled gene activation using CRISPRa libraries can be customized to augment the expression of any selected set of genes, or the whole genome, thereby boosting neoantigen presentation for T cell recognition. Although the mechanism of action underlying the anti-tumor responses observed here are likely more complicated than involving T cells alone, the data herein demonstrate that endogenous gene activation-based therapies, including CAVac, AAV- CAVac and AAV-PCAVac, offer an orthogonal vaccination approach for cancer immunotherapy that can function in concert with other established immunotherapeutic modalities.

Example 9 : Compositions and methods for off-the-shelf and customizable endogenous gene vaccination cancer vaccine Presented herein are two modes of multiplexed vaccination with endogeneous gene activation using the CRISPRa system. In an unvaccinated individual, a tumor cell contains tumor-specific mutated genes that are transcribed, translated, then presented as peptides (neoantigens) on MHC class I molecules (FIG. 17A). Oftentimes these neoantigens are expressed at a low level, and thus elicit a weak response upon binding to a TCR of a CD8+ T cell. In one approach described herein, Multiplexed Vaccination by Mutated Gene CRISPR Activation (MGCA), a plurality of mutant endogenous genes are activated by the CRISPRa system using sgRNAs specific for these mutant endogenous genes (see Examples 4, 5, and 6) . This leads to high expression of neoantigens on MHC class I molecules yielding a robust CD8+ T cell response (FIG. 17B). In a second approach utilized herein, Multiplexed Vaccination by Antigen Presentation CRISPR Manipulation (APCM), a plurality of antigen presentation genes are activited by the CRISPRa system using sgRNAs specific for these antigen presentation genes (see Example 10 below). This leads to augmentation of antigen presentation machinery, increased expression of cytokines and/or immunological modulators, increased presentation of neoantigens on MHC class I molecules, and a robust CD8+ T cell response (FIG. 17C). The precision (“Personalized”) AAV-PCAVac system was proven effective as a therapeutic vaccine. The AAV-PCAVac was designed to target a set of the most highly mutated genes in E0771 cells as compared to normal mammary fatpad of C57BL/6J female mice (SEQ ID NOs: 349-4,187; Table 4). The efficacy of the AAV-PCAVac multiplexed endogeneous gene activation was tested using a syngeneic orthotopic model in C57BL/6J hosts. E0771 triple-negative breast cancer (TNBC) cells were engrafted in the mammary fatpad of female C57BL/6J mice. Mice were treated with PBS, AAV- Vector, or the AAV-PCAVac library (SEQ ID NOs. 349-4,187). Survival over time was monitored for all treatment groups (FIG 18). Efficacy was seen in both AAV-Vector and AAV- PCAVac, however AAV- PCAVac had a stronger anti-tumor effect (FIGs. 18-19). A two-sided tumor induction was performed, wherein tumors (E0771 TNBC) were induced at two locations, a primary and a distal site, in C57BL/6J mice. Mice were treated at the primary site with either PBS, AAV-Vector, or AAV-PCAV. Regression of both the primary and distant tumors was observed in the AAV-PCAVac treated mice (FIG. 20). Using the syngenic orthotopic TNBC model, C57BL/6J mice were re-challenged with E0771 tumor cells after complete regression of a first E0771 tumor following AAV-PCAVac treatment. No growth was seen in the AAV-PCAVac treated mice following re-challenge (FIG. 21). The Precision (“Personalized”) AAV-PCAVac system was further validated as a therapeutic vaccine against TNBC. E0771 TNBC were engrafted in the mammary fatpad of C57BL/6J female mice. Mice were treated with PBS, AAV-Vector, AAV-Emutl 1 library or AAV-PCAVac library. The Emutl 1 library targets a set of the topmost 11 mutated genes in E0771 cells (Tekt2, RSClal, Acer2, S!c36a /, Tmeml06b, Gabrg2, Ago4, G3hpl, FAT2, Hmmr, Trp53). Efficacy was seen in both AAV-Vector, AAV- Emutl 1 and AAV- PCAVac, however AAV- PCAVac had the strongest anti-tumor effect (FIG. 22). SgRNAs were designed to target a set of the most highly mutated genes in B16F10 (melanoma), GL261 (glioma), Hepal-6 (hepatoma), MC38 (colon cancer), and Pan02 (pancreatic cancer) cells (SEQ ID NOs. 11,809 - 23,776). The sgRNAs were cloned into an adeno-associated viral vector and packaged, as described elsewhere herein

Example 10: Antigen Presentation CRISPR Manipulation (AAV-APCM) system An off-the-shelf Antigen Presentation CRISPR Manipulation (AAV-APCM) system was designed and tested as a therapeutic vaccine. An AAV-Apcm library was designed by first selecting a small set of genes that elicit immune responses: B2M, B7-H2 (ICOSL), Calnexin, Calreticulin, CCL5, CD30L(TNFSF8), CD40L, CD70, CD80, CD83, CD86, CXCL10, CXCL3, CXCL9, Cystatin B, Cystatin C (x), ERAP1, ERp57(PDIA3), Flt3L, GITRL(TNF SF 18), IFNa4, IFNbl, IFNg, IL-2, LIGHT (TNFRSF14), NLRC5/CITA, OX40L/TNFSF4, Sec61al, Sec61b, Sec61g, TAPI, TAP2, Tapasin, TAPBPR, TL1A (TNFSF15), and TNFSF9 (4-1BBL). SgRNA sequences were designed to target these genes in mice, yielding a library of 107 sgRNAs (SEQ ID NOs. 23,779 - 23,885) (FIG. 27). Because the composition is fixed, by definition this APCM library is also an “Off-the-shelf’ vaccine, while it can definitively be combined with personalized vaccine. The sgRNAs were cloned into an adeno-associated viral vector and packaged, as described elsewhere herein. Efficacy of the AAV-APCM multiplexed endogenous gene activation was tested in a syngeneic orthotopic model in C57BL/6J hosts. E0771 TNBC cells were engrafted in the mammary fatpad of C57BL/6J female mice. Mice were treated with PBS, AAV-Vector, or the AAV-Apcm library. Efficacy was seen in both AAV- Vector and AAV-Apcm treatment, however the AAV-Apcm treatment had a stronger anti-tumor effect (FIG. 23). A second AAV-APCM library (AAV-Apch) was generated that was designed/optimized specifically for human genes. SgRNAs were designed to target the same set of antigen presentation genes as above, yielding a library of 219 sgRNAs (SEQ ID NOs: 23,886-24,104) (FIGs. 28A-28B). The sgRNAs were cloned into an adeno- associated viral vector and packaged, as described elsewhere herein.

Example 11: “Off-the-shelf’ whole-genome libraries An off-the-shelf whole-genome AAV-CAVac system was designed and tested as a therapeutic vaccine against melanoma. Therapeutic efficacy of whole-genome gene activation AAV-CAVac (i.e. AAV-SAM) against established orthotopic syngeneic B16F10 tumors by intratumoral administration was demonstrated. Growth curves of orthotopic transplanted B16F 10 tumors in C57BL/6J mice treated with PBS and AAV- CAVac at indicated times (days post-injection; arrows) are shown in FIG. 24 The off-the-shelf whole-genome AAV-CAVac system was also established as a therapeutic vaccine against pancreatic cancer. Therapeutic efficacy of whole-genome gene activation AAV-CAVac (i.e. AAV-SAM) against established orthotopic syngeneic Pan02 tumors by intratumoral administration was demonstrated. Growth curves of subcutaneous transplanted Pan02 tumors in C57BL/6J mice treated with PBS and AAV- CAVac at indicated times (arrows) are shown in FIG. 25. An off-the-shelf AAV-SingleCAVac system was proven effective as a prophylatic vaccine (FIG. 26). Efficacy of AAV-SingleCAVac endogenous gene activation in a syngeneic orthotopic model in C57BL/6J host was demonstrated. Shown are growth curves of Arhgap30 or Nolcl activated E0771 cell induced syngeneic orthotopic tumor. As compared to vector transduced cells, sg-Arhgap30 or sg-Nolcl transduced E0771 cells generated tumors that grew slower and often got rejected by the C57B1/6J host. A human version of the AAV-CAVac (i.e. AAV-SAM) system is designed for therapeutic and prophylactic use against different cancer types. SgRNAs are designed against endogeneous human genes expressed in different cancer types. SgRNAs are cloned and packaged into viral vectors as described herein.

Example 12: Multiplexed endogenous gene activation leads to tumor rejection through an immune-mediated mechanism The CRISPRa system uses a catalytically dead Cas9 without nuclease activity (dCas9), enabling simple and flexible regulation of gene expression through dCas9 - transcriptional activation domain fusion. This system can be further enhanced by the recruitment of other effectors such as synergistic activation mediators (SAM). Herein, broad genome-wide CRISPRa libraries were utilized for initial experiments, since activation of all coding genes in the genome includes activation of all mutated genes. To test the effect of endogenous gene activation on the immunogenicity of cancer cells, it was essential to utilize fully immunocompetent tumor models. The E0771 syngeneic mouse model of triple-negative breast cancer (TNBC), in which E0771 cancer cells are transplanted into the mammary fat pad of fully immunocompetent C57BL/6 mice, was used. E0771 cells were transduced with CRISPRa lentiviral vectors expressing dCas9-VP64 and MS2-p65-HSFl (E077 1-dCas9-VP64-MPH) (FIG. 29A andFIG. 30A). Observing that dCas9-VP64 alone has a moderate effect on tumor growth (FIG. 30B), all subsequent experiments were performed using E0771-dCas9-VP64 cells. Next, a mouse genome-scale lentiviral SAM CRISPRa sgRNA library (mSAM, or SAM for short) (Konermann et al. (2015) Nature 517, 583-588) was transduced into E0771-dCas9-VP64- MPH cells, generating a highly diverse population of cells encompassing the entire library (E0771-dCas9-VP64-MPH-SAM cell pool, or E0771-SAM for short). This was confirmed by Dlumina sequencing for 6 independent replicates (FIG. 30C). For controls, E0771-dCas9-VP64-MPH cells transduced with the empty lentiviral vector expressing an inert sgRNA and a MS2-loop-tracrRNA chimeric backbone (E077l-Vector for short) were used. The E0771-SAM cell pool was transplanted into C57BL/6J mice to test their ability to form syngeneic tumors (FIG. 29A). In sharp contrast to E0771-Vector cells (0/8 rejection, i.e. 8/8 engrafted, all with large tumors), the E0771-SAM cell pool was rejected in most (42/50, 84%) of the mice, with the remaining mice (8/50, 16%) developing small tumors (FIG. 29B). To examine the contribution of innate and adaptive immune responses towards rejection of E0771-SAM cells, E0771-SAM cells were transplanted into the mammary fat pad of immunodeficient Nu/Nu and RagF mice. Unlike in immunocompetent C57BL/6J hosts (5/5 either completely rejected or only with small modules), all immunodeficient Nu/Nu (4/4) and Rag (5/5) mice rapidly grew large tumors from E0771-SAM cells (FIG. 29C). Notably, E0771-SAM cells formed significantly larger tumors RagF mice compared to in Nu/Nu mice (FIG. 29C). When both CD4+ and CD8+ T cells were pharmacologically depleted in C57BL/6J mice by treatment with a-CD4 and a-CD8 monoclonal antibodies, all mice that received E0771- SAM transplantation formed large tumors (4/4), in contrast to untreated mice (0/1 1 with tumors) (FIG. 29D). Of note, the E0771-SAM outgrown “escaper” tumors were sensitive to immune checkpoint blockade (ICB), with rapid complete regression upon treatment with antibodies against programmed death-1 (PD-1) or cytotoxic T-lymphocyte associated antigen-4 (CTLA-4) (Figures 30D-30G). Together, these results indicated that pooled activation of endogenous genes using the CRISPRa system in a genome-scale manner induced potent tumor rejection in vivo only in immunocompetent hosts.

Example 13: Cell-based Multiplexed Activation of Endogenous Genes as an Immunotherapy MAE G )has prophylactic and therapeutic efficacy in syngeneic tumor models Intrigued that the host immune system consistently rejected the E0771-SAM cells, it was next investigated whether CRISPRa-mediated activation of endogenous genes within tumor cells could stimulate broad anti-tumor immune responses. It was hypothesized that multiplexed activation of endogenous genes can be harnessed as a new approach of immunotherapy (MAEGI or CAVac, used interchangeably herein) distinct from all existing modalities. To test this experimentally, CRISPR-mediated gene activation was confirmed in the system (FIG. 5D). The SAM lentiviral-sgRNA library was then transduced into E0771-dCas9-VP64-MPH cells to generate E0771-SAM cells, followed by mitomycin treatment to induce senescence while maintaining the integrity of peptide-MHC-I complex on cell surface. This procedure generated the cell-based MAEGI (c-MAEGI or cell-based CAVac, which are used interchangeably herein). As a control, E0771-Vector cells that were treated with mitomycin in parallel (Cell-Vector control) were used. c-MAEGI was inoculated into C57BL/6J mice prior to E0771 tumor induction. In sharp contrast to untreated mice or Cell-Vector control treated mice (both 0% tumor free), c-MAEGI treated mice had complete protection (100% tumor free) against a subsequent tumor challenges with the unmodified parental cancer cell line (E0771). This held true across two vaccination regiments, i.e 7 or 14 days prior to tumor challenge, while vaccination 3 days prior to tumor challenge granted near-complete protection (1/6 mice with a small nodule, 5/6 tumor-free). The results demonstrated that genome-scale activation of endogenous genes using CRISPRa (c-MAEGI) is an effective approach for prophylaxis against tumors with otherwise identical genetic background. Given its efficacy as a prophylactic agent, it was postulated that c-MAEGI could also be used as a therapeutic intervention in established tumors To test this, orthotopic syngeneic E0771 tumors were induced before treating the mice with c-MAEGI. Using a three-dose treatment scheme, tumors in c-MAEGI treated mice were significantly smaller than those in mice treated with Cell-Vector control or PBS. No efficacy was observed using heat-inactivated lysates of E0771 parental cells, or heat-inactivated c-MAEGI (FIGs. 31A-3 IB), suggesting the importance of maintaining the integrity of cellular components for immune stimulation in this setting. To examine the contribution of T cell- mediated immunity in driving the anti-tumor response, CD8+ T lymphocytes were specifically depleted in C57BL/6J mice with an a-CD8 antibody. CD8+ T cell depletion abolished the therapeutic efficacy of c-MAEGI (FIGs. 31C-31F), indicating that CD8+ T cells are essential for the c-MAEGI mediated anti-tumor responses. It was then investigated whether c-MAEGI could be used in conjunction with other immunotherapies or immunomodulatory agents. Interestingly, the combination of c- MAEGI + a-CTLA4 was significantly more effective than c-MAEGI alone (p < 0 0001) or anti-CTLA4 alone (p = 0.0005), leading to complete regression of established tumors (FIG. 1J). Moreover, the mice that underwent complete responses were completely resistant to tumor re-challenges (FIG. 31G), suggesting long-term protective memory in treated mice.

Example 14: AAV-mediated in situ activation of endogenous genes as an immunotherapeutic agent (AAV-MAEGf) Although the cell-based MAEGI showed significant anti-tumor efficacy, it was reasoned that direct in vivo delivery of MAEGI with viral vehicles to the target tumors can yield a deliverable therapeutic modality and might also further improve efficacy. Adeno-associated viruses (AAVs) are potent viral vectors capable of mediating efficient transgene delivery into various organs in mice and humans. They are non-replicative without helper adenovirus, have serotype-specified tropism and cause minimal toxicity or undesired immune responses. Because of these properties, AAVs have been commonly used in clinical studies of gene therapy, and an AAV-based treatment recently received FDA approval. To enable direct delivery of MAEGI to tumors, an AAV version of MAEGI was devised by generating an AAV-CRISPRa vector with the CRISPRa modules (EFla-MPH and U6-sgRNABackbone-MS2) and cloning in the genome-scale SAM sgRNA library (AAV-g-MAEGI or AAV-CAVac, used interchangeably herein). The resultant library was then pool-packaged into AAV (FIG. 2A) The effectiveness of pool- packaged AAV-CRISPRa in activating endogenous genes was confirmed by infecting E0771-dCas9-VP64 cells with CRISPRa AAVs carrying a small pool of sgRNAs targeting genes including Cd70, Cd80, and Cd86 (FIG. 32A). Furthermore, by introducing a model antigen transgene (chicken ovalbumin, OVA) driven by a PGK promoter into E0771-dCas9-VP64 cells, it was confirmed that PGK promoter-targeted sgRNAs delivered by AAV can significantly increase the presentation of processed antigenic peptide on the cell surface, as revealed by flow cytometry staining with antibody specific to the complex of SIINFEKL peptide bound to class I major histocompatibility complex (pMHC-I) (FIG. 32B-32C). C57BL/6J mice bearing syngeneic orthotopic E0771 tumors were then treated with AAV-g-MAEGI by intratumoral administration (FIG. 2A). AAV-g-MAEGI was significantly more efficacious compared to either AAV-Vector or PBS (FIG. 2B). Of note, the AAV-Vector treatment also showed a significant effect against tumors in the E0771 model (viral vector with EFla-MPH and U6-sgRNABackbone-MS2), but was nevertheless significantly weaker than AAV-g-MAEGI (FIG 2A). CD8+ T cell infiltration into the tumors was observed by histology and immunohistochemistry (FIG. 33A-33B). AAV-g-MAEGI elicited higher frequencies of tumor-reactive immune cells in treated mice (in terms of the frequencies of IFNy producing splenocytes stimulated by tumor antigens) compared to AAV-Vector or PBS (FIGs. 2F-2G). No difference was observed in the frequencies of tumor-reactive IFNy-secreting splenocytes between PBS and AAV-Vector (FIG. 2G). These data demonstrated that multiplexed in situ activation of endogenous genes by AAV-g-MAEGI can elicit robust and specific anti-turnor immune responses. To test the broader utility of MAEGI, the same modality for treatment of other highly aggressive tumor types was tested. On a syngeneic melanoma mouse model (B16F10, expressing dCas9-VP64), AAV-g-MAEGI again demonstrated significant efficacy (FIG. 2C). Additionally, the efficacy of AAV-g-MAEGI in a syngeneic model of pancreatic cancer was tested using the Pan02 cell line. Against established Pan02-dCas9- VP64 tumors, AAV-Vector again had an anti-tumor effect compared to PBS, while AAV- g-MAEGI had significantly stronger efficacy against these tumors, both compared to AAV-Vector and to PBS (FIG. 25). To assess the infection rate of intratumoral AAV delivery, the experiments were repeated using titer-matched AAVs containing a GFP reporter. Four days following intratumoral AAV injection, tumor cells, tumor-infiltrating immune cells (TIICs, CD45 +), and cells from non-tumor organs were harvested. Analysis of GFP expression by flow cytometry revealed that the cancer cells were transduced by AAV in all tumors injected (12/12, 100%), with an infection rate of 4.2 ± 0.51% (mean ± s.e.m.) for tumor cells, reflecting a local injection (FIG. 33C). In contrast, 25% (4/12) of injected tumors showed above-background transduction in pan-immune (CD45+) cells, with an infection rate of 0.74 ± 0.25% (FIG. 33C). The off-target infection rate for the spleen, liver, lung and heart in the same cohort of mice was 0 ± 0%, 0.04 ± 0.04%, 0.18 ± 0.06% and 0.11 ± 0.08%, respectively (FIG. 33D). These data together demonstrated that in situ MAEGI by AAV-mediated delivery of a genome-scale CRISPRa library elicits host immune responses against established tumors across multiple aggressive cancer types, with minimal effect on non-cancer cells and other off-target organs. Example 15: Multiplexed in situ activation of tumor-specific mutated gene sets as a precision immunotherapy Since individual tumors have their own unique mutation profiles that distinguish them from normal tissues, the MAEGI approach was customized to tumor-specific mutated gene sets. This approach was termed precision MAEGI (p-MAEGI or PCAVac, which are used interchangeably herein) (FIG. 4A). By customizing the AAV library to tumor-specific mutant genes, it was hypothesized that the precision version could both enrich for potentially antigenic mutants as well as exclude genes that could cause adverse effects. Whole-exome sequencing of the E0771 cancer cells was performed and all SNPs, insertions and deletions (indels) in annotated genes were called, by comparison to healthy mammary fat pad cells from wildtype C57BL/6J mice that were sequenced in parallel (FIG. 4A). The exome sequencing data revealed the E0771-specific mutation profile (FIGs. 4B-4C). The differential mutation data was then harnessed for CRISPRa sgRNA library design, generating a library of 3,839 activating sgRNAs (SEQ ID NOs: 349-4,187) targeting 1,116 E077l-mutated genes. The library was synthesized and pool-cloned. Successful cloning was verified by Illumina sequencing, and the AAV pool was produced as an E0771 -specific precision MAEGI (E0771 AAV-p-MAEGI or E0771 AAV- PCAVac, used interchangeably herein). C57BL/6J mice bearing E0771 syngeneic orthotopic TNBC were treated with AAV-p-MAEGI, along with AAV-Vector and PBS controls. While the AAV-vector itself showed anti-tumor effects as compared to PBS, AAV-p-MAEGI exhibited dramatic efficacy compared to both AAV-Vector and PBS (FIG. 4E), indicating that the mutant gene-specific CRISPRa sgRNAs generated potent anti-tumor responses. The complete response (CR) and near-complete (nCR) rates were determined for each treatment, which revealed a combined nCR/CR rate of 0% for PBS, 0% for AAV-Vector, and 50% for AAV-p-MAEGI (FIG. 4M). Three months after the initial tumor transplantation, 9 AAV- p-MAEGI treated mice that had undergone complete response were re-challenged All (9/9) mice completely rejected the E0771 tumor re-challenges (FIG. 4F). The complete response of AAV-p-MAEGI treated mice retained a long-term benefit for over 180 days as the end of experiment (FIG. 4F). These data indicated that AAV-p-MAEGI had induced potent and durable anti-tumor responses. The efficacy of AAV-p-MAEGI was completely abolished in immunodeficient hosts, as evidenced by near-identical growth curves of all treatment groups in Ragl-/- mice (FIG. 4N), indicating that the adaptive immune system is essential for the anti-tumor effect of AAV-p-MAEGI. Consistent with this, CD8+ T cell infiltration into tumors was observed by histology and immunohistochemistry (FIGs. 34A-34B). AAV-p-MAEGI treated tumors also showed reduced proliferation (FIGs. 34C-34D). Given the importance of adaptive immunity in driving these anti-tumor responses, it was investigated whether intratumoral delivery of AAV-p-MAEGI could elicit systemic anti-tumor immunity to affect distant sites (FIG. 40). In a syngeneic model of E0771 TNBC where mice bear both local and distant mammary fat pad tumors, after administration of AAV-p-MAEGI only to local tumors, significant anti-tumor effects against both local tumors and distant tumors were observed, which had not been directly infected by AAV-p-MAEGI (FIGs. 4P-4Q). A 67% complete response rate was observed at distant tumors under AAV-p- MAEGE treatment (FIG. 4Q). These data demonstrated that AAV-p-MAEGI treatment had successfully galvanized systemic anti-tumor immune responses.

Example 16: AAV-p-MAEGI recruits active T effector cells into tumors To examine the T cell adaptive immune responses over a time-course, flow cytometry analysis of tumor-infiltrating T cell populations was performed at several time points (FIG. 35A). AAV-p-MAEGI treatment significantly augmented CD4+ and CD8+ T cell tumor infiltration as compared to AAV-Vector or PBS treatment, with significantly increased CD8+ T cells and CD4+ T cells from day 29 onwards (FIGs. 36A-36B). Other immune cell populations were examined at day 19, as this is the time point with initial observation of striking tumor regression (FIG. 35B). The results showed that AAV-p- MAEGI treatment increased the fraction of MHC-II + antigen-presenting cells over AAV- Vector treatment (FIG. 36C), with a trend of increased dendritic cells (FIG. 36D), but no significant changes in macrophages, monocytes, or neutrophil abundance (FIGs. 36E- 36G). These data together revealed that AAV-p-MAEGI treatment increased T cell infiltration into tumors and changed the composition of certain infiltrating immune cells, ultimately resulting in tumor regression. Given these findings, it was next investigated whether the adaptive immune responses induced by AAV-p-MAEGI were tumor-specific. By performing ELISPOT on splenocytes taken from E0771 tumor-bearing mice, it was observed that AAV-p-MAEGI significantly augmented the frequencies of tumor-reactive IF producing splenocytes compared to PBS and AAV-vector treated mice (FIG. 36H-36J) To test whether these stimulated immune cells are specific to the endogenous tumor antigens but not healthy normal tissues, E0771 tumor-bearing mice were again treated with AAV-p-MAEGI or AAV-Vector. ELISPOT assays were performed on both splenocytes and fluorescence activated cell sorting (FACS)-isolated tumor-infiltrating immune cells (TIICs), stimulated with either E0771 cancer cells or matched normal tissues (primary C57BL/6J wildtype cells isolated from mammary fat pad) (FIG 36H). In both AAV-Vector and AAV-p- MAEGI conditions, the ELISPOT assays showed significantly higher IFNy-producing splenocytes and TIICs after stimulation by E0771 tumor cells, as compared to stimulation with normal primary cells (FIG. 36K-36N). Importantly, within the E0771 -stimulated experimental groups, AAV-p-MAEGI treated mice had significantly higher frequencies of IFNy-secreting immune cells than AAV-Vector treated mice. This effect was particularly pronounced in TIICs, where AAV-p-MAEGI significantly augmented the frequencies of IFNy-secreting immune cells in response to E0771 stimulation, but not to matched normal cells (FIG. 36M-36N). The anti-tumor specificity of AAV-p-MAEGI was similarly observed in splenocytes (FIG. 36K-36L). These results demonstrated that tumor-antigen specific immune responses were elicited by AAV-p-MAEGI.

Example 17: AAV-p-MAEGI remodels the host tumor microenvironment To understand the repertoire of T cells recruited by MAEGI, T cell receptor sequencing (TCR-seq) was performed to profile the TCR repertoire in mice treated with AAV-p-MAEGI, AAV-g-MAEGI, AAV-Vector or PBS (FIG 37A). TCR clonal proportion was assessed and various metrics were calculated (FIG. 37B-37D). In comparison to PBS or AAV-Vector, AAV-p-MAEGI significantly increased TCR diversity in both spleens and TILs as measured by the Chaol index (FIG. 37C). In comparison to AAV-g-MAEGI treated mice (genome-wide AAV-MAEGI), splenocytes from AAV-p-MAEGI treated mice (precision AAV-MAEGI) had higher Chaol indices, with no significant difference among TILs (FIG. 37C). Next, the Gini-Simpson indices were calculated, which quantify the evenness of TCR clonal abundances. While there were no significant differences among spleen samples from differing treatment conditions, TILs from AAV-p-MAEGI treated mice had significantly higher Gini- Simpson indices compared to PBS or AAV-Vector treated mice, but not compared to AAV-g-MAEGI treated mice. Intrigued by the increased TCR diversity and clonal evenness among TILs from AAV-p-MAEGI treated mice, it was investigate whether these changes were due to differences in T cell infiltration. The number of unique CDR3 clonotypes identified in each sample (i.e. TCR richness) were examined (FIG. 35C). AAV-p-MAEGI mice had significantly more unique clonotypes than PBS or AAV- Vector samples in both spleen and TIL samples (FIGs. 37E-37F). Collectively, the TCR- sequencing data affirmed the conclusion from the flow cytometry analysis that AAV-p- MAEGI significantly enhanced T cell infiltration into tumors, while additionally revealing the richness and diversity of these tumor-infiltrating T cells. To further investigate the effect of AAV-p-MAEGI on the tumor microenvironment, single cell RNA sequencing (scRNAseq) was performed to profile the composition of TIICs, and simultaneously, their gene expression signatures (FIG 38A). From single cell suspension of tumors, total TIICs were isolated by FACS of CD45+ cells and scRNAseq was performed, recovering a total of 4,381 cells from AAV-p-MAEGI and 3,482 cells from AAV-Vector treated mice (n = 3 mice pooled for each condition). After filtering low-quality cells and lowly-expressed genes, imputation and k-means clustering were performed to identify a total of 9 distinct clusters. Analysis of differentially expressed genes in each cluster revealed the cell type identities of each cluster (FIG. 38B and FIGs. 39A-39F). After excluding a population of cells (k-means cluster 7, or k7) that were negative for Cd45 gene expression (encoded by Ptprc ) (FIG. 39A-39B), the final dataset of TIICs comprised the transcriptomes of 4,065 single cells from AAV-p-MAEGI and 2,799 cells from AAV-Vector treated mice (FIG. 38C). Given that the flow cytometry data and TCR-seq analyses had both identified increased T cell tumor infiltration with AAV-p-MAEGI compared to AAV-Vector, it was investigated whether these findings were recapitulated by scRNAseq at a global scale. To perform in silico analysis on T cell populations, mRNA transcript expression levels were filtered (“mRNA-gated”) on cells in k6 or k9, as these clusters comprise the cells that robustly express Cd3e, Cd4, and Cd8a (FIG 39C). Examining the Cd3e + cells within k6 and k9, the cells were mRNA-gated into Cd8a +Cd4~and d4 Cd populations. Visualization of these cell groups by t-SNE dimensional reduction revealed clear separation of putative CD8+ T cells (defined by Cd8a +Cd3e +Cd4 mRNA gating) from CD4+ T cells (defined by Cd4 +Cd3e +Cd8a mRNA gating) (FIG. 38D). The relative abundance of these different T cell populations in k6 and k9 were quantified, revealing that AAV-p-MAEGI mice had significantly more Cd3e + T cells, putative CD8+ T cells, and putative CD4+ T cells (FIG. 38E). Furthermore, among these putative CD4+ T cells, AAV-p-MAEGI treated mice had increased abundance of Tbx2J , Ifng , and lhx2 1 Ifn cells, indicative of anti-tumor Thl cells (FIG. 38F). Thus, the single cell transcriptomic analyses on the global TIICs reaffirmed the earlier cell type specific observations by FACS and TCR-seq, that AAV-p-MAEGI promotes T cell tumor infiltration. To investigate whether AAV-p-MAEGI treatment led to transcriptomic changes in tumor-infiltrating T cells, differential expression analyses were performed to compare T cells from AAV-p-MAEGI and AAV-Vector treated mice. Among the putative CD8+ T cells in k6 (characterized by higher Gzmb expression compared to k9) (FIG. 39C), 267 upregulated and 753 downregulated genes were identified in AAV-p-MAEGI treated mice compared to AAV-Vector (FIG. 40A). Gene ontology analysis revealed enrichment of several T cell signatures within the upregulated gene set, including adaptive immunity, T cell activation, and the T cell receptor complex. Interestingly, the strongest enriched gene set was the AIG1 family of GTPases, particularly Gimap genes (GTPases of immunity-associated protein). Gimap proteins are known to play critical roles in T cell activation and survival. As for the putative CD8+ T cells in k9, 665 genes were upregulated and 80 genes downregulated with AAV-p-MAEGI treatment (FIG. 40B) Enriched gene ontologies in the upregulated gene set included mitochondrion, exosome, proteasome, RNA-binding, adaptive immunity, ribonucleoprotein, AIGl/Gimaps, and rRNA processing. The same analysis was performed on putative CD4+ T cells, revealing 335 upregulated and 65 downregulated genes with AAV-p-MAEGI treatment (FIG. 40C). AAV-p-MAEGI upregulated gene ontologies in putative CD4+ T cells included the proteasome, extracellular exosome, poly(A) RNA binding, mitochondrion, spliceosome, and ribonucleoprotein. Collectively, the scRNAseq data further refined the mechanism of action that AAV-p-MAEGI increased T cell tumor infiltration, additionally revealing significant transcriptomic changes in TILs following MAEGI treatment.

Example 18: Comparison to RNA or peptide neoantigen vaccines Current state-of-the-art approaches to target tumor neoantigens are largely focused on delivering mutant RNAs or peptides to lymphatic tissues The AAV-MAEGI approach is not directly comparable to these neoantigen vaccines, as AAV-MAEGI directly amplifies tumor immunogenicity by intratumoral injection. Nevertheless, under the intratumoral / in situ treatment scheme, experiments were performed to compare AAV- mediated CRISPRa gene activation with AAV-mediated mutant mini-ORF expression (the closest analog to RNA or peptide vaccines while still maintaining the mode of delivery). Notably, the mutant mini-ORF strategy has been adopted by some biotech startups, using viral vectors such as oncolytic viruses. Interestingly, in the same E0771 syngeneic model (FIG. 41), the data indicates that while AAV-MAEGI is highly efficacious (FIG. 41, left panel), intratumoral delivery of the predicted top 20 mutant mini-ORFs by AAV (AAV-20MutORF) is not more effective than AAV-Vector alone. One may wonder if >1,000 mutant ORFs could be used for a closer comparison to AAV-p-MAEGI, but doing so is currently impractical because ~50 different AAV-ORF constructs each with 20 peptide-encoding CDSs would have to be created. Similar issues regarding scalability would apply to mRNA ORFs (also needs ~50 mRNA constmcts) or synthetic peptides (>1000 constructs) - both well beyond the realm of clinical feasibility. However, the AAV-MAEGI approach is highly scalable, because sgRNAs can be synthesized as a pool and generated as one mixed product, as demonstrated herein. This supports the promise of AAV-MAEGI as a new approach, with multiple advantages over existing neoantigen-based approaches.

Example 19: Comparison to other intratumoral approaches to amplify tumor cell immunogenicitv Several other approaches for directly amplifying tumor cell immunogenicity have been described in the literature. However, none can match the flexibility and scalability of the CRISPR-based MAEGI approach. To evaluate the importance of library size (and hence scalability) in the anti-tumor efficacy of AAV-MAEGI, AAV-g-MAEGI (exome- wide library) was directly compared with a mini-pool MAEGI (AAV-mini-MAEGI) in theB16FlO syngeneic model. AAV-g-MAEGI outperformed AAV-mini-MAEGI (targeting the same 15 genes chosen based on predicted antigenicity for prior B16F 10 melanoma vaccines) (FIG. 42). Indeed, the antigen/expression-based mini-pool showed some initial efficacy, but the effect rapidly disappeared as the tumors grew (with similar growth curves as AAV-Vector), possibly due to immune escape of the 15 selected antigens. In contrast, the broader AAV-g-MAEGI library showed stronger and more sustained efficacy. Moreover, experiments targeting a small set of mutated genes for the E077 1 model (Emutl 1, carrying an sgRNA library targeting the top 11 mutant genes in E0771) were also performed. As the data in FIG. 43 illustrates, reduced efficacy was observed with Emutl 1 (right panel, only 20% nCR/CR rate), as compared to strong efficacy with E0771-p-MAEGI carrying an sgRNA library targeting 1,116 mutant genes (left panel, 50% nCR/CR rate). Therefore, the ability to target a larger number of mutant genes is key for optimally accessing the maximal efficacy space. While this quickly becomes impractical for traditional mRNA/peptide/CDS approaches, it is readily feasible with the CRISPRa approaches disclosed herein by scaling the desired number of sgRNAs in the library, up to the entire genome.

Example 20: Dual-AAV delivery It was demonstrated herein that dual-AAV delivery into fully un-modified parental E0771 cells can mediate activation of endogenous genes (FIGs. 44A-44B) This was achieved using two different AAV serotypes: both AAV9 and AAV-DJ (FIGs. 44A- 45). A dual AAV system for in vitro and in vivo delivery of MAEGI was developed herein. The dual AAV vector system of CRISPR activation (AAV-dCas9, i.e. EFs- dSpCas9-spA; and AAV-CRISPRa vector, i.e. U6p-sgSapI-EFla-MS2-p65-HSFl- WPRE), was generated by restriction cloning and Gibson assembly. Individual sgRNA or sgRNA libraries were cloned into the AAV-CRISPRa plasmid. dCas9 or U6-sgRNA- EFla-MS2-p65-HSFl expressing AAVs produced using the methods as described in detail elsewhere herein. For in vitro and in vivo delivery, AAV-dCas9 and AAV- CRISPRa were simultaneously added into cultured cells or co-injected into tumors at a ratio of 1:1. Syngeneic TNBC were established by orthotopic transplantation of 2 x 106 E0771 cells into the mammary fat pad of 5-8 weeks old female C57BL/6J mice. 4, 9 (or 11) and

18 days after tumor induction, 1-5 x 10 10 GCsof AAV-dCas9, together with same titers of AAV-p-MAEGI or AAV-Vector, or PBS were intratumorally administrated into tumor bearing mice. Tumors were measured every 3-4 days using caliper and sizes were calculated with the formula: Vol = π/6 *x*y*z. Two-way ANOVA was used to compare growth curves between treatment groups. Dual-AAV delivery of a personalized library (AAV-PCAVac, i.e. AAV-p- MAEGI) into fully un-modified parental E0771 cells mediated anti-tumor activity in vivo in C57BL/6 mice (FIG. 46). It was also demonstrated that dual-AAV delivery of an APCM library into fully un-modified parental E0771 cells can mediate anti-tumor activity in vivo in C57BL/6 mice (FIG. 47).

Example 2 1: AAV infectivitv in vivo by serotypes AAV infection efficiency across serotypes was assessed by intratumoral delivery of GFP-expressing AAVs and flow cytometry analysis (FIG. 48). Percentage of GFP+ cells within tumors from mice 4 days after intratumoral injection of PBS (n = 3) or AAV- GFP (n = 12), was grouped by CD45+ and CD45 cells. The background GFP fluorescence was set as the maximum % GFP positivity in PBS samples, denoted by a dashed line. Fractions above AAV conditions denote the number of samples with % GFP positivity above background in the indicated cell population. The data demonstrated that in vivo infectivity across different AAV serotypes was similar (FIG. 48).

Other Embodiments The recitation of a listing of elements in any definition of a variable herein includes definitions of that variable as any single element or combination (or subcombination) of listed elements. The recitation of an embodiment herein includes that embodiment as any single embodiment or in combination with any other embodiments or portions thereof. It is to be understood that wherever values and ranges are provided herein, all values and ranges encompassed by these values and ranges, are meant to be encompassed within the scope of the present invention. Moreover, all values that fall within these ranges, as well as the upper or lower limits of a range of values, are also contemplated by the present application. The disclosures of each and every patent, patent application, and publication cited herein are hereby incorporated herein by reference in their entirety. While this invention has been disclosed with reference to specific embodiments, it is apparent that other embodiments and variations of this invention may be devised by others skilled in the art without departing from the true spirit and scope of the invention. The appended claims are intended to be construed to include all such embodiments and equivalent variations. Table 4: Personalized sgRNA minipools: E0771 (TNBC) exome based PCAYac sgRNAs (SEQ ID NOs: 349-4,187), Lewis (Lung) exome based PCAVac sgRNAs (SEQ ID NOs: 4,188-7,980), and GL261 (GBM) exome based PCAVac sgRNAs (SEQ ID NOs: 7,981-11,808). SEQ ID SEQ ID SEQ ID

TTTCGGTTGTCTTTCTGCAG Pafal 349 TAAGTGACACGTGACTGCCC Dnajcl6 4169 ATGGGAGGGTCGCAACGACC Utfl 7989 o GCGGAGAGCGGGTCGCCCAC Npy 350 GTCGAGGAGCGGCTCCTTAA FbxoS 4170 ACTAAGAGGAGGGAGAAGGG Zkscan3 7990 b GGCGCGGGTTCGAGCACCTC 3830406C13Rik 351 CCCTTGCACGATCTGTGGGC BC049762 4171 GGCGCGAGTAGGACTGGGCC Dis31 7991 5 GGACTTCGATCTAGCATTCT AtpSal 352 CGAGTTCACCTATAGTACAT Dpysl3 4172 AGGTCCCATTGAATCACTAA Cox7c 7992 b CTTTAAATTGTGTTCTACTG Cfli 353 GACTGTAGAGATTGACGTGG Paxl 4173 CTCCCTGTGGTGGAGGCTCG Nme8 7993 o 4 GTGTGTGGGCAGAAGGCCAC 1700024P16Rik 354 TGACAAGCTAGATCCCTTTC Hfe 4174 AAATACAGCTTTCCTCAAGC Bmprlb 7994 TTAAACGCCCACTTCGGATG Satbl 355 AGCTGAACATAGCCCGGTTT Erbb4 4175 CGGCATGGCCCGACAGCCCG Cabp7 7995 ACGTTGTTAACCAAATCAAA Slcl7a3 356 TCTCTAGGCTCTAACCCGAG Tmeff2 4176 GGCAAGACCGGAGAGGAGGA Cln6 7996 ATGGGAGGGTCGCAACGACC Utfl 357 GTCCTTATTGCGGGCCGCGC Gmebl 4177 ACGTACCACGTGCCCAAACG Zmym6 7997 CTAGCΑ Α GGACTCACTAAA Bubl 358 GTCACCTTCGGAGTTCCCTC Fibin 4178 CCGAAGTCTGTCTGAGCCTG Fam219b 7998 ACTAAGAGGAGGGAGAAGGG Zkscan3 359 GCGCTCTGCTCGCTCCATTA Tmeml09 4179 CCCTCCCAAAGACTAGCGGG Tubb6 7999 CTCCCTGTGGTGGAGGCTCG Nme8 360 TCTGGCCCTAGATATAGCAG Osbp2 4180 TAGGTCTGAACTCCCTCTTA Hgf 8000 AAATACAGCTTTCCTCAAGC Bmprlb 361 GCACCTCGACTCTGGCGACC Impdhl 4181 GCTGCTACTCTCAGCACGCC Lama3 80 1 CGGCATGGCCCGACAGCCCG Cabp7 362 AGTCAAAGGTCGGTAAATAG Bsdcl 4182 TAGGTCATCGCTAGCAGGTT Arhgap26 8002 ACGTACCACGTGCCCAAACG Zmym6 363 GCAGCTCCAGCTTCTCTTTC Aox4 4183 CAGATTCCTCACAGTCAATA 0 1fr 6 8003 CAGATTCCTCACAGTCAATA 0 1fr 6 364 TGTTGGGCCCGCCTCTCCTC Fuom 4184 CAGACACTTTATCAGATAAG Cnga3 8004 CAGACACTTTATCAGATAAG Cnga3 365 GGAGAGAGAGAGAGGAGAGC Lrplb 4185 CCGCAGCTCTCAGACTTCTA Atl2 8005 ACTAGCCCTTGCGCCAAGGC Tsn 366 AGGTAGAGCGGTGACGCAGC Ar gef l 4186 ACTAGCCCTTGCGCCAAGGC Tsn 8006 CGGGCTCTCGGCGGTGGAGG Map2 367 GGCACTGAGGCATTGTGTGC Spinkl4 4187 GAGACCGGGCAAGTCCTGTG Bdnf 8007 AGGCAGCACATGCCGGCGTC Cede13 368 TTTCGGTTGTCTTTCTGCAG Pafali2 4188 GCTGCGGTCCCGCGGAAGGG Svbp 8008 GCTAACACCCTTGAGATTTA 4930430A15Rik 369 ACTTGCGTCAGGTCGGCAGC 0610009B22Rik 4189 AACACTGTTTAGCTATGGAT Xcrl 8009 TTTCAGGACTCGCCTTTATT 115 370 GCGGAGAGCGGGTCGCCCAC Npy 4190 TATCTAGGTCACCAGGTCTT Lce6a 8010 AGAGATAACTTCCGGGAGAT Slu7 371 CCGGTGGCGGCACCGGCCAG Prkcq 41 CGCACTAAACCAATGTTTAT Zfp691 8011 AGCTCTTACTATCTTACTTC Tgm6 372 CTTTAAATTGTGTTCTACTG Cfli 4192 GCTAACACCCTTGAGATTTA 4930430A15Rik 8012 CGAGGGCTGACTACCTATTC Ndufa4 373 CGGTCCTCTCTTCCTCCCAG Lhfpl5 4193 GAAGTGGGTGGAGATCAATA 9130008F23Rik 8013 GGCGGGATGTTCCCACGTGG Cox4i2 374 TGACCTCATAATGTTAACAT Wd 4 4194 TTTCAGGACTCGCCTTTATT 115 8014 CTGTCGCAAAGGCCACATCC Zc3hl5 375 GTGTGTGGGCAGAAGGCCAC 1700024P16Rik 4195 AGCGGTCGCAACTTTGGCGC Slc4a4 8015 TATCATTGTGATGCATACAA Cpxcrl 376 CAGTTACTCTGGCCCTAAAT Gm853 4196 AGAGATAACTTCCGGGAGAT Slu7 8016 AGGAAGTCAATACCGTCAGG Leprot 377 GCAGCAAAGAATTGAACGGA Zbbx 4197 GGCGGGATGTTCCCACGTGG Cox4i2 8017 CTAACAGTCTGTCTACTCCA Atg4c 378 ACGTTGTTAACCAAATCAAA Slcl7a3 4198 CTGTCGCAAAGGCCACATCC Zc3hl5 8018 CCCAGGGAGCAGCCTTGGAC An l 379 GACCTCTGGGCCAACGTTCC Dab2ip 4199 TGGGAAATAGCCCGTGTGAT Histlh3e 8019 AGTGTCAATGTTTGGTCGGA H2afv 380 ATGGGAGGGTCGCAACGACC Utfl 4200 TTTGGAGACGGAGACAGGTC Mcmbp 8020 TGATGAAACAGAGTGGCCTG Themis 381 CTAGCATAGGACTCACTAAA Bubl 4201 TTTGCTAGGCTGATTTGGAG SlOOalG 8021 CTTCCTTAACTGAGTGGTGG Zfp83 382 ACTAAGAGGAGGGAGAAGGG Zkscan3 4202 AGGAAGTCAATACCGTCAGG Leprot 8022 AAGCTGAGCAGAAGCAATGG Hp a 383 GGAGAGAGCCTGTGTCAGTG Spin4 4203 CCCAGGGAGCAGCCTTGGAC Anol 8023 CAACTCTAAGTTGGGAGCCC Sf3al 384 CTCCCTGTGGTGGAGGCTCG Nme8 4204 GGCGCCTCTCCGAATCCGGG Them4 8024 GAAACCTGCCACCTCTTACC Anxa6 385 CGGCATGGCCCGACAGCCCG Cabp7 4205 AGTGTCAATGTTTGGTCGGA H2afv 8025 n TGCGCGT CATTTGCAGTCTG Zfhx4 386 CAGCACAAATTC CCTTAGAA Scg2 4206 TCCTGCGGAGCGCTCCTAGA Iqch 8026 TAACTTATCCCATTTCAAAC Slcl7a3 387 TGGGAATGGTTCACTCCATT Nml 4207 GGTGGCGCGGCTGCGTCGTG Tspan5 8027 n TGGGAAGGCGCTTCGAGCGA Canx 388 ACGTACCACGTGCCCAAACG Zmym6 4208 ATAGACACTCAGCGCGCGCA Toel 8028 CATTGTGGGAGCCGCGCGAG Poiutl 389 GCTGCGATATGAATTTCTTC Trmt2b 4209 GGGCGGAGACTGACGCTTCC Ubaslt3b 8029 o CGCTCGCTCGCTCTCCTCAC Erbb4 390 TAGGTCTGAACTCCCTCTTA Hgf 4210 AAGCTGAGCAGAAGCAATGG Hpca 8030 5 GAGGAAGCCGAGACCTAAAT Slc9al 391 CAGATTCCTCACAGTCAATA 0 1fr 4211 CAACTCTAAGTTGGGAGCCC Sf3al 8031 GAACAGAGAGGGTCTTCTGG Tpte 392 CAGACACTTTATCAGATAAG Cnga3 4212 GAAACCTGCCACCTCTTACC Anxa6 8032 5© GGTTGTCACCTGCCGTGGGT Zfp467 393 AGGAGCGGAGATCTATAGCC Mier2 4213 AATGGGCAGGATGTCTAGCA S100a7a 8033 TACTGGTTGTTTACTTTCAA Nek 10 394 ACTAGCCCTTGCGCCAAGGC Tsn 4214 CCCTAGAAAGCAATCAGAGG Dao 8034 GCTAGAGTCATCTGAAAGGA Nrfl 395 AGGCAGCACATGCCGGCGTC Ccdcl3 4215 TAACTTATCCCATTTCAAAC Slcl7a3 8035 GACTCCTCCTTCAAGAATTG Sh3d21 396 GGGAAAGGGAGGCGGAGGCC Efhcl 4216 TGGGAAGGCGCTTCGAGCGA Canx 8036 GAATTAGGCGGGACCCTGGA Abcal2 397 TTTCAGGACTCGCCTTTATT 115 4217 CATTGTGGGAGCCGCGCGAG Pofutl 8037 TAGGATGCTAAGAGCTGTCA Ttc39a 398 AGAGATAACTTC CGGGAGAT Slu7 4218 GAGGAAGCCGAGACCTAAAT Slc9al 8038 AATTGACTGCTGCGATGGCT Ubr3 399 ACTTGGCGTCACAGCGCAAA Cd72 4219 CCCAGTGGAAGTCGTGACGT Isg2012 8039 GGTCCCGCATCTACTTCCGG Eya3 400 AGCTCTTACTATCTTACTTC Tgm6 4220 GACTCCTCCTTCAAGAATTG Sh3d21 8040 AGCCTTGCGTTACTTGTTTA Csmp3 401 GGCTGCCAGGCGTGTTCTTC Thgll 4221 GAAGGTGCGGGTCCGGCTGT Meal 8041 GCTGCCGCCTGGCTGCTCTG Prkg2 402 CGAGGGCTGACTACCTATTC Ndufa4 4222 AATTGACTGCTGCGATGGCT Ubr3 8042 GCACGCGTGATGGAGCTACC Zfp46 403 GGCGGGATGTTC CCACGTGG Cox4i2 4223 GGTCCCGCATCTACTTCCGG Eya3 8043 GAGCGACGAGGCCAGGTGGG Wwc2 404 TGGGAAATAGCCCGTGTGAT HistllGc 4224 CAACGTCAAGTGTTGCGTGG Ruscl 8044 TGGCTGAATGCACTCCACCT Ctrc 405 ACTGCAGAGAATGGACTTCA Pla2g4b 4225 GCACGCGTGATGGAGCTACC Zfp46 8045 TTTCCCATCCCGTCATGGGC Clqtnf2 406 TATCATTGTGATGCATACAA Cpxcrl 4226 GCACACCTGCATCCTAGCCT Podn 8046 AGTGGGCGTGGGTAGCCCGC Eril 407 AGGAAGTCAATACCGTCAGG Leprot 4227 GCTGAAGCCTTATCCTCTTG Ptk6 8047 GTAGAGTCCTCTGACCCAGA 1600015I10Rik 408 CTAACAGTCTGTCTACTCCA Atg4c 4228 AAAGGAACTGCGTTCATTGA Dtna 8048 TTCAGCACTCTGATTTGTCA P2iyl2 409 CCCAGGGAGCAGCCTTGGAC Anol 4229 TGCATCTATGTCACATGGGC Arhgdib 8049 CTTAGGATGTGCATGTGACA 01fr56 410 AGTGTCAATGTTTGGTCGGA H2aiV 4230 AGCCGTGAGCCCTTCTGTCC Bnip2 8050 GGAAATCCTGTCACTCAGCC Stab2 411 CTTCCTTAACTGAGTGGTGG Zfp831 4231 CGCGAACAATGCTGTGACCC Mrps 10 805 1 CAAGCGCCACAGACAATAAC Lirak2 412 AAGCrGAGCAGAAGCAATGG Hpca 4232 GGCGGCCGGGCGCGCGCCGG Zbtb46 8052 ACAACATACCCGTCACCCAA Tgm3 413 CAACTCTAAGTTGGGAGCCC Sf3al 4233 TTTCCCATCCCGTCATGGGC Clqtnf2 8053 CAGTTGCTAAGGAAACGACG C k 414 GAAACCTGCCACCTCTTACC Anxa6 4234 AACAGGCCACAGAGTGGGAG Islr 8054 ACGTGAATACAGTGCTCAGC Ab a a 415 GCTTCCTGCTCCACCCTCAT Gimap3 4235 GGTAGTTACAAAGGCATAGA Otog 8055 TAGGAACGCTTGCAACAGTG Slc35e4 416 TGCGCGrCATTTGCAGTCTG Zflix4 4236 GAGGACAGGCTCCAACCAAA Adamtsl4 8056 AGGGCGTGTCCTTGTAGTGG Cdc42se2 417 CGATAGATGCTCTGCGGCCC Sc a 4237 CTTAGGATGTGCATGTGACA 01fr56 8057 ACTCACCCAGAAGCCTCTAG Hjurp 418 TCAAATTCTGGCTTTCTATT Histlh2ab 4238 CAAGCGCCACAGACAATAAC Limk2 8058 GACGCGCTAAGCAAGGGCAG Mme 419 TAACTTATCCCATTTCAAAC Slcl7a3 4239 AACGGGAAGTCTTTGGTCTC Adgrfl 8059 ACGTTAACGGGTGGGTTCCC Zzefl 420 TGGGAAGGCGCTTCGAGCGA Canx 4240 TAGGAACGCTTGCAACAGTG Slc35e4 8060 CATGTGGTTGGCTAGAAGCA Ctrc 421 CATTGTGGGAGCCGCGCGAG Pofutl 4241 ACGGGAGGGCGCCGGCCCGG March5 8061 AGTAGAGTGGATTATAAGAC Olfrl370 422 CGCTCGCTCGCTCTCCTCAC Erbb4 4242 AGGGCGTGTCCTTGTAGTGG Cdc42se2 8062 GGGATTGCTATCGCTTTAAA Grm7 423 GAGGAAGCCGAGACCTAAAT Slc9al 4243 GGGCGGTGATGGACTCAGCG Calcoco 1 8063 GCTGCTTAGTCTGTCTTCTC Plic2 424 GGTTGTCACCTGCCGTGGGT Zfp467 4244 CTGCAGCGAGGTCCGGACGC Sehll 8064 TGGAAGAGATGTGAGTCTGC Gabrg2 425 TGGACTGTTACACTGCGAAC Pcedla 4245 ACAAGGGCGGTCACGTGCGA Nptn 8065 GTCATCCTGCTTATGCAAGA Tgm3 426 TACTGGTTGTTTACTTTCAA NeklO 4246 ACTCACCCAGAAGCCTCTAG Hjurp 8066 CGCCGGGCTTCGCCTCCAAG Hmcnl 427 GCTAGAGTCATCTGAAAGGA Nrfl 4247 AGTAGAGTGGATTATAAGAC Olfrl370 8067 AGAGCGCCTTCAGAGAAATG Tpx2 428 GACTCCTCCTTCAAGAATTG Sh3d21 4248 CGAGTGCCGAGCGCGCCGAG Hdgf 8068 CTTCTAGAACGACAAGGGAA Cela2a 429 CATTGGCTAGTACGTTCCAT Ska2 4249 CAAGTTGGCTAGGAGCCCAG Lraanll 8069 AGCAGCAGGATTTAGAGGGA Gm597 430 GAArTAGGCGGGACCCTGGA Abcal2 4250 AATCGAATGCGCAAGACTGG Gria2 8070 GAGGATCAGCGCAAACGTGG Mcts2 4 1 TAGGATGCTAAGAGCTGTCA Ttc39a 4251 GCTGCTTAGTCTGTCTTCTC Phc2 8071 ACACACCGCGGACGAGCTGG Pkhdlll 432 GGTCCCGCATCTACTTCCGG Eya3 4252 GGTGGATGAGGTCATCGGCT Nlrxl 8072 TTGTCATCCCAGTAGCAAAG Tmco5b 433 TCCAATTGGAGCAACCTACG Ankmy2 4253 TGGAAGAGATGTGAGTCTGC Gabrg2 8073 TGACTAGGTCTAAACGCTCT Faml50a 434 GCACGCGTGATGGAGCTACC Zfp46 4254 AACTTGCCTACCCTGAGCAA C130074G19Rik 8074 GGGTGGCAGTTCAGATCATC Sgipl 435 GAGACAGATGGCCCATGGAA Rnfl65 4255 CGCCGGGCTTCGCCTCCAAG Hmcnl 8075 CCGATGGCGAGCATTGGTTG E2fl 436 GAGCGACGAGGCCAGGTGGG Wwc2 4256 AGAGCGCCTTCAGAGAAATG Tpx2 8076 GATGGTATCAGCCTGTCTTC Serpinb9c 437 TGGCTGAATGCACTCCACCT Ctrc 4257 CCCGGGCGCTGCTGGTCGAA Pabpc4 8077 ATTGGAGTCGCGTCTGCAGG Ada 438 TTTCCCATCCCGTCATGGGC Clqtnf2 4258 GAGGATCAGCGCAAACGTGG Mcts2 8078 GCTCTTACATGGTCCTCACC Aven 439 GGTAGTTACAAAGGCATAGA Otog 4259 ACACACCGCGGACGAGCTGG Pkhdlll 8079 GGCTGGCTCCTGGCGGAGCG Ankrd44 440 AGTGGGCGTGGGTAGCCCGC Eril 4260 GGGTGGCAGTTCAGATCATC Sgipl 8080 TGGCTAGGGCGCATCTGCAG DocklO 441 GTAGAGTCCTCTGACCCAGA 16000 1 1lORik 426 CCGATGGCGAGCATTGGTTG E2fl 8081 CACTGAAGTAGAAACACATG Themis 442 GGACCAACAGATGGCAGGCC Cggbpl 4262 GATGGTATCAGCCTGTCTTC Seq)inb9c 8082 GTGTAGGTGAATACTGATAA Skint8 443 CTTAGGATGTGCATGTGACA 01fr56 4263 ATTGGAGTCGCGTCTGCAGG Ada 8083 AGTAAATCTGAGCCACGCCA Skint10 444 CAAGCGCCACAGACAATAAC Limk2 4264 GGGAGCACGCGACCATAGAG Tcf4 8084 TCAGGCTTGCAGAATCATAG Skint3 445 ACAACATACCCGTCACCCAA Tgm3 4265 TGGCAGTCATGGACATGCAG Zbtb46 8085 o GCGCTGAAAGAGCTGATTTG Sndl 446 CAGTTGCTAAGGAAACGACG Crnkll 4266 ACAGCGGTCGGTCGGAATGC Bdnf 8086 TGGAGGGCGGGCGTTGCAGA Mgatl 447 GGATCCTAGTGTTTCACGTG Ctcl 4267 GTCACCTGTTTGGGACGCCA Ndufaf7 8087 ACTTGTGATACCGCACACCT C8b 448 TAGGAACGCTTGCAACAGTG Slc35e4 4268 ACGTAAATCGTCCATAGCAC Tuftl 8088 b AATCAGATACCATATTGCTA Btk 449 AGGGCGTGTCCTTGTAGTGG Cdc42se2 4269 CGGCCTCACACCCAACCTGG Hdgf 8089 o AGTGCCGCCCTCrGGCGGCT Lsmll 450 GCCAGCTGTAGGGAGCAAAG Alx4 4270 CATGGACTACATACAGTCTT Gm7361 8090 4 GTCGCGTGCCGGTGTCGCCG Sdc3 451 CGCGGCAGCCGACCTGGTGC Runxltl 4271 TACAGATTAAGTGCTTCATG Asic5 8091 TTTGAAACGTCTCCAACGAT Stpgl 452 ACTCACCCAGAAGCCTCTAG Hj p 4272 AATGAGTCATTTGACGCTCC Sh3rf2 8092 TAATTAGCTCTTATCCCTAT D7Ertd443e 453 CATGTGGTTGGCTAGAAGCA Ctrc 4273 GTCGCGTGCCGGTGTCGCCG Sdc3 8093 TCCTTGCAATGACAAACCTG Agraat 454 GAGCGCGCGCGAGGCCTCTC Oprdl 4274 TGACATTAAGTACTCAGTGT H2-M3 8094 AGAAGCTGAAATCTAGAACT Timd2 455 AGTAGAGTGGATTATAAGAC Olfrl370 4275 TTTGAAACGTCTCCAACGAT Stpgl 8095 ACCGGGAAGAGGTGGGAGAC Fg 456 GGCTTGATTTCGATAACTCA Gda 4276 TAATTAGCTCTTATCCCTAT D7Ertd443e 8096 CGCCCACCGTGGCTGAGTCC Dclkl 457 ACGCAACACTGACGGACGAG Nrxn2 4277 AGAAGCTGAAATCTAGAACT Timd2 8097 CACTTCTAAACTACAGAAAT Bpifal 458 GCTGCTTAGTCTGTCTTCTC Phc2 4278 TGCGTATACGTCAGTCCCAA Sin3a 8098 GCAGGAGGCAGCGTCGGCCC Ankrd44 459 TGGAAGAGATGTGAGTCTGC Gabrg2 4279 ACGCGGCTTCAGACGTCTGC Vars2 8099 CCCTTCGCTAGCCGGGACCC Ago4 460 AAAGTAGTGGGTTCATGGGT Histlh2bc 4280 GGTGAGGCCCAGGTGCGGAC Sult6bl 8100 TTCTGCCTTGTAAGGCCGGG My19 461 GTCATCCTGCTTATGCAAGA Tgm3 4281 ACCCTAAACATGATGTCATC Carl2 8101 AATCTTTAGGTCTCAGTTCC Iqub 462 AGAGCGCCTTCAGAGAAATG Tpx2 4282 CGCTCGGCCGCGCGTCGGGA Raplgdsl 8102 CGCCTGAACrrCCTCCTGCG Lyrm7 463 CTTCTAGAACGACAAGGGAA Cela2a 4283 GGGCGTGGCCTCAAGTGGGC Fez2 8103 AAGGAACACACCTTTAATCG SpllO 464 GAGGATCAGCGCAAACGTGG Mcts2 4284 ACCGGGAAGAGGTGGGAGAC Fgf3 8104 TCTCTGGCCTTTACAGCAGC Lepr 465 ACACACCGCGGACGAGCTGG Pkhdlll 4285 CACTTCTAAACTACAGAAAT Bpifal 8105 GCCCTTCTCTCCTACGCCCG Phykpl 466 GGGTGGCAGTTCAGATCATC Sgipl 4286 GCCGGACTCGGCCTCACACG Exosc7 8106 + CTGCTATGTGGCTCTTCTCA Morel 467 CCGATGGCGAGCATTGGTTG E2fl 4287 CCCTTCGCTAGCCGGGACCC Ago4 8107 GCTCTTTAGGTTATTGGATC Pdyn 468 GATGGTATCAGCCTGTCTTC Serpinb9c 4288 TTCTGCCTTGTAAGGCCGGG Myl9 8108 ACACATGGGCTTTCTTGAAA Gimap5 469 ATTGGAGTCGCGTCTGCAGG Ada 4289 ATAACTGCAGAAAGTTCGGG Gbp3 8109 CAAGCAAGTCATGATGAAAC Skint7 470 GTGTAGGTGAATACTGATAA Skint8 4290 CGCCTGAACTTCCTCCTGCG Lyrm7 8110 TCTGGCTTCTCTACCGTCAG Zfp956 471 AGTAAATCTGAGCCACGCCA Skint10 4291 GAGATCAGGGCCATTCTTGC Col5a3 8111 CGCTCTATCTCCTTAAGAAC Mat2b 472 TCAGGCTTGCAGAATCATAG Skint3 4292 AACTTTGGAGCAGGAGTAGG Cd38 8112 GTTCCTTCCCACCCATCGGC Osbp2 473 GCGCTGAAAGAGCTGATTTG Sndl 4293 GAGCCCGGCGAAGAGTTCAG Stard6 8113 CGGCGGCGGCAACTCCGCAT Elmol 474 TGGAGGGCGGGCGTTGCAGA Mgatl 4294 ATCCACGTGGCAGAGGGACC C2cd4a 8114 ACAAGTATCCTACACCAAAG 01fr56 475 ACTTGTGATACCGCACACCT C8b 4295 TCTCTGGCCTTTACAGCAGC Lepr 8115 GGGAGACTAGGAAACTGGAG Zfp467 476 AATCAGATACCATATTGCTA Btk 4296 GCCCTTCTCTCCTACGCCCG Phykpl 8116 ACTGACGCAGCGCGGGCGCG Asxll 477 GAAATACTCGGAGAGCAAGG Rackl 4297 CGCTCTATCTCCTTAAGAAC Mat2b 8117 GGCCTTGACGAAGCTAGCCC Atoxl 478 AGTGCCGCCCTCTGGCGGCT Lsmll 4298 GTTCCTTCCCACCCATCGGC Osbp2 8118 CGAGAGACAATATGGCCGCG Dhx35 479 GTCGCGTGCCGGTGTCGCCG Sdc3 4299 TGGGTCTCTAAACTGCTTAA Kdm4c 8119 CTGTGGCTCCAGTCCCAGTT K td 480 TTTGAAACGTCTCCAACGAT Stpgl 4300 CGGCGGCGGCAACTCCGCAT Elmol 8120 GATATGCAAGATTCTACTTT Histlhlt 4 TAATTAGCTCTTATCCCTAT D7Ertd443e 4301 ACAAGTATCCTACACCAAAG 0 1fr 8121 n TTTGAGTATCTACACGGTGA Ogdh 482 TCCTTGCAATGACAAACCTG Agmat 4302 ACGTCCCATTGCTGAGCCCG Smad6 8122 ATGCTGCAGTAATAATCGCA Lepr 483 AGAAGCTGAAATCTAGAACT Timd2 4303 ACTGACGCAGCGCGGGCGCG Asxll 8123 ATTATCTAGGGTGGCTGCTG Commd7 484 ACCGGGAAGAGGTGGGAGAC Fgf3 4304 GGCCTTGACGAAGCTAGCCC Atoxl 8124 n TTTACCCGCGGTGCATGTTG Kiz 485 CACTTCTAAACTACAGAAAT Bpifal 4305 CGAGAGACAATATGGCCGCG Dhx35 8125 o CAATCATTGGTTCTAATCCA Ntm 486 GCCGGACTCGGCCTCACACG Exosc7 4306 GATATGCAAGATTCTACTTT Histlhlt 8126 ACATCACCCArCTCTAGCCC Rifl 487 CCCTTCGCTAGCCGGGACCC Ago4 4307 GCGGGATCTCAAGTGGTCCC Epha6 8127 GCCGCGGGCTCGCTCCACCC Xkr8 488 TTCTGCCTTGTAAGGCCGGG Myl9 4308 TTTGAGTATCTACACGGTGA Ogdh 8128 TGAGCACAGAGTCCCGCTAG Viprl 489 AATCTTTAGGTCTCAGTTCC Iqub 4309 ATGCTGCAGTAATAATCGCA Lepr 8129 J AGGATTAACACTGGAGAACA SpllO 490 CGCCTGAACTTCCTCCTGCG Lyrm7 4310 GGATAACCCTTGAGCAAATT Pkm 8130 GAGCCAGAGGAAAGAAAGCC Cdh26 491 TCTCTGGCCTTTACAGCAGC Lepr 4 1 ATGAAATTGAGTCATGCCAT Fcrll 8131 AGTCAAGAGCAGGTGCCGCC Ccdc85a 492 GCCCTTCTCTCCTACGCCCG Phykpl 4312 ATTATCTAGGGTGGCTGCrG Commd7 8132 TATTGCTGGAAGACAGAGAG Grm5 493 ACACATGGGCTTTCTTGAAA Giraap5 4 CAGGCGACGCCCATTGCCTA Meal 8133 o TTTATAGCTCTCACTCAAAG Slc26a4 494 GTTGTTGATTCATATGCAAA Hdac9 4314 AAGGCCTATGTACCCTTGGG Zbbx 8134 CCCAGTAGGCTGTGGCCCAG Vps41 495 CAAGCAAGTCATGATGAAAC Skint7 4315 GCCGCGGGCTCGCTCCACCC Xkr8 8135 ACCAGCTCCGGTTTGGCCAC Repinl 496 TCTGGCTTCTCTACCGTCAG Zfp956 4316 TTGAGAACCTACTGTATArG Ccdc33 8136 5 TGGACTAACCTGAGCGCCGA Limk2 497 CGCTCTATCTCCTTAAGAAC Mat2b 4317 CCCAGTAGGCTGTGGCCCAG Vps41 8137 o CGCTGTGCGCTAGATTGCAA Rraga 498 GTTCCTTCCCACCCATCGGC Osbp2 4318 TAATCCTCTGAAACCTTAGT Ctbp2 8138 4 CATGATGAGGTCAAAGAATT Slcl7al 499 CGGCGGCGGCAACTCCGCAT Elmol 4319 TGGACTAACCTGAGCGCCGA Limk2 8139 AGAGCTCGGAGGTGTGGGTA Nipsnapl 500 CACTTTCTTCGAGGTTTGTG Steap2 4320 CGCTGTGCGCTAGATTGCAA Rraga 8140 GAGGTAGACAAGTGGTCTGG Asap3 501 ACAAGTATCCTACACCAAAG 01fr56 4321 TCAGGAAATCTCAGCTATCA Fbxw7 8141 TGGTACGGCCCAGCGCTAGC Psipl 502 GGGAGACTAGGAAACTGGAG Zfp467 4322 AGAGCTCGGAGGTGTGGGTA Nipsnapl 8142 GAGTCTCTCTGACAGGGCGG Myo9a 503 GTTGGGTATATGCTGTTATT Dab2ip 4323 GACCTTAACCCTTCCGACCC Lama5 8143 TGTAGAGAGTGATAAGGGTT Pramef25 504 ATGTCACTTCAGTGTGGGCG Nrg4 4324 GAGGTAGACAAGTGGTCTGG Asap3 8144 GTACTTAAGAGTGTTCTAGG Foxp2 505 ACTGACGCAGCGCGGGCGCG Asxll 4325 CCTGACAGCTGGAAGAAACA Arhgefll 8145 TACCAGTAACAGACTCATGG Rab42 506 GAGGGTGTACAGGAAGCTAG Fam50a 4326 GCTTACTGAGTGTGTGCTTT Vit 8146 GGTTTGGTATCTTCCATGCA Rps6ka6 507 GGCCTTGACGAAGCTAGCCC Atoxl 4327 ACTGCAGTTGCACAGGAGAG Eif2ak2 8147 CGCTGAGCAGGGCGAGTGAC Smarca2 508 CGAGAGACAATATGGCCGCG Dhx35 4328 AGAGTGGGTGGTGTTATAAA Cypla2 8148 AGCCAGAAGTAGAGATTGTT Iqub 509 AGATAAGGGTAGTAGGGATG 9530002B09Rik 4329 GAGTCTCTCTGACAGGGCGG Myo9a 8149 TGTAATCACGAGTACTTCCG Ms4a7 510 GATATGCAAGATTCTACTTT Histlhlt 4330 GCCCTGACACAAAGCAAATC Slc37a2 8150 CTTGTTTATTGTCGCGCCGC SlitrkS 511 GCGGGATCTCAAGTGGTCCC Epha6 4331 GTACTTAAGAGTGTTCTAGG Foxp2 8151 GTCTGCCTGGCGACCTTGAT 2 1014lK09Rik 512 TTTGAGTATCTACACGGTGA Ogdh 4332 TACCAGTAACAGACTCATGG Rab42 8152 GGGTACAAAGGTGCCTAGTC I122ral 513 ATGCTGCAGTAATAATCGCA Lepr 4333 GATGACGTCACCGCCGACTG Snapc5 8153 GCGCCAGAGTTGCAGGCGGG Ada 514 ATTATCTAGGGTGGCTGCTG Commd7 4334 GACTCTAAAGACACGGTGTG Zfp6 1 8154 GACCAGTAGATGGCTCATAA Stard3nl 515 TTTACCCGCGGTGCATGTTG Kiz 4335 GTCTGCCTGGCGACCTTGAT 2410141K09Rik 8155 GGCAGTGGGAGGTGCTGAGC Synel 516 AAGGCCTATGTACCCTTGGG Zbbx 4336 GGGTACAAAGGTGCCTAGTC I122ral 8156 TGGCAAGACTTGACTTATCC Skint3 517 GCCGCGGGCTCGCTCCACCC Xkr8 4337 TAAGGAAAGACGGCCCTGAG Tpm3 8157 TCTTCGTAAGCGTGAAGCGC Kctd3 518 TGAGCACAGAGTCCCGCTAG Viprl 4338 GCGCCAGAGTTGCAGGCGGG Ada 8158 TGTACTGATCTGGGATCTCA Plin2 519 AGGCACGCCAGGTCTAAATG Car5b 4339 GACCAGTAGATGGCTCATAA Stard3nl 8159 AACATGGAGAGAGTGTTAGA Sis 520 GAGCCAGAGGAAAGAAAGCC Cdh26 4340 CGTCACGGGCGTCGCAGGCT Cepl26 8160 TTTGTTCTGAGAGGGAGAGA Nipbl 521 AGTCAAGAGCAGGTGCCGCC Ccdc85a 4341 TAGGCTTTGTCTAAGACCCG Tubb5 8161 CGAGTGAGCCCACGAGAGCC Rpe 522 TATTGCTGGAAGACAGAGAG Grm5 4342 GGCAGTGGGAGGTGCTGAGC Synel 8162 ACAACCTCAAGAAGTTAAAT Cdh26 523 AATCTGCCGCTGTACTCTGT Arhgap28 4343 TCTTCGTAAGCGTGAAGCGC Kctd3 8163 GTTCAGCTACCGCAATCCAG Fstl5 524 CCCAGTAGGCTGTGGCCCAG Vps41 4344 TTTCACTTTGTCTGTAGGGC Fcrl5 8164 TTAAATAGGACAGTTCGGCC Sfpq 525 ACCAGCTCCGGTTTGGCCAC Repinl 4345 TGCCATCCTTCGCTCCTCGC Kcnn3 8165 ACGCGAACGCTATGGACACG leal 526 TGGACTAACCTGAGCGCCGA Limk2 4346 TGTACTGATCTGGGATCTCA Plin2 8166 ATTCACCACAAGCACAGCAA Kndcl 527 CGCTGTGCGCTAGATTGCAA Rraga 4347 AGATGCAACCCACGCAAGTC Νρ1 4 8167 ACTTTGGTTCCTCACATGGC Wdr36 528 AACGGACTTCTCCTACTTAT Histlh2bc 4348 GTTCAGCTACCGCAATCCAG Fstl5 8168 GGACGAACAGACACGTGCTG Met 529 AGAGCTCGGAGGTGTGGGTA Nipsnapl 4349 TTAAATAGGACAGTTCGGCC Sfpq 8169 n TGTCATGGTTTGAAATCCTG P c2 530 GGAAGGGACTGTTTGAGCGA Chn2 4350 ACGCGAACGCTATGGACACG leal 8170 GGAAAGCTGATGCGCAGGCG D330045A20Rik 531 GAGGTAGACAAGTGGTCTGG Asap3 43 CCTCGGTGATTTAAAGCGTC 2810403A07Rik 8171 GAATTTGGTTGTAAATAACG Pesl 532 TGGGTTTGAAATAAATGTCC Gdf9 4352 ATTCACCACAAGCACAGCAA Kndcl 8172 n CGGACCGGAAGTAGTTACAG Chchd5 533 AATCCTACCCGTTTGCGGTT Nrg4 4353 GGCCAGCCGAGTGATAAGGC Cd276 8173 GGGCAGACCTCAACACTTCC Tmeml76b 534 GTACTTAAGAGTGTTCTAGG Foxp2 4354 ACGGAGGCGGTCGTCAAGCC Pex6 8174 5 GCTTTAAGAAGGTGCGGAGG Rein 535 TACCAGTAACAGACTCATGG Rab42 4355 TGTCATGGTTTGAAATCCTG Pnrc2 8175 TTACTTGAGACCATCTGAGG Elavl4 536 GGTTTGGTATCTTCCATGCA Rps6ka6 4356 GAATTTGGTTGTAAATAACG Pesl 8176 5© CAGTGACCACATGAACCTTG Aoa 537 CGCTGAGCAGGGCGAGTGAC Smarca2 4357 GTTGGACGGAGTCTAAGCCC Ptpn2 8177 TTTGTGAAGGCTTTCTGCAC Rapgef6 538 TGAAAGAGTGGGACTGTTTG Ube2h 4358 CGGAGTCAAGTCCGCTAGAG Piasl 8178 TTCTCTGGAGAGCATCTCCC Plbl 539 AGCCAGAAGTAGAGATTGTT Iqub 4359 CAGTGACCA CATGAACCTTG Aoa 8179 TCTGGCTGCGAAGGTGCGTG Tes 540 GTCTGCCTGGCGACCTTGAT 2410141K09Rik 4360 TTTGTGAAGGCTTTCTGCAC Rapgef6 8180 GCAGCrCTGTTCTTGAATGA Skint11 541 GGGTACAAAGGTGCCTAGTC I122ral 4361 ACTAGCCTGAAATGACTGAG Muc5ac 8181 o AACGCCGCCCGCCCGTTGCA T xl 5 542 GCGCCAGAGTTGCAGGCGGG Ada 4362 AGCAGCATTCGCrCGGFTTC Atp8b2 8182 GCTCACCTGGGAGCTTCCTA Ada 543 GACCAGTAGATGGCTCATAA Stard3nl 4363 CAGTAGTCCTAAATCArCAG Gbp2b 8183 TCACCCTGGCAACCGCGGCT Fsdll 544 GGCAGTGGGAGGTGCTGAGC Synel 4364 TGGCTAAACCATTGACGGAT Sin3a 8184 TGGAACGGAAGTTCCGGCGG Lypla2 545 TGGCAAGACTTGACTTATCC Skint3 4365 GCTCACCTGGGAGCrrCCTA Ada 8185 o GTCCGACrCTTGGTTCCCTC Ascc3 546 TCTTCGTAAGCGTGAAGCGC Kctd3 4366 TGGAACGGAAGTTCCGGCGG Lypla2 8186 4 AGAGCCTTGCTGTAGAAGCC Oca2 547 TGTACTGATCTGGGATCTCA Plin2 4367 GGAATACAAATTCTCTACCC Celf3 8187 AAGTCCGTTGACTTCCCAGC Nrlh5 548 AACATGGAGAGAGTGTTAGA Sis 4368 AGAGGTGTAACAGGGTGTAG Pig 8188 GGTGTGTCCGCGCACCACGG Pdikll 549 TAAGATCTGCAAATGAGAAA Spata31 4369 AGGAAGATGCTGGGAGCATT Lce3f 8189 GACCCAGAAAGGCGAAGTGA Slu7 550 ACAACCTCAAGAAGTTAAAT Cdh26 4370 TGTTTCCAAGATTTCTGACA Lce3f 8190 AGCTCGAAAGAGCCAATCAG Mllt3 551 TTCTCTGATTAACTTTCCAC Igfl 4371 GGAACAGTGAAGGGATGGGA Tpm3 8191 GAGAGGGATGTCTGCAGCGC AW551984 552 TTAAATAGGACAGTTCGGCC Sfpq 4372 ACAACCGGGACAGGTTGCCG Txnrdl 8192 TGGTGGCACATCCCAGCCCT Ide 553 ACGCGAACGCTATGGACACG leal 4373 GGTGTGTCCGCGCACCACGG Pdikll 8193 GGAAGAAATTCAAACCGAGA Cntnap2 554 ATTCACCACAAGCACAGCAA Kndcl 4374 TCGATTGTTTCTGACGGACT 1190007I07Rik 8194 AACTGGAAGTGTGGTGGGCG Map3k7 555 GGGCGTGGTTGTGGGCGGTG Rai2 4375 CCTGCTCAGTTCGCAGGGTG Tcpll 8195 CCACGCCTCTTCGCGCTAAC Actr5 556 GGACGAACAGACACGTGCTG Met 4376 GACCCAGAAAGGCGAAGTGA Slu7 8196 TGTCGGGACACAGGACCCTC Faml50a 557 TGTCATGGTTTGAAATCCTG Pnrc2 4377 AGCTCGAAAGAGCCAATCAG Mllt3 8197 GGCTGTCTGCCAAGAGTTCG Mdfic 558 AGAGTCCGTTTGTAAACCTT Cyp2rl 4378 GAGAGGGATGTCTGCAGCGC AW551984 8198 CCCTGTTTCCTGCCCAAGTC Ncmap 559 GAATTTGGTTGTAAATAACG Pesl 4379 GTGCACATCGCTCGCTATCC Femlb 8199 TTTGATAGGCGGAGTTACGG Pde4b 560 TTCTATAGTGACGGCGCGTC Ctcl 4380 CCACGCCTCTTCGCGCTAAC Actr5 8200 GTTGTCATCTAATCAGCTAC Ub 2 561 CGGACCGGAAGTAGTTACAG Chchd5 4381 AGTGTGCACCACGCGCTGAT Col5a3 8201 GCTCGAGCCAATCCAACGGG Rifl 562 TCAAGGTGACATTGTTTCCC 5430401F13Rik 4382 AAAGCCGCACTCACGGGAGG Pars! 8202 TATCACACAAAGTGACTTTA Ave 563 GGGCAGACCTCAACACTTCC Tmeml76b 4383 GGCGGGTAGGTAGACATGCT Rpap2 8203 GGGTCGCTGAGCCGGTGCGC Hcrtrl 564 TTACTTGAGACCATCTGAGG Elavl4 4384 CCCTCGCTCCTCTCCTAGTG Ddrl 8204 CCCGCGATGGCTAAGGAATG Asxll 565 TGCATTCTGCCTATAGACCC Slc45al 4385 CCCTGTTTCCTGCCCAAGTC Ncmap 8205 GGGACAAAGAGCGTGGCCTA Sla2 566 CAGTGACCACATGAACCTTG Aoa 4386 CAGCAACAGGTATAGCGCTC Rcn2 8206 GGGCCTArACrGAGAGATGG Klhll 567 ATCTGATCAGTTTGCTGAGC Fgf20 4387 AGCTTTAGAACTAACAAGTT Pstpipl 8207 CCGAGGTTCCCAAACCTAGA Prex2 568 TTTGTGAAGGCTTTCTGCAC Rapgef6 4388 CGCGGCTCTGATTGGAAGGT HiOa 8208 TTGACAAGGCGATGTTTGCA Bpifb2 569 AGAGCAAGTTTGAGTACGTG Thgll 4389 AATGAGATCGCCTCTACCAC Jtb 8209 GGTGATGCrGGATGTGTTTG Tctexldl 570 GCTGTTGAGAGTCACATGAA Za 4390 GAAGAGAGCGAGCTTGAAGA Dnphl 8210 CGGGTGCGATGTTGACAGCC Csmp3 571 TCTGGCTGCGAAGGTGCGTG Tes 4391 GGGTCGCTGAGCCGGTGCGC Hcrtrl 8211 ACTCACTTGGTTGCGCGACG Tcergll 572 GCATGGGAACCGCTTGGTGG Trpcl 4392 GTCAGCTATCACGTGGAGGC Recll4 8212 TGGCTAAAGTAGAGCTCTTG Sh3d21 573 GCAGCTCTGTTCTTGAATGA Skintll 4393 CACACAACGTTTGCAGAACG Marchl 8213 TCTCGGAGCCTCAGACGCTC Sf3al 574 AACGCCGCCCGCCCGTTGCA Tbxl5 4394 CCCGCGATGGCTAAGGAATG Asxll 8214 GGGCAGTCCGGAGTCCGTCC Prom2 575 GCTCACCTGGGAGCTTCCTA Ada 4395 GGGACAAAGAGCGTGGCCTA Sla2 8215 AATACTCTGGGAACACCGAT Dnah6 576 TTCCCTTCCGGGCTGTCGCG Ykt6 4396 CGCGTCTCACACTCGGCGGT Enpp4 8216 GGCTGTCArrAGCAGTTACA Ogd 577 TGGAACGGAAGTTCCGGCGG Lypla2 4397 GGTGAACTCCTTGGGTAGCG Pold2 8217 n TGGATCCGTGGCGCCTCGCC 573Q409E04Rik 578 GCAACCGCAGTGACAGCCGG Phfl2 4398 AGGGAGCCAGGATGAACTGT Inpp5f 8218 TAGCGGCGCGCGCGCGGGTT Fsdll 579 GGTGTGTCCGCGCACCACGG Pdikll 4399 TTGACAAGGCGATGTTTGCA Bpifb2 8219 GGGTCAAACTGCGATTCCGT Ascc2 580 GACCCAGAAAGGCGAAGTGA Slu7 4400 CTTCTGCAACATCTTCCTTC P3hl 8220 n CCCTCCTACCTGCCTACTCT Cstll 581 AGCTCGAAAGAGCCAATCAG Mllt3 4401 ACTCACTTGGTTGCGCGACG Tcergll 8221 o CGTTACTTCACTGAGGCAGA Ppargcla 582 GAGAGGGATGTCTGCAGCGC A 551984 4402 TGGCTAAAGTAGAGCTCTTG Sh3d21 8222 TGCTACATAGTTTAAGAGCC Zfp398 583 GGAAGAAATTCAAACCGAGA Cntnap2 4403 GCAAAGCACCAGAGTTGACC Kcnq2 8223 GGGCCCAAGAGATGAGCCAC Gjb4 584 TAAAGCGAGGACTAGCCAAT Ppfial 4404 TCTCGGAGCCTCAGACGCTC Sf3al 8224 CTCTCACGTCCCGGCGGCTG Husl 585 CCACGCCTCTTCGCGCTAAC Actr5 4405 CCCAGGTCCGAGGTGAGTTG Carl2 8225 J CTCCACCCAAAGCCACGGGC Adgrdl 586 GGCTGTCTGCCAAGAGTTCG Mdfic 4406 TTATAAGTTTCTAGACCTGA Zfyve9 8226 GAGACCTGTCAGCGCCCGCG Slc9al 587 CCCTGTTTCCTGCCCAAGTC Ncmap 4407 GGCTGTCATTAGCAGTTACA Ogdh 8227 GCACCCA CCCATATTG A Inpp5j 588 TTTGATAGGCGGAGTTACGG Pde4b 4408 TGGATCCGTGGCGCCTCGCC 5730409E04Rik 8228 TAATCTCATTAACGCGCGCG Slc6a20a 589 GTTGTCATCTAATCAGCTAC Ube2u 4409 GGGTCAAACTGCGATTCCGT Ascc2 8229 GGCTGAGGAGCTCCGCGCAC Fa l 6a 590 GGGECGCTGAGCCGGTGCGC Hcrtrl 4410 CGTTACTTCACTGAGGCAGA Ppargcla 8230 CGCATTTAGTAATACGCGCG Rpia 591 CCCGCGATGGCTAAGGAATG Asxll 4411 GCAGCGCCGCACGAAAGCTC Dnajc5 82 1 CTGTTGCTGAGACTGGCTGC Nalcn 592 GGGACAAAGAGCGTGGCCTA Sla2 4412 GGGCCCAAGAGATGAGCCAC Gjb4 8232 CAGAGAGCCGGCTCCGGAGG Gpr3 593 GGGCCTATACTGAGAGATGG Klhll 4413 ACTCGCACGGGATTGGACAC Dolppl 8233 TTAATGATTGTCGGACTCGG Evalb 594 GGTGAACTCCTTGGGTAGCG Pold2 4414 GGGAGTACGTAGACGC A GA C Rab28 8234 GCAGTAAGAGCTCACTGAAG Mgatl 595 TTGA CAAGG CGATGTTT GCA Bpifb2 4415 CTCTCACGTCCCGGCGGCTG Husl 8235 TCTCCTGCATCCCGGCCGGG N6141 596 GGTGATGCTGGATGTGTTTG Tctexldl 4416 GAGACCTGTCAGCGCCCGCG Slc9al 8236 GCAAATC CAGCAA GACAATG At l 3a4 597 ACTCACTTGGTTGCGCGACG Tcergll 4417 GCACCCACTTCCCATATTGA Inpp5j 8237 AAAGGATCAGCTGAAATCCT Cdh12 598 TCACTGGTCCTTAGTCACCA Sema4a 4418 TAATCTCATTAACGCGCGCG Slc6a20a 8238 TTCTTTGGACCGGAAGCAGG Tnfrsf26 599 TGGCTAAAGTA GAGCTCTT G Sh3d21 4419 CTCCAATGCTGGGTTAAACC H2-M3 8239 GGAGGAGCTGAAGAAGGGCG Hddc2 600 TCTCGGAGCCTCAGACGCTC Sf3al 4420 GGCTGAGGAGCTCCGCGCAC Faml96a 8240 GCTTAAGGCAACATCCTTCT Enpp2 601 GGGCAGTCCGGAGTCCGTCC Prom2 4421 CTCGCTCAACCGGGTCCCTC Uaca 8241 AGCTGTTTGCGGCGACGATC Hmmr 602 TAAAGAGGCTCATTTGCTCT Itgb6 4422 TGTGTGACAGCATCGACGTG T pl l 8242 TGGCGGAGCCCACCTGGCCC Arhgefl6 603 AATGAAGTCACGGACGCTAA Brinp3 4423 CGCATTTAGTAATACGCGCG Rpia 8243 GTGTGTGTGTGACTTACTGA Tekt2 604 AATACTCTGGGAACACCGAT Dnah6 4424 CAGAGAGCCGGCTCCGGAGG Gpr3 8244 ATAGGCACCAGTGACTGTCC Oprml 605 GGCTGTCATTAGCAGTTACA Ogdh 4425 TTAATGATTGTCGGACTCGG Evalb 8245 GGGCGGCTCAGGCCTTTCCC Dsel 606 TGGATCCGTGGCGCCTCGCC 5730409E04Rik 4426 GGATCACGCGACTCTTCAGC Jtb 8246 GACAGCCTArAGTCACTTGG Ccdc85a 607 TGCGCTCAGGCTTCCGGTAC Tbrg4 4427 TCTCCTGCATCCCGGCCGGG Nol41 8247 GATTACCCTTCTTACCCTCG Sy el 608 GGGrCAAACTGCGATTCCGT Ascc2 4428 TTCTTTGGACCGGAAGCAGG Tn s 26 8248 GCTGCTTCCAGGAAGGGCTT Bpifbl 609 CCCTCCTACCTGCCTACTCT Cstll 4429 AGCTGTTTGCGGCGACGATC Hmmr 8249 CGCGAAGGCTGCCGGCAGCC Ddi2 610 CGTTACTTCACTGAGGCAGA Ppargcla 4430 GAGAAACAGGATGTGTGTTT Lmanll 8250 AAAGAACCTCACATAAGCTC Mtgl 611 GGGAACGGGTGCTTAGATCT Eml5 44 AGGCAAGAAGACAAGCGCCG Bsx 8251 GATATAGGGCTCTGGCGGCG C kl 612 TGCTACATAGTTTAAGAGCC Zfp398 4432 GTCAGAACTAATGAGCGGGT Dnphl 8252 TTAGCTAGGGAGTCAGCTGT Cngb3 613 GGGCCCAAGAGATGAGCCAC Gjb4 4433 CCGTTGGCCTCCCGATTCGT Mstol 8253 TTGATCTGACAAGTGATTCG Satbl 614 CTCTCACGTCCCGGCGGCTG Husl 4434 GTGTGTGTGTGACTTACTGA Tekt2 8254 CCCAGTGAGGAGCTGCCTGC Tmeml76b 615 GAGACCTGTCAGCGCCCGCG Slc9al 4435 CAATTCAAGTCCAAAGTCGA Cspg4 8255 GCAGAGCCTTTGGTACGCAT Fam83d 616 GCACCCACTTCC CATATT GA Inpp5j 4436 GTAGGTACTGTGCTCTGCCA Asxl3 8256 GAAAGAATGCCCGCCTGGCG Stxbp4 617 GTTAACAGCCGAGAACAAGT Chd5 4437 GCGCATCACGTGCGCCGGTC Atp6v0b 8257 CCCTCCGCTCAGCAGAAGCC Tmc5 618 TAATCTCATTAACGCGCGCG Slc6a20a 4438 GGGCGGCTCAGGCCTTTCCC Dsel 8258 CATGCGCArTTGCAAGCGCT Slu7 619 GGCTGAGGAGCTCCGCGCAC Faml96a 4439 ATAAACGGATACTATCAGAG Gml6130 8259 GTGTGTATTTCACCAACCCT Pdyn 620 CGCATTTAGTAATACGCGCG Rpia 4440 ATGCTCGCACAGTGTCCTCA Asxl3 8260 GTAATTTCACATGCTGCCCA Atpl3a5 621 CAGAGAGCCGGCTCCGGAGG Gpr3 44 CAGCTTTCCGGTCTGTTCTA Gml2886 8261 CAGCTTCACGCGCGCATCCC Eril 622 TTAATGATTGTCGGACTCGG Evalb 4442 GATTACCCTTCTTACCCTCG Synel 8262 TAGAGCTCATTTGTCTGCAA Pxmp4 623 GCAGTAAGAGCTCACTGAAG Mgatl 4443 GCTGCTTCCAGGAAGGGCTT Bpiibl 8263 ATGTCTTTAGAAATACTGCA Slcl7a3 624 TCTCCTGCATCCCGGCCGGG Nol41 4444 AGGGAGCAAGGCCCGCCCAC Pkm 8264 GTGCAGTGCAGCGAGGATGG Spm 625 AGGGCTCTTGCGCAGGCTCT Nkapl 4445 AAAGAACCTCACATAAGCTC Mtgl 8265 GGAACAGCTGCAAATTGGAC P2iyl2 626 AGTCGAGGACCGGGAGGTAT C130060K24Rik 4446 TCATGGGCCGTGAAGTCCTT Calcocol 8266 GGTCTGCCAGGTGAGATACT Saxol 627 TTCTTTGGACCGGAAGCAGG Tnfrs£26 4447 GATGACGCGCAGGCGCGGTG Exosc7 8267 GTCAGAATCGCGAGGGCCAG E2fl 628 AGCTGTTTGCGGCGACGATC Hmmr 4448 GCGTGGTCCAGAGACTGCCC Ptpn2 8268 CAAAGGGATTGAGCCGGCTG Dclkl 629 TGGCGGAGCCCACCTGGCCC Arhgefl6 4449 GCAGAGCCTTTGGTACGCAT Fam83d 8269 AAGTCAAGGCTGCCTCATCC Tmem26 1 630 GTGTGTGTGTGACTTACTGA Tekt2 4450 GGAGGAAGGTGTAATCAGTA PpplrlO 8270 CACGGGTGATGTATGCTCCT Coll2al 631 GTAGGTACTGTGCTCTGCCA Asxl3 44 GAAAGAATGCCCGCCTGGCG Stxbp4 8271 GCGGCCAGGCCACAACCGAG Mpp6 632 CCTCCGACGTCGCGTCGCGG Nrbf2 4452 CATGCGCATTTGCAAGCGCT Slu7 8272 AGTCCAGATGTCGCTCTCCC Paqr7 633 AACCGAACCCAGGGTCGAGG Trpm6 4453 GGGTGGAATCCCGTTACGAT Tpral 8273 CAGCAGCGAATGGGAGCTCA Sec22c 634 TCCACTAGGGTGACGATACT Gdf9 4454 TCATTATTTGCAGCTTAATG Bdnf 8274 CCCAGGACTTCTCCCGGATC Itgal 635 GGGCGGCTCAGGCCTTTCCC Dsel 4455 GATAATACCGGGCGCCATAT Cox7c 8275 GCTGGCGGAACCCAGAAGCA Tgifl 636 GACAGCCTATAGTCACTTGG Ccdc85a 4456 TAGAGCTCATTTGTCTGCAA Pxmp4 8276 GTGGTCTAAGATCCTCTGAA 4921507P07Rik 637 ATGCTCGCACAGTGTCCTCA Asxl3 4457 GGCCGTTCCGGAGGCGGGCG Nprl 8277 o CATGCGCACCGCGGTCCGCC Zmyml 638 GCCGCCGTCTGGACGCTTAA Zfp651 4458 ATGTCTTTAGAAATACTGCA Slcl7a3 8278 GCGGGAGCTACGGCGGCGCT Rnfl9b 639 CAATCAATACCTAACTAGCT Gga2 4459 TTTCTTTCCCACCGAATACA Sqstml 8279 GTCAGAGGTTCTAGCCGGAG Map3k6 640 GATTACCCTTCTTACCCTCG Synel 4460 GTGCAGTGCAGCGAGGATGG Spm 8280 TCGCTTCAGTCACCTCCCTG 5330417C22Rik 641 GCTGCTTCCAGGAAGGGCTT Bpifbl 4461 TAATAGCAGGTTCCATCCTA Hepacam 8281 o CTGGATTAGAGCCAGTCGCC Stk32a 642 GCCCTCTCCTCTCGGGTACT Col6al 4462 GGTCTGCCAGGTGAGATACT Saxol 8282 4 CATGACTACCTGGGAGGAGA Cstl3 643 GGGACTCGCCGCCCGGAACT Pldl 4463 GTCAGAATCGCGAGGGCCAG E2fl 8283 GAGGGTAGGGCTGAGCTTGC K j l 5 644 CGCGAAGGCTGCCGGCAGCC Ddi2 4464 CGAGCCCTCGGCGCGAGCCC Lcorl 8284 CCCGCCCAGGAAAGCTGTCA Klhll 645 AAAGAACCTCACATAAGCTC Mtgl 4465 AAGTCAAGGCTGCCTCATCC Traem261 8285 TGCATCCTGTGATGTGAGAT Runx3 646 GATATAGGGCTCTGGCGGCG Cmkll 4466 TCTGCTTCAGTTCTGATAGA Vwa5a 8286 TCCCTGCCAAGAAGTGGAAA Atpl3a5 647 GATGACGCGCAGGCGCGGTG Exosc7 4467 CACGGGTGATGTArGCrCCr Coll2al 8287 ATGGAGTGCATGGCCGGCGG kx6-2 648 CCCAGTGAGGAGCTGCCTGC Tmeml76b 4468 AGTCCAGATGTCGCTCTCCC Paqr7 8288 GCATGAGGGCGAGTGTGCGA Adgrl3 649 GCAGAGCCTTTGGTACGCAT Fam83d 4469 ACTTCACGCCGTCCAATCAG Bhlhe23 8289 GGGCGCGGTGCACTAGGCGC E2fl 650 CATGCGCATTTGCAAGCGCT Slu7 4470 TCAAGAAATGCGTGGGCTGT Zcchcll 8290 GGCTTAAGGAGAATTGCCAA Apob 651 CAGCTTCACGCGCGCATCCC Eril 4471 GGTGAGAGAGGCGCGGGCCA Ctbp2 8291 AAATGCTCCGCTACAAACAC Tmem222 652 TAGAGCTCATTTGTCTGCAA Pxmp4 4472 TTGCGCAACAATCAGCGCCG Smad6 8292 TTGCTGCTAGCTGGAACCCA NoplO 653 ATGTCTTTAGAAATACTGCA Slcl7a3 4473 ATAAATCAATATGACGGAAG Dmbtl 8293 TTTGCTTTCCGTCGGAGCCT L3mbtll 654 TTTCTTTCCCACCGAATACA Sqstml 4474 TAGACAGAGCCCATCCTTCC Mytl 8294 ATCAGAGTTATATGGAAATC Skint3 655 GTGCAGTGCAGCGAGGATGG Spm 4475 GGTTTGCAAGGCACCGCACG Nphp4 8295 GGGCrGGAACTGAGAGGTCT Tmeml76b 656 GGTCTGCCAGGTGAGATACT Saxol 4476 CATGCGCACCGCGGTCCGCC Zrayml 8296 GCAAGAGTACGCAGATTAAG Atp6vlf 657 GTCAGAATCGCGAGGGCCAG E2fl 4477 GCGGGAGCTACGGCGGCGCT Rnfl9b 8297 TCACCACACTGTGTCTGAGA Gml2171 658 AAGTCAAGGCTGCCTCATCC Tmem261 4478 GTCAGAGGTTCTAGCCGGAG Map3k6 8298 GGCTTCAATAAGCGGGTGGG Pdlim4 659 CACGGGTGATGTATGCTCCT Coll2al 4479 CTGGATTAGAGCCAGTCGCC Stk32a 8299 ACCGTGGCGGAGCCAGGCTG Map2 660 GCGGCCAGGCCACAACCGAG Mpp6 4480 TGCATCCTGTGATGTGAGAT Runx3 8300 GCACTAA CGGCTGGCA Zbtbl7 661 AGTCCAGATGTCGCTCTCCC Paqr7 4481 CGAACTCCTCACAAGTTCTC Gbp2 8301 TGGCGTCCCTCTCTGGGCAC Limdl 662 CAGCAGCGAATGGGAGCTCA Sec22c 4482 ATGGAGTGCATGGCCGGCGG Nkx6-2 8302 AATAAATGACACGCCTACGC Gjb3 663 CCCAGGACTTCTCCCGGATC Itgal 4483 TTGTGACTATAGCACTCAAG Sytll 8303 GGGAGTGCAGTCTGGGATAC Gja4 664 GCTGGCGGAACCCAGAAGCA Tgifl 4484 GGGCGCGGTGCACTAGGCGC Ε2 8304 CTCACTGGAATAAACATTAC Dppal 665 GTGGTCTAAGATCCTCTGAA 4921507P07Rik 4485 GGCTTAAGGAGAATTGCCAA Apob 8305 GGGCTGGAAGAAATGCATAG Bpifb3 666 CATGCGCACCGCGGTCCGCC Zmyml 4486 AAATGCTCCGCTACAAACAC Traem222 8306 AGAGCAGCATCGGGAAGTAG Propl 667 GCGGGAGCTACGGCGGCGCT Rnfl9b 4487 TTTGCTTTCCGTCGGAGCCT L3mbtll 8307 TCGACTGGAAACTTACACCA Polrlb 668 GTCAGAGGTTCTAGCCGGAG Map3k6 4488 TGGGTCCGGATGGGAATTAA Traem69 8308 AAGTAGGCAGAGTAGTAACA Naa20 669 CTGGATTAGAGCCAGTCGCC Stk32a 4489 TCAGGCTGGGCAGGAATTCA Mtg2 8309 GTCTTAGGGAAACAGCAATG Lhcgr 670 CATGACTACCTGGGAGGAGA Cstl3 4490 GGGACTACGTGTTGTAGCCG Pipf38a 8310 TGCTTCCGGAGGCGGGTCAG Mtfrll 671 CCCGCCCAGGAAAGCTGTCA Klhll 4491 TGGGAGACCGATGGTTGCTC Ccdc24 8311 TCGTCCTGCTCGTGTTGCTT Rad50 672 TGCATCCTGTGATGTGAGAT Runx3 4492 GAGTGATTGGGAGCTGGAGT Tbx3 8312 AGCTTGAAACCCGCGCGAGG Casp3 673 ATGGAGTGCATGGCCGGCGG Nkx6-2 4493 TAGAACCTTTATCAAGCATA Xcrl 8313 n GTTAATTGAGACGGAGCTCT Grrpl 674 GCATGAGGGCGAGTGTGCGA Adgrl3 4494 TCACCACACTGTGTCTGAGA Gml2171 8314 CCTGCAGGCACTGGGTCTGA Rpp40 675 GGGCGCGGTGCACTAGGCGC E2fl 4495 GGCTTCAATAAGCGGGTGGG Pdlim4 8315 n GCTTGTCACGTGCAATTCTG Wdrl7 676 GGTCGGTCGCCTAGCATCTT Trpcl 4496 CGACGTAACCGCACCAGCGC Rnf32 8316 64 GCGTCTTCCGGCGCCCGTGG Smarca2 677 AAATGCTCCGCTACAAACAC Tmem222 4497 TGGCGTCCCTCTCTGGGCAC Limdl 8317 o GGGAGGGTGGCCGCCGGAAA Cst3 678 TTTGCTTTCCGTCGGAGCCT L3mbtll 4498 AATAAATGACACGCCTACGC Gjb3 8318 TGCTTAGCTGCGCAGCTTTG Azin2 679 ATCAGAGTTATATGGAAATC Skint3 4499 GGGAGTGCAGTCTGGGATAC Gja4 8319 TTTGGGACAGTCCCACTAAA Sec 16b 680 GGGCTGGAACTGAGAGGTCT Tmeml76b 4500 CTCACTGGAATAAACATTAC Dppal 8320 CGCTGGCCAATAGAAAGTCT Cep85 681 GGCGGCGCGCTTCATAGAAG Paics 4501 AATGTGGGAATTTCCTCTTA Ccr3 8321 J TGGAGAGCCCGGCGCTACCC KlhdclO 682 AGCCACACAGACTAGAGCTA Pldl 4502 GGGCTGGAAGAAATGCATAG Bpifb3 8322 CGGGAGGCTGGGCTGCTGGG Xkr8 683 GCAA GAGTACGCAGATTAAG Atp6vlf 4503 CCAACTCA CTGTGACTCCCT Bdnf 8323 AGGGTGCAGGTTCAAACATC Pabpcll 684 TCACCACACTGTGTCTGAGA Gm 12171 4504 AGAGCAGCATCGGGAAGTAG Propl 8324 TATCTCCAAGATCCCTATGC Cyb r2 685 GGCTTCAATAAGCGGGTGGG Pdlim4 4505 CGAGCGAAATTCCT GAGACC Ano5 8325 o CGTAGGCAGCTGCCAAACCC Kifl6b 686 GCACrAACTTTCGGCTGGCA Zbtbl7 4506 CGGTTCTCCTCAGGTGCGGG Podn 8326 CGCGAGGGCTCGGTGCCGAG Trim62 687 AGGAGAAGGACCTCCTTACT Plpp3 4507 TGCTTCCGGAGGCGGGTCAG Mtfrll 8327 ACACACACACACACTCACAC Gbp4 688 GCGCCTTTGAATGTCGAGAG Rnfl65 4508 TCGTCCTGCTCGTGTTGCTT Rad50 8328 GAAGACAGGCGGTGGACCAA Cnksrl 689 TGGCGTCCCTCTCTGGGCAC Limdl 4509 AGCATTGGACTATGGCTTGA Spirel 8329 o GAGACGCCTAATACATGGAC Cntnap2 690 AATAAATGACACGCCTACGC Gjb3 4510 AGAGTATCTGTCAGCTGTGG Ritl 8330 4 CCTGTTGGGAGCAGCTCTCA Nox3 691 GGGAGTGCAGTCTGGGATAC Gja4 4511 CCGCGTGTTCCTGGATTTGA Cepl92 8331 GTGGAATCGGTGGGAGGAAC Eci3 692 CTCACTGGAATAAACATTAC Dpp l 4512 GCGCGGGTGAGGCGGTGCGG Lgi2 8332 CAGGCACTACAGGAATGACC Tgm3 693 GAGTCTCTTTAGCGCGCTCA Ncapg2 4 3 GCTCCGCGGCAGGTTGGCCC Atl2 8333 CGCCGCCAGGGCGTTGGGCG Cdkn2c 694 GGGCTGGAAGAAATGCATAG Bpifb3 4 4 TGCTGCTGCTTTCACAACAG Lce3f 8334 ACACGTCACCTCTACGTGAT Dhdds 695 AGAGCAGCATCGGGAAGTAG Propl 4 5 GCTTGTCACGTGCAATTCTG Wdrl7 8335 CTGTATTGTCCAGTTGCTAG Eiflenifl 696 TCGACTGGAAACTTACACCA Polrlb 4516 CGTACATGTTCCCGCCTCTC 0610009B22Rik 8336 ATAAAGCATTCAGCCCTGCG Azin2 697 AAGTAGGCAGAGTAGTAACA Naa20 4517 CACACTGCACAAGACCTAGT Zfp691 8337 ATCGCGTGTGCGGCCTAAAC Dnajcl6 698 TGCTTCCGGAGGCGGGTCAG Mtfrll 4518 TGCTTAGCTGCGCAGCTTTG Azin2 8338 AAGTTATGAGTGCAAATCAT Spata6 699 TCGTCCTGCTCGTGTTGCTT Rad50 4519 CGCTGGCCAATAGAAAGTCT Cep85 8339 CCACAGCGCCACTCAACGGC Adprhl2 700 AGCTTGAAACCCGCGCGAGG Casp3 4520 CGGGAGGCTGGGCTGCTGGG Xkr8 8340 AGCGCGGCGGTGCAGGCCAA Coll6al 701 GTTAATTGAGACGGAGCTCT Gripl 4521 AGGGTGCAGGTTCAAACATC Pabpcll 8341 CTGTGGAGGGCGAAAGGACG Nadsytil 702 CTGTCGGTGTCTGCCATCCC Higdla 4522 CGCGAGGGCTCGGTGCCGAG Trim62 8342 AGACCAGTGGTTCAATCTC C Cmpkl 703 CCTGCAGGCACTGGGTCTGA Rpp40 4523 GAAGACAGGCGGTGGACCAA Cnksrl 8343 GTCAGAGCACAGTGGAGAAC Clip4 704 GCTTGCATTCAGGCTCAAGG Pccb 4524 GTGGAATCGGTGGGAGGAAC Eci3 8344 AGGAGAGTCTGTGCAGATCC Lrrc27 705 GCTTGTCACGTGCAATTCTG Wdrl7 4525 ACACGTCACCTCTACGTGAT Dhdds 8345 CTGACTATTGGTCTCCGCTG Bubl 706 CGTACATGTTCCCGCCTCTC 0610009B22Rik 4526 CTGTATTGTCCAGTTGCTAG Eif4enifl 8346 GATTGAGAGTGCCCGACTCC Phlda2 707 GCGTCTTCCGGCGCCCGTGG Smarca2 4527 GGCGAGACAAGACTCCGACG Gskip 8347 TGGAACTCTACAAATCTCCA Cdl6311 708 GGGAGGGTGGCCGCCGGAAA Cst3 4528 ATAAAGCATTCAGCCCTGCG Azin2 8348 CGCGTGGCGTGGTTCGGCCA Onecut2 709 TGCTTAGCTGCGCAGCTTTG Azin2 4529 CCACAGCGCCACTCAACGGC Adprhl2 8349 AACGTCTTCAACCATAGCAA Cst9 710 CAGGAGGGCTCCTGATGCTC Mum 111 4530 AGCGCGGCGGTGCAGGCCAA Coll6al 8350 GCTTGGAGGCAGAACTCCCA Sept8 711 TTTGGGACAGTCCCACTAAA Sec 16b 4531 CTGTGGAGGGCGAAAGGACG Nadsynl 8351 GCAGGTCCGAGCGGCTGGCG Sirpa 712 CGCTGGCCAATAGAAAGTCT Cep85 4532 AGCACAGCTACTCCTAGGAG Enpp5 8352 AAATAGGGCAGCCGCGGCAG Fstl4 713 TAAATGGTGATTCTCTACCA Nr l 4533 GGCGGCGTCTTAGGGTGTTT Sepsecs 8353 GGAGTGCAGGCGCCTCGCGA Stk35 714 GACGGCTGCTGAGTTGTGGT Lypdl 4534 TTGCTAGGCTTACAAGGAGC Senp2 8354 CCATGCAGGATTGGCCAGAT Nudcd2 715 CGGGAGGCTGGGCTGCTGGG Xkr8 4535 CGGCTGCTCCCTGCTGACTG Stm 8355 AACGGGCACACGTTGGTAAC Dctd 716 AGGCTAAAGATCGGCGCCTG Arhgap21 4536 AAAGAGTTTACCAGGCCCTG Qpct 8356 ATTTATTGACTTCGGATGCA Gprunb 717 AGGGTGCAGGTTCAAACATC Pabpcll 4537 CAGCAGCAGCGGAGACAACC Gtf2b 8357 TTTCCACTACCGCAGATCCT DpplO 718 AATTAATCATAGGAGGTTGG Dcx 4538 CCAGCTG GTCAACAGCATTT 49 1406P 16Rik 8358 GAAAGACAAGAATGAGCCAA Mat2b 719 AGACTCGGGTTGTAGCAGCT 170000 1P0 IRik 4539 AGGAGAGTCTGTGCAGATCC Lrrc27 8359 CTCACCAAGTTGTCTGTCAG Rnf215 720 TATCTCCAAGATCCCTATGC Cyb5r2 4540 AAGTTTGTTGTGTGATTAAC Hgf 8360 TGAGCAAATATGCCCAGTCA Sec 16b 721 CGCGAGGGCTCGGTGCCGAG Trim62 4541 GATTGAGAGTGCCCGACTCC Phlda2 8361 n GCTAAGAGCCAGCCATGCTA Cldn22 722 GAAGACAGGCGGTGGACCAA Cnksrl 4542 TGGAACTCTACAAATCTCCA Cdl6311 8362 AGGTTTCAGGAACAGTGGTA Ly6c2 723 GAGACGCCTAATACATGGAC Cntnap2 4543 AATGATCCTTTACTGTACGT 4930563M21Rik 8363 CAATAACCACTCATCTCCCT Cyp2el 724 GTGGAATCGGTGGGAGGAAC Eci3 4544 GCTTGGAGGCAGAACTCCCA Sept8 8364 TTCCATACAAGCGCATTTCT Apob 725 CAGGCACTACAGGAATGACC Tgm3 4545 CCCGAACCTGGCGGAGGCCG Uckll 8365 o TTGGTTAAATTGGCCTCTCC Obscn 726 CGCCGCCAGGGCGTTGGGCG Cdkn2c 4546 AAATAGGGCAGCCGCGGCAG Fstl4 8366 TGACTTGACTCATCTGTGAT Bpifa5 727 ACACGTCACCTCTACGTGAT Dhdds 4547 GGACCCGGGACCGCTTTCCT Dsc3 8367 GGCTGGCrrCTCCATCATGG Tnipl 728 CTGTATTGTCCAGTTGCTAG Eif4enifl 4548 CATATAAGAAAGGAGCAATA Ashll 8368 GCAACGCGCCTGCTTACGCT Ndrg3 729 ATAAAGCATTCAGCCCTGCG Azm2 4549 GCTTGCCGCACGGCCTTGTG Uckll 8369 J GGGACGCCAGGCTCGGTGAC Paxl 730 ATCGCGTGTGCGGCCTAAAC Dnajcl6 4550 CCATGCAGGATTGGCCAGAT Nudcd2 8370 TTAATGCAGCTTGTTTGATA Pde4b 731 AAGTTATGAGTGCAAATCAT Spata6 45 GGCCGTACGGTTAAGCCCAT Htral 8371 CAACTAGGCAGTTGGACTCC Cnksrl 732 CCACAGCGCCACTCAACGGC Adprhl2 4552 AAGAGAGGCGGCCCTGCTCT Rabl3 8372 TTCCGCAGGTGrCCTGCAGG Raver2 733 AGCGCGGCGGTGCAGGCCAA Coll6al 4553 AACTCTAACCAACCAGATCA Ktil2 8373 o ATGTAACCTAGGTAGGAAGA Spinkl 734 CTGTGGAGGGCGAAAGGACG Nadsynl 4554 TTTCCACTACCGCAGATCCT DpplO 8374 AGGGAATCTTrGACAGCGCC Myh 735 AGACCAGTGGTTCAATCTCC Cmpkl 4555 TTTAAAGAAATGCAAGGCGG Kn n 8375 TATTTCAAACAACAGCCAGC Csmp3 736 GTCAGAGCACAGTGGAGAAC Clip4 4556 GAAAGACAAGAATGAGCCAA Mat2b 8376 AAGCAATCAATCGCCCAACC C dc5 737 ACAGCCTCACGCCCACGAGC Nrnl 4557 CTCACCAAGTTGTCTGTCAG Rnf215 8377 o GAAGTCrCrCCAAGGCATCC Nop 10 738 AGGAGAGTCTGTGCAGATCC Lrrc27 4558 CACTGACGATTGTTTATGTG Rpap2 8378 GACGAGCCTCCGCGAAGCAG Fam227a 739 CTGACTATTGGTCTCCGCTG Bubl 4559 CAATAACCACTCATCTCCCT Cyp2el 8379 CTCTAGAAGCTAGATAAGCG Scn7a 740 AAGTTTGTTGTGTGATTAAC Hgf 4560 TTCCATACAAGCGCATTTCT Apob 8380 GAGGGAAGAAGAGGCGCGAG Plagl2 741 TGGAACTCTACAAATCTCCA Cdl6311 4561 TTGGTTAAATTGGCCTCTCC Obscn 8381 GGGCAGAGCCAGCGGAGGAA Gm2a 742 AATGATCCTTTACTGTACGT 4930563M21Rik 4562 TGACTTGACTCATCTGTGAT Bpifa5 8382 TTTACTCTTTCCTACCTGAA Uqcib 743 TTTCAAATATTTGGGAGAGG Pparg 4563 GGCTGGCTTCTCCATCATGG Tnipl 8383 TAGGGAGCTCAAAGTCCGAC Esxl 744 GCTTGGAGGCAGAACTCCCA Sept8 4564 GCAACGCGCCTGCTTACGCT Ndrg3 8384 CTCAGCTCTTTCTCATCAGA C dc6 745 GCAGGTCCGAGCGGCTGGCG Siipa 4565 CAACTAGGCAGTTGGACTCC Cnksrl 8385 TAAAGGGCATGCATGCCTCC Kdfl 746 AAATAGGGCAGCCGCGGCAG Fstl4 4566 AGGGAATCTTTGACAGCGCC Myh8 8386 CAAGGTTCTAGACAACACCC Gpx3 747 GGAGTGCAGGCGCCTCGCGA Stk35 4567 TGTACGGCCTGCCCTGCTAC H at 8387 ACAACAGCGGATGCCAGCCC Fadd 748 AGCGAGTTCTGACAACCGGA Adgb 4568 CCAGCCCGCTGCCCTTGGAC Svbp 8388 GCCATTTAACATCAAGTTCC Tbx22 749 CCATGCAGGATTGGCCAGAT Nudcd2 4569 GAGGGAAGAAGAGGCGCGAG Plagl2 8389 AAGGCAGGGCGCGCGCCTCG Otud7a 750 AACGGGCACACGTTGGTAAC Dctd 4570 GGGCAGAGCCAGCGGAGGAA Gm2a 8390 CGGGAGGGACGACAAGGATG Syf2 7 1 ATTTATTGACTTCGGATGCA Gpnmb 4571 TTTACTCTTTCCTACCTGAA Uqcib 8391 AAAGGCCCAAGCTTCCAAGA Adig 752 TTTCCACTACCGCAGATCCT DpplO 4572 GGTGTGAGTCCATGCAACCT Itga4 8392 GCGCTGGGAATCGGAACCGC Mmpl6 753 GAAAGACAAGAATGAGCCAA Mat2b 4573 CTCAGCTCTTTCTCATCAGA Ccdc69 8393 TCCCAATGGGACCAGAGCAG Smtn 754 CTCACCAAGTTGTCTGTCAG Rnf215 4574 GGCTCATCGCGTGGACAGAG Lama3 8394 o TTGGGCTGTCAGCAGATCTG Ttn 755 TGAGCAAATATGCCCAGTCA Secl6b 4575 CAAGGTTCTAGACAACACCC Gpx3 8395 GGCGTGTTTGCAGCAACCAC Scml2 756 GCTAAGAGCCAGCCATGCTA Cldn22 4576 TCAGCAGCTCAACTTCCTGT Pstpipl 8396 TTGGAATCACCCTCTGGACC Sorcs3 757 AGGTTTCAGGAACAGTGGTA Ly6c2 4577 ACAACAGCGGATGCCAGCCC Fadd 8397 GCCGGTGGTAATGGATGTGG P4 a2 758 CAATAACCACTCATCTCCCT Cyp2el 4578 CGGGAGGGACGACAAGGATG Sy 2 8398 GTTCCTATAGCTTTCAAACG Atpl3a4 759 TGACTTGACTCATCTGTGAT Bpifa5 4579 AAAGGCCCAAGCTTCCAAGA Adig 8399 GATTTCTCAGTGAGTAAATT Cdhl2 760 GGCTGGCTTCTCCATCATGG Tnipl 4580 TCCCAATGGGACCAGAGCAG Smtn 8400 CTTCGGTGCCTAGCGGGTGC Col4a4 761 GCAACGCGCCTGCTTACGCT Ndrg3 4581 TTGGGCTGTCAGCAGATCTG Ttn 8401 TGCGCGCTGATTGACAGCTG Barx2 762 GGGACGCCAGGCTCGGTGAC Paxl 4582 TTCGCGTCAGCATCTGTTCG Corola 8402 GGTAGCrTGAGGGCAAAGTT Gccl 763 TTAATGCAGCTTGTTTGATA Pde4b 4583 GCCGGTGGTAATGGATGTGG P4ha2 8403 ACATAGTAGCTATGTTGACA Cdl6412 764 CAACTAGGCAGTTGGACTCC Cnksrl 4584 TCAACACAGCCCAGAGAGTC Dao 8404 CCGACCGGAAGTGCAGCTGC Nipbl 765 TTCCGCAGGTGTCCTGCAGG Ra er2 4585 GATGCACCAATGGCGATGCG Nphp4 8405 CGGAAGTGGCCGGAGGGCGC Tbpll 766 ATGTAACCTAGGTAGGAAGA Spinkl 4586 CGTGCGCGCGCGCTCGAGCG Tmem266 8406 GCGTTCTACCCAGCTGAAGG Satbl 767 AGGGAATCTTTGACAGCGCC Myh8 4587 ACATAGTAGCTATGTTGACA Cdl6412 8407 AACTTATGAGAAGGCCCACC Myli8 768 GGCGTGCCTGCGTCCCTAGG Copg2 4588 GTCTGTCCTATGGCAGGGAG Col6a3 8408 CGTTTCACAATTAAGGTCCC Tm9sf4 769 GCTGACCCTGGCAGGACTGA Nr0b2 4589 AACTTATGAGAAGGCCCACC MyhS 8409 n TAAACAAGGAAGGACAGCTC Lcp2 770 CTCTAGAAGCTAGATAAGCG Scn7a 4590 AGTGTCACATGCTCTTGCCC 1700001C19Rik 8410 AGCAGTAAATTACTTCTGCT Cngb3 771 GAGGGAAGAAGAGGCGCGAG Plagl2 4591 CTGATCAACCTAGATATTAA Ppie 8411 TCGGTCGCGATGCGCCAGCC Glral 772 GGGCAGAGCCAGCGGAGGAA Gm2a 4592 CGTTTCACAATTAAGGTCCC Tm9sf4 8412 AAGCAAGAGCGCAGAGACAT Luzp2 773 TTTACTCTTTCCTACCTGAA Uqcib 4593 TCGGTCGCGATGCGCCAGCC Glral 8413 o ATAGGACAGCTTACAGCTTA S p 774 TAGGGAGCTCAAAGTCCGAC Esxl 4594 CGTAGTTCCAGACGCCGAGT Kdm4a 8414 CCAGAGTTCATACACCTTCA Luzp2 775 CTCAGCTCTTTCTCATCAGA Ccdc69 4595 TTCCTGTTGGATATAAGTAT Tdpoz2 8415 b GCTCGGCGTGTTACTACGTC Hnnpa2bl 776 TAAAGGGCATGCATGCCTCC Kdfl 4596 GGAGAGACAACAGCCGATCG Mstol 8416 CCACAGGAGATCAATGGAAA X r7 777 CAAGGTTCTAGACAACACCC Gpx3 4597 ACGGTGAACATCTCTCCACT pn5 8417 J GACTGTGGTGAACGCAGAGC Stxbp4 778 ACAACAGCGGATGCCAGCCC Fadd 4598 TCACGCGGCTCCTTGGTAAC Stxl9 8418 AGGCGCCTAGCGGCCTGAAG Kiz 779 CTACTGACTCTAGTGGCCAC Efhcl 4599 TCAGTGCAATCTGTCACTGT Zfp938 8419 ATCTTGAGCAATCAAGCGTT Erv3 780 TGAAGCATTATTAGAAACAC Skint6 4600 CCACAGGAGATCAATGGAAA Xkr7 8420 TGACTCAGGCTAAGGATTCC Riokl 781 GGCGTGGCACGGGCGCCAAG Car5b 4601 CGAGGAGGCGGAGCGGTGGA Psmg2 8421 GCGCATTCGCCTGCTCCTCT Rcan3 782 CGGGAGGGACGACAAGGATG Syf2 4602 GACTGTGGTGAACGCAGAGC Stxbp4 8422 ACGTCACGGGAGGCGCGCGC Purb 783 CAGAATAATCCTGAACCGTC Fan 460 GGCTTCCTTGCCCTTTGG T Freml 8423 TCTATGGTCGCCGTTTCCCA Rpl36a 784 GGCAGGTCCGAGACCCAGCG Bex4 4604 GCCACGCCTACAGrCTTCCC Uspl71b 8424 GGAAGCTCTCACATCCAAGC Dnah9 785 CGAGCGCCAGCGGTGATCCC Kankl 4605 GCGCTGGAACCGGACCAATC Xpo6 8425 AGCTGACAGACCAATCGCCC Ing2 786 GCGCTGGGAATCGGAACCGC Mmpl6 4606 TGGAAACGCAGAGCAGCGCA Fankl 8426 GGGCTCAGATGGTCCAGGTT C77080 787 GTCCTCGTTGGGCTACGCGG Enppl 4607 GCGCATTCGCCTGCTCCTCT Rcan3 8427 ACTTGTGCTAAGAACTTTCC D7Ertd443e 788 CTCTCTTTGCCCTAGCTGAT Paics 4608 ACGTCACGGGAGGCGCGCGC Purb 8428 AGCTAGTGTGATATACTGAT 01frl324 789 TCCCAATGGGACCAGAGCAG Smtn 4609 GGGTCACGCCTGCGCACTGG Vpsl3c 8429 GATTCGATGACACGATTTCC Tmem230 790 TTGGGCTGTCAGCAGATCTG Ttn 4610 GAGGCTATCACTTGAGGGCG Helz2 8430 ACTATTCATCCTTAAATGCT Gprl41 791 TTGGAArCACCCTCTGGACC Sorcs3 46 AGTTACACTTGTAGGAGGAC Vwa5a 84 1 GGAGCGGCGCGCAAACCTTC Zfp362 792 GCCGGTGGTAATGGATGTGG P4ha2 4612 GGAAGCTCTCACATCCAAGC Dnah9 8432 GAACCCTCCATTAAAGACAA Tmc5 793 TAGCAAGCAAAGTTCATAGT Cpal 4613 ACTAGAAGGCTCTCCAATCG Dsg2 8433 GCCAGTGGCAGCCGAGTAAG Zfp467 794 TGCGCGCTGATTGACAGCTG Barx2 4614 GGGCTCAGATGGTCCAGGTT C77080 8434 GCAGAGGTCTCTGGCCAAAC Fat4 795 GGTAGCTTGAGGGCAAAGTT Gccl 4615 ATCATTGACATTCTTCAGGA Cub 8435 TGGGCACAGAGCGAGGGCGA Th 796 ACATAGTAGCTATGTTGACA Cdl6412 4616 CGAAGTGACAAAGTCCACTC Trim31 8436 CCCAGTTATTCACAACCGCC Tipm5 797 AACTTATGAGAAGGCCCACC Myh8 4617 ACTTGTGCTAAGAACTTTCC D7Ertd443e 8437 GTTAATGTCACTGTGTTCAG Mugl 798 AGTGCTATTTATATCCTTGA Nr0b2 4618 CTCAGGTAGAGATTGATAAA Gbp2 8438 CGGCTGGACAGAGCTGACAC Duspl5 799 GCCCGACGGCCGCGCAGCCC Zfp777 4619 ACTATTCATCCTTAAATGCT Gprl41 8439 ACAATACTGCAAGTGGACTC Bboxl 800 CGTTTCACAATTAAGGTCCC Tra9sf4 4620 GGAGCGGCGCGCAAACCTTC Zfp362 8440 CCGGGATGGCGCCAGCCTAT Snmp48 801 TCGGTCGCGATGCGCCAGCC Glial 4621 ATCCTGCCATTTAAGAAGTA Etl4 8441 GGGATTGGTTCTCAAGTACC Cds2 802 GCTCGGCGTGTTACTACGTC Hnrnpa2bl 4622 TGCAGAAGTGATAAAGACAA Lce6a 8442 TGTGTGACCCTCAGACAACA Tssk3 803 CCACAGGAGATCAATGGAAA Xkr7 4623 TGAGAGATCAAATGCTAAAT Ccdc33 8443 GAGACGTTGCGTGACGACCG Stil 804 AGGCGCCTAGCGGCCTGA AG Kiz 4624 TGGGCACAGAGCGAGGGCGA Th 8444 AAATTCATAGGCACCAGCCT Cntnap5b 805 ATCTTGAGCAATCAAGCGT Erv3 4625 CCCAGTTATTCACAACCGCC Trpm5 8445 GGGTCTCCGGCCGGACAGCG Zfp34L 806 TTGCTGCGCGCAGTGACCAA Traem47 4626 CGGCTGGACAGAGCTGACAC Duspl5 8446 CTAAACCATCCGGGCGGGCT Cldn23 807 TGACTCAGGCTAAGGATTCC Riokl 4627 TGTGTGACCCTCAGACAACA Tssk3 8447 TTACGTCAGTCACCGCTAGC Stk32c 808 GCGCArrCGCCTGCTCCTCT Rcan3 4628 AGGCTGAGGCTGGTCTCTTG Sqstml 8448 AGAGGCATCCACAATTCGGA Ddx56 809 ACGTCACGGGAGGCGCGCGC Purb 4629 AATCAGGATCTTCACAAACA Spal7 8449 CATCTCTCTACGTCACGGCC Rapgef6 810 GGGTCACGCCTGCGCACTGG Vpsl3c 4630 TCCAGCCCAGTCAACTCTCA Mytl 8450 CGCCGCAGAGGACCACTGCC Adcyl 811 GCCGTTGCCGTAGCTGTCGC Cacnalg 4631 GGGTCTCCGGCCGGACAGCG Zfp341 8451 CCCGGTTTCGGGTCGTTGCA Cdk5rap2 812 TCTATGGTCGCCGTTTCCCA Rpl36a 4632 TAACTTTGGCCTGAGAGGTG Pramef6 8452 CTTGATAGGGACCAAGAGCT Tinagll 813 GGAAGCTCTCACATCCAAGC Dnah9 4633 TTACGTCAGTCACCGCTAGC Stk32c 8453 GCGCCAGACATTTCCTAAAG Serinc2 814 AGCTGACAGACCAATCGCCC I g2 4634 AGAGGCATCCACAATTCGGA Dds56 8454 ACTGAAGGCCATATGTGGGA Gml2171 815 ACTGGAACCTGGGCGCCCTT Chn2 4635 CATCTCTCTACGTCACGGCC Rapgef6 8455 AAGGGAGGCGTTGCAACATC Elavl4 816 TTTGTGCAAGACCACTTGAA Gga2 4636 GAGGCTCTGCAAACCCGCAG Prkd3 8456 TGATGACACGCCAGCGCGCG Zdhhc3 817 CTGTCATCGAGGTCGCAAAG Fail 4637 ACGAGAGGTATCCCTCCGCG Pogz 8457 TTGACGGGCCAATAAGAGAG Hnmpr 818 GGGCTCAGATGGTCCAGGTT C77080 4638 CGCCGCAGAGGACCACTGCC Adcyl 8458 GACGCGTGAATGGAGGTGGA Hcrtil 819 ATCATTGACATTCTTCAGGA Cub 4639 CTTGATAGGGACCAAGAGCT Tinagll 8459 CGCACGTACACTCTTTAGTA Map2k6 820 ACTTGTGCTAAGAACTTTCC D7Ertd443e 4640 GCGCCAGACATTTCCTAAAG Serinc2 8460 CCAAGGCAAGGCTGTCCTCA Acnatl 821 CAGTGGTCCAGTGATGGCTA Stl8 4641 ACTGAAGGCCATATGTGGGA Gml2171 8461 AGGTGCGGGCAAGCCCGAGG Rein 822 ACTATTCATCCTTAAATGCT Gprl41 4642 TGTTCAGCCTCTAAGTGATA Gml553 8462 TTTAATAGCCGGCTCCTCGA Snap25 823 GGAGCGGCGCGCAAACCTTC Zfp362 4643 AGTCTAGTCTGCGGGTCTCT Gabbrl 8463 AGCGAGCCGAGGTTTGTCGA Wac 824 GCCAGrGGCAGCCGAGTAAG Zfp467 4644 AGGGCGACTGGTCAGGAGGG Rcan2 8464 CGGTGATGATATCTGAGACA Skint7 825 TGGGCACAGAGCGAGGGCGA Th 4645 TGCCACGCCCATGCGTGAAG Ruscl 8465 TCAAGGGTTCTGTGTTCTTC Gprl41 826 CCCAGTTATTCACAACCGCC Trpm5 4646 AACCAAGAGCTGGAGGACAA Fez2 8466 GGGACAAACCTAGAGCGACA Met 827 GTTAATGTCACTGTGTTCAG Mugl 4647 GTCGCTGGCAGCGCGGTCGG Mcmbp 8467 TCCCGGACTGTTCACGCACT Ralgapa2 828 ATTAAArCTTCCCAGAGGFT Caapl 4648 TGATGACACGCCAGCGCGCG Zdhhc3 8468 GCGGGACGCGCCCACTTGGC Sync 829 CGGCTGGACAGAGCTGACAC Duspl5 4649 TAGAGAGCCGCTGCTCCAAG 1700056E22Rik 8469 ACCTGGGCGGCGGAGGCGTG Cftr 830 CCGGGATGGCGCCAGCCTAT Snmp48 4650 TTGACGGGCCAATAAGAGAG Hnmpr 8470 GAGGAATGCACAACCGATCC Itili2 831 GGGATFGGTTCTCAAGTACC Cds2 46 GACGCGTGAATGGAGGTGGA Hcrtrl 8471 GTATCTTAGCAGACAAGGAA Adckl 832 TGTGTGACCCTCAGACAACA Tssk3 4652 GGAGGGACGCGTAACCGGGC Afg312 8472 GCTCACATGCGGGCTCAGAA Lrrtm4 833 AGGCFGAGGCTGGTCTCrrG Sqstml 4653 GGTCCAGTGATCTAGAGGCG Imp3 8473 CTCCTCCGATGTGACGCCTG Ublcpl 834 TGCAGGAAGCATGCCCTGTG Ryrl 4654 TACTGGGAGAGGCACGGAGC Adgrf2 8474 TGGTAGGATCCTTGAATCTC Serpinb9c 835 GAGACGTTGCGTGACGACCG Stil 4655 GGAAGGTACGTATAACCAGT Dsglb 8475 GTAAGCAAAGATTTCATATG Skint3 836 AAArrCATAGGCACCAGCCT Cntnap5b 4656 GCTCGCTGCTCTGTGGTCCA B3galt5 8476 AGGCTCGTCTGTGGCGGCGA Laip4 837 GGGrCTCCGGCCGGACAGCG Zfp341 4657 TCTTCAGAGTTCCAGAAGTC Tigd4 8477 TTACGAGGCAACCAAGAGGA Zkscan3 838 TAACTTTGGCCTGAGAGGTG Pramef6 4658 AGCGAGCCGAGGTTTGTCGA Wac 8478 GGGTGGAGCCTATGGTACAC Bmprlb 839 CTAAACCATCCGGGCGGGCT Cldn23 4659 TGGCTCGCAGTTCCTGTTTC Nsun3 8479 AAGGAAACCCAGGCTGTGTC Tcn2 840 TTACGTCAGTCACCGCTAGC Stk32c 4660 TCAAGGGTTCTGTGTTCTTC GprUl 8480 AAACGGAGTGACGGCGCGAC Ppia 841 AGAGGCATCCACAATTCGGA Ddx56 4661 GGTTATGTAGACTAGGGACA Stxl9 8481 TGGACTGGAATCCAGGAGAC Gca 842 CATCTCTCTACGTCACGGCC Rapgef6 4662 GTACGGCGGCAAAGGTGAAG Rcn2 8482 CTTGCTATTATAGCACTGTG Calr4 843 CGCCGCAGAGGACCACTGCC Adcyl 4663 CCACGCAGATGCAGTACAGC Ccdc33 8483 AGGCTGGTGCCCGTGAATTT Cntnap5c 844 GATCTTTACCGGTGTTTCCA Ppfial 4664 GCGGGACGCGCCCACTTGGC Sync 8484 ACTGCTTGTCTCCACTAATT D7Ertd443e 845 CTTGATAGGGACCAAGAGCT Tinagll 4665 CGTAGGGAGGTCGTCACCGC Rabl3 8485 ACTGCAATTATTAGATTGAG NeklO 846 GCGCCAGACATTTCCTAAAG Serinc2 4666 ACACATCATCCAAAGTGAAA Kdm4c 8486 AGGCAACTGGCTAACTAGCC Stpgl 847 ACTGAAGGCCATATGTGGGA Gm 12171 4667 GCCAGGCGTCACCCTGGTGG Pcdhl 8487 CGCCAAAGTCTCTAGGGATG Ttil 848 CTTAAAGACTGCCCTCTGTC Sgcz 4668 ACTGGAGAGACAGAATCATG Runx2 8488 CCTCATCATCTGCGTGGTCC Zfp831 849 CTTCTTGTCCACCCAGCATA Entpd2 4669 GACCGGGATAGGACAGAGCG Amhr2 8489 CGCACGCTTTGGCTCGGGAG Pithdl 850 AAGGGAGGCGTTGCAACATC Elavl4 4670 TGGTAGGATCCTTGAATCTC Seipinb9c 8490 GATTATCTGCTCCACGCACG 1110034G24Rik 8 1 CAGAGTTTCTGTGCAATTCT Spdye4b 4671 GGATGCCTGCAACT GTTTGC Freml 8491 GTGGGCCGGAACTACGGCAG Mpped2 852 ACGGCFTTCATGCGGCCGCG Dicerl 4672 TTACGAGGCAACCAAGAGGA Zkscan3 8492 GGTTGTGTCCTCTACACACA Col3al 853 AGGFGACACGGCAGCAGAGG Krt20 4673 GGGTGGAGCCTATGGTACAC Bmprlb 8493 TGGCGGCGAGTTCTGTCACG Taf71 854 TGATGACACGCCAGCGCGCG Zdhhc3 4674 AAGGAAACCCAGGCTGTGTC Tcn2 8494 GGCTCCTCAATTGCCCTAAA Myll2a 855 GCGAGTGAATTTGCGTGCCC Apafl 4675 AAGAACCTCAGTCCCGTCGT Fam81a 8495 GCGCAAACTCGCTCACTTCC Ulk4 856 TTGACGGGCCAATAAGAGAG Hnmpr 4676 TTTCTAAGAAGCCTTGAGCA Crisp4 8496 CAAGGAGGGCGATACCAAGA C m2 857 GAACAGGATGTGTTCTTCAA 543040 lF13Rik 4677 ACTGCTTGTCTCCACTAATT D7Ertd443e 8497 TCAAAGCAAACAGTGATAGG Rad50 858 GACGCGTGAATGGAGGTGGA Hcrtrl 4678 ACCGAGTTCTACCGGAGCTC Dnajc5 8498 CTGTGCACGrTTGTTGAGCT Tgm6 859 CGTCTCGATGCAGCTGCCCT Zfp651 4679 AGGCAACTGGCTAACTAGCC Stpgl 8499 CGGCGCCATCCCTTAGCTTG Dfna5 860 CCAGACCTGCCTTATTTATA Colla2 4680 CGCACGCTTTGGCTCGGGAG Pithdl 8500 GAGGGTCTTCTGTAGGGTGA Smo 861 AGCGAGCCGAGGTTTGTCGA Wac 4681 TGGACAACACATTGAACTTG Ubd 8501 CAGACCrTTAGAGGCTCTCT Ccdcl3 862 CGGTGATGATATCTGAGACA Skint7 4682 CAGCTGCAAGTACTTTGTTC Sh3rf2 8502 TTGTTAGGGrCACTTAAACA Tpte 863 TCAAGGGTTCTGTGTTCTT C Gprl41 4683 AGCCTTTCTGCGTTCATCTT GpiA8 8503 CGCTCTATATATACAGCGCC Histlhlc 864 GCAGGCCTGGAGCTTGTAAG Ccdcl37 4684 CAAGGAGGGCGATACCAAGA Ccm2 8504 GTCACGTGACGTCCGCGGCC Myll2a 865 GGGACAAACCTAGAGCGACA Met 4685 TCAAAGCAAACAGTGATAGG Rad50 8505 TGTCAGGAAGAGGAAGAGCG Efhd2 866 TCCCGGACTGTTCACGCACT Ralgapa2 4686 CTGAGCAGGGTCGACAGAGC Kncn 8506 CAACCTTAGACrTAGGCATG Hormad2 867 GCGGGACGCGCCCACTTGGC Sync 4687 AGGAGGAAAGGGACTTCGAA Col9a2 8507 CCAAGCGGAAACTTACACAC Pcdhl9 868 TGCCCTCCTGTCAAGCGCTT Fail 4688 CGCTCTATATATACAGCGCC Histlhlc 8508 GTCGGAGTGGCGGAGGCTCT Epha7 869 ACCTGGGCGGCGGAGGCGTG Cftr 4689 CCCGCGGCAGTCACGTGCGC Pkn2 8509 GAATGAACCAAGTGTCCGCC Csmd2 870 AGCATTACACCTGATGTTCC Plekhsl 4690 GCGCCATGAGCTCTAGGCTT Skorl 8510 TGCTGCTGTGCATTGAAGCC Plxna 871 ACTGGAGAGACAGAATCATG Runx2 46 CAACCTTAGACTTAGGCATG Honnad2 8511 CAGCATCACCACTCTGGGCG Sycp2 872 CTCCTCCGATGTGACGCCTG Ublcpl 4692 GAGGAAGGGAGGTGACTGAG Cd51 8512 AACGACTGGCGCGCGCACCC Gmds 873 TCTCGCGCGTTGCCAGGGCG Ssbp2 4693 GACAAGTTCATGACTGAATG Epcam 8513 TTTGGATATCATGACAAAGT Adam29 874 TGGTAGGATCCTTGAATCTC Serpinb9c 4694 GAATGAACCAAGTGTCCGCC Csmd2 8514 TTCATGCAAGAAACTATCTG Cntnl 875 AGACCTTGTTGCCTCGGAGG Gimap9 4695 AAGAATTCACATTTGAACCC Cebpzos 8515 CCCTTGGCAGCGGGTCTAAA Zbtb8os 876 GTAAGCAAAGATTTCATATG Skint3 4696 TGTCGAATCTCAACCTAGGA Rcan2 8516 CGCAGGTAAATCCATGCGCC Lif 877 TTACGAGGCAACCAAGAGGA Zkscan3 4697 AACGACTGGCGCGCGCACCC Gmds 8517 o ACATTCAGAGCTGACCCGGG Lrm4 878 AAGGAAACCCAGGCTGTGTC Tcn2 4698 CTAGAGCGGGTTGTTGAATC Ccdcl5 8518 TTGCAATTGGTCGCAACCAG Psipl 879 AAACGGAGTGACGGCGCGAC Ppia 4699 CGCCTCCAACCGCCGCACGC Arihl 8519 CTAGCGAAAGGCTGCCGCCC Srrml 880 TGGACFGGAATCCAGGAGAC Gca 4700 CTTATTGATTGGCCCTGCAG Arhgap26 8520 5 GGCTCTGGAAGAGCTGGTTT Impdhl 881 CTTGCTATTATAGCACTGTG Calr4 4701 TCCAGGACTGACAGTACTTT Pate2 8521 o 4 TTAGTGCAACCTGTGGCACG Nphpl 882 CTCCTTATCAAATAGGGAFC Trmt2b 4702 CCCTTGGCAGCGGGTCTAAA ZbtbSos 8522 O ACTACAATTCCCATAAAGCA UqcrlO 883 ACTGCTTGTCTCCACTAATT D7Ertd443e 4703 CGCAGGTAAATCCATGCGCC Lif 8523 o TTGCGCGGGCCCAATGAGCG Golim4 884 ACTGCAATTATTAGATTGAG NeklO 4704 TCAACTTATGGTAATGAGCT Otog 8524 GGAGGAGGGAGTCTGTTAGG Lefl 885 AGGCAACTGGCTAACTAGCC Stpgl 4705 CTGTAGTATCCTCTAAGATT Gml553 8525 TGAGTAGTATACATGTGAGC Polm 886 CCTCATCATCTGCGTGGTCC Zfp831 4706 CTAGCGAAAGGCTGCCGCCC Srrml 8526 TGTGCGGTGAGCAATAGCTG Gap43 887 CGCACGCTTTGGCTCGGGAG Pitlidl 4707 AGCGTAGACTAGGCAAGAGG d 4c 8527 TTCTTACGTAAGCCGGGAGC Ak4 888 GATTATCTGCTCCACGCACG 1110034G24Rik 4708 GCAACAGGATTCTTTCAGCC Hgf 8528 TGACTATAGGAGGTGATGCG Ankefl 889 AAACATAGCTCAGGGAAGAG Igfl 4709 ACTACAATTCCCATAAAGCA UqcrlO 8529 CGGCTCCGACTGCGTGTGAG Rock2 890 TGGCGGCGAGTTCTGTCACG Taf71 4710 CTCTCGCTCCTCCGGCTTTC Vars2 8530 GATAAGGTCTGCTGGAATCG Spata4 891 GGCTCCTCAATTGCCCTAAA Myll2a 4711 CAAAGTATTGTAGGAAATGC Sc l 8531 AGGCTCAGTCTGCTTAGGCT Wisp2 892 GCGCAAACTCGCTCACFTCC Ulk4 4712 TTGCGCGGGCCCAATGAGCG Golim4 8532 GAAGCTTCCGGCGGACGCCA 1110008F13Rik 893 CAAGGAGGGCGATACCAAGA Ccm2 4713 CAGTCGTGGCGCGTGGAGTG Eprs 8533 TCAACAGGAACTAGACAGCA Gale 894 TCAAAGCAAACAGTGATAGG Rad50 4714 TCTGTGCAGACTGCTGGTTG Thsd4 8534 GGAAGGAGGAAGGCAGCCGT Bpi 895 CTGTGCACGTTTGTTGAGCT Tgm6 4715 TTGTGGCGGAGAGTTAGACG Rab3gap2 8535 GCAGCCAGCCCGGCCTTATT Myl9 896 CGGCGCCATCCCTTAGCTTG Dfna5 4716 TGAGTAGTATACATGTGAGC Polm 8536 GGGACCAGCATCAGTGAGTG Acsll 897 CAGACCTFTAGAGGCTCTCT Ccdcl3 4717 GAGGCAGCCTACACACTTCC Itgax 8537 TCTGGCCCTGTGGCTAAGTC Cnga3 898 CGCTCTATATATACAGCGCC Histlhlc 4718 GTGTCTTCTAGTCTCAAAGC Tdpozl 8538 TACTTTGCGCCCACTCCTAG Jade2 899 GTCACGFGACGTCCGCGGCC Myll2a 4719 GTCTGAGCTCGTACACTGAG Clic5 8539 AGGAGCTGGTCTCCGGCAGG Steapl 900 TGTCAGGAAGAGGAAGAGCG Efhd2 4720 AGGCTCAGTCTGCTTAGGCT Wisp2 8540 AAAGCTGACTCTGACAGCAA Klra2 901 CAACCFTAGACTTAGGCAFG Hormad2 4721 GAAGCTTCCGGCGGACGCCA 111000SF13Rik 8541 TTACATCATCCTTGGGCGTG Osm 902 CCAAGCGGAAACTTACACAC Pcdhl9 4722 GGCAGTTAGACAGTTCTCCA Ak7 8542 GGATGGGAGCGTCCCTGCAA Iars 903 GTCGGAGTGGCGGAGGCTCT Epha7 4723 TCAACAGGAACTAGACAGCA Gale 8543 GAGCCCAAGTCCCTGTGTGG Faml79a 904 GAAFGAACCAAGTGTCCGCC Csmd2 4724 GGAAGGAGGAAGGCAGCCGT Bpi 8544 GGCTCGCGACCATAGAGAAG Thoc5 905 TGCTGCTGTGCATTGAAGCC Plxna4 4725 GCAGCCAGCCCGGCCTTATT Myl9 8545 TTGCTTGCAGGAGCGAGTGA Chd6 906 CCCTTCCGCCCTGTGTTGTC Agrp 4726 AAGTTCTA GACCGCAGGAGG Gramdlb 8546 GCTAGACCCAGATGCAGCCT Sa d 907 CAGCAFCACCACTCTGGGCG Sycp2 4727 TCTGGCCCTGTGGCTAAGTC Cnga3 8547 TGTAGAAFFGGAACTACTAG Zfp341 908 AACGACTGGCGCGCGCACCC Gmds 4728 TACTTTGCGCCCACTCCTAG Jade2 8548 GGTCTTTCTGGCAGGCATCG Tmeml09 909 GATTACAGGGACCAGGGAGG Tnncl 4729 ACTCTCCTCAGGCCACTGCG Gpr68 8549 TCCTGTGAAAFCAGACCAAT 114 910 TTTGGATATCATGACAAAGF Adam29 4730 AATTATTCCACAACCATAGC Seipini2 8550 TTTCCTGAGTCTCTGATTTG Sult2a5 911 CCCTTGGCAGCGGGTCTAAA Zbtb8os 4731 AACTGTGCTGGCTGGCCACC Gbel 8551 AAGCFGFCGAGAAAGCTATC SlcSal 912 AAFTAAAGCCTCTAATTCAC Satll 4732 TTACATCATCCTTGGGCGTG Osm 8552 TCACATGCFCTTTAAACGTC Tgifl 913 CGCAGGTAAATCCATGCGCC Lif 4733 GGCTCGCGACCATAGAGAAG Thoc5 8553 n AAATGCrCAATGTTTAACTG Dnahll 914 ACATTCAGAGCTGACCCGGG Lrrn4 4734 GAGCTCTCGGCACCGGGCTG Nt5cla 8554 GGGAGGGCCCAGGCGAGCGG Nol41 915 TCAACTTATGGTAATGAGCT Otog 4735 TTGCTTGCAGGAGCGAGTGA Chd6 8555 GGCCCGCCFCCrCCGAGACC Plekhm2 916 CTAGCGAAAGGCTGCCGCCC Srrml 4736 ACGCGGCGCTTCCCGGAAGA Dnajcl3 8556 n ATCTAGTCAAAGAATGAGGG Cntn6 917 GCAACAGGATTCTTTC AGCC gf 4737 TGTAGAATTGGAACTACTAG Zfp341 8557 o GCTAGCFGFGGAAAGTTGGG Hmcnl 918 CTACGCAGGCGGTAGGGCTG Rasa2 4738 TCCTGTGAAATCAGACCAAT 114 8558 5 GGCCCGCGFGATCCACGCAC Kifl6b 919 GGCTCTGGAAGAGCTGGTTT Impdhl 4739 TTTGTCCAATGAGGGAGAGC Thsd4 8559 AAATTCCGFAGACTCGCCTA Fucal 920 TTAGTGCAACCTGTGGCACG Nphpl 4740 ATGCTTTCAACACCACATTT Fcrl5 8560 GTAGACFCAACAAGTTCCAG Faml 6a 921 AGTCCTTTGAGGGCGCGAGG Smarca4 4741 GGGAGGGCCCAGGCGAGCGG Nol 1 8561 GGGTCCTTCCTAGAAATAAA Tmem82 922 ACTACAATTCCCATAAAGCA UqcrlO 4742 GACATATAGGTGGCCTCTGC Dsc2 8562 TCCCACTTCCCGCTGTGGAT Fgr 923 AAACGCGTGTATCGGGAGTC Sgce 4743 GCTAGCTGTGGAAAGTTGGG Hmcnl 8563 TCGCCCGCCGCCGAGGAGAA Csmd2 924 GGGCTTCGGCCGCGGGTTCT Arl4a 4744 CCCACCAACCGCGCGCGGCG Prkd3 8564 CCAACATCTCGTGAGGTGGG Osm 925 GAACCGGTTCGCGAGGGACT Emcl 4745 AAATTCCGTAGACrCGCCTA Fucal 8565 o CTCTTGATTTGGATTTGATG Bboxl 926 TGAGTAGTATACATGTGAGC Polm 4746 GTAGACTCAACAAGTTCCAG Faml96a 8566 A G GT AAGAA GGTTGGCAG Lbp 927 TGTGCGGTGAGCAATAGCTG Gap43 4747 GAGCCCAAACGCAACACTGA Pabpc4 8567 AGAGGTGACCAGATCTCAAG Sec 14 4 928 TTCTTACGTAAGCCGGGAGC Ak4 4748 TCCCACTTCCCGCTGTGGAT Fgr 8568 5 GG CATAAATA GTGGGTTCC Calr4 929 TGACTATAGGAGGTGATGCG Ankefl 4749 AATCATGGAGTAAGAAGCCC Zpldl 8569 o GGTGGGTAGAAGATTGACAG C t 930 CACGAGGACACCAAGGTTAG Gtf2hl 4750 TGAGTTGCCACCATCAGAGG Adgrel 8570 4 TGGGCGGAGCATCCGCCTCG Rbbp4 931 GAAACCGGCAAGTGAGGATG Zfp593 4751 GACCTTGCGGGCTACCATTG Ctbp2 8571 GTGGTTGATTAGCAAAGTCT Olfrl370 932 GATAAGGTCTGCTGGAATCG Spata4 4752 TCGCCCGCCGCCGAGGAGAA Csmd2 8572 CTTGTTTACCCGGGAGTTCC Potla 933 GCTGGGCATGTCAACTCACA Skint6 4753 CCGCCTGGCACGTGATCGGT Tubb5 8573 GAAAGGTTT CAGAA GCGGAC Cldn22 934 GAGGGCCTGTCAGCTCACAA Fam71f2 4754 CCAACATCTCGTGAGGTGGG Osm 8574 TTTGTCTTACTTTGCTAAGT Foxp2 935 AGGCTCAGTCTGCTTAGGCT Wisp2 4755 GGCGTGATGATTGGACGGCA Dcbld2 8575 TTTATGAGAATTGAGGGCCT Aplbl 936 GAAGCTTCCGGCGGACGCCA 1110008F13Rik 4756 AGAGTCAAGAAGGTTGGCAG Lbp 8576 GCGCTTACCGCCrCTTATGC Lrrc27 937 GCTCTGGCACTAGGGCAAGC TbcldlOc 4757 AGAGGTGACCAGATCTCAAG Secl414 8577 GAGGTTGCTAAGAATTCTGC Gml7019 938 CGCGGCGAGCGGCGATCCCG Phfl2 4758 ACATAGGCGACCACGCATGC Gabbrl 8578 CTGCCGCTCGCCCAGGCTTT SlOOpbp 939 GGGTTGTATTAGCTTTCAAC Capnl3 4759 GGTGGGTAGAAGATTGACAG Ctn 8579 GAGGGTAGGAAGTGCCGCCG Phactr4 940 TCAACAGGAACTAGACAGCA Gale 4760 GAGGCAGTATTTACGGTAAC Gnal 8580 GCTTGTGAGTCACCGGTACC Nebl 941 GATTGGCTGGGATGAGCCCG Pan2 4761 TGGGCGGAGCATCCGCCTCG Rbbp4 8581 CGAGGAGCAGGCTGACTCCG Dpysl3 942 GGAAGGAGGAAGGCAGCCGT Bpi 4762 GTGGTTGATTAGCAAAGTCT Olfrl370 8582 GTCCCTCAGACrTGTTTGCT Zfp354c 943 GCAGCCAGCCCGGCCTTATT Myl9 4763 GGAACTGGGTGTTCCTCACC 2300002M23Rik 8583 GTAGTCCGGPCCATACCATA Nfia 944 GGGACCAGCATCAGTGAGTG Acsll 4764 TTTGTCTTACTTTGCTAAGT Foxp2 8584 ACCTCGCGCGCGGACTGCCC Mierl 945 TCTGGCCCTGTGGCTAAGTC Cnga3 4765 CGGCGGGCTCTGGCCAGACC Stam 8585 GGGTTTGGTGCACGTGGGAG Ano3 946 TACTTTGCGCCCACTCCTAG Jade2 4766 TAGCAAACTATTCATTTCAG Pdlim5 8586 GAGATTCATGCAATGCTAAT Piwil4 947 AGGAGCTGGTCTCCGGCAGG Steapl 4767 TTTATGAGAATTGAGGGCCT Aplbl 8587 TCCCAGArTGGCrGAGACCC Ascl2 948 AAAGCTGACTCTGACAGCAA Klra2 4768 GAAAGAGCTACAATGTGATG Tmem225 8588 AAGGAAGGCACGCGCAAGAC Ar 949 TTACATCATCCTTGGGCGTG Osm 4769 GCGCTTACCGCCTCTTATGC Lrrc27 8589 GTCATGGCCTTTGACATCAG Itk 950 GAGCCCAAGTCCCTGTGTGG Faml79a 4770 CCTGCGCTGGGAGGACC GAA Stomll 8590 TCATCTCTGAACTATATCCC Slc30a8 951 GGCTCGCGACCATAGAGAAG T oc5 4771 GAGGTTGCTAAGAATTCTGC Gml7019 8591 GACGGCTC CGTTGCGACATC Zzefl 952 TTGCTTGCAGGAGCGAGTGA Chd6 4772 CTGCCGCTCGCCCAGGCTTT SlOOpbp 8592 CGCGCTGGGCCTGGGTTCGC Cdkn2c 953 TGTAGAATTGGAACTACTAG Zfp341 4773 GAGGGTAGGAAGTGCCGCCG Phactr4 8593 AGATGCAACGTCATCACGCC 9530068E07Rik 954 TCCTGTGAAATCAGACCAAT 114 4774 GGAGTCTAATAGGGAAGGGC Ppdpf 8594 CCCTTTCGATTACGCTTTGC Adamts9 955 TTTCCTGAGTCTCTGATTTG Sult2a5 4775 CGAGGAGCAGGCTGACTCCG Dpysl3 8595 TAGGCCTTGGTGCAGATGCC Col9al 956 TCACATGCTCTTTAAACGTC Tgifl 4776 AATGTGGATGGGTTTCTGTA Tcf4 8596 GCTCGACCCTTGCACCGAAA Stk32c 957 GGGAGGGCCCAGGCGAGCGG Nol41 4777 GGAGCCTGCCAGAGTTGGTG AdamtsH 8597 AGAGATGCGCGGCCTCGCGC Cttnbp2 958 GGCCCGCCTCCTCCGAGACC Plekhm2 4778 GTCCCTCAGACTTGTTTGCT Zfp354c 8598 CGCGCGTGCAGCCTCGGAGC Ldlrapl 959 GCGCAAGCCGCAAGCTCGAC Krbal 4779 GCTCACGCTGGATTATGTCT Arhgei2 8599 CTTGCAGCTCAGCCAGTCTC Nkx6-3 960 CGCAAGGCGCTCAAGTACGG Pik3c2a 4780 GCTTTGTAGATGGGTGACAT Ruscl 8600 AGTTTCCTGAAFAGTGAGCG Wdtcl 961 TTCTTCGTATTGTGGGAGAG Arhgap21 4781 GCCATTGTTACGAGACAGCC Tp 3 8601 n GGAAACGTAGCTGTGGGTGA Psmb2 962 ACTAAGGCCACAGGCAGCTA Foxil 4782 CATCAGCACCACGGCGGCAG Faml35b 8602 CCGAGCCCAGAGGACGCGTC Ago4 963 AAATTCCGTAGACTCGCCTA Fucal 4783 CGTCGGACGTTCTCCGTGAC Atp6v0b 8603 CGGATGTCTGTGCGCATGCT Rsipl 964 GTAGACTCAACAAGTTCCAG Faml96a 4784 TCCCAGATTGGCTGAGACCC Ascl2 8604 n CCCGCCGCCAACGAACTGGG Nsmaf 965 GGGTCCTTCCTAGAAATAAA Tmem82 4785 GCGCGAGCGGGAGCGGGAGC Tmem266 8605 o TACCTGCAAATGACTGAGTT Hmgb4 966 TCCCACTTCCCGCTGTGGAT Fgr 4786 AAGCAATGTATTAGTTAGCC Tln2 8606 5 ACCCAGACAGCTCCCTCGCA Mdfic 967 TCGCCCGCCGCCGAGGAGAA Csmd2 4787 ACTCGCTAGCTACGAGACGT Uqcrh 8607 b GCTCCTTCAGAGCCTGTAGG Pdrgl 968 GAGGGCGGAGCTCTGGCGTG Ssbp2 4788 GTCATGGCCTTTGACATCAG Itk 8608 5© ATTGACTAAGGCAGATTAAA Gabm6 969 CCAACATCTCGTGAGGTGGG Osm 4789 TTCCTCCAGCTA A CGCCAAG Tnfrsf21 8609 J CAACTGAGTGAATGCCCAGT T¾x22 970 AGAGGTGACCAGATCTCAAG Secl414 4790 AGATGCAACGTCATCACGCC 9530068E07Rik 8610 TGCCAGCAAGAAAGAAGCCC Sgipl 971 GGACATAAATAGTGGGTTCC Calr4 4791 GGCCTCCTGATCAGATCTAC Ccdc24 8611 AGTTGCGCAGGCGCAACCGC Zfp2 972 GGTGGGTAGAAGATTGACAG Cttn 4792 TCCCAAAGGCTGGAGGGACT Rpp25 8612 CTCAGCGGGACAAAGCAAAC Ube2u 973 TGGGCGGAGCATCCGCCTCG Rbbp4 4793 CAATAAGGAGGAGCTTCCCG St3gal6 8613 o GGCAGCATCTGGACTGCAGC Tnfrsf26 974 GTGGTTGATTAGCAAAGTCT Olfrl 370 4794 TAGGCCTTGGTGCAGAFGCC Col9al 8614 GAGGAGACTAGAGTTGAATT Nupl55 975 CTGTTGCGCCACTGTGCTCC Zfp212 4795 GCTCGACCCTTGCACCGAAA Stk32c 8615 CGGTGCGAGTTCTTGC GAGT Dhdds 976 CTTGTTTACCCGGGAGTTCC Potla 4796 AGGTTAAGAAGATGTCTCAA 01frl328 8616 5 GAGCGATTGTAAATGTGTGA Esrrg 977 GAAAGGTTTCAGAAGCGGAC Cldn22 4797 TGTCCGTGGTGCTAAATATT Scamp5 8617 o CCAGCAGGTTCGGCGATGCC Mierl 978 TTTGTCTTACTTTGCTAAGT Foxp2 4798 GCGGGAGGTGACGGCCAATG Cgn 8618 4 TGACTTCCAGGTATATACTA Slc26a5 979 TTTATGAGAATTGAGGGCCT Aplbl 4799 GCTGTTTGTTTGGCAACACC Tcpll 8619 ATGCAGTGGTAAGTGCAGAC Plbl 980 CTATGGCTCTGCGGAGGGAG Emcl 4800 CGCGCGTGCAGCCTCGGAGC Ldlrapl 8620 ATTAGCCTACTTTGCAATCC WdrL7 981 GCGCTTACCGCCTCTTATGC Lrrc27 4801 AGTTTCCTGAATAGTGAGCG Wdtcl 8621 GTGCTTTGATTGGTTGCCTG Ankrd36 982 GGTGATTTCGCATTGGGTAT Fam50a 4802 GGAAACGTAGCTGTGGGTGA Psmb2 8622 GTCAGCAGAGGAAGTGGTAA Lcp2 983 GAGGTTGCTAAGAATTCTGC Gml7019 4803 CCGAGCCCAGAGGACGCGTC Ago4 8623 TTTGAGCAGCTCCrCCTGAC Calr4 984 CTGCCGCTCGCCCAGGCTTT SlOOpbp 4804 GTTCGAGTGCAAGCTTGAGC Snupn 8624 TCCCAGTACTCCTCCAGGCA Hpca 985 GAGGGTAGGAAGTGCCGCCG Phactr4 4805 CGGATGTCTGTGCGCATGCr Rsrpl 8625 CAAATGTTGGGTGAGAATTA Obox7 986 CGAGGAGCAGGCTGACTCCG Dpysl3 4806 GCTCTGGATGTTCGCTCTTC Nfyb 8626 GTGTAGTCTTCCGCAAGCGC Haus6 987 GTCCCTCAGACTTGTTTGCT Zfp354c 4807 AGCGGCTCTACGGTCCAAGG Dclk2 8627 ACTCTTGCTTAGAAATCTAA Elavl4 988 GTAGTCCGGTCCATACCATA Nfia 4808 GCTCCTTCAGAGCCTGTAGG Pdrgl 8628 CTCTCCACAAGGCGGCACCT Trpal 989 ACCTCGCGCGCGGACTGCCC Mierl 4809 TGCCAGCAAGAAAGAAGCCC Sgipl 8629 GCCGACCTCACTCATTGCTT Zmat4 990 GCTTGGTCTGTAGATAGAAG Ccdcl36 4810 AGTTGCGCAGGCGCAACCGC Zfp2 8630 CTGCGGCTCACrAGCTTGGC Dpysl3 991 TCCCAGATTGGCTGAGACCC Ascl2 48 CGTCCCATGGTTGCAGTCAG Pxk 863 1 TGAGGGAGGTGGTACCAAGG 9230104L09Rik 992 AGCAACGTGCCCTGGGCCAC Acacb 4812 CCCGCCTGTCCGAGGACGTC Lama5 8632 TTCTCAGTATGATTCTTTGT Adckl 993 AAGGAAGGCACGCGCAAGAC Ar 4813 GGCAGCATCTGGACTGCAGC Tnfrsf26 8633 AAAGCTTACTGTGCCAGGCC Fermtl 994 GTCATGGCCTTTGACATCAG Itk 4814 CGGTGCGAGTTCTTGCGAGT Dhdds 8634 AGTCCCGCCCATCAACTGCG Tail 995 CGCGCTGGGCCTGGGTTCGC Cdkn2c 4815 ATCACTCTTGTGGTGCCCTG Proml 8635 CAGGGCCTTTGTGCGACGAG Impdhl 996 ATATAAGACTTCCAGCACAC Prg4 4816 GAGCGATTGTAAATGTGTGA Esrrg 8636 GGGAGTTTAGAGGGCATCCT Itili5 997 AGATGCAACGTCATCACGCC 9530068E07Rik 48 TCTGCAGCACAGATGTGCTA Zbtb46 8637 GGACAAAGTACAAATAATGT GmlllO 998 CCCTTTCGATTACGCTTTGC Adamts9 4818 ATTAGCCTACTTTGCAATCC Wdrl7 8638 CTGTGACCrCATAGAGTACT Sun5 999 GTGTAGTGAGATCCTGGTCG Tbrg4 4819 GCAGTCTTTCAGTGGATTTA Parvg 8639 CCTTTCTACCCTACTCATTA Gjb3 1000 TCTGATTCTCAATCCACAAG Stra61 4820 GTGCTTTGATTGGTTGCCTG A krd 8640 GGGAAACACTGTCTAGGTTC Olfr530 1001 GCTCGACCCTTGCACCGAAA Stk32c 4821 CCACCAGATCCTGTTAAGAA Gucala 8641 CCCTCCCACTACTGACTGAA Magee2 1002 AGAGATGCGCGGCCTCGCGC Cttnbp2 4822 CCGTCCCTTCCCTGGACTGC Celf6 8642 CCAGGCGAGAAGCTGCAGAC Paqr7 1003 CGCGCGTGCAGCCTCGGAGC Ldlrapl 4823 ACTAAGACAGCGCAGCCGAT Epcam 8643 GTACTAATTAAGGACAACAG Ada 7 1004 CTTGCAGCTCAGCCAGTCTC Nkx6-3 4824 TCCCAGTACTCCTCCAGGCA Hpca 8644 CAATGAACCAGAGACCTGAA Bpifa6 1005 AGTTTCCTGAATAGTGAGCG Wdtcl 4825 ATCTAGAGCTTATCCATGTA 4930563M21Rik 8645 GTGGCTCTCTGAGGCCTAGG Dnah7a 1006 GGAAACGTAGCTGTGGGTGA Psmb2 4826 GCAGGATATCGAGACAGCCC Arhgdib 8646 ACTCACCAGCTACCAAGCCC Osbpl3 1007 CCGAGCCCAGAGGACGCGTC Ago4 4827 GTGTAGTCTTCCGCAAGCGC Haus6 8647 GGCTAATAATAGACTGATTA Pdzplil 1008 CGGATGTCTGTGCGCATGCT Rsrpl 4828 TTCGCCCAGTTTCTTGGGAG Cldnl9 8648 ACGCGATAGGAGGCAGCAGC Abcc9 1009 TACCTGCAAATGACTGAGTT Hmgb4 4829 ACGAAGAAACGCCATACTTC Nsun3 8649 n GAGCCGTGGGCCCGAGGAAC Map3k7 1010 ACCCAGACAGCTCCCTCGCA Mdfic 4830 CTGAGCACTGGGCGGAGTCA Κ1 7 8650 CGCAGTGGGCAGCAGGCCTG Rnfl45 1011 GCTCCTTCAGAGCCTGTAGG Pdrgl 4831 CTGCGGCTCACTAGCTTGGC Dpysl3 865 1 GAGTCAGCCCGCCTGCCGCT Arap2 1012 ATTGACTAAGGCAGATTAAA Gab 6 4832 TTTCTGATCGTGACTGTCCC Fbxw7 8652 CAGCACAGCTGTCACACAGC Fam46b 1013 AGAGCGCAGCCCGGCGCGTG Prkaa2 4833 CCTAAAGCTCGGTTAATGCC Gramd2 8653 o GAGCAGCTGCAGTGCAGTGT Noval 1014 TGCCAGCAAGAAAGAAGCCC Sgipl 4834 GGGTAATGGTTAACAGCAAT Pdzd3 8654 AACTTTCTCTGGATTTGTAC Pesl 1015 AGTTGCGCAGGCGCAACCGC Zfp2 4835 TTGGGTTCTATAAGAAGAGC Arhgap26 8655 b TCTAGGTTGCCAAGCGACGC 4930430A15Rik 1016 CTCAGCGGGACAAAGCAAAC Ube2u 4836 GGTGTGAGTCTTGGAGCTAA Ptk6 8656 AAGATAAACAGTGAGCGAGC Nrsnl 1017 GGCAGCATCTGGACTGCAGC Tnfrsf26 4837 AGAACGCGTTGGGAGAAAGC Pik3r3 8657 J CACATCTGCGTCACTTACAG Klhll 1018 AGATCTCCCAAACCCTCTTA Alx4 4838 ACGTTGCTCCTGGAAGGAGG Iqsecl 8658 CGCGAGCGCAGTCCGTTGCC Gnaz 1019 CGGTGCGAGTTCTTGCGAGT Dhdds 4839 GGCTTTGCGGCACTTCCGAT Dph2 8659 CTAACAATGCCAGTGTAAGG Ep l 1020 GCCGGAGCTGGAATACGAAC Cpsf3 4840 AACATTAACACTGCGTGGTC Txnrdl 8660 GGGCAGAAAGTTGCCATTTA Lefl 1021 GAGCGATTGTAAATGTGTGA Esrrg 4841 CTGTGACCTCATAGAGTACT Sun5 8661 o GAATCATAATGAAGCGCCTC Dclkl 1022 CCAGCAGGTTCGGCGATGCC Mierl 4842 CCTTTCTACCCTACTCATTA Gjb3 8662 GAGCCGTAACCTGCTCTTGC Synel 1023 ATTAGCCTACTTTGCAATCC Wdrl7 4843 GGGAAACACTGTCTAGGTTC Olfr530 8663 GAAGAGTGTCTGTTTAAGGG Cntnap5b 1024 AGGCGACTGCATTTATCTGC Runxltl 4844 GCAGAGGGTAAATTGATGTC 1700001C19Rik 8664 GCGCTGCCAGTCTCGGGAGG Dacli2 1025 GTGCTTTGATTGGTTGCCTG Ankrd36 4845 CCAGGCGAGAAGCTGCAGAC Paqr7 8665 o CATGCGTAGTGTCCATTCCA Tmeml06b 1026 TTTGAGCAGCTCCTCCTGAC Calr4 4846 GTTGTTTGTTCCTGCCGTCT Ctbp2 8666 4 ACAGGAGCCAGTCAGACTGG Etippl 1027 TCCCAGTACTCCTCCAGGCA Hpca 4847 CAATGAACCAGAGACCTGAA Bpifa6 8667 ACATCGCTCACGTCCGCCAG Aplbl 1028 ATCTAGAGCTTATCCATGTA 4930563M21Rik 4848 AATGCTCGCATACGTGGAAA Bdnf 8668 CTTCAGAGCGCATCCTCCAG Zbtb8b 1029 CCCACGCAGGCCCGGCGCCG Zfp777 4849 CTGAGAGTCCATCCTTTCCC Fhdcl 8669 ATCTCTCGGAGAGCAGCGAT Smiml2 1030 GTGTAGTCTTCCGCAAGCGC a s6 4850 TTCTCCCGAGGCGCCCTGTG Fycol 8670 CGCGCTGArTGGCCGCTACC Tes 1031 ACTCTTGCTTAGAAATCTAA Elavl4 4851 GCCGCGCTGAGGCAGCTCCG Markl 8671 TAAAGAAATGCAGAGTCACA Tmc5 1032 GCCGACCTCACTCATTGCTT Zmat4 4852 CAGCACAGCTGTCACACAGC Fam46b 8672 ATCTGCTATTAGGAGGCTCC Tfap2a 1033 CTGCGGCTCACTAGCTTGGC Dpysl3 4853 AACTTTCTCTGGATTTGTAC Pesl 8673 TGTCTGCTAAATGCTTCACC Gml2794 1034 AAAGCTTACTGTGCCAGGCC Fermtl 4854 GGGTCAACTTCCGTTCCGAG Toel 8674 AGACGGAGATCTCCGAGTTC Gml2789 1035 CAGGGCCTTTGTGCGACGAG I pd l 4855 TGGGAGCTACAGCCAAGAAG Ppie 8675 CTGAGGCACATTGTACAATC Ntm 1036 CCTTGGAAAGGAGCGCCTGC Lypdl 4856 TCTAGGTTGCCAAGCGACGC 4930430A15Rik 8676 TCTAGGGTCAGAGATCTTTC Aass 1037 TACCCAGTGAAACATTTACT Stra 1 4857 CCTCGCTTGCACGCTATCAT Lztfll 8677 GGTCCTGCGGGTTAGAGGCG Anol 1038 CTCAGACGCATGCGTGCTGA Nrap 4858 CGAGCTCACACGTGACGGCA Sorll 8678 GAAGCAACATTTATTCAGTA Rhd 1039 TACGTAGAGACAATCCATGG Vmnlrl95 4859 TCTAGTAGGAGGCAATAGCA Rcn2 8679 GGACAGGAAGTGCCTTGCGC Zfpl05 1040 CTGTGACCTCATAGAGTACr Sun5 4860 CCATTCCTGAAGTCATGCCG Fgb 8680 TGTTGGTAATGTCCCAAACT Cyp2a4 1041 CCTTTCTACCCTACTCATTA Gjb3 4861 TGCACGAGCGAGCGCGCTTG Lrp2 8681 AGAGCTTTCTGAGCAGGTGC Tmeml76b 1042 GGGAAACACTGTCTAGGTTC 01fr5 30 4862 GAGCCGTAACCTGCTCTTGC Sy l 8682 CTGGATAGCATTCTTGGTTT Serpinb9b 1043 GCGAGGATCCCTAGATGCAG Spdye4b 4863 GAAGTGACTCAACTCGGTTA Fez2 8683 TGAGGCAGCCCGCGTGCAAG Cd55b 1044 CCAGGCGAGAAGCTGCAGAC Paqr7 4864 GTGGGACTTCTCTCTTGCTG PpplrlS 8684 TCAGTATGTGTCACCAAAGG Nf2 1045 GTACTAATTAAGGACAACAG Adam7 4865 GACTGCAGCGATACTAACCC Arhgef2 8685 GCATAATCAAGACCAAAGTC Cyp2a4 1046 CAATGAACCAGAGACCTGAA Bpifa6 4866 CATGCGTAGTGTCCATTCCA Traeml06b 8686 GACATGGACAAGTTGTCTTG TsgaS 1047 ACTCACCAGCTACCAAGCCC Osbpl3 4867 ACTCCAAAGTGTAAGGTACT Txnrdl 8687 TCTCTCTCAACTCGTTATCA Soxll 1048 GGCrAATAATAGACTGATTA Pdzphl 4868 ACATCGCTCACGTCCGCCAG Aplbl 8688 AACGCCTCGCrrAAAGTAAC Mllt3 1049 CGCAGTGGGCAGCAGGCCTG Rnfl45 4869 GCGGAAGAAGGTGACGTCAA Senp2 8689 AGCTGTTTATCAACTGCACC Nap 114 1050 GAGTCAGCCCGCCTGCCGCT Arap2 4870 TGATCCCTCTAGATGCTCCC Gm7616 8690 TCCTGCTAAATTTGCCGCCA Dnahll 1051 CTGCTGAGCTGAGACTGAGG TbcldlOc 4871 TCGAGTGAGCGATCTGGCAG Supt3 8691 CTCTTTATTTCAAGAACTCC Grik2 1052 CAGCACAGCTGTCACACAGC Fam46b 4872 CTTCAGAGCGCATCCTCCAG Zbtb8b 8692 AAAGCCCGCGTAGTAAGCGC Itgb3bp 1053 CCTGAGCCTAAACACGCGAG Zc3hcl 4873 ATCTCTCGGAGAGCAGCGAT Smiml2 8693 AATGGAAGGAGCCAATGAAG Fam47c 1054 GGGACAAACTGAATCAGGCG Pan2 4874 AGTGGTTTCCCGGACCCTGC Κ1 7 8694 GCCAATTTGAAGGATGAAGA Plat 1055 GAGCAGCTGCAGTGCAGTGT Noval 4875 TGTACAGACCCTAAGATCTA Dsg2 8695 GGGTGACAGGAGCCCGACGT D630003M21Rik 1056 AACTTTCTCTGGATTTGTAC Pesl 4876 TGGAAACAGGATCCTGCAA G Cebpz 8696 AGCAACTCrCGGCTTAAACT Hnrrpl 2 1057 CGAGCrCACACGTGACGGCA Sorll 4877 CGCTCCAGCAGCGTCACGTG SenpS 8697 n GCTAGGGTGACTCACTGTCT Myll2a 1058 CACATCTGCGTCACTTACAG Klhll 4878 GGTCCTGCGGGTTAGAGGCG Anol 8698 GCATCA GG ATAAACTTC CC Skint1 1059 GTGACAGCGCTAACGCCTTC Zfp944 4879 AGGAGCCTTAGCCAGGTGCC Pglyrp4 8699 CAAGAGCCTCCCTATCCTCC Wisp2 1060 GGGTGGGTCACATGTTCCCG 01fm4 4880 GAAGCAACATTTATTCAGTA Rlid 8700 n ATTACCATGTATTAGCATAC Phc2 1061 GAGCCGTAACCTGCTCTTGC Synel 4881 GGACAGGAAGTGCCTTGCGC Zfpl05 8701 o CAGGAGGAGAGAGCGACGTG Ncmap 1062 GAAGAGTGTCTGTTTAAGGG Cntnap5b 4882 GGCAGCGCCAGTCTCTGCGG Enpp4 8702 CCCAGAGCAGGAGTTAATCG Nlgnl 1063 GCGCTGCCAGTCTCGGGAGG Dach2 4883 CCCTGAGAGGCTCGGAGCGG Assl 8703 b TGAGAGCCTGCCCACCGCTC Zfp941 1064 CATGCGTAGTGTCCATTCCA Tmeml06b 4884 GAGAGGTGTGAACGAGGTGT Crtam 8704 CACTAACCCrGAGCCAAGAG Pik3ipl 1065 GGCATTCCGTAACCTTGTTT Pan2 4885 ATGAGCAAGCCACAGTCCTG Traeml25 8705 J AGGGCTTGTAGAGCTTACTA Clip4 1066 ACATCGCTCACGTCCGCCAG Aplbl 4886 CTGGATAGCATTCTTGGTTT Seipinb9b 8706 CCCGCCCTGCAAAGCAGACG Smox 1067 GAGGAGGAGCCTAGAATGCC Eci2 4887 TCAGTATGTGTCACCAAAGG N£2 8707 GCACAAAGGAGAAATCATAC Slc24a2 1068 CTTCAGAGCGCATCCTCCAG Zbtb8b 4888 AACGCCTCGCTTAAAGTAAC Mllt3 8708 TTCTAGAAACTTGGATTCCA Slc30a2 1069 ATCTCTCGGAGAGCAGCGAT Smiml2 4889 AGCTGTTTATCAACTGCACC Napll4 8709 o ATCGGCATATTGAGGATGAG Grm6 1070 CGCGCTGATTGGCCGCTACC Tes 4890 TTCTGGAAACAGCCTATACA Taf7 8710 GATGTTGCAGGTTAGTGGAA Zfp354a 1071 ATCTGCTATTAGGAGGCTCC Tfap2a 4891 TGCCCTGGTGCAGGGTCATC Dnalil7 8711 GAAGCCGCGGTGCCAAATTA Lyrm7 1072 AATCCTGGCCTGGAGTCGTC Dab2ip 4892 GCCCTCCTGCGGAGCGATCT Lbr 8712 TTTCTGGTGCTAACTTGCCT Skint 10 1073 TGTCTGCTAAATGCTTCACC Gml2794 4893 GCTAATTTCCGCGGGTACAT Lztfll 8713 oi CCTACCCTGCAGGCAGAATG Trpal 1074 AGACGGAGATCTCCGAGTTC Gm 12789 4894 GGGTGACAGGAGCCCGACGT D630003M21Rik 8714 TA CGTGA GCAGAA GTA GTTC Hnr p 2 1075 TCTAGGGTCAGAGATCTTTC Aass 4895 CTTAACCTCGTGTTTGCACG Erailin3 8715 CCAACTTCTTTAAGGAGTTA Dctd 1076 GGTCCTGCGGGTTAGAGGCG Anol 4896 ACTGTGTGTGATGTCTGCCA Itga4 8716 ATTAGCTCGCGCGGCGACCC Shisa3 1077 GAAGCAACATTTATTCAGTA Rlid 4897 TGTAGTCCACGGACGCTTGT Lars 8717 GGCGGTGAGTAACACATCAT At l a4 1078 GGACAGGAAGTGCCTTGCGC Zfpl05 4898 CAAGAGCCTCCCTATCCTCC Wisp2 8718 ATGGTGCTGCGCCGGTTGCC Eiil 1079 ATGCTGGATGGAGTTTAAAC Ephx3 4899 ATTACCATGTATTAGCATAC Phc2 8719 CGGGAGTTGCAAGTAAGCGC Mfliasl 1080 AGGTATGATGTTATTTGTCA Igfl 4900 CAGGAGGAGAGAGCGACGTG Ncmap 8720 ACAACCCAGACTTACAGACC Laptm5 1081 AGAGCTTTCTGAGCAGGTGC Tmeml76b 4901 TGAGAGCCTGCCCACCGCTC Zfp941 8721 AGGCAGCACGAGGTGGCCTG Ctsc 1082 CTGGATAGCATTCTTGGTTT Serpinb9b 4902 CACTAACCCTGAGCCAAGAG Pik3ipl 8722 CATGCGTACTTCAAGAGCCC Kif3a 1083 TGCACCACCGGGCTCCGAGC Oprdl 4903 GCACAAAGGAGAAATCATAC Slc24a2 8723 CTTAAAGCTCTTCCCAAGCT Myolg 1084 TCAGTATGTGTCACCAAAGG Nf2 4904 TTCTAGAAACTTGGATTCCA Slc30a2 8724 TAGGTGAATGCCACCATTCC Tbcel 1085 CACAGTACGCCAGAATTTGG Folhl 4905 TAAAGTGGTATTTGTGAAAG Arhgdib 8725 GGGAACCGGGTACGGAGAGG Nol41 1086 GACATGGACAAGTTGTCTTG TsgaS 4906 ATCGGCATATTGAGGATGAG Grm6 8726 CTCACCAATGGCCGTCCGGG Tspan33 1087 TCTCTCTCAACTCGTTATCA Soxll 4907 GATGTTGCAGGTTAGTGGAA Zfp354a 8727 AAGAGCAGGCATTAGGAGTC Tspyl3 1088 AACGCCTCGCTTAAAGrAAC MUt3 4908 GAAGCCGCGGTGCCAAATTA Lyrm7 8728 AGACATGCTGAATAACAAAG Adamtsll 1089 AGCTGTTTATCAACTGCACC Nap 114 4909 TTGAGTTACAGGAAGGACCG Acnat2 8729 GGACGAGAGGGAGAGAGAGG Gap43 1090 GCGGACGGGTAGCTAAGCGG Ykt6 4910 ACAACCCAGACTTACAGACC LaptmS 8730 ATGGCTGTGAACGGCCACTG Hnf4g 1091 AAAGCCCGCGTAGTAAGCGC Itgb3bp 49 CATGCGTACTTCAAGAGCCC Kifia 8731 CTGAGACAACCTTACTGCGC Dhcr7 1092 GAGCCATAGCTACACTGCTG Clec3b 4912 GCTCGGGTTGCCCTGACAAC Fankl 8732 GAGGCGCTTCTAGCGACACG Uqcrq 1093 AATGGAAGGAGCCAATGAAG Fam47c 4913 AAGCAGGCAGCCCTAGTGTC Cetf3 8733 CTGTCTGGAAGTGGGAATGT Plbl 1094 GGAAGGAGGCACTCGGAGAC Sema4a 4914 CTTAAAGCTCTTCCCAAGCT Myolg 8734 CAGAGATTCAAAGCTAACCT C77080 1095 GCCΑΑ ΤGAAG GATGA AGA Plat 4915 TAGGTGAATGCCACCATTCC Tbcel 8735 GCCGCCGCTAAGGAAAGAGG Tfap2a 1096 GGGTGACAGGAGCCCGACGT D630003M21Rik 4916 CCGGACTGCTGGAGCTGGAC Rabl3 8736 CGAGCCTTCCGGAGGACGCG Phc2 1097 CTTAACCTCGTGTTTGCACG Emilin3 4917 GCAGGGAGGAGGATACTGCC Oxct2a 8737 ATTGTCTGTCTTGAAGGGAG Rassf2 1098 AGCAACTCTCGGCTTAAACT Hnrnph2 4918 TGGCCATCCTGGTGGAGGTG Robo3 8738 GAACTGATGGACACCGAGTG Cfap46 1099 GCTAGGGTGACTCACTGTCT Myll2a 4919 GGGAACCGGGTACGGAGAGG Nol41 8739 GTTCTCGTGGCGCACTGAGC Srrml 1100 GCATCAGGT ATAAACTTC CC Skint 1 4920 AAGAGCAGGCATTAGGAGTC Tspyl3 8740 ACTGCAAACTGACGCCGACG Cars 1101 CAAGAGCCTCCCTATCCTCC Wisp2 4921 AGACATGCTGAATAACAAAG Adamtsll 8741 ACATCGGCTGGCGACGGTGG Emc7 1102 ATTACCATGTATTAGCATAC Phc2 4922 CTGAGACAACCTTACTGCGC Dhcr7 8742 ATCATCGGGCAACAGTGCTT Kdfl 1103 CAGGAGGAGAGAGCGACGTG Ncmap 4923 GAGGCGCTTCTAGCGACACG Uqcrq 8743 GAGACTTGriTGrCTGGGCC Tcn2 1104 TGAGAGCCTGCCCACCGCTC Zfp941 4924 CAGAGATTCAAAGCTAACCT C77080 8744 AAGAAATCCACGGCTAGTTT Gabra6 1105 CACTAACCCTGAGCCAAGAG Pik3ipl 4925 CGAGCCTTCCGGAGGACGCG Phc2 8745 n GTCGCTACAAACTTCGCCGA Myh8 1106 AGGGCTTGTAGAGCTTACTA Clip4 4926 GGCTCCACTTTGGCGCCTGA Ing3 8746 CGACTCTCGAGCGTCTCCAT Rbbp4 1107 CCCGCCCTGCAAAGCAGACG Smox 4927 TGGCCGCGGATCCATTGCAC Adaml2 8747 TAATCACTAGGGTATGTCTT Foxp2 1108 GCACAAAGGAGAAATCATAC Slc24a2 4928 GTGTGTTCCTATTGGTCAGG Cadm2 8748 GGCGGTAAGTAAA GATG GTG Slcl3al 1109 CAGACACCAGCTGTTTATGT Ccdcl36 4929 GAACTGATGGACACCGAGTG Cfap46 8749 oi ATGGACACAACGGCAGGGCG Pxmp4 1110 TTCTAGAAACTTGGATTCCA Slc30a2 4930 TACTGTAGATATAACACCAC Lamp5 8750 CGGAACTTA ATAGACA CCAA Cars 1111 GCCACTGCACTCCACCGATC Slc22a4 4931 GTTCTCGTGGCGCACTGAGC Srnnl 875 1 TCATTTCTATGCTAGGGCTT Scgb3a2 1112 ATCGGCATATTGAGGATGAG Grm6 4932 GCACTCTGGAAGCCATGACT Arhgdib 8752 AGATTGAATCTCAGAGTTTA B020004J07Rik 1113 GATGTTGCAGGTTAGTGGAA Zfp354a 4933 ACTGCAAACTGACGCCGACG Cars 8753 J TCGGAGAGCAAGCATTCTGC Mllt3 1114 GAAGCCGCGGTGCCAAATTA Lyrm7 4934 ACGTCGACGTCCGCACGCTG Afg312 8754 GCCTTGCACGCCGCCCATTC Mrgprg 1115 TTTCTGGTGCTAACTTGCCT SkintlO 4935 GACTCTCAAATTAAGTGGGC Cxcr6 8755 AAACAAAGCTTTATCACGTG Slcolcl 1116 GGCCTGGCTGCCCGCGTTGC Dab2ip 4936 GGGCGGTGGAGCTTTAGGAG Dcbld2 8756 GGCTGCGGGAGGAGGGTGCC Gabrg3 1117 TACGTGAGCAGAAGTAGTTC Hnmph2 4937 GAGACTTGTTTGTCTGGGCC Tcn2 8757 o GGAGCTGCGGCTAAGCGCGC Zmym4 1118 CCAACTTCTTTAAGGAGTTA Dctd 4938 GGGACAGGGAGGCCTCCCGG HiOa 8758 GGCTGCTGAGCCCACGTCAG Sfip4 1119 ATGGTGCTGCGCCGGTTGCC Eril 4939 GTCGCTACAAACTTCGCCGA Myh8 8759 TATCCCAGAGTGCTCGAGTC Mtgl 1120 TTGAGTTACAGGAAGGACCG Acnat2 4940 CGACTCTCGAGCGTCTCCAr Rbbp4 8760 ATAΑΑΓΓΑΑΓGCTCCTGCGC Dadl 1121 CGGGAGTTGCAAGTAAGCGC Mfhasl 4941 GAGACCCTTAGTCATGGrGG Bdnf 8761 o 4 AATTGCTAACAATCAGATAG 115 1122 ACAACCCAGACTTACAGACC Laptm5 4942 AACTCATATGGGTTGGAGGG Arid3b 8762 CGGAGGCTGAGCGATCGCTG C77080 1123 AGGACAGTGCCAGCCAATTC Pparg 4943 ACGCGCCCTTTGAAACTCAG Pex6 8763 AAGTGGCrTGrrCATGCACA 4930430A15Rik 1124 CATGCGTACTTCAAGAGCCC Kif3a 4944 TAATCACTAGGGTArGrCrT Foxp2 8764 ATGCCGTGTCCTCTGAACGG Mylk2 1125 TAAGAAATCTTTATTCGCGC Ap4el 4945 GGTGAGGGCAGGAAATCATC Lat 8765 ACCCGGTGCGGATAGGGCTC Epsl5 1126 CTTAAAGCTCTTCCCAAGCT Myolg 4946 AACTGGGCAGCCTAGCAGAG Cc2d2a 8766 TCGCTGCTTCTTACGTAAGC Ak4 1127 GGGAACCGGGTACGGAGAGG Nol41 4947 ATGGACACAACGGCAGGGCG Pxmp4 8767 CCCGAGATCCCGCAGCTCGG kx2-4 1128 CTCACCAATGGCCGTCCGGG Tspan33 4948 CGGAACTTAATAGACA CCAA Cars 8768 TGCATAACGCTCGAGCATTC Taf71 1129 AAGAGCAGGCATTAGGAGTC Tspyl3 4949 TCATTTCTATGCTAGGGCTT Scgb3a2 8769 TGAGAACTGTCATTATCTAG Gmll437 1130 AGACATGCTGAATAACAAAG Adamtsll 4950 AGATTGAATCTCAGAGTTTA B020004J07Rik 8770 CGTGATGATGCAAACCGGTG Grm7 1131 GCAGGTAACCCGGCCTAATA Tc2n 495 CTGGCCATGTGGCTGTATAA AbcaSb 8771 TCAGGCTGGAGCTAGGTCGC Spef2 1132 GGACGAGAGGGAGAGAGAGG Gap43 4952 TCGGAGAGCAAGCATTCTGC Mllt3 8772 ACTCATCTGATCGTGATGCG Adgrl3 1133 TCAGCCACCGCACTTCTTTG Rosl 4953 GCCTTGCACGCCGCCCATTC Mrgprg 8773 AGCTGCGCGCAGTGCCCTCG Cdkl3 1134 CTGAGACAACCTTACTGCGC Dhcr7 4954 GGAGCTGCGGCTAAGCGCGC Zraym4 8774 AGTTGATTGCAAAGAGGCGG Erbb4 1135 GAGGCGCTTCTAGCGACACG Uqci 4955 GGCTATCAGCCGGGTAGGAC Tbrgl 8775 CAATACTAAAGAAAGCATCC Tm9sf4 1136 CAGAGATTCAAAGCTAACCT C77080 4956 GGCTGCTGAGCCCACGTCAG Sfrp4 8776 GGAACAGAGCGTAGTGCCAA Impdhl 1137 GCCGCCGCTAAGGAAAGAGG Tfap2a 4957 TATCCCAGAGTGCTCGAGTC Mtgl 8777 TTGACAGCGAGAGCGCCTCC Rnf215 1138 CGAGCCTTCCGGAGGACGCG Phc2 4958 CTGCAGTCTTAGCAGCTATA Rxfpl 8778 GTCATAGAGGACTCAGTCCT Saxol 1139 GAGAGGGCCAGCCTCACCGC Lmo2 4959 CTGACTCAACTCCACGAACA Dt a 8779 CCTGGAGGGCGTCCTGGCGG Emidl 1140 ATTGTCTGTCTTGAAGGGAG Rassf2 4960 ATAAATTAATGCTCCTGCGC Dadl 8780 AGCTCGAATCCGTCGCTATG Cyb5r2 1141 GAACTGATGGACACCGAGTG Cfap46 4961 CAGTGGGCGTGGCTAGGCGT Lrrc71 8781 TCACCGTCCTCTAGGGACTC Tcf7 1142 GTTCTCGTGGCGCACTGAGC Srrml 4962 AATTGCTAACAATCAGATAG 115 8782 ATAGGGCTrGATTCTCATCC Bpifa2 1143 ACTGCAAACTGACGCCGACG Cars 4963 CGGAGGCTGAGCGATCGCTG C77080 8783 TTCTCTTTGTGGCCTCGCTC Npral 1144 ATCATCGGGCAACAGTGCTT Kdfl 4964 AAGTG GCTTGTTCATGCACA 4930430A15Rik 8784 CTTCCGCAAACGCGCCTGGG Arf5 1145 GAGACTTGTTTGTCTGGGCC Tcn2 4965 AAGCAAAGATGAGCATCTGC Trcgl 8785 ATCAAACCAGCCCGCTCTAT Fam83d 1146 AAGAAATCCACGGCTAGTTT Gabra6 4966 ATGCCGTGTCCTCTGAACGG Mylk2 8786 TGCGGAGCGCTGTTTGGCGC Arhgaplla 1147 GTCGCTACAAACTTCGCCGA Myh8 4967 CGCTAGAGGCTGCTTGTTCC Commd4 8787 TTGCTAAGAACTCTCTCTCC Speer4fl 1148 CGACTCTCGAGCGTCTCCAT Rbbp4 4968 AGAGCTGCAAGTCGATTGTC Nr2f2 8788 GGCGGCTCCGCATAACCACG Asxll 1149 TAATCACTAGGGTATGTCTT Foxp2 4969 GAGACACAGGTCCTGCGGAC Gpatchl 1 8789 GGGCAAGGCTAAGTAAGGTA Dacli2 1150 GGCGGTAAGTAAAGATGGTG Slcl3al 4970 AACTCGTCTAAGTTCACGAA Meal 8790 GTTTGGGTGTCACCGGCTGC Anxa6 1151 GGGTAGTACACTTCCAGCAG Sox5 4971 AGAGCATTCTCACATGGCCC Gml6130 8791 ACGGAGGGTGGCGCATTGAA Tpx2 1152 ATGGACACAACGGCAGGGCG Pxmp4 4972 CCCACTGAAGGGCTCGGGAG Efna5 8792 TCCAAAGCAAGATCCA GATA B020004J07Rik 1153 CGGAACTTAATA GACACCAA Cars 4973 GACTGGTGAGACCCGCCTCC Gbel 8793 n CTCTCTCCCTCCTAACATGC Prom2 1154 TCATTTCTATGCTAGGGCTT Scgb3a2 4974 ATTGTCACCTAGGCGTCCTT Pptl 8794 GGGCCCAGCCCTTTCC CGAC Map3k6 1155 AGATTGAATCTCAGAGTTTA B020004J07Rik 4975 CAGGCGCGGGTGCTGATGTC Lgi2 8795 CAGAGGCCAACCTGTCCTCT Faml79a 1156 TCGGAGAGCAAGCATTCTGC Mllt3 4976 GGCCAGGAGCACCGGCGGCA Npt 8796 n GTTTGTGTTTCTGGCCTCTA Atp6vlf 1157 GGAGCTGCGGCTAAGCGCGC Zraym4 4977 AATTGCCTCAGTGATGCCAC Kdm4c 8797 o GCCCGAGGCTGACTTCTCAT Tspan33 1158 GGCTGCTGAGCCCACGTCAG Sfip4 4978 TAGCGCCAGCAAAGCACTGC Cplx3 8798 CAGCGGGTGAGCCAGCTTGC Maf 1159 TATCCCAGAGTGCTCGAGTC Mtgl 4979 CCTGAAACTAAGGATTTAGA Klc4 8799 b AACATCArCGGGATCTAATC Ofccl 1160 ATAAATTAATGCTCCTGCGC Dadl 4980 AGCTGCGCGCAGTGCCCTCG Cdkl3 8800 GGGACGTTGGTTCCCTGCAC Slco6dl 1161 TCAGGGTAGGAGATGGGTGT Skmt6 4981 TAAACTCTTCCCTACTTCGC Tbrgl 8801 J CGGGACCCTCGGCACCCATT T¾cldlOa 1162 CGACCTCGGATGACGCCAGC Morf411 4982 CAATACTAAAGAAAGCATCC Tra9sf4 8802 TAGGGCrATTTCTGCCAGGC Fstl5 1163 AATTGCTAACAATCAGATAG 115 4983 TTGACAGCGAGAGCGCCTCC Ruf215 8803 ATGAAAGACGCACTCACTCC Tnc 1164 TTGTGCGGCTCGCCCAGGCC Rai2 4984 GGCCGCATTGAGGCTGCGCT Zfp24 8804 TTGGCACAGCTACATCAGCG Tm2dl 1165 CGGAGGCTGAGCGATCGCTG C77080 4985 CTGAACGCTCGCTTTATCAG Ermap 8805 o AAAGGAGCTCTGGACCACTA H13 1166 ATGCCGTGTCCTCTGAACGG Mylk2 4986 TCTCGAGGCTCACGCCCTCG Creb314 8806 TGCCTAACCACCTCTACCTT Prame 1167 GCCTCAGGTCAGAGTCGCCC Pparg 4987 GTCATAGAGGACTCAGTCCT Saxol 8807 TGCCAAACTCCAGAAATACC Spagl7 1168 ACCCGGTGCGGATAGGGCTC Epsl5 4988 TTAAACACTTAGGCCTAACG Proml 8808 ATA GAGTTTGGTTACTTGAA leal 1169 TCTGAATATGAGCAAGTGGT Gml3103 4989 CCTGGAGGGCGTCCTGGCGG Eraidl 8809 o AGACTACCACCGTAGA CAAG Fam83d 1170 ATGCTAAGACCACAACTACA Gimapl 4990 AGGGAATAAAGGCACTAGTG S100a5 8810 4 GCGCCGCTGCCCTTGTAGCC Dnmt3b 1171 TCGCTGCTTCTTACGTAAGC Ak4 4991 CCTAGAAATCTCCCACACCC H2-M10 4 8811 TCACTTTGAGAAGAGAGATA Defb7 1172 GCGACCAGCCAGGTTCAGTC Kcnip3 4992 TCACCGTCCTCTAGGGACTC Tcf7 8812 TGCGCATGTTCCACCCGCTC Hjurp 1173 TGCATAACGCTCGAGCATTC Taf71 4993 GGGCTGTGCAGCCTCTAGCG March5 8813 GAACCCGCGGAGCCTCCGGT Rps6kal 1174 ATTCTGAAGCCAGATGCGCC Rackl 4994 ATAGGGCTTGATTCTCATCC Bpifa2 8814 GTAGCCACGCCCAAGTCGCG MapkS 1175 GCTCAGAGCCTTATCCACAC Cacnale 4995 ATCAAACCAGCCCGCTCTAT Fam83d 8815 GAACTTGATAGACTGAACTA Prr27 1176 ACTCATCTGATCGTGATGCG Adgrl3 4996 CACGACTTCCGCTCACGACG Rrp36 8816 GAAGCCTGAGAGCGAGGCTG Caly 1177 AGCTGCGCGCAGTGCCCTCG Cdkl3 4997 CTGCCCGCGAAGCGACCGCC Neol 8817 GCAATCGGCTCGTGTCTCTC Bpifa5 1178 AGTTGATTGCAAAGAGGCGG Erbb4 4998 GGCGGCTCCGCATAACCACG Asxll 8818 GCTTTGGCACGGATGGCACG Calr4 1179 CAΑΓΑ CTAAA GAAAGCATCC Tm9sf4 4999 CGGGAAAGTTGGTTCCACTC 17000 17B05Rik 88 19 CGAGTTTCACTCTCACTATC Gmll437 1180 GGAACAGAGCGTAGTGCCAA Inipdhl 5000 TGCGCATGCGCGGAAGTCGA Sepsecs 8820 GCTGTCTTACCTGATTCCTC Tmeml76a 1181 TTGACAGCGAGAGCGCCTCC Rnf215 5001 GTTTGGGTGTCACCGGCTGC Anxa6 8821 GGTCACATGGCATAGATGTC Lactbll 1182 GTCATAGAGGACTCAGTCCT Saxol 5002 AGGCGCCCGGACAGGCATCG Fycol 8822 TAAGCGGAAGAGACAAGAAC Wdr36 1183 CCTGGAGGGCGTCCTGGCGG Emidl 5003 TGGACGCTAACTACGACTCC Fycol 8823 GTGCTGCTGCGCTATAGCGG Stk31 1184 AGCTCGAATCCGTCGCTATG Cyb5r2 5004 GCTGGAGGCGGGACGACGAC Adpgk 8824 TACACTAAACCCATACCTCC Bcl211 1185 TCACCGTCCTCTAGGGACTC Tcf7 5005 ACGGAGGGTGGCGCATTGAA Tpx2 8825 GGAGCCAAACATGGCGTCTA Ccm21 1186 GCCGCAGCAAGTCCCTGCCC Jak3 5006 TCCAAAGCAAGATCCAGATA B020004J07Rik 8826 TGCGCAGAGCCAG CACAAAT Ddx56 1187 ATAGGGCTTGATTCTCATCC Bpifa2 5007 GCAAGCTCTTTAGCTGTACG AdamtsW 8827 AGAGGTGGCAGTTGCAGGCC Ppplr3g 1188 CTTCCGCAAACGCGCCTGGG Arf5 5008 AACCTTCTCTGCCTTAGTCA Abcc5 8828 CCTTTCGGGCTTCGGTGGAG Ralgapb 1189 ATCAAACCAGCCCGCTCTAT Fam83d 5009 GGGCCCAGCCCTTTCCCGAC Map3k6 8829 AAGATGAGCCGCGCTCGCTG Tall 1190 TCAGCAACCGCCGAGTAGTG Cggbpl 5 0 TGTTGACATAAACGCAGGAC Tbx3 8830 GGTAACCCACAGCCAGTGAC Pax4 1191 GCGGATGTCCCGACCCTCCr 01fm4 5011 GCTAGACAGTTGCCTTCTTT Tecta 8831 AGTATG CAAAGGATA GTGAT HistllBa 1192 GGCGGCTCCGCATAACCACG Asxll 5012 AGTTCTAGTTGCCCAACTAT Acnat2 8832 TTTCGGTTCTACTCCTGCAG Snligll 1193 GGTGGCTTTGCGGGCGCTCG Phfl2 5013 CGGGACCCTCGGCACCCATT TbcldlOa 8833 AGCTAAGGCCTCACCTCCCT Cobl 1194 GGGCAAGGCTAAGTAAGGTA Dach2 5014 TAGGGCTATTTCTGCCAGGC Fstl5 8834 ACCTCCCTTGGATCTCGCCC 1122ml 1195 GTTTGGGTGTCACCGGCTGC Anxa6 5015 TGCGCGAGACACAGGTCCTG Heatr5b 8835 AGAAACTTATGACTTCCTAA Rnfl48 1196 ACGGAGGGTGGCGCATTGAA Tpx2 5016 GGTCTAGGGAGAACCTGAAG Celf3 8836 TCGCCGTCAGATrrCTTTGG Zfp282 1197 GCTTGGCGGGTGCTGTGCGT Pparg 5017 AAAGGAGCTCTGGACCACTA H13 8837 GGTCAGTGGAAGGAAGGCTG Arl5a 1198 TCCAAAGCAAGATCCAGATA B020004J07Rik 5018 GGAATCCTCTGCTTCCGTTT Recll4 8838 CTACACCAArrGAAGGTTAC Ap3m2 1199 GTTCTGCTCAGACAATAAGA Hdac9 5019 TCTAGAGCCCTTGCCGGGCG Col5a3 8839 AAA GAGACGCCACTGTTAGA Rnpc3 1200 CTCTCTCCCTCCTAACATGC Prom2 5020 TGCCAAACTCCAGAAATACC Spagl7 8840 CGTGCTTAAACGGCACAGCA Dnah5 1201 GGGCCCAGCCCTTTCCCGAC Map3k6 5021 CTCGTTCTGAACAGCAGTAT B3galt5 8841 n ATTAAGATAAAGCATCAGAG Insl5 1202 CAGAGGCCAACCTGTCCTCr Fanil 79a 5022 ATAGAGTTTGGTTACTTGAA leal 8842 TACGCATGTGCCTCCCAGCT Itk 1203 GATGCAATAAGGCTTGCCCG Cstal 5023 AGACTACCACCGTAGACAAG Fam83d 8843 GAGAGGAGATGGATGTCCCT Paox 1204 GTTTGTGTTTCTGGCCTCTA Atp6vlf 5024 GCGCCGCTGCCCTTGTAGCC Dnmt3b 8844 n TATTTATATCCATCCCACTC Adgrdl 1205 GCCCGAGGCTGACTTCTCAT Tspan33 5025 TCACTTTGAGAAGAGAGATA Defb7 8845 o AGCACAATCTGGGCGGGTCC Gja4 1206 GACTATCATGCTCAGAGCCT Nme4 5026 TGCGCATGTTCCACCCGCTC Hj p 8846 GGTACCGGAACAAATCTTGC Zscan20 1207 AACATCATCGGGATCTAATC Ofccl 5027 GAACCCGCGGAGCCTCCGGT Rps6kal 8847 b GGTGTCCATGCAGGTGGGCG Slc36a2 1208 AAATCCTATTGGCATCCAGG Gda 5028 GAGGTGTTTCTGCCTTCCAC Dsglb 8848 CAAAGGTGCAAGTTTCCCTC Cntnl 1209 AGTTCTAGTTGCCCAACTAT Acnat2 5029 GCAAGTCACAGAGCACAACA Pdlim5 8849 J GTGAGCACrGGCGCCGCGGG Zfp746 1210 GGGACGTTGGTTCCCTGCAC Slco6dl 5030 TATTGTCCTCCTCCGAGACA Prelid2 8850 GGAAGGAACGGGAGAACTAG Grhl3 1211 CGGGACCCTCGGCACCCATT TbcldlOa 5031 GGCAAGAGGCAGAGCATTGT Gucala 8851 ATTGCTCAGGTTATGACACC Histlhlt 1212 TTGGCACAGCTACATCAGCG Tm2dl 5032 AAACTGACCAATAGAAGAAG Cgn 8852 CAATAAACATGTTGGCCCTG Ly6c2 1213 AAAGGAGCTCTGGACCACTA H13 5033 GAAGCCTGAGAGCGAGGCTG Caly 8853 o GGCCTGTTCGGAGGGAGTGG Osbp2 1214 TGCCAAACTCCAGAAATACC Spagl7 5034 GCAATCGGCTCGFGFCrCTC Bpifa5 8854 GGGTCCGGAACCGGTTTGGG Spagl7 1215 ATAGAGTTTGGTTACTTGAA leal 5035 GCCAAATGCTTGArCTCTGA Celf3 8855 AGCGTTTCTTTACGTAGCGC Tmem230 1216 AGACTACCACCGTAGACAAG Fam83d 5036 GCGTTGGTATATTCCTATAC Slcl6al4 8856 GCAGAGCAGCTTCTCCTATG Foxp2 1217 GCGCCGCTGCCCTTGTAGCC Dnmt3b 5037 AGAGGTCAAAGGGCGTTGAG Stai 6 8857 o GCTGGACCATTCTCAAGAGG Oca2 1218 TGCGCATGTTCCACCCGCTC Hjurp 5038 GTAGAGCTGGCTGGAGTCCA HiGa 8858 4 TTACGTCAGTGTGCTGTTTC Pet2 1219 GAACCCGCGGAGCCTCCGGT Rps6kal 5039 AGTTCTCAGTATTTACATAC Mpi 8859 CCATCAAA CATTGAAGA GAG Satbl 1220 GTAGCAACCATAGGTTCTAA Zan 5040 TACACTAAACCCATACCrCC Bcl211 8860 GACAGAGCTAGTCCATCACC Fhadl 1221 GAAGCCTGAGAGCGAGGCTG Caly 5041 GGAGCCAAACATGGCGTCT Ccm21 8861 ACCTGAGCCATGCCAAGGAA Skint9 1222 GCAATCGGCTCGTGTCTCTC Bpifa5 5042 AGCGGTGACTGAGAGAAGGG C sp2 8862 GGCGGAGTTFAGGGAAGCAG Urgcp 1223 GCTTTGGCACGGATGGCACG Calr4 5043 TGCGCAGAGCCAGCACAAAT Ddx56 8863 TGCTCAGAGCrrCCGACTGC Foxsl 1224 GAGAGCGGCGACTGGTGACG Ncapg2 5044 CCTTTCGGGCTTCGGTGGAG Ralgapb 8864 CTCTTGACTATACATAACAG Nxf2 1225 GTGCGAAAGGGTACCCGAGG Rai2 5045 AGTATGCAAAGGATAGTGAT Histlh3a 8865 GCGAGGACTGCGCGCTACCC Eif4enifl 1226 GCTGTCTTACCTGATTCCTC Tmeml76a 5046 CCTAGGCCACTACCGCGAAA Vegfa 8866 CAGATTCTGAGCTGCAAGAC Gm55 2 1227 GGTCACATGGCATAGATGTC Lactbll 5047 TTTCGGTTCTACTCCTGCAG Snhgll 8867 TTTAGGGTGGAGATAGAACT Trim27 1228 TCTAGCTGGGCGCGAGCCCG Apafl 5048 ACCTCCCTTGGATCTCGCCC I122ral 8868 GGCCTCTCTTTCCATAGACC Lnn4 1229 GTGCTGCTGCGCTATAGCGG Stk31 5049 CATCACTACCAGCAGGCGG A Cfap44 8869 AAGACCCGACATTCCTCTTC Esrrg 1230 TACACTAAACCCATACCTCC Bcl211 5050 CTTCGTTGGCGCGGCGGCCC Zicl 8870 GACTCTTCCAGAGCTGCTGA Havcrl 1231 GGAGCCAAACATGGCGTCTA Ccm21 5051 AGAGACAGGGACAGGACGTG Mpl 8871 ATCACGFGArCCATAGTGGG Dhx35 1232 TGCGCAGAGCCAGCACAAAT Ddx56 5052 TACGCATGTGCCTCCCAGCF Itk 8872 TTGATCCTGGAAGGCAATCC Rab42 1233 AGAGGTGGCAGTTGCAGGCC Ppplr3g 5053 GAGAGGAGATGGATGTCCCT Paox 8873 CGTCAGAGGAAATAGAGGCG Sla2 1234 AGGCGGCTGTGGGTGGG CAG Cacna2dl 5054 AGCACAATCTGGGCGGGTCC Gja4 8874 o CAATCGCCGCGCCGGCCAGA Sfipl 1235 CCTTTCGGGCTTCGGTGGAG Ralgapb 5055 GGTACCGGAACAAATCTTGC Zscan20 8875 CAAATGAGGGA CACA GAGGA Piwil4 1236 AAGATGAGCCGCGCTCGCTG Tall 5056 GGTGTCCATGCAGGrGGGCG Slc36a2 8876 GGATACrCrCCGCTGATCCA Phykpl 1237 GGTAACCCACAGCCAGTGAC Pax4 5057 ATGCCCTCTCTGACCTCCTG H2-B1 8877 GGGACGTTrGGAAGATGCTT Cst9 1238 AGTATGCAAAGGATAGTGAT Histlli3a 5058 GGTGGGCTGGCrCrGCGACC Arhgef2 8878 TGACTCGTCTTGTTCTATTT Pdzplil 1239 GTGGGAATGAACCGGCTGGG Spin4 5059 CTTGGGCTCCAGCACCACAA Phldbl 8879 CCCGTTTGGCCAATGACAAT Ascl2 1240 TTTCGGTTCTACTCCTGCAG Snhgll 5060 GGTTCGCTCTGTTTA AGTCT Adpgk 8880 CTGGAGAGGGAGTAACCCGT Gccl 1241 ACCTCCCTTGGATCTCGCCC I122ral 5061 GCCTCTCAGAGGACCTGGCA Klc4 8881 GGGAGGCGCGCGTGTGCTCC Rein 1242 AGAAACTTATGACTTCCTAA Rnfl48 5062 GGAAGGAACGGGAGAACTAG Grhl3 8882 GTGCCCAACGGTGCCAGGGT Nrsnl 1243 TCGCCGTCAGATTTCTTTGG Zfp282 5063 ATTGCTCAGGTTATGACACC Histlhlt 8883 TGCGCCCAGAGGCGCTACGG Wac 1244 AAGACCTCGTGAGTTGGAGG Gga2 5064 GAGTGGGATGCAAAGCCTCT Trappc8 8884 GGATGACCGCGACCGCGCGC Lpin2 1245 CTACACCAATTGAAGGTTAC Ap3m2 5065 TTTCTCTGGGTCGGGTAGGA 4930503L19Rik 8885 TCTATCACCCATAAGCTTAC Tespal 1246 TGGAATTCATGAAGCAGCCA Vmnlrl89 5066 GTTTG CAGAGCCGGCGGGAC Jtb 8886 GGTCAGCTCACAATGATGAA Fam71fl 1247 ATTAAGATAAAGCATCAGAG Insl5 5067 GCGAGGGAGGATCAAGAAGA Tbx3 8887 TTGTAGTTTGCATGTGTCCG Cenpj 1248 TACGCATGTGCCTCCCAGCT Itk 5068 GAGCGCTCGAGGAGAAGTCA Lrat 8888 ACCTCCAGGGCTAGCCAATG Zfp956 1249 GAATAGCAGCAAGGCCAAGG Stra61 5069 GGCCTGTTCGGAGGGAGTGG Osbp2 8889 n GAGGCAGTCTCCAGGGAAGT Slc36al 1250 GAGAGGAGATGGATGTCCCT Paox 5070 GGGTCCGGAACCGGTTTGGG Spagl7 8890 AAGCCAAGAACTAGGAGGAG Paxl 1251 AGCACAATCTGGGCGGGTCC Gja4 5071 GCAGAGCAGCTTCTCCTATG Foxp2 8891 TTGCATCACAAAGCGTTGCC Cst8 1252 GGTACCGGAACAAATCTTGC Zscan20 5072 TCCGGAGCAGGACCGACTTT Bmp8b 8892 n TTTATGCAATGTTAAGTGAG Skintll 1253 GGTGTCCATGCAGGTGGGCG Slc36a2 5073 TCGTCAGAGCCTGAGTTCCC Bpntl 8893 o CACGGCGTCrrGGGTGGTCC Slc25a53 1254 GTGAGCACTGGCGCCGCGGG Zfp746 5074 CGGTGATTCTCCTCAGCGCT Lrba 8894 GAGGCAGTGGAGGGTTATCC P l 1255 CATTACAGAGAGTTGGAACT Dab2ip 5075 GGCGGAGTTTAGGGAAGCAG Urgcp 8895 b CTCGTCCCGGTTACTAGCAC Wtl 1256 GGAAGGAACGGGAGAACTAG Grhl3 5076 GCGAGGACTGCGCGCTACCC Eif4enifl 8896 GAGATCAGGAAATTCTGCGT Plaa 1257 ATTGCTCAGGTTATGACACC Histlhlt 5077 GGGACCCGGGCGGCGTGGGC Slc4a4 8897 J GGCTTAGTGGCTAGGGTTGG Cnga3 1258 TAGAGTGCGTGATTTCATAG Gimapl 5078 TTTAGGGTGGAGATAGAACT Trim27 8898 GGGTCAGAGGTCCGGGTGGC Nap 114 1259 CAATAAACATGTTGGCCCrG Ly6c2 5079 AAGACCCGACATTCCTCTTC Esrrg 8899 GGGTCTGTTTACTCCTATAA Tcf7 1260 GGCCTGTTCGGAGGGAGTGG Osbp2 5080 AGACAGAATTCGAGGGCACG Ptchd4 8900 AGAAAGTACTTGGAGGAAGA Serinc2 1261 GGGFCCGGAACCGGTTTGGG Spagl7 5081 GACTCTTCCAGAGCTGCTGA Havcrl 8901 o GTGTGATCTGTTGGTGAGCC Kir3dll 1262 GCAGAGCAGCTTCTCCTAFG Foxp2 5082 ATCACGTGATCCATAGTGGG Dhx3 8902 GCAGCTAGAAGCAAAGCCTC Zkscan7 1263 TTACGTCAGTGTGCTGTTTC Pet2 5083 TTGATCCTGGAAGGCAATCC Rab42 8903 CGCAAATAGAAGGACACGGA Htrld 1264 GACAGAGCTAGTCCATCACC Fhadl 5084 CGTCAGAGGAAATAGAGGCG Sla2 8904 5 b AAGAACCAAGTATTCAGCCA Catsper4 1265 ACCTGAGCCATGCCAAGGAA Skint9 5085 GGATACTCTCCGCTGATCCA Phykpl 8905 o CCCAGAGTCCCAGAGCCATT Calr4 1266 GGCGGAGTTTAGGGAAGCAG Urgcp 5086 CCCGTTTGGCCAATGACAAT Ascl2 8906 4 TGAGAGAGAGAGAGAGAGAG Foxp2 1267 CTCTTGACTATACATAACAG Nxf2 5087 AAGTCAGAGCCTGGAAGGAT Kcnsl 8907 G4 AGAACCATCTGTGGCTCCTG Ccdc69 1268 GCGAGGACTGCGCGCTACCC Eif4enifl 5088 TGCGCCCAGAGGCGCTACGG Wac 8908 ATTTCTTCTTTGGTTCTTTG Nf2 1269 AGArACTAGCATTTAGCATG Ti l l 5089 GAGGCAGTCTCCAGGGAAGT Slc36al 8909 AGTCCTGGGCTGGCCTTATC Lcat 1270 TTTAGGGTGGAGATAGAACT Tiim27 5090 GATGAGGCAGCCCGTCCACT Lat 8910 CGCGCAGGAAGCACTGCTCC Zcchd 1271 GGCCFCTCTTTCCATAGACC Lrrn4 5091 AGGAATCGGTTGGCGGG C Meal 8911 TTTATGGAGCGCCCTTGTCG Npy 1272 AAGACCCGACATTCCTCTTC Esrrg 5092 ATCTGGTTCTGTTACTCTGC Fgfr2 8912 AATCACGCTCATCGACCTAT Ush2a 1273 GACTCTTCCAGAGCTGCTGA Havcrl 5093 TGGGCTCAGATAAGGAGGCG Cyplal 8913 TGGGCGGGTTCAAGGCTGCG Col 1lal 1274 ATCACGTGATCCATAGTGGG Dhx35 5094 GAGGCAGTGGAGGGTTATCC Polm 8914 CCGCGAGCTGCCGCGAACTC Elmo 1 1275 TTGATCCTGGAAGGCAATCC Rab42 5095 AGAGCTGTCCAGAAATACGC Pcdhgal 8915 CGGACCTGTGGACCGGATCA Tubgcp2 1276 CGTCAGAGGAAATAGAGGCG Sla2 5096 ATTGCCAACCACAGCTCATC Fbxw26 8916 CTGATACAGTCTGGTAGATA K d2 1277 CAATCGCCGCGCCGGCCAGA Sfrpl 5097 CTGGGTTTCTCTCTGAGTTA Scn3b 8917 GGAGGCAGACATAGTCACCG Tgifl 1278 GGAFACTCTCCGCTGATCCA Phykpl 5098 GAGATCAGGAAATTCTGCGT Plaa 8918 TCTCTTCCTGCCAGCACTGC Myom3 1279 TGAC CGTCTTGTTCTATTT Pdzphl 5099 GGCTTAGTGGCTAGGGTTGG Cnga3 8919 CCCACACCTGCCGGGATGTC Helt 1280 CCCGFTTGGCCAATGACAAF Ascl2 5100 AGATAGGCAAGAAGCCATAC Cyplal 8920 TAGGTAACAACATAATCATC Phc2 1281 CTGGAGAGGGAGTAACCCGT Gccl 5101 GGGTCAGAGGTCCGGGTGGC Napll4 8921 CGCACAGGGTTAAGCGGCAG Cttnbp2 1282 AGTGGACCGGAATGCCTGTC Mroh2b 5102 GGGTCTGTTTACTCCTATAA Tcf7 8922 CTCAATTGGTCCCGCCTGTC Mapk9 1283 TGCGCCCAGAGGCGCTACGG Wac 5103 GCTGTACAACTGGTGCCAAG H2-M10 4 8923 GCCAGGCCTTATCTAGAGGA Ppplrl6b 1284 GGAFGACCGCGACCGCGCGC Lpin2 5104 AGAAAGTACTTGGAGGAAGA Serinc2 8924 TTTGTGTTTCTTCCAGATAC Chrm5 1285 GGTCAGCTCACAATGATGAA Fam71fl 5105 GCAGCTAGAAGCAAAGCCTC Zkscan7 8925 GGCGGGAACTGGTCGGAGAA Zfp5 1 1286 ACCTCCAGGGCTAGCCAATG Zfp956 5106 CAATTAA CGCTAGGATTCAT Sec23ip 8926 GAGGAGGGCCGCGACGAGCC Ptgfm 1287 GAGGCAGTCTCCAGGGAAGT Slc36al 5107 CGCAAATAGAAGGACACGGA Htrld 8927 GGCTTGTGTCACCGTCGCCC Gpx3 1288 AAGCCAAGAACTAGGAGGAG Paxl 5108 AAGAACCAAGTATTCAGCCA Catsper4 8928 CTTGCAAGGACCACGAGGAG Sgipl 1289 TTGCATCACAAAGCGTTGCC Cst8 5109 TGAGAGAGAGAGAGAGAGAG Foxp2 8929 TCTGAGAGGCTCGTCTCCTC Tbcel 1290 TTTAT GCAATGTTAAGTGAG Skint 11 5110 AGAACCATCTGTGGCTCCTG Ccdc69 8930 TAAAGTCCCGGCGCTGCCCG Glcci 1 1291 CACGGCGTCTTGGGTGGTCC Slc25a53 5111 CCCTATCAGCTTGTGTGCAA Map9 8931 ACAGAACACAACCAACCCAA Phc2 1292 GAGGCAGTGGAGGGTTATCC Polm 5112 ATTTCTTCTTTGGTTCTTTG Nf2 8932 GTCGTGTCGTGTCGCGGCGC Morc2a 1293 ACCTGGCAGGTTTGCGTGCC Poflb 5113 CTGGAGTAAGGCAGTGGGCA Bdnf 8933 CCAGCGGACTTTGGATCTGG Fgr 1294 GAGATCAGGAAATTCTGCGT Plaa 5114 AACTGCTGCCCTCACCCAGC S100al6 8934 GAAGGGTCTFCFGCCACCGA Kctd3 1295 GGCTTAGrGGCTAGGGTTGG Cnga3 5115 AATCACGCTCATCGACCTAT Ush2a 8935 CTGGCCGCTCrCCCAGTGCC Mllt3 1296 GGGTGGCAGAGCAGATCCCG Chll 5116 CAACCCGTGTAGCTCTTGAC Gatb 8936 AAATGCGGCTGCCGCTTGTT Ublcp l 1297 GGGTCAGAGGTCCGGGTGGC Nap 114 5117 GTGTGGGCGTCTCTTCGCCG Fhdcl 8937 n ACTAGGCAGACAGGTGACTA Dctd 1298 GGGTCTGTTTACTCCTATAA Tcf7 5118 CCGCGAGCTGCCGCGAACTC Elmol 8938 GCCGAGCGGGCTTGGCGGTG Slc35dl 1299 GGAGGCAGGCCGTGTGAAAG Seel 5119 CGGACCTGTGGACCGGATCA Tubgcp2 8939 CTAAGCTTTACAGCTCTGTG Cdkn2c 1300 AGAAAGTACTTGGAGGAAGA Serinc2 5120 GTGAGGTGCGCGAGGCATGC Btf314 8940 n TCAGCTGGCAACCATGAGAA Leap2 1301 GTGTGATCTGTTGGTGAGCC Kir3dll 5121 TCTCTTCCTGCCAGCACTGC M om3 8941 o AACTCGTGACAACCCGTCGG Rmnd5b 1302 GCAGCTAGAAGCAAAGCCTC Zkscan7 5122 CGAGCCTTATGCCCTGGAGA Lama5 8942 5 CGAGGAGTTACAGCTGGAGC Dpysl3 1303 CGCAAATAGAAGGACACGGA Htrld 5123 GAATTCTATTAGGCACACTC Bdnf 8943 TTCTTCTAGGCAGACAAACG Rplll 1304 AAGAACCAAGTATTCAGCCA Catsper4 5124 TAGGTAACAACATAATCATC Phc2 8944 5© CATTTCCACTTGGCCTGTGA Ifi47 1305 CCCAGAGTCCCAGAGCCATT Calr4 5125 AGCTCGCAGACTATGAGCTG Hgf 8945 J AATAGGATATCACCTCACTC Mud 5 1306 TGAGAGAGAGAGAGAGAGAG Foxp2 5126 GTATCTGACAGGAACCTGAG Mpl 8946 ACTTTCCTTCCCTACCTAAA Smarca2 1 07 AGAACCATCTGTGGCTCCTG Ccdc69 5127 GGGCCCGCCGACT GAAAG Tcergl 8947 GGAGAAGCACCAGATGCAAG Myo 2 1308 ATTTCTTCTTTGGTTCTTTG Nf2 5128 TGCCAAACTCCTCAGGTCTG Zfp938 8948 TGGGCGGGCGTGCGCGTTGA Mapk8 1309 TTTATGGAGCGCCCTTGTCG Npy 5129 CTCAATTGGTCCCGCCTGTC Mapk9 8949 o TATGTACACATrGCCTCCTC 4930595M18Rik 1310 AATCA CGCTCATCGACCTAT Ush2a 5130 GGCGGGAACTGGTCG AGAA Zfp511 8950 AGCAGGGAGGTAAGCTAATT Impg2 1311 TGGGCGGGTTCAAGGCTGCG Colllal 5131 AGCTTCGGACACGTGACTCG Rab3gap2 895 1 GTGAAGTCTGACCTCACAGG Saxol 1312 AGTCCAAGTGCTGCGGCGAG Cenpe 5132 CTATGATCGGCAGCGGGATG Hspa8 8952 TGGAAGGAGGATGTTCTCAA Gm9758 1313 GGAAGAACACTATATTAGTC Agrp 5133 GGCTTGTGTCACCGTCGCCC Gpx3 8953 o TGGTCTGGAAGACTTCTGAG Fat4 1314 CCCTGCAGGGCGCACCCAAC Foxd2 5134 GGGCACAGCTGTAACAATGG 1700001C19Rik 8954 4 AGACTTCCTAAAGCGAAGGA Sycp3 1315 CCGCGAGCTGCCGCGAACTC Elmol 5135 CCCGATAGGTAGACCCTCCC Spal7 8955 GGGTGGACCCGTGACCTGAG Echsl 13 16 CGGACCTGTGGACCGGATCA Tubgcp2 5136 AAGTGGAATCCCAAAGAGCA Snapc5 8956 GAAAGGAAACTGTGTTTAAA Sis 13 17 GGAGGCAGACATAGTCACCG Tgifl 5137 CTTGCAAGGACCACGAGG AG Sgipl 8957 TCCGCGTGGGCCGGATGGCG Eif4enifl 1318 TCTCTTCCTGCCAGCACTGC Myom3 5138 TCTGAGAGGCTCGTCTCCTC Tbcel 8958 AGTCCTGCGAAGAGTTTGTC Desi2 1319 CCCACACCTGCCGGGATGTC Helt 5139 TAAAGTCCCGGCGCrGCCCG Glccil 8959 GGGTTTAAACTCACCTCCTC Hmgn2 1320 TAGGTAACAACATAATCATC Phc2 5140 ACAGAACACAACCAACCCAA Phc2 8960 CTAGCTAGCGAGCATCCTCT Viprl 1321 AGCTCGCAGACTATGAGCTG Hgf 5141 GTCGTGTCGTGTCGCGGCGC Morc2a 8961 TGCAGCTATAAATATCAGAG Trim63 1322 CGCCTTATCTCTACGGCCAT Cyp2rl 5142 CCAGCGGACTTTGGATCTGG Fgr 8962 GAACAGATACTATCGGCAAA Havcrl 1323 CGCACAGGGTTAAGCGGCAG Cttnbp2 5143 GAAGGGTCTTCTGCCACCGA Kctd3 8963 GCCATTATCAGAACCAAGCG Ascc3 1324 GAACTCTGACTCCCAGAGCC Adamtsl9 5144 CTGGCCGCTCTCCCAGTGCC Mllt3 8964 AGCTTCCTTTCTCACATCTC Pet2 1325 CTCAATTGGTCCCGCCTGTC Mapk9 5145 GTGTGAGTCACGGGCGTGAG Ddrl 8965 AGCTGAGAGGCAGGTCAGTC Mucl5 1326 GGCGCGTCGTGCGCAGAGCG 2610020H08Rik 5146 TTTCTGGCTGCAGTGAGTGG Fbxw26 8966 CAGCAATCCTGACTCAGCAG Hfe 1327 GGCGGGAACTGGTCGGAGAA Zfp511 5147 GCTCAGCCCTCGGAAGCCCT Bdnf 8967 ATTGCCAACCArAGTTCATC Fbxw24 1328 ACACATCCACACTCCTCGCC Glis3 5148 GTGTCCTTCAGTGGGTAAAG Map4kl 8968 CAAACCAGGTG GCACATCGC Zfp746 1329 GGGAGCAGGCACGAGCTTTA Rapgef3 5149 TCAGCTGGCAACCA GAGAA Leap2 8969 CGGAGGTTGCGTGGTGCAGG Cull 1330 GAGGAGGGCCGCGACGAGCC Ptgfm 5150 CGAGGAGTTACAGCTGGA GC Dpysl3 8970 TGTTTCCGATTGGGCAGAAT Ak2 1331 GGCTTGTGTCACCGTCGCCC Gpx3 5151 TTCTTCTAGGCAGACAAACG Rplll 8971 GGGACACAGCGCGGCACGAT Tcergll 1332 CTTGCAAGGACCACGAGGAG Sgipl 5152 CTTGTCGCCGAATCTGGGAG Nprl 8972 GTGTGCACGTTCGAGCTTTC Maf 1333 TAAAGTCCCGGCGCTGCCCG Glccil 5153 CATTTCCACTTGGCCTGTGA Ifi47 8973 CGCGGCTGACTGACGCGGTG Sfipl 1334 ACAGAACACAACCAACCCAA Phc2 5154 GCTGGACGGCCATrrATAAG Ubl7 8974 TCTGACTCTGGAGTGCTTTA Skint5 1335 GTCGTGTCGTGTCGCGGCGC Morc2a 5155 GAACAAAGGACTGGAGTTGG Cyp21al 8975 GACTGAGGTGGAGGCCTGGG Sugct 1336 CCAGCGGACTTTGGATCTGG Fgr 5156 GTGAAGTCTGACCTCACAGG Saxol 8976 CACGTGTCATGTTCCATATT Vmnlrl91 1337 TTACCCAAATGTTTG AAAGA Pzp 5157 TGTGCGCATGAGATTAGAGG P3hl 8977 GGTCACTGTCCTACACAAAT Slcolb2 1338 GAAGGGTCTTCTGCCACCGA Kctd3 5158 AATTAGACTTGTCATACAGG Dt a 8978 GAAGCGTGCGAGTACTTATG Adprhl2 1339 TGGCGGCTCTGACTTTGCTC C130060K24Rik 5159 GGGTGGACCCGTGACCTGAG Echsl 8979 AGGCATGTCTCCACCAAATA Neb 1340 CGACATGGCTCCGAACTGCG Trim45 5160 CGGGTTGTGCGTCTCTCTCC Celf3 8980 GCAGTTGGGAAACTTGATAT Bpifal 1341 CTGGCCGCTCTCCCAGTGCC MUt3 5161 TCCGCGTGGGCCGGATGGCG Eif4enifl 8981 ATGCAGATGAGGCGGGCGCG Wwc2 1342 AAATGCGGCTGCCGCTTGTT Ublcpl 5162 GGGTTTAAACTCACCTCCTC Hmgn2 8982 TGGCAACCGTGGCGCAGCTT Tm2dl 1343 ACTAGGCAGACAGGTGACTA Dctd 5163 TGCAGCTATAAATATCAGAG Trim63 8983 AGCAAATCTCATTGGTAAAG Lpin2 1344 GCCGAGCGGGCTTGGCGGTG Slc35dl 5164 GAACAGATACTATCGGCAAA Havcrl 8984 CGTGACCGCCGATCCCTCTG Hmgcl 1345 CTAAGCTTTACAGCTCTGTG Cdkn2c 5165 GGAAGTGACTACAGAGTCTA Spirel 8985 n GGGAGGGCGCAGATCACCCG Ί χ15 1346 TCAGCTGGCAACCATGAGAA Leap2 5166 TTTCTAATAACTTCCTCCAA MrpslO 8986 TCAGTCACAGAAGACTGAGA Slc5a9 1347 ACCCAAGCGGGAGGCTTTGT Pah 5167 TGTGTGCCTGCCTGGCAATC Gml2888 8987 GCTGGGCATGTTAACCCACA Skint5 1348 AACTCGTGACAACCCGTCGG Rnmd5b 5168 CTAAGGCATGAGGGCCAGGC Robo4 8988 n GGCTTCTCTGGGATTACGTT Wdr63 1349 CGAGGAGTTACAGCTGGAGC Dpysl3 5169 AGCACAGTGCACACCTGCTA Serpini2 8989 o ATGGTGGGATTGGGCTTCTG Leprot 1350 TTCTTCTAGGCAGACAAACG Rplll 5170 GGGAGCAGCCGCGGCCCACG Arihl 8990 GGCCCTAGGCTTGCCCTGGG Primpol 1351 CATTTCCACTTGGCCTGTGA Ifi47 5171 CGCAACTCTTCACTGCGGTA Sorll 8991 b GGTGATCGCGACCGGTGCCG Eif4enifl 1352 ATTCCAGCAGAGTCTGTACC Sema4a 5172 CAGCAATCCTGACTCAGCAG Hfe 8992 CGGTTAGAArrCATTCCTCC Efcab3 1353 TTCTACACGGCAGGGCACGT Tbrg4 5173 GGATGGCCTACAACTCCCAT Fycol 8993 J CTCTACAAAGGCTTGTGTTA Morc2a 1354 ACTTTCCTTCCCTACCTAAA Smarca2 5174 GACTTGGTGACATATTGTTC Itgax 8994 CCATGGAATCGAAAGGGTCT Aplbl 1355 TATGTACACATTGCCTCCTC 4930595M18Rik 5175 TGTTTCCGATTGGGCAGAAT Ak2 8995 GGGAGAGCTACGCACAAGCG AU040320 1356 TCCTCCGACAGGCACAGTCC Fastkd3 5176 CCCAGGCGCGCTCGGCCGAG Taf4 8996 ATGCTGGGCTGGTATAGACT Tspyl3 1357 GTGAAGTCTGACCTCACAGG Sasol 5177 TTCCTCAGAGGCTGCCAGTG Muc5ac 8997 o TTCCACCAACACTGCATTCG Calr4 1358 TGGAAGGAGGATGTTCTCAA Gm9758 5178 GGGACACAGCGCGGCACGAT Tcergll 8998 CTCGAGACGGCGGCGCGCCT Hmgn2 1359 AAAGGGCCAGTATCCCAATC Dab2ip 5179 CCCGTCTTGCCAATTTATGT MrpslO 8999 GGGTGGACGGTCAGCGGAGG Epsl5 1360 GGGTGGACCCGTGACCTGAG Echsl 5180 GACTGAGGTGGAGGCCTGGG Sugct 9000 5 CGGGTCCGATTGTGATTGGA Pefl 1361 GAAAGGAAACTGTGTTTAAA Sis 5181 CACGTGTCATGTTCCATATT Vmnlrl91 9001 o GGATCAGCCCAGATAGGGCG Acsll 1362 TCCGCGTGGGCCGGATGGCG Eif4enifl 5182 GGTGGTAACAAGCCTTCCTG Trim3 1 9002 4 TGCAGGACAGCATACACCCG Cm2 1363 GGGTTTAAACTCACCTCCTC Hmgn2 5183 CCTAGTCTTCCAAGACTCCA Paivg 9003 G4 GGTCGCTCGGGCCAACTTCC Drgl 1364 CTAGCTAGCGAGCATCCTCr Viprl 5184 GAAGCGTGCGAGTACTTATG Adprhl2 9004 GAGATCGGGTCTAGCTCTGT Rad50 1365 TGCAGCTATAAATATCAGAG Tiim63 5185 GCAGTTGGGAAACTTGATAT Bpifal 9005 GCCGGACACTACGGAGCAAG Spata6 1366 GAACAGATACTATCGGCAAA Havcrl 5186 AGCGGCAGGCATGGTGGACC Stomll 9006 TTTCAGAACGCGCCTGGCCC Zfp354c 1367 AGCTTCCTTTCTCACATCTC Pet2 5187 TTGCACACTGGGTTGCTAGC Dmapl 9007 AAGGCGGGATGCAAAGCACT Gab l 1368 CGCAACTCTTCACTGCGGTA Sorll 5188 TTCACCGGGAGCTCTGACCC Dsc2 9008 TATGGCAGATCGCAGAAGAA Rin2 1369 CAGCAATCCTGACTCAGCAG Hfe 5189 CACAGAACTAGGGACAGATC Heyl 9009 GCTGAATCTTTGTACTATAC Prr27 1370 CTAGGCCGGCCTCTCCTGCG Alg5 5190 AATGAGGGAGGGATGGAAGC Bdnf 9010 TGGCTTCTTCGTACGGCCAT Calu 1371 CAAACCAGGTGGCACATCGC Zfp746 5191 TTATCCCACCAATCGGTCTC Laol 9011 AGGCTGATAGGACCTATCTG Cstl3 1372 CGGAGGTTGCGTGGTGCAGG Cull 5192 TCGTGCGTCATCGCGAGGCG Hspa8 9012 CTGTGTGCCGGCCGCCACCG Pwwp2b 1373 GTACAGAAACACAGATGATG Ube2h 5193 GGCTTCTCTGGGATTACGTT Wdib3 9013 ATGGATGATTGGGCTAAACT Myl7 1374 TGTTTCCGATTGGGCAGAA Ak2 5194 ATGGTGGGATTGGGCTTCTG Leprot 9014 GGAGCAGGAGCACCTGCTGG Aplbl 1375 GGTCTCGCTGGGAGGTGCAT Mpp7 5195 GGTGATCGCGACCGGTGCCG Eif4enifl 9015 GGAGGCGTGCGCTTCGCAAA Rasef 1376 GGGACACAGCGCGGCACGAT Tcergll 5196 CTCTACAAAGGCTTGTGTTA Morc2a 9016 TGACGTCAGTGCCACCTCCT Kctd 1377 TCTCCTCCTCCGGTCTCGAG Gtf2hl 5197 CCATGGAATCGAAAGGGTCT Aplbl 9017 GGAATGTGCrTAATTCATTC Npvf 1378 CGCGGCTGACTGACGCGGTG Sfrpl 5198 GGGAGAGCTACGCACAAGCG AU040320 9018 CAAGGGAATCGCTGGCTCTC Fam46b 1379 TCTGACTCTGGAGTGCTTTA Skint5 5199 ATGCTGGGCTGGTATAGACT Tspyl3 9019 CCTCCGCTCCTTGGCTCACG Potla 1380 GACTGAGGTGGAGGCCTGGG Sugct 5200 CTCGAGACGGCGGCGCGCCT Hmgn2 9020 GTCACCAAACCGGTGGCCGG Gpr3 1381 CACGTGTCATGTTCCATATT Vmnlrl91 5201 CGGGTCCGATTGTGATTGGA Pefl 9021 GGATGTACGTGCAAAGATAT Caly 1382 CTTGCGATTTGCTGCCTACG Thgll 5202 TGCAGGACAGCATACACCCG Cm2 9022 GCCGCTGTCGTGAGGCATGC Ccdcll7 1383 GAAGCGTGCGAGTACTTATG Adprhl2 5203 GGTCGCTCGGGCCAACTTCC Drgl 9023 CGGATTCCGTGACGCCAGCC Osbpl3 1384 GCAGrTGGGAAACTTGATAT Bpifal 5204 CGCGTGCGCACAGGACGGGA 2300009A05Rik 9024 TGTTAAGTGCCGTGGCAGTA Gjb3 1385 ATGCAGATGAGGCGGGCGCG Wwc2 5205 GAGATCGGGTCTAGCTCTGT Rad50 9025 CCAGTGCGGCGCGCCCAATC Rpe 1386 TGGCAACCGTGGCGCAGCTT Tm2dl 5206 TGGCTTCTTGTCTGGCTAGC Scn3b 9026 GAAGCTGTCAGAGCATTTGA Clqtnf2 1387 AGCAAATCTCATTGGTAAAG Lpin2 5207 GGTGGCTGGAGGGACAGCAG Adaml9 9027 ACTCTCGCGACGCTTGCGTC Nktr 1388 CGTGACCGCCGATCCCTCTG Hmgcl 5208 TTTCAGAACGCGCCTGGCCC Zfp354c 9028 AGTGTCCATTGGTCAATTGT Cep85 1389 GGGAGGGCGCAGATCACCCG Tbxl5 5209 AAGGCGGGATGCAAAGCACT Gabral 9029 GGAGGAAGTGCTGGTGCCCG Xrn2 1390 TCAGTCACAGAAGACTGAGA Slc5a9 5210 TTGAGGACATCAGCCTCGCG 1700056E22Rik 9030 CGTTGGGTCGGTTTGTCCTC Tra2a 1391 GCTGGGCATGTTAACCCACA Skint5 5211 GGACTGCGGACACGATCACA Ulk3 903 1 AGAGAAGCTTCTGAGTAAAC Ttil 1392 ATGGTGGGATTGGGCTTCrG Leprot 5212 CTGTGTGCCGGCCGCCACCG Pwwp2b 9032 TGACAGGTArGGGTCAGACC Sk t4 1393 GGAGGGAGGGAGGTGCAAAG Col6al 5213 ATGGATGATTGGGCTAAACT Myl7 9033 n GTACATCTGCCGCACCTACC Insml 1394 GTAAGTACATGCATTAACAT Vmnlrl95 5214 GGAGCAGGAGCACCTGCTGG Aplbl 9034 GCCCGGAGCGGACCCTATGC Ahdcl 1395 GGCCCTAGGCTTGCCCTGGG Primpol 5215 CAGGAAGCTGTCAAGTGGCC Selenbp2 9035 CTCCATCAAGATGGTATAAA Collal 1396 GGTGArCGCGACCGGTGCCG Eif4enifl 5216 TTAATGTGAGTTGTCTGAAT Adgral 9036 n 4 ATCATGCCATTGTGCTTTCA Tbs22 1397 CTCTACAAAGGCTTGTGTTA Morc2a 5217 CAAGGGAATCGCTGGCTCTC Fam46b 9037 TCCATCAGGAGTAGATGATC Tmeml76b 1398 CCATGGAATCGAAAGGGTCT Aplbl 5218 CACTCTGGAGTCCGCAGAGT Rab38 9038 5 GGCTGACCrTGAGTCAAAGC Tbx22 1399 GGGAGAGCTACGCACAAGCG AU040320 5219 GGCTGCTGCGAACTCTCTTC Tbx3 9039 AAGGGCAGGCAACACTTAAA Etippl 1400 ATGCTGGGCTGGTATAGACT Tspyl3 5220 GTCACCAAACCGGTGGCCGG Gpr3 9040 CCCGGCGGAGCAGCCGACTC Ptgfm 1401 TTCCACCAACACTGCATTCG Calr4 5221 GGATGTACGTGCAAAGATAT Caly 9041 CTGAAAGAGAGATAAAGCTG Gcm2 1402 CTCGAGACGGCGGCGCGCCT Hmgn2 5222 TAGGTGTGTTTGACTGATTG Dmbtl 9042

ATCTTGTATCCATAGTGCCA Clip4 1451 CTGAAAGAGAGATAAAGCTG Gcm2 5271 TCAAGACCAGCTGCTCTTCT Celf3 9091 CCCGCAGGCTCACCTGGCTG Coll6al 1452 CCCGCCACTCAGTGTGTGGC Ttl 5272 CTGAGACCACCACAGAGCTA Slc36al 9092 TTTGCATGACAGAAACACAT Col3al 1453 AGGTCTTAGAACTGGCAGGT Prapl 527 CATTTACTCATTCCGTCACC Bpifbl 9093 AATGGTCArrAATAATGCAG Htrld 1454 ACGGCTrCCGGGTTGGCGGG Emidl 5274 CAATCTCAGGTTAACGTGTA Hrnr 9094 TGAGGGrrTGCACCAATCCG Clspn 1455 CCCGCGCTCGCTCGACCCAC Adcy8 5275 AGCCTTTCCGCGTGGAGCTC Nfyb 9095 GGAATTGTAGTCCGGGCCAG Stmnl 1456 TTCTTCGAATTCGTTCTTCG Osm 5276 CGGAGCAAGGATAAACACCG Spire 1 9096 TTCTTACCGGGCTAGCTGGG Lrrc63 1457 TGTGCTCCAATCAGATACTA Wdrl7 5277 ACAAGCAGGTGTTTGATTCC Zfp354a 9097 CAATGCTCCGCrCGAGGGCG Sh3d21 1458 GTACATCACAGTAGCCGATG Pet2 5278 CGCTGCCGTTCATTGGCTCC SrsflO 9098 TACTCTTAGTGCCGCAGCCG Wbscrl7 1459 CTAGTTCTTAGGCAGATGGA Phfl4 5279 CCCGCAGGCTCACCTGGCTG Coll6al 9099 GCGTGGCGAGGGAGAGGGCG Mips24 1460 CGGCTTCCCTGCTTCTTACC Sema4a 5280 AATGGTCATTAATAATGCAG Htrld 9100 TTTCTGCTGCTGCGCGACCC Ptprzl 1461 CCGAAACGCCGGCTTCTCTT Rnfl45 5281 GGGCGTCCCGGTTTGCTCGT Rab28 9101 GGGCCGGAACGCACCGCCAT Cull 1462 GTGGTGGGAACAAAGGGAGG Fbliml 5282 TGAGGGTTTGCACCAATCCG Clspn 9102 GATGATrCAGGAAGCTGCCT Tinagll 1463 GGACAAGAACACAAACGCAC Ube2h 5283 GGAATTGTAGTCCGGGCCAG Stmnl 9103 GGCCCTCTGGTGGTAGCACC Mpp6 1464 TGCCGGAGCCAAGGAGCTTG Cedcl37 5284 ACTTGGTGTAATGCTATCCG Bdnf 9104 GTGGCCGAGGCGGAGCGCCC Ptprt 1465 GGGTTTCCGAATCCGGGTCT Histlh4c 5285 CAATGCTCCGCTCGAGGGCG Sh3d21 9105 TGGTCTATCCTGGGTGTGGG Frk 1466 TCAGGGCTGGGTCTGTGTTG Zfp511 5286 GCGTGGCGAGGGAGAGGGCG Mrps24 9106 TCTGTTGGCGTCCTTCCTGT Zfp369 1467 CCCTCCATCATCAACGCGGG Mgatl 5287 GATGATTCAGGAAGCTGCCT Tinagll 9107 CGTAGCTTCTGCTATGTGGC D7Ertd443e 1468 CCGGCCTGACGCGCGCACCG SrsflO 5288 GTGGCCGAGGCGGAGCGCCC Ptprt 9108 GGCAGGGCTCTCTTCAACCT Cd b 1469 AAGCCACAGCTACCTCACAA Slc36a3 5289 ACCGGATACGCTCCAGAACT PpplrlS 9109 GTGTGCTTGAAATGGCTTTG Gprl41 1470 AGGCGTGACTTCGACTTCTC Fgr 5290 AATGGTTCTTCCCAGCCCGG Adgral 9110 GAGGTTCACGTGATCATTGC Nxf2 1471 TCCTTCCCGGTCACGTGCGC Clqtnf2 5291 TCTGTTGGCGTCCTTCCTGT Zfp369 9111 GCGCAGACCTGACCACCAAT 9030624G23Rik 1472 GCGGCCGTTGCCCTGGCGAG Zf 0 5292 GGGAGTGCGCTTGCGCACAG 2310061I04Rik 9112 GCTCCATTTATAGGAGGAGC Apob 1473 GAATGAAATGTAAATGGGCC Z ch l 5293 TAGTAATCGAGAATCTAACA Senp8 9113 CAGGGCGTGTCCTGAAACCC Cyp2abl 1474 GGAGCATCCGCGCGCGAGCC Cntn5 5294 CGTAGCTTCTGCTATGTGGC D7Ertd443e 9114 CGTGATAGCCCAGCTGCCTG Plin2 1475 CCCATGCCTGCACCAATGGG Dctd 5295 GTGTGCTTGAAATGGCTTTG Gprl41 9115 CAAGACCTCCAGCTCAAGGG Gm609 1476 TCTTGAACAGCTGCGGGCGC Mall 5296 CTAGTACTGTTCAACTTGTG Cub 9116 TCAATGGGCACCGATGGGCG Nude 1477 ACGGTTCACCGGAGCGGCCG Ak4 5297 GAGTATGACGATGTCATTCC S100a7a 9117 AGCTGTCTGGAGAATCTAAC Fermtl 1478 GAGCTAAGGAGGAAAGGTGC AU040320 5298 GCTCCATTTATAGGAGGAGC Apob 9118 AAATTCTCCTAGTGAGAATG Tpte 1479 CGGCCTGAGCTTGCGCTAGG Peed la 5299 CGTGATAGCCCAGCTGCCTG Plin2 9119 GATCCCGTAGCTAGAGAACG Ldlrapl 1480 TTGGTGCTGGCTGCGGGTTT Plxdc2 5300 TGAGGCAAAGGTCATTCTCG Uckll 9120 TGATTGGCGGAGCGCGATGC Tmeff2 1481 GGAAATGGGCGGGCCACAGC Clic4 5301 TCAATGGGCACCGATGGGCG Nude 9121 GTCGCCGAGCCGGGTTGCTA Kif3b 1482 AAACAACAGAATTCTTGGTG Lrrn4 5302 CACCCGTCACCATAGCAACG Iqch 9122 AAATCCCGCGATTTGTACCG Stk35 1483 CTGACGCGCGGGCTGACGTG Aff4 5303 GATCCCGTAGCTAGAGAACG Ldlrapl 9123 AATGACTGTTTAATTTGGGT Ctrc 1484 CGGTGTCGGCGGAACAGGTG Nitl 5304 AACCACACCCAACTTGGGAG Uspl71b 9124 CAGAAGTGCTCTGCAGCGCC Ubr3 1485 CACTCTCCTAATCTTTGTCT Snx25 5305 GTGTTGAAAGCATACTCAGC Slcl0a2 9125 ACACTATCCCAGAGTCTCCC Vmnlrl88 1486 CTGAGACCACCACAGAGCTA Slc36al 5306 GTCGCCGAGCCGGGTTGCTA Kif3b 9126 CCTGTACGTTTACATGTGCC Kcnd2 1487 CATTTACTCATTCCGTCACC Bpifbl 5307 GAGCAGTTCTTCCAGCCAAT Hnmpll 9127 CACTAGTTACAACTCCTGCA Sfil 1488 GGTGGCGGTGGCTGCCGCAA Slc35dl 5308 AGGGAATTTATGCAACCAAT Selenbpl 9128 TCCATCGTGACCTTTAAAGG Bpifb9b 1489 TTCTGAAAGACGTGAAATAA Gpm6a 5309 CAGAAGTGCTCTGCAGCGCC Ubr3 9129 GAGCAATACAGCAGGAGTCG Nme8 1490 ACAAGCAGGTGTTTGATTCC Zfp354a 5310 ACACTATCCCAGAGTCTCCC Vmnlrl88 9130 TTTGGGCTCATGAAAGGTTT Opnlsw 1491 CGCTGCCGTTCATTGGCTCC SrsflO 5 CACTAGTTACAACTCCTGCA Sfil 9131 GAGTGATGGCAAGGAAGCCC 1700024P16Rik 1492 ATCTTGTATCCATAGTGCCA Clip4 5312 GATCACCGAGTATCACGAAA Rpap2 9132 CCTGAATGTATGAATCCCAC Ha cr l 1493 CCCGCAGGCTCACCTGGCTG Coll 6a 1 5313 CTAACTCGCGGCGCCGAGTG Fancc 9133 GCTCGTATATCCAACCTCAG Hpca 1494 AATGGTCATTAATAATGCAG Htrld 5314 GAGCAATACAGCAGGAGTCG Nme8 9134 TCAGGACAGACAGTTAGGCA Myolg 1495 TGATATATGGGCGGTTTGGA Stl8 5315 GGGCAGCACGAGATGCGCGC Abcc5 9135 GACCCTAATTCAGTAGATCT Prokr2 1496 ACTCTAAAGCTGTCTTCACT Adgb 5316 CCTGAATGTATGAATCCCAC Havcrl 9136 TGAACAAGCACATCCG CCCG Hacd4 1497 CTGCCTGGGTCTTAGAGATC Gimapl 5317 ATCGCTCTCCGCAGACCAGT Pik3r3 9137 AGAGGCTTGTCTACATGCCT Elavl4 1498 TGAGGGTTTGCACCAATCCG Clspn 5318 GCTCGTATATCCAACCTCAG Hpca 9138 GGTGCTCTTGAGTGCTGGCT Doxl2 1499 TGACGTAGGGATCACGTGAC Ubap2 5319 TCAGGACAGACAGTTAGGCA Myolg 9139 GCCACAGTrAGAGGAGGTTG Sntal 1500 GGAATrGTAGTCCGGGCCAG Stranl 5320 TGAACAAGCACATCCGCCCG Hacd4 9140 AAATT CCTGCAGCTCAGAAA Ppplrl6b 1501 CAGTATTCCTGATGCAGTAA Tmemll5 5321 CGAAACGCGTGTTCCCAAGG Pabpc4 9141 O GCTGCTCTACACCTGCCGCG Fstl4 1502 CAATGCECCGCTCGAGGGCG Sli3d21 5322 AGGGAGGGAGAAGGGACCTT Glrb 9142 GGCGTGTCTCAACAGAGAAT Smtn 1503 TACTCTTAGTGCCGCAGCCG Wbscrl7 5323 GCCACAGTTAGAGGAGGTTG Sntal 9143 T CAAGAATCTTT CTCATGG Rsclal 1504 GCGTGGCGAGGGAGAGGGCG Mrps24 5324 GTGTTGGAGAGGGCCCAGGG Tiaml 9144 TCGGTGCGTGCCAGGCCGGG Docks 1505 TTTCTGCTGCTGCGCGACCC Ptprzl 5325 GCTGCTCTACACCTGCCGCG Fstl4 9145 o GCCACCCGGGATGCGAGCAC Trim62 1506 AAAGAAAGCCTCTCCCGGGC Gtf2hl 5326 GCAGGTAACGCGATACCGGC Cc2dlb 9146 4 CCAGGTGACCGGCAGGGCTC Tns3 1507 GGGCCGGAACGCACCGCCAT Cull 5327 AACGGATTCCTGGCAGCCTC Ccdc33 9147 TTAATCTGTGAGAGTTAATC Gabrg2 1508 GATGATTCAGGAAGCTGCCT Tinagll 5328 CGATCTAAAGCAACAGGTGG Pkm 9148 GCGCCGCCGTCTCACTCCAG Irsl 1509 GGCCCTCTGGTGGTAGCACC Mpp6 5329 AGGCCACCTGCGGGTGGGCG Assl 9149 GGAATCACCTAGAACAGGCC Sparc 15 10 GTGGCCGAGGCGGAGCGCCC Ptprt 5330 GGTCGATCCGCGCGCGAGTG Ar ge 2 9150 AAACGTTGGGCACATCATTT Lefl 1511 TCTGTTGGCGTCCTTCCTGT Zfp369 5331 GGCGTGTCTCAACAGAGAAT Smtn 9151 GGGCGTTGCTTCTACGGGCT Tmaulap 1512 CGTAGCTTCTGCTATGTGGC D7Ertd443e 5332 AGCTAATTTGATGTCGCAAA 1700001C19Rik 9152 TGGCATCTCAGGTTGCAGCC Gpx6 1513 GTGTGCTTGAAATGGCTTTG Gprl 1 5333 GCCACCCGGGATGCGAGCAC Trim62 9153 ATCTGTCACTGAAGCTGAAA Rsclal 1514 GAGGTrCACGTGATCATTGC Nxf2 5334 CCAGGTGACCGGCAGGGCTC Tns3 9154 GGTGAAGCACTTGGTGCAGG 1110034G24Rik 15 15 CTAGTACTGTTCAACTTGTG Cubn 5335 TTAATCTGTGAGAGTTAATC Gabrg2 9155 GGCTCGAGAAGGGAGGGCTT Irs4 15 16 CGTGATAGCCCAGCTGCCTG Plin2 5336 TGGATGTGCAGGCGTGGCCC Trim29 9156 TTATTCCATGGAATCTCATT Glccil 1517 GGGAGCATGTTGTGTCTTTC Nsun2 5337 GGTAAATGGATTTGACAGGC 4931406P16Rik 9157 GGGCTGGCTGAAAGACACTC Adig 1518 TCAATGGGCACCGATGGGCG Nude 5338 CACTGAACAGAGGGCGGACG Fbxw7 9158 GGGCTAACTGCCAATCGCAA Tssc4 1519 AGCTGTCTGGAGAATCTAAC Fermtl 5339 GGAATCACCTAGAACAGGCC Sparc 9159 TCCCAGCTACTGTTAGTCTG Erv3 1520 GATCCCGTAGCTAGAGAACG Ldlrapl 5340 GGGAGGCCGGCGAGATTGTA PpplrlS 9160 TAGTGATAACACTTAGAAGC Pafah2 1521 TGATTGGCGGAGCGCGATGC Tmeff2 5341 GGGCGTTGCTTCTACGGGCT Tmanlap 9161 GCCGGATCCAAATTCCAGGG Gas211 1522 GGGATGTCTATAAATGTGCC Adam6a 5342 TGCTAGGAGCTAAAGAAACA Rcan2 9162 ACAGTAGCTTGTCACTGGCG Epha5 1523 GTCGCCGAGCCGGGTTGCTA KiBb 5343 TGGCATCTCAGGTTGCAGCC Gpx6 9163 TCAGAGGGCGTTCTTGAGGC Ubxnll 1524 AAATCCCGCGATTTGTACCG Stk35 5344 GGACCATCCATCAAGAAGAA Cyp21al 9164 GACTAGAGCCCACCGGGTCA Irf4 1525 AATGACTGTTTAATTTGGGT r 5345 GGCTTGGGATTCCAGTGCTG Podn 9165 GTGTAAAGGAGTGTAAATTG Oprml 1526 GCTCGGGAAGTGCGGGCTCC Edfl 5346 CTCAGCTTACTGTCAGTACA Gm7361 9166 GGCTTTCATCGGAGCACGCT Pafah2 1527 ACACTATCCCAGAGTCTCCC Vmnlrl88 5347 TTATTCCATGGAATCTCATT Glccil 9167 AATAAACEGAAAGCCCTCTG Amy2b 1528 GGTACCAAGAAGCTGACTTT Pappa2 5348 GGGCTGGCTGAAAGACACTC Adig 9168 GCCCTGGGCGAGCAGCTTGG Lars2 1529 CACTAGTTACAACTCCTGCA S il 5349 GGGCTAACTGCCAATCGCAA Tssc4 9169 CCGCATCTGCCTATAACTGA G3bpl 1530 GAGCAATACAGCAGGAGTCG Nme8 5350 GAGAA CGTGGCTGAG CAGCG Mfsd2a 9170 AACACATAATCTCTTC AGCT Cst9 1531 TTTGGGCTCATGAAAGGTTT Opnlsw 5351 TAGTGATAACACTTAGAAGC Pafah2 9171 GTCAGAACCGCGTTCCCTCA Sntal 1532 GAGTGATGGCAAGGAAGCCC 1700024P 16Rik 5 5 TGGATTCAGATGGAAATGTC Tecta 9172 GCTGGGAGGCCTCTGCGGCG Arl5a 1533 CCTGAATGTATGAATCCCAC Ha crl 5353 TTGGACTGGGTCCTGATGGG Rcan2 9173 TATAGGCACCAACGAGTAGC Slc9al 1534 GCTCGTATATCCAACCTCAG Hpca 5354 GCCGGATCCAAATTCCAGGG Gas211 9174 TGCTATGGTCACCAGATACC Nude 1535 TCAGGACAGACAGTTAGGCA Myolg 5355 AGCTTGGCCTAATCCCACAG Slco4al 9175 GCATGATGGrGTTAAATTAC Glccil 1536 GACCCTAATTCAGTAGATCr Prokr2 5356 TGCCAGGAGGATATTCAAAC Sult6bl 9176 GGGACGCCACCTCCGGAGGT Dus l 5 1537 TGAACAAGCACATCCGCCCG Hacd4 5357 TGTGGCTTTAGCCTTGCACA Ppcdc 9177 n AAACGTAGCATGTTTAACTT Mppel 1538 AGAGGCTTGTCTACATGCCT Elavl4 5358 GTGCGCGGCACGGCGCGCTC Neol 9178 CAGCAAGTAGCTGACAGGAA Tmeml76b 1539 GGTGCTCTTGAGTGCTGGCT Doxl2 5359 GACTAGAGCCCACCGGGTCA Irf4 9179 CGTGTGGAATATTTCACAAC Mat2b 1540 GCCACAGTTAGAGGAGGTTG Sntal 5360 CTTCGTCTCCAGAAGCGACA Toel 9180 n GGTCCCTTAGTTAGAGCAAG Actr5 1541 GTGTTGGAGAGGGCCCAGGG Tiaml 5361 CTGCGTCACGCCCTCCTTAA Vps8 9181 o AAA GAGGAA CTTTATA GAGC Irf4 1542 GCTGCTCTACACCTGCCGCG Fstl4 5362 CGGCTGCAAGCCGGTCACCC Efna5 9182 GCGCGCTCCGAGACGCAGAG Cbx3 1543 TGTCGACGCCGGTGCTCGTG Scn8a 5363 GGCTTTCATCGGAGCACGCT Pafah2 9183 CCTCCCTTTCCCTCTGGCTC Lin23a 1544 GAAGACAAGAATGTGATGT G Nme4 5364 TTGGTCGAGAGCCGCCGGCT Rcan2 9184 TACTTACCTTTGCAACTGCC Secl6b 1545 GACGCGCTCTGGGCCAGCCG Myold 5365 TGCACCGTCTTTGTGAGGTG Stra6 9185 J ACAGGCAGTGGTTGAAATTC Scgb3a2 1546 GGCGTGTCTCAACAGAGAAT Smtn 5366 GCCCTGGGCGAGCAGCTTGG Lars2 9186 TTCGGGAAGCAGGTATGGCA Slc24a2 1547 TACAAGAATCTTTCTCATGG Rsclal 5367 CCGCATCTGCCTATAACTGA G3bpl 9187 CCAGAGCCCTTCAGCACCAT 583041 lN06Rik 1548 GACCGGAACCGTGGTGTCCT Zf 9 4 5368 AGAGAGGGTGGCGGCCCTCG Adss 9188 GGCACTAAATATAGACTTCA Tcea3 1549 GCCACCCGGGATGCGA GCAC Tiim62 5369 TTAGTTCCTGATTCAATCCC Zpldl 9189 o TCGTTCAGTAAATTGCT CTT Rapgef6 1550 CCAGGTGACCGGCAGGGCTC Tns3 5370 GCCCTGCCGTAAAGTGAAGA SenpS 9190 GTACCTCAGGTrrCCTGCAG Gm5 111 1551 TTAATCTGTGAGAGTTAATC Gabrg2 5371 GTCAGAACCGCGTTCCCTCA Sntal 9191 CACAGGAAGTGGTGACTTGT Dock 10 1552 TTGTACTTCGTCCAGTACAA Acacb 5372 TTACGTGCTAAATCTGAACT Rcan2 9192 AATTGCTAACAGGCTTCCTT Id 1553 GGAATCACCTAGAACAGGCC Sparc 5373 ATCCCAACCGTCAGCTCGAG Lcorl 9193 o GAGTGGAGCTTGCACAACCC Vav3 1554 GGGCGTTGCTTCTACGGGCT Tmaulap 5374 TATAGGCACCAACGAGTAGC Slc9al 9194 4 TAGGAGCCCTGGAAGTCGCG Zfhx4 1555 CCCACATCTCCACCACCCGC Dab2ip 5375 CGCTTGTGGAGCGCGCAGCG Dclk2 9195 o AGGGAAGGAGCGAGGCTAAG Gm2a 1556 TGGCATCTCAGGTTGCAGCC Gpx6 5376 TGCTATGGTCACCAGATACC Nude 9196 ACCTACCGGGTGCACTTCAC Tcn2 1557 ATCTGTCACTGAAGCTGAAA Rsclal 5377 GCATGATGGTGTTAAATTAC Glccil 9197 TCAGACAAGAAATC CAGTTC Ifnlrl 1558 GGTGAAGCACTTGGTGCAGG 11 10034G24Rik 5378 ACCGCGGTGCGTGCTGTACC Parp6 9198 GGGAGGACCAATCTGGAAGA Tcea3 1559 TCCGCCCGCATGTCTGTTGG Fastkd3 5379 GGGCTCAGAATGAATATGAT Ermn 9199 GGAGTCTGAGCCGCGGAACC Epsl5 1560 TTATTCCATGGAATCTCATT Glccil 5380 AGGGAAGGGTGCTATGGTGC SlOOal 9200 GCGTATTCTTGTGGGATGGC Klral 1561 GGGCTAACTGCCAATCGCAA Tssc4 5381 GGGACGCCACCTCCGGAGGT Duspl5 9201 CTTGTCACCGAGCAACAAGA Ppplrl6b 1562 TCCCAGCTACTGTTAGTCTG Erv3 5382 GACGCTTGGGAACCTGCAGG Nlrxl 9202 GGGCTACAGGTTAGGGCGAC Trim56 1563 TAGTGATAACACTTAGAAGC Pafah2 5383 AAACGTAGCATGTTTAACTT Mppel 9203 CGGGACTTCCATGCGCGCCT Rasef 1564 AGGGCATCACTGAACTGGCC Sema4a 5384 CGTGTGGAATATTTCACAAC Mat2b 9204 GTTCGGCAAGAATCCTCACG Ogdh 1565 GCCGGATCCAAATTCCAGGG Gas 11 5385 GGCATTTACAGACTGGCAAG Asic5 9205 CTGGACATTCTATTGTCTCC Gm9758 1566 AGACAACCTACAGAGGCTG A Phex 5386 GGTCCCTTAGTTAGAGCAAG Actr5 9206 GGGTCTGTCrACACGGGCTC Sla2 1567 TCAGAGGGCGTTCTTGAGGC Ubxnll 5387 AAAGAGGAACTTTATAGAGC Irf4 9207 ACCCTATTGATTTCTTCTTC Faml96a 1568 GCGCTGTGTGCGGGTTGTGC Nkapl 5388 GGGACCACATTGGATGAA GC Stra6 9208 GTCTGTTAATTGCATCACTT Echsl 1569 GGCTTTCATCGGAGCACGCT Pafah2 5389 GTGGATTCTTGCTCCGCTCG Ppdpf 9209 GGTGGAGATGGAGATAAGGA Fgf3 1570 AATAAACTGAAAGCCCTCTG Amy2b 5390 CGTCCGGAAAGCCTGCTATG Mcoln2 9210 GTACGCGACTGTCCTCCTTG Tinagll 1571 CATATTTGTCATTTGCCTGT Utp20 5391 CCTCCCTTTCCCTCTGGCTC Lin28a 9211 ACACTTGGTGAGGAGGTAAA Gpm6a 1572 GCCCTGGGCGAGCAGCTTGG Lars2 5392 ACAGGCAGTGGTTGAAATTC Scgb3a2 9212 TGGAAGTTCATTTAGACTGC X 2 1573 CCGCATCTGCCTATAACTGA G3bpl 5393 GGCTCTGGTAACTAGGCAAC Arll3b 9213 AATGATTATGCTGAGCCATG Ef a 1574 CCTGGGTTTGGCATCTCTCG Cdhll 5394 TTCGGGAAGCAGGTATGGCA Slc24a2 9214 AGAGAGAAATGGAGAGGGAG Cstll 1575 GTCAGAACCGCGTTCCCTCA Sntal 5395 CTGAGCCTTTGTTAATAGGT Freml 9215 GCAGCGAGTCTGATTGTTCC Psd3 1576 TATAGGCACCAACGAGTAGC Slc9al 5396 GGTTAAGGGTGATGGCCTTT Tdg 9216 ACTGTGAAGCTGAGGGAACT Gpm6a 1577 TTGCGGAGAATCCATACTCC Pah 5397 CCAGAGCCCTTCAGCACCAT 5830411N06Rik 9217 GAGCCCATCCrCAGCTAAGA Tenm3 1578 TGCTATGGTCACCAGATACC Nude 5398 GGCACTAAATATAGACTTCA Tcea3 9218 GGAGGGTGAAGTGATGTGAC Zfp354c 1579 GCATGATGGTGTTAAATTAC Glccil 5399 CGTTGGACAGTAGGTGGGAG Clk3 9219 GGGCGCTAACCAGTCCTTGA Hck 1580 GGGACGCCACCTCCGGAGGT Dus l 5 5400 GGTAGGCTAAGGTGAGCGAA Spatal7 9220 CGAATGCTTATGTGAGCTCT Bpifb6 1581 CAGCAAGTAGCTGACAGGAA Tmeml76b 5401 TCGTTCAGTAAATTGCTCTT Rapgef6 9221 CCTAAAGGATAATGTAAGAA Abcc3 1582 CGTGTGGAATATTTCACAAC Mat2b 5402 CGTACTTCCGCCAATTTGCT Orel 9222 GGGCGGGTGGACCCGCTTGC Gnaz 1583 GGTCCCTTAGTTAGAGCAAG Actr5 5403 AATTGCTAACAGGCTTCCTT Id3 9223 TTGATGAATCACGTGTGTCG Diaph2 1584 GCGCGCTCCGAGACGCAGAG Cbx3 5404 TAACAGTCACTGGGTGTGGC Adam6b 9224 TGGTAAGGTCrAGGAGGCTT Pik3ipl 1585 TGTAGAAAGCTCCCGTGrGG cn 5 5405 AGGGAAGGAGCGAGGCTAAG Gm2a 9225 n GGGCGCGGGCGGAGGCTCGG Limdl 1586 CTGAGATATTGTTCAGATTG Myot 5406 ACCTACCGGGTGCACTTCAC Tcn2 9226 AGATGACGGCTCTCATATGG 583041 lN06Rik 1587 CCTCCCTTTCCCTCTGGCTC Lin28a 5407 TATGCACTGTCTGGAGGGTG Lrp2 9227 CAGGCACTGGTGCCAAGCGA Mat2b 1588 TACTTACCTTTGCAACTGCC Sec 16b 5408 GACAAGCTGGCGGGAGCCAA Enpp5 9228 n ATTTGCAACCTGATTCAACA Kynu 1589 ACAGGCAGTGGTTGAAATTC Scgb3a2 5409 TCAGACAAGAAATCCAGTTC Ifnlrl 9229 o GAAGCGTTATCATGTGAGGC Casp9 1590 TTCGGGAAGCAGGTATGGCA Slc24a2 5410 GGGAGGACCAATCTGGAAGA Tcea3 9230 AAACTTACAAACCTTCCGAT Nudcd2 1591 CCAGAGCCCTTCAGCACCAT 583041 lN06Rik 5411 GCGAGTTCTCTGTCGAAACC Rabl3 9231 b CCCGCCGCCAGCTGTAGGGA Tlisd7a 1592 GGCACTAAATATAGACTTCA Tcea3 5412 GCCGGGTGAATGCAACACCC Txnrdl 9232 TGGTCCGGCAGACTATTCCA Rnfl45 1593 TCGTTCAGTAAATTGCTCTT Rapgef6 5413 GACTTGGAATATGAGCTTGC Cc2d2a 9233 J CGCTCACGGrGGCCTCCCAC Itgax 1594 AGGCGGTGCTTGGGCCTTGG Ncapg2 5414 GCGTATTCTTGT GGGATGGC Klral 9234 AGGAGACGGAGGGTGGGACC E2fl 1595 GTACCTCAGGTTTCCTGCAG Gm5111 5415 GAGAGAGTGTCAGAGTCACT Adgrf2 9235 AGGGAGTTACCAGCGAGTCG Asap3 1596 AATTGCTAACAGGCTTCCTT Id3 5416 GTGTCCGGCTGCGAGCGAGC Grik4 9236 GCCCTGGAATTCGAGAAGCC Alg6 1597 TAGGAGCCCTGGAAGTCGCG Zfhx4 5417 GTTCGGCAAGAATCCTCACG Ogdh 9237 o AGGAGAGTGTAATCTTACTC Snx25 1598 AGGGAAGGAGCGAGGCTAAG Gm2a 5418 ACCCTGTAATTTGAACAGCC Selenbp2 9238 TTGGATTCGCGCGCCGGCCC Leprot 1599 GCAGCTCTCCGCAGGCACGC Steap2 5419 GGGAATGTGTTCGCTCCGCG Dsg2 9239 CTTTGTAAACAAGTGACAAT Cyp2abl 1600 ACCTACCGGGTGCACTTCAC Tcn2 5420 GGAGCGAGAGGAGGAGCAGG Col6a3 9240 5 ATAAACCAGTTT ACCCGGCA Gpn2 1601 TCAGACAAGAAATCCAGTTC Ifnlrl 5421 GGGTCTGTCTACACGGGCTC Sla2 9241 o AGATG CΑΓGAGAGAAGCACG D330045A20Rik 1602 GGGAGGACCAATCTGGAAGA Tcea3 5422 GAGAGGTGTTTACTATCACT Iars2 9242 4 ATTGGTCGGTGTTGGCGCGA Rbbp4 1603 GGAGTCTGAGCCGCGGAACC Epsl5 5423 GGAGAAGCGTCATCAGTATC H2-M3 9243 TCCCTTTAAGGTCTCCAGCT Besl 1604 ACCTGAGACTGTATTAATTA Tc2n 5424 ACCCTATTGATTTCTTCTTC Faml96a 9244 CAGGGATGTGTTTACTAAGC Osbp2 1605 GCGTATTCTTGTGGGATGGC Klral 5425 AGCACATTGGCTCAGGCTTC Rrp36 9245 TATGTATGAGCTCCCTCCCT Gal3stl 1606 GGGCTACAGGTTAGGGCGAC Tiim56 5426 GTCTGTTAATTGCATCACTT Echsl 9246 AGAAGT GGTCGGGACATTTA Ndufa4 1607 GTTCACATTTCAAACAGAGC Plekhsl 5427 GGTGGAGATGGAGATAAGGA Fgf3 9247 GGTCACTACCAAGTTTGGTT Aunip 1608 CGGGACTTCCATGCGCGCCT Rasef 5428 GTACGCGACTGTCCTCCTTG Tinagll 9248 CAGGTGGATTTCTGAGTTCA Laip4 1609 GTTCGGCAAGAATCCTCACG Ogdh 5429 CGGCTTTATAAATACAGAGC Psmb4 9249 GGGTCCAGCGAGCCTGACCG Ago4 1610 CCAACTGATTAACTCTGCCG Tmsbl5b2 5430 ATTGTGTATCTTTAGTTACC 01fr921 9250 AACGAGCTATGCTAAAGTGA Tmeml76a 1611 CTGGACATTCTATTGTCTCC Gm9758 5431 GAGC CCATCCTCAGCTAAGA Tenm3 925 1 AAACGGATTAGTGGGCATCT 01frl394 1612 GGGTCTGTCTACACGGGCTC Sla2 5432 CATGGCAACAGTCAGTGCGC Tritl 9252 TAGAGGAAGTGCATCTGTGC Nlrplb 1613 ACCCTATTGATTTCTTCTTC Faml96a 5433 GGAGGGTGAAGTGATGTGAC Zfp354c 9253 TACAAGGACTCTTCGCTGGT C tn l 1614 GTCTGTTAATTGCATCACTT Echsl 5434 GGGCGCTAACCAGTCCTTGA Hck 9254 AGGGAATCAA ATTCG CACAA Magee2 1615 GGTGGAGATGGAGATAAGGA Fgf3 5435 TTATTTATTCTTCCTCCTGT Tdpoz3 9255 AGGAATGGGAAATGGGATCT Ryr3 1616 GTACGCGACTGTCCTCCTTG Tinagll 5436 CGAATGCTTATGTGAGCTCT Bpifb6 9256 GCACTGTGTCATGAAGGTGG Lrrtm4 1617 ACACTTGGTGAGGAGGTAAA Gpm6a 5437 TGGTAAGGTCTAGGAGGCTT Pik3ipl 9257 CGCCGCAGCTCCGGCCATAG Sntgl 1618 TGGAAGTTCATTTAGACTGC Xm2 5438 GGGCGCGGGCGGAGGCTCGG Limdl 9258 CCCGGTAGTGCTCCATTCTC Mtgl 1619 AGAGAGAAATGGAGAGGGAG Cstll 5439 AGATGACGGCTCTCATATGG 5830411N06Rik 9259 CTGGCATGTCCACAATAGTG Efcab7 1620 ACTGTGAAGCTGAGGGAACT Gpm6a 5440 CAGGCACTGGTGCCAAGCGA Mat2b 9260 CATCCTAACCTCATGCAAGG Zfp2 1621 GAGCCCATCCTCAGCTAAGA Tenm3 5441 GTGGTCCAAGGCCAACAGTA Zfp691 9261 GCAGACCGTGAAGGGAGGCG Insrnl 1622 ATAAAGGGTCATACAGGTAG Gml3103 5442 AAACTTACAAACCTTCCGAT Nudcd2 9262 ATGGACATTGAGGCTCTAAG Tmem54 1623 GGAGGGTGAAGTGATGTGAC Zfp354c 5443 GTTGGTTTGACCCTTGACCT Traem225 9263 AGCCAACTCCAGTCCACGAC Tgifl 1624 GGGCGCTAACCAGTCCTTGA Hck 5444 AGGAGACGGAGGGTGGGACC Ε2 9264 TGAGATGCAGTTAGACTTAC Timd2 1625 CGAATGCTTATGTGAGCTCT Bpifb6 5445 AGGGAGTTACCAGCGAGTCG Asap3 9265 AGCTCACAGCAAGCGGCGCC Mpped2 1626 TTGATGAATCACGTGTGTCG Diaph2 5446 AAGCAGAGACAGGTTGAGTT Cd51 9266 ACATGTGCAAAGCTCCCGTT Cntn6 1627 TGGTAAGGTCTAGGAGGCTT Pik3ipl 5447 TGGCAATGCTTCCGGGTCCT Ubl7 9267 GTCAAGCGCTCCGCACCTCC Snap25 1628 CCGCGGCCAGCGCCAGAGTT Lhfpl5 5448 AAGGTCGGCCGGCGTTTGAA Zyglla 9268 ACGAAACTTCAAGTACCAAA Gpat l 1629 GGGCGCGGGCGGAGGCTCGG Limdl 5449 TCCCGACTGCGGCGTGACTG Tubb6 9269 CTGTTGTGGTTGTTTAAGAC Morel 1630 AGATGACGGCTCTCATATGG 583041 lN06Rik 5450 TTGGATTCGCGCGCCGGCCC Leprot 9270 GGTCTCACAATCGCGTGGCC Calu 1631 CAGGCACTGGTGCCAAGCGA Mat2b 54 ATAAACCAGTTTACCCGGCA Gpn2 9271 GATTGGGTATGACCTTCAGT Colllal 1632 GAAGCGTTATCATGTGAGGC Casp9 5452 ATTGGTCGGTGTTGGCGCGA Rbbp4 9272 TAAGCGACGTTCCTAGTTCA Tcn2 1633 CCTACACAGGCGTCTCTGAT Tmsb 15b2 545 3 CAGGGATGTGTTTACTAAGC Osbp2 9273 n TACAGTCGTGGGTGGACCAG Abcal5 1634 AAACTTACAAACCTTCCGAT Nudcd2 5454 TATGTATGAGCTCCCTCCCT Gal3stl 9274 CTCTAGGCAGAGGACAGCGA Lactbll 1635 TGGTCCGGCAGACTATTCCA Rnfl45 5455 GGTCACTACCAAGTTTGGTT Aunip 9275 CAAGTGTCCGAGTGGCGCGG Lif 1636 ATTCCGCTCTACTCCGGGAG Eml5 5456 CACGTGACAGTCGGAGGCGC Dao 9276 n GAGGAAAGGTCACTTGTGAC Slc25a34 1637 AGGAGACGGAGGGTGGGACC E2fl 5457 GAAAGCTGAAGTCTTAACTG Cldndl 9277 o CCATTTGGGAGCCCATGTTA ActllC 1638 AGGGAGTTACCAGCGAGTCG Asap3 5458 GGGTCCAGCGAGCCTGACCG Ago4 9278 5 TAGATGTCGGAGAGTGTGCC Glral 1639 GCCCTGGAATTCGAGAAGCC Alg6 5459 AAACGGATTAGTGGGCATCT 01frl394 9279 b CCCAAAGTCCAGTGCAATAA Cela2a 1640 GAGCCCAGAGTCAGTTTAAA Lcelal 5460 GGAGGGTCACGTGAACGGGA Hexa 9280 TACATT GGAAAGTGTT GATT Zcchc3 1641 AGGAGAGTGTAATCTTACTC Snx25 5461 AGGAATGGGAAATGGGATCT Ryr3 9281 J GACTAAGAAATGTGGGCTGG Col9al 1642 ACCAGAGCAGGCTGAACTTG Cl s2 5462 CCACCAGACTCTACTATATA Pptl 9282

AACACAAAGAAGAATGAAAC Ms4a7 1691 TGCGCCGATGCTCCAAGGCC Ttc39a 5511 GAACAGGGAACCCTAGAACC Slc22al8 9331 CTTTACATATGCAGTCCCAC Esrrg 1692 GTGCATGTATGCATGCATGT Zmiz2 5512 GTATCTTAGGGAATACTACT Uqcrh 9332 GTCCGCAGCCGCCGCACGTG Unc5d 1693 CCCTTCGGCCACCGTCGGAG Tubgcp2 5513 CACCCTCGACCAGCCCAGTC S100a4 9333 o CTGGCAGCCCGCGCGAGGTG RassΏ 1694 ACTCCAAACTCGCGCCTAGC Cenpu 5514 GAGGCACCTGCCrCGCEAAT Nkx6-2 9334 AAACAGCTACAAGGCTTGCT Scn7a 1695 ACTGCCTGCCAGTCCCAAGC NipaB 5515 CGCTGGACTCCTCAGTCTCC Agol 9335 GGCAGGACATTCCGGTCAGA Snrpn 1696 AAGGACCCGGCACGCGGCAA Efhd2 5516 TCTTCTGTGCCTCCTCATTC Dao 9336 5 CCCGCTCAACTCACAAGAGG DocklO 1697 GGCTAAAGGTGTCAGGGTAT Adam29 5517 CCACTAACTAGAGTGATTAT Olfr920 9337 o GGAAGTGTCCGCAGTTCGCC Pclo 1698 GGGTCCCACGGGCGGGCGCG Zraym4 5518 GTTTGAACTCTGTGAGTTCA AbcclO 9338 4 GGCGGTTCCCGTGCTCTGAT Spdya 1699 CAATCTAGGGAAGGCGGGCC Sfpq 5519 TGAGGTTCCGGCTTCTTT AA Pdikll 9339 TATCCCACCATTCCCTCTAG Wbscrl7 1700 CTCTGGTTGAGAGTGCCTTG Mroh2a 5520 TATTCAGAGGGAAGTTGGCA Hepacam 9340 GTACTGCTCCCTAAGCTCTA Dytn 1701 CGCAGATGCCGCCGAGTCGG Epha6 5521 GGATCAATATCACTCACATG Slc22al 8 9341 TTTCTGACTTCCTGTCAGAG Timd2 1702 TGGAGCAGCCCTGGTGGTAC Kiz 5522 AGGCTATGAGGGTAAGAGCC Gucalb 9342 CCCTCCATCTGTGAAGATGG Tctexldl 1703 ATGCAACTGTACGCCCAGAG Qrfpr 5523 TCCGCCGTGACTTTCGCCCG CdkSrapl 9343 GGGTGAACCAAACCAGTTTG Sfn 1704 ATCTGATACTGTTTCTTTAG Aga 5524 TGCACCAAATCTCTCGAGTT Histlhlc 9344 GGCGGGTCTGTAACCGGAAA Malsul 1705 CTTTCGGCCACGCCTGATTC Casp3 5525 GCAGCGAGCACACCTGGGCG Svbp 9345 GGCAAGTGGAGATGTGGGCG Plbl 1706 GAACAGGGAACCCTAGAACC Slc22al8 5526 AGAGATTTGGTTTGTTAAAG Anapcl 9346 TGTTGCTGGTTGTATGGAGT Slc25a53 1707 GAGGCACCTGCCTCGCTAAT Nkx6-2 5527 CCGTCCTGGGCCACTTGTCC Fbxw7 9347 GGAGGCGACCTCGGACTCTG Cldn23 1708 CGCTGGACTCCTCAGTCTCC Agol 5528 AGCAGGTTAGTGGGCGCCAC Wdtcl 9348 CGGGAATGCCGCG CCGTGGG Rps6kal 1709 GCGTTGCTTTAGTTGATATG Srfbpl 5529 TGGGAAGCTAAGACCAGAAG 1700003F12Rik 9349 GAGCGGCTGTCCCATCGCCC Pisd 1710 TGTGTCTGCCAGCGTGCAGC Ankefl 5530 CACCACCTCCCTGAGCCTAG SlOOal 9350 GAGGGACGATGCTACCAGCC Nyap2 1711 AATACTAGATAAAGTCACTG Skint4 55 CTTTACATATGCAGTCCCAC Esrrg 9351 CTTTGTCTGGTTCTGTTGTG Gabrg2 1712 GGCGGGCCTAAGCAGGGTAG Rapgefll 5532 CTGGCAGGCGCACCTGGAGC Hcn4 9352 TCTTCTCTCGGTTAATGTCT Sparc 1713 TGAGGTTCCGGCTTCTTTAA Pdikll 5533 TTTCTGACTTCCTGTCAGAG Timd2 9353 ACGCAGCGTCAGCTCCTGAT Fbn2 1714 GGATCAATATCACTCACATG Slc22al8 5534 GGGTGAACCAAACCAGTTTG Sfn 9354 + o ATGTGTGAGCACAGACTTCC Arhgap40 1715 GTTTATTTACTTCCGGCTTG Ch d5 5535 CGGGAATGCCGCGCCGTGGG Rps6kal 9355 GGAGGAGCTGAAGGAGGGCG Hddc2 1716 CTGTGCTTTCTGAATCTTGT Plpp3 5536 CTTTGTCTGGTTCTGTTGTG Gabrg2 9356 CCGCCCAATCTCGGGTGTCC KiBa 1717 TCCGCCGTGACTTTCGCCCG Cdk5rapl 5537 GCCAGGACTGGCTCGGTCGC Cpne8 9357 CTAGATGGTGCGCTTGCGCC Cepl62 1718 TGCACCAAATCTCTCGAGTT Histlhlc 5538 AAACTTATCCCATCAAATAG 4930591A17Rik 9358 CTGTAGGGAAGAGTGGGCTG Zfp786 1719 GCCGGGACTCGAGGGTCGCC Insml 5539 TCTTCTCTCGGTTAATGTCT Sparc 9359 CCAGATTGGrGTTAAGAGGA Hcrtil 1720 AGAGATTTGGTTTGTTAAAG Anapcl 5540 AGGACTGGACGACTGAGAGA PpplrlS 9360 TGTTGTTTGTAGGTGTTGGA Iars 1721 ACAGTGTTTACTAAGCACAT Insl5 5541 GGTACTTGGAGCTGAAACCT Tecta 9361 AGCTTCGGAGGACAGGCTGT Sntal 1722 TCTTACCCGAGTACTCCAGG Hti6 5542 ATGTGTGAGCACAGACTTCC Arhgap40 9362 GCAGCTTTGGTGTCCGGGAG Atoxl 1723 AGCAGGTTAGTGGGCGCCAC Wdtcl 5543 CCGCCCAATCTCGGGTGTCC KiBa 9363 CCTTCAGAGTGTATCCTCTA Col22al 1724 TGGGAAGCTAAGACCAGAAG 1700003F12Rik 5544 CCAGATTGGTGTTAAGAGGA Hcrtrl 9364 GCGGTTGCTTAGCAACTAAG Ccdcl26 1725 CTTTACATATGCAGTCCCAC Esrrg 5545 AGCTTCGGAGGACAGGCTGT Sntal 9365 GGGCAATGCGGGTCCAGCCA Adralb 1726 CTGGCAGCCCGCGCGAGGTG Rassf2 5546 GCAGCTTTGGTGTCCGGGAG Atoxl 9366 AAACGGCGAGAGGGCGGGAC Sf3al 1727 AAACAGCTACAAGGCTTGCT Scn7a 5547 CCTTCAGAGTGTATCCTCTA Col22al 9367 ATCACA TATTAAGCACAG Adam29 1728 GGCGGTTCCCGTGCTCTGAT Spdya 5548 TCAGCTGACCTGAGTCAAGC Commd4 9368 GGGCGCGCTCCCGGAGGGTG Adam23 1729 TATCCCACCATTCCCTCTAG Wbscrl7 5549 GGGCAATGCGGGTCCAGCCA Adralb 9369 n ACTCATAGTCAGTGTGGGTG Fatl 1730 GGTCTGACGTCAGCCATGTG Nr2el 5550 AAACGGCGAGAGGGCGGGAC SBal 9370 ACCTAACAAGTGTAAG GCCC Pafah2 1731 GTACTGCTCCCTAAGCTCTA Dytn 555 GCAGTGTGATGGTTGGAGCG Rab28 9371 CACACACACACTCAAACAGA Col5a2 1732 TTTCTGACTTCCTGTCAGAG Timd2 5552 GCCCGGATCTCATTTCGTAC Tdo2 9372 n AAAGCCAGCCTTCTAGATAT 4921539EllRik 1733 CCCTCCATCTGTGAAGATGG Tctexldl 5553 CAAAGCCCATTAAGAAGTGT Sytll 9373 o TTGGGTAGGCGCGCGCTGGT Nebl 1734 GAATAAACACAGAAAGAATC Pparg 5554 CCCACCTCCGCGATTGCGGG Vpsl3c 9374 5 ACCACGTGGTTTCGCCAGCT Adckl 1735 GGGTGAACCAAACCAGTTTG Sfn 5555 ACCTAACAAGTGTAAGGCCC Pafah2 9375 b AATTAATCAATGGAACACTC Epsl5 1736 GGCGGGTCTGTAACCGGAAA Malsul 5556 AGGAGAGAATCCGCAGCACT Clmp 9376 CCAAGCGGACCCTATTCTGG Pdlim4 1737 TGTTGCTGGTTGTATGGAGT Slc25a53 5557 CCCGAGCCAGAGGTGAGGGA Med8 9377 J GTTGCACGAGATCCGATCCG Abcal5 1738 GGAGGCGACCTCGGACTCTG Cldn23 5558 CCAAGCGGACCCTATTCTGG Pdlim4 9378 TTCTACTCTGGTTGCATTCC 1700007B14Rik 1739 ACTCAACTTTGAGTGACTTC Higdla 5559 AGGCTAATCAGCCTTGGGTG Tspanl 9379 GTGGCCACGCCTCTCCTCAG Tnfrsf22 1740 CGGGAATGCCGCGCCGTGGG Rps6kal 5560 CTCGGAGAACGAGGGAAGCC Dis31 9380 ACAAACCGCTGTCAAGTGAA Slcl5a4 1741 TATTCACACAGAGTGCAGGG Cstal 5561 GTGGCCACGCCTCTCCTCAG Tnfrsf22 9381 TTAGCATGTGAGCGCGACCC Tmem54 1742 AAACAGTCTCATTCACAGGA Seel 5562 TTAGCATGTGAGCGCGACCC Traem54 9382 CTGATGGTTTGGCTTCTGAT Zfp46 1743 CTTTGTCTGGTTCTGTTGTG Gabrg2 556 CTGATGGTTTGGCTTCTGAT Zfp46 9383 AATACCAGATGCAGTCACTA Skint3 1744 TCTTCTCTCGGTTAATGTCT Sparc 5564 GGGTAAGGCGGCCGGGTAGC Prdml5 9384 GCAGGCGGTGGGTGTAGCAA 4921536K21Rik 1745 ACGCAGCGTCAGCTCCTGAT Fbn2 5565 GCAGGCGGTGGGTGTAGCAA 4921536K21Rik 9385 CTTGCGGGTAGCAGATGCTT ZfpSOO 1746 AGCACTGCGGGCGGTCGACC Oprdl 5566 CGTACAACATCCTCGCTGCT Txnrdl 9386 AGCCGGCCCAGAGCTCTGAG Thsd7a 1747 ATGTGTGAGCACAGACTTCC Arhgap40 5567 GCCGACCAGCCGCTACGAAG Rnfl9b 9387 GCCGACCAGCCGCTACGAAG Rnfl9b 1748 CCGCCCAATCTCGGGTGTCC Ki 3a 5568 AGATGTGAGGTCCTGTGTCC Scnml 9388 CCGCCCATCTCACCTGTGAT Gca 1749 CTGTAGGGAAGAGTGGGCTG Zfp786 5569 GGGAGTCCGGTGGGAAGTTA Atp6v0b 9389 TTTGGATGTGGGCTGGCAGC Btnl9 1750 CCAGArTGGTGTTAAGAGGA Hcrtrl 5570 TTTGGATGTGGGCTGGCAGC Btnl9 9390 GTGGAAAGTTGCTTTCGTTG Mycs 1751 AGCTTCGGAGGACAGGCTGT Sntal 5571 A GATCTA GCATG CCAAGCCT Tiaml 9391 CACGCCCTGATCACCCGCAA Impdhl 1752 GCAGCTTTGGTGTCCGGGAG Atoxl 5572 GTGGAAAGTTGCTTTCGTTG Mycs 9392 TAGACTCGTCACCTTCCTGA Ttc39a 1753 GCGGrTGCTTAGCAACTAAG Ccdcl26 5573 GCTGCTGGATGGGAAAGGAA Fgfbpl 9393 GAAGGAAGCGTACAATTGGC H2afv 1754 GGGCAATGCGGGTCCAGCC A Adralb 5574 GAAGGAAGCGTACAATTGGC H2afV 9394 CAGCTGATGTGAGCTCCTTC Tfap2e 1755 AAACGGCGAGAGGGCGGGAC SBal 5575 TGTGCAAGTGCCTATAGCGA Anapcl 9395 GTCAGAGACCAGAGCAGTGG Lin28a 1756 ATCACATTTATTAAGCACAG Adam29 5576 CAGCTGATGTGAGCTCCTTC Tfap2e 9396 TCTGTCCTGCCCTCACATGT Map3k6 1757 ACTCATAGTCAGTGTGGGTG Fatl 5577 GGGCGGGCTCTAGCTCGAAG AbcclO 9397 CTGTGCAACTGTAGAGTTGG Nipsnapl 1758 AACGTGTTACTGCCATCTAC Scn3a 5578 GTCAGAGACCAGAGCAGTGG Lin28a 9398 GGATTCTTAACATTTCTGGT Tgifl 1759 TTTGGATCAGATCTGTACTC Gml3103 5579 TCTGTCCTGCCCTCACATGT Map3k6 9399 AGTTTCTGAGTTTGGGATCG Fndc3cl 1760 CCCACCTCCGCGATTGCGGG Vpsl3c 5580 CGGAGGAAATAGCGGTCCCG Staid6 9400 CCTCGCGCGCATGCGTGACA Focad 1761 ACCTAACAAGTGTAAGGCCC Pafah2 5581 TAGCAAAGAACCAGACAGAA Nup2101 9401 ATGGTACAGATCATAGCTCA Snrpn 1762 GGGCGTGGCCCAGCGGACCA Cpsf3 5582 CTGTGCAACTGTAGAGTTGG Nipsnapl 9402 ATG ACA CACATGAA CCGA GA Psd3 1763 AAAGCCAGCCTTCTAGATAT 4921539EllRik 5583 CTCGTCTCTCTCGGCGGCAA Tspan5 9403 CCAGGAGCTGCCTGTCTAAA Ar ga l l a 1764 AATTAATCAATGGAACACTC Epsl5 5584 AGACACGGGTGCCAGCAGCT ItgbS 9404 GCACTTGTGATGTCGAACGT Bubl 1765 CCAAGCGGACCCTATTCTGG Pdlim4 5585 CCTCGCGCGCATGCGTGACA Focad 9405 ACGTGACGAGGCCGCCTTAG Vpsl6 1766 GTTGCACGAGATCCGATCCG Abcal5 5586 ACTGGAGATGTCCGGATGCG Plekha3 9406 TTCTTCTTGCGGTGTCCCGG Ndrg3 1767 CCAGGAACTCATATATTACC Spata31 5587 ATTTGTCACCCGTCTTGGGC Ccdcl5 9407 ATCAACGCTCCGAATGACCC Emc7 1768 GTGGCCACGCCTCTCCTCAG Tnfrsf22 5588 CCTG GGAACTC A GCATT CGT Clic5 9408 CTTTAAGCTAAAGAAGAAGT 9830107B12Rik 1769 TTAGCATGTGAGCGCGACCC Tmem54 5589 TTCTTCTTGCGGTGTCCCGG Ndrg3 9409 AATATTTCCATCCACATGCC Robol 1770 CTGATGGTTTGGCTTCTGAT Zfp46 5590 CACTCCTTCGTCAGATTTAG Lyplall 9410 CCA GAACTACCATGAG CAA G Kifl5 1771 AATACCAGATGCAGTCACTA Skint3 5591 CCAGAACTA CCAT GAGCAA G Kifl5 9411 GGGCTAACTGCATGCTAATG Atp8b5 1772 GTGAGGCTTGAAGGCCTTGC Sema4a 5592 GCTTGCAGTTCACGTCATCA Phykpl 9412 GCTTGCAGTTCACGTCATCA Phykpl 1773 GCAGGCGGTGGGTGTAGCAA 4921536K21Rik 5593 GACAAAGATCTGAACGTTAT Ush2a 9413 GACAAAGATCTGAACGTTAT Ush2a 1774 CTTGCGGGTAGCAGATGCT Zfp800 5594 AGTGGCTGGTGCAGAATTCA Gbp2b 9414 TTTCCTTTCCCACTGCGCGG Iqub 1775 GCCGACCAGCCGCTACGAAG Rnfl9b 5595 TTCCGGCTCCTGGCGTACTA Chmp4b 9415 TTTCCTTTCCCTGGTTAGGA Stab2 1776 CCGCCCATCTCACCTGTGAT Gca 5596 GGGAGGAAGCTCTATCAAGT Adralb 9416 TCCCTCCTACTCACGGCGCG ArhgeflO 1777 TTTGGATGTGGGCTGGCAGC Bt l 5597 GGGAAATGGGAAGGCACTTC Cul7 9417 GGCTCACTAGCACAGACTGG Snrpn 1778 AGATCTAGCATGCCAAGCCT Tiaml 5598 AGCGCTGAATTGAACGCTGG Stpg2 9418 GCCATGACGCTCATCCTCCG Ccdc59 1779 GTGGAAAGTTGCTTTCGTTG Mycs 5599 GGGACCTGCGGCTCCTTGCG Anp32a 9419 TTCCGGCTCCTGGCGTACTA Chmp4b 1780 CACGCCCTGATCACCCGCAA Impdhl 5600 TCGCACGCCTGAGGGTCACT Meal 9420 GCGACAGTAGTGGAGGGACG Npml 1781 TAGACTCGTCACCTTCCTGA Ttc39a 5601 AACGCCACTAGTGAGATGCA Amp 9421 GGGAGGAAGCTCTATCAAGT Adralb 1782 GAAGGAAGCGTACAATTGGC H2afv 5602 GGCTCCACCAGACCGCTCCC Vegfa 9422 AACGCCACTAGTGAGATGCA Amph 1783 CTCAGGTCCTTGATAAAGCA Lrao2 5603 GAAGCAGCTTCGGCTTGTGT Rcan2 9423 CACCGGCGCTTCACCCGCTG Zmym4 1784 TGTGCAAGTGCCTATAGCGA Anapcl 5604 CACCGGCGCTTCACCCGCTG Zmym4 9424 CCTTGTCTCTCGCGGCTGAG Tuscl 1785 CAGCrGATGTGAGCTCCTTC Tfap2e 5605 CCTTGTCTCTCGCGGCTGAG Tuscl 9425 TACGTCAGCGTGCTGCTTTC Tmem261 1786 GTCAGAGACCAGAGCAGTGG Lin28a 5606 TACGTCAGCGTGCTGCTTTC Tmem261 9426 GCACATACTTATATCCTGAA Cds2 1787 TCTGTCCTGCCCTCACATGT Map3k6 5607 GTTTGGAAGGATCACTGGTA Limk2 9427 GTTTGGAAGGATCACTGGTA Limk2 1788 CTGTGCAACTGTAGAGTTGG Nipsnapl 5608 AGTTGCACAAGACATCTACA Gm94 9428 GATGGGAGAGGACCCGACTC 1700024P16Rik 1789 GGATTCTTAACATTTCTGGT Tgifl 5609 AAAG CA GAT GTCACGA GTTT Ak7 9429 AGTTGCACAAGACATCTACA Gm94 1790 CCTCGCGCGCATGCGTGACA Focad 5610 GATCGCAGCTGCAAGCTTGG Tfap2e 9430 TCCAGGGCrCCCTCAGCTGC Zdhlicl8 1791 ACTGGAGATGTCCGGATGCG Plekha3 5611 AGCAGACGGTTGGGCGCTGC Snx27 9431 GATCGCAGCTGCAAGCTTGG Tfap2e 1792 GCACTTGTGATGTCGAACGT Bubl 5612 CCTAATTTCTCCCTTAAATC Adgrel 9432 CAGATACTACATCATCAGTC Ar 1793 TTCTTCTTGCGGTGTCCCGG Ndrg3 5613 AGTGTGGCTCTGGAGGTTTG Cypllal 9433 GAATGCTCAAGCATTCCTTT S p 1794 AATATTTCCATCCACATGCC Robol 5614 TTCAAGCAATCGACTGACGT Ttll9 9434 4 ATGGCGCCGGAAATTGGAGT Tmeml09 1795 CCA GAACTAC CATGAG CAA G Kifl5 5615 CCAGTACCGCCGAGCCCAGA Dis31 9435 TTCAAGCAATCGACTGACGT Ttll9 1796 GGGCTAACTGCATGCTAATG Atp8b5 5616 CGCAGAACAATGCAAGCTTG Tmed4 9436 CGCAGAACAATGCAAGCTTG Tmed4 1797 GCTTGCAGTTCACGTCATCA Phykpl 5617 GCTCACCATGTGGCCCACAC Mcoln2 9437 ATTCGCTTCCAACAGTCAAC Fezfl 1798 GACAAAGATCTGAACGTTAT Ush2a 5618 AGGTTTGGAAAGGTTACTGG Heyl 9438 TGTGCTGTTTCTGTGTCTGT CoBal 1799 TTTCCTTTCCCACTGCGCGG Iqub 5619 ACGCGAAACCGGATAAGGAC Zscanl2 9439 ACACAGTAGCATTGGCTTCC Skint9 1800 TCAGTCCATCCCTCAGCGGG Fry 5620 CGGTTACCTTCCCAGGTCTG Lrrc4c 9440 ACGCGAAACCGGATAAGGAC Zscanl2 1801 TTCCGGCTCCTGGCGTACTA Chmp4b 5621 GGTCTGTTCTCGGCGTTGAG Nf2 9441 TCTGACATGTTTATGGCTTC Skint2 1802 GGGAGGAAGCTCTATCAAGT Adralb 5622 CTGAAGAAGGCGTGCAGGGA Podn 9442 AGCTCCACCTGCAGCTCGAG Zfp746 1803 AACGCCACTAGTGAGATGCA Amph 5623 ACGTCCGGGCCCTCAGCCTT AU040320 9443 CGGTTACCTTCCCAGGTCTG Lrrc4c 1804 CACCGGCGCTTCACCCGCTG Zraym4 5624 AGAGCCGAGAGAGATGCTTG Tnfrsf26 9444 GGTCTGTTCTCGGCGTTGAG Nf2 1805 CCTTGTCTCTCGCGGCTGAG Tuscl 5625 TTTCTGTAAACTCGTGCTGA Fcrll 9445 TCCTTCAGATCAACCATAAA Cd l 2 1806 TACGTCAGCGTGCTGCTTTC Tmem261 5626 GGGCTAGAAAGATAGGCTTG Pla2g7 9446 A CGTCCGGGCCCTC AGCCTT AU040320 1807 GCACATACTTATATCCTGAA Cds2 5627 CAGCAAAGCGCCCAGTCTCT C77080 9447 AGAGCCGAGAGAGATGCTTG T frs 26 1808 GTTTGGAAGGATCACTGGTA Limk2 5628 CTTCAATTCTCTAGGTTTGC Gpx5 9448 GGTCCGAACTGGGCGGGACC AtpSal 1809 GATGGGAGAGGACCCGACTC 1700024P16Rik 5629 GCCTGGGAGGGTCTACCTAT Siae 9449 CAGCAAAGCGCCCAGTCTCT C77080 1810 AGTTGCACAAGACATCTACA Gm94 5630 CAGAGTCTGTAGAACAAAGG Vmnlrl91 9450 CTTCAATTCTCTAGGTTTGC Gpx5 1811 TCTTTCTCTAACCGACCTTC Arhgap21 5631 GAGGAGCTCGGGCAGAACCG Limk2 945 1 GGCGAATCCTTGGCTGTGCA Steapl 1812 TCCAGGGCTCCCTCAGCTGC Zdh cl 5632 CCCGTGTTTGGCTCTGGGAC Secl413 9452 CCCGTTGTGACCTCAGCAGC Prokr2 1813 GATCGCAGCTGCAAGCTTGG Tfap2e 5633 ATAAATATCAGGAAGTCTTG AW5519S4 9453 CAGAGTCTGTAGAACAAAGG Vmnlrl91 1814 CAGATACTACATCATCAGTC Ar 5634 TTTGGGCACATTTGTTGGTG Mytl 9454 GAGGAGCTCGGGCAGAACCG Limk2 1815 TTCAAGCAATCGACTGACGT Ttll9 5635 GACCAAGCTCCAGAAAGTGA Cldndl 9455 CCCGTGTTTGGCTCTGGGAC Sec 14 3 1816 CGCAGAACAATGCAAGCTTG Tmed4 5636 GAGTCTGAATGTGTTAGCTG Adam6b 9456 ATAAATATCAGGAAGTCTTG AW551984 1817 ATTCGCTTCCAACAGTCAAC Fezfl 5637 GTTCCGGCAGCCTTTGAATT Gatb 9457 AGTGTGGCTGATGTGCTCAC Noval 1818 AATCAAGAGTTGGGATGAGC Clvs2 5638 TTTCTAACAGTCTCCCGCTG Glib 9458 GGCCCGAGTGGACCTAGCCC Vpsl6 1819 ACACAGTAGCATTGGCTTCC Skint9 5639 AGAGTGCTCAGAAGTCAACG Runx2 9459 CCAGCTACTTTCAGAGCCTT Hnf4g 1820 ACGCGAAACCGGATAAGGAC Zscanl2 5640 CTCTCTGGTCCTCAGCTTGG Lif 9460 CTTAATCCTTCTGGGAATTC A2m 1821 TCTGACATGTTTATGGCTTC Skint2 5641 GCAAGCCCAGCTTTGAGAGC Pwwp2b 9461 ATGCCTTAGTGTATGGTGAG Herc3 1822 AGCTCCACCTGCAGCTCGAG Zfp746 5642 TACATTTCCCAGAAGCGCGG Tmem261 9462 GGGCGGAAG AAA CTTCCAAT Gdap2 1823 CGGTTACCTTCCCAGGTCTG Lrrc4c 5643 GCGCCTCAACAGACGATGAC Morc2a 9463 GAGTGACGAAGGTAGTGGCG Slc25a53 1824 GGTCTGTTCTCGGCGTTGAG Nf2 5644 TTGCCCGACCAACTACATCC Rab42 9464 CTCTCTGGTCCTCAGCTTGG Lif 1825 ACGTCCGGGCCCTCAGCCTT AU040320 5645 TTTGTGCAATGCTCTGTACA Qpct 9465 n GCAAGCCCAGCTTTGAGAGC Pwwp2b 1826 AGAGCCGAGAGAGATGCTTG Tnfrsf26 5646 TTTA ATCAAGCA GAA CAGGG Gucy2e 9466 TACATTTCCCAGAAGCGCGG Tmem261 1827 CAGCAAAGCGCCCAGTCTCT C77080 5647 GGGCCCATCCAGACCACACT Mpl 9467 GGGCTGCTCAGGTTGCTAAG Fam47c 1828 CTTCAATTCTCTAGGTTTGC Gpx5 5648 CAGGTAAACAGGTCACTCAA Mplkip 9468 n CGCTTAGCCACACCCACCCA Dctd 1829 GGCGAATCCTTGGCTGTGCA Steapl 5649 TCGGAGAATGGAATCTTCTT Mtfpl 9469 GCGCCTCAACAGACGATGAC Morc2a 1830 CCCGTTGTGACCTCAGCAGC Prokr2 5650 AATAGCAAGATTCCTCCGAA Ermn 9470 TTGCCCGACCAACTACATCC Rab42 1831 CAGAGTCTGTAGAACAAAGG Vmnlrl91 5651 AGCGCAATGGCCAGAGCCCG Pdikll 9471 b GCCTGGGCCCAGTTAGGAAA 1832 GAGGAGCTCGGGCAGAACCG Limk2 5652 AATAAACGAACTTGACCTTC Freml 9472 GCGCTAAGGATTCTGGACGC Rnpc3 1833 CCCGTGTTTGGCTCTGGGAC Secl413 5653 AAGGGAGCCTTGGTGAAGAG Stra6 9473 J TCCGTGCATAACTGCAGAGC Iars 1834 ATAAATATCAGGAAGTCTTG AW551984 5654 TCAGAGTAGACTATGCAGAG Vwa5a 9474 CCACCTCCAGCCCTGGGCGG Ptprzl 1835 TCTCCACCAATGGGAGGGCT Colla2 5655 AATAAGGACCAATTCATGCT 01frl394 9475 CAGGTAAACAGGTCACTCAA Mplkip 1836 TTTGTTTAACTAGCCATGAT Dab2ip 5656 CACAGTCTCTGAGCATTCAT Slc22al 8 9476 TCGGAGAATGGAATCTTCTT Mtfpl 1837 AGrGTGGCTGATGTGCTCAC Noval 5657 CCTGCAGCATAAACATTTCC Ifi47 9477 o AGCGCAATGGCCAGAGCCCG Pdikll 1838 TCCTGCTCGTTGGTCTGATA GnglO 5658 GCGCTACGGCAAGCCGGAGG Pdikll 9478 AATAAGGACCAATTCATGCT 01frl394 1839 ATGCCTTAGTGTATGGTGAG Herc3 5659 CCCTCAGGGAGAGCCAGTCC Fgfbpl 9479 CACAGTCTCTGAGCATTCAT Slc22al8 1840 GGGCGGAAGAAACTTCCAAT Gdap2 5660 AGGCTTCTCAGTAACAGATC Ccr2 9480 5 CCTGCAGCATAAACATTTCC Ifi47 1841 AGAGTGCTCAGAAGTCAACG Runx2 5661 GTGAGGGCCAGCCGGAGCCT Iqch 9481 o TTTCAGTTCATCAACTGCAT Dnah8 1842 GAGTGACGAAGGTAGTGGCG Slc25a53 5662 ATCTGGCCTCATTCATGAAA Thsd4 9482 4 GCGCTACGGCAAGCCGGAGG Pdikll 1843 CTCTCTGGTCCTCAGCTTGG Lif 5663 AGCCTCAGAGGCAGATGACG Map2kl 9483 AGCCAGAGAGGGAGCGGCGG Plxna4 1844 GGCGGGCAGAATAGTGGGAC Zfp593 5664 GAAGAAGGCGCTAGAACCGG Tcf7 9484 GAAGAAGGCGCTAGAACCGG Tcf7 1845 GCAAGCCCAGCTTTGAGAGC Pwwp2b 5665 CCCAGGCTGAGGAGGCGAAA D630003M2 IRik 9485 CCCAGGCrGAGGAGGCGAAA D630003M21Rik 1846 TACATTTCCCAGAAGCGCGG Tmem261 5666 CACCGGCTCAGGTGGCAGAG Itgall 9486 ATATCCTCATTATGTAATCC Osbpl3 1847 GGGCrGCTCAGGTTGCTAAG Fam47c 5667 AGAGGTCAGGGCGCAAACTC Bdnf 9487 AACCACAGTAGAATGTCCTC Diaph2 1848 CGCTTAGCCACACCCACCCA Dctd 5668 GCTGTCCAATCATAGCCAAG G3bpl 9488 GCTGTCCAATCATAGCCAAG G3bpl 1849 GCGCCTCAACAGACGATGAC Morc2a 5669 GCCGAGTCTAAGCTCGCTGC Ccdcl5 9489 GGCACTTCCCTGCTTATCAG Nrlh5 1850 TTGCCCGACCAACTACATCC Rab42 5670 CCCGAATCCCGTGGTCTCTG Mtg2 9490 AAGATGGAGCCCTTAAAGAA Plpl 1851 GCCTGGGCCCAGTTAGGAA A Kazn 5671 AGGCGGAGCAGGAGGCGAGT Nol 1 9491 AGGTAGAGTAGAACGTGGGT Prame 1852 CCACCTCCAGCCCTGGGCGG Ptprzl 5672 GGGCTCTTCCTGAATTCGGC Spal7 9492 AGGCGGAGCAGGAGGCGAGT Nol41 1853 CAGGTAAACAGGTCACTCAA Mplkip 5673 GCAGTTGTGCAGGTCTCACG Pik3ipl 9493 TAGGAGCrrTGCGGCCCGGT Kdfl 1854 TCGGAGAATGGAATCTTCTT Mtfpl 5674 ACAGGGAGAGAGCCCAGCAT Jhy 9494 GCAGTTGTGCAGGTCTCACG Pik3ipl 1855 AGCGCAATGGCCAGAGCCCG Pdikll 5675 GGGCCTGCGCGCGAATGCAA Ice2 9495 TGCAAACrGGCCAGGAGGCG Soxll 1856 GGTCTGGTCAGGAGGGCCTT Timp4 5676 GCGCGTGGTGGGAGCTCCCT TbcldlOa 9496 GCGCGTGGTGGGAGCTCCCT TbcldlOa 1857 AATAAGGACCAATTCATGCT 01frl394 5677 AAGTCCCTCGCGCCCTCTGG Dpysl3 9497 AAGTCCCTCGCGCCCTCTGG Dpys 1858 CACAGTCTCTGAGCATTCAT Slc22al8 5678 TCAGTGGTACCGTTCAAGCG Pithdl 9498 + TCAGTGGTACCGTTCAAGCG Pithdl 1859 CCTGCAGCATAAACATTTCC Ifi47 5679 ATGTCCAGCACTTTAACTCT ActllO 9499 ATGTCCAGCACrrrAACTCT ActllO 1860 GCGCTACGGCAAGCCGGAGG Pdikll 5680 TCAGAAGAGAATACAAGTCG Clk3 9500 GTGCATGTTTGCCAGGCTGC S pn 1861 AGCCAGAGAGGGAGCGGCGG Plxna4 5681 GAAGGCGGGCGCGCGCCCAT Lrig3 9501 GGGTGAGCGAGTGGAAGGCG Pcdhllx 1862 GAAGAAGGCGCTAGAACCGG Tcf7 5682 TCCTATCCTCCCAGAGGAGC Stra6 9502 ACGAAGTCGCA CA CCCACAG Epha5 1863 CCCAGGCTGAGGAGGCGAAA D630003M21Rik 5683 CATGAAGGGACTGCTTCTAC Cyplal 9503 CTATATTTAAGACGGTTACA Myom3 1864 ATATCCTCATTATGTAATCC Osbpl3 5684 GGGATGCTGCTGCTTTATTT Atp8b2 9504 ACATACCGCTCATGCCTCAC Paqr7 1865 CAGAGCCAAGGTAAGCCAAC Pla2g4b 5685 GGGCCCGGCGGACGGCGAGA Fankl 9505 TCGTCAGCTCTGGTAGGTAG Zfpl05 1866 AACCACAGTAGAATGTCCTC Diaph2 5686 AGAGAGAGAGAGAGAGAATG Grm4 9506 GCATGGCAACCGCTCTCTGA Faml79a 1867 ACACTAGCCGTCTGTTTGCC Cggbpl 5687 CTATATTTAAGACGGTTACA Myora3 9507 ACTTAGAGCGCTATGTGCCC Rps6 1868 GCTGTCCAATCATAGCCAAG G3bpl 5688 ACATACCGCTCATGCCTCAC Paqr7 9508 GCGCAGCGCGAGGCGCCTCG Glccil 1869 AAGATGGAGCCCTTAAAGAA Plpl 5689 TCGTCAGCTCTGGTAGGTAG Zfpl05 9509 GGGCGGACAGGGCGTGCGTG Gnecut2 1870 AGGCGGAGCAGGAGGCGAGT Nol41 5690 CAGTTGCGGAGAGATGGTTG Abcg4 9510 GGATGCrCTGAGGACGGCTC Bmprlb 1871 GAAAGGGCTCGGATGCCCTG Nrxn2 5691 ACTTAGAGCGCTATGTGCCC Rps6 9511 CCGGTCCTGGGCGTTCACAG M3 1872 AGAACCTCA CAGAGGAAGGG TbcldlOc 5692 GTGTCCGCACTGCCCTTCGC Pabpc4 9512 CTGAGGGrGCGCCACAAATC Satbl 1873 TAGGAGCTTTGCGGCCCGGT Kdfl 5693 GCGCAGCGCGAGGCGCCTCG Glccil 9513 n CGGGCGGCGGCCGTGCGGTG Nfia 1874 GCAGTTGTGCAGGTCTCACG Pik3ipl 5694 GCCCAGATAGCGCAACTTCG Tiaml 9514 ACTAAAGAACTACCAACCAA Trim30d 1875 TGCAAACTGGCCAGGAGGCG Soxll 5695 ATCAAATTGTAGCCTCGCCC Nes 9515 5696 9516 n ACAAAGCGATGCTAAGCATC Ssrl 1876 GCGCGTGGTGGGAGCTCCCT TbcldlOa TGTCATAGAGATTCAGTGCT 1700042G07Rik 64 GAATCTGGCAGCTCTTTAAG Cst3 1877 AAGTCCCTCGCGCCCTCTGG Dpysl3 5697 GGATGCTCTGAGGACGGCTC Bmprlb 9517 o CTATAAGAGrCGGCCGCTGC M3 1878 TCAGTGGTACCGTTCAAGCG Pithdl 5698 GCGGCGGGCTGAGTGGAGAG Maikl 9518 5 TGGTGGCAACCCGCACTGCT Mylk2 1879 GGCCGGTTCCCTGTGGGCTT Wdsubl 5699 CACTGTGTTCCTCCAGAAGT Dao 9519 64 CTTTATATTCAGGGTCTCCC Commd7 1880 GGGTGAGCGAGTGGAAGGCG Pcdhllx 5700 CCGGTCCTGGGCGTTCACAG M3 9520 5© GGCTAGCTTACCTCACAAAG Cstl3 1881 CTATATTTAAGACGGTTACA Myom3 5701 CCTTATTGGTCTGGGCCTCG Capl 9521 J 5 GTGAAGTGCCTCCAGACCAA Atpl3a5 1882 GTTGGAAGCGATTTAAACTC Suclgl 5702 GCGCAGTGCGGACCAATCAG Zbtb46 9522 GGGAGCTGCGCGGTTGTGCT Stk32a 1883 ACATACCGCTCATGCCTCAC Paqr7 5703 GGGTTGGAGCTGACAGCATG Corola 9523 AAATGCGCCAAGTAGCCAGA 4921536K21Rik 1884 TCGTCAGCTCTGGTAGGTAG Zfpl05 5704 CTAGGGCATTGGAACCACTA Traem225 9524 AGAGCGGAAGTTATGGCGCG Zbtb8os 1885 GCATGGCAACCGCTCTCTGA Faml79a 5705 CTATAAGAGTCGGCCGCTGC Id3 9525 o CTTAACTGCTCATGCGCGCG Gml6432 1886 ACTTAGAGCGCTATGTGCCC Rps6 5706 TGGTGGCAACCCGCACTGCT Mylk2 9526 TGGCCTGACCrrCGTGTAGC Uqciq 1887 GCGCAGCGCGAGGCGCCTCG Glccil 5707 GCGCGCTCCCGACTCCCrCT Dap3 9527 TCCGTCATATCCCGTCCTCG Btnl9 1888 GCCCAGATAGCGCAACTTCG Tiaml 5708 CTTTATATTCAGGGTCTCCC Commd7 9528 5 TGAGCCCAGTGAAGTGGGCG Irs4 1889 CTCTATGGTAGGCCAGCAAA ZkscanS 5709 GGGAGCCCGGCGAACCAATA Bsx 9529 o AGCGGCGTCTTCCAGTGCCG Nupl55 1890 CCGGTCCTGGGCGTTCACAG Id3 5710 CAGCTGGCTGAGGCACTTGG Cd2ap 9530 GGGATGCCGGCGGGCTGGCT Onecut2 1891 CGGGCGGCGGCCGTGCGGTG Nfia 5711 GGGAGCTGCGCGGTTGTGCT Stk32a 9531 CCGGACAAGGATGCTGCAGC Dpysl3 1892 ACTAAAGAACTACCAACCAA TrinBOd 5712 AAATGCGCCAAGTAGCCAGA 4921536K21Rik 9532 CCAGACACATTGATGT AGGG Bsdcl 1893 ACAAAGCGATGCTAAGCATC Ssrl 5713 CGAGGAGTATGCCGCACTTC Uqcrh 9533 TTGAACAGGATCGTCCAAGG Sugct 1894 GAATCTGGCAGCTCTTTAAG Cst3 5714 GGGCTGCTTTACCTCCCACC Clmp 9534 CGCCGCGGCGCGTCACTGCC Nol41 1895 CTATAAGAGTCGGCCGCTGC Id3 5715 CTTGTCACTCAGAACTGCCC Enpp5 9535 AGCCCTCAGCTGGCGGCGTG Pesl 1896 TGGTGGCAACCCGCACTGCT ylk2 5716 TCCATTAATTACTTGGAGGG Commd4 9536 CGGGTCTGCGCACCGCACGG Dabl 1897 CTTTATATTCAGGGTCTCCC Commd7 5717 TTCGCAGACAGGCGTGCG GA Pearl 9537 TGATCTCTCTGTGCTTTCTA Slc30a8 1898 GGCTAGCTTACCTCACAAAG Cstl3 5718 AGAGCGGAAGTTATGGCGCG ZbtbSos 9538 TCATTTAAAGGGATAGGCTC K td 1899 TAAACGGAGCTTCTATTGGC Cep41 5719 TGGCCTGACCTTCGTGTAGC Uqciq 9539 CTCCTTTCTGGCCGTTACCA Tnpo3 1900 GGGAGCTGCGCGGTTGTGCT Stk32a 5720 TCCGTCATATCCCGTCCTCG Btnl9 9540 GACAGTTTGATATGAGCTCC Tspan32 1901 AAATGCGCCAAGTAGCCAGA 492 1536K21Rik 572 GTCGCCGCCTCCGTGCGCGC March5 9541 CCCATGAGCCCAGTGACTCC Adig 1902 GGTGTTGTACTGTCTGGTTC Spin4 5722 TTTGTCGTGGCAGGATCATG Clk3 9542 GGGAGAGTCAGACGCTGGAG Smo 1903 AGAGCGGAAGTTATGGCGCG Zbtb8os 5723 GGAAGGGTCAGGGTAGGCTA Gpatch2 9543 CTGGATCGCCGGCCGAAGAA Plaa 1904 TGGCCTGACCTTCGTGTAGC Uqciq 5724 TAACTGGCACCGCCCTGCGG AbcaSb 9544 AGACGTGCTCTGAAGACTAC Dna 9 1905 TCCGTCATATCCCGTCCTCG Btnl9 5725 CCGGACAAGGATGCTGCAGC Dpysl3 9545 CACGTGACCGTCGCCTCACG Irs4 1906 GCTCCTCCCAGCACCTCACG Tc2n 5726 CCAGACACATTGATGTAGGG Bsdcl 9546 4 GACGAAGCCAGAGTCCCGGG Mme 1907 CCGGACAAGGATGCTGCAGC Dpysl3 5727 GGCGCGAGCGAAGGGACCTG Dis31 9547 AACCGATTAGCTGTTTAATC Cngb3 1908 CCAGACACATTGATGTAGGG Bsdcl 5728 TTGAACAGGATCGTCCAAGG Sugct 9548 CGCGCGCGGAACATGGCTGA Unc80 1909 CCAAGGCTCTGCGACTAGGA Arhgap28 5729 CGCCGCGGCGCGTCACTGCC Nol41 9549 TCAGGCTACAGGCTGGGCCT Dus l 5 1910 TTGAACAGGATCGTCCAAGG Sugct 5730 AGCCCTCAGCTGGCGGCGTG Pesl 9550 ACGCCTAGACACCGACTTAA Pclo 1911 CGCCGCGGCGCGTCACTGCC Nol41 5731 GACAGTTTGATATGAGCTCC Tspan32 9551 TGATGGCCTAGTTACTGCCA A2ra 1912 AGCCCTCAGCTGGCGGCGTG Pesl 5732 AGCGGCGGTGACGAAGCGCC Htral 9552 GACTCACTGTAGGGTTGGTA I15ra 1913 CGGGTCTGCGCACCGCACGG Dabl 5733 CCCATGA GCCCAGTGACTCC Adig 9553 ACGAAGTGATCTGTAATAAA Ave 1914 CTCCTTTCTGGCCGTTACCA Tnpo3 5734 TCCTGCTAGACCGCCATCTG Dsc2 9554 GAGGTTGCCAAGAACTCTCT Speer4e 1915 GACAGTTTGATATGAGCTCC Tspan32 5735 TGCTACTTCTGGTCTATCAG Ppdpf 9555 TAGGAAACTGAAGCTCGGGC Repinl 1916 TACACACACCCTGCAGGAGG Wdi64 5736 TCACAAGGAGCACGAGCTCT Paivg 9556 AAATGACACCAGGGCAACGT Tlrl2 1917 CTGGATCGCCGGCCGAAGAA Plaa 5737 CTGGATCGCCGGCCGAAGAA Plaa 9557 GATGCTTCCAGGGCAGCCCG Pla2g3 1918 AGACGTGCTCTGAAGACTAC Dnah9 5738 AGACGTGCTCTGAAGACTAC Dnali9 9558 AATGTT CTTCGGTCCAATAG HistllBb 1919 TGTGAGGGACGGAGCAGTAA Krbal 5739 CTCAAGCTAGAAGCTATATA Flg2 9559 AGAACTAAGTGCTAATGGAA CstlO 1920 TCAGGCTACAGGCTGGGCCT Duspl5 5740 TATATAAAGAGTTGTGGGTC Kprp 9560 CTGGTCGTTGGrGGACTTTG Gp b 1921 GACTCACTGTAGGGTTGGTA I15ra 5741 TCAGGCTACAGGCTGGGCCT Duspl5 9561 n CGAGCACGACAAGAGCGCCT Pttgl 1922 GAGGTTGCCAAGAACTCTCT Speer4e 5742 GAGGTTGCCAAGAACTCTCT Speer4e 9562 TAGCGCCTCTGAGCGGAGCG Rockl 1923 TAGGAAACTGAAGCTCGGGC Repinl 5743 TCCTGCACTCAGGAAGTGGG Traem69 9563 ACTGCCCTCGCATACCTTTA Nudtl2 1924 TGATCTAAGCATCCTTCCGG Pcedla 5744 AAATGACACCAGGGCAACGT Tlrl2 9564 n GCATCTCCACCTTGGGAGGT Hpca 1925 GGGCCCTCCACTTGGGCTGC Ank2 5745 GGAGCTAAATCCCTCTGCTG Adam6b 9565 o GCGCCCGTCGTCTAGGCGAG SlOOpbp 1926 AAATGACACCAGGGCAACGT Tlrl2 5746 CAGATCATGAGTCAGCGCGG Slc37a2 9566 AAGACTGGCTGAGTCAATCC C77080 1927 GATGCTTCCAGGGCAGCCCG Pla2g3 5747 GATGCTTCCAGGGCAGCCCG Pla2g3 9567 b GGCCCAGGAGCGCCTCTGAT Esrrg 1928 AATGTTCTTCGGTCCAATAG HistllBb 5748 AATGTTCTTCGGTCCAATAG HistllBb 9568 CAACCAATGGCTGGCCGCCT KlhdclO 1929 GAAGCAGCATAAGAAGAGAG Hgf 5749 ATCTGACCTGGTGACACGTG Adaml9 9569 J CAGGGCGAGGAAGCTCGGGA Dnmt3b 1930 GGGCAAAGGCACCTGAGGTT Sstr4 5750 TTCAGAGGCACGTGCGAAGT Etv3 9570 ACCATCGGGCCAGGCCTCGG RhbdcB 1931 AGAACTAAGTGCTAATGGAA CstlO 5751 GAAGCAGCATAAGAAGAGAG Hgf 9571 CCGCCCGGAGACCGCCATGA Nrfl 1932 CTGGTCGTTGGTGGACTTTG Gpnmb 5752 CGAGCACGACAAGAGCGCCT Pttgl 9572 TCAGAAGCGCAGAAACTTCA Sfil 1933 GAGTCCACGCCCGCGACCGT Mpz 5753 GCATCTCCACCTTGGGAGGT Hpca 9573 o AGCTCTGTCTTTCAGGAGCT Trim30d 1934 AAACGCCCAGGGAAGGTGGC Psap 5754 TTGCTTCCCTGGTCCAGACA Islr 9574 TTCTCGGGCACACAGGAGGC Colllal 1935 CGAGCACGACAAGAGCGCCT Pttgl 5755 GCGCCCGTCGTCTAGGCGAG SlOOpbp 9575 GTTCCCACCTACACTGTTAG Kl 1936 GCATCTCCACCTTGGGAGGT Hpca 5756 TCTTTCTCTGAGTTTGGGAG Cypllal 9576 CCCAATTTGGAACGAAGAGG Collal 1937 GCGCCCGTCGTCTAGGCGAG SlOOpbp 5757 AAGACTGGCTGAGTCAATCC C77080 9577 o CTCGGATCTTGGTTCCCTTG Wbscrl7 1938 AAGACTGGCTGAGTCAATCC C77080 5758 GGCCCAGGAGCGCCTCTGAT Esrrg 9578 4 AGGAGTGCGCTGAGACGAAG Sorbs2 1939 GGCCCAGGAGCGCCTCTGAT Esrrg 5759 CAGGGCGAGGAAGCTCGGGA Dnmt3b 9579 CCAGCCGAAGCCCTGCAAGC Itgav 1940 CAGGGCGAGGAAGCTCGGGA Dnmt3b 5760 ACCATCGGGCCAGGCCTCGG Rhbdd3 9580 CTGACAGATGGTCCCATAAA Elavl4 1941 ACCATCGGGCCAGGCCTCGG Rhbdd3 5761 TCAGAAGCGCAGAAACTTCA Sfil 9581 ATCCAGGGAGGCGTGTCCAG Dsel 1942 CCGCCCGGAGACCGCCATGA Nrfl 5762 CTTTCTGCATACAGTGGTGG Pig 9582 GCATCTGGCTGCAGTGAGAG Fbxw24 1943 TCAGAAGCGCAGAAACTTCA Sfil 5763 ATCCAGGGAGGCGTGTCCAG Dsel 9583 GTAATCCATCCTGAGATTTG H13 1944 AGCTCTGTCTTTCAGGAGCT Trim30d 5764 GTAATCCATCCTGAGATTTG H13 9584 CTGCTCACAGCAGGTAGAAC Nme8 1945 TTCTCGGGCACACAGGAGGC Colllal 5765 TCTGGGAGTTGAGACACAGG Pi4k2b 9585 CACCGGCTCTAGCAGCACGC Topi 1946 CAGAGTGTCAGTCAAGGAGT Mpp7 5766 TGGGAGGGCGCGGTACAGAA Cul7 9586 GTGTCTGCCTGTCCTCTCCG Lrrtm4 1947 GTTCCCACCTACACTGTTAG Klhl4 5767 CTGCTCACAGCAGGTAGAAC Nme8 9587 ACACAATGAGTTCCACATTG Pramef25 1948 CTCGGATCTTGGTTCCCTTG Wbscrl7 5768 ATTGGCCTACAGCGTGCCGG Nmur2 9588 ATTGGCCTACAGCGTGCCGG Nmur2 1949 AGGAGTGCGCTGAGACGAAG Sorbs2 5769 GCGGTCGGCTCCAAGCTGGT Mga 9589 AAGAGTTCTTAATACTCCAG Mucl5 1950 CTGACAGATGGTCCCATAAA Elavl4 5770 GATTGCCACGTCGCCAGCAG P3hl 9590 CTGAGCTCGTGGGACAGCCT Ί 2 1951 ATCCAGGGAGGCGTGTCCAG Dsel 5771 CTGAGCTCGTGGGACAGCCT Tlrl2 9591 TTCTATACCAGCTGTTGCTC Tspan32 1952 GTAATCCATCCTGAGATTTG H13 5772 TTCTATACCAGCTGTTGCTC Tspan32 9592 GTCATTCAGGATGAAGGAAC Timd4 1953 CTGCTCACAGCAGGTAGAAC Nme8 5773 GTCATTCAGGATGAAGGAAC Timd4 9593 ACAGGAGGGTAAGATTCGTG Slc26a4 1954 GTCAGCCACCAGGGAACGTG Fam50a 5774 GGTGACCACCGGGCAGGAAG Gbel 9594 + ACATGCACTTCCCGCCAATT Phflld 1955 ATCCAGCTGTGGTGTGCGCC Cacnalg 5775 GGCTGGCAATCTGCTAACAG 1700001C19Rik 9595 ACGCCGCCACCGAGGCGCAG Manla2 1956 CTGACTCCAGCATTAGCTTA Pla2g4b 5776 GTTCTGCGGCTTGAGAGTCA PpplrlS 9596 ATGGGTTCTTTCGTGACGTC Smarca2 1957 TCCTTTAGCATGTCATTAGT Foxil 5777 TTCTTCCTGAAGGCAGAGAC 58304 HN06Rik 9597 AGTGGGCGCGCTAAGAGATG Acsll 1958 ATTGGCCTACAGCGTGCCGG Nmur2 5778 CTTTGGCGATTGGTCCAGCG Iqsecl 9598 TGAGTCAGGGTCAAACAGCA Itili2 1959 CTGAGCTCGTGGGACAGCCT Tlrl2 5779 TCACCGCGGGAATCCCAGGG N p2 9599 ATTCCCAATGCCTATGTAAA Calr4 1960 TTCTATACCAGCTGTTGCTC Tspan32 5780 ATGGCACCTGCCCACGTGCC Slcl2a5 9600 AATCGAACATGCACTGTTAT Enpp2 1961 GTCATTCAGGATGAAGGAAC Timd4 5781 CGGAACCGTGGTCCCACTTC Isg2012 9601 TTCTTCCTGAAGGCAGAGAC 583041 lN06Rik 1962 ACGCCGCCACCGAGGCGCAG Manla2 5782 CACCTGCGCAGTACGCTGCG Sycel 9602 TCACCGCGGGAATCCCAGGG Nhp2 1963 ATGGGTTCTTTCGTGACGTC Smarca2 5783 AGTTAAAGTTGCTGAAACCA 114 9603 CACCTGCGCAGTACGCTGCG Sycel 1964 AGTGGGCGCGCTAAGAGATG Acsll 5784 AAGTAAGAAGGTAAACACCT Hrnr 9604 TGCCAAGTGGGCAGTTCTCC Sardli 1965 ATTCCCAATGCCTATGTAAA Calr4 5785 GCGCGAAGAGAGACAGAAGC Mstol 9605 CGCACGAGGGTTGGGCACGT Lrrc63 1966 TGCCTTGGCTAGCAGTCGCC Ka k l 5786 GCCTGGAAACTCTGGCACCA Kpip 9606 AGTTAAAGTTGCTGAAACCA 114 1967 GCTCAGCTTCCCTCTGTCTC Lmo2 5787 CCTGGCCATATGAGAAGTCC Polm 9607 AAGTAAGAAGGTAAACACCT Hnir 1968 TTCTTCCTGAAGGCAGAGAC 5830411N06Rik 5788 TTGAAAGGGAAGCTGGCGAG Nipsnapl 9608 GGCTCGTCGCCGGGAAGGGC Kat6a 1969 TCACCGCGGGAATCCCAGGG Nhp2 5789 GAGGAACTAGGTAGGCGAGG Utfl 9609 n AGAATTGGCTAATAGGCCAC Abcal3 1970 CACCTGCGCAGTACGCTGCG Sycel 5790 TTCACTTGGAAGTCCCTTTA Bcl211 9610 ATCTCGCAGATGCAGACGAC Dnah7a 1971 AGTTAAAGTTGCTGAAACCA 114 5791 GCCGTGGGCGGTCTAGGGAG Gabbrl 9611 CCTGGCCATATGAGAAGTCC Polm 1972 GCCTCAGGTTCCAGCAGTTT Kmt2d 5792 TGCGAGCTAGACGGCGGCGA Runx2 9612 n TTGAAAGGGAAGCTGGCGAG Nipsnapl 1973 GGCTCGTCGCCGGGAAGGGC Kat6a 5793 CCGTAGCCGCCGTGCCCTTT Eif4enifl 9613 o GGCTTTGCACTGATGCTAGG Pde4b 1974 TGTAGTCCACAGTGGAAACC Zfp879 5794 TCTTTAAGCAAGAGGAGGCG Slc36a2 9614 GAATCATGATAAACCTACCA Spink 14 1975 TCACGATAAGATGGGCGTGG 1700001P01Rik 5795 CCACCGGCTACCCTTCCGGC Lirc4c 9615 b CTGGGCTCCACrCACGAACC Nkx2-2 1976 CCTGGCCATATGAGAAGTCC Polm 5796 CTCAGGCGTGCGACGTGAAC Meal 9616 GAGGAACTAGGTAGGCGAGG Utfl 1977 TTGAAAGGGAAGCTGGCGAG Nipsnapl 5797 AAACATACATTTGAAGGACC Cede 17 9617 J ACCGTGAACACCACTGTGCG Gdap2 1978 GGCTTTGCACTGATGCTAGG Pde4b 5798 CTGTGAGGATTTCACACCCA Fstl5 9618 CGTGGGCGAGCCGACAGCGG Btbd7 1979 GAATCATGATAAACCTACCA Spinkl4 5799 CACTGCCCATCACAAACTGC Skorl 9619 TTCACTTGGAAGTCCCTTTA Bcl211 1980 CTGGGCTCCACTCACGAACC Nkx2-2 5800 ACCGATCCGTCTCTAGGCAG Gpn2 9620 CCGTAGCCGCCGTGCCCTTT Eif4enifl 1981 GAGGAACTAGGTAGGCGAGG Utfl 5801 ATCGCCTAGGACTAAGGGAT H13 9621 o AACTGCGGGTGTAGCTGCCA A830018L16Rik 1982 TATAAGGATATGCCCTATGG 4931440F15Rik 5802 TGGGTGGAGCCCAACCACAG Dennd4c 9622 TCTTTAAGCAAGAGGAGGCG Slc36a2 1983 ACCGTGAACACCACTGTGCG Gdap2 5803 GGCTGAGGTGAGAACCGCGA Man2cl 9623 CCACCGGCTACCCTTCCGGC Lrrc4c 1984 GCGTTTAAACAGACCGGAAG 2 10020H08Rik 5804 TAGCAGGCGTCAGGCAATCC Kremenl 9624 CTACTTATCAGTTCTCAATC Rps6ka6 1985 TTCACTTGGAAGTCCCTTTA Bcl211 5805 GTGCGAGCACGAGCAGTTTG Ubl7 9625 o CTGTGAGGATrrCACACCCA Fstl5 1986 TGCGAGCTAGACGGCGGCGA Runx2 5806 TTGTGTGCTTACGGGCTCCC Fbxw7 9626 4 TTAGACCCTCTTCATCTGAT Sorbs2 1987 CCGTAGCCGCCGTGCCCTTT Eif4enifl 5807 AGTGGACTACAAGTCCCGTG Phactr4 9627 AACTAAGAGATCTCTAATCT Opnlsw 1988 TCTTTAAGCAAGAGGAGGCG Slc36a2 5808 CGGTACCCATTCTTCCTTCC Nlixl 9628 ACCGATCCGTCTCTAGGCAG Gpn2 1989 CCACCGGCTACCCTTCCGGC Lrrc4c 5809 TCTCGCCATGACTCAGCACG Dst 9629 ATCGCCTAGGACTAAGGGAT H13 1990 CTACTTATCAGTTCTCAATC Rps6ka6 5810 GGAACAGGTAGAAGAATACA Dt a 9630 CTTCATGGAGArrGTTGCTA 1700012A03Rik 1991 TTAGACCCTCTTCATCTGAT Sorbs2 5811 GCCGCTGGTCCCTGAAGTCC Skorl 9631 TGGGTGGAGCCCAA CCACA G Dennd4c 1992 AACTAAGAGATCTCTAATCT Opnlsw 5812 CAGACCTCTAGGCTCCACTG Bpi 9632 TAGCAGGCGTCAGGCAATCC Kremenl 1993 ACCGATCCGTCTCTAGGCAG Gpn2 5813 CCCGAGGGAGCGGTGGGAGG Lcorl 9633 CCTGATGTCATGGAGTCCTG Fhadl 1994 ATCGCCTAGGACTAAGGGAT H13 5814 CCCAGCGCGTAGCCTCCACT Ddrl 9634 TTGAATTTGACGGGAAGTGT Nlgnl 1995 CTTCATGGAGATTGTTGCTA 1700012A03Rik 5815 CCTTCACAAACGACACCCAA SlOOal 9635 TCCACTGCGGACGAATCCCG Ncam2 1996 TGGGTGGAGCCCAACCACAG Dennd4c 5816 GACTGGCTAGAGAGCGACTC DusplS 9636 AGTGGACTACAAGTCCCGTG P a tr4 1997 TAGCAGGCGTCAGGCAATCC Kremenl 5817 CCCTACTGCAGTGGGATACG Psmb4 9637 TCAATGCACTTCCTGTAGCC C n l 1998 CCTGATGTCATGGAGTCCTG Fliadl 5818 CCGACGTCGCTTTCACTTCC Plekha3 9638 CAGACCTCTAGGCTCCACTG Bpi 1999 TCCACTGCGGACGAATCCCG Ncam2 5819 AGTAGCTTGCTGCATTTCTC Col9al 9639 GGGCAGATGTATCAGAGTGC Lactbll 2000 AGTGGACTACAAGTCCCGTG Phactr4 5820 AATGTAGCATTGAAAGGGCC Zpldl 9640 GTTAGCCAATGGCACGGCGG Viprl 2001 CAGACCTCTAGGCTCCACTG Bpi 5821 GTGTGTGTTGGTTAGTGACT Lrplb 9641 GACTGGCTAGAGAGCGACTC Dus l 2002 GAGAAGGGCCTCCAGTCCC A Steap2 5822 CTTATCAACACATCTACCTC Bpifb9a 9642 CTGTGCAAAGCTGAGGTTCC C8b 2003 GGGCAGATGTATCAGAGTGC Lactbll 5823 AACCTTCCTAGTTTCAGAGA Trcgl 9643 CCTCAGGCCGCGCTCCCTGA Hfml 2004 GTTAGCCAATGGCACGGCGG Viprl 5824 GTAGGACTGAATATAGTTTC 2310061I04Rik 9644 AGTAGCTTGCTGCATTTCTC Col9al 2005 GACTGGCTAGAGAGCGACTC DusplS 5825 GACCATTGGGCGTGCGGCGG Zyglla 9645 GTGTGTGTTGGTTAGTGACT Lip l b 2006 CTGTGCAAAGCTGAGGTTCC C8b 5826 TTGCCAGGAATGGCAAACGC 1190007I07Rik 9646 CTTATCAACACATCTACCTC Bpifb9a 2007 CCGACGTCGCTTTCACTTCC Plekha3 5827 CGGAGGAGTCTAGCAAATAG Vps8 9647 CTAAATTGGrrGCATTCAAA Svsl 2008 GTGTGTGTTGGTTAGTGACT Lrplb 5828 ACTTAAGTTCTATGTGATTC Slc24a2 9648 TGGGAGGAACTAAAGTTGAC Ky u 2009 CTTATCAACACATCTACCTC Bpifb9a 5829 TATTACAGGAGTGTCATCCA Stmn3 9649 ACTTAAGTTCTATGTGATTC Slc24a2 2010 CTAAATTGGTTGCATTCAAA Svsl 5830 GCCGCGGACCGTGAGACGCG Wdtcl 9650 CAAGTAAATCAGCTTAGCAC Klhl4 2011 ACTTAAGTTCTATGTGATTC Slc24a2 5831 TATTGTGTGGAATTGCAGGC Prkd3 965 1 GCGACGTCCCTCCGACCGAT Mall 2012 CAAGTAAATCAGCTTAGCAC Klhl4 5832 GCGGGACGGCCGCGTGCCCG Plekha3 9652 CTGGA GAGCACTC AGACCGC Cntnap2 2013 GCGACGTCCCTCCGACCGAT Mall 5833 AATGCGCGGAATTCTGATTC Bdnf 9653 GCCGCGGACCGTGAGACGCG Wdtcl 2014 CTGGAGAGCACTCAGACCGC Cntnap2 5834 CCGCCTCTGGGCTGACTGCA Adralb 9654 CCGCCTCTGGGCTGACTGCA Adralb 2015 GGTCGCCGGCCTGTGTGGCA Fail 5835 ATCAAACTCTCAGAACCCAG Map4kl 9655 AAACAGTGTAGGTGGAGCTG Yars 2016 GCCGCGGACCGTGAGACGCG Wdtcl 5836 AAACAGTGTAGGTGGAGCTG Yars 9656 CTGCTGTGCACACCTGGACC Kcnkl5 2017 GCGGGACGGCCGCGTGCCCG Plekha3 5837 TTAACAGTTTGACTAATCCG Dmbtl 9657 n GTTGCAGGAACACGGCTCAC Gripl 2018 CCGCCTCTGGGCTGACTGCA Adralb 5838 GCCTTTGGTAAACTCACCAA Dtna 9658 CTCTGCGCGGGATGACGCCC Shank2 2019 AAACAGTGTAGGTGGAGCTG Yars 5839 GCCTAGTGGGCAATGAACCA Cdl9 9659 AACGAGCCGGAGCTAGTGGT Gnaz 2020 GTTGCAGGAACACGGCTCAC Grrpl 5840 TGACAGCAGCAACTCAAGTC Bodll 9660 n CATTTACATCACAATTGGGC Tssk3 2021 CTCTGCGCGGGATGACGCCC Shank2 5841 CAGATGTGCTGAGTTCAGCA Cd51 9661 o AGAGCGCGGCGAGCAGCGAG Satbl 2022 ACTTCCTCATTCACCTTATA Itgb6 5842 CATTTACATCACAATTGGGC Tssk3 9662 AACCGGAGCAGGCAGGACTG ZfpSOO 2023 GTGGTAATTTACCTGGAAGT Wdsubl 5843 GCTCAGCTTTGTTGGTTTCG Nr2f2 9663 4 TGAGATGCGTGGAGGGATGG Slcl5a4 2024 CATTTACATCACAATTGGGC Tssk3 5844 CTCTGCCTACTGTGCAGCCC Tbcld9b 9664 TTTCAGTCCTACCAGAGCCA Shank2 2025 AACCGGAGCAGGCAGGACTG Zfp800 5845 GGCGTAAGGAAGGCGTCCCG Pi4k2b 9665 J AAGTTAGTTAGTGACAGTGT Qsc 2026 TTTCAGTCCTACCAGAGCCA Shank2 5846 TGAGGATGACCAACACAGCA Bpifa3 9666 CTCTGCCTACTGTGCAGCCC Tbcld9b 2027 CTCTGCCTACTGTGCAGCCC Tbcld9b 5847 AGACGGACTTAAGCGACAGC Gm7 4 9667 TGAGGΑΓGACCAACACA GCA Bpifa3 2028 AAGACTGATATTTCCTGAAG Noxl 5848 TTTCCCGCCATTGTGAGAAG Mcmbp 9668 AGACGGACTTAAGCGACAGC Gm7534 2029 TGAGGATGACCAACACAGCA Bpifa3 5849 TTTAATGTTGGGTGGTGATG A3galt2 9669 o TTTAATGTTGGGTGGTGATG A3galt2 2030 AGACGGACTTAAGCGACAGC Gm7534 5850 ACTTGAGAAATAACTAGGAG Dsc3 9670 AAACTATATGCCGCCAAATT E2f2 2031 TTTAATGTTGGGTGGTGATG A3galt2 5851 AAACTATATGCCGCCAAATT E2f2 9671 GCTGGATAGGGCGTGTCTCC Raver2 2032 AAACTATATGCCGCCAAATT E2f2 5852 TGGGTCTTCCGCGGTTGCCA LsmlO 9672 TCTGCTCACGCTACATGGTG Prapl 2033 TGGGTCTTCCGCGGTTGCCA LsmlO 5853 CTCAGGAGCTGTTACTCTAG Sult6bl 9673 o ATATGTCACCATGTAGATAG Nal 2034 GCTGGATAGGGCGTGTCTCC Raver2 5854 GGACAGACAGGACATATGAG Gm7616 9674 4 GCACATCTAGAGGAGATTTC Cpxcrl 2035 TCTGCTCACGCTACATGGTG Prapl 5855 TTTCTGTAAGAACAGAGGAA Fgfbpl 9675 TGACTTTAGTCCATTGGAAG Cd55b 2036 GCACATCTAGAGGAGATTTC Cpxcrl 5856 ATACAGATAGATTGGCTAAG Ubd 9676 CAGTATTGGTTTCTGTGGCC Op ls 2037 AGGGCGAGGTGTGCGCGAAG Sorll 5857 AAATGGGCGTGGTCGAGGGC Celf6 9677 ATGGAACAAGGAGGATCTAG CstlO 2038 CAGTATTGGTTTCTGTGGCC Opnlsw 5858 TCTGCTCACGCTACATGGTG Prapl 9678 GCACTCCGGCTGTGATTGCT Bend5 2039 ATGGAACAAGGAGGATCTAG CstlO 5859 GTTCATGCATGTGCCCACTC Traem69 9679 GATCTGCGCCGCTCCGCCCT Vdacl 2040 GCACTCCGGCTGTGATTGCT Bend5 5860 AGGGCGAGGTGTGCGCGAAG Sorll 9680 AGTTTGAGCAGTGGCCATCG Scml2 2041 GATCTGCGCCGCTCCGCCCT Vdacl 5861 AAGTGCGGACTGCACAGGCA Selenbpl 9681 CACTGGGCCGCGACCCTCCC RasllOa 2042 TAATTCATCTTGTCTGGCTG 5430401F13Rik 5862 GTTATGATGGCAGACCAGAA Bdkibl 9682 GGCTTCCGGAAGCCGTCCCG Mcm8 2043 CACTGGGCCGCGACCCTCCC RasllOa 5863 CTGCCAGCTTCTCCAGGTTT Eif2ak2 9683 GTGGAAATAGGCGCGCTCCC Tm9sf4 2044 GGCTTCCGGAAGCCGTCCCG Mcm8 5864 GATCTGCGCCGCTCCGCCCT Vdacl 9684 CTTTGTAACAACCATGCATT Oprml 2045 GTGGAAATAGGCGCGCTCCC Tm9sf4 5865 CGCCCTGAGCCGAAGACTCC Ano5 9685 ATTGGGCCGCGCCAGTGACT Psmb2 2046 ATTGGGCCGCGCCAGTGACT Psmb2 5866 CTCCAAGTGGCCAGGAAACG Cdh2 9686 CGGACCCTAGGCGCGGGCGG E2fl 2047 CGGACCCTAGGCGCGGGCGG Ε2 5867 CGAAGACCACACTTCCGTAG Reel 14 9687 ACTGCGECTTCCCGTCGCCC Spe 2 2048 AATTGCCCTTCTGGCTAGAG Slc22al8 5868 GGCTGCCTATCATAAGTGCC Gnal 9688 AATTGCCCTTCTGGCTAGAG Slc22al8 2049 AATCTAGTGCGCATGCTCTT Hmmr 5869 CACTGGGCCGCGACCCTCCC RasllOa 9689 AATCTAGTGCGCATGCTCTT Hmmr 2050 CTGGTGTGGACTGGAAGCGC Dnajcl6 5870 GTGGAAATAGGCGCGCTCCC Tra9sf4 9690 + CTGGTGTGGACTGGAAGCGC Dnajcl6 2051 CAACTAAGAAAGCTGGTGCA Timd2 5871 GCAAGATCTTGTCAATAACC Scgblb3 9691 GAAGTTGGAGCTGCTGAACC Gabip 2052 AAGGGTACTTTCAAAGTGCC Itgal 5872 ATTGGGCCGCGCCAGTGACT Psmb2 9692 CAACTAAGAAAGCTGGTGCA Timd2 2053 GGCGCAGCGTCATGACGTCA Ce pe 5873 CGGACCCTAGGCGCGGGCGG E2fl 9693 AAGGGTACTTTCAAAGTGCC Itgal 2054 AGTCTGTGCGCGCATCCCGC Mtfrll 5874 CAAGCCCACTTATTAGCCAG Kcnn3 9694 ACCTAGACAATTAGTTCTTG Cntn6 2055 AAGGATGCAGGGTTAGGAAA Propl 5875 AATTGCCCTTCTGGCTAGAG Slc22al8 9695 ACAGCGGGTGCACCGCGATG Shisa3 2056 AAGGCGTGGCCTCACCAGAG Utfl 5876 AATCTAGTGCGCATGCTCTT Hmmr 9696 AAAGGCATAGCCCAGATTAA Prex2 2057 GGAGGCACCCAGATCTGCAC AdcyS 5877 ATATATCCCGTGGCGGAGCG Sin3a 9697 AGTCTGTGCGCGCATCCCGC Mtfrll 2058 GGGCAGCTAATCCCGCAGGG Lmo2 5878 TCCCAGTTCCTCTTCCACTG Bstl 9698 AACAGGGACAGGCGGTGAGA Lhcgr 2059 TGCACTAATCTGGCTTCCAA SeptS 5879 TCGGCGAGGCTGGAGGACGC Atp8b2 9699 AAGGATGCAGGGTTAGGAAA Propl 2060 GAAACGGGCTTCTGTCTGAT Chd6 5880 CAACTAAGAAAGCTGGTGCA Timd2 9700 TCAACTGTACCATAACCCTC Cd84 2061 GGCGCAACAGCAGAAGGAGG Arf5 5881 TGGGCAAGCCGATCAAAGCA Blocls2 9701 AAGGCGTGGCCTCACCAGAG Utfl 2062 ACCTGATACCCAACAAAGAC Pgbdl 5882 GGGAAATCTTCCTAGGGCCA Helz2 9702 GGAGGCACCCAGATCTGCAC AdcyS 2063 TAACAGAGATCAGTGTTTGA Nme4 5883 AGTCTGTGCGCGCATCCCGC Mtfrll 9703 GACTCTGGGCCAACGAGGTG Adgrdl 2064 GGACCTGGGTTGAGATGAAC Rps6ka6 5884 AAGGATGCAGGGTTAGGAAA Propl 9704 TGCACTAAECEGGCTTCCAA Sept 2065 GCCCGACTTCCGCTTAACCC Rps6 5885 AAGGCGTGGCCTCACCAGAG Utfl 9705 n GCAGGCTrCAACTGCATTCC Zcc 3 2066 AATTATAAATACCCTACGGC Nrfl 5886 TGCACTAATCTGGCTTCCAA Sept8 9706 GAAACGGGCTTCTGTCTGAT Chd6 2067 AATG CAGTGTCTTAAGCCC Faml99x 5887 GGGAACCTGTTGCGTCCTCT Proml 9707 GGCGCAACAGCAGAAGGAGG Arf5 2068 TGAGCCATTGTTATCATCCC Stl8 5888 GAAACGGGCTTCTGTCTGAT Chd6 9708 n ACCTGATACCCAACAAAGAC Pgbdl 2069 AAGCCACGCCCATCCTCAGA Rhbdd3 5889 TGGGCTCAGAACCTATGCCC Corola 9709 o GGACCTGGGTTGAGATGAAC Rps6ka6 2070 TGTTTGGATGACACGCCTTT Ttll9 5890 AAATCAGCGTCCGGGCACGC Tbx3 9710 GCCCGACrrCCGCTTAACCC Rps6 2071 GGCTAGTGCCTGGCGTAGCC Pcdhl9 5891 ACCTGATACCCAACAAAGAC Pgbdl 9711 b AATTATAAAEACCCTACGGC Nrfl 2072 TCAGCAAGAGTTAACCTAGG Grrpl 5892 CGCCGCCGGGCAGGAAAGAG Pearl 9712 AATGTCAGEGECrrAAGCCC Faml99x 2073 ACCTGCACTAGACGCGTCAT Abcal2 5893 AGTTGGAACTTCAGAGATGA Islr 9713 J GGAGACGAAAGCCCAGATGT Fndc3cl 2074 AGAGTTGGACTAATCTAGGG Pde4b 5894 TGATAAGTAGGGCTTCAATC H2-M10 6 9714 AAGCCACGCCCATCCTCAGA Rhbdd3 2075 CCCGTTGCGGCGGGCCAATG 1810013L24Rik 5895 ACCAAAGCATCCACCCTAAA Pcp4 9715 GGTGATGCAAGACAGATTAT Abcal3 2076 CAATCATTAACTGGTTGCAC Ugtlal 5896 GCCCGACTTCCGCTTAACCC Rps6 9716 GCACAATCTGGCAGCGGGAT Adckl 2077 TTCTTAGATCTTGCGCAAAG Canx 5897 AAGCCACGCCCATCCTCAGA Rlibdd3 9717 o TGTTTGGATGACACGCCTTT Ttll 2078 ATGGGCAGGGCCAAACTCCC Myolg 5898 AGTTGTGGTTTATTGGGCTT Snx27 9718 CCTACTGCAGAGGCAGCACC Deib7 2079 AGCCACAGTTAACAGGCGTA Klhdc7a 5899 GCTTGTTGCTCCCGAGAAGG Hif3a 9719 GGCTAGTGCCTGGCGTAGCC Pcdhl9 2080 TTAGGGCGTGGTGGAGGGAG Rpp40 5900 TGTTTGGATGACACGCCTTT Ttll9 9720 TCAGCAAGAGTTAACCTAGG Grrpl 2081 TCAGGTGAGAACTCATGTAT Sfn 5901 CCTACTGCAGAGGCAGCACC Defb7 9721 o ACCTGCACTAGACGCGTCAT Abcal2 2082 GGGTCTCTCTAGGTGTTAGC Stmnl 5902 CTGGTGATTATAGAGAAATA Myol5 9722 4 AGAGTTGGACTAATCTAGGG Pde4b 2083 AGGTAGAACTATCAAGTCTC Sfn 5903 TCCACCTCTTCTTCCTAACA Tpm3 9723 TTCTTAGATCTTGCGCAAAG Canx 2084 GTTGAGGGTGGGACCAGAAG Dppa4 5904 TCTGAAGCAAAGTCCAGAAC 01fr921 9724 ATGGGCAGGGCCAAACTCCC Myolg 2085 GGAGGACCGCTGCCGACGTG Lpin2 5905 CGGCCGCGCTTGGCGGCTGC Pkn2 9725 AGCCACAGTTAACAGGCGTA Klhdc7a 2086 AATGGGCCATATCTTTATCA Nkx6-3 5906 TTGGAGGCGACTCTTACTCG Sin3a 9726 TTAGGGCGTGGTGGAGGGAG Rpp40 2087 AAGCTATTTAGAAAGCGATG A3galt2 5907 TTCTTAGATCTTGCGCAAAG Canx 9727 TCAGGTGAGAACTCATGTAT Sfn 2088 AGTGGGCACGTGACACTCTC Phc2 5908 ATGGGCAGGGCCAAACTCCC Myolg 9728 GGGTCTCTCTAGGTGTTAGC Stmnl 2089 CACCTTTGTAGGCTCCGGCT LsmlO 5909 TCAGGTGAGAACTCATGTAT Sfn 9729 AGGTAGAACTATCAAGTCTC Sfn 2090 GGTCGTAGGGCGTGGCGAAG Casp9 5 0 GGGTCTCTCTAGGTGTTAGC Stmnl 9730 GTTGAGGGTGGGACCAGAAG Dppa4 2091 GGATGCAGGACAAGTCCTAC Abcal2 5911 AGGTAGAACTATCAAGTCTC Sfn 97 1 GCAGACGTCCTTCCTGCGAA Map2k6 2092 AGCTCTGTGCACGTGATCAG Cyp2j6 5912 GCCCATAGCATCTGTAAAGC Bmprlb 9732 GCCCATAGCATCTGTAAAGC Bmprlb 2093 CAGGCAAGTGTCCTTGATAG Lmo2 5913 AAGCTATTTAGAAAGCGATG A3galt2 9733 CACATAAATCTGGTGCTTGT A830018L16Rik 2094 TAATCACCCAGTAATTGCTT Tgm6 5914 GGGTATCGATGTCAGCCGGA Ccdc24 9734 GGAGGACCGCTGCCGACGTG Lpin2 2095 CTGTGGCTTGCTCGTCATTG Gm7534 5915 AGTGGGCACGTGACACTCTC Phc2 9735 AATGGGCCATATCTTTATCA NkK6-3 2096 CATTCTACAACTGAAGACAG Zan 5916 CACCTTTGTAGGCTCCGGCT LsmlO 9736 AAGCTATTTAGAAAGCGATG A3galt2 2097 CTTGCAGACTCATAGACACC Npvf 5917 AAGAGGGATCTAGTAGGAGC Bdkibl 9737 AGTGGGCACGTGACACTCTC Phc2 2098 TGGTCGGAGAGGCAGCACGG Foxd2 5918 CTCTTCTTCCATGGGCCTGT Snapin 9738 GGTCGTAGGGCGTGGCGAAG Casp9 2099 TCACTCCGCACTCTGACCAA AU040320 5919 TGTATAACAGGTGCAAAGTG H2-M10.6 9739 GGATGCAGGACAAGTCCTAC Abcal2 2100 CAACTGTGTTCCGTGAATTG Hnmpa2bl 5920 AGAAGACAGCAGTGGAGACG Nt5cla 9740 CTTATCAGCACAACTACCTC Bpifb9b 2101 GGAAGGTGTTCTCCCTCCCG Riokl 5921 GGCATAGAGCCCGGTCTCCG Calml4 9741 TAATCACCCAGTAATTGCTT Tgm6 2102 CGCGAGAGTTGAGGAAGTTG Aga 5922 CTGTGGCTTGCTCGTCATTG Gm7534 9742 GAGAAATTGGTGTTGCTCTT Psd3 2103 AATAGTCCAGCTGTCAACTT Cnga3 5923 AGCAGTGGTTCCACTCTGCG Rcan2 9743 CTGTGGCTTGCTCGTCATTG Gm7534 2104 GAACCCTGTTTGCTAGGGAA Gabral 5924 AAAGACTCATTTGTCAGTCC Adaml9 9744 AACATTATTAGGAACCATGG Slc5al2 2105 TTGGCTAGCACAAAGGCCAG Dab2ip 5925 GGCGTTAGGTCGCCGTCCTC 4930503L19Rik 9745 TGTGTGAATGTGATTACTCC Setbpl 2106 CTAAGGAGCACAACGCTTGC Pgbdl 5926 TGTGTGAATGTGATTACTCC Setbpl 9746 CTTGCAGACTCATAGACACC Npvf 2107 GGCGGGCTGGCAGTGCGGCG Zfp777 5927 TCACTCCGCACTCTGACCAA AU040320 9747 TCACTCCGCACTCTGACCAA AU040320 2108 GACAGAAGGACACACCAATC Tmem57 5928 CAGTGCAGCTAGGGCCCTAA Lrrc71 9748 CAACTGTGTTCCGTGAATTG Hnrnpa2bl 2109 TCTGTTTGCTTTCTCCTAAC Tlrl2 5929 CGCGAGAGTTGAGGAAGTTG Aga 9749 GGAAGGTGTTCTCCCTCCCG Riokl 2110 GGGCGTGACCAGGGAGTTAG Asap3 5930 CCTGCCAAAGCTCAGCTAAG Bstl 9750 CAAACCCTGTCATTCTGTTC Cntnl 2111 CAGAGTAGTTGTCCCGGGCC Ti m56 5931 ACTAACAACAGTGGCTGAGT S om 1 97 1 CGCGAGAGTTGAG GAAGTTG Aga 2112 ATCAGTGCGTCCATCCCGCG Nkx6-2 5932 AATAGTCCAGCTGTCAACTT Cnga3 9752 GGTTCTGCGGrAGGACTCCC Unc80 2113 CGGGCGTAGAGGTACGATGC Stk 5933 GAACCCTGTTTGCTAGGGAA Gabral 9753 n AATAGTCCAGCTGTCAACTT Cnga3 2114 CCGGGCCGGTTGGGTCGCCC Faml99x 5934 CTAAGGAGCACAACGCTTGC Pgbdl 9754 GAACCCTGTTTGCTAGGGAA Gabral 2115 TTTGCACGAGAAGTGGAAAC Dync2hl 5935 GGAAGACGCAGCCGACCACC Plekhh2 9755 CTAAGGAGCACAACGCTTGC Pgbdl 2116 GAAGAGAGAATTCAACCGCA Cm2 5936 GACAGAAGGACACACCAATC Traem57 9756 n GACAGAAGGACACACCAATC Tmem57 2117 AAGTCTTGCAACTGTTGTGA Clintl 5937 TCTGTTTGCTTTCTCCTAAC Tlrl2 9757 o TCTGTTTGCTTTCTCCTAAC Tlrl2 2118 CATGAAGACAAGAGTCTGCA Clip4 5938 GGGCGTGACCAGGGAGTTAG Asap3 9758 GGGCAGCCGGGCGCCCTCAG Hfml 2119 TGCAGGCCTTTATGCAAATG Histlh2ab 5939 ATCAGTGCGTCCATCCCGCG Nkx6-2 9759 b GGGCGTGACCAGGGAGTTAG Asap3 2120 AAGGTGTTTCCACGCTCTTC Snmp48 5940 AGGCTACCATAGTAACTGAG Tpm3 9760 CAGAGTAGTTGTCCCGGGCC Trim56 2121 TACTATGGAAATCAGAGTAC Phfl4 5941 TGATGAGTCAAGTCTCAATC H2-M10 3 9761 J ATCAGTGCGTCCATCCCGCG Nkx6-2 2122 CTTCGAAATATCTGTCTGAT Pxmp4 5942 GAAGAGAGAATTCAACCGCA Cm2 9762 CGGGCGTAGAGGTACGATGC Stk35 2123 GCCCTCAGCTTCGGCTGCCC Phfl 5943 AAGTCTTGCAACTGTTGTGA Clintl CCGGGCCGGTTGGGTCGCCC Faml99x 2124 GTTAACTTGGAGCTGGGAAG Runxltl 5944 AGCACATCTGGAAGCGTTTC Glt8d2 GAAGAGAGAATTCAACCGCA Cnr2 2125 GAAGTGAACAGCAGGCGACC Zfp362 5945 TACTATGGAAATCAGAGTAC Phfl4 AAGTCTTGCAACTGTTGTGA Clintl 2126 AAGGCGTGCGCCACCACGCT Mat2b 5946 GGTGGCAGCGCAACGAGGGC cn 3 CTCTGAAAGCCTTAGCCTCG Cbx5 2127 AGCGGGCGGGACGTAAGGGT SlOOpbp 5947 CTTCGAAATATCTGTCTGAT Pxmp4 CATGAAGACAAGAGTCTGCA Clip4 2128 GGGCAGCTAAGGTGACATTA Zmyml 5948 GCCCTCAGCTTCGGCTGCCC Phfl4 AAGGTGTrrCCACGCTCTTC Snmp4S 2129 TGAACCCGAAAGGTTAGCGT 9530068E07Rik 5949 AGCAACGGAGTCTGTTTCTC Traeml54 TACTATGGAAATCAGAGTAC Phfl4 2130 ACAGTAGGCCTAGCTGGCAC Tmaulap 5950 TTGTGCTCGCTGTCTCATGG Ptk6 CTTCGAAATATCTGTCTGAT Pxmp4 2131 AAGCTGCCACGAGATTCTGG Slc25a53 595 GAAGTGAACAGCAGGCGACC Zfp362 GCCCTCAGCTTCGGCTGCCC Phfl4 2132 GAGTTCATAATCCTATCAGA Pramef6 5952 AAGGCGTGCGCCACCACGCT Mat2b CAGCCTTCAGAGCTAAGTGC Ano3 2133 GCCCAGCGGCAGCCCAGAGC Dawl 5953 AGCGGGCGGGACGTAAGGGT SlOOpbp AAACTTCCGCATTTCCACCT Docks 2134 AGTAGGTAGCCCAGTCCGTG Bpifa6 5954 GGGCAGCTAAGGTGACATTA Zmyml GAAGTGAACAGCAGGCGACC Zfp362 2135 TCGCGGCTGCGGAGACTAGA Ywhaq 5955 TGAACCCGAAAGGTTAGCGT 9530068E07Rik AAGGCGTGCGCCACCACGCT Mat2b 2136 ACGTGGTGCTCTCGCGAGAG GpatclG 5956 CACTCTAAATTCGTCCAGCC Bbs4 AGCGGGCGGGACGTAAGGGT SlOOpbp 2137 AATAGCTCTGAAGAGTTCAT Dppal 5957 ACAGTAGGCCTAGCTGGCAC Tmaulap TATGCGCGCAGGGCGGCGGG Msil 2138 CAGTGCTTTCCAAGCGCGTA Hintl 5958 GGAGGCTGAGAACTATGGAA Ddrl GGGCAGCTAAGGTGACATTA Zmyml 2139 CTCAGCCCTGTGTCCGTGCC Tuscl 5959 TCCGCCCGCCCAGCTCCCAG Robo3 TGAACCCGAAAGGTTAGCGT 9530068E07Rik 2140 CCCAGGATTCTTTAAACAAC Pde4b 5960 GAGTTCATAATCCTATCAGA Pramef6 ACAGTAGGCCTAGCTGGCAC Tmaulap 2141 CGTCAGCTGTTCTGCCAAGG Tcn2 5961 AGTAGGTAGCCCAGTCCGTG Bpifa6 AAGCTGCCACGAGATTCTGG Slc25a53 2142 TAAATCATCCAGGCATACGG Rpl36a 5962 ACGTGGTGCTCTCGCGAGAG Gpatch3 CTGCCCGAGCCAAGGCAATA Dpyd 2143 GCGGAGTAGTTGAGAGATGC Cntn5 5963 AATAGCTCTGAAGAGTTCAT Dppal GCCCAGCGGCAGCCCAGAGC Dawl 2144 ATTGTACTTTACGTTGGGAA Zbtb8a 5964 AAGCAAGTCTGTAAAGAGGA Fcrls AGTAGGTAGCCCAGTCCGTG Bpifa6 2145 TTGAGCGTAGGCAAAGGTTA Sorbs2 5965 CAGTGCTTTCCAAGCGCGTA Hintl TGCGGAAGGACGAGCACAAA Cepl62 2146 GGCTCTACCCTGTGACCAAT Nlip2 5966 CTCAGCCCTGTGTCCGTGCC Tuscl + CTTCCTACGGAAACAAGGCG Cdk5rap2 2147 GCTGTTTCATAACAGACTTT Tgm6 5967 CTCAGATTGGAGGAAATTAA Tmeml44 GGCGGGTGTACGTCACGGGC Epha4 2148 CCGCGAGCGCACAAGGCACC Nitl 5968 TCCACTGGGAGAAGGAGGGA Dsgla ACGTGGTGCTCTCGCGAGAG Gpat l 2149 TGTTCCATTAGCCTCTTGGC Coll 6a 1 5969 CGTCAGCTGTTCTGCCAAGG Tcn2 AATAGCTCTGAAGAGTTCAT Dppal 2150 ACCTGCAGTCAGGGACTCCC Nphpl 5970 GATTGGTTGAAAGCAAGAGG AU022252 CAGTGC T TCCAAGCGCGTA Hintl 2151 GCCTGCATTAACAGCTAGAA Dcx 5971 TTAATGTCTGCTTCAGGGCT Grm4 CTCAGCCCTGTGTCCGTGCC Tuscl 2152 TGTGCGAGCTGGTGCGAACT Esxl 5972 GGCCTGAGGCCCATTGTGTG Mytl CCCAGGATTCTTTAAACAAC Pde4b 2153 GTGGAGAAATTCTGGAGTTG Ofccl 5973 CGGTTTCCCATAGAAACAAA Ktil2 CGTCAGCTGTTCTGCCAAGG Tcn2 2154 GCTACCATCGGGCCAGGCCT Ewsrl 5974 ATTGTACTTTACGTTGGGAA ZbtbSa TAAATCATCCAGGCATACGG Rpl36a 2155 TAGTTAGCACACACTGGAAC 01fr531 5975 GGACCTAAGAGGCGCGGCCG Mbd2 GCGGAGTAGTTGAGAGATGC Cntn5 2156 CCATCGGCCGTGCTGGGAGC Tmem54 5976 GGCTCTACCCTGTGACCAAT Nhp2 ATTGTACTTTACGTTGGGAA Zbtb8a 2157 TGTGCTGGTGAAGAGGCAAG Kctd3 5977 TGTTCCATTAGCCTCTTGGC Coll6al TTGA GCGTAGGCAAAGGTTA Sorbs2 2158 TAGCCGATCTGA CAGAGGAG Cntnap2 5978 TCTGAGCCGGAGATCCGCGC Tritl GGCTCTACCCTGTGACCAAT Nhp2 2159 GCTGGAGCGCACGGCGACAC Kankl 5979 CGCCCAGCCGGCGGAGCGGG Zbtb46 GCTGTTTCATAACAGACTTT Tgm6 2160 GCTATTGGTGGCCGCTCTCG Dhdds 5980 GAGGGAAAGTTGCACGCTGA Inpp5f TGTTCCATTAGCCTCTTGGC Coll6al 2161 GAGCTGTTACGAGGCTCCTA Limk2 5981 GGGAAACGTGGATCTCGGCG Tdg CTATGCTAAAGACACGCCTC Dpyd 2162 CGCCGGGAAGCCGAGTCCTC Slc22a4 5982 AACGTGCTGAAGAGAGACAA Cc2d2a GGAGCTCACGCAGCTTCCGG Faml50a 2163 GAAGCCTCCGCCTGAAGATT Spm 5983 ATGCGAGGAGAACTTCTACC Dst ACCTGCAGTCAGGGACTCCC Nphpl 2164 TTTACACCGCTTTATTTGTC Helt 5984 ACATGTGATCAACTATTAAC Bdnf TGCGCAACCAATCCTGGGCT Cbx5 2165 TAAAGAAGTAGTAGGTCTCA Cdk5rapl 5985 GCTACCATCGGGCCAGGCCT Ewsrl TGTGCGAGCTGGTGCGAACT Esxl 2166 AGGCCAAGTGTCCACCGTGA Amph 5986 CCATCGGCCGTGCTGGGAGC Tmem54 GTGGAGAAATTCTGGAGTTG Ofccl 2167 ATCAAGAGTTGACTGAAGAC 1700012A03Rik 5987 TTTCTGCCTGATTCAGTTCT Rcan2 GCTACCATCGGGCCAGGCCT Ewsrl 2168 AGGTCACGTTCCAACCCTTT Arl4a 5988 TGTGCTGGTGAAGAGGCAAG Kctd3 CCATCGGCCGFGCTGGGAGC Tmem54 2169 CGTTGGGCGATGGACAAGCT Ggh 5989 TTCTGAGTTCAATGCCAGCT Dsglc TGTGCTGGTGAAGAGGCAAG Kctd3 2170 AGAGTTCAACGGCCGGAAGT 2610020H08Rik 5990 GCTATTGGTGGCCGCTCTCG Dhdds TAGCCGATCTGACAGAGGAG Cntnap2 2171 TATCTCTGTGTCTAGGGTAT Tgm2 5991 GAGCTGTTACGAGGCTCCTA Limk2 98 11 GCTATTGGTGGCCGCTCTCG Dhdds 2172 GAAGTGTGTGAGGAGGTTGG Ube2h 5992 GCTACCCGTGGCCACAGCTG Stra6 9812 GGTGTGTATCGCCrCCAGCC Rifl 2173 AAACAGGCGGGAATCGGTGG Gti2hl 5993 GAAGCCTCCGCCTGAAGATT Spm 9813 o GAGCTGTTACGAGGCTCCTA Lirak2 2174 TCTTCAGTTAGGAACAGTCC Pde4b 5994 TAAAGAAGTAGTAGGTCTCA Cdk5rapl 9814 GAAGCCTCCGCCTGAAGATT Sp 2175 CCCGCCCTGTCAAGGCAGCC Reml 5995 AGGCCAAGTGTCCACCGTGA A ph 9815 TTTACACCGCTTTATTTGTC Helt 2176 AAAGGAAACACTTGGCCTTT Ppargcla 5996 TCCCAGGGATTCAATAACCT Spirel 9816 5 TAAAGAAGTAGTAGGTCTCA Cdk5rapl 2177 GGAGGGCCTTAACGTGGGCG Entpd2 5997 CGAGGACACATAAGGTTCCT Dao 9817 o AGGCCAAGTGTCCACCGTGA Amph 2178 GCGTCCTGGATACTTTAGGA Uqcib 5998 GACGACCGCTCCTAAGGTTT Pcdhl 9818 4 ATCAAGAGTTGACTGAAGAC 1700012A03Rik 2179 TTAGCAGGAGTCTGATTGGC Adamtsll 5999 CAGCGAGTACAGGCTTAGGC C d l 7 9819 CGTTGGGCGATGGACAAGCT Ggli 2180 TATCTGCGACTCCAGCGCGG Paqr7 6000 GGAGGGTGAACGTAAGTACC AbcclO 9820 CTGCGAATTTGGGATTCTAT Cntnap5a 2181 GACAGTCTCCCGCGGGACCG Zfp467 6001 CTGCGAATTTGGGATTCTAT Cntnap5a 9821 TCTTCAGTTAGGAACAGTCC Pde4b 2182 CAGGAAGGAGGAACTCAAGA Rps6kal 6002 GAGGTGGGTGTGAGGGAAAC Amhr2 9822 CCCGCCCTGTCAAGGCAGCC Reml 2183 CTACTAAGCAATAAGTCAAG Rnfl48 6003 TTCCATTACTCTATGTCCCT Fezl 9823 AAAGGAAACACTTGGCCTTT Ppargcla 2184 TCGTCTCAGCGCTCTCTCAT pp7 6004 CGTAGGTCGAGGACTGGCGA Psmg2 9824 GCGTCCTGGΑ ACTTTAGGA Uqcib 2185 GAGCTTCCTTCTTTCAAACC Cd52 6005 CCCGCCCTGTCAAGGCAGCC Reml 9825 TTAGCAGGAGTCTGATTGGC Ada tsl1 1 6 TGGTGAGGTATGGAGGAAGG 49 1440F15Rik 6006 AAAGGAAACACTTGGCCTTT Ppargcla 9826 TATCTGCGACTCCAGCGCGG Paqr7 2187 TGGGCTAGACAGCGAGTAGC Lmod3 6007 GGGTCCTAGAGACCGCTCCG Adaml2 9827 GACAGTCTCCCGCGGGACCG Zfp467 2188 TGAGCCTAACTAAGCAAGGG Kcnip3 6008 GGCGGGACCACACTTGGCGC Adss 9828 CAGGAAGGAGGAACTCAAGA Rps6kal 2189 TTGGGCCCTCCTAATACATG Gale 6009 GCGTCCTGGATACTTTAGGA Uqcib 9829 CTACTAAGCAATAAGTCAAG Rnfl48 2190 AAAGCCCAGGGCGGTGAAGA Prkaa2 6010 TTAGCAGGAGTCTGATTGGC Adamtsll 9830 GAGCTTCCTTCTTTCAAACC Cd52 2191 CTTCTTCCCAGGGCGAGGTG Dsp 6011 GCCAACACGCGGCGTTCCCG Syde2 9831 AGTCCCAGITAACCCTTTCC Col9al 2192 ACAGTCGGGCCCAACCACAG Sytll 6012 TATCTGCGACTCCAGCGCGG Paqr7 9832 TTGGGCCCTCCTAATACATG Gale 2193 TGTGCTACGGTGGCCGCGCG Atg4c 6013 AAAGAGGACCGGAGTCGTCG Lcorl 9833 GGTGCCTGCAGTTTCCTGCC Abcc9 2194 GGAGACACCAACCACTAAGA Hmgb4 6014 CAGGAAGGAGGAACTCAAGA Rps6kal 9834 o AGATGGAGTTTAGTAGGCTA D330045A20Rik 2195 GCCGACCTGAACACCGGCAC Ptp 6015 GAGCTTCCTTCTTTCAAACC Cd52 9835 CTTCTTCCCAGGGCGAGGTG Dsp 2196 GCATCACGTGGGCCAAGGAG Dhx35 6016 TCAGCCGAGCTCAGGTGCCC Lrba 9836 GCGTGCGCCGAACGTGTCTG Usp24 2197 CACAAGGTAGTGTTGACAGA 4930 63M2 IRik 6 CTCTCTTAGCCTTGAGCTGG Cypllal 9837 ACAGTCGGGCCCAACCACAG Sytll 2198 AAAGAAAGGAGCATGATGAT Fat2 6018 AGTCCCAGTTAACCCTTTCC Col9al 9838 TGTGCTACGGTGGCCGCGCG Atg4c 2199 TCTTAGTCTCGTCGTACGAT Ak2 6019 TTGGGCCCTCCTAATACATG Gale 9839 GGAGACACCAACCACTAAGA Hmgb4 2200 AGTGAAGGTAGCGGCGGCTA Trap 6020 GCAAGCGCAATGAAGCTCGC Piasl 9840 GCATCACGTGGGCCAAGGAG Dhx35 2201 TCCTGCAGGACTGGTGCACC Tgifl 6021 ACAGTCGGGCCCAACCACAG Sytll 9841 GGGTTGCTGCAAAGCGCTCA Snap25 2202 CTGCGCATGACTGAAGGGCG Atp6vlf 6022 GCCGACCTGAACACCGGCAC Ptpm 9842 AAAGAAAGGAGCATGATGAT Fat2 2203 GGCTGGGCACGCGCAGTGCG Ptprzl 6023 GCATCACGTGGGCCAAGGAG Dhx35 9843 TTGCAGTAΑ ΑCAAGTAGT Ms4a7 2204 AGCGCACTGGGCGTGGTTAG Aunip 6024 GGCTAATTCTGGTTTGTCAG Slcl6al4 9844 TCTTAGTCTCGTCGTACGAT Ak2 2205 GCACACCTACCTCTCCCTCA Ndrg3 6025 CACAAGGTAGTGTTGACAGA 4930563M21Rik 9845 TCCTGCAGGACTGGTGCACC Tgifl 2206 TATAAGCGCCAAAGTCCAGA Ctli 6026 AAAGAAAGGAGCATGATGAT Fat2 9846 CTGCGCATGACrGAAGGGCG Atp6vlf 2207 GTTCTGACGCGCGGAAACCC Rmnd5b 6027 GCTACTTCGATAGCATGTGC Cd276 9847 GGCTGGGCACGCGCAGTGCG Ptprzl 2208 AATTGAACTGGTGGCATATC Xbpl 6028 TCTTAGTCTCGTCGTACGAT Ak2 9848 AGCGCACTGGGCGTGGTTAG Aunip 2209 TTGAGTAGGTGTAGCCTTGT AtplOb 6029 CGCCCACCGAAACTCCACAG Pdlim5 9849 n GTGTTCCGGGATAGGCATCC Gtpbp3 2210 CTCTGCACAGGGCAGGCTGG Xkr8 6030 CTCTATACCCAGGATTCTTC Tmem202 9850 GCACACCrACCrCTCCCTCA Ndrg3 2211 TCAGCGGTAGATCTAGCAAA Plxdc2 6031 AGCGCACTGGGCGTGGTTAG Aunip 9851 GTTCTGACGCGCGGAAACCC Rmnd5b 2212 AGCTTTGCCCACCGTGCTCC Esrrg 6032 GCACACCTACCTCTCCCTCA Ndrg3 9852 n AATTGAACTGGTGGCATATC Xbpl 2213 TCCGACCGATGCTCGATGCT Myl9 6033 AATTGAACTGGTGGCATATC Xbpl 9853 o TTGAGTAGGTGTAGCCTTGT At lOb 2214 GCACCTCAGACAGCTCCCGC Glra3 6034 TTGAGTAGGTGTAGCCTTGT AtplOb 9854 5 CTCTGCACAGGGCAGGCTGG Xkr8 2215 CCGCCCACAGCACAAACTCT Ryrl 6035 CTCTGCACAGGGCAGGCTGG Xkr8 9855 b TCAGCGGrAGATCTAGCAAA Plxdc2 2216 CTAACTGCAGTGAGCCGCCA Focad 6036 CAGCCAATCGGAGGCCACAG Taf4 9856 5© AGCTTTGCCCACCGTGCTCC Esrrg 2217 TAACTGAGTAAGGGATTAAC Gm853 6037 AGCTTTGCCCACCGTGCTCC Esrrg 9857 J GGCTCCAAGAATGGCCTCAG Actcl 2218 CCGCCATCTTGTCATTGAGT Cedcl57 6038 AGGCAGGCCCGACGCGCCTG Lrba 9858 TCCGACCGATGCTCGATGCT Myl9 2219 TAGGArGTGACTCAATGTTT Spata4 6039 AGGAAGAAAGCAGATGCGAC Wdrll 9859 GACATCTGCTGAGACTTAAC Nlrplb 2220 CAGATGTGTCAGTTGGCTGA 1700012A03Rik 6040 TGCAAGCCTCACACTCGCTG Rapgef2 9860 TTTAAAGCTTGCCTTTAGCT Laip4 2221 CTATCGTCACCTTGGCTGCC Agrp 6041 TCCGACCGATGCTCGATGCT Myl9 9861 GAGATACTCTGTTGCAGCCA Gbp4 2222 AGTTGATATATTCAGCTGAA Pde4b 6042 CGGGACCCGCGATGGCCTGC Plxnal 9862 GCACCTCAGACAGCTCCCGC Glra3 2223 CATCTCGTGCGTAAGATCCA Eya3 6043 GCACCTCAGACAGCTCCCGC Glra3 9863 CTAACTGCAGTGAGCCGCCA Focad 2224 GGCATGTCATTGTTAGGCAT Clip4 6044 GCACGTGCAGTGAGAATTGC Meal 9864 CCGCCATCTTGTCATTGAGT Ccdcl57 2225 CCCGCTCGGCGGGACGGGAG Mierl 6045 CTAACTGCAGTGAGCCGCCA Focad 9865 TAGGATGTGACTCAATGTTT Spata4 2226 TGCAGAGTTGCATCTAACCC Tgm4 6046 CTTCATGTAATAACTTCTCC Thsd4 9866 CAGATGTGTCAGTTGGCTGA 1700012A03Rik 2227 GGGCACAAGTCCCTTCCAGC Tc2n 6047 TAACTGAGTAAGGGATTAAC Gm853 9867 AGTTGATATATTCAGCTGAA Pde4b 2228 GAGCGGGCCGCTTAGAATTG Npy 6048 CCGCCATCTTGTCATTGAGT Ccdcl57 9868 CATCTCGTGCGTAAGATCCA Eya3 2229 CTCAGATCTAGTTGCATGAT leal 6049 CTTGGCGGCTACTCTGGACC Psmb4 9869 TGTCTCCTAAGCTAGAGCAG Tespal 2230 GGGAATGTAGTCCCGCCTTG Ccdcl26 6050 AACCGCGGGCACTCGCCCAC Femlb 9870 GGCATGTCATTGTTAGGCAT Clip4 2231 TTATGAAGGGCCCACTTGTT Pde4b 6051 CATCTCGTGCGTAAGATCCA Eya3 9871 CCCGCTCGGCGGGACGGGAG Mierl 2232 GCTAGATTGACTTTCATAAA SkintlO 6052 GGAGGCGGAAGTTCGGCAAG Hnmpll 9872 TGTGTGGTACGTGTCGCGTG La p4 2233 GGAGGCACGCACGCGACGCA Nrfl 6053 GCCAGGCTGCCCGTCAACCC Fstl5 9873 GCCAGGCTGCCCGTCAACCC Fstl5 2234 CCTGGAAATGGCTAGCTTGT Tgtp2 6054 TGCAGAGTTGCATCTAACCC Tgm4 9874 TGCAGAGTTGCATCTAACCC Tgm4 2235 GTTGAGGCTGCCTGTGACGG 49 1507P07Rik 6055 TGGAATTTCGAGCTGCTGAT Gpatch2 9875 GAGCGGGCCGCTTAGAATTG Npy 2236 CAGAGGGTACCTCGCTAGCC Kazn 6056 CTCAGATCTAGTTGCATGAT leal 9876 CTCAGATCTAGTTGCATGAT leal 2237 CGGTGTCGATGCGAAACCCT Ralgapa2 6057 AAGTTCTCTCCCAGCTCTCT Gbp5 9877 GGGAATGTAGTCCCGCCTTG Ccdcl26 2238 GAGAAGAATTAGCTCTACAA Morc2a 6058 AGAATGGAGAAGCTCCTAAG Tnfaip812 9878 TTATGAAGGGCCCACTTGTT Pde4b 2239 GCCTCCAACTGCGATGGCCG Jade2 6059 GGCTGTCACGTGATAGGCTT Sec23ip 9879 GCTAGATTGACTTTCATAAA SkintlO 2240 GTAGAGCAAGGCCTGCTGAG Hormad2 6060 CCTGGAAATGGCTAGCTTGT Tgtp2 9880 GGAGGCACGCACGCGACGCA Nrfl 2241 TGCCCTCCCTCCCTGCCTAA Synel 6061 ACACAGGCGCGCGGCGAGCC Setbpl 9881 CCTGGAAATGGCTAGCTTGT Tgtp2 2242 TTTCCGGCAGTGCCGCAAG Srfbpl 6062 GCAACCCTTAGAAACACTTC Dmapl 9882 GTTGAGGCTGCCTGTGACGG 49 1507P07Rik 2243 GCCTGGGCAGCCGAGCCAAT Cep41 6063 CACCTCAGTTCCTACAGCAA Dsg3 9883 ACACAGGCGCGCGGCGAGCC Setbpl 2244 GCGTCGGCGCGGACTTCTCG Drgl 6064 AAACTGCAGTTCTAAAGCTC Lyplall 9884 CAGAGGGTACCTCGCTAGCC Kazn 2245 ATTTATTACCTCCGACTCCG Hmgn2 6065 GAGAAGAATTAGCTCTACAA Morc2a 9885 CGGTGTCGATGCGAAACCCT Ralgapa2 2246 AGTTTAGAGGGTCTGGGTGC Aebpl 6066 GCCTCCAACTGCGATGGCCG Jade2 9886 CACCTCAGTTCCTACAGCAA Dsg3 2247 AGGTGGAGCTAAGACTCGGA Kcnip3 6067 GTAGAGCAAGGCCTGCTGAG Hormad2 9887 GGGCCCGGATTACGAGGGCG Mapk8 2248 GAGGTTGCTAAGAACTCTCC Speer4c 6068 TGCCCTCCCTCCCTGCCTAA Synel 9888 GAGAAGAATTAGCTCTACAA Morc2a 2249 TTCCTAGGCCCTTCTGCATT Rpia 6069 GGAGAACTGGTGAAGGGAGG Cln6 9889 GCCTCCAACTGCGATGGCCG Jade2 2250 TCCTTAGGGCCCTACTTTAA Dhcr7 6070 GAAAGCGACTCCCAGAGGTA Dnphl 9890 GTAGAGCAAGGCCTGCTGAG Hormad2 2251 AAGACCTGGTCTGTGTGGTG Tiaml 6071 GCCTGCGTCGTCCCTACACG Stpg2 9891 TGCCCTCCCTCCCTGCCTAA Synel 2252 CCCAGGCTGCCTGTCACTTG Tnipl 6072 GCGTCGGCGCGGACTTCTCG Drgl 9892 TTTCCGGCAGTGCCGCAAGT Srfbpl 2253 CCGGTAGGGTTTGGCCTTGG Cldn23 6073 ATTTATTACCTCCGACTCCG Hmgn2 9893 GCGTCGGCGCGGACTTCTCG Drgl 2254 TTCGCCAAAGTCCGGCTGCC Pgm2 6074 AGTTTAGAGGGTCTGGGTGC Aebpl 9894 ATTTATTACCTCCGACTCCG Hmgn2 2255 TAACTGCACTGTGGTTGATT Slc36a2 6075 TTCCTAGGCCCTTCTGCATT Rpia 9895 AGTTTAGAGGGTCTGGGTGC Aebpl 2256 ATTGTAAGACCGGGACAATC Lars2 6076 TCCTTAGGGCCCTACTTTAA Dhcr7 9896 GCGTGGAGTGACTGAGATGT Qsc 2257 TCTGGAACTCAGCAGAAGAG Doxl2 6077 AAGACCTGGTCTGTGTGGTG Tiaml 9897 TTCCTAGGCCCTTCTGCATT Rpia 2258 CCTAGCTCGGAGGGATGTCA Rhd 6078 CCCAGGCTGCCTGTCACTTG Tnipl 9898 TCCTTAGGGCCCTACTTTAA Dhcr7 2259 GACTAAGCAGGAGAGGTTGA Zrayml 6079 TAACTGCACTGTGGTTGATT Slc36a2 9899 CCCAGGCTGCCTGTCACTTG Tnipl 2260 GAGAGCAGCAGCACTGATTT Brinp3 6080 ATTGTAAGACCGGGACAATC Lars2 9900 CCGGTAGGGTTTGGCCTTGG Cldn23 2261 GATCCCTGCCAGGCCCTCAC Robol 6081 GGCAGCATTGTTACCTGCAG Fhdcl 9901 TTCGCCAAAGTCCGGCTGCC Pgm2 2262 GGTTAATGCTTGGACTCCTG Gpm6a 6082 CCTAGCTCGGAGGGATGTCA Rhd 9902 TAACTGCACTGTGGTTGATT Slc36a2 2263 TGCTAAAGAGAACGGAGGAG Krbal 6083 GCCTTTCTTGCTAAGAATTG Nup2101 9903 ATTGTAAGACCGGGACAATC Lars2 2264 AGCGCTGGAATTGCTTTATG Cyp8bl 6084 GACTAAGCAGGAGAGGTTGA Zmyml 9904 TCTGGAACTCAGCAGAAGAG Doxl2 2265 TTCCCAGCAGCCAACAGCAG AW551984 6085 ACGGGTCAGGCCTTGGTTCA Laol 9905 CCTAGCTCGGAGGGATGTCA Rhd 2266 TTCATAAAGAGAGTGCCTAT S dl 6086 AGCGCTGGAATTGCTTTATG Cyp8bl 9906 TTATATCCCTCACTAACCTG Ttil 2267 TTTGGTGTAATCAGGTACAG Trimll 6087 TTCCCAGCAGCCAACAGCAG AW551984 9907 GACTAAGCAGGAGAGGTTGA Zmyml 2268 GAGATACCACCGCGCCGGTG Pdikll 6088 GAGATACCACCGCGCCGGTG Pdikll 9908 CGCAGCTCTCATGATGGTCG Neb 2269 GGAGACTCTTGTCATTGACC Scn8a 6089 AGACACGCGGACCGCGACAG Tspan5 9909 o GATCCCTGCCAGGCCCTCAC Robol 2270 TTAGCAGACATTAAATACTG Igfl 6090 GACACCGGTGCGTGTCAACC Bag3 9910 GGTTAATGCTTGGACTCCTG Gpm6a 2271 AGATCCTTCCTCAAAGGGCC Atoxl 6091 AGATCCTTCCTCAAAGGGCC Atoxl 9911 TTCCCAGCAGCCAACAGCAG AW551984 2272 TAGGTTCACTGCTGCCCGAC Duspl5 6092 TAGGTTCACTGCTGCCCGAC Duspl5 9912 TCTTTAAATGCCTGCATCAA Pramef25 2273 TGGAGCACCTAGCTCTTAGC Zkscan7 6093 GGGTCCTTGGGACAGGTTCG Arhgef2 9913 o4 TTCATAAAGAGAGTGCCTAT S dl 2274 TTCACGCTCAGTGGCGTTTA Nsun2 6094 CCAGACCCGCGCTTAGATTT Cspg4 9914 4 GAGATACCACCGCGCCGGTG Pdikll 2275 TCTGTGACGTCAGGGACGGC BC049762 6095 GACAACTGCAAGGCTTTGAA Svbp 9915 AATCTGAATCCACAGCTCCC K nj l 2276 AGTCTCGGCTAGTCGGTGGG 0610009B22Rik 6096 CACCCTTATTTATCTGTGCT Gbp5 9916 AGATCCTTCCTCAAAGGGCC Atoxl 2277 CCATGCTGTGAGTGAACTTT Gm l27 4 6097 TGGAGCACCTAGCTCTTAGC Zkscan7 9917 TAGGTTCACTGCTGCCCGAC Duspl5 2278 GAACGCAGATCCAACCTACT Zfp398 6098 TCTGTGACGTCAGGGACGGC BC049762 99 18 TGGAGCACCrAGCTCTTAGC Zkscan7 2279 GAGAGAAGTCTTCCTAGTGT Golga7 6099 AGTCTCGGCTAGTCGGTGGG 0610009B22Rik 99 1 TCTGTGACGTCAGGGACGGC BC049762 2280 GCGGAGTTCGAGACACTCAT Cds 6100 GTCCTATCCAGTTCTGGCTT Cul7 9920 CCATGCTGTGAGTGAACTTT Gml2794 2281 CACGGTTCCCACAATACTCC Tssc4 6101 ATCCAGTCAGCGGAACCGCC Ano5 9921 GAACGCAGATCCAACCTACT Zfp398 2282 AAAGCCCTGGACCTGTGCAC Alg5 6102 CGATTCCACCTTATTGATTT Sec23ip 9922 GAGAGAAGTCTTCCTAGTGT Golga7 2283 TTGCAGAAACTTGGTGAGAT Mplkip 6103 CACGGTTCCCACAATACTCC Tssc4 9923 GCGGAGTTCGAGACACTCAT Cds2 2284 ACAAACGCAGGGCGGAAATA Dadl 6104 TTGCAGAAACTTGGTGAGAT Mplkip 9924 CACGGTTCCCACAATACTCC Tssc4 2285 CTGAGACAGTGCGGTGACAA Myom3 6105 ACAAACGCAGGGCGGAAATA Dadl 9925 TTGCAGAAACTTGGTGAGAT Mplkip 2286 GGAGTATCTTTAGAACATCC Bpifa2 6106 CTGAGACAGTGCGGTGACAA Myora3 9926 ACAAACGCAGGGCGGAAATA Da l 2287 GCGGCGGTCGGGCCATTGTG Pofutl 6107 GGAGTATCTTTAGAACATCC Bpifa2 9927 CTGAGACAGTGCGGTGACAA M o 3 2288 CGATGGGCTGGCAACCGAGG Adgrl3 6108 GCCGTGCCGCGCGCATGCGC Plxnal 9928 GGTTAGGTGTCTTATGAAAC Tmco5b 2289 GCAGGAGGAGCGCAGCCGGG Jam2 6109 GCGGCGGTCGGGCCATTGTG Pofutl 9929 GGAGTATCrrTAGAACATCC Bpifa2 2290 AAACCACGACCTGGCTCCAC Pgbdl 6110 TTCCGGTAGGAAAGTGGGCG Pex6 9930 GCGGCGGTCGGGCCATTGTG Poiutl 2291 TAGGCCAGCCAATCAGAACT Mapk9 61 AGCTTGGTTACGAGAACCTT Nlrxl 99 1 TTGATCTCATCATATCTGAA Abca6 2292 TGAGCAGTCGGTGCCGGTGC Lrrtml 6112 GCAGGAGGAGCGCAGCCGGG Jam2 9932 CGATGGGCTGGCAACCGAGG Adgrl3 2293 CACTGGAAATATGGCAGGGC Tctexldl 6113 AAACCACGACCTGGCTCCAC Pgbdl 9933 TCAGCGCTGAGAACACCAGG Morel 2294 TCTGGTCCCGGTCTCCGAGC Slc22a21 6114 GCTAGTATGTCAGTTTCGAG Slcl0a2 9934 GCAGGAGGAGCGCAGCCGGG Jam2 2295 AACAATCACAGATGAAGTCA Sis 6115 TAGGCCAGCCAATCAGAACT Mapk9 9935 AAAGTCACGTCTTCTCTCAT Slitrk5 2296 CAGACGGCGAGCCGCCTAGG Mapk9 6116 TTTCTGCGCGCGGAGCTTCA Mpi 9936 AAACCACGACCTGGCTCCAC Pgbdl 2297 ACACTGCACTCTTTCGGGTC Smarca2 6117 TACATATGTTGTTGTGCAGC Fstl5 9937 TAGGCCAGCCAATCAGAACT Mapk9 2298 TATCACTCCTCTGCAGCAGA Stl8 6118 TGGTAGAGCTTCTGAGGATC Cntnap5a 9938 GCCGGCGAGGAACCCGCGCT Unc80 2299 TTTCCGGCGAGCTGCATACG Itgb3bp 6119 TCTGGTCCCGGTCTCCGAGC Slc22a21 9939 TACATATGTTGTTGTGCAGC Fstl5 2300 AAGGTTCGCGAAGTGCCGCT Sync 6120 CCAGTTCAAATACAGACTCC Tdpozl 9940 TGAGCAGTCGGTGCCGGTGC Lrrtml 2301 AAGGCCGTTTGCGACGCGAA Trrap 6121 CAGACGGCGAGCCGCCTAGG Mapk9 9941 CACTGGAAATATGGCAGGGC Tctexldl 2302 ACGGTAGCAGCGCAGCGGCA C77080 6122 TCTGCAGCGATGACGTCAAC Ing3 9942 TGGTAGAGCTTCrGAGGATC Cntnap5a 2303 AACACAATCAAGAAACAGTT Dnah7b 6123 GACAAACAAATAATGCTGCA 01frll6 9943 TCTGGTCCCGGTCTCCGAGC Slc22a21 2304 ATCTGAGATTAAAGATGTGG Gml2789 6124 CAGTTTCTGTAGAGAAAGAG Bdkibl 9944 AACAATCACAGATGAAGTCA is 2305 ATGAAGGACTCTAAGCCCAG Gabral 6125 AAGGTTCGCGAAGTGCCGCT Sync 9945 n CAGACGGCGAGCCGCCTAGG Mapk9 2306 GGGCAGCTGGCCAAGGCCTA Fam7 If 1 6126 GCTCACGCCTGCGCGTGCGC Gpbplll 9946 ACACTGCACTCrrTCGGGTC Smarca2 2307 GGGAGGAGGGCAGTGGGTTT Ly6c2 6127 ACGGTAGCAGCGCAGCGGCA C77080 9947 2308 CGCCCACTGTATATTTAGAT Mllt3 6128 AACACAATCAAGAAACAGTT Dnali7b 9948 n TTTCCGGCGAGCrGCATACG Itgb3bp 64 GAGAGCAGCGGTTCAACAGC Dock 10 2309 ATCGGATCAATAGCAGTCTG Noval 6129 ATGAAGGACTCTAAGCCCAG Gabral 9949 AAGGTTCGCGAAGTGCCGCT S c 2310 AACAGAGGGTGCGTGCGAGA Runxltl 6130 CGCCCACTGTATATTTAGAT Mllt3 9950 ACGGTAGCAGCGCAGCGGCA C77080 2311 GCAGCTGACCTCTTGACCAC Fbliml 6131 CCTAGGCTGCCTAACATGCC Nr2e3 995 1 64 AACACAATCAAGAAACAGTT Dnah7b 2312 GGTAGGGAGGACTGCGTGGG Eml5 6132 TCGGGACCAATGAGCTGCGC Sh3bgrl3 9952 ATCTGAGATTAAAGATGTGG Gml2789 2313 CTGGACAGCTGGCTTTGGTG Hdac 6133 GTTCAGAGGCACAAGCCAGC Dao 9953 ATGAAGGACTCTAAGCCCAG Gabral 2314 GGCTTCATTCATAATTACAA Zfp879 6134 GTTAGGCTCCCTTGCTAAGG RpsSkal 9954 AGGACAAATCCCTGCAGCAG Csmp3 2315 TAAGATAGATGCCATTTCAA Tctexldl 6135 AGAGCAGGGCGCGCTGTGAT Histlhlt 9955 GGGCAGCTGGCCAAGGCCTA Fam71fl 2316 TTCTCGGCGTCTAGCAGCCT Cdhll 6136 CGGTTGGTTGTGGGTTCCCG Tmem222 9956 GGGAGGAGGGCAGTGGGTTT Ly6c2 2317 TTCTGTAGGTTGTAGGACCC Psap 6137 GAGGCTCCTTCCTCCAAGAT Proml 9957 CGCCCAC G ATA AGA Mllt3 2318 TCGGGACCAATGAGCTGCGC Sh3bgrl3 6138 CTGGACATTCTATTGTGTCC Gml0354 9958 ATCGGATCAATAGCAGTCTG Noval 2319 ACACGAATTCGACACCGCCC Nitl 6139 CAACACAGGCAGAGGTGGCC Ccr9 9959 GCAGCTGACCTCTTGACCAC Fbliml 2320 GTTAGGCTCCCTTGCTAAGG Rps6kal 6140 GTCCCTTCCATCTGCATTGC Tiel 9960 AAGTCCGTATGCTAATAAAG Topi 2321 AGAGCAGGGCGCGCTGTGAT Histlhlt 6141 ACGTATCCACTCATTAAATG Gpi68 9961 o GGGTGAGGAAACAGAAGCCA Slcolcl 2322 CACGGCCTGCTGGACTAGCC Smchdl 6142 GTTGCTGCAGGACGCAGTCG Caly 9962 4 TAAGATAGATGCCATTTCAA Tctexldl 2323 AGTGAATGCGCTCAGCTTGA 11 10034G24Rik 6143 GGCAGGGCAGTAGTAGAAAG Bpi 9963 o TCGGGACCAATGAGCTGCGC Sh3bgrl3 2324 CGGTTGGTTGTGGGTTCCCG Tmem222 6144 CGGGCGGCTGGCGAGGGACT Napll4 9964 GTTAGGCTCCCTTGCTAAGG Rps6kal 2325 CTGGACATTCTATTGTGTCC Gml0354 6145 GTTTCCGCATACCCAGCTTC Rapgef6 9965 GCAGAAGTGTGTGTGATGAG Chrm5 2326 CGGGCGCAGCCCTCCGTACA Cacna2dl 6146 GGTTAGCACTCGTGATTCTG Havcr2 9966 AGAGCAGGGCGCGCTGTGAT Histlhlt 2327 GTCCGGAGGACGTCACACTG Cagel 6147 CTTCTGGCGTGGAGCGCCGC Ccdc69 9967 CACGGCCTGCTGGACTAGCC Smchdl 2328 GTTGCTGCAGGACGCAGTCG Caly 6148 GGAGGAGGAGACACCTCAGC Sytll 9968 AGTGAATGCGCTCAGCTTGA 1110034G24Rik 2329 GGCAGGGCAGTAGTAGAAAG Bpi 6149 TTGAGGAGGGATGAGAGGAG Tdpoz2 9969 CGGTTGGTTGTGGGTTCCCG Tmem222 2330 CCTGGCACTCTTTGATGAAG Gabib2 6150 ATGACACGCTGGCTAATACC Txnrdl 9970 AATCAATGGCCTTCAATCCG Rims2 2331 CGGGCGGCTGGCGAGGGACT Napll4 6151 CCACCTGAGTCAAACAGAAC Tspyl3 9971 TTTGAGAGAATGCAGAAGCA Atpl3a4 2332 GTTTCCGCATACCCAGCTTC Rapgef6 6152 CCCGGGCTGGAGGATCAGCG Dst 9972 GGATAGCCCGACCCACCGAC Fibin 2333 GGTTAGCACTCGTGATTCTG Havcr2 6153 CGCGTGTCTTCTGTAGGATG Tubgcp2 9973 ATATAAGGACATTGGAAGAA SpllO 2334 CTTCTGGCGTGGAGCGCCGC Ccdc69 6154 GGATCCTCATCCTAACCAAG Secl412 9974 GTCCGGAGGACGTCACACTG Cagel 2335 GGAGGAGGAGACACCTCAGC Sytll 6155 GGTTTCCTAGCTACATCTTG Pafah2 9975 GTTGCTGCAGGACGCAGTCG Caly 2336 CCACCTGAGTCAAACAGAAC Tspyl3 6156 AGATAACTGTGTAAGAGCTC Cdl6311 9976 GGCAGGGCAGTAGTAGAAAG Bpi 2337 ACTCTTCGGTAGGACGATAG I g2 6157 CCCGCACAATAGCGGTGGGA Lin28a 9977 CCTGGCACTCTTTGATGAAG Gabrb2 2338 AGCGCCGCCCACTTGGCCAG 181001 3L24Rik 6158 GGCGTGCTGTCCTTTGCGGC Fhdcl 9978 CGGGCGGCTGGCGAGGGACT NaplU 2339 CTCCCAGAGCCTTCTGTCCC Ggh 6159 AATGGCAGTCTTTCTTTCCC Ccnjl 9979 TTAGTCCTTAGCGCAGTCTA P2iyl2 2340 GCGCCCTGCGACGCACCAGT Riokl 6160 CAGATGAAGACACGGAAGCG l l 9980 GTTTCCGCATACCCAGCTTC Rapgef6 2341 CGCGTGTCTTCTGTAGGATG Tubgcp2 6161 CTGTCACGCGGTCTGCTTGC 4921536K21Rik 9981 GGTTAGCACTCGTGATTCTG Havcr2 2342 GTTGGCACTGATTGTTCCTG Tmeml76b 6162 AAAGGGAGGAGACAAACGTT Grhl3 9982 CTTCTGGCGTGGAGCGCCGC Ccdc69 2343 AGCGAGGCTCGATCCGGCCT Rasa2 6163 TACGCGCTTGAGTGCGCGAG Ptprt 9983 GGAGGAGGAGACACCTCAGC Sytll 2344 GGATCCTCATCCTAACCAAG Secl412 6164 TTGGAAGGGAGAAAGACTTA Fucal 9984 CAGACGTATTTCrGAGTTCG Laip4 2345 GGTTTCCTAGCTACATCTTG Pafah2 6165 CGCGCTTGGAATGCATAGGC Arhgdib 9985 CCACCTGAGTCAAACAGAAC Tspyl3 2346 AGATAACTGTGTAAGAGCTC Cdl6311 6166 TGAACTCATCTCTAAGCTCT Ddrl 9986 ACTCTTCGGTAGGACGATAG Ing2 2347 CCCGCACAATAGCGGTGGGA Lin28a 6167 GGACCCAGGCTCTGACTAAC B3galt5 9987 CTCCCAGAGCCTTCTGTCCC Ggh 2348 AATGGCAGTCTTTCTTTCCC Ccnjl 6168 CCGCTCTCCATTCATAAATC Hcrtrl 9988 TGTGGGTTGGAGCTAGGGAA Unc79 2349 TGAAGGCGAGGGCTGGAAAG Dab2ip 6169 GACGCGCATGCGTGTCTCCA Rsrpl 9989 GCGCCCTGCGACGCACCAGT Riokl 2350 CTGTCACGCGGTCTGCTTGC 4921536K21Rik 6170 GGCCTCAGAGCAGGAACTAA Mips24 9990 CGCGTGTCTTCTGTAGGATG Tubgcp2 2351 AAAGGGAGGAGACAAACGTT Grhl3 6171 GGGCGCGAGGAACCCAGGGA Rcan3 9991 GTTGGCAC GATTGTTCCTG Tmeml76b 2352 CCTGCAGAGATTCCATAGCC Lmod3 6172 TTTATAACGTGTCGTTGAGA Cyp2el 9992 GGATCCTCATCCTAACCAAG Secl412 2353 TACGCGCTTGAGTGCGCGAG Ptprt 6173 AACATAAGCACCCATCAGCT Inpp5j 9993 n GGTTTCCTAGCTACATCTTG Pafali2 2354 TTGGAAGGGAGAAAGACTTA Fucal 6174 AACATGCGCTCCTGGGAAGA Psmg4 9994 CATCAAAGGATCACGTAGGA Tail 2355 AGCGCTCGCGGAACGCAACC Prkcq 6175 GGCGGCAGCGTCGTGAGGTG Cc2dlb 9995 TGGAATATCTCCCGCCGAGA Mcoln2 9996 ζ AGATAACTGTGTAAGAGCTC Cdl6311 2356 CCGCTCTCCATTCATAAATC Hcrtrl 6176 b CCCGCACAATAGCGGTGGGA Lin28a 2357 GACGCGCATGCGTGTCTCCA Rsrpl 6177 CTCTCCGGCATCTCTAGTTT Gucala 9997 AAGAGAGGCGACGGTTAGTA Impg2 2358 AAAGGCCACCAGCACTGAAA Hmgb4 6178 GACAGGGTATCCTAGCGGAG Haycrl 9998 GGGCTAATCCCTGGACGCCC Vav3 2359 GGCCTCAGAGCAGGAACTAA Mips24 6179 GATGTGATCGCAGCGGTGAT Chd6 9999 b CTGTCACGCGGTCTGCTTGC 4921536K21Rik 2360 GGGCGCGAGGAACCCAGGGA Rcan3 6180 CCCGCCTGCAGGCCAAAGCA Mytl 10000 GGTTGAAATTGTATTGAAGA Tbx22 2361 GCAAAGCAAAGAATTCAATC Vmnlrl95 6181 TCGGAAGCGGAACTCTGCCG Csk 10001 AAAGGGAGGAGACAAACGTT Grhl3 2362 TTTATAACGTGTCGTTGAGA Cyp2el 6182 AGGGACAGAAATGATCAATG Thsd4 10002 TACGCGCTTGAGTGCGCGAG Ptprt 2363 CTCTCAACACTGAGTCACGC Seel 6183 AGCATTGCTAGTCCTGTCCC Ddrl 10003 TTGGAAGGGAGAAAGACTTA Fucal 2364 GTTCCCAGTGAGGTTTGTCC Dctd 6184 TTTCAAACAACTATCGCGGG Ncapg 10004 CCGCTCTCCATTCATAAATC Hcrtil 2365 AACATAAGCACCCATCAGCT Inpp5j 6185 GGGACTTGTAGGAATACTGG Cldndl 10005 o GACGCGCATGCGTGTCTCCA Rsipl 2366 AACATGCGCTCCTGGGAAGA Psmg4 6186 TCATAT C AAACCAAACATA Xcrl 10006 ACACTTGTGAGGGCTGCTCT Prex2 2367 AAGGCAGGGTCTGAGAGCAC ZdhliclS 6187 GCTCTCGACCAATCGGCGCT AU040320 10007 AAAGGCCACCAGCACTGAAA Hmgb4 2368 AAGTACAGTGGAGCTACAGC Secl6b 6188 ACTAATTGGAGCCCATGAGA Rnfl85 10008 5 GGCCTCAGAGCAGGAACTAA Mips24 2369 GACAGGGTATCCTAGCGGAG Havcrl 6189 GCCGATGGATCTTGTCGACG Ptpru 10009 o GGGCGCGAGGAACCCAGGGA Rcan3 2370 GATGTGATCGCAGCGGTGAT Chd6 6190 CTACAGCAAGTTATTTGAAG Uspl71b 10010 4 TGTTGCTAAACATGATTAAG Dnah5 2371 GCTCTCGACCAATCGGCGCT AU040320 6191 GCAGAGTAGGGTTTCAAAGC Sgcd 10011 TTTATAACGTGTCGTTGAGA Cyp2el 2372 ACTAATTGGAGCCCATGAGA Rnfl85 6192 GGAGGCGCCGAGCCGTCCTG Raplgdsl 10012 ATCTTCAAGATCCTGGTTGG Acnatl 2373 GCCGATGGATCTTGTCGACG Ptpru 6193 GCCAAAGCCTTAGCTGGCCC Bnip2 10013 GTTCCCAGTGAGGTTTGTCC Dctd 2374 AGCCATCTTGAGTTCCGGCC Mpz 6194 AACACTCCTGTCACCCATTT Runx2 10014 AACATAAGCACCCATCAGCT Inpp5j 2375 CGCCGTGCGGAGTCCTTCCT Lamal 6195 ACACTCAAGAGTTCTTGACC Cfap46 10015 AACATGCGCTCCTGGGAAGA Psmg4 2376 TCCATGGGCAGTCCTATTAT Dmd 6196 GCGGCTTTCTCTAGCCCGGT Zraym6 10016 AAGGCAGGGTCTGAGAGCAC Zdhlicl8 2377 TTTGCCTTGGTTCCCGGAGC Klhdc7a 6197 TAACCTAGTGGCTGTGTTGG Tspan32 10017 AAGTACAGTGGAGCTACA GC Secl6b 2378 GCAGAGTAGGGTTTCAAAGC Sgcd 6198 CCCTGTCAAAGGGCGGA AAG Arll3b 10018 GCAAGTCCTTCTAGCGACTG Dclkl 2379 AGGTGCAGTGTGTGTCACGC Pccb 6199 TATCAACACTATACAGCCTG Rliag 10019 GCGGCTCGGGCTGGCCGCTT Wwcl 2380 AACACTCCTGTCACCCATTT Runx2 6200 CCGGAGGCCGCTTTCCCGTT Senp2 10020 GACAGGGTATCCTAGCGGAG Haycrl 2381 ACACTCAAGAGTTCTTGACC Cfap46 6201 CCGGCTGCCTACAGTCCGCG Dis31 10021 GATGTGATCGCAGCGGTGAT Chd6 2382 TTTCCCTAAGAAGTCAAGTA Acsll 6202 GGGAAGATCTGAATCTCTCC Fancc 10022 TGCTGATGCrGTAGCCTGCA Adam23 2383 GCGGCTTTCTCTAGCCCGGT Zmym6 6203 GGTAGACGTGGAACAGGTAA Rpp21 10023 GAGCGTCACFGACAACCACC Slfl 2384 ATATATGATAGTAGCGTTAG Bend5 6204 TTTCCGGGCTTCTAGTTTCT Svbp 10024 GCTCTCGACCAATCGGCGCT AU040320 2385 TAACCTAGTGGCTGTGTTGG Tspan32 6205 CAGGGCTCCTTGAGCGTCCC Vps8 10025 ACTAATTGGAGCCCATGAGA Rnfl85 2386 CGTGGTGCGCCCACACTTCC Thgll 6206 CTAGAGTAGGAGTATACTTT Nf2 10026 CGCCGTGCGGAGTCCTTCCT Lamal 2387 TCCCTAAAGGCAATTCAAGC Pldl 6207 GGCCTCTGACCA CTTTGGCC Nlixl 10027 TTTGCCTTGGTTCCCGGAGC Klhdc7a 2388 GGCGTGACGTCGCCACGCGC Nrbf2 6208 GCAAATGACATGTCAGTGGG 1700001C19Rik 10028 GCAGAGTAGGGTTTCAAAGC Sgcd 2389 CCCTGGCTTGTAAGGCAGGA Brinp3 6209 AGGCCATGATGGACTCCGCG Slc22a2 1 10029 ACACTCAAGAGTTCTTGACC Cfap46 2390 CTAGAGTAGGAGTATACTTT Nf2 6210 GCGGTCACCGCACAAGCAAG Sema7a 10030 TTTCCCTAAGAAGTCAAGTA Acsll 2391 AGGCCATGATGGACTCCGCG Slc22a2 1 62 GGATGGGAGGATAGTCAGAG Bpiib4 10031 GCGGCriTCTCTAGCCCGGT Zmym6 2392 TGGTGGAGCGTCACGTCGCC Nrk 6212 AGCGAACGCTGCTTTCGACC Ddrl 10032 ATATATGATAGTAGCGTTAG Bend5 2393 GGATGGGAGGATAGTCAGAG Bpifb4 6213 AGACCGGAAGCAGACACGGA Taf7 10033 TAACCTAGTGGCTGTGTTGG Tspan32 2394 GTTTGCACCTAGAAGGTGTT Tgm6 6214 AGGCCGTGGACCCTGGTAAG Vegfa 10034 AAGTAATCTGCAGGCTGCCG Epha5 2395 AGACCGCCTAAAGGCGAAGC Nxf2 6215 TCCTAAGCGCTAAAGGGAAA Arhgef2 10035 CTAGAGTAGGAGTATACTTT Nf2 2396 GATATTAATGAACCTCCAAG Nr2el 6216 GTTCCGGCGCCATCGCGTTT Map2k5 10036 GAATAAGTCGCCAGAACTTG Myo3b 2397 GGGACCCGGTCTATTGTCAA Ak4 6217 TATATCTAAGCGCCCTCTCG Snapin 10037 AGGCCATGATGGACTCCGCG Slc22a21 2398 GACGCACCACGGAGCCGGAC Gtf2hl 6218 TCGGTGATGGAACACACTGT Gbp3 10038 ACGTGGGTAGTGAGGTGTCC Plbl 2399 TACGTAGCTGGCGGGCTCTG Smchdl 6219 GGAGAGGCCCACGTGACGCA Btf314 10039 TGCAAGATGCTGCGCGCCCG Dnah 2400 ATAAGAGCAAGAGAGAGCTT 492 153 9E 1IRik 6220 TTTACAAACAGAGCTAGATA S100a5 10040 TGGTGGAGCGTCACGTCGCC Nrk 2401 CATTGCGGGTAGCAACTGAG Top2b 6221 ATGCAGACATGGAGTCTCTC Histlh4b 10041 n GGATGGGAGGATAGTCAGAG Bpifb4 2402 ATGCAGACATGGAGTCTCTC Histlh4b 6222 AAGGGCAGGGACGGTACTCA Eif4enifl 10042 GATTGGACAGGAGGTGTTAG Ephbl 2403 AGAGGTAGTTAAGCCAATCC Rnfl48 6223 CCTGATTGGTTGCCAAGAGG Lyrm7 10043 GTTTGCACCTAGAAGGTGTT Tgm6 2404 AGTAAACGCTACTACTTGAT Histlh2bc 6224 CAGAACCTCCAGAGAGTGTG Lbp 10044 n AGACCGCCTAAAGGCGAAGC Nxf2 2405 AAGGGCAGGGACGGTACTCA Eif4enifl 6225 GCACAGGACATGATGCTCCT Mycs 10045 o GGGACCCGGTCTATTGTCAA Ak4 2406 TAAGGGAGGAAGGGTCCCGG Tfap2a 6226 GTGGCCGAAGAGGAGCGAAC Ewsrl 10046 5 TACGTAGCTGGCGGGCTCTG Smchdl 2407 CCTGATTGGTTGCCAAGAGG Lyrm7 6227 CTACTTGACAGAATTCCAAA Glccil 10047 b ATAAGAGCAAGAGAGAGCTT 4921539EllRik 2408 GCACAGGACATGATGCTCCT Mycs 6228 TTAGGAGCTCTCACTTTGCG Txnrdl 10048 5© CATCTATCTTGACAATTTCA Obox7 2409 GTGGCCGAAGAGGAGCGAAC Ewsrl 6229 ATGACTACTCTCACCTCCAC 01frl328 10049 J GGTGAAGAGGGTCCTGGATG Abcc9 2410 CTACTTGACAGAATTCCAAA Glccil 6230 TAACAATGTCCTGCGTTTCC Tns3 10050 GTTTCTGGCTGCAGTGAGAG Fbx 9 2411 GCACAGAGTCTCCGCTACTC Csmd3 6231 CTGGGCTGGCAGTAGGACAA Gal3stl 10051 ATGCAGACATGGAGTCTCTC HistlMb 2412 TGTGTCAGGATTGTGTGGCC Rosl 6232 GTGCGCCCTGTGCTCAGGCG Cd2ap 10052 AGAGGTAGITAAGCCAATCC Rnfl48 2413 TAAGCTAGGAAAGATGGAGG Gpnmb 6233 AATTCCTGCCATGCTGCCCT Hacd4 10053 o GAGGACTTCGCCAGCGGCTT Tbpll 2414 GAACTACCTACAGGCACAGA SkintS 6234 CTCACGAGAAGACGTAGTCA Taf7 10054 AAGGGCAGGGACGGTACTCA Eif4enifl 2415 TAACAATGTCCTGCGTTTCC Tns3 6235 GGTGGAGTTTCCGACCGGGC Ccm21 10055 TAAGGGAGGAAGGGTCCCGG Tfap2a 2416 CTGGGCTGGCAGTAGGACAA Gal3stl 6236 CATTGTTGTGATCACTGCAC Lbp 10056 5 CCTGATTGGTTGCCAAGAGG Lyrm7 2417 GGTGGTGCAGCAGGTGCCCA Arhgefl6 6237 TTGAGGAGTAAATAGCACCT Ifnlrl 10057 o CAGAACCTCCAGAGAGTGTG Lbp 2418 AATTCCTGCCATGCTGCCCT Hacd4 6238 AGACGGGCCCGATTGGCTGC Uaca 10058 4 GCACAGGACATGATGCTCCT Mycs 2419 GGTGGAGTTTCCGACCGGGC Cem21 6239 AAAGCACTCAGTTAGCTGGC Ifi47 10059 GTGGCCGAAGAGGAGCGAAC Ewsrl 2420 TTACTATGGACGTGAGATGT Cdkn2c 6240 GCTCAGCCCAAGAGATTGTC Nacad 10060 CTACTTGACAGAATTCCAAA Glccil 2421 GGGTGCTGACCTGCGCACCC Barx2 6241 CTACTTGATTGTGCCTGCTG S100a4 10061 GCACAGAGTCTCCGCTACTC Csmd3 2422 TTGAGGAGTAAATAGCACCT Ifnlrl 6242 AGCTGGGCGACTGGAACCAA Srrml 10062 TAAGCTAGGAAAGATGGAGG Gp b 2423 CCGGATGCGGCTGTCCTCTA Ndufa4 6243 TTGTCTGCTGAACCAAAGCG Serinc2 10063 AACTG GCGGGAGGC GAGAA Abca9 2424 AAAGCAGGTGTTAAGGGAAC Agrp 6244 GCGGCCTGCCACTCACGCGC Kremenl 10064 GAACTACCTACAGGCACAGA SkintS 2425 CATGACCTCGCGCAGGGAAA Pena 6245 CATGTGTTTACATATCTATC Hgf 10065 TAACAATGTCCTGCGTTTCC Tns3 2426 AAAGCACTCAGTTAGCTGGC Ifi47 6246 AGCGGCAGGTTCTCAACCCG Lama3 10066 GTCTGTCGTAAACCTGGCAC Nkx2-4 2427 GCTCAGCCCAAGAGATTGTC Nacad 6247 AAGTAGGAGCAACTTCCTCA Ifi47 10067 CTGGGCTGGCAGTAGGACAA Gal3stl 2428 TTCTTCTATTACAGGTGGCC Fatl 6248 CGCAGAGAACTCGAGCCGGA Shrooml 10068 GGTGGTGCAGCAGGTGCCCA Arhgefl6 2429 AGCTGGGCGACTGGAACCAA Srrml 6249 TACTCCAGGTACCTACAAGT Tinagll 10069 AATTCCTGCCATGCrGCCCT Hacd4 2430 TTGTCTGCTGAACCAAAGCG Seiinc2 6250 GAGCCAATCAGAGCTGGCGG Extll 10070 GGTGGAGTErCCGACCGGGC Ccm21 2431 GCGGCCTGCCACTCACGCGC Kremenl 6251 GCGCGCGCAGCTTCCACTCG Foxkl 10071 TTACTATGGACGEGAGATGT Cdkn c 2432 CATGTGTTTACATATCTATC Hgf 6252 AGAGTTTGGAGATGGTGTCC Cebpzos 10072 CATTGTTGTGATCACTGCAC Lbp 2433 CTGCTTTGTGCTGGTTCTTA Chn2 6253 GTATGTGAAATGTATTTCGT Caly 10073 GGGTGCTGACCTGCGCACCC Baix2 2434 CTCTCGCCTGGGCGCGGAAA Bend5 6254 GTGTTGTTAGAAGGAGAAGC Lif 10074 TTGAGGAGTAAATAGCACCT Ifnlrl 2435 AAGTAGGAGCAACTTCCTCA Ifi47 6255 AACTAACAAGGTCACACTGA Col9al 10075 CCGGATGCGGCTGTCCTCTA Ndufa4 2436 GGAACAGATG GCAAGA GACC Tnncl 6256 AGCCCTGGCGAAGGCACTAC Pgbdl 10076 CATGACCTCGCGCAGGGAAA Pena 2437 CGCAGAGAACTCGAGCCGGA Shrooml 6257 TGCGCACAAAGCCGCCACGG Gmebl 10077 AGGCGCACCGTGCGGTGCGG Hfml 2438 GGCGGAGCATAGCGAGGACT Cenpu 6258 GAAGCGTGAAGTACAAGGCG Hcrtrl 10078 AAAGCACTCAGTTAGCTGGC Ifi47 2439 TACTCCAGGTACCTACAAGT Tinagll 6259 CGGCTCCTTCGTTGGGATCC Cabp7 10079 GCTCAGCCCAAGAGATTGTC Nacad 2440 GAGCCAATCAGAGCTGGCGG Extll 6260 AGTCTGTGTTGTATCTTCTC Adgrf4 10080 TTCTTCTATTACAGGTGGCC Fatl 2441 GTATGTGAAATGTATTTCGT Caly 6261 TCAGCTTTGCTTAGGTAGTT Mfsd2a 10081 AGCTGGGCGACTGGAACCAA Srrml 2442 CGCTCCGCCTAAGAAGTGCG Sstr4 6262 GGACAAGTCACGCAGAGTTG Rpp25 10082 TTGTCTGCTGAACCAAAGCG Serinc2 2443 CGAGCGCCCTCAGCTACACC ZkscanS 6263 TCGTGGGTCTCACTCAGCCG Oxct2b 10083 GCGGCCTGCCACTCACGCGC Kremenl 2444 GTGTTGTTAGAAGGAGAAGC Lif 6264 CTGTGGTTGCGCTGGTGACA Dnahl7 10084 CTCTCGCCTGGGCGCGGAAA Bend5 2445 AGCCCTGGCGAAGGCACTAC Pgbdl 6265 GAAGGATGTGAATGAGCCAG Hcrtrl 10085 AAGTAGGAGCAACTTCCTCA Ifi47 2446 TGCGCACAAAGCCGCCACGG Gmebl 6266 ACATGGACCACATTGGCCTT Coro2b 10086 CGCAGAGAACTCGAGCCGGA Sh o l 2447 GAAGCGTGAAGTACAAGGCG Hcrtrl 6267 AATTCCTCAGATGGGCGAGG Tpral 10087 GGCGGAGCATAGCGAGGACT C pu 2448 CGGCTCCTTCGTTGGGATCC Cabp7 6268 AGTATAGTAAGAACTCTCTT Pcdhl 10088 TACTCCAGGEACCEACAAGT Tinagll 2449 CAAGTCTGAGTTGGAGCTGG Mumlll 6269 TATGATGACGCCTTGTCCTG Slc24a2 10089 n CTGGTGAGAGTCATCAACCT Ppplrl6b 2450 GAAGGATGTGAATGAGCCAG Hcrtrl 6270 GGATGCTTTGTCGCGTCGTC Stard6 10090 GAGCCAATCAGAGCTGGCGG Extll 2451 TGGCGCAAGTCGGCCGGAGG Casp3 6271 GACCTTTAAACAGCCAGCGT Lrat 10091 GCGCGCGCAGCTTCC ACTC G Foxkl 2452 CATGCGAGAACGCTCAACCA Apafl 6272 TAGAACCCGGAGCGCTTCCT Bmp8b 10092 n GTATGTGAAATGTATTTCGT Caly 2453 TATGATGACGCCTTGTCCTG Slc24a2 6273 GGAAGGCGGTGACGCGCTCC Stard6 10093 o GTGTTGTTAGAAGGAGAAGC Lif 2454 CAGACACAGATATAGAGATT Nxf2 6274 CAGGGCGCGGAGAAAGTTTG Cchcrl 10094 5 AACTAACAAGGTCACACTGA Col9al 2455 GAAAGAGATTCCCTGCTCCC Pde4b 6275 GCAGCGGCACCTGTACTTGC Tubgcp2 10095 b AGCCCTGGCGAAGGCACTAC Pgbdl 2456 GCAGCGGCACCTGTACTTGC Tubgcp2 6276 TGGAGGCGTTCCTTGTTTGA Nlixl 10096 5© TGCGCACAAAGCCGCCACGG Gmebl 2457 CTTGCAGAGTTTGTGAAGCG Copg2 6277 CCAGCTGCAGGGCTGTGCAG Map4kl 10097 J TGATGGCCACGTGGCCTCGC ArhgeflO 2458 AGAAGTTGAAATCTAGAACT Havcrl 6278 AAGGGAGAGAGCTCTAAGGC Myol5 10098 CCATGACAACCAGCTTGCGC Nyap2 2459 GCCTGCGCTCGCAGTGCTTG Wnt2 6279 TCCAGGCCACGATCCAGCCC Foxkl 10099 GAAGCGTGAAGTACAAGGCG Hcrtil 2460 CTACTTTCTCTGCACGTGGG Paics 6280 AGAAGTTGAAATCTAGAACT Havcrl 10100 CGGCTCCTTCGTTGGGATCC Cabp7 2461 GATGGCCTTGGCCCTAACTG Klhdc7a 6281 TCAACCAATACAGCAAGCCT Iqsecl 10101 o GAAGGATGTGAATGAGCCAG Hcrtil 2462 GATCTTCACGTCCCAAGCTG Zfp282 6282 GGAAGAGTGCCTGCAAATGG Cdl9 10102 TGGCGCAAGTCGGCCGGAGG Casp3 2463 TGGTGACCTGGAGGACAATG Gml2171 6283 GAACAGACTAACAGGCCACC Dsg3 10103 GGTGAGGAAAGTCCGCCCTC Shisa3 2464 GAATGAATCACAGTGAGAGT Arhgap40 6284 GGGAGGCGCCACGCGGAGGA Adaml9 10104 TATGATGACGCCTTGTCCTG Slc24a2 2465 CCCGGGCGCTGAGTTGGGCG Adcyl 6285 CTCATTGATAAATACCGCCC Tuftl 10105 o CAGACACAGATATAGAGATT Nxf2 2466 TCTGCGTGGGTTCCCTTCTC Cdk5rapl 6286 ACGCGCCTGCCCATCTCGGC Mfsd2a 10106 4 GCAGATGAGGAGCGCGGCGA Msil 2467 TGACAGACCAGGAGAGCAAG Htrld 6287 TCCTCCGCAGTACTTTATTT Hmg20a 10107 GAAAGAGATTCCCTGCTCCC Pde4b 2468 AGACTGCTGTGACGACCAAT Stil 6288 CAGCCTAAGACTGGCAGACA Nr2f2 10108 GCAGCGGCACCTGTACTTGC Tubgcp2 2469 ATTAGCTTTCTCGGCTTCTA Slc26a8 6289 TGGTGACCTGGAGGACAATG Gml2171 10109 TCCAGGCCACGATCCAGCCC Foxkl 2470 GAGCGAGCGCAGCGCAGCAG Aridla 6290 GAATGAATCACAGTGAGAGT Arhgap40 1 110 GCGTGATrGGAGGGCTGTGC S pa 2471 TGTGACACCAGCTTTCTTAA Bpifb5 6291 CCCGGGCGCTGAGTTGGGCG Adcyl 10111 AGAAGTTGAAATCTAGAACT Havcrl 2472 CAGTGTCGCGGTGACCTTTA Dctd 6292 TCTGCGTGGGTTCCCTTCTC Cdk5rapl 10112 GCCTGCGCTCGCAGTGCTTG Wnt2 2473 ATGAATGCCTTCAAGTCTGA Ppplr3g 6293 ACAGATGTCATCTCTTCCTT Mrgprg 10113 GAACAGACTAACAGGCCACC Dsg3 2474 CTAGGACGCGGTAACATGGT Raver2 6294 TGACAGACCAGGAGAGCAAG Htrld 10114 AAAGCCTTAACTCAGGAATG Plbl 2475 CCGCCACCACGCCTTTATGA Myocd 6295 GTCATGCTCCCTGGACACAT Vmn2r87 10115 GATGGCCTTGGCCCTAACTG Klhdc7a 2476 GGGCGTCTTGGGCGAGCTTG Pttgl 6296 TGTGACACCAGCTTTCTTAA Bpifb5 1 116 GATCTTCACGTCCCAAGCTG Zfp282 2477 GGCACGTGCGGCGCGTGCGC Bnip3 6297 CTCTAAAGGGTTAAGGCCTA Nes 10117 TGGTGACCTGGAGGACAATG Gml2171 2478 GCAGAGCCTCGTGGCTGTGG Gm5111 6298 GCTGAGGGCAGGGCTTGAAT Gm7030 10118 GAATGAATCACAGTGAGAGT Arhgap40 2479 CGGGTAACCCACAGACTTGT Tmem50a 6299 AGCAGAATCTGCGCTTCTCC Iqsecl 10119 CCCGGGCGCrGAGTTGGGCG Adcyl 2480 ACGGTGAATAATCAAACTGG Plat 6300 GGGCGTCTTGGGCGAGCTTG Pttgl 10120 TCTGCGTGGGTrCCCTTCTC Cdk5rapl 2481 GCGAATGAAACCCTTCCGGG Golga7 6301 ATTAAACTTAGGGCATTGCC Bstl 10121 ACAGATGTCATCTCTTCCTT Mrgprg 2482 GTTTGTGGGCGTTGCATAGG 2610020H08Rik 6302 CTCCCTCGGGTTCGAGTGAT Pogz 10122 TGACAGACCAGGAGAGCAAG Htrld 2483 AGACAATAGAATGTCCAGGA Speer4e 6303 TTTAGGGTGGAGATCCAGAC Dsgla 10123 AGACTGCTGTGACGACCAAT Stil 2484 TAATCAATCACCGCTCTAAA Scn8a 6304 GCAGAACCCGGCTGTGCCTC 17000 17B05Rik 10124 GAGCGAGCGCAGCGCAGCAG Aridla 2485 GGTCCCAGACGACTAGACTT Prg4 6305 GGCACGTGCGGCGCGTGCGC Bnip3 10125 ACAGAAGGTTTGGAGAAGCC Nyap2 2486 ACACTCACCAGAGCTACTGT Bpifa3 6306 GAGATTTCTCATAACTTTGG Etl4 10126 TGTGACACCAGCTTTCTTAA Bpifb5 2487 TCAGTTCCGCAGCTTAAGGA Ccngl 6307 CGGGTAACCCACAGACTTGT TraemSOa 10127 ATTGGTCACGAGCTCTGGAC Epha4 2488 AGCAGTAAGCACAGTGTGCC Leap2 6308 TCATATGACAGCTCACGTCA Bdnf 10128 CAGTGTCGCGGTGACCTTTA Dctd 2489 GCGCACTAAGCTGACTGCGC Spen 6309 AAGAGTCGCTCAGTTCAGGG Snupn 10129 ATGAATGCCTTCAAGTCTGA Ppplr3g 2490 AGAGAGCGGGAATGCTGTTC Sgcd 6310 AAACTCCAGCTAAACTCGGA 9130008F23Rik 10130 CTAGGACGCGGTAACATGGT Raver2 2491 CCTTCTCTTCTTCATGGGAC Dnah7b 6 AGACAATAGAATGTCCAGGA Speer4e 10131 GAGCGTAAAGTACGCAAACA 383O406C13Rik 2492 CAGAAACATAGGCTCGCCCG Purb 6312 TTGAGCGAGGCACTGACTAG 9130008F23Rik 10132 CCGCCACCACGCCTTTATGA Myocd 2493 CTCGGATCGGCGGGAGGCAG Barx2 6 ACACTCACCAGAGCTACTGT Bpifa3 10133 GGGCGTCrTGGGCGAGCTTG Pttgl 2494 CAATTGGTCCCTCCGAGAGG Pttgl 6314 TCAGTTCCGCAGCTTAAGGA Ccngl 10134 AAATACGCAACAGCGTGAGA Wdr36 2495 AGGTTTAGGGTCTATGGACT Lrrc27 63 5 AGCAGTAAGCACAGTGTGCC Leap2 10135 GGCACGTGCGGCGCGTGCGC Bnip3 2496 TGCTAGCTGACAAATAGACT Shank2 6316 AGAGAGCGGGAATGCTGTTC Sgcd 10136 GCAGAGCCTCGTGGCTGTGG Gm5111 2497 GGGCCT GTTTGTGCCCTGT Cldn22 6317 TTGCTACGTAGCGGAGAGCC Mcoln2 10137 n CGGGTAACCCACAGACTTGT Tmem50a 2498 CCTGTGAGGGCAAGCAGGAG Lhfpl5 6 GGCTTCTTGAACTGATTGTG 1700042G07Rik 10138 ACGGTGAATAATCAAACTGG Plat 2499 CCTCCCAAGCCTCCAGGACA Gm906 6 9 CCTTCTCTTCTTCATGGGAC Dnali7b 10139 GCGAATGAAACCCTTCCGGG Golga7 2500 GACGCCAAACAGACCAATCG Sec22c 6320 GGGTGCAAGCGCCGGAGACC Arfipl 10140 n ACCCAGGTTGCTAAACAATT Vay3 2501 GCGGGCGGCCCTGCAGGCTG Nfia 6321 CAGAAACATAGGCTCGCCCG Purb 10141 o AGACAATAGAATGTCCAGGA Speer4e 2502 GGGACGAGTGGAACATCGCG Vegfc 6322 CAATTGGTCCCTCCGAGAGG Pttgl 10142 ACACTCACCAGAGCTACTGT Bpifa3 2503 CGTGGCACAAGGAAGAAGAG Fam221a 6323 CGTATCTATGGACTACAGGA Qpct 10143 b CCGCCTCCTTAGACTTGACA Foxsl 2504 GGCCAATCAGCTGTTCGCAG Slc25a53 6324 AGGTTTAGGGTCTATGGACT Lrrc27 10144 GCGCTGCGCATGCTCGACTG Adam23 2505 AATCTAAAGAGTTGTCCCAG Secl413 6325 ATGCGCCGTGCAATTGGCGC Heatr5b 10145 J TCAGTTCCGCAGCTTAAGGA Ccn l 2506 AGTGCTGAGGTGTCCCACGT Ct 6326 TACTACTTGAAAGGGCTTCA Clqtnf7 10146 AGCAGTAAGCACAGTGTGCC Leap2 2507 CGAGAGCGCGGCTCGCGAGT Vdacl 6327 GTTTGGCCTCCTGATGTTGG Mga GCGCACTAAGCTGACTGCGC Spen 2508 CATATCTGGTGATTAAATCA Psap 6328 CCTCCCAAGCCTCCAGGACA Gm906 AGAGAGCGGGAATGCTGTTC Sgcd 2509 GTGCTGCAGGGAATGTATGG Gpm6a 6329 TCTTT GGAG GGCATC ATCGC Glib CCTTCTCTTCTTCATGGGAC Dnah7b 2510 GACTGTCATAGGACAGCTCT MedlS 6330 GGGACGAGTGGAACATCGCG Vegfc CAGAAACATAGGCTCGCCCG Purb 2511 AGGTGGTGCTGTCTATCCCT Nrfl 6331 AATCTAAAGAGTTGTCCCAG Sec 1413 CTCGGATCGGCGGGAGGCAG Barx2 25 12 TACAGTTACCCTGATGGGCG 1700003F12Rik 6332 TGCATTTGTGAGCGGATTCA Opn5 ATTAAGCTGTCGTGAGCAAA Zzefl 2513 TTCTAGCGATTGTTAACGCC Trim27 6333 CGAGAGCGCGGCTCGCGAGT Vdacl CAATTGGTCCCTCCGAGAGG Pttgl 2514 AAGCTGATGAGG CCA GGCGT Agrp 6334 CTCGCCATCAATCTTGACGT Tcergl GGTAAATACTTTGACCGTTT Nlgnl 2515 CACCAGATTGTCAGTTATTC 114 6335 GACTGTCATAGGACAGCTCT Medl8 AGGTTTAGGGTCTATGGACT Lrrc27 2516 CACAGCGAGGCCAAGGCGGC Chn2 6336 TACAGTTACCCTGATGGGCG 1700003F12Rik TGCTAGCTGACAAATAGACT S ank2 2517 CATCACCTGCTGTGAAATGT Gm94 6337 CAAATCTACTCTTTCAATCT Ryr3 GGGCCrrGTTTGTGCCCTGT Cldn22 2518 GCTGAGGAGGCGGAGCTCCC Capza2 6338 TTCTAGCGATTGTTAACGCC Trim27 CACTGCTGAGTGGTAGGCAG Bboxl 2519 TAATTGTGACGCACCAAGGC Dadl 6339 CACCAGATTGTCAGTTATTC 114 CCTCCCAAGCCTCCAGGACA Gm906 2520 CACACATCCCAGATTGAGGG Timd4 6340 ACCGTTGGCTCTGGGCCTTG Eri3 GACGCCAAACAGACCAATCG Sec22c 2521 GCTGGCAGGAAGGTCGGCTG Pafah2 6341 CATCACCTGCTGTGAAATGT Gm94 GCGGGCGGCCCTGCAGGCTG Nfia 2522 ACTCGCAACCCGACTCCGCT Epha7 6342 TAATTGTGACGCACCAAGGC Dadl GGGACGAGTGGAACATCGCG Vegfc 2523 TCTGGGCGGATAGGTGGGTG Smox 6343 AAACCTTCGCTACCCGCACG Sema7a CGTG GCA CAAG GAA GAAGA G Fam221a 2524 GACCGGTCCCGTAGAGTGTA TmemllS 6344 GTTAGATGGGCTGGGAGTGG Itgall GGCCAATCAGCTGTTCGCAG Slc25a53 2525 GGAGTCACGCCTCCGGTTCC Pold2 6345 CACACATCCCAGATTGAGGG Timd4 AATCTAAAGAGTTGTCCCAG Sec 14 3 2526 CTGAAAGGCGCACCCTGCCC Nrk 6346 GCTGGCAGGAAGGTCGGCTG Pafah2 CGAGAGCGCGGCTCGCGAGT Vdacl 2527 TCACCGGGCTGGGCCACTGC Eif4enifl 6347 CGAAAGCGGAAACACCTACA Ttc22 GTGCTGCAGGGAATGTATGG Gpra6a 2528 TGAGTGGCTGCGAAAGGGTG Btk 6348 AACTTAGGAGTCTATCCTGA Pate2 GACTGTCATAGGACAGCTCT Medl8 2529 CATGATTCTGCAAGCCTTAC Skint2 6349 GGTGCTGTTCGGGTTGAAGG Fhdcl AGGTGGTGCTGTCTATCCCT Nrfl 2530 GCTCTGTTAGGAAGGCATGA Ttn 6350 GGTAGACTTTAGACAGACTT Cd276 TACAGTTACCCTGATGGGCG 1700003F12Rik 2531 GTTTCTTCCCATCAATGTCC Hfe 6351 GGAGTCACGCCTCCGGTTCC Pold2 CAAATCTACTCTTTCAATCT Ryr3 2532 GTGCCCGCGGCAGCTCCGGT Wdsubl 6352 TCACCGGGCTGGGCCACTGC Eif4enifl TTCTAGCGATTGTTAACGCC Trim27 2533 TCAAAGATACACTGCCTCCC Gjb3 6353 GCTCTGTTAGGAAGGCATGA Ttn CACCAGATTGTCAGTTATTC 114 2534 CTGAATGAGGCGCCGCGCGG L p 6 6354 TTCGATAAGCTCTAATGCTG Emm GAGGATGCTTrCGCGAAGCC Pdyn 2535 TGTCTGATGCACAGATTACT Zfp354a 6355 CAGACTGCACATCAATTATA Fbxw7 CATCACCTGCTGTGAAATGT Gm94 2536 GAGGCTGTTCCCTAGCGCCG Evalb 6356 GGAAGCTGGGAGAGGGACGG Bdnf GCTGAGGAGGCGGAGCTCCC Capza2 2537 CAGCTTCGCCTTTGCGCAAC Snkgll 6357 CTGAGATGAAATGGATAGAG Itgax TAATTGTGACGCACCAAGGC Dadl 2538 TCCATCATGACCTTTCAAGG Bpifb9a 6358 GTTTCTTCCCATCAATGTCC Hfe CACACATCCCAGATTGAGGG Timd4 2539 AGGAGGAGGGAGGCCGACGC Cdhll 6359 TCAAAGATACACTGCCTCCC Gjb3 GCTGGCAGGAAGGTCGGCTG Pafah2 2540 GTCTGCAATATGCTGGGACC Evalb 6360 AGGGAATTTATGCATCTAAT Selenbp2 AACTCCGGCCGAGAACACCC Axin2 2541 AGAGCGAAGCTTGCGCTTTG Paqr7 6361 CGCGCTCCCGCCTCGGCGTA Supt3 ACTCGCAACCCGACTCCGCT Epha7 2542 CCCACCGCGTATGCAAAGGC Pena 6362 TGTCTGATGCACAGATTACT Zfp354a TCTGGGCGGATAGGTGGGTG Smo 2543 AAGGGTTGCTGACAGATAGG Tspan32 6363 GAGGCTGTTCCCTAGCGCCG Evalb CTGAAAGGCGCACCCTGCCC Nrk 2544 AGAGCCAAAGGGTTAGGAAC Emilin2 6364 CAGCTTCGCCTTTGCGCAAC Snhgll TCACCGGGCTGGGCCACTGC Eif4emfl 2545 GCGTAATCTTACTGCATCCC Pafah2 6365 TCCATC ATGA CCTTT CAAGG Bpifb9a TGAGTGGCTGCGAAAGGGTG Btk 2546 AGTGGGTTCTCTATAGGCGG Ubap2 6366 GCGGTGACTGGGACATTTCC Prosl CATGATTCTGCAAGCCTTAC Skint2 2547 AAAGATGGCGACTGCACACC Atp6v0al 6367 GTCTGCAATATGCTGGGACC Evalb GCTCTGTTAGGAAGGCATGA Ttn 2548 GCGAGAGAGGAGGGAGCCTG Lmo2 6368 AGAGCGAAGCTTGCGCTTTG Paqr7 TGGGAAGGAAGGAATTTATG Etnppl 2549 CGTCGCTTTACGGCCGGAGG Golga7 6369 AAGGGTTGCTGACAGATAGG Tspan32 GTTTCTTCCCATCAATGTCC Hfe 2550 CGAGTGACGCGGCGCCAGCC Gmds 6370 GCGTAATCTTACTGCATCCC Pafah2 TCAAAGATACACTGCCTCCC Gjb3 2551 AACGGGAGATAGGCGGAGTC Soxll 6371 AGAATAGAAACCACCGCCTC Kcnsl TGTCTGATGCACAGATTACT Zfp354a 2552 AGGTCTGCACTTGTCCGCTC Nefh 6372 GCAGAAAGAGCTCACATTTC Fgg GAGGCTGTECCCrAGCGCCG Evalb 2553 CAATCGCTGTTGCCCTGCCG Trim63 6373 TGCCTGTGCCGGCCACTGGG Dis31 CAGCTTCGCCTTTGCGCAAC Snkgll 2554 GGGCGCCAAATTCAAATCTG 11 10059G10Rik 6374 CGAGTGACGCGGCGCCAGCC Gmds TCCATCATGACCTTTCAAGG Bpifb9a 2555 TCGACCCTGATACTTGATTG Dync2hl 6375 AGTGAGCAGCCTGACTTCTC Dao 10195 AGCATTCACCAGGATATTGT Desi2 2556 GGATGTGTGGGTCATGTGGG Utp20 6376 AGGTCTGCACTTGTCCGCTC Nefh 10196 CCTCCTTCCCTTCAAACTGA SatbL 2557 CTGAGATGAAATCATCTCGG Atp6v0al 6377 CAATCGCTGTTGCCCTGCCG Trim63 10197 o GTCTGCAATATGCTGGGACC Evalb 2558 CCGCCCATCCGAGCCAACAC Tall 6378 AGGCAGTGGGAATACCTCTT Plekhh2 10198 AGAGCGAAGCTTGCGCTTTG Paqr7 2559 TGGGTTTGAAATTCTCTATC Dpysl3 6379 GGGCGCCAAATTCAAATCTG 1110059G10Rik 10199 CCCACCGCGTATGCAAAGGC Pena 2560 AAAGGACTGCGGTTTCCCGC Cox4i2 6380 CCTGCTCCCATTCATCAGGG Zicl 10200 AAGGGTTGCTGACAGATAGG Tspan32 2561 CACATGTATACAGTATTTGT Zbtb8a 6381 GGCCGGGTGCTCCTAGGATC Itga4 10201 o AGAGCCAAAGGGTTAGGAAC Emilin2 2562 GGGCTAAGTGGCTACCCGCT Inpp5j 6382 CGTGGGACAACTCAAAGTCC Cyplal 10202 4 GCGTAATCTTACTGCATCCC Pafali2 2563 CCTTAGGGAGGCAAGGCGTG Nxf2 6383 TAAGTGTGTGCACGCGCGGG Dtna 10203 CGTCGCTTTACGGCCGGAGG Golga7 2564 CTCTCTGATAATCTTAACAA Noxl 6384 TGGGTTTGAAATTCTCTATC Dpysl3 10204 GGGCGAGGTACCTAGGCGTG Npral 2565 GAATCTGAGCGCGACCGAGA Prkaa2 6385 GGGTGATTCTGAGGGCCAGG Stra6 10205 CGAGTGACGCGGCGCCAGCC Gmds 2566 GGAGGGCCGGGCGTCAGAGC Cacna2dl 6386 AAAGGACTGCGGTTTCCCGC Cox4i2 10206 AACGGGAGATAGGCGGAGTC Soxll 2567 GAATGGAATCTCTCTAGAGC Adamtsll 6387 CACATGTATACAGTATTTGT ZbtbSa 10207 AGGTCTGCACTTGTCCGCTC Nefh 2568 TCAGCTTCTAATAACCGCGC Tfap2a 6388 GGGCTAAGTGGCTACCCGCT Inpp5j 10208 CAATCGCTGTTGCCCTGCCG Trim63 2569 GGTCACTCGGCCAAGACATC Ifi47 6389 TGCTTGGCAAGGAACGCCAC Ndufaf7 10209 GGGCGCCAAATTCAAATCTG 1110059G10Rik 2570 GTCTGCATGGCTATGGCCTC L3mbtll 6390 GTTGGAGCTAAGCATGGAAG Wdrll 10210 GACTAGTCAGTTTCTACTTT 1112b 2571 TTCGACTCCATGCAGTCGCC Cln8 6391 TGTCTACAATCTCGCGAGAC Nsun3 10211 GCGGAATTGGTGTGGCTGGC SpllO 2572 AACGCTAGGAGCTCTCTTCT Clvs2 6392 GGCGGCGCCTGGGCGCGATC Ddrl 10212 CCGCCCATCCGAGCCAACAC Tall 2573 AAGATCACTCACAAGTCCAC Fauci 6393 GGGTGGTCACACCTTAGGTT Cdl9 10213 TGGGTTTGAAATTCTCTATC Dpysl3 2574 CTGAGAGGCGTGACCTGCTC Lsml 1 6394 GAATGGAATCTCTCTAGAGC Adamtsll 10214 ACCGACGCTAACGACGACCT Nd 80 2575 TGGTTAGAGGTCCAGGGCCG Shrooml 6395 GCCCTCCCATCAATTCGCCC Chmplb 10215 AAAGGACTGCGGTTTCCCGC Cox4i2 2576 CATCAGAGCATGCGCCTCGC LsmlO 6396 GCAGCGGCGGGTCGGTAGAG Syde2 10216 CACATGTATACAGTATTTGT Zbtb8a 2577 CGCACGTGACCCGCAGTTTG Zfp62 6397 GGTCACTCGGCCAAGACATC Ifi47 10217 GGGCTAAGTGGCTACCCGCT Inpp5j 2578 CGCCATGGAGGCCAACGCTG Shank2 6398 GTCTGCATGGCTATGGCCTC L3mbtll 10218 CCTTAGGGAGGCAAGGCGTG Nxf2 2579 GTCTGCTTTCCCTCAGTGTG Mgatl 6399 TCTAAGTACCTGCTCTCAAC H2-T3 10219 AAGCTAGAAGCGCCCTAGCC Maf 2580 AATGGCTCCGCGTCCCAAAG Ank2 6400 GTATTCATACTCCCGCCGGC Nes 10220 GAATGGAATCTCTCTAGAGC Adamtsll 2581 ACCCGGACGGCGGAAGGCTC Tmem47 6401 GCGGATCGCGCGACCTGGAC Sc5d 10221 TCAGCTTCTAATAACCGCGC Tfap2a 2582 AACTAGGATGAAGCCTTTGA Zfp369 6402 TGGTTAGAGGTCCAGGGCCG Shrooml 10222 GGTCACTCGGCCAAGACATC Ifi47 2583 TTACTACGCGTAGCTTCTGG Caapl 6403 CATCAGAGCATGCGCCTCGC LsmlO 10223 GGGCGCACTTCCGTGCGCGC Itgav 2584 AAGGGAGTGTGCGGAGTCTA Aebpl 6404 ATTGGCTCCGACTATGGGCG Dnajc5 10224 GTCTGCATGGCTATGGCCTC L3mbtll 2585 TAGAAGGTAAGGGAAACGCC Wdr3 6405 CGCACGTGACCCGCAGTTTG Zfp62 10225 ACCTTATTGGCTTGTCAGAA Vav3 2586 TCTCTGTCTCTTTGCTACTG Mierl 6406 TCTGTCAAGCTGTGAGACGA Hmg20a 10226 TAGGACACTGCTGACGGTGG Ggt7 2587 GTCAAAGTAAGTACTTTCCA Tcn2 6407 AACTAGGATGAAGCCTTTGA Zfp369 10227 CTGAGAGGCGTGACCTGCTC Lsmll 2588 GGATGGGCCTCCTGAATAAG AW551984 6408 AAGGGAGTGTGCGGAGTCTA Aebpl 10228 TGGTTAGAGGTCCAGGGCCG Shrooml 2589 TATCAGAGCTTGAGCGAGCG Aszl 6409 AGGTGGAGTCTCAGGATAGG Inpp5f 10229 CGCACGTGACCCGCAGTTTG Zfp62 2590 TGAGGATTCTGATAGCGCAC Tiaml 6410 AAGTCTCTACAGTCCCTTCC Prdml5 10230 CGCCATGGAGGCCAACGCTG Shank2 2591 GACGCGGCGGACTGAACGCT Ythdc2 6411 TGCCTGAACACTGCCCGCTC Stam 10231 GTCTGCTTTCCCTCAGTGTG Mgatl 2592 GTTAAAGGTTGGAGGCGGAG Jak3 6412 GTCAAAGTAAGTACTTTCCA Tcn2 10232 AACTAGGATGAAGCCTTTGA Zfp369 2593 GGGAGGCCTGGCAGCCTGCC Arf5 6413 GGATGGGCCTCCTGAATAAG AW551984 10233 n AAGGGAGTGTGCGGAGTCTA Aebpl 2594 GGTCTGCCACCTGCATATGT Gale 6414 GTAGAACCTAGGATCCAAGC Cldnl9 10234 A CAA CAATACA CTGTCTCT C Mme 2595 CCCGGCTGCGGGAGCGGGCC Slc35dl 6415 TGAGGATTCTGATAGCGCAC Tiaml 10235 TAGAAGGTAAGGGAAACGCC Wdr3 2596 CCTCTTTCTCCTGGATGACC Bpifbl 6416 GACGCGGCGGACTGAACGCT Ythdc2 10236 n 4 TCTCTGTCTCTTTGCTACTG Mierl 2597 CATCCCAGGTCACCCTCGCA Xkr7 6417 ACTTGCCTCTTCTCTACTGA Dsgla 10237 GTCAAAGTAAGTACTTTCCA Tcn2 2598 GAACATGACGGCTGTGGGTG Sh3d21 6418 ATCTTGGTGTGACAGCGATA Pcdhal 10238 GGATG GGCCTCCTG AATAA G AW551984 2599 GGTTCTAAGGAACAAGCTGA Pappa2 6419 GGTCTGCCACCTGCATATGT Gale 10239 64 TATCAGAGCTTGAGCGAGCG Aszl 2600 TGTGTCCGCTAACCCTAAGC Xbpl 6420 CCTCTTTCTCCTGGATGACC Bpiibl 10240 ATCATAGGGTGAGTTGTGGG Itih5 2601 GGACAGAGAGGGTGTCAGAC Ptafr 6421 CATCCCAGGTCACCCTCGCA Xkr7 10241 GACGCGGCGGACTGAACGCT Ythdc2 2602 AGGAAGCGCAGCTCAGCGCC Ccnjl 6422 GGCTGCCTGCCTTCTCGGCG Tdrd6 10242 TTCACATGACTTGCTTAGCC Gm609 2603 TCCGAAGCTTGTTAAGAACC Ogdh 6423 GAACATGACGGCTGTGGGTG Sh3d21 10243 GGGAGGCCTGGCAGCCTGCC Arf5 2604 GGTCATAGACAGTGGAGCAG 1700003F12Rik 6424 GCTCTCTGTTGAGTTATCTA C r3 10244 GGTCTGCCACCTGCATATGT Gale 2605 TCACGCGGAGGCTGTGTCAG Clintl 6425 TGGCCAGCCTATTAAAGAGC Afg312 10245 o CCCGGCTGCGGGAGCGGGCC Slc35dl 2606 CCCTTGCCAATTAGGGCGCC Arl4a 6426 AGAGGCGTGGTCTTGCGTAG Siae 10246 CCTCTTTCTCCTGGATGACC Bpifbl 2607 GGCCAGGCATAGAAAGTATG Hacd4 6427 TGTGTCCGCTAACCCTAAGC Xbpl 10247 CATCCCAGGTCACCCTCGCA Xkr7 2608 CCTGGAAGGTAGACCTAGAG Patzl 6428 GGACAGAGAGGGTGTCAGAC Ptafr 10248 5 GAACATGACGGCTGTGGGTG Sh3d21 2609 CAACCTAGTCTTAGCCATTT Fine 6429 AGGAAGCGCAGCTCAGCGCC Ccnjl 10249 o GGATCGCATAGGGCGGGACA Vpsl6 2610 TGTGGCTGAGTTAGGACACT Pldl 6430 GCTGAAGTCCTGTGTGGAAT Spatal7 10250 4 TGTGTCCGCTAACCCTAAGC Xbpl 2611 GGAAACAGACCTCGCAGCAA Limk2 6431 GGAAGCTCTTCGCAGCTGGG Prosl 10251 GGACAGAGAGGGTGTCAGAC Ptafr 2612 AGACAGGCAGTCATAATCAT Hpea 6432 TCCGAAGCTTGTTAAGAACC Ogdh 10252 AAGGAGGCTGGCTGAAGACC Nlgnl 2613 CTGGGAGGCCCTCCGCGTCG Spen 6433 GGTCATAGACAGTGGAGCAG 1700003F12Rik 10253 TCCGAAGCTTGTTAAGAACC Ogdh 2614 CTTCTAGTCCTAGCTCTCTC Bphl 6434 TCACGCGGAGGCTGTGTCAG Clintl 10254 GGTCATAGACAGTGGAGCAG 1700003F12Rik 2615 TGGTATGACTTATCCTTACT 1600015I10Rik 6435 AACCGTATGGCGCGGCTCCT Cebpz 10255 TCACGCGGAGGCTGTGTCAG Clintl 2616 TTCTGCCTTCCTCGTCTAAA Noxl 6436 GGCCAGGCATAGAAA GTATG Hacd4 10256 GGCCAGGCATAGAAAGTATG Hacd4 2617 ATGTTTAAGAACTGCAGTTG HistllBa 6437 GGGACCATCCCAACAACTTC Med8 10257 CCTGGAAGGTAGACCTAGAG Patzl 2618 CTCCCGAATACATCATAATT Tall 6438 AGAGCTCACATAAAGGACCA Fgg 10258 CAACCTAGTCTTAGCCATTT Fine 2619 CTGAGCCAGTGCACAGTGAA Neil3 6439 CCTGGAAGGTAGACCTAGAG Patzl 10259 GTTTCTACAAGCATTTCTCC Slc30a8 2620 TGTGAGACTGAGTGAGCTTG Mierl 6440 CGAGTACGTGCCGGGAGTCT Atg2b 10260 GGAAACAGACCTCGCAGCAA Limk2 2621 AACATTCGGAACTGGACTGA Paox 6441 TGGAACGTCGCTGCGCCGCG Tbx3 10261 CGGCTAAGAGCTCCCGGCAC Col22al 2622 GTTCGGCGTTTCAAAGGCAG Ntik3 6442 GGAAGATGCATGACTAAGTG Nsmce4a 10262 AGACAGGCAGTCATAATCAT Hpea 2623 AGGACATGATGCAGCCGAAA Steap2 6443 CAACCTAGTCTTAGCCATTT Fin 10263 GGCGGGCAGAGGGTACGGGC Lhcgr 2624 GTTCATGATCATTCTATTAG Ap4el 6444 GGAAACAGACCTCGCAGCAA Limk2 10264 CTGGGAGGCCCTCCGCGTCG Spen 2625 CAGCAAGCATTTATACTAAC Histlh2ab 6445 CGGCTAAGAGCTCCCGGCAC Col22al 10265 CTTCTAGTCCTAGCTCTCTC Bphl 2626 GTTTGCCCGAAGCACTCTGT Aoah 6446 AGACAGGCAGTCATAATCAT Hpea 10266 GATTGGAGCTCGCATCTCCG Cntnap5c 2627 CCGGCGCGGACGTGCGCACC Ptgfm 6447 AGAGTGTTACGAAGTTTAAA Uaca 10267 TGGTATGACTTATCCTTACT 1600015I10Rik 2628 AGTTTGTTGACACTAAACAC Mtfrll 6448 ATGTTTAAGAACTGCAGTTG HistllBa 10268 ATGTTTAAGAACTGCAGTTG HistllBa 2629 CTAAGTTGTGTGGTTCATAA Ush2a 6449 CTGAGCCAGTGCACAGTGAA Neil3 10269 CTCCCGAATACATCATAATT Tall 2630 AACACAGAACAGCCTCTTGC Pafah2 6450 AACATTCGGAACTGGACTGA Paox 10270 CTGAGCCAGTGCACAGTGAA Neil3 2631 GTGTGTGAAGTGCTTGTGTC Caly 645 TACACATGCGCCCTGCGGCC 4930503L19Rik 10271 TGTGAGACTGAGTGAGCTTG Mierl 2632 ACAAATTTGGTTGTATCTGT Slc6a20b 6452 CATGTGGGAATCACTTGGCA Lcelg 10272 AACATTCGGAACTGGACTGA Paox 2633 AACTAAACTGGTGTTCTCTA Spink5 6453 GTTTGCCCGAAGCACTCTGT Aoah 10273 GTTTGCCCGAAGCACTCTGT Aoah 2634 GGAGAAGCCCATGGAGCTCC Exosc7 6454 CTGACTTAAGTGGTCCTCAG Carl2 10274 CCGGCGCGGACGTGCGCACC Ptgfm 2635 TACTCAGAAATTATCGCTGC Cstll 6455 TAGCTCGGAAGGAATAGGTG Bbs4 10275 AGTTTGTTGACACTAAACAC Mtfrll 2636 GTTCTGAGGCTCTCAGTTCC Cenpe 6456 AGTTTGTTGACACTAAACAC Mtfrll 10276 CTAAGTTGTGTGGTTCATAA Ush2a 2637 CCTTCATAGCTCCTGGCCCT Tnncl 6457 CTAAGTTGTGTGGTTCATAA Ush2a 10277 AACACAGAACAGCCTCTTGC Pafah2 2638 CAGCGGACCGGGTTTCGAAA Tmed4 6458 GGTAAACAGAGCGCCTAGAG Tcf4 10278 AAAGGTCACTTGAGAGCTCA Col24al 2639 AAGAGACAGCACAAAGCGCT Calr4 6459 TGGAGTTCAGAAGAGGATAG AbcclO 10279 GTGTGTGAAGTGCTTGTGTC Caly 2640 AAAGGCATTAACAGCGTGAG Nmur2 6460 CCGACCGCCGCTTAGCCTTT Tdg 10280 AACTAAACTGGTGTTCTCTA Spink5 2641 CTCTAAGCCCTCAAAGAGAC C l 6461 TTATAGGCAGCAGGCACTCT TrinBl 10281 n TACTCAGAAATTATCGCTGC Cstll 2642 CGAGTGCCCTAGCCGCCTGC Pcdhllx 6462 AACACAGAACAGCCTCTTGC Pafah2 10282 CAGCGGACCGGGTTTCGAAA Tmed4 2643 AATCCGCACCCGGCTAGTCT Edfl 6463 TGGCGCTCGGTCAGGGCTGG Asphdl 10283 AAGAGACAGCACAAAGCGCT Calr4 2644 GGCAGGCCGACGCGCCATGG Napll4 6464 AAAGACGTTCGTCGGTACAG Scaper 10284 n AGAAAGCCAAGAGTTGGGTG Gm597 2645 ACTTGAGGAGTCCGTGACGC Cfap46 6465 GTGTGTGAAGTGCTTGTGTC Caly 10285 o ATGGGAGCATCAGTTGAGGT Cobl 2646 AGGCGCGAAACCCGCAACCT Ewsrl 6466 AACTAAACTGGTGTTCTCTA Spink5 10286 5 AAAGGCATTAACAGCGTGAG Nmur2 2647 ACTGGCTCGCGGAGGTCCGC Mumlll 6467 TAGAAGACACACCCTGAA CG Gml0696 10287 b CGAGTGCCCTAGCCGCCTGC Pcdhllx 2648 ACCCGCCTAAGAACCTCAAG Spdya 6468 GGAGAAGCCCATGGAGCTCC Exosc7 10288 5© GGCAGGCCGACGCGCCATGG Nap 114 2649 GTAAGGCTAGTTTACGCTAG Tmed4 6469 AACATTCCACAAAGCATGCG Ptchd4 10289 J ACTTGAGGAGTCCGTGACGC Cfap46 2650 GGAGGAGGAGAAGGGTAGGA Tfap2a 6470 CAGCGGACCGGGTTTCGAAA Traed4 10290 AGGCGCGAAACCCGCAACCT Ewsrl 2651 GCGGGATAAGAAGTGGCCTG Kazn 6471 TGGGAAATAAACTAGATACT Olfrl507 10291 ACCCGCCTAAGAACCTCAAG Spdya 2652 TGGAGTCCTTTAGAAGAGGC Pabpcll 6472 GGCTGTGGTTTACA CCAA G Gml6130 10292 GTAAGGCTAGITTACGCTAG Tmed4 2653 GCGTGCGCTGTAGCGCGCAG Ppia 6473 AAAGGCATTAACAGCGTGAG Nmur2 10293 o GGAGGAGGAGAAGGGTAGGA Tfap2a 2654 CAACTGTTTGTTGCTTCTTT Ptafr 6474 GTTCATCAAGGCCTGCCFCC Pate2 10294 GCGGGATAAGAAGTGGCCTG Kazn 2655 AGTCGTCTGGATCAGCTTGA Zmiz2 6475 GGCAGGCCGACGCGCCATGG Napll4 10295 TGGAGTCCTTTAGAAGAGGC PabpcLl 2656 GCACGATCTCCTGGGATTCT Bpifa2 6476 ACTTGAGGAGTCCGrGACGC Cfap46 10296 5 GCGTGCGCTGTAGCGCGCAG Ppia 2657 TCGCTAAGCTTCAGTTACAG Dcx 6477 AGGCGCGAAACCCGCAACCT Ewsrl 10297 o CAACTGTTTGTTGCTTCTTT Ptafr 2658 GGAAGATAGTTCCGAGGGTG Slc32al 6478 TCAGGCGGCAGCGTTCCGAT ItgbS 10298 4 AGTCGTCTGGATCAGCTTGA Zmiz2 2659 CACACTTTAACATTGAGGAG 2410141K09Rik 6479 CGGCTGCTGGCGGATCGAGC Grik4 10299 GCACGATCTCCTGGGATTCT Bpifa2 2660 TCCGTTTCATATTCGGAAAG Tas2rll8 6480 GTAAGGCTAGTTTACGCTAG Tmed4 10300 TTATCCAGCCTGATCTTGGG Tail 2661 GGCCCTTTGTGGCGCGGCTC Rnfl65 6481 TGGAGTCCTTTAGAAGAGGC Pabpcll 10301 GGAAGATAGTTCCGAGGGTG Slc32al 2662 AGGCGGTGAGGCGTTGGACT Osbpl3 6482 TTGCGTCAGTCTCGGGCACG Meal 10302 CACACTTTAACATrGAGGAG 2 101 1K09Rik 2663 CACCGAGCAACCATTACAAG Hti6 6483 GTGCGTAGCTGCCCGGGCTT Trappc8 10303 TTCATGTTGGGTTTAGACTC Ao 4 2664 CCTAGTCTAGAGTGGTACCG MedlS 6484 CAACTGTTTGTTGCTTCTTT Ptafr 10304 CTGCAATCCCGCACGCGCGG Unc5d 2665 CAGTGGTTGCCATAGCGACC Stpgl 6485 GCACGATCTCCTGGGATTCT Bpifa2 10305 AGGCGGTGAGGCGTTGGACT OsbpH 2666 TTGATGGCTTTCAAAGTGTC Mgatl 6486 TGAAAGACAAGTTACAGCCA Pdgfc 10306 GTTGTCAAGGCGACATGGAT 5330417C22Rik 2667 ATTTGAGACCTTCCCATAGC Cachdl 6487 GGAAGATAGTTCCGAGGGTG Slc32al 10307 CCTAGTCTAGAGTGGTACCG Medl8 2668 GTATGGTAAGTATAATGCCC Tnfrsf4 6488 CACACTTTAACATTGAGGAG 2410141K09Rik 10308 CAGTGGTrGCCATAGCGACC Stpgl 2669 AATTTGATTTAAAGGTGCCA Gpm6a 6489 ACTGTTTATCCCACCGGTAT Epcam 10309 TTGATGGCTTTCAAAGTGTC Mgatl 2670 CACAAGTAATATTGCAGACT Vmnlrl89 6490 CCTAGTCTAGAGTGGTACCG Medl8 10310 ATTTGAGACCTTCCCATAGC Cachdl 2671 CTCCAATAATATCAATTAGG Epha7 6491 CAGTGGTTGCCATAGCGACC Stpgl 10311 AATTTGATTTAAAGGTGCCA Gpm6a 2672 AGCGAACCCTGGATGCTCCA Steap2 6492 GAGAAAGCGCGGCTCAGAGC Gria2 103 12 CTCCAATAATATCAATTAGG Epha7 2673 AGCAGCTCACAGTGCGGGTG Fry 6493 AATGGGCGGAGACTCATCCT Sytll 10313 GCCGCGAGAAGGAGGCGCGC Prkg2 2674 AATTTACTTCATTGCTCCAC Fa 7c 6494 GGGCATTAGAGGTGGGAGGC Tiel 10314 AATTTACTTCATTGCTCCAC Fam47c 2675 TGGATTACACAGGTAGCAAG Zfp944 6495 GTGTGGGAGTCTCGCGAGAG Scamp5 10315 AGGCCGGTTAAGATCGGAGG Fam46c 2676 AGGCCGGTTAAGATCGGAGG Fa 46c 6496 TACAATGGAGTCCCAAACAG Oxct2a 10316 CTGTGAGTrCGAGACCAGTC Polrlb 2677 CTGTGAGTTCGAGACCAGTC Polrlb 6497 CGTAAAGACATACGCTCCGC Mut 103 17 GTGGAGAGAAGACAAGAAAG Fgf3 2678 GTGGAGAGAAGACAAGAAAG Fgf3 6498 CACACGGACAGAGGCACAAC Mytl 10318 ACAATGCrGCCGAACCGGGA Arap2 2679 ACAATGCTGCCGAACCGGGA Arap2 6499 GCGGCTCAGCGCGTCAAGCC Dst 10319 TGGCAGArGCATCCCACAGG Bpifb2 2680 TGGCAGATGCATCCCACAGG Bpifb2 6500 GCTGCGGCTGCCTCTGGGAG Asphdl 10320 GAAGAGTCACGTTTCGGAGA Emilin2 2681 GAAGAGTCACGTTTCGGAGA Emilin2 6501 GTGGAGAGAAGACAAGAAAG Fgf3 10321 AAGAGCTCCCGGGAACCGCC Aunip 2682 TTAGACTTCTAGATTCTCTT Gimap3 6502 TGGCAGATGCATCCCACAGG Bpifb2 10322 CCGGCGArrTGCAAAGTGCC Nlgnl 2683 AAGAGCTCCCGGGAACCGCC Aunip 6503 AAGCCCGGAAACCACGGAAA Corola 10323 GGGTTGACACTGGGAAGGTC Runx3 2684 GGGTTGACACTGGGAAGGTC Runx3 6504 AAGAGCTCCCGGGAACCGCC Aunip 10324 CGAGCCACrGCGCACACGCC Capza2 2685 CGAGCCACTGCGCACACGCC Capza2 6505 GCCGGGAAGTGGGTCAACTG Stm 10325 AGTAGACrrTAAGCAGGCGG Ggt7 2686 CTCCCTAACGGGAAGGGCCT Gtf2hl 6506 CGATACTGGCGAGGGCGTCG Itgall 10326 GCTCTGCCAGAGGCGGGATG Tnipl 2687 GCTCTGCCAGAGGCGGGATG Tnipl 6507 GGGTTGACACTGGGAAGGTC Runx3 10327 ACAACCGGGCACCGGGAGCG Mme 2688 GGAAAGCAACTTGAGAGAAA Dmd 6508 GCTCTGCCAGAGGCGGGATG Tnipl 10328 TAGCAGACGCTTACGGACTT Zfp369 2689 TAGCAGACGCTTACGGACTT Zfp369 6509 TGGCGGCCGGAGTAGCTAAT Ple l 2 10329 n ATCCCGACCAATGAGCGCAC Mme 2690 CCTTCCGATTGGGCGGCGGT Hmmr 6510 TAGCAGACGCTTACGGACTT Zfp369 10330 CCTTCCGATTGGGCGGCGGT Hmmr 2691 CCCGCGTGTCACCGACGCCT Dsp 6511 CCTTCCGATTGGGCGGCGGT Hmmr 10331 CCCGCGTGrCACCGACGCCT Dsp 2692 GCCGATAGAGGAGTGGCCAC Zscan20 6512 GCGGATATGGAGAACAGAAC Pla2g7 10332 n GCCGATAGAGGAGTGGCCAC Zscan20 2693 GTCCTGGCGTAAGCGAATCT 111005 9G lORik 65 GGAGCAGCAGTGGCCGTCTT Ptk7 10333 o GTCCTGGCGTAAGCGAATCT 1110059G10Rik 2694 AGATGGCfTTGCATAAATGC Trim27 6514 GCCGATAGAGGAGTGGCCAC Zscan20 10334 5 TGACTTCGTATTATTTGTTG Ms4a7 2695 CAAGATCGCGCGCAGGCGTG Steap2 6515 GTCCTGGCGTAAGCGAATCT 1110059G10Rik 10335 b AGATGGCrrTGCATAAATGC Trim27 2696 AAAGCAGCGGCGGCAGCGGT DpplO 6516 CACGACACACTGCTGGTCTC Parvg 10336 5© AAAGCAGCGGCGGCAGCGGT DpplO 2697 TGGTCGCGTTTAGTGATCAC Chchd5 6517 ATCCACACTGAAGACACCTC Gprl51 10337 J TGGTCGCGTTTAGrGATCAC Ch d5 2698 AACACAAGTTGGGCGCAGCG Histlhlc 6518 TGCTACCGTTGCGTGGAGCC 4930591A17Rik 10338 AACACAAGTTGGGCGCAGCG Histlhlc 2699 CCGATGCCTTGCAGATGCCT Erv3 6519 AGATGGCTTTGCATAAATGC Trim27 10339 CCGATGCCTTGCAGATGCCT Erv3 2700 ACTTCCTGTGGCGACCCTGC Zfp511 6520 CGTATTTGAGAAGCAGTCAA Tbxas 1 10340 CGGACGTGACACGTGCGGCG T cel 2701 TTCCTTGGGTTTAAGAGTGT Mat2b 6521 AAAGCAGCGGCGGCAGCGGT DpplO 10341 o ACTTCCTGTGGCGACCCTGC Zfp 1 2702 TAAACAAGCCCTTCCGCTGC I122ral 6522 AACACAAGTTGGGCGCAGCG Histlhlc 10342 TTCCTTGGGTTTAAGAGTGT Mat2b 2703 GAGCTGGACCGTATAGGGCG Kcnip3 652 CGGACGTGACACGTGCGGCG Tbcel 10343 GTTCTAGCCAGGTCTCCATA 9830107B12Rik 2704 GCACCACCGGAGAACCTGTT Ra n 6524 CCCAGTGACTTCACGTGGGT Muc5ac 10344 5 TAAACAAGCCCTTCCGCTGC I122ral 2705 GCTCCACCACAGGTCGCCrr Sspo 6525 GTTAGTGACTTTACTGCATG Thsd4 10345 o GCTCCACCACAGGTCGCCTT Sspo 2706 TAGCTTCAGCGCCTGTATTT Cd72 6526 ACTTCCTGTGGCGACCCTGC Zfp5 11 10346 4 GGGCTGTGAGAAGACTTGAG Unc79 2707 CCGGCGCGTGTACGACTAGC Srfbpl 6527 TTCCTTGGGTTTAAGAGTGT Mat2b 10347 o G CTTCCAGGGCACATGGCTGG Tmem230 2708 TACAGGATTCCAGGAAGAGT Slc30a2 6528 TAAACAAGCCCTTCCGCTGC I122ral 10348 TTGTGTCTCACTCGGGCCCA Pdyn 2709 ACTTGCTTGTGCGCAGGTCC Dmd 6529 ACCGGTGGAATTGTGTCAGC Clqtnf7 10349 CCGGCGCGTGTACGACTAGC Srfbpl 2710 GCTTCCACGGACCGACCACT Clic4 6530 ACATAATCACAAATTGATGC Mytl 10350 TACAGGATTCCAGGAAGAGT Slc30a2 2711 GTCACTAGTTGGGAGGGATG Ncmap 6531 GTGGCGTAGAACTCTTTCGC Ore 1 10351 GCTTCCACGGACCGACCACT Clic4 2712 CATATACCCGTGCGGAGGAC Agol 6532 TACAGGATTCCAGGAAGAGT Slc30a2 10352 GTCACTAGTTGGGAGGGATG Ncmap 2713 TCCGGACCGGAAAGCGGAAG Mcm8 6533 GCTTCCACGGACCGACCACT Clic4 10353 CATATACCCGTGCGGAGGAC Agol 2714 AACTCTTAGAAGGCTTTAAA Phex 6534 GTCACTAGTTGGGAGGGATG Ncmap 10354 TCCGGACCGGAAAGCGGAAG Mcm8 2715 AAGCrCTCCCTTGAACCCGG Helt 6535 TTGCGCACTGCGCACGTCTG Rpp2 1 10355 AAGCTCTCCCTTGAACCCGG Helt 2716 CCACTGCCTTTCGAAGTTGG Mgatl 6536 CATATACCCGTGCGGAGGAC Ago 1 10356 CCACTGCCTTTCGAAGTTGG Mgatl 2717 GCCCACGGCCCGCGGGACAA Dus l 6537 GCAAGCTCGGCTCCGAGGCG Trappc8 10357 GCCCACGGCCCGCGGGACAA Duspl5 2718 CCGAATGCTTGATCGACAGC Maprel 6538 GCCGCCCAACCTGACAGCCC Pearl 10358 CCGAATGCTTGATCGACAGC Maprel 2719 CTTGTTGGAGCCAAGTAAGG Plpp3 6539 GCCCACGGCCCGCGGGACAA Duspl5 10359 GAGTCTTCAAGAGAGCTCCT Rnfl85 2720 GAGrCTTCAAGAGAGCTCCT Rnfl85 6540 CCGAATGCTTGATCGACAGC Maprel 10360 GATAGCACTGTCCCACAATG Sspo 2721 GATAGCACTGTCCCACAATG Sspo 6541 GAGTCTTCAAGAGAGCTCCT Rnfl85 10361 GTGCCGTGCCAGTTCCACCT Sycp2 2722 GTGCCGTGCCAGTTCCACCT Sycp2 6542 TAGGCAAAGAAATGGTGGCC Neill 10362 GGTAGATTCACTCAATTCCC Sec22c 2723 GGTAGATTCACTCAATTCCC Sec22c 6543 CGTTTCTGAGCGTTCTGCGC Bpntl 10363 ATCACAACCCAGTGCGCAAT Lrrc4c 2724 ATCACAACCCAGTGCGCAAT Lrrc4c 6544 ATCACAACCCAGTGCGCAAT Lrrc4c 10364 CATCTTGTGAGATCCTGCCA Spink5 2725 CATCTTGTGAGATCCTGCCA Spink5 6545 CATCTTGTGAGATCCTGCCA Spink5 10365 TCAACAACGCTGAGCACTTC Syf2 2726 TCAACAACGCTGAGCACTTC Syf2 6546 TCAACAACGCTGAGCACTTC Syf2 10366 GCGACGGTGGCAGCTTAGCG Map2 2727 TAGCAACAGGACTTCCCAGT Poflb 6547 GAGCCCGGCGATACGGCCAA Napll4 10367 GCTAGGCGCCAATGGCCACC Ppplr3g 2728 ACAGCCAACCGGCTGCTTTA Slc45al 6548 CTACAAAGGAAGGAGACTCA Dclk2 10368 AGCAGTGAGGCGCCTGGCGA Cntn5 2729 GCTAGGCGCCAATGGCCACC Ppplr3g 6549 TGAGAAAGGTGGACTACAAC Meal 10369 GAGCCCGGCGATACGGCCAA Nap 114 2730 AGCAGTGAGGCGCCTGGCGA Cntn5 6550 GGTAAGCTTAGCTCGGCGTG Dolpp 1 10370 GGGAGGGTCCTGGCGCAGAT Zfp467 2731 GAGCCCGGCGATACGGCCAA Nap 114 6551 TAGCCCATTAACCTAGAGCC Urgcp 10371 GGCAAATACCTGGCCACCTG Cobl 2732 CGACCGCATCTCTAAGTGGG Sema4a 6552 GCTTGGGCTACGTTCCAAGT Anxa2 10372 GGTCCTTAGTGTCGCTGGAT Ulk4 2733 GGGAGGGTCCTGGCGCAGAT Zfp467 6553 GGTCTACAGGGCGGAGACCC Reml 10373 CTGGGACTCTGACTGACGTC 3830406C13Rik 2734 GGTACACACAGGGCGCCTGC Igfl 6554 AGCTCAGACCTGACATTCTG Stra6 10374 TAGCCCATTAACCTAGAGCC Urgcp 2735 GGTCCTTAGTGTCGCTGGAr Ulk4 6555 ACCCTCTGCCAAGGATTGCC Ulk3 10375 GGGCCAGCTAGGAAAGATTT Sirpa 2736 TGCGCCCGCCCAATAGCGCA Herc2 6556 TGCACACGTTTGATGCTTGA Ankrd36 10376 ACTCCGCTAGAATTGCAGTG Potla 2737 TAGCCCATTAACCTAGAGCC Urgcp 6557 GTATAAATAGGTCAGATTGT S100a4 10377 n CGCAGGGACATCTGGAGCAG Kcnkl5 2738 GGGCCAGCTAGGAAAGATTT Sirpa 6558 CCTAAACTCAGAACCCACCA Ldlrapl 10378 GGTCTACAGGGCGGAGACCC Reml 2739 ACTCCGCTAGAATTGCAGTG Potla 6559 ATAAGGCCTAGACGCGTGGC Tmem57 10379 CCCTGCTTTGGGAGTAGCTT 4921539EllRik 2740 GGTCTACAGGGCGGAGACCC Reml 6560 CGGGCCAAGCGGCTAAGTTC Aplbl 10380 n 4 CTGAGAAACATGCCAAAGAC Cela2a 2741 CCCTGCTTTGGGAGTAGCTT 4921539EllRik 6561 AACATCAAGTGCTTGAAAGA Glra3 10381 ACGGCCGTGGCGTTGCGACG Ddi2 2742 CTGAGAAACATGCCAAAGAC Cela2a 6562 TTTGACCTAGACGCCCACAC Bmprlb 10382 5 GTGACTCGGTGCCCACCGCG Cobl 2743 ACGGCCGTGGCGTTGCGACG Ddi2 6563 GCAGCCGGACCTCGCCCTCG C77080 10383 64 TGCACACGTTTGATGCTTGA Ankrd36 2744 TGCACACGTTTGATGCTTGA Ankrd36 6564 TATTCATTGGTCCGGGCCCG Lgi2 10384 5© CTCCCAGGTCTCCATCGCCC Plekhm2 2745 CTCCCAGGTCTCCATCGCCC Plekhm2 6565 AGGCCCAATTCCTCTACCTT Zfp941 10385 CCTAAACTCAGAACCCACCA Ldlrapl 2746 CCTAAACTCAGAACCCACCA Ldlrapl 6566 CAAGGGAAGAGGGAAGAAAG Olfrl507 10386 CCGCTCGCCGGCAGGGAGTG Btafl 2747 ATAAGGCCTAGACGCGTGGC Tmem57 6567 GCCCACCTGAGCCGCAGACT Eraidl 10387 ATAAGGCCTAGACGCGTGGC Tmem57 2748 CGGGCCAAGCGGCTAAGTTC Aplbl 6568 GTCTAGCCAACCCAACTCTG Jhy 10388 CGGGCCAAGCGGCTAAGTTC Aplbl 2749 AACATCAAGTGCTTGAAAGA Glra3 6569 GAGTCAGCTCCGGGACCCTC Ncapg 10389 AACATCAAGTGCTTGAAAGA Glra3 2750 AAGGAAGCCACGCGACTAGG Trmt6 6570 TTCCTTTGATTTCCGTGAAA Mrgprg 10390 AAGGAAGCCACGCGACTAGG Trmt6 2751 GCAGCCGGACCTCGCCCTCG C77080 6571 ATAAA GTCCATG CAGCCCTA H2-B1 10391 TTTGACCTAGACGCCCACAC Bmprlb 2752 AGTCTCACCATATCTGGGCT 01fr5 1 6572 TGGCGACCTCTAGAGGCGTT Limk2 10392 GCAGCCGGACCTCGCCCTCG C77080 2753 AGGCCCAATTCCTCTACCTT Zfp941 6573 GACGACGGACTATTGGAAGG Wdrl 1 10393 AGGCCCAATTCCTCTACCTT Zfp941 2754 GTTAAGTGGGCGGGTTCAAG Tmemll5 6574 TGGCGGCGATTGGGCAGGCG Fstl4 10394 CTTTGCAGAATAGTGCGCCA Myocd 2755 CTTTGCAGAATAGTGCGCCA Myocd 6575 TCTCAAAGTTCCAAGGGTCT Mroh2a 10395 GCCCACCTGAGCCGCAGACT Emidl 2756 GCCCACCTGAGCCGCAGACT Emidl 6576 GACGCAGGGCGCTAAATTCC EmilirG 10396 CTCCCGTCTGCTCCGACGAC Collal 2757 AGGAGCGCAAGGAGCGCGCG Cftr 6577 AAAGCTGCTTCAACAGGCTA 1113 10397 GGAAGAGCCCAGAGCTCGCT Ndc80 2758 TGGCGACCTCTAGAGGCGTT Limk2 6578 AAAGCCCGGACCAGCTATCC C2cd4a 10398 AGGAGCGCAAGGAGCGCGCG Cftr 2759 TGGCGGCGATTGGGCAGGCG Fstl4 6579 TATCTTTGATCCAGGGTGAG Nr2f2 10399 TTCCTTTGATTTCCGTGAAA Mrgprg 2760 GAGGATTTCATCTCAGGACT At b 6580 CTAGCAGCGGGCTCAGCGGT Eri3 10400 TGGCGACCTCTAGAGGCGTT Limk2 2761 TCTCAAAGTTCCAAGGGTCT Mroh2a 6581 AGGGTGTTAAGCTGCACTGT m r2 10401 TGGCGGCGATTGGGCAGGCG Fstl4 2762 GACGCAGGGCGCTAAATTCC Emilin3 6582 GCGCGTCGACTTGGAGGCAG Fam8 l a 10402 GAGGATTrCArCTCAGGACT At 8b 5 2763 AAAGCTGCTTCAACAGGCTA 1113 6583 GCTGAGCTTATGGTGGCCTC Havcrl 10403 TCTCAAAGTTCCAAGGGTCT Mroh2a 2764 CTCTCCCTCCGCGTCTCGGC Cacnalg 6584 GGTTTGGTATGTTCTAAATT Gml553 10404 AAAGCTGCrrCAACAGGCTA 1113 2765 TCCTATGACCGTAAACGCCA Cagel 6585 CAGACGCGAGAGCTGGGCGG Pttgl 10405 TCCTATGACCGTAAACGCCA Cagel 2766 ATCCGATTGGTCTTTATTGA Ap3m2 6586 TCGTGACCTGCAGCGGACCT Pefl 10406 ATCCGATTGGTCTTTATTGA Ap3m2 2767 GCCAAAGGCCAGGTGTTGGG Agmat 6587 CGAGGGACCCGAGGGCTCTT Vegfc 10407 GCCAAAGGCCAGGTGTTGGG Agmat 2768 TGCAGGCTGCCACTAGCTCA Pzp 6588 GGCGGCGGAGGCCTCACCAC Pfn2 10408 TTAACTGGGCAAGCTGGGCG Slcl5a4 2769 AGGGTGTTAAGCTGCACTGT Nmur2 6589 CTTTGTGGATGGGAGCAGGG Nr3cl 10409 AGGGTGTrAAGCTGCACTGT Nmur2 2770 GGTTGGAATTTGCCTTTCTA Armcxl 6590 CAGATCAGCATCATTCACCA Fndc9 10410 TCTGAGCTGTATATAAGTCC Stab2 2771 CTAGTCTGTTCTTGCCTTGT Cst3 6591 CCACAGCCCTTCTCGTTGCC Spm 10411 CTAGTCTGTTCTTGCCTTGT Cst3 2772 GCTGAGCTTATGGTGGCCTC Havcrl 6592 AGTAAGTTATCCGGGACCCT Zkscan4 10412 GCTGAGCTTATGGTGGCCTC Havcrl 2773 CAGACGCGAGAGCTGGGCGG Pttgl 6593 GACAGTGAGAAGCGCAAACC Cars 10413 CAGACGCGAGAGCTGGGCGG Pttgl 2774 TCGTGACCTGCAGCGGACCT Pefl 6594 TTTCAGCAGAGGCAGCAACC Adgrfl 10414 TCGTGACCTGCAGCGGACCT Pefl 2775 CGAGGGACCCGAGGGCTCTT Vegfc 6595 GGAGCTCTCTTGCCAGTGGG Hpgd 10415 CGAGGGACCCGAGGGCTCTT Vegfc 2776 GTTCGTCGGGTCGTGCAGCC Myll2b 6596 TGAGGAATCGACTCAGGGTG Ywhab 10416 GTTCGTCGGGTCGTGCAGCC Myll2b 2777 CAGATCAGCATCATTCACCA Fndc9 6597 GGGCAGGAGGACAATGCTAG Stmnl 10417 AGTACGGCTGCCAGTTGTCA Cbx5 2778 CCACAGCCCTTCTCGTTGCC Spm 6598 TGAAGGAGTCAGAGGTCTGG Mcoln2 10418 CAGATCAGCATCATTCACCA Fndc9 2779 AGTAAGTTATCCGGGACCCT Zkscan4 6599 TAATTCACACTCCGGTGAAG Thoc5 10419 CCACAGCCCrrCTCGTTGCC Spm 2780 GACAGTGAGAAGCGCAAACC Cars 6600 ATGGTTGGAAGCTGGGTTGA Cttn 10420 AGTAAGrrATCCGGGACCCT Zkscan4 2781 GGAGCTCTCTTGCCAGTGGG Hpgd 6601 GAGCGGCGATCGAACGCCCG Csk 10421 GACA GTGAGAA GCGCAAA CC Cars 2782 TGGCAAGGAAATATATAGCT G6pd2 6602 AGCCCAGGACACAGCAAAGG Cep85 10422 ATTCCCGAAGCCTAGGAGTC Sgol2b 2783 GGGCAGGAGGACAATGCTAG Stmnl 6603 TTGTCGCCGTCAGGCACAGC Ago3 10423 GGAGCTCrCTTGCCAGTGGG Hpgd 2784 TATAAGAGTCTTGATAGAAC Satll 6604 TCGAAGCGAATCGGCTGTCG Gpatchl 1 10424 TGAGGAATCGACTCAGGGTG Ywhab 2785 TAATTCACACTCCGGTGAAG Thoc5 6605 GGGCTTCGGCTGGCGTCACG Scaper 10425 GGGCAGGAG GACAATGCTA G Stmnl 2786 ATGGTTGGAAGCTGGGTTGA Cttn 6606 GCGCTCTGCCTGCCCAGTGG Mbd2 10426 TAATTCACACTCCGGTGAAG Thoc5 2787 AATCTACAGCAAGAGTGGCT Scn8a 6607 AACCGACCCAACATGGCGCC Stard6 10427 ATGGTTGGAAGCTGGGTTGA Cttn 2788 AGCCCAGGACACAGCAAAGG Cep 5 6608 AAGTTTCCTGCAGAAAGAGA Ccr2 10428 AGCCCAGGACACAGCAAAGG Cep85 2789 AACTGAAGATAAGGATTCCC Lmo2 6609 GAGGATTCCAATTGATTCCT Nr2 2 10429 CCTTCTCTCCTACCAATCAG Aass 2790 CCTTCTCTCCTACCAATCAG Aass 6610 GGTGACCCGCAAGGCATAGG Dnmt3b 10430 TTGTCGCCGTCAGGCACAGC Ago 3 2791 TTGTCGCCGTCAGGCACAGC Ag 3 6611 CTGTGGCAACACCTCAGTTT Cfap44 10431 AACCATTCrAGAATGTCTGG 4930595M18Rik 2792 AACCATTCTAGAATGTCTGG 4930595M18Rik 6612 TACACAGGGCAGTGTGAGTT Fezl 10432 GTACAGGGAGAACATTAGCA Gm9758 2793 GTACAGGGAGAACATTAGCA Gm97 6613 GAGATTCGTATGTGACCAGA Ritl 10433 AGTCCCGCTGTACCTAAAGG Hnmpa2b 1 2794 AGTCCCGCTGTACCTAAAGG Hnmpa2bl 6614 ATTTAGGTCTCAGGTGGGAC Slc35e4 10434 TCGGTCTGAGGGCCGCGGCC Manla2 2795 TCGGTCTGAGGGCCGCGGCC Manla2 6615 GATTGGGACAGTGACCAA CC 1190007I07Rik 10435 CCAGTCCAGGCGCGCAACTC Ak4 2796 CCAGTCCAGGCGCGCAACTC Ak4 6616 GTTCTGTACCGGGCAGGAAC Med8 10436 ACCTAGTTTACTGTGGTTGG Rmnd5b 2797 ACCTAGTTTACTGTGGTTGG Rnmd5b 6617 AGATATTTCATCTTACTGCA Rapgef6 10437 GGTGACCCGCAAGGCATAGG Dnmt3b 2798 GGTGACCCGCAAGGCATAGG Dnmt3b 6618 CCCTCGGCTTTACGACTTTC Hormad2 10438 GTTATTAGGACCAATTAAGA Pdzphl 2799 GTTATTAGGACCAATTAAGA Pdzphl 6619 CTAACTCAGGCACCACCCTT BcllO 10439 AAA GAAAGGCAAGAGAAGAG Rassf2 2800 AAA GAAAGGCAAGAGAAGAG Rassf2 6620 GGGCACTTCCGAGGCCGCTC Zfp62 10440 GAGAGTGAGCCTGTTCTGTG Rockl 2801 ATTTAGGTCTCAGGTGGGAC Slc35e4 6621 TGTGGGCGGGAGGCCGAGTG Htrld 10441 o ATTTAGGTCTCAGGTGGGAC Slc35e4 2802 TGCGCTCGAGGCCTTGAGGC Stk31 6622 TGCCCGGGTCGAGGTCGGGT Adgra3 10442 4 TGCGCTCGAGGCCTTGAGGC Stk31 2803 TCTGTAGGTGACAAAGAGGA Morf411 6623 CGGTCCCAGTCTTGCAGCCC Corola 10443 AGTAGCGTCGTAGCTCTCTC Naa20 2804 AGTAGCGTCGTAGCTCTCTC Naa20 6624 ACCTACCCTGCCGTGAAGAA Pxk 10444 AGATATTTCATCTTACTGCA Rapgef6 2805 AGATATTTCATCTTACTGCA Rapgef6 6625 CAAATCAGACGCATGCGCTT Fadd 10445 CCCTCGGCTTTACGACTTTC Hormad2 2806 CCCTCGGCTTTACGACTTTC or ad2 6626 GGAAGAACAACAAATCTATT Zfyve9 10446 GAGACAACCATTAAGAGTCA Slc26a4 2807 GGGCACTTCCGAGGCCGCTC Zfp62 6627 TAGTCCCGAGAATTTGCTGC Lyplall 10447 AAGTGGAGTGAGGGCTGTGT Dnah7a 2808 GCGCGCGGAGGGATCCGCCG Ncam2 6628 GCAAAGACGCTGCGGCTTGC Stard3nl 10448 GGGCACTTCCGAGGCCGCTC Zfp62 2809 TGTGGGCGGGAGGCCGAGTG Htrld 6629 AAATGGCTGCCCGGCCCACA Gpbplll 10449 GCGCGCGGAGGGATCCGCCG Ncam2 2810 AAAGAGTGTCACTTGCTGGA Fatl 6630 CAGGGTGATCCGCTGAGGAC Gm7616 10450 TGGTCGCCTTAGCACCATCT Actcl 2811 TGCCCGGGTCGAGGTCGGGT Adgra3 6631 TAGCGGATGGGCGGGCTCTA C77080 10451 TGTGGGCGGGAGGCCGAGTG Htrld 2812 TAGCATTGCTGCATCTTCTC Insl5 6632 TTGCAGCACCCATTGGGTTG Fcrls 10452 GAGCCTGAGCTCAAACGTCG Adckl 2813 TGTTTGGTGCCCTTGTCACA Prss2 6633 TCATTTCAAAGGCTGACCCT Cyp2el 10453 AAAGAGTGTCACTTGCTGGA Fatl 2814 GTCATTAGTTGTCAGGGAGC Dnah6 6634 CCCTGCACTATATTCCCGCC Tubgcp2 10454 TGCCCGGGrCGAGGTCGGGT Adgra3 2815 CAAATCAGACGCATGCGCTT Fadd 6635 TTTGCGGTGTGCGGCGCTGG Abcc5 10455 TAGCATTGCTGCArCTTCTC Insl5 2816 AGAATCTGGAAGTTTACAGC Fa 71 2 6636 GGCTGCTGATTCCAGAATGC Cldnl9 10456 GTCATTAGTTGTCAGGGAGC Dnah6 2817 CCGCCTCCTGCTCTTGTGAT Zmat4 6637 CAATTCTTGGCTTCAAGCCA Cypla2 10457 CAAATCAGACGCATGCGCTT Fadd 2818 GCAAAGACGCTGCGGCTTGC Stard3nl 6638 CCCTGCACAGTGCCTAGGAC Elmol 10458 CCGCCTCCTGCTCTTGTGAT Zmat4 2819 AGGAAGCTCGGGCGACGATT Wdr78 6639 GGAGCTTGGGCGAAGCTTTG Lepr 10459 GCAAAGACGCTGCGGCTTGC Stard3nl 2820 GAATGAATCAGCTACATATA Snx25 6640 GTTAAGGGCGGCAATGTGGG Patzl 10460 GAATGAATCAGCTACATATA Snx25 2821 TAGCGGATGGGCGGGCTCTA C77080 6641 AGTGTAAGCTGGGTGCTGAT Tdo2 10461 TAGCGGATGGGCGGGCTCTA C77080 2822 TCATTTCAAAGGCTGACCCT Cyp2el 6642 CCTAGAAGGAATGCTAACAG Rnfl85 10462 TCATTTCAAAGGCTGACCCT Cyp2el 2823 CCCTGCACTATATTCCCGCC Tubgcp2 6643 AGCGGTGGACGGCGTCGATC Cep76 10463 CCCTGCACrArATTCCCGCC Tubgcp2 2824 GGTTTACTAGAACTAGACCC Sfrpl 6644 GGGTTTGGGAGATACTGAGT Csf2 10464 GGTTTACTAGAACTAGACCC Sfipl 2825 AAACTGCTGTTGCTCGCCGC Bell lb 6645 GGCCAATTCCTTCTTAGCTG Grhl3 10465 AAACTGCrGTTGCrCGCCGC Bell l b 2826 GGTCGCGAGCTGCCCGGCCC GnglO 6646 GGTCACAGGGAGCCCGACTG LaptmS 10466 CCCTGCACAGTGCCTAGGAC Elmol 2827 CCCTGCACAGTGCCTAGGAC Elmol 6647 TTGCCGGAGCCGCCTCGAGG Tns3 10467 GGAGGAAATAGGAGGGAGGG Gcm2 2828 GGAGGAAATAGGAGGGAGGG Gcm2 6648 CAAAGCGCCCTCAGGTTCCG Bhlhe23 10468 ATAAGGACATTAAA GAAGGA Gml2789 2829 ATAAGGACATTAAAGAAGGA Gml2789 6649 ATAGCCTTTCCGCGGCGCCG Fa 81a 10469 GGAGCTTGGGCGAAGCTTTG Lepr 2830 GGAGCTTGGGCGAAGCTTTG Lepr 6650 GATTCAGTCTTCAACTTGGG Arhgefll 10470 GCTGGAAAGTGCTGCGTCCC Gimap5 2831 GCTGGAAAGTGCTGCGTCCC Gimap5 6651 AAGCCAAAGTCTGGGCACCA Mtg2 10471 CGTCAGCAGFGATCGTGCCG Calu 2832 GGATGAACCAATTAGTCCAA Prg4 6652 GGAATTGTGATATAAGGCAT Timd4 10472 GTTAAGGGCGGCAATGTGGG Patzl 2833 CGTCAGCAGFGATCGTGCCG Calu 6653 AAACACTT GAAGGTGTGGCC Havcrl 10473 n GAGΑΤΑ GGTGTAAGCACGC Ada ts9 2834 GTTAAGGGCGGCAATGTGGG Patzl 6654 ACTGGACGCGCCTGTACGTG Slc22a2 1 10474 CCTAGAAGGAATGCTAACAG Rnfl85 2835 GAGATATGGTGTAAGCACGC Adamts9 6655 GCTGACGCTGCTATTAGTCT Aebpl 10475 GGGTTTGGGAGATACTGAGT Csf2 2836 CACCCGGGTGGACAGATGTC Fry 6656 AGCACTAAGCCCAGTATGAG Vit 10476 GGCCAArrCCrrCTTAGCTG Grhl3 2837 CCTAGAAGGAATGCTAACAG Rnfl85 6657 GGCGCAGACCGTGTCTTACC Nadsynl 10477 o GGTCACAGGGAGCCCGACTG Laptm5 2838 GGGTTTGGGAGATACTGAGT Cs 2 6658 CGGGCCCAGCTGACACTTAT Fam46b 10478 TTGCCGGAGCCGCCTCGAGG Tns3 2839 GGCCAATTCCTTCTTAGCTG Grhl3 6659 TCTGAGCTATGGTTGGGTGG 1700042G07Rik 10479 o b AAGAACAAGGAGGAGAGTAA Tctexldl 2840 TCTTGGTGATATTTCAGGAG Myot 6660 AGACCAACGCACGCGGAAGA Cbfa2t2 10480 GGAATFGFGATATAAGGCAT Timd4 2841 GGTCACAGGGAGCCCGACTG Laptm5 6661 GGACGCCGGACGCTCACGAG Lbr 10481 J CACTGGACCAGAGTTGGGCG Cenpj 2842 TTGCCGGAGCCGCCTCGAGG Tns3 6662 GGCACCTCCCATGCAGTGGG A d 10482 TTTGGGTACAATTATCTACA Slc26a5 2843 AAGAACAAGGAGGAGAGTAA Tctexldl 6663 GTGACGTTTAAGACTCTGAT Histlh3a 10483 AAACACTTGAAGGTGTGGCC Haver! 2844 GGAATTGTGATATAAGGCAT Timd4 6664 GGGACGTGGGTGCGGGTTTG Ascl2 10484 ACTGGACGCGCCTGTACGTG Slc22a21 2845 AAACACTTGAAGGTGTGGCC Havcrl 6665 GCGTAGGGCGCAGAGACAGT Cpne8 10485 o GGGTCAGCCCGGCGTGGCGT Prkg2 2846 ACTGGACGCGCCTGTACGTG Slc22a2 1 6666 GAGGGCCGCGGGAAGGAGGT Prosl 10486 GCTGACGCTGCTATTAGTCT Aebpl 2847 TGGCTCTTAGTTATGCTAAT Arhgap28 6667 CCAAGACGGGAGGAAAGCCT Paox 10487 GCAGATAGCGCAGGCGGCTT Slc39alO 2848 TTAAGCGCCTCAGCGGTCTG Ska2 6668 GCCCGTGTCTGAGTCTCTCC Scgblb3 10488 5 GGCGCAGACCGTGTCTTACC Nadsytil 2849 GCTGACGCTGCTATTAGTCT Aebpl 6669 CCTGTGCCGACTGACCAATT Snupn 10489 o GTAGTGCAGAGCCCATGCTC Gml2794 2850 GCAGATAGCGCAGGCGGCTT Slc39al0 6670 GGTGGATGAAACTAGCCTTG Cd52 10490 4 CGGGCCCAGCTGACA CTTAT Fam46b 2851 GGCGCAGACCGTGTCTTACC Nadsynl 6671 CCCTCTATACCAGGTTGTGA AtplOb 10491 TTTGAACAGCTGGTACCCAG Sspo 2852 GTAGTGCAGAGCCCATGCTC Gml2794 6672 CCTGTCCCATATCAGATATA Rabl3 10492 AGACCAACGCACGCGGAAGA Cbfa2t2 2853 CGGGCCCAGCTGACACTTAT Fam46b 6673 GCAGGGCGACCGCCCATCCG Ago3 10493 AGGAATGCGGAGCCGGGAAG Spen 2854 GGCAAGCGCTGGCAGCCGAG Dab2ip 6674 GATGGCCGCAGATTTGAATT Kifl5 10494 GAAGTGCATAGAGACT GAGG Oprml 2855 TTTGAACAGCTGGTACCCAG Sspo 6675 TTTAGTCTCGCAGAGGTCAA Chmp4b 10495 GGCACCTCCCATGCAGTGGG Anol 2856 AGACCAACGCACGCGGAAGA Cbfa2t2 6676 CCGTGCCTTTCTCGGGCCTT Gas211 10496 TAGAAAGACTTGCTCCACCC Skint4 2857 AGGAATGCGGAGCCGGGAAG Spen 6677 GGCAAACTCCAGGGT CCCAC Opn5 10497 GTGACGrrTAAGACTCTGAT HistllGa 2858 GGCACCTCCCATGCAGTGGG Anol 6678 TGGGAGGACTGCCGAGGCGG Rnfl9b 10498 GAGCAGAGTACCCTGGGACG Myom2 2859 TAGAAAGACTTGCTCCACCC Skint4 6679 TCTGACTTCGGATGTTTCTA Gtf2h4 10499 GGGACGTGGGTGCGGGTTTG Ascl2 2860 GTGACGTTTAAGACTCTGAT Histlh3a 6680 CCGGCTCCTCTCCGGACTTC Mcts2 10500 CGCTTCCTCCCTGTGATGAA Acnatl 2861 GGGACGTGGGTGCGGGTTTG Ascl2 6681 GGCGCAGAGACTGACAGCTG Vpsl3c 10501 CGGGAGAGCATTTATCAGCC Svsl 2862 CGGGAGAGCATTTATCAGCC Svsl 6682 TTGCTGAGACCTCCGCTTCC 5730507C01Rik 10502 TCTGCGGAGCGGGCTGTGCT Steapl 2863 TCTGCGGAGCGGGCTGTGCT Steapl 6683 CCACGTGACCGCCGATCTTC Thrap3 10503 CCAAGACGGGAGGAAAGCCT Paox 2864 CCAAGACGGGAGGAAAGCCT Paox 6684 GCGCAGTGATCCAGAGTTGA Parp6 10504 GGTGGATGAAACTAGCCTTG Cd52 2865 GGTGGATGAAACTAGCCTTG Cd52 6685 TGCCATTCCGAGTGAGAAGC Glccil 10505 CCCTCTATACCAGGTTGTGA AtplOb 2866 CCCTCTATACCAGGTTGTGA AtplOb 6686 GCACTTCCTGTAGTTGGAGC Pgbdl 10506 GGTCCTGCAGGAAGCCCTGT Atg4c 2867 GCTCCCTCTCGCGAGGAGAG Nrbf2 6687 ATGCCGGAGCTTCTGGCCCG Rlibdd3 10507 ATATTGTCACCTACAGTCAA Sult2a5 2868 TCAGAAAGTTGCACCGCAGG Gimap9 6688 TTTAAGGTCTAATGCAGAAG Bnip3 10508 GCAGGGCGACCGCCCATCCG Ago3 2869 AGCAAAGCATGGCAGGGCAT Cyp2j6 6689 AGCGGGCGCTGTGCAAGCGG Phldbl 10509 GGAGACGCGATCGTGAGAAG Trappcll 2870 GGTCCTGCAGGAAGCCCTGT Atg4c 6690 GGCACTTCCGGAATCTTGGC Pan 2 10 10 GATGGCCGCAGATTTGAATT Kifl5 2871 ATATTGTCACCTACAGTCAA Sult2a5 6691 CCTTAGCAAGCAGCTCTGCC A530032D15Rik 10511 TTTAGTCTCGCAGAGGTCAA Chrap4b 2872 GCAGGGCGACCGCCCATCCG Ago3 6692 AAATTTCGAGCAGAGACCCA Nup2101 10512 GAGTAGTTTAAGGAATGAGG Malsul 2873 GGAGACGCGATCGTGAGAAG Trappcll 6693 CCCTTTGAAGGCAAGCGGTG Plxnal 10513 CCGTGCCTTTCTCGGGCCTT Gas211 2874 GATGGCCGCAGATTTGAATT Kifl5 6694 TGTTTGGGTAAAGTTTCCTC Fbxw7 10514 GTTTCACAGCTGAATGATGC Nlrplb 2875 TTTAGTCTCGCAGAGGTCAA Chmp4b 6695 AAACTCCTGACGTCACTCCA Ppargc la 105 15 TGGGAGGACTGCCGAGGCGG Rnfl9b 2876 GAGTAGTTTAAGGAATGAGG Malsul 6696 CTCTGGCTCAGGGATGTTCA Wdrl7 105 16 CAAAGCCGAAGGTCGGCCTC Sirpa 2877 CCGTGCCTTTCTCGGGCCTT Gas211 6697 GAAGAATGGGTTAATGACCC Mppel 10517 CCGGCTCCTCTCCGGACTTC Mcts2 2878 TGGGAGGACTGCCGAGGCGG Rnfl9b 6698 CATCAGAACCTAGGAGGGAG Ptchd4 10518 TTGCTGAGACCrCCGCTTCC 5730507C01Rik 2879 CAAAGCCGAAGGTCGGCCTC Sirpa 6699 TCACTGCTGCCCGCCTACGA Ice2 10519 CCACGTGACCGCCGATCTTC Thrap3 2880 CCGGCTCCTCTCCGGACTTC Mcts2 6700 CCTCGCGTATCGTCAGCGTC Rnf32 10520 AAATGTCTAACCTCGGAGAA Satbl 2881 GGCGCAGAGACTGACAGCTG Vpsl3c 6701 GGGCAAAGATTGCCTGAGCC Tcea3 10521 n TGCCATTCCGAGTGAGAAGC Glccil 2882 AGTCTCTTGAACTCTATAAA Krt20 6702 CCCGTTCCGACAGAACCCAG Eya3 10522 GCACTTCCTGTAGTTGGAGC Pgbdl 2883 TTCAGATTTGCCTCGCTTCC Psap 6703 TGTCGACTTGTAGAGCTGGG Hpca 10523 AAGACATTTACAAGTCTAAG Bell l b 2884 TTGCTGAGACCTCCGCTTCC 5730507C01Rik 6704 TGGGAGTGGAAATTCGAA AG Vit 10524 n 4 TTGCCTGCGGCCGCCCTGGC Mme 2885 CCACGTGACCGCCGATCTTC Thrap3 6705 GCGCATCACTGGCCTGCAGG Limdl 10525 GGGAGTGGGCATGCTTCACC Csmp3 2886 TGCCATTCCGAGTGAGAAGC Glccil 6706 TTCCGATAAGTTGTTGCAAA Fga 10526 5 AGCTCAGGAATGTGGCGGCG W c2 2887 TGTACAGCTAGGCATGCTTG Gdf9 6707 GGCGAGCGAGGGAACGAAAT Hintl 10527 64 ATGCCGGAGCTTCTGGCCCG Rhbdd3 2888 GCACTTCCTGTAGTTGGAGC Pgbdl 6708 CGCCCATGACGCACCCTCTC Yars 10528 5© ATCATCAGATTGCTAAGGAA Prr27 2889 GCCCAATGCGTGTGCTTGGG Nrxn2 6709 CTAGCATTGTGTCTTCTCTT C77080 10529 TTTAAGGTCTAATGCAGAAG Bnip3 2890 AAGACATTTACAAGTCTAAG Bclllb 6710 TAATTATAGACGCATTTGCG Tmaulap 10530 CACTAACTTTGCTCAAATTC Itih2 2891 AGCTCAGGAATGTGGCGGCG Wwc2 6711 TGAGAAATAACGGCCAGCCC Gbp5 10531 ACAGTAGCCTTCAAATGAAA Cepl62 2892 ATGCCGGAGCTTCTGGCCCG Rhbdd3 6712 GGGAAAGTCCAGCAACGACA Serinc2 10532 AAACrCCTGACGTCACTCCA Ppargcla 2893 TTTAAGGTCTAATGCAGAAG Bnip3 6713 AAGCAAGCTGCATCTATCTT Lcelg 10533 o CTCTGGCTCAGGGATGTTCA Wdrl7 2894 AGCCGAGCGTGGGTACTCCC Fut9 6714 AGACACAGCTTTGGGCTGTT 01frl328 10534 GAAGAATGGGTTAATGACCC Mppel 2895 AAACTCCTGACGTCACTCCA Ppargcla 6715 ACTTAATCCGCCCAAACAAC Mut 10535 CTTTAAAGAACCTTGGGATA Stil 2896 CTCTGGCTCAGGGATGTTCA Wdrl7 6716 GACACGATGAGTGGAGGCGT Pla2g3 10536 GCGTCACTCAACAGGTCTGT Slco6dl 2897 CTTTAAAGAACCTTGGGATA Stil 6717 TCAGAATCACACTGTGGGCG Orel 10537 o AATAGGACAGTGATAGTTAA Epsl5 2898 GCGTCACTCAACAGGTCTGT Slco6dl 6718 GTATGTCTACAGATAACTTC Lars 10538 4 GGGCAAAGATTGCCTGAGCC Tcea3 2899 AATAGGACAGTGATAGTTAA Epsl5 6719 ATACATGACACAGCAGAGTT Cyp8bl 10539 CCCGTTCCGACAGAACCCAG Eya3 2900 GGGCAAAGATTGCCTGAGCC Tcea3 6720 AGTTACAGCCTGGGTCTACC Ice2 10540 ATACTCCAGCTCATAACATT Klra2 2901 CCCGTTCCGACAGAACCCAG Eya3 6721 CACAGGTGTCCTATCCATTG Citam 10541 TGACTTGATGTTACTAACGC Tfap2a 2902 ATACTCCAGCTCATAACATT Klra2 6722 AGAGAAAGCGAGTGATCGCA Ppcdc 10542 TGTCGACTTGTAGAGCTGGG Hp a 2903 TGACTTGATGTTACTAACGC Tfap2a 6723 GTATAAACACTGTATTTCCC t a 10543 GGTCCCAGGCAAATGTCGGG Btk 2904 TGTCGACTTGTAGAGCTGGG p a 6724 TCTGGCAGTGTTTATCTCGT Meal 10544 ACAGAGACTCATATTTACCT Nox3 2905 GCCAACAGACCTCGGTTTAG Pcedla 6725 CCGGCACGGGAGGAGAGCTC Zyglla 10545 AATTACAACAGTCTCAGGAA Mugl 2906 GGTCCCAGGCAAATGTCGGG Btk 6726 CTCTGTTGGGCGTGTTGCCT DusplS 10546 GCGCATCACTGGCCTGCAGG Limdl 2907 AATTACAACAGTCTCAGGAA Mugl 6727 TGCGAAGAGGCGTGGGTTCC B3galt5 10547 CCCGCAAGCCAGCTTGTGTG Satbl 2908 GCGCATCACTGGCCTGCAGG Limdl 6728 AGGTTCTGGTCAGTTTGCTC Cd38 10548 GGCGAGCGAGGGAACGAAAT Hintl 2909 GGCGAGCGAGGGAACGAAAT Hintl 6729 AAATAAGGCAAAGAAGACCC Pcdhgal 10549 CGCCCATGACGCACCCTCTC Yars 2910 CGCCCATGACGCACCCTCTC Yars 6730 GGAAACAAGGTTTCTTCTCC Tekt2 10550 CTAGCATTGrGTCTTCTCTT C77080 2911 CTAGCATTGTGTCTTCTCTT C77080 6731 AGGCTGGTGTCTGGGTGTCC Plpp4 105 1 CTCAACAECAGAACCTCGCG Zfp786 2912 CTCAACATCAGAACCTCGCG Zfp786 6732 TCACAGTGTCTGTAAGTGCA Gprl51 10552 TAATTATAGACGCATTTGCG Tmaulap 2913 TAATTATAGACGCATTTGCG Tmaulap 6733 GGCGCGTGACGCAAAGCGGC Thrap3 10553 GGGAAAGTCCAGCAACGACA Serinc2 2914 ACACAAACATCTCAGTGGTG Gimap3 6734 ACCGCGGAACTCGCGCCCGG Ptpru 10554 GAACTTGGGCGCCACGTTCC Mmpl6 2915 GGGAAAGTCCAGCAACGACA Serinc2 6735 ATGCGGTGCGGGACAGCCTC Acer2 10555 TGGACGGGCGACGGCCCTAG Rock2 2916 GAACTTGGGCGCCACGTTCC Mmpl6 6736 CGGCGGGAAAGCGCCGCTCA Ythdc2 10556 TGTGCTCCGGCGGGCAGCGG Cobl 2917 ATCCAGGAGCCACAGAAGTG Sema4a 6737 CGGGCACCACCTCGTAACAA Hnmpab 10557 GGACATTGGCGAAGGCGTGA Nupl55 2918 GACACGATGAGTGGAGGCGT Pla2g3 6738 GGGTTTCCCTTGGCGCTTTC Fam219b 10558 GACACGATGAGTGGAGGCGT Pla2g3 2919 GTTTACTTTCACTGCCCATC Pzp 6739 GAATGGAGCGGCACGTGACC Slc36al 10559 ATAACTGTGGAGGAGGCTTC Gca 2920 ATAACTGTGGAGGAGGCTTC Gca 6740 GCAGATTTAATCCGAATGCA Echdc2 10560 CGAGAGTCTGCGATTCTGGC Tnpo3 2921 CTAGGCATTAGACAACCTCC Sox5 6741 AAGATGACTTAGACCAGTGA H at 10561 GGCAGCATGGCCTGTCCGTC Msil 2922 CGAGAGTCTGCGATTCTGGC Tnpo3 6742 TTCTTGAAGTGAGTTATGTC Zranbl 10562 AGTACTTTATATTTAGCCAC Shank2 2923 ACAGGCATTACTGGGAAGTT Runxltl 6743 TGGTTGGATGCCGGAACCTT Man2cl 10563 GCTACAGCCGCCGAGCGTCG Psipl 2924 ATACATGACACAGCAGAGTT CypSbl 6744 GGATGTCAGACAGGAAGAAC Nlr l 10564 GGGACTTGCGGTAGGACGCA Cds2 2925 AGTACTTTATATTTAGCCAC Shank2 6745 CATGCGCAGGCCGCCCGGCT Kremenl 10565 CTCTGTTGGGCGTGTTGCCT Dus l 8 2926 GCACTCCGCTGCGGGCGTCG Chn2 6746 GGGAGAAACAAAGGGCTTCA Tbxasl 10566 GGTGTTTCTTCCCTATCGTG Clip4 2927 GGGACTTGCGGTAGGACGCA Cds2 6747 CTCCTAAATGTGACTTCCAA Mpdz 10567 CTGTCTTCATCCTCCAATCG Ap3m2 2928 CTCTGTTGGGCGTGTTGCCT DusplS 6748 GTAAAGGTCCTTCTTTGCCG Ermap 10568 TGGAGACrrrGAGGTTATCT Ar 2929 GGTGTTTCTTCCCTATCGTG Clip4 6749 TGCCATTAGCCCACGCAAGG ActllO 10569 n GGAAACAAGGTTTCTTCTCC Tekt2 2930 CTGTCTTCATCCTCCAATCG Ap3m2 6750 CCGCATGCAAAGAATAGCTG Histlh4c 10570 GGCGCGTGACGCAAAGCGGC Thrap3 2931 TGGAGACTTTGA GGTTATCT Ar 6751 TCAGCCTCACCTCAATATGG Arhgap40 10571 TGTCAGGCCATGAAATGCCC Besl 2932 GGAAACAAGGTTTCTTCTCC Tekt2 6752 AGGAATGAATGGCCATCAGG Aimll 10572 n AAGATGTTGCGGAGACTTAA Cdkn2c 2933 GGCGCGTGACGCAAAGCGGC Thrap3 6753 TAGAATGTGGTACAGGCGAC Obscn 10573 o ATGCGGTGCGGGACAGCCTC Acer2 2934 TGTCAGGCCATGAAATGCCC Bexl 6754 TGCCAACTGCTGAGAGACCC Bpifb2 10574 GGTGArTTAGACGGATTGCC Malsul 2935 ACCGCGGAACTCGCGCCCGG Ptpru 6755 TAAGAATGTGCCACATTAAA Histlh4i 10575 b AGCAAGACAGATAGCCATCT Frk 2936 AAGATGTTGCGGAGACTTAA Cdkn2c 6756 CCGTTAGACCGCTGTTACTC Map2k5 10576 GTGGCCAArCAGCTGTTCGC Zccl 2937 ATGCGGTGCGGGACAGCCTC Acer2 6757 CCCACCACTGACAACCTGTT Trim29 10577 J CGGCGGGAAAGCGCCGCTCA Ythdc2 2938 GGTGATTTAGACGGATTGCC Malsul 6758 TGACTAAGAACTGAAGGCAC Prpf38a 10578 CGGGCACCACCTCGTAACAA Hnmpab 2939 GTGGCCAATCAGCTGTTCGC Zcchcl8 6759 GGCACCAGCTCTGAGCTGGA Jade2 10579 TTCAGGTGGAGCCAGATGTC Pde4b 2940 CGGCGGGAAAGCGCCGCTCA Ythdc2 6760 TGCAGAACTGGAGTAAACCG TmemSOa 10580 AGAACTGAAGAGAGGAGAAA Ms4a7 2941 CGGGCACCACCTCGTAACAA Hnmpab 6761 GGTACTGTGATCTCAGTAAC Blocls2 10581 o TGTGGAGCTGGAAGGTGCGG Tgifl 2942 TTCAGGTGGAGCCAGATGTC Pde4b 6762 CGGAAAGTCCTGGCAGGACG Myo9a 10582 AGTGGCGGCCCGGCTGGCAG Ankrd44 2943 TGTGGAGCTGGAAGGTGCGG Tgifl 6763 ACGTGGTGGAATGTTACCTT Kprp 10583 CGTA G GGGAC GGGTGATCT Tgifl 2944 CGTAGAGGGACGGGTGATCT Tgifl 6764 ATGTATTGAACTGTCGTCTA Pramef6 10584 GCCACGCCCAAGCTGTCCAC Vwde 2945 GCCACGCCCAAGCTGTCCAC Vwde 6765 AGACGCGCGCCCGCAATGTC Cenpq 10585 o GAATGGAGCGGCACGTGACC Slc36al 2946 GAATGGAGCGGCACGTGACC Slc36al 6766 TCAGGATAAGAGTTGTAGCT Olfr530 10586 4 A GGATTA CAAG GGATAGCCT Cstll 2947 AGGATTACAAGGGATAGCCT Cstll 6767 ACTGTCGATCCTATATATAG Fgb 10587 CATGCGCAGGCCGCCCGGCT Kremenl 2948 CATGCGCAGGCCGCCCGGCT Kremenl 6768 TCGCCTGTCGCAAGGCATCT Gtf2h4 10588 CTTAGCTTATCTGTGCCTTT SlcSal 2949 CACAGTTCACAGTGCTGTTC Doxl2 6769 CTCCGGCGCGCTGTCCGCTG Mtmr3 10589 CTGTCTTATGCTAAAGAAGG DocklO 2950 TCTAGTTTACCTTCTCCTCT Fezfl 6770 CTGCCCAAAGTCCAGAAGTC Klc4 10590 CACAGTTCACAGTGCTGTTC Doxl2 2951 CCTCCAGGCGCAGCTAAAGA Wnt2 6771 TTCA CTT GAGTT CAAACTC C Timd2 10591 TCTAGTTTACCTTCTCCTCT Fezfl 2952 TGGTCAGGCAGCAGAATGTC Myoml 6772 GGCTCCACGTGGGCGCACCC Golim4 10592 TGCCATTAGCCCACGCAAGG ActllO 2953 CCGCATGCAAAGAATAGCTG Histlh4c 6773 GGTGCTCGCGCGTTGCCTTT Zscan20 10593 CCTCCAGGCGCAGCTAAAGA Wnt2 2954 TCAGCCTCACCTCAATATGG Arhgap40 6774 ACGATCTGTGGGCGGGCACG Clk4 10594 CCGCATGCAAAGAATAGCTG Histlh4c 2955 TAGTGTTGCTGTCTCTTTAA Taf71 6775 GGCGGGACATCCGCAAGGAG Rpp21 10595 TCAGCCTCACCTCAATATGG Arhgap40 2956 AAGCAGTCTGGGCATCTGCA Cyp2j6 6776 TCAATCTGCAAGATGTGGCG Gbp3 10596 TAGTGTTGCTGTCTCTTTAA Taf71 2957 AGGAATGAATGGCCATCAGG Aimll 6777 CTACACTGGAGTGCGTTGCC DusplS 10597 AGGAATGAATGGCCATCAGG Aim 11 2958 TGCCAACTGCTGAGAGACCC Bpifb2 6778 AGGCTTGAGAAACTGTGTAC Mppel 10598 TAGAATGTGGTACAGGCGAC Obscn 2959 TAAGAATGTGCCACATTAAA Histlh4i 6779 TGTGGTGCTACACCTTCTGC B020004J07Rik 10599 TGCCAACTGCTGAGAGACCC Bpifb2 2960 GTGACCATTTCTCCAAGTAA Tctexldl 6780 TGTGGACGTGCATTCCCTGA Tbrgl 10600 GTGGGTGAGCAAGCTGGAGT Zbpl 2961 GGCACCAGCTCTGAGCTGGA Jade2 6781 CTCCTTCTCCTAGACTACCC Bag3 10601 GTGACCATTTCTCCAAGTAA Tctexldl 2962 TCCAGTAGTTACAGTTACGA Atg4c 6782 ACATTTGCCGGGCAGGCAGG Clspn 10602 TTAATTCCTGACCCGTTAGC A2m 2963 TGCAGAACTGGAGTAAACCG Tmem50a 6783 GGCGGGCGCTGTGGAATGTA Slcl2a5 10603 ACAAAGAGTGGGTAGGCAGA T¾x22 2964 GGAGGAGGAGGGCCAGGAGA Tfap2a 6784 CAACAGGGCTCCACCGCTTC Zscanl2 10604 GGCACCAGCTCTGAGCTGGA Jade2 2965 ATGTATTGAACTGTCGTCTA Pramef6 6785 TAGAGAACTGTTGCAAGTTG H2-M10 5 10605 TCCAGTAGTTACAGTTACGA Atg4c 2966 GGACACAAAGAGAGCACCGG Kmt2d 6786 CACTCCTTCCACACTCAGAT Fine 10606 TGCA GAACTGGA GTAAACCG Tmem50a 2967 TCAGGATAAGAGTTGTAGCT Olfr530 6787 GTCAGCATGATCTCCAGACC Timd2 10607 CGGAAAGTCCTGGCAGGACG Myo9a 2968 TGTCACCAGAGCCTTAGACT Qrfpr 6788 AGGTATGTCAGTGTGGATGT AtplOb 10608 GGAGGAGGAGGGCCAGGAGA Tfap2a 2969 CTCCGGCGCGCTGTCCGCTG Mtmr3 6789 GCCTAGCCCTCTTGAATCTC Etl4 10609 TCAGGATAAGAGTTGTAGCT Olfr530 2970 TTCACTTGAGTTCAAACTCC Timd2 6790 GTGAATAGTGGCAGAGGAGA Staid3nl 10610 CTCCGGCGCGCTGTCCGCTG Mtmr3 2971 GGTGCTCGCGCGTTGCCTTT Zscan20 6791 TGTTGGACACCGACATCGAA Bcl211 10611 TTCA CTTG A GTT CAAACTCC Timd2 2972 ACGATCTGTGGGCGGGCACG Clk4 6792 CTGACGTAGCGAAGGCTGCC Dis31 10612 GGCTCCACGTGGGCGCACCC Golim4 2973 ACACACACACACGCGTCCTT Cntnap2 6793 AGTCCAGAAACTTGGCACTG Freml 10613 GGTGCTCGCGCGTTGCCTTT Zscan20 2974 CTACACTGGAGTGCGTTGCC Duspl8 6794 TTCTAGAGAGAGGCTGTCCG Arfipl 10614 ACGATCTGTGGGCGGGCACG Clk4 2975 CAGCAGGGAAGGACTCGGGT Ak4 6795 TACGGCTTCGGCTCCGTGGG Mga 10615 TAAACATTAAGCATTACCCT Slcl7al 2976 TGTGGTGCTACACCTTCTGC B020004J07Rik 6796 GATACAGCCTTCTGAATAAC S100al6 10616 ACACACACACACGCGTCCTT Cntnap2 2977 ACATTTGCCGGGCAGGCAGG Clspn 6797 GCAGGAAGCTATAAATAATT Zranbl 10617 n CTACACTGGAGTGCGTTGCC DusplS 2978 TCTGGTCTCTGTTGTTGTAG Elavl4 6798 ATTTAAAGAGACAACCGACC Adgral 10618 TTCGGCTGTAGCAGGGCTTG Lrrc63 2979 ATTCCACTAGGTGGGAATGC Slc26a8 6799 A GGTCC A CGTCAATC CCTCC Pithdl 10619 AGGCTTGAGAAACTGTGTAC Mppel 2980 CTGCCACGGTTGGTCGCGCC Myll2b 6800 GCGCTCCGAGCGCTCAGCCC Mapklipl 10620 n CAGCAGGGAAGGACTCGGGT Ak4 2981 CAACAGGGCTCCACCGCTTC Zscanl2 6801 CCCAACAAAGCAGAGACCAG 1113 10621 o TGTGGTGCTACACCTTCTGC B020004J07Rik 2982 TGATCACCTGCTCCAGCACC Calr4 6802 CATAAGGCCTACAGAGTTCT Κ1 7 10622 GAGTCGGTACCGACGGAGGG Nipbl 2983 CACTCCTTCCACACTCAGAT Fine 6803 TGCTCACCACCGCGTGCGAC Lat 10623 4 CCAGTCAGCCTGACTGCTTT Ab a a 2984 GTCAGCATGATCTCCAGACC Timd2 6804 CGACTGGCAATTCGCTCCGG Stk32a 10624 ACATTTGCCGGGCAGGCAGG Clspn 2985 AGGTATGTCAGTGTGGATGT AtplOb 6805 TGGCGGTGGCATGAGAATTG Adgrf2 10625 J GCCAGATGTTTGGCAACCTG ym 2986 GGAAGCGGTCCGACGCGAAG Hspa4 6806 ACGTCACTTCCGGCAACAAT Fbxo8 10626 TCTGGTCTCTGTTGTTGTAG Elavl4 2987 CAGGGCGCGCGTGTGAGTCC Trpm6 6807 CAAGCGTGGAACATCATCCC Scnml 10627 TAGAGGTGAGGTGTCCATCA Sycp3 2988 GGATGATCCAATGAGAATTC Brinp3 6808 TGACGCGAGCGGGCTTCCGG Ago3 10628 CTGCCACGG1TGGTCGCGCC Myll2b 2989 GTGAATAGTGGCAGAGGAGA Stard3nl 6809 AAGGACAGAGGTAGTTCAGT Psmg4 10629 o GCCTCAAGGCGCCTACACTC Wtl 2990 TGTTGGACACCGACATCGAA Bcl211 6810 GTGGGAAGCTGGTATCGTTT Cebpzos 10630 CAACAGGGCTCCACCGCTTC Zscanl2 2991 TTGGCTCATTGACCATCCAG Agmat 6811 TTAAGAACAGTTCCTAACAA Freml 10631 TGATCACCTGCTCCAGCACC Calr4 2992 TAATGCAGGCTGCAATCACT Hdac9 6812 CAGACGGCTGATCGGAAGAT Arhgdib 10632 b CACTCCTTCCACACTCAGAT Fine 2993 GTAGGACAAGGAGTTAAGAA Ccdcl36 6813 CTGCTGTACTGGGAAGTGGG Xbpl 10633 o GTCAGCATGATCTCCAGACC Timd2 2994 AGGTCCACGTCAATCCCTCC Pithdl 6814 ATCAAATCAGTTTAGTAGAG Olfrl370 10634 4 AGGTATGTCAGTGTGGATGT AtplOb 2995 GGCGGACACAAAGCCTCCCG Tra2a 6815 TCAGGCGCGTGGAACGTTTA Bcl211 10635 G4 GCTAGCTAGGAAAGGAGGCG Frmd3 2996 TGAGCGGGTGAGTCTCAAG A Herc2 6816 GGGCCTGAGGCAGGAGTGCG Bnip3 10636 GTGAATAGTGGCAGAGGAGA Stard3nl 2997 AGCGGAATAACGGCAGAAGG Spdya 6817 TCCTCGTCCGGAGACTGCTG Atg2b 10637 TGTTGGACACCGACATCGAA Bcl211 2998 GCGCTCCGAGCGCTCAGCCC Mapklipl 6818 GCGGTGCCGCGGGCTCTCTA Plagl2 10638 CTGAGAACCrrCTCCGGCAG Sgol2b 2999 CCCAACAAAGCAGAGACCAG 1113 6819 GGCAGCAGGCGGGCCTGCGC Eif4enifl 10639 TTGGCTCATTGACCATCCAG Agmat 3000 CGACTGGCAATTCGCTCCGG Stk32a 6820 TGTCGGCGCGCCTGCGCAGT Taf4 10640 AGGTCCACGrCAATCCCTCC Pithdl 3001 ACGTCACTTCCGGCAACAAT FbxoS 6821 GGGACAGAGCTGCTCGCTAG Pafah2 10641 GGCGGACACAAAGCCTCCCG Tra2a 3002 TGACGCGAGCGGGCTTCCGG Ago 3 6822 GAAAGTTTATCTGGCAAGTT Clqtnf7 10642 AGCGGAATAACGGCAGAAGG Spdya 3003 AAGGACAGAGGTAGTTCAGT Psmg4 6823 CGCAGTAGTCCCTTCGGCTG Ralgapb 10643 GCGCTCCGAGCGCTCAGCCC Mapklipl 3004 GAGGATGAAGCGTGCGGAAG Scn8a 6824 ACTGAAGAATTACTTCCAAG Heyl 10644 CCCAACAAAGCAGAGACCAG 1113 3005 TTTGCACAGCAAGACACTGG Bex4 6825 ACAATAGGTCCAAACCACCG Ruscl 10645 CGACTGGCAATTCGCTCCGG Stk 3 3006 GAACCCACTGACGTAGTCTC RapgeD 6826 AGCAGCTTTAGAAACTAAGC Chm lb 10646 ACGTCACTTCCGGCAACAAT FbxoS 3007 CTGCTGTACTGGGAAGTGGG Xbpl 6827 TGAAGGAAGGCAGTCCGCAC Aimll 10647 TGACGCGAGCGGGCTTCCGG Ago 3 3008 ATCAAATCAGTTTAGTAGAG Olfrl370 6828 GGTCTGAGTTGGGCCCGAGA Eci3 10648 AAGGACAGAGGTAGTTCAGT Psmg4 3009 GCAGGGCATGACCTAGTACC Aass 6829 CCTCACGAAGAGTAAGTGTT AU022252 10649 CTGCTGTACTGGGAAGTGGG Xbpl 3010 TCAGGCGCGTGGAACGTTTA Bcl211 6830 GGTCAGGGCCACGACAGAGA Col22al 10650 ATCAAATCAGTTTAGTAGAG Olfrl370 3011 GGGCCTGAGGCAGGAGTGCG Bnip3 68 GTGCTACGCGGGTCCGGCGG Patzl 10651 GCAGGGCATGACCTAGTACC Aass 3012 GCGGTGCCGCGGGCTCTCTA Plagl2 6832 CGGAGGTGACTGGACTAATA Cd38 10652 TCAGGCGCGTGGAACGTTTA Bcl211 3013 GGCAGCAGGCGGGCCTGCGC Eif4emfl 6833 GAGGCTCCTAGTCCGGCTGC Hcn4 10653 GGGCCTGAGGCAGGAGTGCG Bnip3 3014 GGGACAGAGCTGCTCGCTAG Pafah2 6834 GCCTTGCTGTGGGCCTTCTA Pglyip4 10654 GCGGTGCCGCGGGCTCTCTA Plagl2 3015 CGCAGTAGTCCCTTCGGCTG Ralgapb 6835 AGCCGTTCCCTCGGAGCTAA Tinagll 10655 GGCAGCAGGCGGGCCTGCGC Eif4emfl 3016 CGCCTAGTGGCGCGGTCTGC Ntik3 6836 TCTAGGCTGCTGGCAGCGCG Meal 10656 GGGACAGAGCTGCTCGCTAG Pafali2 3017 CAGCGCCACGGTTCGGACTA Nkapl 6837 CCTCAGTATAAAGTCCAGCC Pou6f2 10657 CGCAGTAGTCCCTTCGGCTG Ralgapb 3018 TGAAGGAAGGCAGTCCGCAC Aimll 6838 CTCCTTTCACTTCGGGCGAG Vegfc 10658 GCTACTCAAGTGTGTGCAGC Luzp2 3019 GGTCTGAGTTGGGCCCGAGA Eci3 6839 GGTTTCCAAGTGCGGGAGAC AbcclO 10659 TGAAGGAAGGCAGTCCGCAC Aimll 3020 GTGCTACGCGGGTCCGGCGG Patzl 6840 TGCTTCGCGTGAGCGCCCTC Cbfa2t2 10660 GGTCTGAGrTGGGCCCGAGA Eci3 3021 ATCATGTTCGAAGTGGCGTG Ulk4 6841 TGGATTTATTGAGAAGGGTC 1113 10661 GGTCA GGGCCA CGA CA GAGA Col22al 3022 GGATGGGCTGAAATAATTGC Elavl4 6842 TTGAGAGCTGGGTGGAAGCC Mycs 10662 GTGCTACGCGGGTCCGGCGG Patzl 3023 AGCCGTTCCCTCGGAGCTAA Tinagll 6843 GGCATAGATGCGTGGAATCT Lrrc71 10663 CTCTGCGTCGCTAGCGCTCC Nebl 3024 CGGCATAACACGGCACACAC Top2b 6844 ATCTCAACGGCCAGCCCGGC Skpla 10664 ATCATGTTCGAAGTGGCGTG Ulk4 3025 ACTCAAGACATCATGCAGTA Calr4 6845 CCAGG CAA CAT ATC AGGA CA Tiaml 10665 n GGATGGGCTGAAATAATTGC Elavl4 3026 GTGTCACATGACTCTGGCAC Cyb5r2 6846 TGGTTAATCCTTAACCCTGG Ccr9 10666 AGCCGrrCCCTCGGAGCTAA Tinagll 3027 CCTCAGTATAAAGTCCAGCC Pou6f2 6847 AAGTGAGCCTTTCAATGTCG Ppcdc 10667 ACTCAAGACATCATGCAGTA Calr4 3028 CTCCTTTCACTTCGGGCGAG Vegfc 6848 CGCAGGCCTACAGGCAAGCG Stm 10668 n CTTTACAAACCACTCTGCCT 9230104L09Rik 3029 CATGTTAAGAATTACAGTAC Atg4c 6849 TCAGAGCCCGCGTCCATTCC Mtfrll 10669 o GTGTCACATGACTCTGGCAC Cyb5r2 3030 TCAGAGTTTCCCTGTGACCC Pde4b 6850 GTGGCGTGATGGCAGAGGGC Map 9 10670 CCTCAGTATAAAGTCCAGCC Pou6f2 3031 TGAGATCAGCTGAAGCCCTA Tgifl 68 TCAGCCATTGGCTAGAAACC Creb314 10671 CTCCTTTCACTTCGGGCGAG Vegfc 3032 TGCTTCGCGTGAGCGCCCTC Cbfa2t2 6852 CTGTTCTCTCTCCCGGGAGG Hpca 10672 CATGTTAAGAATTACAGTAC Atg4c 3033 TGGATTTATTGAGAAGGGTC 1113 6853 CCCTTGCAACCTCTTTCGCT Extll 10673 J TCAGAGTrrCCCTGTGACCC Pde4b 3034 TTGAGAGCTGGGTGGAAGCC Mycs 6854 GGGTGGAGTTTAATGAGAAA Ccr5 10674

CTAGTGACGTGAGCCGTGCC Psd3 3083 ACTTGTCGCTCTGCCGCGAC Prkcq 6903 GTTCTCCCGCGGCTCGCACA Sdc3 10723 CGCGTGCTCGTGGCCACCGT Otud7a 3084 AAA CATTCTTCG CGACACAA Uqcib 6904 CTGGTATGTAGTGGATGCCC Pdrgl 10724 AGGAGCATGTCGGGAATAAC P c2 3085 CACGTAAAGAACTGGATATG Ap3bl 6905 AGAGTGCGAGGGCGACCAGG Sugct 10725 o TAAGAAGAGGGAAAGGGTTC Fat2 3086 AACAGACAGAAGACACACAA Cacnale 6906 CAAGAGGCAGGCGCGTGGAT Rpap2 10726 GGAACAATGTTTCAAGACTG Elavl4 3087 TATGTCAAATGTGTGTAAGG Tas2rll8 6907 TGTCTTCATTGTGGAAGGTG Flg2 10727 CTGCAAGCGTTrCGAAGACC Myll2b 3088 AGGAGCATGTCGGGAATAAC Pnrc2 6908 CCAGGCCACGGAGCAGGGCG Sh3bgrl3 10728 5 AAGAGGCCGCCTGCCTGGCA Th 3089 TAAGAAGAGGGAAAGGGTTC Fat2 6909 AGACAGCACATGCCCAACTG PlacSll 10729 o TACTTGGATCTCCTGGTTCA Av 3090 GGAACAATGTTTCAAGACTG Elavl4 6910 CCCTCGCCGCCTGCGCGCGT Cdh2 10730 4 GCACTAGAAACCCGAGAACG Cep44 3091 CTGCAAGCGTTTCGAAGACC Myll2b 6911 CACTTAAGGTTGTAAACTGT Asic5 10731 GTTTCCTGCAGAGCAAGCAA Ptafr 3092 AAGAGGCCGCCTGCCTGGCA T 6912 AGAACTAGCCCTGGTGAAGT Slc22al8 10732 CCGAGGAGCCAATCAGAGGG Fam46c 3093 GCACTAGAAACCCGAGAACG Cep44 6913 GGGCGGGACCTGACAGGCTT Acer2 10733 GGGTGGGCTCTGCACCGTGG Epha4 3094 GTTTCCTGCAGAGCAAGCAA Ptafr 6914 GCGCAGGAAGGAGGTGCCGC Tgii2 10734 GGAGCTAGAGAAAGAACCCA leal 3095 ATTATCTCCCACAGGCATGG Psap 6915 TTGGGACATGGATTGGACAA Bsdcl 10735 CTGCCAGGAGCTTCCGGCGC Kif3a 3096 CCGAGGAGCCAATCAGAGGG Fam46c 6916 ACGAGCATCCTTGCATCTGC Tekt2 10736 AGCCCGGATCGCATAGACCC Plekhm2 3097 GGAGCTAGAGAAAGAACCCA leal 6917 CACTTGGTCTGTCCTGCAGC Stra6 10737 GGAGGTCCTGGGTAGGACAG Lamal 3098 CTGCCAGGAGCTTCCGGCGC Kif3a 6918 GAACCTGAGAGGTGGGTTTG Slc37a2 10738 TCAGGATGACCAATGTCAAC Pou6f2 3099 AGCCCGGATCGCATAGACCC Plekhm2 6919 ACAGCCGGACCAGGAGTGCC Hhat 10739 GCAGCCCrGCCCAGATTAAG Col4a4 3100 GGAGGTCCTGGGTAGGACAG Lamal 6920 GGGAATCACTTGTGTAGCTC Cdl6412 10740 TGGAAGAATCGCTCACTCGG Cntnap5b 3101 TCAGGATGACCAATGTCAAC Pou6f2 6921 TCACCCATCTGAGTCCTTCA Gatsl3 10741 GATAGGTGTCGGTCTATAAA Leap2 3102 GAGTCTAGATATTTATTCCC Zfp951 6922 CGAGGAGGCCCGGCAGCGTG Aplbl 10742 GTTCTCCCGCGGCTCGCACA Sdc3 3103 TGGAAGAATCGCTCACTCGG Cntnap5b 6923 TACCCATGAACACAGGCCAC Slc24a2 10743 CTGGTATGEAGEGGATGCCC Pdrgl 3104 GATAGGTGTCGGTCTATAAA Leap2 6924 CCGCAGCCAATTTGAGTGGG Sehll 10744 CGCTTTAGGCGCGCCAATGT Arl5a 3105 GTTCTCCCGCGGCTCGCACA Sdc3 6925 TAGAAACTCTAACGGATGTC Runx2 10745 GAAATGGTGCAGGGAGTCTA Itgb3bp 3106 AGCTTAAGAGGTGAATATAG Sema4a 6926 GCGCCTGGCTTACGAATAAT Traeml06b 10746 AGAGTGCGAGGGCGACCAGG Sugct 3107 CTGGTATGTAGTGGATGCCC Pdrgl 6927 AGGGAGGGAAGAGAGCAAGG Runx2 10747 GCGGAATGATGCTCAAAGCT Snmp48 3108 GAAATGGTGCAGGGAGTCTA Itgb3bp 6928 CTGACCCACGTGGGCCGGTT 5730409E04Rik 10748 GATATCCAAATAGTTGTTTG Clip4 3109 AGAGTGCGAGGGCGACCAGG Sugct 6929 AATGAGCCAAGAGAGAGTGC Gjb4 10749 CCAGGCCACGGAGCAGGGCG Sh3bgrl3 110 GAGTAAGGACTGCACATTTG Agip 6930 CTGGAGGCACCCGGTGTTGG P d 10750 TCTCAGGCTCATCCGACACA SlcSal 3111 GGAAATTCAGTCATTGAGTG Zfp212 6931 GCTAATGAAATTAGGTCAAT Kdm4c 10751 GGAACGATGATGAGGAGCTG Efhd2 3112 GCGGAATGATGCTCAAAGCT Snmp48 6932 GAACCTTGCTAATTCCTAGA Par 2 10752 TAATGCTCAGArCTGATAAG Herc3 3113 GATATCCAAATAGTTGTTTG Clip4 6933 GTCAGAACATCAAAGGATGG Bpifb5 10753 AGAACTAGCCCTGGTGAAGT Slc22al8 114 TATCATCGACGACCATCTGG Zfp593 6934 GGGATGTGGCTAGAATCTCC Ruscl 10754 TCAATGCTCCTCCTTCACGT Obox7 3115 CCAGGCCACGGAGCAGGGCG Sh3bgrl3 6935 TCAGCCCTCTCACGCTCCGG Clintl 10755 GGGCGGGACCTGACAGGCTT Acer2 3116 AGGAGCTTATGCCTGCTTGT Mumlll 6936 CGGATCTTCTGTGCCCACCC Col9a2 10756 TCCGAAGCTGCTGGAGTCAC PcdhlS 3117 GGAACGATGATGAGGAGCTG Efhd2 6937 ATACGGTCTCGTGGGCCGAT Hnmpr 10757 GCGCAGGAAGGAGGTGCCGC Tgif2 3118 TAATGCTCAGATCTGATAAG Herc3 6938 TTGGGCTAGAGCGGAAGTGG Ywhab 10758 TTGGGACAEGGATTGGACAA Bsdcl 3119 AGAACTAGCCCTGGTGAAGT Slc22a 1 6 9 CTTGTTAAGGTTACAAGTCC Tssc4 10759 ACGAGCATCCTEGCATCTGC Tekt2 3120 GGGCGGGACCTGACAGGCTT Acer2 6940 AAGCTGTGTAGTTAGAAGGG Arhgef38 10760 CGGAATCACGGTCGTGGGCG Ttl 3121 GCGCAGGAAGGAGGTGCCGC Tgif2 6941 GACTTCACGTTCTCTAGGCT Uqcrq 10761 n GGGAATCACTTGTGTAGCTC Cdl6412 3122 TTGGGACATGGATTGGACAA Bsdcl 6942 AGTTTCACTCTG GCGTACAA Zfp46 10762 CTCCTCTGGCCATAAATGGG Myom2 3123 CTTCCTCCGGTGACTGTGCC Fut9 6943 AGTGCTGACAGCTTCCGGTC Rab3gap2 10763 AAGTCCAATAATCCCTCTAT Cdh26 3124 ACGAGCATCCTTGCATCTGC Tekt2 6944 GGACTGAAATCCATGAAGCC Spire 1 10764 n TCACCCATCTGAGTCCTTCA Gatsl3 3125 GGCACGTCACCAGTGAGATC Armcxl 6945 TGCCTATGGGATAGAGACGG Cxcr6 10765 o CGAGGAGGCCCGGCAGCGTG Aplbl 3126 AGGCTGCTAGAGTGGGCCGC Adgb 6946 TTCAGATTGTACTCTGTACG A3galt2 10766 5 TACCCATGAACACAGGCCAC Sl 2 a2 3127 CGGAATCACGGTCGTGGGCG Ttl 6947 GACGTCATGCTCAGTGCCCG Serpinb9c 10767 b GTTAACGArTGGCGAGATCT Fezfl 3128 ATGCTGACTTTCTCGGAGCC Clec3b 6948 AAAGATTATGGTAAGCATGC Foxp2 10768 5© GAGACCATATTEGTTCACAG Lcp2 3129 GGCTAATCTCACAAATTCAC Dnm2 6949 AGGAGGAGGAGAAGAAGGCA Col6a3 10769 J GAATGGGTCGGGAGACACGG Tall 3130 GGGAATCACTTGTGTAGCTC Cdl6412 6950 GTTAAAGGTCAATCTAAGCA Nlip2 10770 GCGCCTGGCTTACGAATAAT Tmeml06b 3131 AAGTCCAATAATCCCTCTAT Cdh26 6951 GAGAACACTGCCGCCCGACT Abcg4 10771 CTGACCCACGTGGGCCGGTT 573O409E04Rik 3132 TCACCCATCTGAGTCCTTCA Gatsl3 6952 GCATACTTCGAGCATTCCTT Coll2al 10772 AATGAGCCAAGAGAGAGTGC Gjb4 3133 CGAGGAGGCCCGGCAGCGTG Aplbl 6953 ATACTCCTGTCCAAACTAAG Hepacam 10773 o GGGACGTCTCCTTCTGTTTG 803041 lF24Rik 3134 TACCCATGAACACAGGCCAC Slc24a2 6954 AACCACATGCTTTCTGCCTC Xkr7 10774 ATGCCCAACTTACTGAAAGT Nlrplb 3135 GTTAACGATTGGCGAGATCT Fezfl 6955 ATTGGTCGAGAGCGATGCGG Ncdn 10775 ACTCGTGGAGCTGAGCCGCC Diaph2 3136 TAGAAACTCTAACGGATGTC Runx2 6956 CTCTAGCTGACACAACCTCC Arhgef2 10776 5 GTCAGAACATCAAAGGATGG Bpifb5 3137 GAATGGGTCGGGAGACACGG Tall 6957 CTAGACCCAAATATTTCTCC Dtna 10777 o TCAGCCCTCTCACGCTCCGG Clintl 3138 GCGCCTGGCTTACGAATAAT Tmeml06b 695 8 TGGCTGGCTGTACGTGAGAA Havcrl 10778 4 CAGCCACAATGAAGTACCCA Cntnap2 3139 AGGGAGGGAAGAGAGCAAGG Runx2 6959 ACTCCGAGGACCAATCGGTG Hnmpr 10779 GCTGTGACTCATGGCGTTCC Svsl 3140 CTGACCCACGTGGGCCGGTT 5730409E04Rik 6960 GCTGTGTCTGTGCCTCGCAT Nsmce4a 10780 CCTGGCCCGCTGTGCCTTGC Bphl 3141 AATGAGCCAAGAGAGAGTGC Gjb4 6961 ACTAGTGCTATCTTTAAGAC Havcrl 10781 GTTGCTAAGCAACATTTAGA Pde4b 3142 CTGTGAGTAAGCGAACAAGC Stl8 6962 GAATCCTCTACACCCGCTTT Them4 10782 ATACGGTCTCGTGGGCCGAT Hnripr 3143 GGGACGTCTCCTTCTGTTTG 8030411F24Rik 6963 TCGGATTCTATCCGGCCCGG Nt5cla 10783 TTGGGCTAGAGCGGAAGTGG Ywhab 3144 ACTCGTGGAGCTGAGCCGCC Diaph2 6964 TTTAACTTACTGCTGTCAAG Fbxw7 10784 CTTGTTAAGGTTACAAGTCC Tssc4 3145 ATAGAGAGATCCTAGGAGGG Sgce 6965 CTCTGAAGCCAGGCAGATTG Fuom 10785 GACTTCACGTTCTCTAGGCT Uqcrq 3146 GTCAGAACATCAAAGGATGG Bpifb5 6966 CCTGACGGCAGTCGAAACAC Skpla 10786 AGTTTCACTCTGGCGTACAA Zfp46 3147 GACTCCTTCAGAGTTGAGAA Eci2 6967 ATAGAGTTCGAGAGGACGTC Thrap3 10787 GTTGTAAGGAGCAAGATTTA Cs d3 3148 GTCAAAGAGACTGGTAATCT Capnl3 6968 ACGGATCCTTAAATATGCTG Dst 10788 CCTTTCACACCGGAACCTGA Aszl 3149 TCAGCCCTCTCACGCTCCGG Clintl 6969 CAAACTGCTGGCGAGTCAAG Pigv 10789 TACAGCAAGCTATGGCTGAG Dawl 3150 CAGCCACAATGAAGTACCCA Cntnap2 6970 CCCGTCGCGGCTCTAGTTCC Syde2 10790 AGCATGCGCAGAACAGCCGG Ublcpl 3151 GCTGTGACTCATGGCGTTCC Svsl 6971 AGACAGTAACACCCATCTTC Serpinb9c 10791 TTCAGATTGTACTCTGTACG A3galt2 3152 CCTGGCCCGCTGTGCCTTGC Bphl 6972 GGCGCGCAAAGAGTGACCGC Cdc42se2 10792 TGTGCCGACCrTGAGCGCCC Ttc39a 3153 GTTGCTAAGCAACATTTAGA Pde4b 6973 GGGAGGACAGCATTTAGCTC Hpca 10793 GACGTCATGCTCAGTGCCCG Serpinb9c 3154 ATACGGTCTCGTGGGCCGAT Hnmpr 6974 GTCCCTGACACTTCCTTTCC Vmnlrl88 10794 o AAAGATTATGGTAAGCATGC Foxp2 3155 CTTGTTAAGGTTACAAGTCC Tssc4 6975 GTTGCTCCGTCCTCCTGAAA Ywhab 10795 GTTAAAGGTCAATCTAAGCA Nhp2 3156 TGCTTCCTGAGTGTGAGCGC Glis3 6976 ATGAAAGGGCGAGCCCACGC Rraga 10796 TGTAGAAGAGACTCAGGCCT 01frl324 3157 GACTTCACGTTCTCTAGGCT Uqciq 6977 TCCTAGGATGTTACACTTGG Myl7 10797 CCCACGCCACGCCCTATAAG Cacnalb 3158 TGGGATAGAAATCACAACGC Atp6v0al 6978 GCTGACTCCCGGCGCGTTGG Rps6kal 10798 CAGAAGCCAGAACCCGTGTC Tnpo3 3159 AGTTTCACTCTGGCGTACAA Zfp46 6979 AACCACAGAACCACAAGGCC Runx3 10799 GCATAC TCGAGCATTCCTT Coll2al 3160 GTTGTAAGGAGCAAGATTTA Csmd3 6980 GGGCGGTGCTCCCAGATCTC UbaslGb 10800 GGCATCTGTCTCCTGACTAA Slc5al2 3161 TGACGGCCCGCCGGCCCAAC Copg2 6981 GTACATCTATTACGTTCGTC Pgbdl 10801 GCTGCGTTGCGTCTGCCTTC 9030624G23Rik 3162 CCTTTCACACCGGAACCTGA Aszl 6982 GTAACTAGAGTGTCAGAACA HistllGc 10802 AACCACATGCT1TCTGCCTC Xkr7 3163 TACAGCAAGCTATGGCTGAG Dawl 6983 ACGGCGCCGCTATGCACTGT Zc3hl5 10803 ATTGGTCGAGAGCGATGCGG Ncdn 3164 AGCATGCGCAGAACAGCCGG Ublcpl 6984 CCAATGCAGAACTTT GCATC Ogdh 10804 CAGGAGAGCCCATCCGCCAG Unc79 3165 TTCAGATTGTACTCTGTACG A3galt2 6985 GCGCCGTAGTCGCCGTGAGT Sh3d21 10805 CATGGACAGAGGCGCCACCC Wwcl 3166 TGTGCCGACCTTGAGCGCCC Ttc39a 6986 GACAGGGTCTCGTGACGGCC Dnajcl3 10806 TGGCTGGCTGTACGTGAGAA Havcrl 3167 GACGTCATGCTCAGTGCCCG Serpinb9c 6987 GGCGTCTTCTCTAGCTGGCC Phldbl 10807 ACTCCGAGGACCAATCGGTG Hnripr 3168 AAAGATTATGGTAAGCATGC Foxp2 6988 GGACCTACGGAGATTACTTC Dph2 10808 ACTAGTGCTArCTTTAAGAC Havcrl 3169 GTTAAAGGTCAATCTAAGCA Nhp2 6989 TTCTAGAAGAGACTGTCAGG Laol 10809 n GACGAGCGCTGCGCCAGCGA Zbtbl7 3170 CAGAAGCCAGAACCCGTGTC Tnpo3 6990 GAATAGCACTGCAGTTACCA ArhgeHl 10810 CTAGGGTAGAGCGGGAGCTG Fam221a 3171 GCATACTTCGAGCATTCCTT Coll 2a 1 6991 GCAAACTGGTATGCAGAAGT Ccr2 10811 CTCTGAAGCCAGGCAGATTG Fuom 3172 AACCACATGCTTTCTGCCTC Xkr7 6992 AAAGATGATTGCTCAAGCCC Gbp3 10812 n CCTGACGGCAGTCGAAACAC Skpla 3173 ATTGGTCGAGAGCGATGCGG Ncdn 6993 CAGATTCTCCAAGGCTGATG Cyp21al 10813 o ATAGAGTTCGAGAGGACGTC rap3 3174 TGTGATTGGACGGAGCGCGG Dicerl 6994 TAAAGGTGTGTGTTTCTACC Tdpozl 10814 5 CAAACTGCrGGCGAGTCAAG Pigv 3175 TGGCTGGCTGTACGTGAGAA Havcrl 6995 TGTCTAGGCAAATGTCTACC Trcgl 10815 b TGCTCCCTGGGTCAAGCAGG Mpped2 3176 ACTCCGAGGACCAATCGGTG Hnmpr 6996 CCCGGCGCCGGAGCGAGAAG RasllOa 10816 5© AGACAGTAACACCCATCTTC Serpinb9c 3177 ACTAGTGCTATCTTTAAGAC Havcrl 6997 AGTCGCCGTTCTCATTACCA Adaml2 10817 J AATCAAAGCACATCAAGAGC Gabrp 3178 GACGAGCGCTGCGCCAGCGA Zbtbl7 6998 TCACTCACGACCACGTCCGC Bdnf 10818 GGCGCGCAAAGAGTGACCGC Cdc42se2 3179 CTAGGGTAGAGCGGGAGCTG Fam221a 6999 GGAGGCTGAGCGGAACGGAG Ptpn9 10819 GGGAGGACAGCATTTAGCTC Hpca 3180 CTCTGAAGCCAGGCAGATTG Fuom 7000 GTACTAGCTGCGGGTGCTGC Sept8 10820 GTCCCTGACACTTCCTTTCC Vmnlrl88 1 1 CCTGACGGCAGTCGAAACAC Skpla 7001 GCATCTGTGTGACTGTGTTG Gm7 4 10821 GTTGCTCCGTCCTCCTGAAA Ywhab 3182 ATAGAGTTCGAGAGGACGTC Thrap3 7002 GCACTGATTGATCCTGGGAG Marchl 10822 ATGAAAGGGCGAGCCCACGC Rraga 3183 CAAACTGCTGGCGAGTCAAG Pigv 7003 GGCTGCAAGTCACCAGACTG Mtmr3 10823 TCCTAGGATGTTACACTTGG Myl7 3184 AG CAGTAACA CCCATCTTC Seipinb9c 7004 GGAAGGAGGATTA AACCCGG Rab38 10824 GCTGACTCCCGGCGCGTTGG Rps6kal 3185 GGCGCGCAAAGAGTGACCGC Cdc42se2 7005 GGCAGCGAAATGGTATTTCC Braprlb 10825 AACCACAGAACCACAAGGCC Runx3 3186 TAAGGGCAGGCCACAGAGTG 01fm4 7006 GAAACAGTACTTCCGGCCTC Aoa 10826 GTACATCTATTACGTTCGTC Pgbdl 3187 GGGAGGACAGCATTTAGCTC Hpca 7007 GGTGGAGGAGGCCCACCTGT Htrld 10827 CTGGTCTCTCACTATGTACT 01frl324 3188 GTCCCTGACACTTCCTTTCC Vmnlrl88 7008 GGTTCTCAGCTGGACAGCCA Amhr2 10828 GTGGGACAAAGAACTACTTC Naa20 3189 ATGAAAGGGCGAGCCCACGC Rraga 7009 GGACGCGGTTAACCCTTCCT 1700056E22Rik 10829 CTCACACTTATGCCCTGGTC Cst8 3190 TCCTAGGATGTTACACTTGG Myl7 7010 AGTCGGGCGTGGCTCGAAAG Ccngl 10830 ACGGCGCCGCTATGCACTGT Zc3hl5 3191 GCTGACTCCCGGCGCGTTGG Rps6kal 7011 GGCACAGCTTGTTTGCTAGC Tdo2 10831 CCAATGCAGAACTTTGCATC Ogdh 3192 AGCGGTGTAATTAAACAAGC Ank2 7012 CCAGACCCGGAGTTAAAGGG Gas211 10832 AGGAGTGGAAGGTGGCGACA Pax7 3193 CTGGTGATGAGTCAGTGCCC Trimll 7013 GCAAGGTAAATGCAAACAAC Lrplb 10833 GCGCCGTAGTCGCCGTGAGT Sh3d21 3194 AACCACAGAACCACAAGGCC Runx3 7014 GGGACGACCCAGGAGTGAAG Nefh 10834 TATTAGCGTGCACTTCACAA Rsclal 3195 GTACATCTATTACGTTCGTC Pgbdl 7015 GACCAAAGGAGGCCAGTCAG Rcan2 10835 GCCTGTGGGAAGGGCCGACC Nrsnl 3196 AGTGGAGTGTAAACGCGGGC Steap2 7016 CTAGGTAAGTGGATGGTGAG Hpca 10836 GGAGTCGCTGTGGAAATACA Insl5 3197 GTGGGACAAAGAACTACTTC Naa20 7017 AGAAGCTTTGTTCTAAAGTC Lce6a 10837 GTTAACCCGAAGTTAACTGG Gtpbp3 3198 CTCACACTTATGCCCTGGTC Cst 7018 ACAGGGAGAGAAAGCGAATC Gucy2e 10838 CCGCAAAGGTTGGCCACGTG Nkx2-2 3199 GTAACTAGAGTGTCAGAACA Histlh3c 7019 AGGACAGCAGAAGCAGGAGC Bpifb9a 10839 ATCATCTCACGAAACAAATT Ms4a7 3200 CCAA GCAGAACTTTGC AFC Ogdh 7020 TGACACTATAGTGAGCTGCA HistllGb 10840 ACGAGGCCCAACTCATTCCC Rasef 3201 AGGAGTGGAAGGTGGCGACA Pax7 7021 AGGTTTGAGGAAGTCGTGGT Fcrll 10841 TTTCA GCGCACCATGTG CCG Thsd7a 3202 GCGCCGTAGTCGCCGTGAGT Sh3d21 7022 GAGCGCTGGGCAGGTGATGG Ncmap 10842 GGCCGGCGACTCTGAGTATC Docks 3203 TATTAGCGTGCACTTCACAA Rsclal 7023 CCATATGTCTGTATTTGAGC Gml0696 10843 GGATGTTCTGAGAGGCTCAG Kir3dll 3204 GTTTCCAGGCAGGCTGCGGG Dab2ip 7024 GCTGGATCCACTGCAATGGC Pi4k2b 10844 CCCGGCGCCGGAGCGAGAAG RasllOa 3205 TGCACGATGGCAGGAGAAAG Ube2h 7025 ATTTGCATATCATCACTGAT Gramd2 10845 TTTGTGAAGGTCTGTGGGCG Oca2 3206 GGAGTCGCTGTGGAAATACA Insl5 7026 TGAATTCGGAGTGCTCGTGG Gpx5 10846 TGGCTGGCCGCTCGAGGTGG Mierl 3207 ATTGCTACTTTGCACTGCAA P ex 7027 CTTCCTGTGGCGACCCTGCG Tubgcp2 10847 GTACTAGCTGCGGGTGCTGC SeptS 3208 CCGCAAAGGTTGGCCACGTG Nkx2-2 7028 AAGGAACCAGATTAGTGTGC Vps41 10848 GCATCTGTGTGACTGTGTTG Gm7534 3209 GATTGAACAATGACAGCTTT Clec3b 7029 ACTTATCTCCAGGCAGTAGG Tspanl 10849 GGCTGCAAGTCACCAGACTG Mtmr3 3210 ACGAGGCCCAACTCATTCCC Rasef 7030 GAGCTCGGTTTCGAGGTCCT Trim62 10850 CCCGCCGAAGTGGTGCGGGT Otud7a 3211 GGATGTTCTGAGAGGCTCAG Kir3dll 7031 CCCGAGCTAGAGACGCCGTC HiOa 10851 ATACACAGTACCCATTACCC Nliplb 3212 CCCGGCGCCGGAGCGAGAAG RasllOa 7032 TGTGCCCGCCTGCCACCGCC Acer2 10852 GGCAGCGAAATGGTATTTCC Bmprlb 3213 TGGCTGGCCGCTCGAGGTGG Mierl 7033 TAGAGCACCCACACCACAGA Lif 10853 GAAACAGTACTTCCGGCCTC Aoah 3214 GTACTAGCTGCGGGTGCTGC SeptS 7034 GAATGTGCGTATGTTATAAA Dpysl3 10854 GGTGGAGGAGGCCCACCTGT Htrld 3215 GCATCTGTGTGACTGTGTTG Gm7534 7035 TGCTCTGGCTTGGACGAAGG Cep44 10855 AGGAACTGGGTGTTGAGATA Tall 3216 GGCTGCAAGTCACCAGACTG Mtmr3 7036 CTTTCGCCTCCCTGTCATCC Pkn2 10856 AGTCGGGCGTGGCTCGAAAG Ccngl 3217 AGTCAAAGTTCAGCAGGAAA Trmt2b 7037 CCTCGGCTCTGAACAAGGCC Sparc 10857 CCAGACCCGGAGTTAAAGGG Gas211 3218 GAAACAGTACTTCCGGCCTC Aoa 7038 ACGAGATTCAGCGTTCAGTA Morc2a 10858 GCAAGGTAAATGCAAACAAC Lrplb 3219 GGTGGAGGAGGCCCACCTGT Htrld 7039 GGGTATAAATGGAGCGGTGG Pabpc4 10859 GGGACGACCCAGGAGTGAAG Nefh 3220 CTTAGCACTCTCAGTATAAG Tas2rll8 7040 AGAGCCGAGACGCTTAAGAA Eci3 10860 CTCCCAGAAGCTTTAAGTTT Ddx60 3221 TGTGAGGGTGGATTAAGTAC Plekhsl 7041 GTCTCCCTGGTCTCTCGGAG C77080 10861 ATTAGGAGTGAGTGCTGCGC Ing2 3222 AGGAACTGGGTGTTGAGATA Tall 7042 CCAGCTAGATGTGTGTCACA Tbcld21 10862 CTAGGTAAGTGGATGGTGAG Hpca 3223 AGTCGGGCGTGGCTCGAAAG Ccngl 7043 CCGCAGGTTGGAGAGGCATA Rabl2 10863 AGGACAGCAGAAGCAGGAGC Bpifb9a 3224 CCAGACCCGGAGTTAAAGGG Gas211 7044 CAAACGTTCTGTATAGGGAT Ccdcll7 10864 TGACACTATAGTGAGCTGCA Histlh3b 3225 GCAAGGTAAATGCAAACAAC Lrplb 7045 GCCTGAGTGTTACTTGCCAG Urocl 10865 GAGTGGCTGTGTCGGTTGTG Scml2 3226 GGGACGACCCAGGAGTGAAG Nefh 7046 AAGTGCTGCCCGGTGGCTGC St3gal6 10866

CTCTGTTAGTGATCACTATT 3275 GTGACAAAGAGAATCATTGC Seipinb9b 7095 CAACTGTGCTCCTGTACCCA Dnali7b 10915 CATACACCTGAGGAGCTACT 3276 GGGCGCGCGCAGGCTTTGTC E2fl 7096 TACCCTGCTGCAGAGATACT Pcp4 10916 GAGAGAGATGGAAACTAAGA 3277 CAGTGACAATTCCGGCCAGT Tgifl 7097 TTAACCCATGCTGGATTTGC Tssk3 10917 o CGGAGCCTAGCTACCAGTGG 3278 CTCTGTTAGTGATCACTATT F adl 7098 AGAGCAAGGCGTCGCACAAA D630003M21Rik 10918 GGAGCCAGCAGCGCGCTGTC 3279 CATACACCTGAGGAGCTACT Secl412 7099 GGAGCTGTCGGCCGCATTTG Adprhl2 10919 ACTCCTACAGAACTTTCTGA 3280 GAGAGAGATGGAAACTAAGA Tsga8 7100 GCAGTGTGAGATGTGTCAGG Gm906 10920 CGGTGAAGGAGGTCTACTTT 3281 CGGAGCCTAGCTACCAGTGG Hpca 7101 GGCACCTTGAAACGCGAGGG Runx2 10921 o GCGGCATTCCTAAGGTGGGT 3282 GGAGCCAGCAGCGCGCTGTC Eif4enifl 7102 GGGCGGTAGAAAGGACGCGG Dennd4c 10922 4 CAGTCTTCTCAGGCTGTTCT 3283 CGGTGAAGGAGGTCTACTTT Coll 2a 1 7103 GGACACGGCCGCCTCGCGGA Wac 10923 ACTAGGGTCGATCGTATTGT 3284 GCGGCATTCCTAAGGTGGGT Tgif2 7104 ACGTCAGGCGGCGTCACGCG Pwwp2b 10924 AGCAGGGTATTCTGGGAGGC 3285 ACTAGGGTCGATCGTATTGT Rpia 7105 TGTCTTCCTTTGAGGAGGTG Capl 10925 GGGACTCrTAAATCGGCGCC 3286 AGCAGGGTATTCTGGGAGGC Lrrc27 7106 AAGGTGCTGACACCGTCTAT Traeml25 10926 AACTAACATTGGTCTGTCTG 3287 GGGACTCTTAAATCGGCGCC Lif 7107 TGACTTTGCGAGCGCTTCCC Hmcnl 10927 CGCGCAATGCTCACCGTCCG 3288 AACTAACATTGGTCTGTCTG Slcl3al 7108 GGCTGCTGATGTAATCGCCT Olfrl507 10928 GGTTTGAACTCGGAACTGGG 3289 CGCGCAATGCTCACCGTCCG Cbx3 7109 GATTCCCGCATGCTAGTTCC Lrp2 10929 TAGAATGTCTGGGTGGAACA 3290 GTGCTTCGTGTGCATATGTT Tnfrsf4 7110 TCAGCCAACCAGCAAAGGGA Gprl51 10930 CGGGTACCGCGAGACTCGCG 3291 TAGAATGTCTGGGTGGAACA Catsper4 71 CGGCTCTCTGTTTCGCTCCC Bodll 10931 GGCGGTCCTGGAGTCGCTCG 3292 GGCGGTCCTGGAGTCGCTCG Fbn2 7112 GTTATGCAAGCTCAGACTGC Paqr7 10932 CTGCGCGCGCGCTCTAGATC 3293 GAAGGGCAGGCCGGTGGCCG Dab2ip 7113 GAAGCCTCTGCGCAGGCGAG Nipal3 10933 GGATACTTGTAAATCTTGAG 3294 CTGCGCGCGCGCTCTAGATC Hnri¾)ab 7114 GGCCATATTGCGCAGGGAGG Zdhhc3 10934 AAACTG GAGGAAGTAAAGGG 3295 AGAGGACCCGCATATATACC Fgf20 7115 TTAAAGATCATGGGTATACA Zfyve9 10935 GCGGGACCATAGAGAGCCCG 3296 TGTTTGCGGCTGGGCCTCAT Pold2 7116 CGTGCCTGTTGAGAGCGGGA Skorl 10936 AAGCAAGATGGCCGCACCGG 3297 AAACTGGAGGAAGTAAAGGG Zkscan3 7117 CAAACTCAGAATGCAGACCC Col9a2 10937 ATTGGTCCCTGCATGCGACC 3298 GCGGGACCATAGAGAGCCCG Pofutl 7118 GGGCAGAGTGGTTAATTACC Trim29 10938 TCGAAAGTTACTAGTGGGAA 3299 AAGCAAGATGGCCGCACCGG Ncdn 71 9 AAGGAATGTGGCTCCGTGTA Pogz 10939 AGGATGTGTTACCTAGTGCG 3300 ATTGGTCCCTGCATGCGACC G3bpl 7120 GGCGCACAAAGGAAGCGCGC Phc2 10940 AGACTCrCCCGCrrGATTGG 3301 TCGAAAGTTACTAGTGGGAA Nxf2 7121 AGGAGCTGGCAATAGAAAGA Ptk7 10941 GCTTAGCTGCTGGAACTAGG 3302 AGGATGTGTTACCTAGTGCG 4921507P07Rik 7122 GTAATTTCATCCTTATCTCC Dppal 10942 GGGTGTACCGGACGAATTGC 3303 AGACTCTCCCGCTTGATTGG Ttf2 7123 CACCTCCTGGTGGAACATCT Crtam 10943 AAACCTTGCCTGAGCACTAG 3304 GCTTAGCTGCTGGAACTAGG Brwd3 7124 AATGAGCTACCTGGATGTTG Gal3stl 10944 GCGAGGCCAGCACGGCTCTG 3305 GGGTGTACCGGACGAATTGC Ccdcll7 7125 ACGAGCGCTCGCGAGAAGCA Scamp5 10945 GCGAGCCAAGCACTTAGCGC 3306 AAACCTTGCCTGAGCACTAG Zfp2 7126 CCCTCACTCCGCGAGTAGCA Abcg4 10946 ATAGACCATGGCCTGTGACG 3307 GCGAGGCCAGCACGGCTCTG Nrfl 7127 GCTTCTTCCCGGATACCCTA Dph2 10947 TGTTTGAAGACCCAGGGCAC 3308 TTTGCTGATCAAAGAGCAAC C bn 7128 ACCGGTTTAAAGAGATAGAG Amp 10948 CAAACAGCAGTAGGACGCTA 3309 AAGAACGTGACTGATAGCTG Entpd2 7129 CTGTTTGTCTAAGCACCGAC Dmapl 10949 TTCCCAGAAGGTTCTAGTCC 3310 TGTTTGAAGACCCAGGGCAC 115 7130 CCTGGAAGTCATTCATCCAG Clqtnf7 10950 CTGGGCAAGTATCTTTAGCC 3311 CAAACAGCAGTAGGACGCTA Dawl 7131 CGTGTGGTAGGAGGTTCCGA Arll3b 10951 ACTGTCAAGAGCTGTCATGA 3312 ACTGTCAAGAGCTGTCATGA Trpm5 7132 ACACACAGAACCAGTTGTTC Spink5 10952 AGGAGTATATGTTTAAGCAG 3313 AGGAGTATATGTTTAAGCAG Zkscan4 7133 TTTATTGGGCCTCCGAAGCG Kif3b 10953 n CAACTGTGCTCCTGTACCCA 3314 CAACTGTGCTCCTGTACCCA Dnah7b 7134 CTAAGGAAGGAGAGCCTCGA Snhgll 10954 TTGTTGAGAGACCATATGAA 3315 TTGTTGAGAGACCATATGAA Clip4 7135 AAGAAACTGATAATGTGCAC UqcrlO 10955 TTAACCCATGCTGGATTTGC 3316 TTAACCCATGCTGGATTTGC Tssk3 7136 GCACACAACACATTCAGTTT Echdc2 10956 ACGTTAGCAACTATCAAACC 3317 AGAGCAAGGCGTCGCACAAA D630003M21Rik 7137 GGGCAGATGGACCACAGATC Fcrls 10957 AGAGCAAGGCGTCGCACAAA 3318 GGAGCTGTCGGCCGCATTTG Adprhl2 7138 TGGCCAATCAGCCTCTGCAG Nptn 10958 GGAGCTGTCGGCCGCATTTG 3319 GCAGTGTGAGATGTGTCAGG Gm906 7139 TCAAGGCCGGCCAGGGAACG Tcf4 10959 GCAGTGTGAGATGTGTCAGG 3320 GAGCTGCGGAGGGTCAGTCT Repinl 7140 TGCTGTGAGCTCAGAACAAC Robo4 10960 GAGCTGCGGAGGGTCAGTCT 3321 TGAGTCCTAAATCCCTGAGA Atp8b5 7141 AAAGGCGCTGAGGCGCCGCC Grik4 10961 TGAGTCCTAAATCCCT GA A 3322 GGCACCTTGAAACGCGAGGG Runx2 7142 TTCTCCTCTTCTCGCGATAG Wdr77 10962 TGGATG CΑΑΓΓ CATCTGAAT Slcola6 3323 GGGCGGTAGAAAGGACGCGG Dennd4c 7143 CAGGAGAAGCTGAGGCAATC Cdsn GGGCGGTAGAAAGGACGCGG Dei Wc 3324 GGACACGGCCGCCTCGCGGA Wac 7144 AAGGGACACTGTGACTGAGC Cpeb2 GGACACGGCCGCCTCGCGGA Wac 3325 ACGTCAGGCGGCGTCACGCG Pwwp2b 7145 CTCACGTGAGCGACAGAGAT Osbp2 ACGTCAGGCGGCGTCACGCG Pwwp2b 3326 CGCACTGGCCGGCCCGGCCG Rai2 7146 GCTTGGAGACCTGCCGCGCC Adralb TGACTTTGCGAGCGCTTCCC HmcnL 3327 CTTCTGGAGTCAAGGTTGTT Nr0b2 7147 TGTATGGTTGCCTTATCTCG Tnfrsf22 GTTATGCAAGCTCAGACTGC Paqr7 3328 GAGAGGGCTCGCCACAGTTC Emcl 7148 AAAGATGAGGCCAGAAAGTT Islr GAAGCCTCTGCGCAGGCGAG NipaB 3329 GTTATGCAAGCTCAGACTGC Paqr7 7149 CTGGTCACGCAATGCTTTGT Haus6 GGCCATATTGCGCAGGGAGG Zdhlic3 3330 GAAGCCTCTGCGCAGGCGAG NipaB 7150 AGATCTGAAATTG CA CGGAT Slcl6al4 GCGAAGGGCTGCCAAGTGAG Rims2 3331 GGCCATATTGCGCAGGGAGG Zdhhc3 7151 GGATAATGAATGGAATGCCC GaBstl GGCGCACAAAGGAAGCGCGC Phc2 3332 GTGTGTGCTCTGGCTTTCTT Pldl 7152 CAGAGTCAAGAAAGGAAGTG Zkscan7 GTAATTTCATCCTTATCTCC Dppal 3333 GGCGCACAAAGGAAGCGCGC Phc2 7153 TAAGTTGAATGCCTGAGGTG Arhgdib AACTGCCTTGCAATCCAATC Tgifl 3334 GTAATTTCATCCTTATCTCC Dppal 7154 TGCAGGAAGCTTCACTGTGC 58304 1lN06Rik AATGAGCTACCTGGATGTTG GaBstl 3335 AACTGCCTTGCAATCCAATC Tgifl 7155 GGGCGGGACAACCGTCACCA TbcldlOa CCCGCCGGGAACGCGTCCTG Cbx3 3336 GAGGCCAGGACTAGGAGCAC Kcnip3 7156 CTGAACTTGATTGGTTGTGA Gucalb ACCGGTTTAAAGAGATA GAG Amph 3337 AATGAGCTACCTGGATGTTG GaBstl 7157 ACCAAGGAGTAAAGGACTTC Nefh GGTTCTCAAGAACCTGGCAT Rpp40 3338 CCCGCCGGGAACGCGTCCTG Cbx3 7158 CAGAGGTGTGTGCTGATGTA Mroh2a ACACACAGAACCAGTTGTTC Spink5 3339 ACCGGTTTAAAGAGATAGAG Amph 7159 AGCCTATTACTTCTGTTTAG Arhgdib CAGAGACGCGTGGACTCTAC Map2k6 3340 TGTAAGCCGTGCTAGCACTG Ska2 7160 CCCGCCCAGAGAGCACGCGT Myo9a TCATCATCCCGAGCCGGATC Emc7 3341 GGTTCTCAAGAACCTGGCAT Rpp40 7161 GCGGGAGAATTTCATCCCGT Urgcp TTTATTGGGCCTCCGAAGCG Kif3b 3342 GAGATAGTCCTCTCTCATGG Satll 7162 TTAACTGTCTTCAAACGGTG Cep76 ACCCATTTATATCCTGACAA Amy2b 3343 ACACACAGAACCAGTTGTTC Spink5 7163 TTCTGCCTGGGACAGTAAGC Rcan2 CTAAGGAAGGAGAGCCTCGA Snhgll 3344 TTTATTGGGCCTCCGAAGCG Kil3b 7164 GCAGAATTTGTACCGATAGC Lars2 TGAAACTTTGGTGTGGTTCT Zbpl 3345 ACCCATTTATATCCTGACAA Amy2b 7165 GGCTTCCGCCCAGAAGGTAC Etv3 AAGAAACTGATAATGTGCAC UqcrlO 3346 CTAAGGAAGGAGAGCCTCGA Snhgll 7166 TTACACCGCTAAGCTGCCCG Gucalb P GGAGTATCCCAAAGGAGGTG Plpl 3347 AAGAAACTGATAATGTGCAC UqcrlO 7167 GGACTACCAGCAAGCCTGTG Tdrd6 CTCACGTGAGCGACAGAGAT Osbp2 3348 GGAGTATCCCAAAGGAGGTG Plpl 7168 GCACTGGTGGTACTGGGAGG cn 2 GCTTGGAGACCTGCCGCGCC Adralb 3349 CTCACGTGAGCGACAGAGAT Osbp2 7169 GGGTTTGCGTTCAAGTTTCG Pik3r3 TGTATGGTTGCCTTATCTCG Tnfrsf22 3350 GCTTGGAGACCTGCCGCGCC Adralb 7170 CCCTGTCCTCTGCAGCTACT Sh3bgrl3 CTGGTCACGCAATGCTTTGT Haus6 3351 TGTATGGTTGCCTTATCTCG Tnfrsf22 7171 GCAGCCAAAGCAGATCGTGA Pabpcll GGATAATGAATGGAATGCCC GaBstl 3352 CTGGTCACGCAATGCTTTGT Haus6 7172 TGGTGATGCTGGTGGTGCGC Kcnn2 CAGAGTCAAGAAAGGAAGTG Zkscan7 3353 TTGGCCACTGGTTTGGCTTG Tgm2 7173 GTTATAAAGTGAAGACAGAC H2-M10.3 TGCAGGAAGCTTCACTGTGC 583041 lN06Rik 3354 GGATAATGAATGGAATGCCC GaBstl 7174 CACTCCCAAAGCGCTTTGTC Pdgfc GGGCGGGACAACCGTCACCA TbcldlOa 3355 CAGAGTCAAGAAAGGAAGTG Zkscan7 7175 AGGAAGAGGAGGCAGGAAGC Cnga3 GCATGAAACTCAGCCTCATT Gm609 3356 TGCAGGAAGCTTCACTGTGC 5830411N06Rik 7176 AAGCATTCTGGCTCCAATCC Secl412 ACCAAGGAGTAAAGGACTTC Nefh 3357 GGGCGGGACAACCGTCACCA TbcldlOa 7177 GGTTCTCTAACAGCTGTTGT Sytll GCGGCCAGCCTCTGGGCAGA Sirpa 3358 ACAGACAGTGCGGAACAGAG Sema4a 7178 CCAGACTCCTACCAAGCCTC Denrid4c CAGAGGTGTGTGCTGATGTA Mroh2a 3359 ACCAAGGAGTAAAGGACTTC Nefh 7179 ACACTAGTCGAGAATCTAAA Pla2g7 CCCGCCCAGAGAGCACGCGT Myo9a 3360 GCGGCCAGCCTCTGGGCAGA Sirpa 7180 CCACACTTGCTTGTATTCAG Cnga3 GCGGGAGAATTTCATCCCGT Urgcp 3361 CAGAGGTGTGTGCTGATGTA Mroh2a 7181 CGGAAGAGGACACCTGATCG Parp6 TGGCGGACATCACCTGTTCG Pclo 3362 GCGGGAGAATTTCATCCCGT Urgcp 7182 GGAGGCAGCTCCGGGCCCGG Nol41 GCAGAATTTGrACCGATAGC Lars2 3363 GCAGAATTTGTACCGATAGC Lars2 7183 TCAAGGCGCTCCAGAAACCG Tnfrsf21 ATGTTGGCACAGTAAAGAGG Meplb 3364 ATGTTGGCACAGTAAAGAGG Meplb 7184 CTTTAAACAGAATGTTACCT PlacSll CTCAGTCACGTTGTCTAGCT Fbliml 3365 GGGCTCTGGCTGAATGGGAT Chn2 7185 GGCGGCGACCGCTTTGTCTA PpplrlS TATACTACTGGAGCGGCGGG Lrrtm4 3366 CTCAGTCACGTTGTCTAGCT Fbliml 7186 TCTGGGCAAGAGCGCGGCAC Tsn TTATCTCTTATAGGTCTCCT Gml6432 3367 GAGGGTGGCAGAAGGGCTTC Zmiz2 7187 GTGAGGATCTTTGCTGCAGA Gml2169 GGAAATGAACTAGGGCTGGG Lefl 3368 AGTGTGCGGCTGTGCAGAGG Sox5 7188 TTATAGGACGTAAGTGAAAG Prelid2 GAGGGTGGCAGAAGGGCTTC Zmiz2 3369 GCACTGGTGGTACTGGGAGG Kcnn2 7189 ACGCGGGAGCGCACAGTCAG 5730507C01Rik GCACTGGTGGTACTGGGAGG K n 2 3370 TTGGTAGGAAGGAAGCCAGC Gm5111 7190 CTAGTGGGCGTGAAGGAGGC Gpbplll TTGGTAGGAAGGAAGCCAGC Gm5111 3371 CCCTGTCCTCTGCAGCTACT Sh3bgrl3 719 CGCGCACTGCGAAAGTGAGA Dhcr7 11011 CCCTGTCCTCTGCAGCTACT Sh3bgrl3 3372 GCAGCCAAAGCAGATCGTGA Pabpcll 7192 AAGTGAGGGACTTCGAGGCC Mtfrll 11012 GCAGCCAAAGCAGATCGTGA Pabpcll 3373 AACTTCCCAACTGGGTTTGT Timp4 7193 TGGTTGTAAGGGATTGGGCC Mylk2 11013 o TGCGGGCTCGGGCGCTGAGG Dacli2 3374 TGCGGGCTCGGGCGCTGAGG Dach2 7194 TCACAGTACTCAAAGTAAAG Runx2 11014 TGGTGATGCTGGTGGTGCGC Kcnn2 3375 TGGTGATGCTGGTGGTGCGC cn 2 7195 GGATCCCTGGCTGGGCGGAC Gatsl3 11015 CTGTTCTCCTTCCGTCCACT Tmem82 3376 CTGTTCTCCTTCCGTCCACT Tmem82 7196 CGGCGCAACGCTGGGACTCC Ubash3b 11016 5 GCCCTTCCCGCAGAAACTGG Mmpl6 3377 GCCCTTCCCGCAGAAACTGG Mmpl6 7197 GAGCGGGCAGGCCTTGCGCC C77080 11017 o TGGTTATTGATTGACTTGTG Spinkl 3378 ATGACTGGCTGCGAACCGGG Cck 7198 GGCGCGAAGAGGGTGCTCGT Neol 11018 4 ATTATGCAGTGTAAATGAGC Skint9 3379 TGGTTATTGATTGACTTGTG Spinkl 7199 GGAGTTGCTGGCGCATCAGT Itgb8 11019 GTCTGAAGAGGGCCAGCGCG Irsl 3380 ATTATGCAGTGTAAATGAGC Skint9 7200 CCACCCGCACTTCCGGACCT Ccm2 11020 AGGAAGAGGAGGCAGGAAGC Cnga3 3381 AGGAAGAGGAGGCAGGAAGC Cnga3 7201 TCCCGGACGCCTCCCGCTAA 5730507C01Rik 11021 CTCTCCCAGCCTATGCCACA Fam227a 3382 AACAGGGAGGGAGCTAACCT Mdfic 7202 GTGTCTACTAGCTCTGTGCA Sehll 11022 AACAGGGAGGGAGCTAACCT Mdfic 3383 AAGCATTCTGGCTCCAATCC Secl412 7203 AGGTAGGGCGCAAGACCTGG Pdzd3 11023 AAGCATTCTGGCTCCAATCC Secl412 3384 GGCCTGGTGCGCAGGCCCTT Lamal 7204 GAGGAGGGAGGTGGAGGAGG Tiaml 11024 GGCCTGGTGCGCAGGCCCTT Lamal 3385 AACCGAAGATCTCACCGGAG Rnfl45 7205 CTGCTGCTGCGAAAGAGAGC Extll 11025 AACCGAAGATCTCACCGGAG Rnfl45 3386 GGTTCTCTAACAGCTGTTGT Sytll 7206 TAGGGAGAGACACCCGCCAA Rhd 11026 GGTTCTCTAACAGCTGTTGT Sytll 3387 CCAGACTCCTACCAAGCCTC Dennd4c 7207 GGATGAGAACGCCGGCCTCT Nfyb 11027 CCAGACTCCTACCAAGCCTC D n 3388 AGCATACTCTGAACAGATAA 9530002B09Rik 7208 TGACCAGGGTGATTCAGTTT Limk2 11028 CCAGGATGAAGACGCTACTC Ggt7 3389 GGTATAAGTCACAGGAGGCC Foxil 7209 AACGGTACACACGTTCCTTA Rapgef2 11029 GCGCTGAGCGGCAGGCGAAG Pgapl 3390 AGTCCTGCCCAATCACAAGA Lpin2 7210 GTGACTCTGGAGTACTGTAT Histlh4b 11030 AGTCCTGCCCAATCACAAGA Lpin2 3391 CCACACTTGCTTGTATTCAG Cnga3 7211 GGGAACAGTTAGACATGAAA D7Ertd443e 11031 CAGAGTrrGCAAAGTCGCCG DocklO 3392 CCGTGGAACTCGAGCGATCC Cfap61 7212 GGCGGAGGAAGAAAGGTGGC Tuscl 11032 CCACACTTGCTTGTATTCAG Cnga3 3393 GGAGGCAGCTCCGGGCCCGG Nol41 7213 GGAAGAGATCGCTCACTCGG Cntnap5a 11033 CCGTGGAACTCGAGCGATCC Cfap61 3394 TCTGGGCAAGAGCGCGGCAC Ts 7214 CACGCACTTAACGTTACTGT Bnip2 11034 GGAGGCAGCTCCGGGCCCGG Nol41 3395 GTGAGGATCTTTGCTGCAGA Gml2169 7215 TGCGTTGGTTTGGCGGGTTG Clspn 11035 TCTGGGCAAGAGCGCGGCAC Tsn 3396 AGCTTGTTTGGGCTCCGTAC Zfp951 7216 CTGTGGTACCTGCCCTGCAG Gml2886 11036 GTGAGGATCrrTGCTGCAGA Gml2169 3397 ACGCGGGAGCGCACAGTCAG 5730507C01Rik 7217 CGCGTTAAGGTGTGTCAAGA Eri3 11037 ACGCGGGAGCGCACAGTCAG 5730507C01Rik 3398 CGCGCACTGCGAAAGTGAGA Dhcr7 7218 ACAGGGAAAGAGGCCAAATT Islr 11038 ATACAGTAACTGCTCAAGAA Ide 3399 GTCGGTGAGGAGGTGCAAGG Tmeff2 7219 AATCAGTCATCTAAACTTCT Husl 11039 CGCGCACTGCGAAAGTGAGA D r7 3400 GTGGACCTTGCTGAACTTAT Tiim45 7220 ATCTCATGCGCACAGCTCAA AU022252 11040 GTCGGTGAGGAGGTGCAAGG Tmeff2 3401 AAGTGAGGGACTTCGAGGCC Mtfrll 7221 CTTGGCTGCAGTTGTGCGGC Sgcd 11041 TAGACTAGAGGCCACAGCTG Adckl 3402 TGGTTGTAAGGGATTGGGCC Mylk2 7222 TAGGTGGGACACACCTCTCA Sh3rf2 11042 AAGTGAGGGACTTCGAGGCC Mtfrll 3403 GAGAGGCGTTAGATACCGTT Psap 7223 TGGGCCACACCTTCTTCTCT Gm4858 11043 TGGTTGTAAGGGATTGGGCC Mylk2 3404 TCACAGTACTCAAAGTAAAG Runx2 7224 TAGTCTAGTTAATCTACGCC Rps6 11044 GGATCCCTGGCTGGGCGGAC Gatsl3 3405 GGATCCCTGGCTGGGCGGAC Gatsl3 7225 CGAGACCAGTTGGCGGGAAT Etl4 11045 GACA GAGTTAA GAAATCAAA Etnppl 3406 GAGCGGGCAGGCCTTGCGCC C77080 7226 AAGGTTCCGCCCTACCCGTC Fam219b 11046 GAGCGGGCAGGCCTTGCGCC C77080 3407 CGTTCCCTGTAGAGTTCTAG Slco6dl 7227 CCGCTCTGCTGTGCGATTTA Cdl6412 11047 CGTTCCCTGTAGAGTTCTAG Slco6dl 3408 GGAATGCAATGTTAATTCTG NeklO 7228 TCCCGCAGGAACAGGAGCTT Irf4 11048 AAAGGTCAGATCTGTACTCC Gm597 3409 TCTGTGTGGCTGACGTGGCA Secl6b 7229 CCAGCCAGTGAGACA GTGAC Lcelg 11049 n GGAATGCAATGTTAATTCTG NeklO 3410 CAGAACCTGGATTGACGTTT Cmpkl 7230 CCCACCCACCAGAATCCTCG Nsun4 11050 CCCTCTTCTTGGCCAGTATC Chrm5 3411 CCACCCGCACTTCCGGACCT Ccm2 7231 CAACTTACATTTG CAGCCGG 1110059G10Rik 11051 TCTGTGTGGCTGACGTGGCA Sec 16b 3412 CATGTCACTCAGAGAGAAGC Grm5 7232 GACGCGGTTGCTAAGGAAGT Kif3b 11052 n CAGAACCTGGATTGACGTTT Cmpkl 3413 TCCCGGACGCCTCCCGCTAA 5730507C01Rik 7233 GAACTGAGTGCGCCAGAGAG Nacad 11053 o CCACCCGCACrrCCGGACCT Ccm2 3414 GGGCGGAAATAGCTTCGTGC Ccdcl37 7234 GAGGGTCTGTGTAGTTCTAA Dnalil7 11054 5 CATGTCACTCAGAGAGAAGC Gim5 3415 TTTGTGACAAGGTGTGGTTA Slc5a9 7235 TCTGGGTAACCTCACGTGAC Zraym6 11055 b TCCCGGACGCCTCCCGCTAA 5730507C01Rik 3416 CCAAGTTTGTGAAGTCATGA Cfap97 7236 TAAATGTTGCTCTCCAGCTT AbcaSb 11056 TTTGTGACAAGGTGTGGTTA Slc5a9 3417 GAGGAGGGAGGTGGAGGAGG Tiaml 7237 TACATAACTGAGATTAAGTG Secl413 11057 J CCAAGTTTGTGAAGTCATGA Cfap97 3418 CTGCTGCTGCGAAAGAGAGC Extll 7238 ACCCTGTAATTTCAACAGCC Selenbpl 11058 TACGCTGGCAGGCTGTGGGC Atpl3a4 3419 TAGGGAGAGACACCCGCCAA Rhd 7239 GACTCTGCTTGCAGGGAAAG Tmod4 11059 CTGCTGCTGCGAAAGAGAGC Extll 3420 TGACCAGGGTGATTCAG TTT Limk2 7240 GGGCTTGATCAGCCACACTG BC049762 11060 TAGGGAGAGACACCCGCCAA Rhd 3421 GTGACTCTGGAGTACTGTAT Histlh4b 7241 CGCGCGGAGCCCGCGTGGAG Cdkl3 11061 TGACTTTACAAGAATGCCTG Satbl 3422 TCACCTGCTGTCCTCTGCGA Tmeml76b 7242 GGATTGGATTGGCTAATCCG Cenpq 11062 TGA CCA GGGTGATTC AGTTT Limk2 3423 GGGAACAGTTAGACATGAAA D7Ertd443e 7243 TTCTACTCACCATCTAATCC Wdrl7 11063 GTGACTCTGGAGTACTGTAT HistlMb 3424 GGCGGAGGAAGAAAGGTGGC Tuscl 7244 GGAGTCTGCCAGCGATCTCT Psmg4 11064 TCACCTGCTGTCCTCTGCGA Tmeml76b 3425 GCCAATTGTAGTTAGGCTAA Folhl 7245 GCGAGTTAGAGTTAGGCGCG Ritl 11065 GGTCAACGTGAGGAATTTAG Col4a4 3426 CCGCGGCGCGCTGAGGACGG Lrp6 7246 CTGCGCAGCCGAGAGGCGGG Zfp362 11066 GGGAACAGTTA GA CAT GAAA D7Ertd443e 3427 AAGTGCAGTCCGGGTGCTTG Ggh 7247 CGCCCGCGGATTGCGAGCAG Stk32c 11067 GGCGGAGGAAGAAAGGTGGC Tuscl 3428 GCGCGGCCGCTTCTTGAGCC Mierl 7248 GGAAAGGAAGAGGAGCCTAG Cfap57 11068 GGAAGAGATCGCTCACTCGG Cntnap5a 3429 TGCGTTGGTTTGGCGGGTTG Clspn 7249 TCAGGCAACGCAAGCGCAAG Glt8d2 11069 ACTAAATGCCTGACAAATAC C tn l 3430 CACTATGTCAGAAACAAGGA Cpal 7250 AATGGCGTCTCCGGAGCCCG Setbpl 11070 TTTGTATTCTGGCATCCTGG Tbx22 3431 AACACACGAGAGTGGAGAGA Zfp786 7251 TTT GCGGATAAGGAACCAAA Bdnf 11071 AAGTGCAGTCCGGGTGCTTG Ggli 3432 AATCAGTCATCTAAACTTCT Husl 7252 CCTGAGCACCAGGGTAGGGT Hpgd 11072 GCGCGGCCGCTTCTTGAGCC Mierl 3433 GAACTTCCTCCTCAGCCGAG Manla2 7253 ACCAGCACCCAGGAACGGCC Bpntl 11073 GCCGCAGCCGCCGCTTGTTT Irsl 3434 CTTGGCTGCAGTTGTGCGGC Sgcd 7254 CGCAAGCATTGTGAGAACCG Zfp341 11074 GTTGCTAACGCGGTGTCTGG Rockl 3435 TAGTCTAGTTAATCTACGCC Rps6 7255 TGAATGAGTCTTTCGCCAAT Parvg 11075 TGCGTTGGTTTGGCGGGTTG Clspn 3436 CCGCTCTGCTGTGCGATTTA Cdl6412 7256 AGAGGACATTGTGCCTTAGG C77080 11076 GTCAACAGCATTTACTGTGT Cntnl 3437 GACAGTAGCTGCGTAGGAGA Spinkl4 7257 CTTA GACTA A GCCTTT CCGG E2 2 11077 CACTAACAACTACTCTGCGG Tnc 3438 GGAGACTCGCAGCCTGGGAG Wdr78 7258 A GAAT GA GATGTC AATTCAG Propl 11078 AACACACGAGAGTGGAGAGA Zfp786 3439 GAAAGGCTGGAAAGGTGTGG Kazn 7259 TTGTCAGCAGCATTAAGCAG Oxct2b 11079 AATCAGrCArCrAAACTTCT H l 3440 CAACTTACATTTGCAGCCGG 11 10059G10Rik 7260 CGAGTCTAGTTCTATTAAGT Thoc5 11080 GAACTTCCTCCTCAGCCGAG Manla2 3441 GACGCGGTTGCTAAGGAAGT Kif3b 7261 CCACCTACGGGCGGAGAGAA Echdc2 11081 CTTGGCTGCAGrTGTGCGGC Sgcd 3442 GAACTGAGTGCGCCAGAGAG Nacad 7262 CCAGACGGCAGTGGGATAGC Snapin 11082 AGAAGAGTCAGTGTCGACTT Fbxwl9 3443 TCTGGGTAACCTCACGTGAC Zmym6 7263 CCGAAGCCGCGCAGTTTAGA Cepl92 11083 TAGTCTAGTTAATCTACGCC Rps6 3444 GTGACAGCGCGGAGCGGGAG Cntn5 7264 CTTTAATCTTGTCGTCGCAC Ccdcl57 11084 CCGCTCTGCTGTGCGATTTA Cdl6412 3445 AAAGAAAGGTTCCAGTAGAG Mall 7265 TGTCTCACAACTCAGATTAA Gml0696 11085 GACAGTAGCTGCGTAGGAGA Spinkl4 3446 TACATAACTGAGATTAAGTG Sec 1413 7266 AGAGGGAGAAGCTCGTCACC Fndc9 11086 GTATGCATTTGTCCCAGCCC Rims2 3447 GGGCTTCAGAGTCCACCTTG Pax4 7267 CGAGGACAGTCCACTAGAGG Rplll 11087 GAAAGGCTGGAAAGGTGTGG Kazn 3448 CTTTGACCGCCTCACCAGTC Crnkll 7268 GGACCACCACTTAGTTATGA Slc36a3 11088 TCCCGCAGGAACAGGAGCTT Irf4 3449 GGGCTTGATCAGCCACACTG BC049762 7269 TGCCCAGATCGGCAGAGTAG Phactr4 11089 CAACTTACATTTGCAGCCGG 1110059G10Rik 3450 CACACTCCTCGGAGGAGGGA Lrrtml 7270 GCCCGTCTGTGGAGCGCGTA Sox30 11090 GACGCGGTTGCTAAGGAAGT Kif3b 3451 CGCGCGGAGCCCGCGTGGAG Cdkl3 7271 CCCTTGTGGTGAGATCACAG Catsper4 11091 GAGAAGGCAGTCACATCTGC Slitrk5 3452 TTCTACTCACCATCTAATCC Wdrl7 7272 CTTGGCGATTGGACGAGAGT Rsrpl 11092 GAACTGAGTGCGCCAGAGAG Nacad 3453 GGAGTCTGCCAGCGATCTCT Psmg4 7273 GTCAGTTGGATCAGGGTGGA D7Ertd443e 11093 TCTGGGTAACCTCACGTGAC Zmym6 3454 CTGCGCAGCCGAGAGGCGGG Zf 62 7274 GCTGCGTGCGCACGTCATCA 1110008F13Rik 11094 GTGACAGCGCGGAGCGGGAG Cntn5 3455 CGCCCGCGGATTGCGAGCAG Stk32c 7275 CGGAGCAGGGATCTCGTGCT Map2k5 11095 AAAGAAAGGTTCCAGTAGAG Mall 3456 TGGGCAGAACGAGACACTTA Ephx3 7276 TTTCGGGACGGCGGCTCTCC Tmem266 11096 TACATAACTGAGATTAAGTG Sec 1413 3457 TTGAAATATTCTGTAGGGTT Tgifl 7277 GCTGGGCTATGACGGCAGAG Nadsynl 11097 GGGCTTCAGAGTCCACCTTG Pax4 3458 CCTGAGCACCAGGGTAGGGT Hpgd 7278 GCGCAAACACCCTCCGACCG Scn3b 11098 CTTTGACCGCCTCACCAGTC Crnkll 3459 AAACATTTGCAGTGGCATGT Nfia 7279 GTGGTTCTGAGATTTCCTAC Arhgdib 11099 GGGCTTGATCAGCCACACTG BC049762 3460 CATCTACTCTCTGGGTGCAC 115 ra 7280 CATGGACTACATTCAGCCTT Gml0354 11100 CACACTCCTCGGAGGAGGGA Lrrtml 3461 CAACTAATATTGGTTCCTTT Rin2 7281 TATTAGAAGAATTCCGTTCC Bdnf 11101 CGCGCGGAGCCCGCGTGGAG Cdkl3 3462 CGCAAGCATTGTGAGAACCG Zfp341 7282 ACACGCCTACTTCTCCCACA Rhbdd3 11102 TTCTACTCACCATCTAATCC Wdrl7 3463 TTCACCTTGCCACTGGGTCT Nfia 7283 CGCATTAA A GAGACA AGCTA Tfap2e 11103 GGAGTCTGCCAGCGATCTCT Psmg4 3464 ACAGGGCGAGGGAGCGACCC Tmem47 7284 GCCTGACGTGAGAAGCGCGA Zcchcll 11104 CCCATCTCCGGCGCAGCGGG Gjd2 3465 AGAGGACATTGTGCCTTAGG C77080 7285 GGCTTC AA GACAGAA GTA GG Nr2f2 11105 CTGCGCAGCCGAGAGGCGGG Zfp362 3466 CAGAACTCTAAGCTTCCCAT Mroh2b 7286 CTTCCTCGCTCAGTCCGACG Gramdlb 11106 CGCCCGCGGATTGCGAGCAG Stk32c 3467 GGCGGCCCGCTCTCAGGTCA Smchdl 7287 TGCTCGCCTACTCTTCCGCT Fycol 11107 TTGAAATATTCTGTAGGGTT Tgifl 3468 CTTAGACTAAGCCTTTCCGG E2f2 7288 AGACTGCTGGCTGCAGACGC Lrig3 11108 CGTAACCTACAGTCATTTAG Vav3 3469 CAGTGCTGACGCAGTCCAGC Cck 7289 CGCCCAACTCTCGCGATACC Ubr3 11109 o AATGGCGTCTCCGGAGCCCG Setbpl 3470 AGAATGAGATGTCAATTCAG Propl 7290 TTGCCTAGAGTTGCTAAGTT Slc30a2 11110 GTCGGCATCTCAGGCAGCCC Slfl 3471 CGAGTCTAGTTCTATTAAGT Thoc5 7291 AACTTCAC CCGAAGAATCCT Dis31 11111 CCTGAGCACCAGGGTAGGGT Hpgd 3472 CTGCGCTAGATCCAGCGCCC Fbn2 7292 CCTAAGGAGTTGTGAGTGGA Bbs4 11112 AAACATTTGCAGTGGCATGT Nfia 3473 GCTACAATGTTGA GCCCTTT G6pd2 7293 GATGTGTCCTGGGAGGGCCC Scgblb3 111 13 o CATCTACTCTCTGGGTGCAC I15ra 3474 CTTTAATCTTGTCGTCGCAC Ccdcl57 7294 TCTCCCTGAGTCCTAACGTG Rps6kal 111 14 4 CAACTAArArTGGTTCCTTT Rin2 3475 CACATCCAATCGATGAGTGC Dync2hl 7295 AGCGGCGCCCGCGTGACAAT Hexa 11115 CGCAAGCATTGTGAGAACCG Zfp341 3476 ATATAGTAACCTTTGACTGT Sult2a5 7296 TGCGCATGTGCAAGAGGAGC Tmem63a 111 16 GGGACAGGAGCCAGTCAGAC Etnppl 3477 AGAGGGAGAAGCTCGTCACC Fndc9 7297 GCCGATATGCAGGCGGCGCG Fndc5 11117 TTCACCTTGCCACTGGGTCT Nfia 3478 CGAGGACAGTCCACTAGAGG Rplll 7298 GAGCTAATGCTGGGCTCCAT Golim4 11118 AGAGGACATTGTGCCTTAGG C77080 3479 GGACCACCACTTAGTTATGA Slc36a3 7299 TGGCCGCGGCCCAFGrGACC Aff4 11119 GGCGGCCCGCTCTCAGGTCA Smchdl 3480 AAGAGGTGTGTCAGCAACCC Meplb 7300 GCTGCCGTAGGTAGTGCrCr Urgcp 11120 GAGCTATAAAGCTGCGCTCC Actcl 3481 TGCCCAGATCGGCAGAGTAG Phactr4 7301 GGATCCGCAGGCAAGACTTA Shrooml 11121 CTTAGACTAAGCCTTTCCGG E2f2 3482 CCCTTGTGGTGAGATCACAG Catsper4 7302 GAAGACTGGCCGTCACGGGA Mtmr3 11122 AGAATGAGATGTCAATTCAG Propl 3483 CTTGGCGATTGGACGAGAGT Rsrpl 7303 AACGGCAGGGAACTAGGTCG Slcl2a5 11123 TGGCAGATCTGCTCCCTAAA Tbx22 3484 GAGGAGGAGCCACAGGGAAG Fbliml 7304 GGGAAGGCAGCGGAAAGTAG Marchl 11124 GGAGGGAGGGAAATGAATAA Ide 3485 GTCAGTTGGATCAGGGTGGA D7Ertd443e 7305 CTCCGACTACAAGTCCCAAA Dynclhl 11125 CGAGTCTAGTTCTATTAAGT l oc5 3486 GCTGCGTGCGCACGTCATCA 1110008F13Rik 7306 ATGAATAATGTGAGCGTTGG Fndc9 11126 CTGCGCTAGArCCAGCGCCC Fbn2 3487 AGTTGTGAGTCAGTGGAGTA CstlO 7307 TTGCCTCGGCCCGACCCACG Arhgap26 11127 CTTTAATCTTGTCGTCGCAC Ccdcl57 3488 GCTGGGCTATGACGGCAGAG Nadsynl 7308 AGGCGGCCGACCTGTGGACT Eif4enifl 11128 ATATAGTAACCTTTGACTGT Sult2a5 3489 CGACAGCGATCTGACAGCGA Wdr3 7309 AGGTGTGGTGCTTTGCCAAA Ttc22 11129 AGAGGGAGAAGCTCGTCACC Fndc9 3490 CAGGGCGAAGTCCACGTCGC Mfhasl 7310 CTTGAGTGGGTTGGGAGTGG Obscn 11130 CGAGGACAGTCCACTAGAGG Rplll 3491 CATGGACTACATTCAGCCTT Gml0354 7311 TTTCCGGCCGTGAGGTAAGG 2810403A07Rik 11131 GGACCACCACTTAGTTATGA Slc36a3 3492 ACACGCCTACTTCTCCCACA Rhbdd3 7312 ACTCGAGCAACGGGCACAAG Gskip 11132 AGATTCTGAACGCTGTGTAA Efcab3 3493 TTTGGATTAACAAGTAGATG Steap2 7313 CCCAGCAAAGAAGAGCATGC Scgb3a2 11133 AAGAGGTGTGTCAGCAACCC Meplb 3494 CGCATTAAAGAGACAAGCTA Tfap2e 7314 CCCTTGATGGGACCCTTGAA Sqstml 11134 TGCCCAGATCGGCAGAGTAG P act 3495 CCGCCTGCGTGGCAGTGCCT Ykt6 7315 TCTCTGGGTTAGAGTGGTGC Ythdc2 11135 CCCTTGTGGTGAGATCACAG Catsper4 3496 TACACGACTGGGTGCAGCCG Slc39al0 7316 GGACATTGCCTTCCCTTCCC A 5 1 84 11136 CTTGGCGA GGACGAGAGT Rsipl 3497 GCGTGTGCGAGATGAGGTGT Primpol 7317 TCCGCTGGGTCCAGGAGCAG Adgra3 11137 GAGGAGGAGCCACAGGGAAG Fbliml 3498 TGCCCAATGGGTGTGCGGTG Ryrl 7318 GTGTCATCTCCTAACCACCC 5730409E04Rik 11138 ACAAAGGTAGAGTACTCTTC Bpifb9b 3499 GGTCAGCTGCCTAGAGCGAT Igfl 7319 GCACACCTCCTTGCGCCGCG P4ha2 11139 GTCAGTTGGATCAGGGTGGA D7Ertd443e 3500 CGAGGTCCGAGTTTGCCTTC Trmt6 7320 TGGCGCGGCGGAGCAGGGAG Bdnf 11140 GCTGCGTGCGCACGTCATCA 1110008F13Rik 3501 TTGCCTAGAGTTGCTAAGTT Slc30a2 7321 GGCAGCGGCCGCGTCCACGT Fndc5 11141 AGTTGTGAGTCAGTGGAGTA CstlO 3502 CGCTCTTTGAAAGAGGCTAG Lmo2 7322 CTACCAGCCCGCCTACTGGG Cdc42se2 11142 GCTGGGCrAFGACGGCAGAG Nadsytil 3503 GGGCCGGAAGAGCCACGCCA Spata6 7323 AGTAAACTAGCrGrrrGCAG Cyp39al 11143 CGACAGCGATCTGACAGCGA Wdr3 3504 TCTCCCTGAGTCCTAACGTG Rps6kal 7324 GAGACCGGAGGGAAACGAAC Dec 11144 AAATTAAGGTGTGACGAAAC Atpl3a4 3505 TGCGCCGAGTAGGAAGTGAC cn 5 7325 ATCAAGAATGAGGGTGGACT 2300002M23Rik 11145 n CAGGGCGAAGTCCACGTCGC Mfliasl 3506 GTCGCGAGGGAACGGCTGCC Kat6a 7326 GTCCATTTCCCTCCCTTCAA Pdrgl 11146 AGGTCTCAGGCTCACGTGGG Nsmaf 3507 GCCGATATGCAGGCGGCGCG Fndc5 7327 GAGTGCTGGACCrGGTTCGG Sc5d 11147 CAAGAATTACCCAGTTCCAG Nlgnl 3508 GGCCAATGAAGTCA GCATTC Ube2u 7328 TATGCCTCCCGTCTGTACTA Hpca 11148 n ACACGCCrACrrCTCCCACA Rhbdd3 3509 TGGCCGCGGCCCATGTGACC Aff4 7329 CGAGGTTCTGTCCGCTTGTC Clk4 11149 o CGCATTAAAGAGACAAGCTA Tfap2e 3510 GCTGCCGTAGGTAGTGCTCT Urgcp 7330 TCTCGCCATGTCTCTCCTCT Jam2 11150 TACACGACTGGGTGCAGCCG Slc39al0 3511 GGATCCGCAGGCAAGACTTA Shrooml 7331 ACTCCCAGAGAGCTCCCTTC Bpifb3 11151 b GCGTGTGCGAGATGAGGTGT Primpol 3512 GAAGACTGGCCGTCACGGGA Mtmr3 7332 GGCGGGCAGAAGCCTGTGAT Cepl92 11152 CGAGGTCCGAGTTTGCCTTC Trmt6 3513 ATTC CAGAAATTT CTACCAG Krt20 7333 ACAAAGACTGGTCTGTAGCC Otog 11153 J CGCCCAACrCTCGCGATACC Ubr3 3514 ATGAATAATGTGAGCGTTGG Fndc9 7334 GCTGGACACGGGAGGACTAC Tiel 11154 TTGCCTAGAGTTGCTAAGTT Slc30a2 3515 AGTCAGGAGTGGCCAACTTG Tfap2a 7335 GTAAGGTTATTAAATGGCTT Wdrl7 11155 GGGCCGGAAGAGCCACGCCA Spata6 3516 AGGCGGCCGACCTGTGGACT Eif4enifl 7336 GCTTATCGGAGGACGGAGGG Phlda2 11156 TCTCCCTGAGTCCTAACGTG Rps6kal 3517 GGAGCGCAGCCCTGGTCACG Stk31 7337 ATGTCTAGCATCTCTTCTCT 01fr921 11157 o GTCGCGAGGGAACGGCTGCC Kat6a 3518 GGGTTTCTGACAGTCGCAGA Rapgefll 7338 TCCGATTTAAACGTGATAGT Sycel 11158 GCCGATATGCAGGCGGCGCG Fndc5 3519 GAAGTCAGGTGTACAGTGCC Itgb6 7339 GGGCGGGCAGCCTCCAGACC Dst 11159 GAGCTAATGCTGGGCTCCAT Go li 3520 CCCA GCAAAGAA GAG CAT G Scgb3a2 7340 GCGGGACATCCTGAAATAAT Nipal3 11160 TGCACTCAGGGAGGCAAGGG 1112b 3521 CCCTTGATGGGACCCTTGAA Sqstml 7341 GTAGAACTGGTGCAAGTTGG H2-M10.3 11161 o GGCCAATGAAGTCAGCATTC Ube2u 3522 TCTCTGGGTTAGAGTGGTGC Ythdc2 7342 CCGGACAGAGGTAGATGAAC Timd2 11162 4 CCGCTGCTGTTACTAGCTCC Grik2 3523 GGACATTGCCTTCCCTTCCC AW551984 7343 CTCAAACAAGTCTTTCCACT Adgrf5 11163 TGGCCGCGGCCCATGTGACC Aff4 3524 TCCGCTGGGTCCAGGAGCAG Adgra3 7344 GAGGGAGCTTCTGAAGGTGG Corola 11164 GCTGCCGTAGGTAGTGCTCT Urgcp 3525 GTGTCATCTCCTAACCACCC 5730409E04Rik 7345 CGAGGCAATGGGCACCCGTC Cabp7 11165 GGATCCGCAGGCAAGACTTA Shiooml 3526 GCACACCTCCTTGCGCCGCG P4ha2 7346 TTGTGGTAGCCTAGACTCAC Hpcal4 11166 GAA GACTGGCC GTCA CGGGA Mtmr3 3527 CAGCGCCTCTGTGTGAG CTC Tmeml76b 7347 ACACTGTGTCACAATCCATG Bdnf 11167 TCCTTCCTAAGGGAGCTCAG Myo3b 3528 AGTCCCGGGCAGGACTGCAT Zmat4 7348 TCTCAGAGATCCGTAAGCAA Hexa 11168 ATGAATAATGTGAGCGTTGG Fndc9 3529 GGCAGCGGCCGCGTCCACGT Fndc5 7349 CGTGGTGTGTGTGGGTCTTC Purb 11169 AGTCAGGAGTGGCCAACTTG Tfap2a 3530 CTACCAGCCCGCCTACTGGG Cdc42se2 7350 TGTCTTCTAGTCTCAAGATC Gm4858 11170 AGGCGGCCGACCTGTGGACT Eif4enifl 3531 GAGACCGGAGGGAAACGAAC Dec 73 GGGCCGCGCAAGTCAGAGGG Atl2 11171 GGAGCGCAGCCCTGGTCACG Stk31 3532 ACGAAACTCCTGACAGTTAT Grm5 7352 TACGCGGAGAAACTAATATT Ppplrl8 11172 CTTGAGTGGGTrGGGAGTGG Obscn 3533 TTCAGATGAAGCAAATTCTG Mugl 7353 ACTCTGTCCGCCCAGGATCG Adcyl 11173 ATGCAGCTTTGCGCATCCTT Dds60 3534 GTGGCTAATGGGTGTGGCAG Efhcl 7354 GGGCCCGCCTACGAGGACGG Celf6 11174 CCCA GCAAAGAA GAGCATGC Scgb3a2 3535 AGTCAGAGAATTGTATATCC Skintl 7355 GTGAGGAGGATTCATTCTCT Bdnf 11175 TCTCTGGGTTAGAGTGGTGC Ythdc2 3536 TGTTCTAGAGTGTAGGCCTG Ttc39a 7356 AAAGCCTCTCACAGGAGTTT Pttgl 11176 GGACATTGCCrrCCCTTCCC AW551984 3537 GTCCATTTCCCTCCCTTCAA Pdrgl 7357 GCTGATATGGAAGATGATTA Tgm4 11177 TCCGCTGGGTCCAGGAGCAG Adgra3 3538 TATGCCTCCCGTCTGTACTA Hpca 7358 TTGGATTTCTTGTAGTGCCA Olfr920 11178 GTGTCATCTCCTAACCACCC 5730409E04Rik 3539 CGAGGTTCTGTCCGCTTGTC Clk4 7359 AACCAAATCTTTGCGGGTGC Pabpc4 11179 GCACACCrCCTTGCGCCGCG P4ha2 3540 TCTCGCCATGTCTCTCCTCT Jam2 7360 TTTGGGCGCACCCGCGGCAG Clic5 11180 CAGCGCCrCTGrGrGAGCTC Tmeml76b 3541 ACTCCCAGAGAGCTCCCTTC Bpifb3 7361 AGAGGAGCCAAAGAGACAAT Nsmce4a 11181 AGTCCCGGGCAGGACTGCAT Zrnat4 3542 CTGTGACTCACTCAGCTTTG Col6al 7362 GGTGAGAGCGCCTTGAGGTG 2300009A05Rik 11182 TAGCCCAGCCTGACCCTGCT Col24al 3543 CTCCTGGCTGACTTCACATG Cstll 7363 GTTGTTCGTTTGAACCTCGG H2aiV 11183 GGCAGCGGCCGCGTCCACGT Fndc5 3544 ACAAAGACTGGTCTGTAGCC Otog 7364 CGCATGCCGGCACGTGGTGC Traem222 11184 CTACCAGCCCGCCTACTGGG Cdc42se2 3545 GTAAGGTTATTAAATGGCTT Wdrl7 7365 CTGGGTGGGCCCTTAGAGGA Seipinb9b 11185 GAGACCGGAGGGAAACGAAC Dec 3546 TCCGATTTAAACGTGATAGT Sycel 7366 TAAACAACTGTGTCTTCACC Adaml9 11186 ACGAAACTCCTGACAGTTAT Grm5 3547 GCGGGACATCCTGAAATAAT Nipal3 7367 GTCTCCAACATTTCCTCCTG Tgm4 11187 TTCAGATGAAGCAAATTCTG Mugl 3548 CCGGACAGAGGTAGATGAAC Timd2 7368 GAAAGCCAATAGATACTGGG Sin3a 11188 AGTCAGAGAATTGTATATCC Skintl 3549 CGTCGCGGTGTAAGCTTGTC Ube2h 7369 TGGGAGCCTCCGGAGCGCCC Enpp4 11189 TGTTCTAGAGTGTAGGCCTG Ttc39a 3550 AGACTGCGGGTCCTGCCCTT Tipm6 7370 A GGA CTTC CCATG GGCGTGA Adgif5 11190 GTCCATTTCCCTCCCTTCAA Pdrgl 3551 AATCATGGAGTGGGCATGAT Hmgcl 7371 AGCCTGAGAGCTTAGGCCTT Gmebl 11191 TATGCCTCCCGTCTGTACTA Hpca 3552 CGAGGCAATGGGCACCCGTC Cabp7 7372 ACGGGCGGGACCGGCCGGAG Reml 11192 CGAGGTrCrGrCCGCTTGTC Cl 4 3553 GCACCCACTGGACTTCTGTG Tes 7373 GCGGAGCAGGTGGTCACGGG Mbd2 11193 n TCTCGCCATGTCTCTCCTCT Jam2 3554 CGTGGTGTGTGTGGGTCTTC Purb 7374 GGACGATTACCCGCGGGAGG Sync 11194 ACTCCCAGAGAGCTCCCTTC Bpifb3 3555 ACTCTGTCCGCCCAGGATCG Adcyl 7375 GAAGACAGAGCGCACTAAGC Sfil 11195 CTCCTGGCTGACTTCACATG Cstll 3556 GGCTTCTGCTCCAAATAGTG Kcnli5 7376 TGATACTGTCAGCTAGTCCT Mrps24 11196 n GTAAGGTTArrAAATGGCTT Wdrl7 3557 AGGACTTCTGGGTTGGACCG Cds2 7377 GAACGACCGGCGCACGGGCC Mpdz 11197 o GCTTATCGGAGGACGGAGGG Phlda2 3558 AAAGCCTCTCACAGGAGTTT Pttgl 7378 GACAAAGTTTCAGGAGACTT Sun5 11198 TCCGATTTAAACGTGATAGT Sycel 3559 GAACTGTTGCTGAAGCGGAA Secl6b 7379 AAACAGGAAAGCTATTGGTT Mytl 11199 b GCGGGACATCCTGAAATAAT Nipal3 3560 GCCAGGACTCCACATCACAA Spata31 7380 TACCTATAATTGTATCCAAC Tdpoz3 11200 CCGGACAGAGGTAGATGAAC Timd2 3561 GCTGATATGGAAGATGATTA Tgm4 7381 AAGACATACGCTCCGCAGGC Cenpq 11201 J AATCATGGAGTGGGCATGAT Hmgcl 3562 TGGCA GTGCTTTG AA CCAAT Dnm2 7382 AAGACGCTGCAAGGAAGCAT Pdzd3 11202 CGAGGCAATGGGCACCCGTC Cabp7 3563 TGCCAGCGCATTCGCTCCTC Itgb6 7383 GGTCACAGGCCACGGGTCCC Phc2 11203 GCACCCACTGGACTTCTGTG Tes 3564 GTGCTGGTTCTTGGTCCCGT Ctnbp2 7384 GTGACGCACTTCCTATTGCG Cebpz 11204 CGTGGTGTGTGrGGGTCTTC Purb 3565 GTTGTTCGTTTGAACCTCGG 2a v 7385 TATGAGACAAGCCCATACTC Stmn3 11205 o AAAGAGGTGGGCCCACCACG Foxsl 3566 CGCATGCCGGCACGTGGTGC Tmem222 7386 GCTGGATCCATAAGGGAGTC Bpifb5 11206 CATAGAAGGTCCTTCAGAGC 1700007B14Rik 3567 CTGGGTGGGCCCTTAGAGGA Serpinb9b 7387 AATTGGACTTCAGTGTTTCG Adralb 11207 ACTCTGTCCGCCCAGGATCG Adcyl 3568 GTCTCCAACATTTCCTCCTG Tgm4 7388 GAAGGAGCGCGCGAAAGGGT Slc32al 11208 GGGAGCTGAGTGTGCCACGG Axin2 3569 AAACTTGGACCGCGCTTTAG Nrg4 7389 AGTGCGAGCTGCGTGCTGAC Stpg2 11209 o 4 TGACGCGGATTGGCTAGGCT Cacnalb 3570 AGCCTGAGAGCTTAGGCCTT Gmebl 7390 TTGGCTGTGCATCTTCAAAC Gpx6 11210 O AGGACTTCTGGGTTGGACCG Cds2 3571 ACGGGCGGGACCGGCCGGAG Reml 7391 CTAAGAGGCACCAGGCTGCC Gria2 11211 o GAAGGCTGGTATATAA GCGG Abcal3 3572 GGACGATTACCCGCGGGAGG Sync 7392 GTAATGAGAAGTGACGGGCT Ogdh 11212 GCAGCTGTTAGCAACTTCCT Lrrtm4 3573 TCTGCCTTCCTGGCCATAAA Myoml 7393 GGTAGCAACGTCGGACACCC Ddx56 11213 AAAGCCTCrCACAGGAGTTT Pttgl 3574 GAAGACAGAGCGCACTAAGC Sfil 7394 GCCTATTAAATAAACCCTTT Nr3cl 11214 CCTGCGCAACTGCGAGCAGC Pgapl 3575 TGATACTGTCAGCTAGTCCT Mrps24 7395 GGAGGGCGGTGCCCGCATGA Chmp lb 11215 GAACTGTTGCTGAAGCGGAA Sec 16b 3576 GACAAAGTTTCAGGAGACTT Sun5 7396 AGTAAGCCAGCTCGACCCGC Spagl7 11216 GCTGATATGGAAGATGATTA Tgm4 3577 ATCTCTGCTTGACAAGATCA Ctcl 7397 AGGCGGGCCCTTCAGCCAGC ZbtbSb 11217 CGGGAGAGGAAGCCTGAGCG Magee2 3578 TTCCCAATAAGAACGAACAA Acsll 7398 GGACGTCCTCCTTACTCCGC Skpla 11218 CGGTCAACCrTGGAGCCCAG Itih5 3579 CCCAGATTTAACTTGCCTGC Qrfpr 7399 AACTAAGGGCTAGATCTGCA Actr5 11219 GTGCTGGTTCTTGGTCCCGT Cttnbp2 3580 GGTCACAGGCCACGGGTCCC Phc2 7400 CACTGGGTCAAGGATGTGCC Tinagll 11220 GTTGTTCGTTTGAACCTCGG H2afv 3581 CATGCGCAGGCGCAGTCTTT Cpsf3 7401 GTGCTAGGCAAGCCAGCGTG Ncmap 11221 CGCATGCCGGCACGTGGTGC Tmem222 3582 GCTGGATCCATAAGGGAGTC Bpifb5 7402 ATCAGTTTCATGTTGAAAGT Tenm3 11222 CTGGGTGGGCCCTTAGAGGA Serpirib9b 3583 GTTAGAGACTCCCTCTGCCC Nrk 7403 CTCAGAGGCAGAATCTGCTG Synel 11223 GACCΑ GCAACCAGAAGCC Dclkl 3584 ATTAGGTTAATATGTTCAGC Npvf 7404 GCAGCTGTTGCACCAAGAGG Faml35b 11224 GTCTCCAACATTTCCTCCTG Tgm4 3585 AATTGGACTTCAGTGTTTCG Adralb 7405 GGAGCGCAGCGCGTGCTGCG Gpr3 11225 AGCCTGAGAGCTTAGGCCTT Gmebl 3586 TTCTGCCACGCAACCTAGTT Rackl 7406 GCATGCGCGACTGAGCAGAG Skorl 11226 ACGGGCGGGACCGGCCGGAG Reml 3587 GAAGGAGCGCGCGAAAGGGT Slc32al 7407 CTTATTTGACGCTGCCCACT Ralgapb 11227 GAGGAGGATCTCTACACCCG Kcnj2 3588 TTGGCTGTGCATCTTCAAAC Gpx6 7408 GAGAGAGGCTGAAATGTCGT Eprs 11228 GGACGATTACCCGCGGGAGG Sync 3589 AGACTTGTCCTGAATGTGGG Hdac9 7409 GATCACGTGACGGAGCTCTC Tcn2 11229 GAAGACAGAGCGCACTAAGC Sfil 3590 CCAGGGCTGACGCGCCTCTC Trpcl 7410 CTCCTGTATCAGGAGAGCAA Gpx6 11230 TGATACTGTCAGCTAGTCCT Mrps24 3591 GTAATGAGAAGTGACGGGCT Ogdh 7411 GGCGGTGGCTGGCGTCTCAT Pnrc2 11231 GAACCTTCGCTGTTCGTCCT Desi2 3592 GGTAGCAACGTCGGACACCC Ddx56 7412 GAGGGATTAAGGGCTGCAGC Gucy2e 11232 GACAAAGTTTCAGGAGACTT Sun5 3593 TTCAGCGTCGGAAACCATCG Ntik3 7413 GGCCGCACCTGACTGTTCAC Xpo6 11233 TTCCCAATAAGAACGAACAA Acsll 3594 CACTGATCTCACTGTTGCTA Epsl5 7414 ACGCGCCCGCCTTCTGGCAC MedlS 11234 CGCTCCGATTGGCCAACAGT Kcnj2 3595 AGTAAGCCAGCTCGACCCGC Spagl7 7415 TGTAGCAGCCAATCGAGGCG E2f2 11235 GGTCACAGGCCACGGGTCCC Phc2 3596 GCGCCGTCGGCGTAGAGCGC Slc39al0 7416 CCCAGAAGCCAGGGCGAACC Pkhdlll 11236 TATTTGGGATTCACGGAGGC Aven 3597 AGGCGGGCCCTTCAGCCAGC Zbtb8b 7417 CCCGAAAGTGCTACCAAGTT Slc24a2 11237 AAACGAACCCGCCTGTAAAT Aox4 3598 GGACGTCCTCCTTACTCCGC Skpla 7418 CACACAATACACTTGAACAA Abcc 10 11238 GCTGGATCCATAAGGGAGTC Bpifb5 3599 AACTAAGGGCTAGATCTGCA Actr5 7419 TTTATTGTCCCTCCAATTTC Gbp2b 11239 GTTAGAGACTCCCTCTGCCC Nrk 3600 TTCGCTGCCTAGCCGCACGG Slc22a4 7420 GTCCGAGACTGGAGAGTGCG Fhdcl 11240 ATTAGGrTAArArGTTCAGC Npvf 3601 CACTGGGTCAAGGATGTGCC Tinagll 7421 GAAGGCTCTTCCGCGCTGAC Etv3 11241 n AATTGGACTTCAGTGTTTCG Adralb 3602 GGTGGTGCAACTTCCGTCCC Trim56 7422 CATAGAGTCTGGCCTAGGTT Sh3d2 1 11242 GAAGGAGCGCGCGAAAGGGT Slc32al 3603 GTGCTAGGCAAGCCAGCGTG Ncmap 7423 ATCCTAGAGACCACCTACGT Ulk3 11243 AGCCGATTCCTGGTCATGAC Cd84 3604 ATCAGTTTCATGTTGAAAGT Tenm3 7424 TAATTGGGCATTGAAGACTT C b 314 11244 n TTGGCTGTGCATCTTCAAAC Gpx6 3605 TTCGGGAGTAGTGTTGACAG Lypdl 7425 GTTACGCATGCGACTGGAGG Dynclhl 11245 GTAATGAGAAGTGACGGGCT Ogdh 3606 CTTGGGTCTCCAGCCACGTT Cmpkl 7426 GTGGATACTTGTAGGGCCTG Anxa2 11246 GGTAGCAACGTCGGACACCC Ddx56 3607 CTCAGAGGCAGAATCTGCTG Synel 7427 CTTCGGACGCCAGCCAATAG Anp32a 11247 64 CACTGATCTCACTGTTGCTA Epsl5 3608 GGAGCGCAGCGCGTGCTGCG Gpr3 7428 AGCCTATGTAAATGACAAGG Bel 1 11248 AGTAAGCCAGCTCGACCCGC Spagl7 3609 CTTATTTGACGCTGCCCACT Ralgapb 7429 AGCTCCAACCCTACTTAAAC Fga 11249 GCGCCGTCGGCGTAGAGCGC Slc39al0 3610 TCAAGTCCTTTCATGCGCGC Fgf20 7430 CTACTGGCCTATTTCTTAGA Prkd3 11250 AGGCGGGCCCTTCAGCCAGC Z tb8b 3611 GGGTATTGATTACATCCTGG Atg4c 74 CGTGACCACAGCCTATGCCG Gpn2 11251 GGACGTCCrCCTTACTCCGC Skpla 3612 GATCACGTGACGGAGCTCTC Tcn2 7432 CGCACGCCCAGAGATCTCGC SrsflO 11252 AACTAAGGGCTAGATCTGCA Actr5 3613 GTTCAGCACGTTACTGTGAT Pgm2 7433 TGTGTGCTCCAACAGTGAGT Vmnlrl88 11253 CACTGGGTCAAGGATGTGCC Tinagll 3614 CTCCTGTATCAGGAGAGCAA Gpx6 7434 ATGTCATAGGACAGACACTA Pou6f2 11254 GGTGGTGCAACTTCCGTCCC Trim56 3615 GGCGGTGGCTGGCGTCTCAT Pnrc2 7435 GGCAGTGATGCAAGCGTTTC Dsg3 11255 GTGCTAGGCAAGCCAGCGTG Ncmap 3616 AATGGAACACCTTCCTAACA Trappcll 7436 GGGCTCTGGTTAAGTTTCCT Snx27 11256 ATCAGTTTCATGTTGAAAGT Tenm3 3617 GGGAGACAGGGAAGGGATTC Runxltl 7437 GTCACTCTG CGAAAGGCGCC Zfp24 11257 CTTGGGTCTCCAGCCACGTT Cmpkl 3618 ACGCGCCCGCCTTCTGGCAC Medl8 7438 AGGTGTGCGGCTTCTAGGAA Mtfpl 11258 CTCAGAGGCAGAATCTGCTG S n l 3619 GCAGACGCCCGCGCGTCCTC Lpin2 7439 GGCTACTCCTTTGAGACCCT Rraga 11259 GAAGCTGTrGAAAGTAAGAA Tbx22 3620 TGAGGAGCCAATGGAGCAGC Plat 7440 TCTAATCATAGTGAGCATGC Zscanl2 11260 GGAGCGCAGCGCGTGCTGCG Gpr3 3621 AAGACTGGCGGAGATAATCT Eci2 7441 GCGCTCGGTGCCAACTGATG Clmp 11261 CCGTTAGCTGGCGGCGCGCC Tnc 3622 AAGAAGCTCCTTGCGGTTTG Armcxl 7442 GAGGAAGTAACTAACTCGCC Themis3 11262 CTTATTTGACGCTGCCCACT Ralgapb 3623 TGTAGCAGCCAATCGAGGCG E2f2 7443 ATGAAGCGCCTGGATAGTCC Sc5d 11263 AAGGACTGAGAGCAGGCAGG Csmp3 3624 CCCAGAAGCCAGGGCGAACC Pkhdlll 7444 AGAAGAGGCACCACCTTCTT Tigd4 11264 CACGCTCAAATTrCCGCAGT Snrpn 3625 CCCGAAAGTGCTACCAAGTT Slc24a2 7445 TGGTCTTAATAGGTGTGGGC Gpx5 11265 AGAGGGCACCTCCCTTGGCT Frmd3 3626 GATGGCGCAGCACCAACTGA Pcdhllx 7446 CTGTGGCACCTGCCCTGCAG Gml2888 11266 TTCTGCGTTGCGCGACTTAC Fat4 3627 CGCCTAAGACACCCATTCCC Pik3c2a 7447 GACCATCCTATAAGGAAGCA Ccm2 11267 GGGTATTGATTACATCCTGG Atg4c 3628 GGGCGACGCCCTGGGACGCT Cachdl 7448 CAGGTCTCTCGGGTAACAGG Arhgef38 11268 GATCACGTGACGGAGCTCTC Tcn2 3629 GGGCGGCCCGAGCTCAACGG Arap2 7449 CGGTGCCCGCTGAGGCAACA Tmem57 11269 GTTCAGCACGTrACTGTGAT Pgm2 3630 GACAGACACGTCCCATAGTG Higdla 7450 GAGGTGCTAAAGCACAGCAA 1700008P02Rik 11270 CTCCTGTATCAGGAGAGCAA Gpx6 3631 CATAGAGTCTGGCCTAGGTT Sh3d21 74 AATCTAGCATTT CCATT GGG Rliag 11271 GGCGGTGGCTGGCGTCTCAT Pnrc2 3632 GACGCGGAAGAAGAGACCTG Pparg 7452 CCCGGAGTCAGCTCCAGGGC Tgif2 11272 AATGGAACACCTTCCTAACA Trappcll 3633 AGAGAGCTCCCGTGTGCGCT Tfap2a 7453 GTTGAATCCCATGCCAGTTC Cnksrl 11273 GATTGGCCCGGTGACGACAA Pisd 3634 CGTGACCACAGCCTATGCCG Gpn2 7454 TCCGCGCTGAGATTGCGGAG Psmb2 11274 o ACGCGCCCGCCTTCTGGCAC Med 18 3635 CGCACGCCCAGAGATCTCGC SrsflO 7455 CCAACATTGTCTCTCATAGA Wdr63 11275 GCAGACGCCCGCGCGTCCTC Lpin2 3636 TGTGTGCTCCAACAGTGAGT Vmnlrl88 7456 GCTGTGAGCTGCAGATGGTA Lrrc4c 11276 TGAGGAGCCAATGGAGCAGC Plat 3637 ATGTCATAGGACAGACACTA Pou6f2 7457 CTCCCGGCATGCCTCACGGA Fycol 11277 TGTAGCAGCCAATCGAGGCG E2f2 3638 TCTATTCCCGATATGCACTC Zfhx4 7458 GGATAGTCTGATTGTATAAA Histlh3b 11278 CCCAGAAGCCAGGGCGAACC Pkhdlll 3639 GGTTGGGCGGGCTCATCGGC Myold 7459 AACGGGAAGTGTGCGCTGAT Ccngl 11279 CCCGAAAGTGCTACCAAGTT Slc24a2 3640 AGGTGTGCGGCTTCTAGGAA Mtfpl 7460 GATAGTTTGGAGGTTAAAGT Tdpoz3 11280 GATGGCGCAGCACCAACTGA Pcdhllx 3641 AACAAACTAGATACCGGAAC Cfap61 7461 GTCTTCACAGCGGCTGGTGA Gpr68 11281 GACGCGTGrGTGTTTCTCCC Usp24 3642 GGCTACTCCTTTGAGACCCT Rraga 7462 AAAGTGCCCGTCAAGTTCGG Ak2 11282 AGATGCTCCrCAACGTCACA 1700007B 14Rik 3643 TCTAATCATAGTGAGCATGC Zscan12 7463 ACTGGTCTGGGCGCTGTCCG Vdacl 11283 AGCGCTGCAGAGGTTAGTCG Nsmaf 3644 TGGTCTTAATAGGTGTGGGC Gpx5 7464 AGGTTTAGATTTCTTTCCTA Nf2 11284 GGGCGACGCCCTGGGACGCT Cachdl 3645 AGGGCAGTTGTCTCTTCAAA Gimap9 7465 GCAGCGGAGGATTTATTACC Calml4 11285 GGGCGGCCCGAGCTCAACGG Arap2 3646 GACCATCCTATAAGGAAGCA Ccm2 7466 GTGAGACCCACGGCCATCCC Oxct2a 11286 CATAGAGTCTGGCCTAGGTT Sh3d21 3647 TCACCAGCCGGGTCGGTCCG Zfp651 7467 TGCGTTGATGGTGTTGCACC Olfrl507 11287 CTCGCGGITGGAGGAGGCAC Frmd3 3648 CGGTGCCCGCTGAGGCAACA Tmem57 7468 CTGCTGACGCGTCGCTGCTT Gmds 11288 ATTTACTGCTGGArGGTTTG Cd84 3649 CCCGGAGTCAGCTCCAGGGC Tgif2 7469 AATCAGGCTCCTGAATATAA Bpifb6 11289 AGAGAGCTCCCGTGTGCGCT Tfap2a 3650 GTTGAATCCCATGCCAGTTC Cnksrl 7470 ACAGCTATAGGGCACAGTAG Col9al 11290 CGTGACCACAGCCTATGCCG Gpn2 3651 TCCGCGCTGAGATTGCGGAG Psmb2 7471 GCTCTAATTTCGTTCTACCT Nsun4 11291 CGCACGCCCAGAGATCTCGC SrsflO 3652 GTGGAGCAAGAACGAAAGGC Cagel 7472 GCGGAACCAAAGAAGTGGGA Gatb 11292 AGCAGTCCCTTCTTGCCTCC Speer4fl 3653 CGATGGCGGCGACGGTTTCT Cull 7473 AGAGAGCACGGCTACCGCCC St3gal6 11293 TGTGTGCTCCAACAGTGAGT Vnmlrl88 3654 GCTGTGAGCTGCAGATGGTA Lrrc4c 7474 TAGAGGTGATTGAGTCATAA Spire 1 11294 ATGTCATAGGACAGACACTA P 6f2 3655 GCGCGGCGTCAAGTGCAGCT Z chcl 7475 CACATCGCTCTTGCACACAC Ptprt 11295 TCTATTCCCGATAT GCACTC Zfhx4 3656 GGATAGTCTGATTGTATAAA Histlh3b 7476 TGCCTCGGGCACCTTAGCTC Faml35b 11296 GGCAGTGATGCAAGCGTTTC Dsg3 3657 AACGGGAAGTGTGCGCTGAT Ccngl 7477 TCCATTTAGCTGAATCACCT Ccdc33 11297 CGTGTTAGGTCGGCGTCCAC Ccdc59 3658 TGCAGGCCGGTCACCGAGTG Alg5 7478 GGTGGCGGCAGTTGAGGCCG Adss 11298 AGGTGTGCGGCTTCTAGGAA Mtfpl 3659 AAAGTGCCCGTCAAGTTCGG Ak2 7479 CTTCTGCTAATACAGAACAG Bpifa6 11299 AACAAACTAGATA CCGGAAC Cfap61 3660 GGTCATCGCTCGGCTGCCTG Fa 7 1 2 7480 GCACACGTGCAGAGAACATA Asxl3 11300 GGCTACTCCTTTGAGACCCT Rraga 3661 ACTGGTCTGGGCGCTGTCCG Vdacl 7481 TTAAACCCTTTCTCAACATG Slcl0a2 11301 TCTAATCATAGTGAGCATGC Zscaal2 3662 AGGrTTAGATTTCTTTCCTA Nf2 7482 GAGCCAATCAGGCGCTATCT Dolppl 11302 TGGTCTTAATAGGTGTGGGC Gp 5 3663 GTCTCAGCCGGCCCATGTAG 49 1440F15Rik 7483 GGAGGACCCAAGCTATTGTG Slc22al8 11303 GACCATCCTATAAGGAAGCA Ccm2 3664 CCGACGCAACCAATCATCGC Ctli 7484 TGTCAGTAGTAACCTCCAAG Lrrc4c 11304 CGGTGCCCGCTGAGGCAACA Tmem57 3665 TAGGGrTGCGGACTCCGCCC Dnm2 7485 GTCGCGCGCTACAAATTCAT Histlh3c 11305 TTGGTTCTGGCCAGCGCGTC Slfl 3666 GGCACGTGACTAGCCCACGC Bex4 7486 TATTTGTCTCCGATGGGCCA Gal3stl 11306 CCCGGAGTCAGCTCCAGGGC Tgif2 3667 CTGCTGACGCGTCGCTGCTT Gmds 7487 ACCAGCTGTCCAGCGCACCG Serinc2 11307 GTTGAATCCCATGCCAGTTC Cnksrl 3668 AATCAGGCTCCTGAATATAA Bpifb6 7488 CCGCCTCTCAGAGTAACGAT Fucal 11308 TCCGCGCTGAGATTGCGGAG Psmb2 3669 ACTCTAGGGCATCCCAGTCC Gabib2 7489 CCAGGGCTGATCTAGTTTGA Adralb 11309 GTGGAGCAAGAACGAAAGGC Cagel 3670 CGTAGGGCTGCTCCCACGGG Steap2 7490 GCCACCGGCAAAGCTAGAAA Sema7a 11310 CGAT GGCGGCGACGGTTT CT Cull 3671 CTAGGCGTCCCAGAGCACTA Esxl 7491 CCCACCCTAGCCTCGGCGGG Slc6a20a 11311 CCAACATTGTCTCTCATAGA Wdr63 3672 CCTTTCACGGTTCCTGTGCC Hspa4 7492 TTCGGCTGGCACCGAGTGAC Hpcal4 11312 GCTGTGAGCTGCAGATGGTA Lrrc4c 3673 CA CATCGCTCTTGC A C CA C Ptprt 7493 GACTGAGACTCTGTCCCAGT Robo4 11313 GCGCGGCGTCAAGTGCAGCT ZcchclS 3674 GATTGAGTGAGGAGTCGAGG Trrap 7494 CGCCAAGGAAGGTACGCGTG Dap3 11314 GGATAGTCTGATTGTATAAA Histlh3b 3675 TTGGATTCTTCGGAGAATCC Trim45 7495 AAAGACAGGGCAGAGCTCAT Gm94 11315 AACGGGAAGTGTGCGCTGAT Ccngl 3676 CTTCTGCTAATACAGAACAG Bpifa6 7496 CTGCGGCCCTGCTGCTGCTC Aff4 11316 AAAGTGCCCGTCAAGTTCGG Ak2 3677 GCACACGTGCAGAGAACATA Asxl3 7497 ACGCCTCCACCCGGGTCGCG Dst 11317 ACTGGTCTGGGCGCTGTCCG Vdacl 3678 GCGCGCTCTGAAATCAAACT Tt 2 7498 TGGCGGGCGGGAGTAGACGC Stk32c 11318 AGGTTTAGATTTCTTTCCTA Nf2 3679 AAGCCACCTCATAAAGACTG Timp4 7499 TCCACACTTGTAAGCGCAAC Iqsecl 11319 CTGCTGACGCGTCGCTGCTT Gmds 3680 CTGCACCATACAGGGTGGGT Zfp879 7500 GCCTTGCAGTCCGTGTTCTC Glral 11320 AATCAGGCTCCTGAATATAA Bpifb6 3681 CCGGATTGTGACGTCCAGTC Chd5 7501 ATCCATGATCATGGCTGATC Pcp4 11321 ACAGCTATAGGGCACAGTAG Col9al 3682 AGTGCAGTAAGCGTCCTTGG Dnah6 7502 GTGGATCGGGACACCTCCTT Ttll9 11322 AGAATCCACTCTTCTGTTAG Ab a9 3683 GGAGGACCCAAGCTATTGTG Slc22al8 7503 CAGGTGTCACCACGCCGGGA Pigv 11323 ACTCTAGGGCATCCCAGTCC GabA>2 3684 TGTCAGTAGTAACCTCCAAG Lrrc4c 7504 CACCTGTCTCTTCTCTAGAC Traeml 06b 11324 CCCGACGGTCCGGCTCTGCG Gabrg3 3685 TAAGTTAGAAGTGGTCrGrr Car5b 7505 GAAGTCTGTGATTCAGATTT Tcf4 11325 CTAGGCGTCCCAGAGCACTA Esxl 3686 GTCGCGCGCTACAAATTCAr Histlh3c 7506 AAGGAACTTGATCTACTGGC Graradlb 11326 GAGTCAATGAATGAGTTTAT Plbl 3687 TAAAGCATTTCGCGGAGTGC Zfp212 7507 CGGTTTGCTCTCGCAGCATC Iqsecl 11327 CACATCGCTCTTGCACACAC Ptprt 3688 TATTTGTCTCCGATGGGCCA Gal3stl 7508 CGGGAAGGCGGGCGAGGACG Markl 11328 GGCGACGTTGGCGTCGCGGT Ascc3 3689 ACCAGCTGTCCAGCGCACCG Serinc2 7509 TTATAATGTCCATCTGAGGG Hrnr 11329 CTTCTGCTAATACAGAACAG Bpifa6 3690 CCCGA GTTTAGG AAGA GGAG Smarca2 7510 CGGCGTTCTCGAGCCTCGCG Wac 11330 GCGCGCTCTGAAATCAAACT Ttf2 3691 CCGCCTCTCAGAGTAACGAT Fucal 75 TAGAGAGGAAGAACGTTCCC Zfp691 11331 AGTGCAGTAAGCGTCCTTGG Dnah6 3692 GCCCAGGCCCTTTGTCTGCC Adamtsl9 7512 CTCACTGATATAAACATTAC Gml2169 11332 GGAGGACCCAAGCTATTGTG Slc22al8 3693 AACAGACTTCTCTCCTAACA Acacb 75 L3 ATGCGCTTAGGGACTGTGAT B3galt5 11333 TGTCAGTAGTAACCTCCAAG Lrrc4c 3694 CCAGGGCTGATCTAGTTTGA Adralb 7514 CCAGTGGATAGATTAGGCGG Ptk7 11334 ACTGCTTGTAAATAAACTGC Impg2 3695 CATTGACAGCTTTAGTCATG Ugtlal 7515 CTTCTCATTCTGAACTGCTT Fbxo8 11335 TATTTGTCTCCGATGGGCCA Gal3stl 3696 CCCACCCTAGCCTCGGCGGG Slc6a20a 7516 GTCGAAGGCAGTTACGTCAT Tritl 11336 ACCAGCTGTCCAGCGCACCG Serinc2 3697 AATGFAGTTGCTTAGGACAG Fbliml 75 17 GAGCTTGCCCAAAGGCCTCC Cs 2 11337 CCCGAGTTTAGGAAGAGGAG Smarca2 3698 AAAGACAGGGCAGAGCTCAT Gm94 75 L8 GGAAAGGGAGATGCGCTGCT Cfap57 11338 CCGCCTCTCAGAGTAACGAT Fucal 3699 CGCGGTTGGCTGGCCGCTCG Wdr78 7519 ATCAGGCCGGCGGCCGCGGC Cpeb2 11339 ACCTGCCCTGGTCCAACTGT Kcnd2 3700 CTGCGGCCCTGCTGCTGCTC Aff4 7520 TTCTTCTTCGGGCCAGTCCC Skorl 11340 GCAGCCTTCCCTGCTCAGAA Lrrtm4 3701 TGGCGGGCGGGAGTAGACGC Stk32c 7521 GCTGCGTAGATGTTCCAGAG Dmbxl 11341 AGGAGGGAGGGACGAAGAGA Pmil4 3702 GCCTTGCAGTCCGTGTTCTC Glral 7522 GGTCGTG GGTTGTC CGAT GC Rplll 11342 CCAGGGCTGATCTAGTTTGA Adralb 3703 TGGCATTCCACCCAAACACr Calr4 7523 GCACAGTGCTCCCGAGGGCG Dnajcl3 11343 CCCACCCTAGCCTCGGCGGG Slc6a20a 3704 CCACACTCCCGAGCATCCAA Kazn 7524 CCTTTGTGCAGCCGGAACTA Mplkip 11344 AAATGGATTATAGGACTAAC Phflld 3705 GGCGCFGCGGAGCGAGCCGG Zdhlicl8 7525 GACACGCTTTCAAGCTGCTG Prelid2 11345 AATGTAGTTGCTTAGGACAG Fbliml 3706 GTGGArCGGGACACCTCCTT TtH9 7526 TTTGGAGGTGAATTTAGAGC Hck 11346 AAAGACAGGGCAGAGCTCAT Gm94 3707 CAGGTGTCACCACGCCGGGA Pigv 7527 TCGCCCTCCTCGACCTCTCC Tbcld9b CCCAGCGTGGTTAGCATTAT SpllO 3708 CACCTGTCTCTTCTCTAGAC Tmeml06b 7528 GGCTGTCG GCGAAGCGA CGG Map2kl CTGCGGCCCTGCrGCTGCTC Aff4 3709 CGCGTCTGCAACCGGGTGGG Pax7 7529 CTAGCCTGTAGCTTATGCCC Bpifa3 TGGCGGGCGGGAGTAGACGC Stk32c 3710 CGGCGTTCTCGAGCCTCGCG Wac 7530 ATCAACGACACCCGGGAGCG Spatal7 GCGCTCACTCGCTGGCCTCC AtpSal 3711 CTCACTGATATAAACATTAC Gml2169 7531 TATCACTATTTGCTTCTCGA Hpcal4 GCCTTGCAGTCCGTGTTCTC Glral 3712 GTTGTGATTGATCCAGGTCC Ppia 7532 TCACTAGTGGGAGCTGGAGA Bmprlb TGGCATTCCACCCAAACACT Calr4 3713 CTTCTCATTCTGAACTGCTT FbxoS 7533 AGGGATAGATAATTATCTAG Bpifb6 CCACACTCCCGAGCATCCAA Kazn 3714 GGGCAGCTCCAGCTGGATGC Dab2ip 7534 CTGAGGTCCCTACTCTGGTG Cox4i2 CCGGAGCGAAGCACGCACAG Laip4 3715 GAGCTTGCCCAAAGGCCTCC Csf2 7535 AGTGCGCGCCAGAAAGGGAC Bcl211 GGCGCTGCGGAGCGAGCCGG Zdhlicl8 3716 GCGCCTCTCGCGACTTGCCC Rasa2 7536 GGTCTTTCATGAGGTCTAGT Iars2 GTGGATCGGGACACCTCCTT Ttll9 3717 ATCAGAGGGCGGCGTTCGTC Fam46c 7537 GTTCTTTGTGGTCCGGGCAG Meal CAGGTGTCACCACGCCGGGA Pigv 3718 GGTCGTGGGTTGTCCGATGC Rplll 7538 GAAGGGTCTTAACCGAAAGG Sox30 CACCTGTCTCTTCTCTAGAC Tmeml06b 3719 CCTTTGTGCAGCCGGAACTA Mplkip 7539 CGCCAGAGCCTTCGCGCCAG Dpysl3 GCTTGTAGGAGGGCTGTCCA Ntm 3720 TTTGGAGGTGAATTTAGAGC Hck 7540 ACCAAATAAGAATTCATGAG Morc2a CGCGTCTGCAACCGGGTGGG Pax7 3721 TCGCCCTCCTCGACCTCTCC Tbcld9b 7541 ACAAAGCCCTGGGAGGGCCC Bpifbl TGCTCAGGTGCGGTCGCGTC Arhgaplla 3722 CTAGCCTGTAGCTTATGCCC Bpifa3 7542 CGGCAGCAACTAAACTTGGG Mtfrll TTATAATGTCCATCTGAGGG Hrnr 3723 CGGTTGAGCGCAGTCTTTCT Tmem82 7543 AGCATCCGCTCTGTCATCCC Rabl2 CGGCGrrCTCGAGCCTCGCG Wac 3724 AGGGATAGATAATTATCTAG Bpifb6 7544 CCACAGCCACTCCAGTAATG Bpifb3 TGACTCCGACAGGGAGCAGG Btbd7 3725 GCAGGACGGAGCAAAGGTCC Dfna5 7545 AGGATGCAAGATATAAGGCT Bpifbl CTCACTGATATAAACATTAC Gml2169 3726 CTGAGGTCCCTACTCTGGTG Cox4i2 7546 AGAAGGACAGATTGGTGGAT Cttn GTTGTGATTGATCCAGGTCC Ppia 3727 GTAGTGGGCGGGCGGTCTAT Ppfial 7547 GTGAAGTTTACCATATTTCA Klral CTTCTCATTCTGAACTGCTT FbxoS 3728 AGTGCGCGCCAGAAAGGGAC Bcl211 7548 CCTGGGAGGGACAGACTCCC Gja4 GAGCTTGCCCAAAGGCCTCC Csf2 3729 GCGACTGTATTTGTCTGGAG Sgcz 7549 GGAGACAGAGAGGAGCTGGG Ptpn9 TAGCCTTTGGGATCTGGCTC Lcat 3730 CGCCAGAGCCTTCGCGCCAG Dpysl3 7550 TTACCTCCAGCTAGAGATGC Slc36a3 TACTGTCCTTGAGAATGGAG Oprml 3731 ACCAAATAAGAATTCATGAG Morc2a 7551 CAATGTTTCCTGGTATGGTT Ifi47 ATCAGAGGGCGGCGTTCGTC Fam46c 3732 GGGATAGTAGTAGAGGTCCC Nphpl 7552 GGGTG GTGCGCAACCGA AAG Gnal GGTAAGGAGGAGGATTTGAC Ddx6C 3733 ACAAAGCCCTGGGAGGGCCC Bpifbl 7553 GGCGGGAACACATCCTGAGG Cyp39al GGTCGTGGGTrGTCCGATGC Rplll 3734 CGGCAGCAACTAAACTTGGG Mtfrll 7554 AGTGCAGGCCGCTCCAGGAT Cbfa2t2 CCTTTGTGCAGCCGGAACTA Mplkip 3735 CTTGCCCTAACATTACCAAA Dach2 7555 CGCACCCTTTACACAAACCG leal TTTGGAGGTGAATTTAGAGC Hck 3736 CCACAGCCACTCCAGTAATG Bpifb3 7556 CATCGGGACCATCTGCCTAG A kr 6 TCGCCCTCCTCGACCTCTCC ¾ ld9b 3737 AGGATGCAAGATATAAGGCT Bpifbl 7557 AGTCCGGGCCGGAGCATTTC Atg2b GGACGCAGAATTCTCTACTT Mpped2 3738 AGAAGGACAGATTGGTGGAT Cttn 7558 GCAAAGCTAAAGCCGTGCAG Iars2 CTAGCCTGTAGCTTATGCCC Bpifa3 3739 CCCTCCTTTGCAGAGGGCAT Slc25a4 7559 GCTTCTGCTTGAATACTTCT Aimll TCACTAGTGGGAGCTGGAGA Bmprlb 3740 GTGAAGTTTACCATATTTCA Klral 7560 AAGGACTAGTCTCCACCTTT Olfrl 394 ACATTCTCTCCCTCTTTACC Myo3b 3741 CCTGGGAGGGACAGACTCCC Gja4 7561 GAGTGTGAATAGGATCTATG Myl7 CGGTTGAGCGCAGTCTTTCT Tmem82 3742 TTACCTCCAGCTAGAGATGC Slc36a3 7562 GGAAGTGACGCCATATTGCG Gskip AGGGATAGATAATTATCTAG Bpifb6 3743 TATGATTATTGCTGCTCACT Insl5 7563 AAAGGTTCTGCGAAAGAGGC Gm2a GCAGGACGGAGCAAAGGTCC Dfna5 3744 CAATGTTTCCTGGTATGGTT Ifi47 7564 AAGGTAGGCTTGATGACCTG Sec 1414 TGCAAAGTTATTAAGATCCA NoplO 3745 AACCCGTTCTATTCCAGGAC Rwdd4a 7565 GGTTT GTCAA GCTTGTC ATG Cxcr6 CTGAGGTCCCTACTCTGGTG Cox4i2 3746 GGACATTCG GCGATTC CCAC Ckap21 7566 CCCTGGCCTAGGGTGGTGAG 2300009A05Rik AGTGCGCGCCAGAAAGGGAC Bcl211 3747 AGTGCAGGCCGCTCCAGGAT Cbfa2t2 7567 TGAGGAAACAAACTCGTTCA C2cd4a TAAACAATrCCAAGAATGTC Mme 3748 CCCTAAGGGACCCGCCCGCA Mpp6 7568 TTTAATAGGCCCAGGCTCCA Kncn CGCCAGAGCCTTCGCGCCAG Dpysl3 3749 CGCACCCTTTACACAAACCG leal 7569 GCAAGCAAGCAGTGATTGGC Yars ACCAAATAAGAATTCATGAG Morc2a 3750 CATCGGGACCATCTGCCTAG Ankrd36 7570 GGAAGTCTCGGCTTC AAGTC Kdm4c GGGATAGT AGTA GA GGTCCC Nplipl 3751 TGCA GCGTTCTATTG GTCGG Y aq 7571 TTTGGTACCAGACAGAATAG Clqtnf7 ACAAAGCCCTGGGAGGGCCC Bpifbl 3752 GCTTCTGCTTGAATACTTCT Aimll 7572 GGTTAAGCCTTCCCTCGGCG Sin3a CGGCAGCAACTAAACTTGGG Mtfrll 3753 GAGCACTTGCGTGGTTGCCC Ankefl 7573 GTTTCTGCTGCAGGGTTCTC C130074G19Rik CTTGCCCTAACATTACCAAA Dach2 3754 AAGGACTAGTCTCCACCTTT 01frl394 7574 ATAGGTAAATAAGGCTTGCT Fgb CCA CAGCCACTCCAGT AATG Bpifb3 3755 GAGTGTGAATAGGATCTATG Myl7 7575 GATCTGCTAAGCTCGCGACA Drgl 11395 CTGAGAGGATCGTACCATCC Psd3 3756 AAAGGTTCTGCGAAAGAGGC Gm2a 7576 CCTGAGTGCTCGAGCTAAGG Ncdn 11396 AGGATGCAAGATATAAGGCT Bpifbl 3757 AAGGTAGGCTTGATGACCTG Secl414 7577 GCGGGCACAGAGGTTCCGTG Husl 11397 o GCACGAAGCACGGCCGGTTC ArhgeflO 3758 TCAATGCCCAGCTCATGAGA Mumlll 7578 TCATCCTGAAAGTCAGGGTT Arid3b 11398 AGAAGGACAGATTGGTGGAT Cttn 3759 GGTCTAGGTCTGAAAGAATG Tgifl 7579 TGAACTCCTCTTATAATTCT Itk 11399 CCCTCCTTTGCAGAGGGCAT Slc25a4 3760 TGAGGAAACACGTTCTCTAT Nsun2 7580 GGAGATGCTTCCGTTCTCGC Hpca 11400 5 GTGAAGTTrACCATATTTCA Klral 3761 ACACTCCTAGGCAGTGAAGT Tgm6 7581 TAATCAGATCTTTGACGAAG Lrrc4c 11401 o CGTGCTCTCTCTGCGCTCCG Usp24 3762 GACTTGCCTTGGTGTGACTC Skintll 7582 GCGTTCCTCACTGACGCTTC Mut 11402 4 CCTGGGAGGGACAGACTCCC Gja4 3763 GCAAGCAAGCAGTGATTGGC Yars 7583 GGCGCGATGTCCCGGCGCGG Lrig3 11403 TTACCTCCAGCTAGAGATGC Slc36a3 3764 TTTGCTGTGAGGATGTGAAC Amy2b 7584 CGACTCGCTCATTCGCCGCC Zc3hl5 11404 TATGATTATTGCTGCTCACT Insl5 3765 GAGACCAGAGAGAATTAGCC Sema4a 7585 TGAGGTGTGGCTCTAGGCCT Gml2169 11405 CAATGTTTCCTGGTATGGTT Ifi47 3766 GTGGAGCCATAGAAAGAAGG Brwd3 7586 TAATCGGATCAGAGATAATG Nr3cl 11406 AACCCGTTCTATTCCAGGAC Rwdd4a 3767 GATCTGCTAAGCTCGCGACA Drgl 7587 GTGGTACCCAGAGCCGGCCA Ttc22 11407 ATATTGCGCCAACAGGTCAT Prame 3768 CCTGAGTGCTCGAGCTAAGG Ncdn 7588 GAGCCACCTGATCATGACTC Themis3 11408 GGACATTCGGCGATTCCCAC Ckap21 3769 GCGGGCACAGAGGTTCCGTG Husl 7589 GAGGATGACTCCGTACGGGT MrpslO 11409 AGTGCAGGCCGCTCCAGGAT Cbfa2t2 3770 TGAACTCCTCTTATAATTCT Itk 7590 TTCTGTTTCCTGAGGGTGGG Cfap44 11410 CCCTAAGGGACCCGCCCGCA Mpp6 3771 CTCACAAACTGTAACCCTGT Clip4 7591 ACAGCCAGCATCCTCTCGGG Ctbp2 11411 AGAACGCCAGTCCCGTAGCA Topi 3772 GGAGATGCTTCCGTTCTCGC Hpca 7592 CCGCGGCGCTCGGACGGGCC Cdkl3 11412 CGCACCCTTTACACAAACCG leal 3773 TAATCAGATCTTTGACGAAG Lrr 4 7593 GGACCGGCACATCGACATCC Tmem50a 11413 CATCGGGACCATCTGCCTAG Ankrd36 3774 CAATGAAGCAGA GAGGTC CT Cd72 7594 GGCCAGTCCGTCTCTATAAA Maprel 11414 GTCTATCCTGAGGGCAAGCA 9830107B12Rik 3775 TGAGGTGTGGCTCTAGGCCT Gml2169 7595 TCCTGAATCGCCCTCGCAAT Ndufaf7 11415 GCTTCTGCTTGAATACTTCT Ai l 3776 CTACTGCTGTTGCGCAAGGG B np3 7596 CCACACGCAGGGCCAAGGAG Slc6a20a 11416 GAGCACTTGCGTGGTTGCCC Ankefl 3777 CTGTAGCAAGGGACACAGTG Cln8 7597 CGAGGCTCGGCCCTGCCGTC Tsn 11417 AAGGACTAGTCTCCACCTTT 01frl394 3778 CAGCGCTTCGGAAATCCTGC Brinp3 7598 TGGAGACAAATGATAACAGC Zbtb46 11418 GAGTGTGAATAGGATCTATG Myl7 3779 CACACAAGCAGGGCCTCTCG Siipa 7599 TCCACCTCGGTGGCGACAAC Ccdcl57 11419 CCGCGAGATTTCTGATTGCG k r 3780 CCGCGGCGCTCGGACGGGCC Cdkl3 7600 CTCTGCTGGCCTCCTAATCC Zfp62 11420 AAAGGTTCTGCGAAAGAGGC Gm2a 3781 CATTTCCTGAATGGGATGAG G6pd2 7601 TCTCCGGAGCCTGGGCGGTG Plpp4 11421 AAGGTAGGCTTGATGACCTG Sec 1414 3782 GGACCGGCACATCGACATCC Traem50a 7602 GCTCCTCTGGCAAGGGCAGT Arhgdib 11422 GAGCCCAGGAAATTAATTTA 9230104L09Rik 3783 GGCCAGTCCGTCTCTATAAA Maprel 7603 TCTACACTGACTTAAATCCA Defb7 11423 CAGAGTGTCTGGAGCCTAAG Nrlh5 3784 GGGTGTCTGACCGCTCTGAC Adcy8 7604 TCAAGTACTGTACTTGCTAT Sfpq 11424 GGTCTAGGTCTGAAAGAATG Tgifl 3785 GGCGCTTGACGTGGAGTCGG Elavl4 7605 AGCTAACCATGGAGGAGACT AW551984 11425 A CA CTCCTAGGCAGTGAA GT Tgm6 3786 GGAGCCCGGCACGACCAGGA Mcm8 7606 CATCGGGAAGGCTTGAGTCT Syf2 11426 GACTTGCCTTGGTGTGACTC Skint 11 3787 ACGATGGCTTCATGTTTATG Nrap 7607 CAGCCTGGAAAGCAAGTAGT Myol5 11427 GCAAGCAAGCAGTGATTGGC Yars 3788 CCACACGCAGGGCCAAGGAG Slc6a20a 7608 CTAGGCCACCTTCAGAGCCC Wisp2 11428 TTTGCTGTGAGGATGTGAAC Amy2b 3789 CGAGGCTCGGCCCTGCCGTC Tsn 7609 AAATGTTTGAGCAGAGCCTG Pig 11429 CACCGGAAGCAGCCGAGCGC Aven 3790 TTGGGTAACCATAAACATAA Suclgl 7610 CCAAATCCTGCTGCTGAGTC Gm906 11430 GTGGAGCCATAGAAAGAAGG Brwd3 3791 TCCACCTCGGTGGCGACAAC Ccdcl57 7611 GCCGGAAGGCATCAAGTCGC Lrrc27 11431 GAAGCAGCTGAGACACAGTC Ppplrl6b 3792 GTGACAGAAGGCTAGGGAGC Rai2 7612 TGGGAGGGCGGGTCAAACCT Hck 11432 GATCTGCTAAGCTCGCGACA Drgl 3793 CTCTGCTGGCCTCCTAATCC Zfp62 7613 CAATTTGTGCTCGGAGACTG Capl 11433 n CCTGAGTGCTCGAGCTAAGG Ncdn 3794 GGAGTAGCCAGTGATGTCAC Pax4 7614 ATGAAGACAGACGCGGTTCC Dynclhl 11434 GCGGGCACAGAGGTTCCGTG Husl 3795 TCAAGTACTGTACTTGCTAT Sfpq 7615 CACCTGAATTTCTTTGGGAA Slc35e4 11435 AGGTGATCTTTArCGCTCTC Btafl 3796 AGCTAACCATGGAGGAGACT AW551984 7616 TTT CTGGTATGA GCCATT CT Stra6 11436 n 64 TGAACTCCTCTTATAATTCT Itk 3797 CATCGGGAAGGCTTGAGTCT Syf2 7617 GGAGTCGCCGAGTGGTGGGC Rcan3 11437 CTCACAAACTGTAACCCTGT Clip4 3798 ATACCACAGCAACCTTGACG Csmd3 7618 TGGCCTGCCGCTCTCCCAAT Ncapg 11438 5 GGAGATGCTTCCGTTCTCGC Hpca 3799 CTAGGCCACCTTCAGAGCCC Wisp2 7619 GGAAACGTGAGATTAGATGA Bpifa5 11439 64 TAATCAGATCTTTGACGAAG Lrrc4c 3800 CGAGCTTAGCACTTGAAGGG Bphl 7620 CACCCGGTTTCCGGACCTTG Haus6 11440 5© CGACTCGCTCATTCGCCGCC Zc3hl5 3801 CCAAATCCTGCTGCTGAGTC Gm906 7621 GGGCGGCCGGGCGCAGCCTG Raplgdsl 11441 5 TGAGGTGTGGCTCTAGGCCT Gml2169 3802 GCCGGAAGGCATCAAGTCGC Lrrc27 7622 CTCGTCTGCAGTCCCTGACC Tspan32 11442 CGGCTTCACCGCGCGTGCCT Cdk5rap2 3803 TGGGAGGGCGGGTCAAACCT Hck 7623 CAAATTCCTGCGCCTCCAGG Ascc2 11443 CACACAAGCAGGGCCTCTCG Siipa 3804 GATTGGAAGTTTCTTCCGCC Wdr3 7624 TCATTGTGATGGCAGTTCCA Tbcld21 11444 CCGCGGCGCTCGGACGGGCC Cdkl3 3805 GAAACCGGGAGTAGCGTCCC Cedcl26 7625 GGAAGGGCAGATATATGAAC Bpiib4 11445 o GGACCGGCACATCGACATCC Tmem50a 3806 ACAGTTTCACAACTTGTGCA Adam7 7626 CCTGTGGAACTACATGTCCC Calcocol 11446 GGCCAGTCCGTCTCTATAAA Maprel 3807 ATGAAGACGCCCAGAGAGAA Ak4 7627 CTAGTCCCTACCTGTAGCTC Proml 11447 GGGTGTCTGACCGCTCTGAC Ad y 3808 CACCTGAATTTCTTTGG GAA Slc35e4 7628 AACAGTTACGTCAGATGTGG Fstl5 11448 5 GGCGCrTGACGTGGAGTCGG Elavl4 3809 TTGGGCGTTGCTAGGAGACG Arl4a 7629 ACAGTAGTGTCAGATAGAAG Mllt3 11449 o GGAGCCCGGCACGACCAGGA Mcm8 3810 GGAGTCGCCGAGTGGTGGGC Rcan3 7630 GAGGTGCGGCTTGATGACAA Zfp24 11450 4 CTCCCACGTGAGAACGGGCA Sycp3 3811 TTTCACGTTATTCCGCCCAG Osbpl3 7631 GGAAACACGAGAGGACCGCG Sycel 11451 CCACACGCAGGGCCAAGGAG Slc6a20a 38 12 GAGGCTGGGCTAGGCAGCGC Cftr 7632 AAGGTGTGTGCTGCCATGCC Tln2 11452 CGAGGCTCGGCCCTGCCGTC Tsn 3813 GGAAACGTGAGATTAGATGA Bpifa5 7633 GGTTGATTACTTCAGAAATT Adaml9 11453 GCTATGACGATGAGACTGGC Ano3 3814 GTCCGTACGGCGAAGTGATG Casp9 7634 TCCCGGCCGCTTCAAACCGC Clic4 11454 TCCACCTCGGTGGCGACAAC Ccdcl57 3815 GAGGAACTACATTTCCCAGA Polrlb 7635 AGAGGCTCGGCGGCGACGGG Ctbp2 11455 CTCTGCTGGCCTCCTAATCC Zfp62 3816 CACCCGGTTTCCGGACCTTG Haus6 7636 GGTGTCCCTGAGCTCACACG Mcoln2 11456 GGAGTAGCCAGTGATGTCAC Pax4 3817 CTCGTCTGCAGTCCCTGACC Tspan32 7637 TTTATTTACACCACGGAGAG Tdpoz2 11457 TCTACACTGACTTAAATCCA Defb7 3818 CAATAGAGAAACCTCCACCG Thgll 7638 ACCAAGTCTGCTAAATCGCC Ccdcl7 11458 TCAAGTACTGTACTTGCTAT Sfpq 3819 CAAATTCCTGCGCCTCCAGG Ascc2 7639 CTTCGAGTCTGAACCCGCCC Gjb3 11459 AGCTAACCATGGAGGAGACT AW551984 3820 GGAAGGGCAGATATATGAAC Bpifb4 7640 AGTCCCGGAAGTGGCTGTCA H2-T3 11460 CATCGGGAAGGCTTGAGTCT Syf2 3821 GGAAAGTACAATTATCAGAC Cfap97 7641 GCTGCGGGAAGCCGTGACGC Mpdz 11461 ATACCACAGCAACCTTGACG Cs 3822 CCACAGCAGGCCTGCAAG AA Fam71fl 7642 GACCCACAGACAGAGTAGAA Stra6 11462 CTAGGCCACCrrCAGAGCCC Wisp2 3823 CGCCCAGGACCCTCACCAAA I15ra 7643 GCTGAAACCTTATTCGCTTA Arhgei2 11463 CGAGCTTAGCACTTGAAGGG Bphl 3824 CCCAATTCTGGGATGCTTGA Faml99x 7644 GACTGGCGACGGAGGACGTG Cep76 11464 CCAAATCCTGCTGCTGAGTC Gm906 3825 ACAGTAGTGTCAGATAGAAG llt3 7645 CGTGTGATTGGCAGCCACAG Dmbxl 11465 GCCGGAAGGCATCAAGTCGC Lrrc27 3826 GTGACAGGAGACTAGCCAGT Dctd 7646 GGTCTAATCAGCGACTGGTT Tubb5 11466 TGGGAGGGCGGGTCAAACCT Hck 3827 GGAAACACGAGAGGACCGCG Sycel 7647 CCCGCGTCGCCTGCCGTGGG Ifnlrl 11467 GATTGGAAGTTTCTTCCGCC Wdr3 3828 GGACCACGAGCTGAGATGGT Calr4 7648 GGTAAATAACTCTAGTTAGC Cyp8bl 11468 AGCTACTAGCTCCGTCTCCC Fibin 3829 TCACTTACCTCCTTCTCACT Gcm2 7649 ATTGGCCCGGTGTGGTGGGT Cadm2 11469 GAAACCGGGAGTAGCGTCCC Ccdcl26 3830 CTTGCTCCCAGCAGAACTGG Dytn 7650 GGTCTGAGGCCTGAAGGCGG H2-T3 11470 ACAGTTTCACAACTTGTGCA Adam7 3831 TCCCGGCCGCTTCAAACCGC Clic4 7651 CCTGTCAATTAGCGGAAGCA Enpp5 11471 ATGAAGACGCCCAGAGAGAA Ak4 3832 GCTTCTCAGCTTGCCTCAGT Pcedla 7652 GGCCCTCTCAGATCACATGC Trim63 11472 CACCTGAATrrCTTTGGGAA Slc35e4 3833 CCAGCCTCTAGGAACTAGCG Tbxl5 7653 ATGTAGTTCTCGGCGTGAAG Papola 11473 GGAGTCGCCGAGTGGTGGGC Rcan3 3834 CTTCGAGTCTGAACCCGCCC Gjb3 7654 TTCCACCGGAAGTGCTCCCT Hjurp 11474 TTTCACGTTATTCCGCCCAG Osbpl3 3835 GTAAAGTAAACACACTCTGT Slc5a9 7655 CACCCTGGTCTCACCTCCAC Olfrl330 11475 GAGGCTGGGCTAGGCAGCGC Cftr 3836 GGCTGGCTGCTTAGTGACAT Tspan33 7656 GTCATTCAGCATGGGTTTCC Zbbx 11476 GGAAACGTGAGATTAGATGA Bpifa5 3837 GCATTTAATAAACTGCCTTT Sorcs3 7657 AAAGAAGCACCGCCCGCTAC Gatsl3 11477 GTCCGTACGGCGAAGTGATG Casp9 3838 GGCAATAACAGCTTCAGCAG Scn7a 7658 GAATGGCTGGGCCCTGTAGT Neill 11478 GAGGAACTACATTTCCCAGA Polrlb 3839 TCGCTTGCACAGGACCCTTC Cachdl 7659 ACGAAGCCAATACGAGTGGG Bhlhe23 11479 CACCCGGrrrCCGGACCTTG Haus6 3840 CCCGCGTCGCCTGCCGTGGG Ifnlrl 7660 GAAAGATGCTCCCAGCTGTT Kcnsl 11480 CTCGTCTGCAGFCCCTGACC Tspan 3841 TAGGCTGGGCATCCTTGCAG Adam7 7661 AACGTTACCCTCCAAAGCGA PpplrlO 11481 n CAAATTCCTGCGCCTCCAGG Ascc2 3842 GGTAAATAACTCTAGTTAGC CypSbl 7662 AGGCGTTTGTTGGGACACGC Ilf2 11482 TGGGCTTCATAGGACAGAAG Nliplb 3843 TTCTGAGAAGGCCCGCCCTA Ckap21 7663 CCACACCTGCAGCATTACCC Nr2e3 11483 TAATTCTCACGCTGTTCCGA Psd3 3844 TATAACGCACAGGAAATTGC Dcx 7664 TCTGAAAGGAATCCCAAGAG Pafah2 11484 n GGAAGGGCAGATATATGAAC Bpifb4 3845 AAGGACACAAGTAGCCCGAG 16000 151lORik 7665 GCCAGGGAGGCTCAGCCATT Anp32a 11485 o AGTGTGGCCGGCAAAGCTTT Tmc5 3846 GGCCCTCTCAGATCACATGC Trim63 7666 CTGAGGACTGCGTGGAGGAG Fine 11486 5 GGAAAGTACAATTATCAGAC Cfap97 3847 TCAGGAAGAGCACGCATGCT Utp20 7667 TATGTGGAGATATTGGTTCA Zbtb8a 11487 b CCTTGAGCGGACCCTGGACT Slcola6 3848 TTCCACCGGAAGTGCTCCCT Hjurp 7668 TGGCTGATACTGGCCACTAG Traod4 11488 5© CCACAGCAGGCCTGCAAGAA Fam71fl 3849 TTTAGATTGACGAGCAAATG Itgb6 7669 GCACTTGTTGGAGCAGACTG Ccm21 11489 J CGCCCA GGACCCTCACCAA A I15ra 3850 GTCATTCAGCATGGGTTTCC Zbbx 7670 TTTGTTCCTCACTTACCAGC Gjb4 11490 CCCAATT CTGGGATGCTTGA Faml99x 3851 AAAGAAGCACCGCCCGCTAC Gatsl3 7671 GCGGGACTGGTTCTTGAAGT Focad AACAGTTACGTCAGATGTGG Fstl5 3852 GTTTAGGGAACTATAAAGAC Prss2 7672 GGTCGTACACCTCGGTGCCC Zfpl05 ACAGTAGrGrCAGATAGAAG Mllt3 3853 TGGTTAAAGTTGGCTTGCAA Adamts9 7673 GAGCGAATT CCC CGGAGAG Wdr77 GTGACAGGAGACTAGCCAGT Dctd 3854 TCCACCTGCTGTTCATCAGC Slc25a34 7674 AACATGGCCGCCGAGGAGGG Pigv GGAAACACGAGAGGACCGCG Sycel 3855 AGTCGCCGCGGCGCCGACGA Dabl 7675 TCCTTGGCTGGGTCCAGTGA Kndcl GGACCACGAGCTGAGATGGT Calr4 3856 TCTGAAAGGAATCCCAAGAG Pafah2 7676 CCCGTCTCGAGGCCGGAGGG Prkd3 TCACTTACCTCCTTCTCACT Gcm2 3857 ATTGTATTTGAATCGTGATC Lmo2 7677 TCCGCAGACTGACTCCTCAC Tenm3 GCTAATCTATGCTTTGATTC Gabip 3858 CTGAGGACTGCGTGGAGGAG F n 7678 CAGAGACTTGGAATCTTACT Commd7 CTTGCTCCCAGCAGAACTGG Dytn 3859 TATGTGGAGATATTGGTTCA ZbtbSa 7679 TGGTGTACAGCGACACCATG Pcdhal TCCCGGCCGCTrCAAACCGC Clic4 3860 ATGGTTTCATTTACATGTTG Skintl 7680 GTTGCCTCCACTGCTGTAGC Gm853 TCAGCTTGGTGATACGCTCT Nox3 3861 TGCTAATGCCTGCCAGAGGG Slc25a53 7681 CCCTAATTGGGCGGCCCGGA Wac CCAGCCTCTAGGAACTAGCG b 15 3862 GGCTGTTCTCTCTCGGTCAA Efcab7 7682 TTGCGTCCGGCTCTCAGCCA Them4 CTTCGAGTCTGAACCCGCCC Gjb3 3863 CTGTAAGTCCCACAGCAGAT Wdi64 7683 GGGCAGGAACCTGGGACACG Assl GTAAAGTAAACACACTCTGT Slc5a9 3864 GCACTTGTTGGAGCAGACTG Ccm21 7684 GCTGGGCAAAGACCAGCCAA iD a GGCTGGCrGCTTAGTGACAT Tspan33 3865 TGGAACAACCTGAGCCAGCC Jak3 7685 AGAAGCTGTATTCAGCTCCC Gal3stl GCATTTAATAAACTGCCTTT Sorcs3 3866 CAGACACCCTTAACAGCAAG Slc6a20b 7686 CTCCCACGGCTCGGCCGGAG Plpp4 GGCAATAACAGCTTCAGCAG Scn7a 3867 AGCGGCGGCGCGACGCCGGT Dicerl 7687 GTTGTTCTCTGAAATGGACC Plaa GCTCTCGGGAGCGATCAGCA Gabig3 3868 TTTGTTCCTCACTTACCAGC Gjb4 7688 CCGCCTCGACCGCGGGAGGG Btf314 AGATTGAATCTCCGAGTTTA Prex2 3869 GCGGGACTGGTTCTTGAAGT Focad 7689 GGGAGTCAGGAGAACTCTCC Bd211 TCGCTTGCACAGGACCCTTC Cachdl 3870 CCTATTATTCTCCATCTCTT Scn3a 7690 GAGATAGGTGCGGTTGTCTC Rnf215 CCCGCGTCGCCrGCCGTGGG Ifnlrl 3871 GGTCGTACACCTCGGTGCCC Zfpl05 7691 CCTCTGCCCTCACTTGATTC Xpo6 TAGGCTGGGCATCCTTGCAG Adam7 3872 AACATGGCCGCCGAGGAGGG Pigv 7692 GACTTCAATACTCGTTGTTT Lars TTCTGAGAAGGCCCGCCCTA Ckap21 3873 TCCTTGGCTGGGTCCAGTGA Kndcl 7693 GCCTCTCCACTGGCGAAGAG Rabl3 AAGGACACAAGTAGCCCGAG 1600015I10Rik 3874 ACTCTGGGACTCGTCCCTTG Kcnip3 7694 CCCAGTGAAGGGCCCATGGG Ddrl GAGATTTCCCAGGTGGTATC Speer4fl 3875 CCCAGTTATCCAAGGAAACC Shank2 7695 ATAATGGGCATTCAGACATA 1700008P02Rik GGCCCTCTCAGATCACATGC Trim63 3876 CAGTATATGCCAGAATACAT Klra2 7696 ATTTGAGAACAGACCCTAAG Gjb3 TTCCACCGGAAGTGCTCCCT Hjurp 3877 TCCGCAGACTGACTCCTCAC Tenm3 7697 GCTCATGGGAGGAGGGTCTC Gbp2 TTTCTCGAACAGTATATCAA Cyp2abl 3878 CAGAGACTTGGAATCTTACT Commd7 7698 GGCAGGCTGTAGGCGTCGAT Hdgf AAAGAAGCACCGCCCGCTAC Gatsl3 3879 TTCAGCCTTATGACTCAGTG 4930595M18Rik 7699 GGCAGGCGTGTGCATAGGCG Slco4al TGGTTAAAGrrGGCTTGCAA Adamts9 3880 TGTTATGAACTCGCGCTGGG Tgifl 7700 CGGAAGGATATACCCGCTTG ZbtbSos TCCACCTGCTGTTCATCAGC Slc25a34 388 1 GTTGCCTCCACTGCTGTAGC Gm853 7701 GGGACTGAATAACACAGAAG Nlixl AGTCGCCGCGGCGCCGACGA Dabl 3882 CCCTAATTGGGCGGCCCGGA Wac 7702 GGAAGTGTTGTTGACCGTAG Pefl TCTGAAAGGAATCCCAAGAG Pafah2 3883 GCTGAGCGAGAGGAACTATG Ubap2 7703 GCCATTGTGCGGTGCATTGT Plagl2 CTGAGGACTGCGTGGAGGAG Fine 3884 TGGGAGGCAGTATGACTTTG Slc45al 7704 AGATAGGTCAAACTCCACAT Fancc TATGTGGAGATATTGGTTCA Zbtb8a 3885 ACATGAAACTAATACGGAAA Dytn 7705 GAGAGAGAGAGAGAGAAGAG Grm4 ATGGTTTCATTTACATGTTG Skintl 3886 AGAAGCTGTATTCAGCTCCC Gal3stl 7706 AATCTTAACCGCGTTGCCAT Gpx3 TGCTAATGCCTGCCAGAGGG Slc25a53 3887 CTCTTTGAGACTTTATTGAC Folhl 7707 GTCCGACGGACTGTACTTTA Mcts2 GCGCAGGGAAGGATCCGTTT Cbx5 3888 TTGGACTCCGCTCCGCTGTT Cenpu 7708 GATGGCACCGGGACAGGGCT Bdnf GGCTGTTCTCTCTCGGTCAA Efcab7 3889 AGGGCTCGCTCTCGGCCCTC Arl4a 7709 ATATACTGGAATCATATGCA Etl4 GCACTTGTTGGAGCAGACTG C 21 3890 GTTGTTCTCTGAAATGGACC Plaa 7710 GCGTTGTATAAAGTCCCTAA Gml2886 TTTGTTCCTCACTTACCAGC Gjb4 3891 GGGAGTCAGGAGAACTCTCC Bcl21 1 77 GAACCAATGAACCTTCTTCC Themis3 GCGGGACTGGTTCTTGAAGT Focad 3892 GAGATAGGTGCGGTTGTCTC Rnf215 7712 CCGATTCGCTTCGAAACTTG Heatr5b GGTCGTACACCTCGGTGCCC Zfpl05 3893 GAGGCTGCTCACAGTGTGTA Dach2 7713 GTGCCTCTAGGCGGAAGTGC Ccm2 AACATGGCCGCCGAGGAGGG Pigv 3894 ATGTCAGCAGCAAGGTCACG Rapsn 7714 GTTGAGCAATTATAGGAGCT Timd2 TCCTTGGCTGGGTCCAGTGA Kndcl 3895 ATTTGAGAACAGACCCTAAG Gjb3 7715 CAGCATTGGATGAGCTAGCC Cyplal GGCTCGGCGGACGGCCAGGT Nkx2-4 3896 GAGTGCTGTCACTCAAGCCC Trappc 11 77 AGAACTGACAACTCATCTAC Cd52 CCCAGTTATCCAAGGAAACC Shank2 3897 AGGCTCTCGCGGGAGCCCGT Ssrl 7717 ACTGAGATACTGAATGAGAC Serpinb9c CAGTATATGCCAGAATACAT Klra2 3898 GTTTGTGTCACCACAGGGTC 8030411F24Rik 7718 GTCTTGGAGAGACCAACTCC H2-M10 6 TCCGCAGACTGACTCCTCAC Tenm3 3899 ACTCTGGCTTTGGAGAAGAC CGACCCTTTGTGATGTCACC Tnfrsf21 11539 CAGAGACTTGGAATCTTACT Commd7 3900 CGGAAGGATATACCCGCTTG GCGGCCGGTCGCAGAGCGCG Slc4a4 11540 TTCAGCCTTATGACTCAGTG 4930595M18Rik 3901 ACAAATGACAAATATCACCC CGTGGCCACCGGAATTACTT Pptl 11541 TGGAAGCGATCGCTCACTGA Cntnap5c 3902 GGAAGTGTTGTTGACCGTAG AAAGGTATTACGTAGTGTTC Ccr5 11542 TGTTATGAACTCGCGCTGGG Tgifl 3903 GCCATTGTGCGGTGCATTGT ACATGCGCACGGCGACCCGC Cc2dlb 11543 GGTAAAGGGTCGGAGTCACA Prex2 3904 AATCTTAACCGCGTTGCCAT ATAGGGTTCCACAATGGCCG Sfrp4 11544 CCCTAATTGGGCGGCCCGGA Wac 3905 GTCCGACGGACTGTACTTTA CGGAACACAACCCGCTTCTC Nude 11545 CTATACTCTCCAAGTTTCTC Lefl 3906 TGTGACCCTAGTGGTTGGCG GCACGCCGCTGCTGCTCAGC Tnfrsf22 11546 TGTATATCTCAGGGACAGTG Tmc5 3907 GCAGGGAGCGCGCGATCCCG CGCGACGCCGCAAGACCTGA Papola 11547 ACATGAAACTAATACG GAAA Dytn 3908 GTGCCTCTAGGCGGAAGTGC AGGACTGCTGATCCTCCTCA A d l 11548 AGAAGCTGTATTCAGCTCCC Gal3stl 3909 GTTGAGCAATTATAGGAGCT GGTCCTCCCTTAGACTCGAG Chmp4b 11549 TTGGACTCCGCTCCGCTGTT Cenpu 3910 GGAAGGCGCTCCGGATGCGG AGGTCTCACACTTGTGTCAT Neil3 11550 GTTGTTCTCTGAAATGGACC Plaa 3911 AGAACTGACAACTCATCTAC GGGCAGCCGACGTGTCAGGG Stk32c 11551 GGGAGTCAGGAGAACTCTCC Bcl211 3912 ACTGAGATACTGAATGAGAC CGCTTCCCGAAACGCTTTAG Tpral 11552 GAGATAGGTGCGGTTGTCTC Rnf215 3913 TTTAAATCGAGTTCCTGAGA ACGTCAGGCGGAAGTGCCTG Histlh4i 11553 ACTGAAAGTAAAGTAAACCA Gbp4 3914 TCAGGGTAGGTGAAGGGTGT TGCTGCATAGAGTTAAAGCC Dsel 11554 GAGGCTGCTCACAGTGTGTA Dach2 3915 CCGGCTCGGCGTCTCGCGAG GGGCTTGTAACCGAATCCAC Pla2g3 11555 ACTAACTTCCTTCCCTGCCC SlcoLcl 3916 GCGGTCCCTCAATGACGCAC TTACTGTGAGGGATTACCAA Snapc5 11556 ATTTGAGAACAGACCCTAAG Gjb3 3917 ATAGGGTTCCACAATGGCCG CTTTAACAAGGCGACCCGCC RasllOa 11557 TGACACTACCCAAAGTAATG Themis 3918 CGGAACACAACCCGCTTCTC GAGTTCCGGCCAGGACCTGG Adgra3 11558 GAGTGCTGTCACTCAAGCCC Trappcll 3919 GCACGCCGCTGCTGCTCAGC GTGGATTTATGATGACACAA Ccm2 11559 AGGCrCrCGCGGGAGCCCGT Ssrl 3920 AGGACTGCTGATCCTCCTCA AGCCGTCCAGCGCTCACCGC Ncmap 11560 GTTTGTGTCACCACAGGGTC 803041 lF24Rik 3921 GGTCCTCCCTTAGACTCGAG GTAGACGGGTCCCTTGCTTT Ermap 11561 TCTGTCCCTCCCACTGGCCC Lcat 3922 AGGTCTCACACTTGTGTCAT CTGCTCAGGGAAGAGGCGGT Mpi 11562 ACTCTGGCTTTGGAGAAGAC Tall 3923 GCCAGCATAGGTAGATAGGC GCTCAGGGCTCCCGCGTACC Csmd2 11563 GTGGCACAGACTGCACCATG Plbl 3924 GGGCAGCCGACGTGTCAGGG GGAGCTCCGCCCTGAGTCAT Bag3 11564 CGGAAGGATATACCCGCTTG Zbtb8os 3925 AAGCTGCTCAATGGTTGCCA GCACCGCGAAGGTTCTCCAC Cdh2 11565 ACAAATGACAAATATCACCC SkintS 3926 ACGTCAGGCGGAAGTGCCTG GGAACAGGGATTCTCCCTTG Secl414 11566 GGAAGTGTTGTTGACCGTAG Pefl 3927 TGCTGCATAGAGTTAAAGCC AAATAGGTCAGAGTTCCAAT Mtfpl 11567 GCCATTGTGCGGTGCATTGT Plagl2 3928 GGGCTTGTAACCGAATCCAC TGTGTTGGTACGGTAGCCTT Cep44 11568 AATGGAATGAGAAAGCGGAG Pgapl 3929 CTTTAACAAGGCGACCCGCC GCCTTGCCCTCAGACGGTAG Laptm5 11569 GCGCCGGGAGTCGGTGGGAC Mme 3930 ACAACGAAAGCAAGTCA GAG AAGGTGCAAGGTGACTACGT Ruscl 11570 AATCTTAACCGCGTTGCCAT Gpx3 3931 ACTGCTGACTTCCTGATCAC AGTGCAAGTGCGAGGTACCT Agol 11571 GTCCGACGGACTGTACTTTA Mcts2 3932 GAGTTCCGGCCAGGACCTGG TTATTTCATGTAGCTAGAGA Gp 8 11572 TGTGACCCTAGTGGTTGGCG Zfp956 3933 ATTCTGACCGCATCTCATTT GCTCCCGGCTGCTGGTTGAT Gtf2b 11573 GCAGGGAGCGCGCGATCCCG Mierl 3934 GTGGATTTATGATGACACAA ATCTGGTTCCTCCGCAGAAC Fezl 11574 GTGCCTCTAGGCGGAAGTGC Ccm2 3935 GGCTTGGGAATCGATTTCCC TGTTCCCGGCCTTGAGGATC Pdikll 11575 GTTGAGCAATrATAGGAGCT Timd2 3936 GTGCAAATCCGAGCA GTGGA GTGGGTACCCGGACCATTGA ZbtbSb 11576 GGAAGGCGCTCCGGATGCGG Zfp398 3937 AGCCGTCCAGCGCTCACCGC ACAATTTAAAGGCAGTCTAG Gr 6 11577 AGAACTGACAACTCATCTAC Cd 3938 CTCGGACAGTAAGCAAAGCC TAGGGATTGATAGGGTTGTG Tpx2 11578 ACTGAGATACTGAATGAGAC Serpinb9c 3939 GCTCAGGGCTCCCGCGTACC AAATGAGGACAAAGCCCGCC Hnmpab 11579 TTTAAATCGAGrrCCTGAGA Ofccl 3940 GGAACAGGGATTCTCCCTTG GGTCTGGCTTGGGATAGCTT Lrrc27 11580 TCAGGGTAGGTGAAGGGTGT Skint5 3941 AAATAGGTCAGAGTTCCAAT ACATGGGTGTGTCTGACCAG Prapl 11581 TCTAAATGACCTGTAACCAC Tmc5 3942 TGTGTTGGTACGGTAGCCTT GCTGCTTCGGGAGTGCGCTT 9530068E07Rik 11582 CCGGCTCGGCGTCTCGCGAG Slc25a4 3943 GCCTTGCCCTCAGACGGTAG GGCTGCAGAATAGATTCTCC S100a5 11583 GCGGTCCCTCAATGACGCAC Emihii2 3944 GAATAGCTAGGCTTACAGTT GACAGATGCACCAAGAGGTG Klral 11584 TGACTCGTCCTTTGGGTGCT Lefl 3945 AGTGCAAGTGCGAGGTACCT AAGAACATCTAAATGACCCG Dsglc 11585 CTACCCAGGGAGAAAGACAC K nj l 3946 CCAGTTGTGCAGTGTTCACG CCTGACGGTGCCAGGGTTGG Duspl5 11586 ATAGGGTTCCACAATGGCCG Sfip4 3947 TGTTCCCGGCCTTGAGGATC Pdikll 7767 CGGCAATCCTGGCrrCGCAG Cepl26 11587 CGGAACACAACCCGCTTCTC Nude 3948 CGGCACGGCGGCACGGCTTC C130060K24Rik 7768 TGCGAGGTCCTAGACATCCT Smtn 11588 GCACGCCGCTGCTGCTCAGC Tnfrsf22 3949 GTGGGTACCCGGACCATTGA Zbtb8b 7769 TTTGGAAATCTTTGAGAACr Clqtnf7 11589 o AGGACTGCTGATCCTCCTCA Ahdcl 3950 ACAATTTAAAGGCAGTCTAG Grm6 7770 CGGAGACAGTAAAGATTAAG Nr2e3 11590 CGTGTGCGAGCTGTCAACCA Nktr 3951 TAGGGATTGATAGGGTTGTG Tpx2 7771 GAGGTTCTGTGCAGTGCGGG Islr 11591 GGTCCTCCCTTAGACTCGAG Chmp4b 3952 AAATGAGGACAAAGCCCGCC Hnmpab 7772 GCACGCGACCCTAAGCTCGC Zcchcll 11592 5 AGGTCTCACACrTGTGTCAT Neil3 3953 GGTCTGGCTTGGGATAGCTT Lrrc27 7773 GAGAGAGAGAGAGAAC GTC Traem202 11593 o GGGCGAGGCGCCTCACGCGC Dnah 3954 ACATGGGTGTGTCTGACCAG Prapl 7774 CTGCTGGAGATAAACGCTTG Glra3 11594 4 GGGCAGCCGACGTGTCAGGG Stk32c 3955 GCTGCTTCGGGAGTGCGCTT 9530068E07Rik 7775 CTGTACCTACATCAGGTATC Cyplal 11595 TGCTGCATAGAGTTAAAGCC Dsel 3956 GACAGATGCACCAAGAGGTG Klial 7776 GACCAATCGGTGTGCGCGCG Pdlim4 11596 GGGCTTGTAACCGAATCCAC Pla2g3 3957 CGCTGACCAATGGGATCGCG Arl4a 7777 TATCCCTGATCGCCTTGCAC Bdnf 11597 CTTTAACAAGGCGACCCGCC RasllOa 3958 GTTCCGGGAAACACCGCCTG Ap4el 7778 ATACTGCAGCAACCTGTTGC Rabl2 11598 ACTGCTGACrrCCTGATCAC Mgatl 3959 CCTGACGGTGCCAGGGTTGG Duspl5 7779 AGCATGTGGCAACGTCACAG Smiml2 11599 GAGTTCCGGCCAGGACCTGG Adgra3 3960 TGCGAGGTCCTAGACATCCT Smtn 7780 CTTCTTCCAAGTGATTATAT Gm4858 11600 GTGGATTTATGATGACACAA C m2 3961 TCTTCCTCTCGCAGCGGCGC Lrp6 7781 AGGCATGAGATCCAACTGTA Arhgap26 11601 TCTCCAATCAGCTGTATTCC GmlH37 3962 CTCAAGTCCGGTTGTCGGCC Cfap61 7782 CTTTGCTCTCGCCGCTGCCA Sfrp4 11602 AGGCTGTGTTGCAATCGCTG Abcc3 3963 AGGCAGGAGGCAAACCTGTA Scn3a 7783 CTGGAATGAGCCACCAGAGT Csf2 11603 GTGCAAATCCGAGCAGTGGA Pde4b 3964 GCGCGACAATCTAGCGCACC Ap3bl 7784 GGGCGACTTCTGCAATCAAG Pkhdlll 11604 AGCCGTCCAGCGCTCACCGC N ap 3965 CTGCTGGAGATAAACGCTTG Gl 3 7785 TGAGCATCCCGAGCCGAGCC J y 11605 AAATCTAGGGTGGGCAGATG Mpped2 3966 TCTGGATACTTAGAGGGCTG Morf411 7786 TTCCAAGCGGTGCAACGAGC Man2cl 11606 CTCGGACAGTAAGCAAAGCC Pde4b 3967 CCGGCGGCGCAGTAGGGACG Glis3 7787 TCATAAATATGCGCCCGCCA Eprs 11607 GCTCAGGGCrCCCGCGTACC Csmd2 3968 GACCAATCGGTGTGCGCGCG Pdlim4 7788 AGGAGTTAAAGGACCGGGAT Nprl 11608 GGAACAGGGATTCTCCCTTG Secl414 3969 AGCATGTGGCAACGTCACAG Smiml2 7789 GTGTGGGCCGTGATTGTCCC Pfn2 11609 AAATAGGTCAGAGTTCCAAT Mtfpl 3970 GCTGCAGTAATAGCAAACTG Ttl 7790 GAGCAGAGTCCGCACCACCT Neil3 11610 TGTGTTGGTACGGTAGCCTT Cep44 3971 CTTTGCTCTCGCCGCTGCCA Sfrp4 7791 GATGAGGATAAGAAGGGCAT Serinc2 11611 GCCTTGCCCTCAGACGGTAG Laptm5 3972 AACCAATTACAGTCTCCCTC Ttf2 7792 CCTGCTGTGTTGACCTCAAG Helz2 11612 GAATAGCTAGGCTTACAGTT Zfp831 3973 CTGGAATGAGCCACCAGAGT Cs 2 7793 TAATCAGTTGCTCAGAAAGA Rxfpl 11613 AGTGCAAGTGCGA GGTACCT Agol 3974 GGGCGACTTCTGCAATCAAG Pkhdlll 7794 GCGCTCGGTCCTTGACGACG Gtf2b 11614 CCAGTTGTGCAGTGTTCACG Mgatl 3975 CCTAGAGTTTCAACACCAGG Foxd2 7795 TTAAGGAGATTATGAGAAGA Fcrl5 11615 TGTTCCCGGCCTTGAGGATC Pdikll 3976 AGCTTTCACAGCAGATTATG Rin2 7796 CTGTCTGAAACATAACAGCA Parvg 11616 GTGGGTACCCGGACCATTGA Zbtb8b 3977 GAGCAGAGTCCGCACCACCT Neil3 7797 TCGTCAATCCCACGCACATA Tcergl 11617 ACAATTTAAAGGCAGTCTAG Grm6 3978 GATGAGGATAAGAAGGGCAT Serinc2 7798 CAGGCACCCTTAGCCAACCC Proml 11618 TAGGGATTGATAGGGTTGTG Tps2 3979 CGTCAGGATGTAGGTAGTCT Pah 7799 GTTGGCTTTCCCTCTGCAGG Adgrfl 11619 AAATGAGGACAAAGCCCGCC Hnmpab 3980 CCCTGGTTCCCATTGGTCGG Edfl 7800 AGGAAGCACCAACTCTGAAG Tnfaip812 11620 GGTCTGGCTTGGGATAGCTT Lrrc27 3981 CACCCACTGTGCCCTATAAT Spinkl 7801 TGAGCTCACAATCCCGGCCG Sox30 11621 ACATGGGTGTGTCTGACCAG Prapl 3982 CACCATGTGTTTACACTGAT Lpin2 7802 TGGTTTATGGAATATCTGAT Ryr3 11622 GCTGCTTCGGGAGTGCGCTT 9530068E07Rik 3983 GTAGAGGCGGCCACTTCGTA Epha7 7803 AAGGAGCTGGATAGATCAAC Trpm5 11623 GTAGTTTACAGGCCATCGCC Nudtl2 3984 CTCAGGTAGGCCATCCGCGT Pik3c2a 7804 AGGCAGAGACGACCGGCGCT Pxk 11624 GACAGATGCACCAAGAGGTG Kl 3985 AGAGAAATATTAATCCAGGC SlcBal 7805 CAGCAATCGTCCCTTTAAAT Histlh4c 11625 n CCTGACGGTGCCAGGGTTGG Duspl5 3986 GTTACGTCATACCACCACCG Xrn2 7806 TAACTGTCCAATTAGGAACG Zfp941 11626 TGCGAGGTCCTAGACATCCT Smtn 3987 GGTGAGGTCAGTCACACAAC Mroh2b 7807 TGGCCTAAGCCAAAGAACAG Lmanll 11627 AAACTTAAAGCACGACTCCT Rnpc3 3988 GTTGTATAATTTGATATCCC Cfap97 7808 GGGCGGAAACTCTCGGGCCC Hnmpll 11628 CTCAAGTCCGGTTGTCGGCC Cfap61 3989 GAGACACAGCATTGCTCTCC Fut9 7809 ACTATTCTATGCACAGAACT Ubd 11629 o CTGCTGGAGATAAACGCTTG Gl 3 3990 ATGGAGCTCCCGCGGCCGAG Sstr4 7810 CCAAATTAACCCATTATTGT Zkscan4 11630 GACCAArCGGTGTGCGCGCG Pdlim4 3991 CCCTGCGAGCCAGGCACGCG Ncam2 7811 AGTGTGTCATTACACAGAAC Havcr2 11631 b AGCATGTGGCAACGTCACAG Smiml2 3992 GGAGCGGTGCTTCCACCGCC Sirpa 7812 AGCTCATCACTGAGATGCGA Coro2b 11632 GCTGCAGTAATAGCAAACTG Ttl 3993 GGTGGTGGACTTGATCAAGA Cstal 7813 GGATTCTCAGAAGTGGGTGG Limk2 11633 J AGGCCGAGAGAAGGGCTTCG GmlllO 3994 CCCTCCTGTCGCACAGGTCG Acsll 7814 GGGACGCGGGTAAGGTTGGG Dsc3 11634 CTTTGCTCTCGCCGCTGCCA Sfip4 3995 AGGGCGCAGTTGGGCGCTCC Robol 7815 CATCAGAGATCATTGGGCTA Fuom 11635 AACCAATTACAGTCTCCCTC Ttf2 3996 CCATGAACGTTAACAGTCTG Spata4 7816 TTACAGCCCGGCTCTGTGAT Ttn 11636 CTGGAATGAGCCACCAGAGT Csf2 3997 CGTCTGTGAATGTATCAGTT Skint3 7817 AAATAAAGCCTTGATAATCC Olfrl507 11637 o GGGCGACT GCAATCAAG Pkhdlll 3998 AAGGAGCTGGATAGATCAAC Trpm5 7818 GAGGAGCAGGCACGTGGTTC Cplx3 11638 GCGTGGCCACCGAAGAGGCG Kifl6b 3999 CAGCAATCGTCCCTTTAAAT Histlh4c 7819 ACGGAAACTAGGCGGAACGC Cepl26 11639 AGCTTTCACAGCAGATTATG Rin2 4000 TAACTGTCCAATTAGGAACG Zfp941 7820 TCAATATTAAGCCTTAGCTA Crisp4 11640 GGGAGTGGCGCCCACGGATC Wwcl 4001 TGTAGCTGCCTCTTGTCCCA Chll 7821 CGCAGCAGGTGAGATGAAGG Rn 11641 o GAGCAGAGTCCGCACCACCT Neil3 4002 CTCTGACGTCAGAGGCCTTA Cln8 7822 TGCGCACTGGCGCCGGCGTG Hintl 11642 4 GATGAGGATAAGAAGGGCAT Serinc2 4003 CCAAATTAACCCATTATTGT Zkscan4 7823 GAGAGAGGCGCGGAATCAAA Gtf2h4 11643 CACCCACTGTGCCCTATAAT Spinkl 4004 AGTGTGTCATTACACAGAAC Havcr2 7824 TCTTGCGCGCTCAAGTAGAA Scaper 11644 CACCATGTGTTTACACTGAT Lpin2 4005 GGATTCTCAGAAGTGGGTGG Limk2 7825 TGCACTGA GTTAGGCAAAGC Arhgef38 11645 GTAGAGGCGGCCACTTCGTA Epha7 4006 CTTCCTCTAAGTAGCATGTT Ugtlal 7826 GTGAAGCCTAGCTTTCTGCC Ccnjl 11646 AGAGAAATATTAATCCAGGC Slcl3al 4007 GGGTCTTGAGTTCAAGAGAT Ubxnll 7827 AATCTTTAAACTAGAGCAGG Tmeml44 11647 GGCGGCCGGCGGCGATATGC Rock2 4008 CATCAGAGATCATTGGGCTA Fuom 7828 TGAATATTTCAGCGTATATG Rapgef2 11648 GTTACGTCATACCACCACCG Xrn2 4009 TTACAGCCCGGCTCTGTGAT Ttn 7829 GTCACTTCCGCCCACCGGAG 1110008F13Rik 11649 GTTGTATAATTTGATATCCC Cfap97 4010 AGATCATGTGAGTGTAGGCA Lcelal 7830 AGGAAACAATGTAGCCGGCG Csk 11650 CGCTTTGCTGAGCTAGGCTA Wtl 4011 TGCGCACTGGCGCCGGCGTG Hintl 7831 CCAATGTGGTTCTCTAACGC Tmem63a 11651 GCTTATTGTTGGGCAGTGTA Dnah5 4012 ATCTCCAGTAGCGCTCTGAC Nr2el 7832 GGACGAACGCATTGCCAACC Blocls2 11652 CCCTGCGAGCCAGGCACGCG Ncam2 4013 GTGAAGCCTAGCTTTCTGCC Ccnjl 7833 GTCTACGTCAGAAGTCCGCG Kifl5 11653 GGAGCGGTGCTTCCACCGCC Sirpa 4014 GTCACTTCCGCCCACCGGAG 1110008F13Rik 7834 ACGTTGGGTTTCAGCGTCCC Gpi 8 11654 CCCTCCTGTCGCACAGGTCG Acsll 4015 GGAGGAGAGCAATGTGTGTA Zfp467 7835 GGGTCATACCCAAGTTAGAT Urocl 11655 AGGGCGCAGTTGGGCGCTCC Robol 4016 AGGCCACGTCGACGGTGGCG Ssrl 7836 CCCAGCCCGGTGGACGGGAG Cgn 11656 CCATGAACGTTAACAGTCTG Spata4 4017 GTCTACGTCAGAAGTCCGCG Kifl5 7837 TTCCAGCAGCTGCGTTTGCC Dec 11657 TGGTTTATGGAATATCTGAT Ryr3 4018 CCCTTCCAGAAGCTGGGCGC Pax7 7838 TGGCTGACTGATGTCCGCGG Azin2 11658 CGTCTGTGAATGTATCAGTT Skint3 4019 GACGGAAGTCGCCAGGCTTC Trmt6 7839 GCAGGGCGCGTTGAAACTTT UqcrlO 11659 TTCCTCTCCTCTTGCTTTAA Grik2 4020 GAACACCCGCACACAACAAG Cacnale 7840 GGGCCTCTGGCAGCTGACAA Slco4al 11660 AAGGAGCTGGATAGATCAAC Trpm5 4021 GAACTGAATGTCGCTCATTT CedcS5a 7841 GGTTGCTCTCGCGGCGCGCC Kcnn2 11661 CAGCAATCGTCCCTTTAAAT HistlMc 4022 TTCCAGCAGCTGCGTTTGCC Dee 7842 GGAGGGATGGAGGTTGAAGG Skorl 11662 TAACTGTCCAATTAGGAACG Zfp941 4023 TGGCTGACTGATGTCCGCGG Azin2 7843 ATCGGAATCTTCAACTTCTT Rpap2 11663 GTCGAAATCGAAATTGAAAT Zbpl 4024 GCAGGGCGCGTTGAAACTTT UqcrlO 7844 TCAATCCTTCAGTACTCCGC Stra6 11664 CCAAATTAACCCATTATTGT Zkscan4 4025 CCCGCACCGCCTCCGTTGAG Rnfl45 7845 CAGGCACAGCAGGCGTGGAG Th 11665 CGCTGGTCCCGCCACTACGC Cbx5 4026 GGTTGCTCTCGCGGCGCGCC Kcnn2 7846 ACAGCTGCTACGGCCGAGGG Epha6 11666 AGTGTGTCATTACACAGAAC Havcr2 4027 CATATATTACTTTAGCGGCT Lrrt l 7847 GGCTGCGGCAGATGAAATAT Stmn3 11667 GGATTCTCAGAAGTGGGTGG Limk2 4028 AGTCCAAATGAGTGCTTCTA Vwde 7848 CGAATGCTAATGAGCTGAAA 2410141K09Rik 11668 GGGTCTTGAGTTCAAGAGAT Ubxnll 4029 CAGGCACAGCAGGCGTGGAG T 7849 GAGAGGGACGAGACGCTGCA Glrb 11669 CATCAGAGATCATTGGGCTA Fuom 4030 ACAGCTGCTACGGCCGAGGG Epha6 7850 CCTGGGTCCTCCCGTGCCGA 17000 17B05Rik 11670 TTACAGCCCGGCTCTGTGAT Ttn 4031 CGAATGCTAATGAGCTGAAA 2410141K09Rik 78 AAAGGATGTAAACTTTACAG Cnr2 11671 TGCGCACTGGCGCCGGCGTG Hintl 4032 AAAGGATGTAAACTTTACAG Cnr2 7852 GCCTGCGTCCGGACGGCAGC Arihl 11672 GACAGGGCGGGACTCCCTTC Ndc80 4033 GCTCCGGAGCCCAAACCTGT Prom2 7853 TCAGGCAGACGTTTCCAGTC Pcdhgal 11673 n GTGAACCTTAGAGAGTCCGC Fam227a 4034 TGTCAGGAAGTGGACAGGGT Pafah2 7854 GCTGAAGATGGGCCACGCCC Tuftl 11674 GTCACTTCCGCCCACCGGAG 1110008F13Rik 4035 CTTTCATTTACTGCAGAGCA Seipinb9c 7855 TGTCAGGAAGTGGACAGGGT Pafah2 11675 GTTGTCAACTTGACATATCT Cobl 4036 TAGCATTGCTTATAAATTGC Mierl 7856 CTTTCATTTACTGCAGAGCA Seipinb9c 11676 n GGAGGAGAGCAATGTGTGTA Zfp467 4037 GCAGACGCGAGTTTGAGCCG Rpl36a 7857 ACTGAACGCGGCTGGACGCC PpplrlS 11677 o AGGCCACGTCGACGGTGGCG Ssrl 4038 CTACGAACCAGTCCGGAGCG Cyp2rl 7858 GCGGATGGATAGCGTCTTTG Txnrdl 11678 GTCTACGTCAGAAGTCCGCG Kifl5 4039 TTCAAACTGGAAAGCAG AAA Mumlll 7859 CACGTCGCTCAGGGCTTAGA Pdlim5 11679 b CCCTTCCAGAAGCTGGGCGC Pax7 4040 GTCGGGACGTGTGCTTCACT Pttgl 7860 TACAAACTTCTGCTCCTCTA Arhgdib 11680 GACGGAAGTCGCCAGGCTTC Trmt6 4041 AAGGGTTCCTGAGACAGCCA Synel 7861 GTCGGGACGTGTGCTTCACT Pttgl 11681 J GAACTGAATGTCGCTCATTT Ccdc85a 4042 ACGAGCCCAGCGAGCGATAA Wnt2 7862 TTCGCTGGGAAGAACTAGGC Ilf2 11682 TTCCAGCAGCTGCGTTTGCC Dec 4043 TTGCACTGAACGAGGGCCGC Nf2 7863 AAGGGTTCCTGAGACAGCCA Synel 11683 TGGCTGACTGATGTCCGCGG Azin2 4044 TTCGCGGATCCACAGTAGGG Sdc3 7864 TTGCACTGAACGAGGGCCGC Nf2 11684 GCAGGGCGCGTTGAAACTTT UqcrlO 4045 CCAACCTGGTGCCACAATAT Plin2 7865 TAAAGACCACGCCGCGGCCG Phlda2 11685 o CCCGCACCGCCTCCGTTGAG Rnfl45 4046 CAGGGAAAGACTCCACGCAA Dec 7866 TTCGCGGATCCACAGTAGGG Sdc3 11686 GGTTGCTCTCGCGGCGCGCC Kcnn2 4047 CGTGGGTGTGCAAGGGTGCA Caly 7867 GACATGAACCAGCTTTGTTT Gbp3 11687 ACCCGTTAGGAGCTGT ACAC SatbL 4048 GTCTGTCCGGTTGCGCCGAG Efcab7 7868 CCAACCTGGTGCCACAATAT Plin2 11688 5 CATATATTACTTTAGCGGCT Lrrtml 4049 TTAGACTGGAAGTGGTGTGC Sema4a 7869 CAGGGAAAGACTCCACGCAA Dec 11689 o AGTCCAAATGAGTGCTTCTA Vwde 4050 TGGCGGTGTCCGCTGCTGCC Rnfl45 7870 CGTGGGTGTGCAAGGGTGCA Caly 11690 4 TTACTAAACAAACTGAATCG Hnf4g 4051 GCGCGGGACTAGACACAAAG Jam2 7871 GCGCGGCGGGTAGCGCTCCC Psmg2 11691 CAGGCACAGCAGGCGTGGAG Th 4052 TGCAGTATGGTGTGTGTGTT Tgtp2 7872 GCGCGGGACTAGACACAAAG Jam2 11692 CGAATGCTAATGAGCTGAAA 2 1014lK09Rik 4053 CATCTATCGATCATAGTGCA Pgm2 7873 TCGCAGGCTCAGATAGCGCG Tdrd6 11693 AAAGGATGTAAACTTTACAG Cnr2 4054 CTTCCCACACGCGCCCTGCC Met 7874 TGCAGTATG GTGTGTGTGTT Tgtp2 11694 GCTCCGGAGCCCAAACCTGT Prom2 4055 TCAAGGACCAATCGTACCCG Pena 7875 GCTCTCCATCAGTCGTTCCG Dst 11695 TGTCAGGAAGTGGACAGGGT Pafah2 4056 CCCGGCGCCAACTGTGGAGG As 2 7876 CCCGGCGCCAACTGTGGAGG Ascc2 11696 CTTTCATTTACTGCAGAGCA Serpinb9c 4057 GGGCAGCGAGCGAATCCGAT Anxa6 7877 GGGCAGCGAGCGAATCCGAT Anxa6 11697 TAGCATTGCTTATAAATTGC Mierl 4058 ACAGCTTTCAGTGTGAGTTG Runxltl 7878 AAAGTGCTGGTATGTGGAAC Etl4 11698 GCAGACGCGAGTTTGAGCCG Rpl36a 4059 GGGCGCGGCATGCACTGCTT Sgce 7879 TCAAGCTCAGTGCTCTTAAC Etl4 11699 CTAGGGCGAGTTACGGATGG Kcnkl5 4060 GAAGAGGATGCCGAGAGCAC Gabib2 7880 GCCCGCAGACTCCTTATTTG Pdgfc 11700 AGTCAGTGGGTGTGTGTCTG Col5a2 4061 GGCGGAGCCCTATGGACTCC Impdhl 7881 AGGTTTGACCCGGGCTGCCT Dmbxl 11701 GTCGGGACGTGTGCTTCACT Pttgl 4062 CCCATCTCACGCCCACGGCG Gccl 7882 CCAGTTCACAGGGCTCCCAA leal 11702 GGCGGGACTTCCTCGCCGCA Rpe 4063 CCAGTTCACAGGGCTCCCAA leal 7883 TGTCACTTCCTTGGTCTGTG Map9 11703 AAGGGTTCCrGAGACAGCCA Sy el 4064 GAAGCCACAAATGCTTGCAG Prokr2 7884 CGGTCCTGAAATGCTGTCCT Dst 11704 ACGAGCCCAGCGAGCGATAA Wnt2 4065 TCAAAGTCGCGGAAGCCAAT Ckap21 7885 AGCTGATGCTTGACCAGCTC 1700008P02Rik 11705 TTACCCTGAAAGTTAGCTAC Gml6432 4066 GTAGTTGAGAACTTCAGCCC Tmeml76a 7886 TATAGCTCGCGGGCTTAGGC Napll4 11706 TTGCACTGAACGAGGGCCGC Nf2 4067 TATAGCTCGCGGGCTTAGGC Napll4 7887 CCCGCGGCACTGACCGTCGG Mapklipl 11707 GCTGTTTGTCACTTTCAATG Pdyn 4068 CCCGCGGCACTGACCGTCGG Mapklipl 7888 GCAACATGGCAGCTTCTACC Lypla2 11708 TTCAAACCAAGATCCAGATA Prex2 4069 AGCTGTACTGAAATGTCAGA Lmod3 7889 TTATAGTATCCTGGGAACCA L3mbtll 11709 TAAAGACCACGCCGCGGCCG Phlda2 4070 CCCAAACCCAGAGAAGAGCA Myoml 7890 CAAACGTTAAAGGCCTCAAC Ktil2 11710 TTCGCGGATCCACAGTAGGG Sdc3 4071 GCAACATGGCAGCTTCTACC Lypla2 7891 AATGCTATGGCAACAGTTTC Lamp5 11711 CCAACCTGGTGCCACAATAT Plin2 4072 TTATAGTATCCTGGGAACCA L3mbtll 7892 CTGCACGAAATGCTTCTCTT Cdl6311 11712 CAGGGAAAGACTCCACGCAA Dec 4073 TGGACTGATCGCTCAGGCAA Nkx2-2 7893 TGAGTAGGCAGATGTGACAC Cdsn 11713 CGTGGGTGTGCAAGGGTGCA Caly 4074 TACGCAGTTCACTGGGCTGT Sntgl 7894 GTGCGGAGCTGTGTCTCGGG Efna5 11714 GTCTGTCCGGTTGCGCCGAG Efcab7 4075 CTGCACGAAATGCTTCTCTT Cdl6311 7895 ACGCTGCCACCTACAGCGTC Lypla2 11715 GTGCCGCTGTCGCCGAGCGT Gjd2 4076 CACTTCCTCCGCCCACGAGC Aszl 7896 AAGCAGTATACTCAAATCTG Histlh4b 11716 TGGCGGTGTCCGCTGCTGCC Rnfl45 4077 GGAGAGATCTACCAAAGCAG Rapgefll 7897 TTCATCCCGCCTGGGATCTG Echsl 11717 GCTTTCACTATGCACATTTC Phflld 4078 GCAGCCTTACCTGAGTACTT C8b 7898 GCTGGCGCGGGCAGGAGGAG Tcergll 11718 GCGCGGGACTAGACACAAAG Jam2 4079 ACGCTGCCACCTACAGCGTC Lypla2 7899 AGCGCCGGCGATGATTCAAA Lbr 11719 TGCAGTATGGrGTGTGTGTT Tgtp2 4080 AAGCAGTATACTCAAATCTG Histlh4b 7900 CGGGCGTCAGCTTGGAGCTG Erailin3 11720 CATCTATCGATCATAGTGCA Pgm2 4081 TTCATCCCGCCTGGGATCTG Echsl 7901 ATGCTGGAGTTTGGTCAATG Gpatch3 11721 n CTTCCCACACGCGCCCTGCC Met 4082 GCTGGCGCGGGCAGGAGGAG Tcergll 7902 ACTGGCTGTACCTGGTGGGA Lamp5 11722 AATCTTAAAGACTGGGAGCC Btafl 4083 AAAGGTGACGTGTGGTCCAA Caapl 7903 AAACTGTCAAGCCAGCGCCT Hpgd 11723 TCAAGGACCAATCGTACCCG Pena 4084 CGGGCGTCAGCTTGGAGCTG Emilin3 7904 TAATTACGGCGTGATCCGAG Robo3 11724 n CCCGGCGCCAACTGTGGAGG Ascc2 4085 ATGCTGGAGTTTGGTCAATG Gpatch3 7905 TTCTCAATTAGCAATCAAGG Arhgap26 11725 o GGGCAGCGAGCGAATCCGAT Anxa6 4086 GGGAAAGGGAGAGTGAGAGG Cstll 7906 TATTGGCTGGCTCCTTTACA Ilf2 11726 5 GGGCTTGAAGCTCAGAATAA Plbl 4087 AAACTGTCAAGCCAGCGCCT Hpgd 7907 GGCTGTCCAGTACTTAACTC Cspg4 11727 b AAAGAGGAGGGAGGTACA CA 5330417C22Rik 4088 CTGGAGCTCCGCACCCG TTT S dl 7908 TGTCCACGCGTTACCTAATT Traem63a 11728 5© GAAGAGGATGCCGAGAGCAC Gab 2 4089 CATGGATGCTACATCCAGCA Lcelal 7909 ATCAAGCCTAGAGCAAAGCC Speer4e 11729 J GGCGGAGCCCTATGGACTCC Impdhl 4090 TCGCTCGGAACGCGTTCCGG Dabl 7910 AACTTCCAAAT CTCCTGTAA 49 1406P16Rik 11730 TTCCTAGGAAGCCGCGCCGA Vav3 4091 GTGGCTGTCTTCCACTTCTC Gimap5 7911 CCCAGCAACACCAATAAGCT Grm6 11731 CCCATCTCACGCCCACGGCG Gccl 4092 GCGATGCGTCATTTCCGTCC Mpz 7912 AGGTGTCATTCGGCACTGGG Traeml54 11732 AAGCAACTCGGCGTTCCCTG Cacnalb 4093 GGCTTTGATCTTGGGCGAGC Kmt2d 7913 CTCCACGCAAATTTGGACCG Bdnf 11733 o AGCTCAGGGAAGCGCAGCCC Tbpll 4094 CGGCGGCGGCTCGGCCTAAG Ssbp2 7914 TGGCTGCTTGAGTGGGCCAA Fga 11734 AGGGCACCGGAAGCTGCAGC Trpal 4095 CAGCTTGGAGTGGGTGCAGC Rapsn 7915 TTTCCAGCTTCAAGACTTTG Pcdhal 11735 CCAGTTCACAGGGCTCCCAA leal 4096 ATCAAGCCTAGAGCAAAGCC Speer4e 7916 AGGCGAGGATGGAGGAGGAG Tiaml 11736 5 GAAGCCACAAATGCTTGCAG Prokr2 4097 CCCAGCAACACCAATAAGCT Grm6 7917 GTGCTGCTCTGGGACTGAAC Phc2 11737 o TCAAAGTCGCGGAAGCCAAT Ckap21 4098 TCTCCGCGGACGAGACAGCG Aridla 7918 GTACTGGGTTCTTTAGCTCC Kndcl 11738 4 GTAGTTGAGAACTTCAGCCC Tmeml76a 4099 CAGGAAGGAGCAAGTCAGGG Alx4 7919 CTGTCATAAATGGGTGGGCA S100a7a 11739 TATAGCTCGCGGGCTTAGGC Napll4 4100 AGGCGAGGATGGAGGAGGAG Tiaml 7920 AGATGAAGAAAGAGGCAAGT Cfap57 11740 CCCGCGGCACTGACCGTCGG Mapklipl 4101 AAAGAGCAGAGTGAACCAAT Cds2 7921 GGCTGGGACCGCACCCAGGC Podn 11741 GCAACATGGCAGCTTCTACC Lypla2 4102 TTAAAGACACGCCCACGTCA Enppl 7922 GCCTTCTATTGGCCCAGTGA Aga 11742 TTGGAAGCrCGCTGATTGGC PcdhlS 4103 GTGCTGCTCTGGGACTGAAC P c2 7923 CGTGACGTCAGCCCAGAGAC Traeml44 11743 TTATAGTATCCTGGGAACCA L3mbtll 4104 GTACTGGGTTCTTTAGCTCC Kndcl 7924 TCCAGTTGGGATTAGCTCAT Arhgef2 11744 TGGACTGATCGCTCAGGCAA Nkx2-2 4105 CGGGCGGCCCGCGAGCTTGA Ddi2 7925 CAGCATCAGTACCTCACTTT Olfrl330 11745 TACGCAGTTCACTGGGCTGT Sntgl 4106 GCCTTCTATTGGCCCAGTGA Aga 7926 TATTTGGTAGTTTGATCTCA Prkd3 11746 CTGCACGAAATGCTTCTCTT Cdl6311 4107 CCCACGGTAGGAGGACGCAG Htrld 7927 GGTCTTTCAGCATCACCTCC Bmprlb 11747 ATCAAAGTTCAATCTAGCTT Slcola6 4108 AAAGCAGCCGGTCAGAGGTG Kazn 7928 CCCACGGTAGGAGGACGCAG Htrld 11748 CACTTCCTCCGCCCACGAGC Aszl 4109 GAGTTAATGAAGTACTAGGC Timd2 7929 GAATTGGCCCGCCGCGGCCC Bodll 11749 TAAAGTGGGACTTTCAGATC Slcolb2 4110 TGCCCGTGCCTGTCTTTAGG Myold 7930 GAGTTAATGAAGTACTAGGC Timd2 11750 GCAGCCTTACCTGAGTACTT C8b 4111 GAGCAAGCCTGTTGGGCACG Maprel 7931 GGCTGTGCTAGAGCATCTAA Nsun4 11751 GTGCGTCCGAAGGCGGAAGG Pisd 4112 GCTTCTAAAGGCTACTCCCT Tm2dl 7932 CAGATAAAGGTTCAAACCTG Tpm3 11752 ACGCTGCCACCTACAGCGTC Lypla2 4113 CTCAATTGAGAAGGTAGTTC Anapcl 7933 TTTGCTTCATGATGACCATG Tbxasl 11753 AAGCAGTATACTCAAATCTG Hist l b 4114 TGCGCGTGCGTCGCGCCGGA Ralgapa2 7934 GAGCAAGCCTGTTGGGCACG Maprel 11754 TTCATCCCGCCTGGGATCTG Ec sl 4115 CCAAGTGCGGTGAGCCGTTG Abcal5 7935 CTCAATTGAGAAGGTAGTTC Anapcl 11755 GCTGGCGCGGGCAGGAGGAG Tcergll 4116 CTAAAGCTGGTAGCAGTCAC Pccb 7936 ATCTTTGACTTCTAGCTTGG Nacad 11756 ATGCTGGAGTTTGGTCAATG GpatclG 4117 CCGGTGCACAGCAAGTGTCC Zbtbl7 7937 CATCCGGGCCAGGGATACTC Ahdcl 11757 GGGAAAGGGAGAGTGAGAGG Cstll 4118 ATCTTTGACTTCTAGCTTGG Nacad 7938 CTGTGAATGAGACTGGTCTC Meal 11758 AAACTGTCAAGCCAGCGCCT Hpgd 4119 GAATCTGGACACACCTCCTC Slc25a34 7939 AGAAGCGGGTATCACTGCGT Vars2 11759 CTGGAGCTCCGCACCCGTTT Sndl 4120 CATCCGGGCCAGGGATACTC Ahdcl 7940 GTCTGTACCGCTACTACTAA BmpSb 11760 TCGCTCGGAACGCGTTCCGG Dabl 4121 GAGAAGACGAAGACAGGGCC Aridla 7941 ATTACTATTGCTTTCTGGAA Vmnlrl91 11761 GTGGCTGTCTTCCACTTCTC Gimap5 4122 TGATTGAGATTATGTTCCAA Gab 6 7942 TTCAAGGAGCACCGTCTCTA MrpslO 11762 ATCAAGCCTAGAGCAAAGCC Speer4e 4123 GCAGGCAAGCACCTTCCAAC Cst8 7943 CCGCCCGCCTCATCAATCCC Zicl 11763 CCCAGCAACACCAATAAGCT Grm6 4124 ATTACTATTGCTTTCTGGAA Vmnlrl91 7944 GGCGAGGGAGAGGACGCCCT Urgcp 11764 TCTCCGCGGACGAGACAGCG Aridla 4125 GGCGAGGGAGAGGACGCCCT Urgcp 7945 TGGTTAGGTTACCACTAGCT Gnal 11765 AAA GAGCAGAGTGAACCAAT Cds2 4126 TCACACTTCTTCAAAGTGCT Bclllb 7946 CTGCTCTGCCAAAGTGCACC Oxct2b 11766 GTGCTGCTCTGGGACTGAAC Phc2 4127 TCCGTGCGCAGCACACAGAG Stk32c 7947 TCCGTGCGCAGCACACAGAG Stk32c 11767 GTACTGGGirCTTTAGCTCC Kndcl 4128 CTACATCGTTCATGGAGTGC Zdhlic3 7948 GGGCGCGGAGGGATACCGCC Pfn2 11768 CGGGCGGCCCGCGAGCTTGA Ddi2 4129 CGGAGGCTGGAACTCACCTG Urgcp 7949 GCTACTGCTGACAGCTGATT Cplx3 11769 n CTCTCCGCCGGTGCGGGTGT Fsdll 4130 TCAGCGTGGAATTCATGAAG Ccm2 7950 CTACATCGTTCATGGAGTGC Zdhhc3 11770 GCCTTCTATTGGCCCAGTGA Aga 4131 AGGACCGCATCTGGTGCGCC Mfhasl 7951 AGCGTCACAGACTCCCGCAT B3galt5 11771 GGTCTTTCAGCATCACCTCC Bmprlb 4132 CCCGTTGTTTA GATCTTGAC Mgatl 7952 CGGAGGCTGGAACTCACCTG Urgcp 11772 n CCCACGGTAGGAGGACGCAG Htrld 4133 GAGGTGCTAAGCAGACGTCC Slc32al 7953 TCAGCGTGGAATTCATGAAG Ccm2 11773 o AAAGCAGCCGGTCAGAGGTG Kazn 4134 CCTAATGTACGCTGTACAGG Fermtl 7954 GGCAAGTGCGCCTTGTTCTA Isg2012 11774 5 GAGTTAATGAAGTACTAGGC Timd2 4135 CGAAGTCTGGCGTCACGTCC Hspa4 7955 CCAGTTCAGGCTCAGTTTCC Ccdc33 11775 b AATGCAAACACAACTGTCAG Slc5al2 4136 GTCCTCCCATCTGAAGACCC Tspan32 7956 GAGGTGCTAAGCAGACGTCC Slc32al 11776 5© GAGCAAGCCTGTTGGGCACG Maprel 4137 CCTACCTTATTAACTTAGTG Dnah9 7957 GTCCTCCCATCTGAAGACCC Tspan32 11777 J GCTTCTAAAGGCTACTCCCT Tm2dl 4138 CCAGGCACCCGACCCTGCGT Smi l2 7958 CCTACCTTATTAACTTAGTG Dna 9 11778 TGCGCGTGCGTCGCGCCGGA Ralgapa2 4139 AGAGCTAGACTGCCACGTTG Alg6 7959 CCAGGCACCCGACCCTGCGT Smiml2 11779 CCAAGTGCGGTGAGCCGTTG Abcal5 4140 TTGGAGGCACCCTCCGGCTG Colla2 7960 GGCAGGCAGATCTAAGTGTG Tln2 11780 GCAGGCCATGTCAACTCACC Neb 4141 CTAGCTGGTCTAGGAGATCC Dfna5 7961 GTCGAGGAGCGGCTCCTTAA Fbxo8 11781 CCGGTGCACAGCAAGTGTCC Zbtbl7 4142 TAAGTGACACGTGACTGCCC Dnajcl6 7962 CCACTACAATGGCGTCGTAG Kcnq2 11782 ATAGGGTTACACCGCTGCTG Fndc3cl 4143 GTCGAGGAGCGGCTCCTTAA F xo 796 CCCTTGCACGATCTGTGGGC BC049762 11783 ATCTTTGACTTCTAGCTTGG Nacad 4144 CCCTTGCACGATCTGTGGGC BC049762 7964 GTGTGAAGGTAGGATGTGGC Dis31 11784 GAATCTGGACACACCTCCTC Slc25a34 4145 CGAGTTCACCTATAGTACAT Dpys 7965 TGGTCACCTCAATCCCTGCA Gml2888 11785 CATCCGGGCCAGGGATACTC Ahdcl 4146 GACTGTAGAGATTGACGTGG Paxl 7966 CCCAGTTATGGGTGGAGCTA Adpgk 11786 GAGAAGACGAAGACAGGGCC Aridla 4147 TGACAAGCTAGATCCCTTTC Hfe 7967 CGAGTTCACCTATAGTACAT Dpysl3 11787 TGATTGAGATTATGTTCCAA Gabia6 4148 AGCTGAACATAGCCCGGTTT Erbb4 7968 GGGAAAGTTAT AAAGAGAAC Arid3b 11788 CATGAAAGTGTCTGTTCAAG Enpp2 4149 TCTCTAGGCTCTAACCCGAG Tmeff2 7969 CACCCTTCTCAGGACGGTGG Calml4 11789 GCAGGCAAGCACCTTCCAAC Cst8 4150 GTCCTTATTGCGGGCCGCGC Gmebl 7970 GGCTCATAGGTTCTAGATGT Olfrl507 11790 ATTACTATTGCTTTCTGGAA Vmnlrl91 4151 TCTGGCCCTAGATATAGCAG Osbp2 7971 GCTTGACAGACCCACTGTGG Adgrf4 11791 GGCGAGGGAGAGGACGCCCT Urgcp 4152 GCACCTCGACTCTGGCGACC I pd l 7972 TGACAAGCTAGATCCCTTTC Hfe 11792 TCACACTTCTTCAAAGTGCT Bclllb 4153 AGTCAAAGGTCGGTAAATAG Bsdcl 7973 AGGGAGGAGGAATGAGAGAG Cln6 11793 TCCGTGCGCAGCACACAGAG Stk32c 4154 GCCGGCCTTCCTCCATGCCT Pldl 7974 GTCCTTATTGCGGGCCGCGC Gmebl 11794 TCTACACTGCGGGCTCCGAG Satbl 4155 TGTTGGGCCCGCCTCTCCTC Fuom 7975 CCCAGATAGGCTGAGTAATA Etl4 11795 CTACATCGTTCATGGAGTGC Zdhlic3 4156 GGAGAGAGAGAGAGGAGAGC Lrplb 7976 TCTGGCCCTAGATATAGCAG Osbp2 11796 CGGAGGCTGGAACTCACCTG Urgcp 4157 AGGTAGAGCGGTGACGCAGC Arhgefl6 7977 GGAGGGACGGAGACGCAGAC PpplrlS 11797 TCAGCGTGGAATTCATGAAG Ccm2 4158 AAGCAGAAAGAAGTTAATGC Hdac9 7978 CTTCGCTGTGGCTCTTATAG Lrat 11798 AGGACCGCATCTGGTGCGCC Mfliasl 4159 GTACGCGTGCGCACAGCGAA Smarca4 7979 AGTCAAAGGTCGGTAAATAG Bsdcl 11799 CCCGTTGTTTAGATCTTGAC Mgatl 4160 GGCACrGAGGCATTGTGTGC Spinkl4 7980 AAGTGACTGACTGGGTAGTC Urocl 11800 GAGGTGCTAAGCAGACGTCC Slc32al 4161 ACATTCCACTGAAGTCCCAC Dtna 7981 GCACCGACGCGCTCGCTCTG Dap3 11801 CCTAATGTACGCTGTACAGG Fermtl 4162 TTTCGGTTGTCTTTCTGCAG Pafah2 7982 GGTCCGTGCGCTTCCTTACC Svbp 11802 GTCCTCCCATCTGAAGACCC Tspan32 4163 ACTTGCGTCAGGTCGGCAGC 0610009B22Rik 7983 GAGGTGGGTGTGGACGGCTG Glt8d2 11803 GGAGGGAGGGACTTGGCAAA Etnppl 4164 CTCATGACTGTTACTCTCGC Pstpipl 7984 TACTGAGAATTGTTCCGTTG Hmg20a 11804 CCTACCTTATTAACTTAGTG Dnah9 4165 GCTCACATTGCTTATAGCTA Txnrdl 7985 TGTTGGGCCCGCCTCTCCTC Fuom 11805 CCAGGCACCCGACCCTGCGT Smiml2 4166 CAGTTACTCTGGCCCTAAAT Gm853 7986 GGAGAGAGAGAGAGGAGAGC Lrplb 11806 AGAGCTAGACTGCCACGTTG Alg6 4167 GCAGCAAAGAATTGAACGGA Zbbx 7987 ACAGCCAGCTGCTATTGGAG Tubb6 11807 CTAGCTGGTCTAGGAGATCC Dfna5 4168 ACGTT GTTAACCAAAT CAAA Slcl7a3 7988 GCTTTGAGTTGTCTAGTCCA Olfrl330 11808 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

SubLib GeneName SpacerSeq SEQ ID NO: SubLib GeneName SpacerSeq SEQ ID NO: B16F10 k CACGACCTTTCACCCTCAAT 11809 Hepal-6 Ap5 AGGAGCCGACCGAGCGCCCG 17793 B16F10 Ik ATTGGATGACGCAGGGAAAG 11810 Hepal-6 Ap5 CGAGTCGGCACCTGCCGGCC 17794 B16F10 Ik AAGACTGGAGGGCCCGCTAT 11811 Hepal-6 Ap5bl TTACTCAGACCTGGCGAAAC 17795 B16F10 Cyp2rl AGAGTCCGTTTGTAAACCTT 11812 Hepal-6 Sunl AGAAGAGACAGAAGAGGACC 17796 B16F10 Cyp2rl CGCCTTATCTCTACGGCCAT 11813 Hepal-6 Sunl GGGAGGCCGCTGACCCGCCA 17797 B16F10 Cyp2rl CTACGAACCAGTCCGGAGCG 11814 Hepal-6 Sunl AGCGGGCGCGCTGGGACTTG 17798 B16F10 Dlx5 TGGATCGGGTTCCATTGGCC 11815 Hepal-6 BC048644 GCTGTTGGTTCAGCTCGCAA 17799 B16F10 Dlx5 TTGCTCTGCTCCCGAAGCCC 11816 Hepal-6 BC048644 CAGACGCACTTCTCAGTACG 17800 B16F10 Dlx5 CGCAATTAAGGATTTAACCA 11817 Hepal-6 Parpbp CAGCACAAGCTGGCGATCCC 17801 B16F10 Zfp563 ATCCAATCAGAAGCGCCGAT 11818 Hepal-6 Parpbp TCGATACGCACCTAAAGCAG 17802 B16F10 Zfp563 GTGAAGCGGACGTTCCTCAC 11819 Hepal-6 Parpbp GTCGTGCCGCGAGATTTGAA 17803 B16F10 Zfp563 CTGTGCTCCGTGGTACTAAT 11820 Hepal-6 Gjc2 TTGTGCTTGGTGGCGAGAGG 17804 B16F10 Pclo GGAAGTGTCCGCAGTTCGCC 11821 Hepal-6 Gjc2 GGGAACAATGGAGCCCTTGA 17805 B16F10 Pclo ACGCCTAGACACCGACTTAA 11822 Hepal-6 Gjc2 GCAGGGTGCAGCATTCCTGA 17806 B16F10 Pclo TGGCGGACATCACCTGTTCG 11823 Hepal-6 Zfp97 GGCAGATCCCACAGGGAAAC 17807 B16F10 Nudt4 GCCCAAAGGAGGGAGCGCGC 11824 Hepal-6 Zfp97 AGCAACTCTCTCAGGTTGAG 17808 B16F10 Nudt4 GGGCGCGGCTTCGACCAGCC 11825 Hepal-6 Zfp97 ATGCTACTTGATGCTGTGAT 17809 B16F10 Nudt4 GGGCTCGAGGCCTAAGTCTA 11826 Hepal-6 Skint2 TCTGACATGTTTATGGCTTC 17810 B16F10 Efll AGTGTGCCAGCCTAAGCCTG 11827 Hepal-6 Skint2 CATGATTCTGCAAGCCTTAC 1781 1 B16F10 Efll ACGCTGGAGCGCAGAGCATG 11828 Hepal-6 Skint2 CTACTCCTAACCTGAAAGTC 17812 B16F10 Efll GCGCGCATCTAGAACATCAC 11829 Hepal-6 Gpr22 ACTGCTTCATATGTATGGCA 17813 B16F10 Llcam GGCCAGGTTCAGATGAAACA 11830 Hepal-6 Gpr22 GCAGTTTAAGCCAATACAAC 17814 B16F10 Llcam CGAGGTCCCTATCACGCGCG 11 1 Hepal-6 Gpr22 ATCCTTATATAAAGCCATTG 17815 B16F10 Llcam AACGAGGGTGTGGCGAGGCG 11832 Hepal-6 Caps2 GTATTTGCACCACCCAAACT 17816 B16F10 Ergic 1 AGCGGGAGTCTTGGAGACCT 11833 Hepal-6 Caps2 AATGCAATGGCTTCTTTCTA 17817 B16F10 Ergic 1 TTGGGTAGCATCCCACTCTC 11834 Hepal-6 Mroh2a CTCTGGTTGAGAGTGCCTTG 17818 B16F10 Ergic 1 GCGAGTGGCGAGTGTCGGGC 11835 Hepal-6 Mr 2a TCTCAAAGTTCCAAGGGTCT 17819 B16F10 Tmem67 TGCGTGGTAACCTAGCAACC 11836 Hepal-6 Mroh2a CAGAGGTGTGTGCTGATGTA 17820 B16F10 Tmem67 CGCTGAGCTGATTGGACAAC 11837 Hepal-6 Syn3 TTTCCCTCGCCAGCCAGGTA 17821 B16F10 Tmem67 AAACTCAACCTTGCGACGCC 11838 Hepal-6 Syn3 CCCTACGCCGGAGAGCCCAT 17822 B16F10 Dg TTGCTTTAAACGACCTTCTT 11839 Hepal-6 Syn3 CAAGCAAGCTTTGCTGTTGC 17823 B16F10 Dgkh GGCGCAGGGCTCAGACGTTC 11840 Hepal-6 Serpinalf CTAAATGACAAAGAGGGTGG 17824 B16F10 Dgkh GGGTAAAGCTTATTAGCAGT 11841 Hepal-6 Serpmalf GGCTATTGCAGCCTACCTCT 17825 B16F10 Naccl AAGTTGAGTGACTGCGGGAC 11842 Hepal-6 Serpinalf GCTTAGGTCACAGCAACACA 17826 B16F10 Naccl CGCGGCTAAGCTTGCCTAAG 11843 Hepal-6 Rufy4 CTTTCTCTACCACTTCTCCC 17827 B16F10 Naccl CGTCTACAGAACCGAGACCC 11844 Hepal-6 Rufy4 AGTGACTCAGCCCAGCCTGA 17828 B16F10 Klf6 ACATCATCGTCGCGCAGCCC 11845 Hepal-6 Rufy4 GGGCTGGACCAACCCTGGCC 17829 B16F10 Klf6 GCTCGCACCAATCGCCGGTG 11846 Hepal-6 Pigo CTCGCTGTCTGGCACCACAG 17830 B16F10 Klf6 TTCATTAAAGGCCTCCTTAT 11847 Hepal-6 Pigo GCAGGCGGCGACAAATCTCC 1783 1 B16F10 Csgalnactl GGCCTCCGAGTGGGAGCCCG 11848 Hepal-6 Pigo GCCTGACAGAGCGCCCTACC 17832 B16F10 Csgalnactl TGCAGTCATCTAATTCCTCC 11849 Hepal-6 Rrh AATGGACAGTCTTTGTGAAA 17833 B16F10 Csgalnactl ACAGCGGCCAAGCACAGCGC 11850 Hepal-6 Rrh CAGCCCTCAGCAATGGTGAT 17834 B16F10 Hnmpm CCGATGTCCGCAGATACAGT 11851 Hepal-6 Rrh CGCTTGTAGACCTCAAAGAA 17835 B16F10 Hnmpm TTACAATACGAGCGCACATA 11852 Hepal-6 Ppp6rl CACCTTAAGGCCTCCGACGC 17836 B16F10 Hnmpm ACGCCTCCTTGTGCGGCGAC 11853 Hepal-6 Ppp6rl GCCGCTAGGTCGGCCTGGCG 17837 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 AdgrU GCCACGTCCGTCCGGCAGCC 11854 Hepal-6 Ppp6rl GCATTGTGGGACAGTGGCGG 17838 B16F10 AdgrU GTCCCATCTGTAATCTGACA 11855 Hepal-6 Slc35al CTCTAACGGTCTTCACACAA 17839 B16F10 AdgrU TCCAGGCTGTTTGGGTGAAG 11856 Hepal-6 Slc35al TATAACTTTCAACTCCATCA 17840 o B16F10 cn 8 CAGCAGAAGGAGCTACTCCC 11857 Hepal-6 Slc35al ATTTCAGAATCCTTCTTGCG 17841 B16F10 Kcn S CTGGTCACAGTGCAGCGGCC 11858 Hepal-6 Npffr2 ATTCATGTCACGGAGACTAG 17842 B16F10 Kcnh8 GCTCTACGGAGAGACCCTAG 11859 Hepal-6 Npffr2 CCCAGGATAAACTTTGGCCT 17843 B16F10 Nlrp4b AATGAGTCACTCCTTCTCAT 11860 Hepal-6 Npffr2 CTGAAGAACTCAGACGCCCA 17844 o 4 B16F10 Nlrp4b TGGTATGGCTCTAAACCCAC 11861 Hepal-6 Cmpkl AGACCAGTGGTTCAATCTCC 17845 B16F10 Nlrp4b TCTACTGAGTTGCAGCTGTC 11862 Hepal-6 Cmpkl CAGAACCTGGATTGACGTTT 17846 B16F10 Hsd3b6 ACTTTGAGTTAGTCTCTTTG 11863 Hepal-6 Cmpkl CTTGGGTCTCCAGCCACGTT 17847 B16F10 Hsd3b6 CATTAAAGGCAACCATAATT 11864 Hepal-6 Trp53bp2 GGAGCGGAGCGCCAACCGGG 17848 B16F10 Hsd3b6 TCACATTAACTGATGTGAGA 11865 Hepal-6 Tip53bp2 GAAGGCGCATGCGCAGATGC 17849 B16F10 Ts z3 CCGAACGTGCGGAGGGAAGG 11866 Hepal-6 Trp53bp2 GGGCGGGAACCTTTGCTCCG 17850 B16F10 Ts z3 TGTCAAACTTCCCATTCCGC 11867 Hepal-6 Vephl TAACCCACTTTAAAGAATCA 17851 B16F10 Tsbz3 CGCAGGATGCTGCTGCGCCC 11868 Hepal-6 Vepbl TTGCTACCAACCAGTAATTT 17852 B16F10 Navi GAGGACGGAAGAAACCGCGG 11869 Hepal-6 Vepbl TTAGATCTAACAATTGGCAC 17853 B16F10 Navi GCAAGGAAATAGCGGGTTGA 11870 Hepal-6 Nbeall GGAGCGGCTGCCGGAGGGCC 17854 B16F10 Navi GGCGGTAGTGCCGGGAGAGG 11871 Hepal-6 Nbeall CGGCTGCGCAGGCATGCCGG 17855 B16F10 Tmc3 AGAGATTACTGATGGACTTT 11872 Hepal-6 Nbeall GGCCGGAATGATTAGCCCAG 17856 B16F10 Tmc3 CCAGTAGCCTAGGGCTGTCT 11873 Hepal-6 Bankl GGGCTCAGGCCGCAAGGCTA 17857 B16F10 Tmc3 GTGGGTGTGTTCACATTGAT 11874 Hepal-6 Bankl GGAITGTGGCCCGAGGTTGC 17858 B16F10 Myol8b GTGGTGGCCGTTGAACCAGC 11875 Hepal-6 Bankl TAGTTTGAGAGAGCTGTCTT 17859 B16F10 Myol8b GACAGCATGCACATATATGG 11876 Hepal-6 B c GTAATGGGAGGCTCCTAGGC 17860 B16F10 Myol8b GCTGCTATCTCAGTAGCTGG 11877 Hepal-6 Bo GCAAAGAAAGTAGGCGTTAA 17861 B16F10 Mrgprb4 TTATTGTGCTTCTGGAAGTT 11878 Hepal-6 Boc TCCCATTACCGCTCGAAGAG 17862 B16F10 Mrgprb4 AACACAAGATAGTCTCAGTC 11879 Hepal-6 P s l6 CGAGGAGCTCCTGTTTCATT 17863 B16F10 MrgprtU GGCACAGGTCCATAAAGAGA 11880 Hepal-6 Prssl6 ATATTATAGGTTCTCAGTGA 17864 B16F10 Ccdcl41 CAGATAATGGTTCAAATAAC 11881 Hepal-6 Prssl6 CCAGACGCCAGAGTCTGTAG 17865 B16F10 Ccdcl41 GGGAGAGAGAGTTACACTCG 11882 Hepal-6 ZscanlO AGCTTGGCAAAGTTAGAATC 17866 B16F10 Ccdcl41 TTTCTGTTACCATACTAGGG 11883 Hepal-6 ZscanlO GGAGGTGAAGGGTTAATTCC 17867 B16F10 Zfp648 TGAGGACAGACAGGAGGCCC 11884 Hepal-6 ZscanlO GAGGAGCCAGAAACAAACCA 17868 B16F10 Zfp648 TGGCTTGCTCTGTGAGAGGA 11885 Hepal-6 Gp6 TGGCAAGAAGAGATAAGTGG 17869 B16F10 Zfp648 AGCTGAAACTCAGGCTCCCT 11886 Hepal-6 Gp6 ATTCTCAATTAGGAAATCTG 17870 B16F10 Trpc2 CGAGGCAGGGAGAGAGCAGC 11887 Hepal-6 Gp6 ATAGGAACAGGATGCGCTGA 17871 B16F10 Trpc2 TGCCACATGATGACGTCTCC 11888 Hepal-6 Tmprssl5 CTAGTTCTCAACGAGGCTAA 17872 B16F10 Trpc2 TGAAGGGAGGGCACAGGGTG 11889 Hepal-6 Tmprssl5 GAACAGTCCATTTGTCAGGG 17873 B16F10 Abcc8 CAGGCGAGGCGGTGTCTGAG 11890 Hepal-6 Tmprssl5 CGATTGTAATTTACAGTTGT 17874 6F1 Abcc8 GAGTAGTAACCAAGATGATC 11891 Hepal-6 Gml3178 GGATTGCTGAGAAACTGGTC 17875 n B16F10 Abcc8 CACCCAATGCGCACGTGCGC 11892 Hepal-6 Gml3178 TCTACATTGGCTGACTTAGG 17876 B16F10 B3gnt9 CAGCAAGAGTCTCCCGTGAG 11893 Hepal-6 Gml3178 AGTTCAGAGGTAAGGTCCTC 17877 n B16F10 B3g t GAGCTGAGCTCCAGATGTCG 11894 Hepal-6 h8 CAGTCTACAGCTGCCTTGGC 17878 o B16F10 B3g t ACTTCTTGAGCTTAGAAACT 11895 Hepal-6 Rdh8 CTGAAGCAGTAGGCCCAGTG 17879 B16F10 Tmem39b GTCGGGAGCGCGCTTCTTAA 11896 Hepal-6 Rdh8 TGACATCACAGGTTCCTGAG 17880 B16F10 Tmem b GGCTGCTCAATTTGCATGCT 11897 Hepal-6 BC026585 CTAACCCTAGAAGTGGTGTG 17881 b B16F10 Tmem39b GGTGAAGAAACACGGGAGGT 11898 Hepal-6 BC026585 CGGCCAGAGCAGGCACGTCC 17882 J B16F10 Ddn ACAGGCACACACGTGTGCCC 11899 Hepal-6 BC026585 GGAGAGCGGAAAGGCGTCCC 17883 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Ddn GCGCATGTGACACGCCGCCG 11900 Hepal-6 Fbxo44 GGGAGTGCGCGGGTGAGGCG 17884 B16F10 Ddn GCAGGTCCCATTAGGCTTGG 11901 Hepal-6 Fbxo44 GCCTGAAGGAATGGTGGGCG 17885 B16F10 Col6al GCCCTCTCCTCTCGGGTACT 11902 Hepal-6 Fbxo44 CGCGCGCTCTGCGATCATGA 17886 o B16F10 Col6al GGAGGGAGGGAGGTGCAAAG 11903 Hepal-6 Dtwd2 AAGCAACCCAACACACCAAT 17887 B16F10 Col6al CTGTGACTCACTCAGCTTTG 11904 Hepal-6 Dtwd2 GCCTAGTGGCTGCCTGGGTA 17888 B16F10 Ptprn2 TAGAACCCGCTTCTCGGGAG 11905 Hepal-6 Dtwd2 TCTGCGCGCGCACGTCACGT 17889 B16F10 Ρΐρπι2 TGGGCGTGCCTGAACGTGCA 11906 Hepal-6 Slcl7a4 AGGCAAGCAAGAGTAGTAGC 17890 o 4 B16F10 Ptpm2 AGAAGGGACCACAGCTTGTG 11907 Hepal-6 Slcl7a4 TCACATGAACTTCAAGTATG 17891 B16F10 Uggtl CGGGTCTTATGCCGGTTTCA 11908 Hepal-6 Slcl7a4 AAGATAGAGTGAACATGGTC 17892 B16F10 Uggtl TTTGCCAGAGAGTCCCGCAG 11909 Hepal-6 Scubel TCGCGGTACAGGGTGTCACC 17893 B16F10 Uggtl TCCGGCTATCGAGTGCGGCG 11910 Hepal-6 Scubel GCTGACAGCCGCGCGCTCAT 17894 B16F10 Muc5b AGACCGTGCCTTACATGGCC 11911 Hepal-6 Scubel CTCCGCGGGAGGCCGTCCAG 17895 B16F10 Muc5b CAAACACACGTGGCTGTGCA 11912 Hepal-6 Dnphl GAAGAGAGCGAGCTTGAAGA 17896 B16F10 Muc5b GCCTGGACTTATGTAGCCAA 11913 Hepal-6 Dnphl GTCAGAACTAATGAGCGGGT 17897 B16F10 Fbxw21 AAAGGCTGATGAGCTGTGGT 11914 Hepal-6 Dnphl GAAAGCGACTCCCAGAGGTA 17898 B16F10 Fbxw21 CATCTGGCACCAGTGTGTGG 11915 Hepal-6 If t l l2 ATCCAGGGAGACGCACTGTG 17899 B16F10 Fbxw21 GACTCGGCCAAAGATTTAGC 11916 Hepal-6 Ifltlbl2 TGCAAGAGAGCAGAGAGTCA 17900 B16F10 Med 14 CCCGCGCTGTGCTGTTCTGG 11917 Hepal-6 Ifitlbl2 GTCACACCAACTGGAAGCTC 17901 B16F10 Med 14 AGTCGCCAGGCAGAACGGAA 11918 Hepal-6 Majin GCTTGTGCACATCAAGCTAA 17902 B16F10 Med 14 CCGCTCTCGGCCCAGCAACA 11919 Hepal-6 Majin GAAGTTAGGTGTTCTTGCGC 17903 B16F10 Fsdl TGGGATAACCCAAGCTCCGG 11920 Hepal-6 Majin TAGTTAAGGGATAGGTCATG 17904 B16F10 Fsdl ACTACGCATGCGCGAGCGAC 11921 Hepal-6 Spg7 GCGAAACCTCGAGAGTCAGC 17905 B16F10 Fsdl CTACATITCCCAAGCAGCGC 11922 Hepal-6 Spg7 GGCCTCCCTTTGCGCTTGCG 17906 B16F10 Idol ATCCAGTGGCTTGCTGCTTG 11923 Hepal-6 Spg7 CTAACCTTGCGGATACCAGA 17907 B16F10 Idol TCCTTCAGTGGCCAAGTGGG 11924 Hepal-6 Atpl3a4 GTTCCTATAGCITTCAAACG 17908 B16F10 Idol AGTATTACGTGTCAGCTGTG 11925 Hepal-6 Atpl3a4 GCAAATCCAGCAAGACAATG 17909 B16F10 Ccdc40 CCACCCGGGTCCCGCCGCGA 11926 Hepal-6 Atpl3a4 TTTGAGAGAATGCAGAAGCA 17910 B16F10 Ccdc40 CCGCCGCGCCTCGCTTTCGG 11927 Hepal-6 lsoc2b AATCCACGGAGGGAGGGCCT 1791 1 B16F10 Ccdc40 GCTGGACACGCGCCGGCTCC 11928 Hepal-6 lsoc2b CCCGCGCCGAGCCAACCAAT 17912 B16F10 Myom2 GGAGAAGCACCAGATGCAAG 11929 Hepal-6 lsoc2b TTCAGACCAATCGAATTAAC 17913 B16F10 Myom2 GAGCAGAGTACCCTGGGACG 11930 Hepal-6 Tmprss2 GTCCAAAGACCCGTCGCAGC 17914 B16F10 Myom2 CTCCTCTGGCCATAAATGGG 11931 Hepal-6 Tmprss2 GTTTGATCTCTCGGTGCTAG 17915 B16F10 Gm904 CCAAATCATGCTGCTGAGTC 11932 Hepal-6 Tmprss2 CCTGGAGTTCCCATGGGTCT 17916 B16F10 Gm904 CAGTGTGAGATGTGTCAAGA 11933 Hepal-6 Zfp609 GCCCTGGTTGTCCCGGATCG 17917 B16F10 Gm904 TGACCTTGTCCTGGAGGCTG 11934 Hepal-6 Z p6 9 ATCCAGTGTCCAGGTCTTCC 17918 B16F10 Pi4k2b TCTGGGAGTTGAGACACAGG 11935 Hepal-6 Zfp609 AGCTGAGGGACCCGCAGCCC 17919 B16F10 Pi4k2b GGCGTAAGGAAGGCGTCCCG 11936 Hepal-6 Iflhl ACGAAACTTATTCTCTGGCC 17920 B16F10 Pi4k2b GCTGGATCCACTGCAATGGC 11937 Hepal-6 Iflhl CCTTGTGTTGAGAAAGCAAG 17921 n B16F10 Dsc2 GACATATAGGTGGCCTCTGC 11938 Hepal-6 Iflhl GGCGGGTTAGGTGAGGACTT 17922 B16F10 Dsc2 TTCACCGGGAGCTCTGACCC 11939 Hepal-6 Cyp2gl GTAATATCTCACCTGCGCAG 17923 n B16F10 Dsc2 TCCTGCTAGACCGCCATCTG 11940 Hepal-6 Cyp2gl ATTGATGGCATAATACTGGT 17924 o B16F10 Gnptg TCGGATTTCATCTAACATTA 11941 Hepal-6 Cyp2gl TAAGITGAGGGCTTGTGCCT 17925 B16F10 Gnptg GCACGCTCTTGAACAAACGC 11942 Hepal-6 Nfe213 CACTACCACAGGGCTGCCAG 17926 B16F10 Gnptg ACGGTCACGTGAGTGACAGC 11943 Hepal-6 Nfe213 CAGATATGAGTGTGTCCCAG 17927 b B16F10 Dnah5 CGTGCITAAACGGCACAGCA 11944 Hepal-6 Nfe213 TGGGCTCCAGGCCTCTTTAT 17928 J B16F10 Dnah5 TGTTGCTAAACATGATTAAG 11945 Hepal-6 Steap3 AGCCATCCCTAGGCAGGGTG 17929 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Dnah5 GCTTATTGTTGGGCAGTGTA 11946 Hepal-6 CCGCCCTGCACTACAAGTGG 17930 B16F10 Atm GCTCCCGCTGTGCGTCGGGC 11947 Hepal-6 CTAGCTATTTGGTAAGTATG 1793 1 B16F10 Atm GATGAACATCGCCTAGTCTA 11 4 Hepal-6 AAAGTGTATGTCCTGGCTGC 17932 o B16F10 Atm CTAAGACCCTGGCATTGAGC 11949 Hepal-6 ATATTTGTCAGGTCAGTTCC 17933 B16F10 GmlllO GGACAAAGTACAAATAATGT 11950 Hepal-6 TTTGCCTTCCCGTCAGTTCC 17934 B16F10 GmlllO GTTTCACTTCCTGTGGCGAC 11951 Hepal-6 CGTATTTGAGAAGCAGTCAA 17935 B16F10 GmlllO AGGCCGAGAGAAGGGCTTCG 11952 Hepal-6 GGGAGAAACAAAGGGCTTCA 17936 o 4 B16F10 Polr3a ACCTAGGCCGCGCAGATCAG 11953 Hepal-6 TTTGCTTCATGATGACCATG 17937 B16F10 Polr3a GGACTTTATGAAGAGAGGCT 11954 Hepal-6 GGGTAGTGGGTAGCAGTCTG 17938 B16F10 Polr3a TAGATGGCGATCTAGAAGGA 11955 Hepal-6 ATTGAGTCACCGCAGTCTTG 17939 B16F10 Wrap53 GGGAGTTGTAGTCTGAACTC 11956 Hepal-6 GGGAAATTCTGGGCAAGATT 17940 B16F10 Wrap53 GGAGAATTCCTAGAGGTTTC 11957 Hepal-6 CCGATITCACCCACCAGAGC 17941 B16F10 Wrap53 TTTGCCTACACCTCAAGCGC 11958 Hepal-6 ATGGAGAGCTTTCCTTCGCA 17942 B16F10 Tulp2 TGCCAGCATGGGAGACTCAG 11959 Hepal-6 AACGCACTTCAGGTAGITCT 17943 B16F10 Tulp2 ATGTTACCTCCCTGTATTGG 11960 Hepal-6 TTTGGGCTGCGCGTGTCCAC 17944 B16F10 Tulp2 CAGAACCCAAATTGGTCAAG 11961 Hepal-6 GCCGGAATCCGGAATGCTTC 17945 B16F10 Vpsl3c GGGTCACGCCTGCGCACTGG 11962 Hepal-6 GCGTAITCTTGTGGGATGGC 17946 B16F10 Vp c CCCACCTCCGCGATTGCGGG 11963 Hepal-6 GTGAAGTTTACCATATTTCA 17947 B16F10 Vp c GGCGCAGAGACTGACAGCTG 11964 Hepal-6 GACAGATGCACCAAGAGGTG 17948 B16F10 Foxd3 CGCCGGGCTCCAAGCAGCTC 11965 Hepal-6 CCCTGCCCGCCCGCGTCGCG 17949 B16F10 Foxd3 AACGGGACTTTCGACTACCC 11966 Hepal-6 TGACTCGATCTGGAGGAGAG 17950 B16F10 Foxd3 AGGAGCGGTCCAGGCAAGCG 11967 Hepal-6 TCCTCATTGTGGGCCGGCCG 17951 B16F10 Omg AGCTATGTAAGGCACTCTCT 11968 Hepal-6 GCGCTCCACAAGTCACAGCG 17952 B16F10 Omg TACTTCATGCAAATTAGGGC 11969 Hepal-6 GCTGAGAGGCGAGTACGCGG 17953 B16F10 Omg TGACTCAAATTTATTGCA AG 11970 Hepal-6 CGCGTCACCCACGTCCCTCT 17954 B16F10 Zfp868 GAGCCCATTGTTTAGTGTTG 11971 Hepal-6 ATTGGCTGCTCTTGTGTTCC 17955 B16F10 Zfp868 GATGGGCGGAAGCCAGTACG 11972 Hepal-6 CCTGGTGGCGAAACCGGGCC 17956 B16F10 Zfp868 AGAAGCTTCTAGGAGGCGGG 11973 Hepal-6 TCAAGAGTTCTCTGCGGCTG 17957 B16F10 Dock9 GATGCTAGGCGAAGCATTCT 11974 Hepal-6 AATATCATAGAGCTTTGTTG 17958 B16F10 Dock9 GGATCGTCCGGAGCTAGCCC 11975 Hepal-6 TCAACCACGAAACTAGAGAG 17959 B16F10 Dock9 GACCGAGAAGGCCAGCCTCT 11976 Hepal-6 GCAAACTCTGGCTAACTACC 17960 B16F10 Dsccl CCTTCCTGGAGTCCTCATGG 11977 Hepal-6 AGGATATGAGTCTCCTGAAG 17961 B16F10 Dsccl CGAGGAAGTCGGAAAGTATC 11978 Hepal-6 CTGAAGGAGTGCGGATTCCC 17962 B16F10 Dsccl GAAGTCGGCTCGGGCGGATT 11979 Hepal-6 TAGCTACGTCATCAGTTACC 17963 B16F10 Mcpt4 GATGCAGGAGACTCAGAATC 11980 Hepal-6 GACAGCGAGCTAAATTATCC 17964 B16F10 Mcpt4 AGTCATGAGAATTTCTGATA 11981 Hepal-6 CGGCTTTATACAGGCCCGGC 17965 B16F10 Mcpt4 TGCAGTCGACACCTTATTAT 11982 Hepal-6 GCAATTGGACTTGCAGACGC 17966 B16F10 Lat GGTGAGGGCAGGAAATCATC 11983 Hepal-6 GGGCTAGATGGACAGGTGCC 17967 n B16F10 Lat GATGAGGCAGCCCGTCCACT 11984 Hepal-6 GGCTGGGCGCTAGACTCGCA 17968 B16F10 Lat TGCTCACCACCGCGTGCGAC 11985 Hepal-6 GCGCTTAGCCAGAGGCGCGA 17969 n B16F10 Fgfll TGGAGCTAGTCAGGGCCCAA 11986 Hepal-6 GCGGCGCAGGCCATCCCTAG 17970 o B16F10 Fgfll CTCTTCAGATCCTGTGGGTG 11987 Hepal-6 CGCGTGCGTATGCGTCGCCC 17971 B16F10 Fgfll CTGAGGAGTGCATAGGCTGC 11988 Hepal-6 TCAGAACCATGGCAGGAAAG 17972 B16F10 Mepla TGTAGACTACGCGTACTAAG 11989 Hepal-6 TGGGAAAGGTTTAGAGATGG 17973 b B16F10 Mepla AAGCTATACACAGTGCCCTC 11990 Hepal-6 TGGTGATGCTATCCTTTGTC 17974 J B16F10 Mepla TGCAAACTTTGACCGTGCTG 11991 Hepal-6 AGGTTGAGAAGGCATCAGCA 17975 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Dbnl CACGTCAGAGGCGAGGCTTC 11992 Hepal-6 Erich6b CTACCACTTCTCTGTTGTTT 17976 B16F10 Dbnl CTAGGCTGAGGGTAAAGTTG 11993 Hepal-6 cll b ACTTAAACTCGAGATTGGAA 17977 B16F10 Dbnl ACGAACGAGGACCTACGGGC 11994 Hepal-6 r c b GCTCTCTGTTACCATGGGAA 17978 B16F10 Fmo5 CTTCTCAGCAGCACCCGCAT 11995 Hepal-6 Fltl GCCGGCGAGGGCGGGTAGCC 17979 B16F10 Fmo5 GAAGGGTGCACGCCCTTGGG 11996 Hepal-6 Fltl GAGGAAGAAGAGGGTAGGTG 17980 B16F10 Fmo5 AGCTGTTTCCTTTGCGTTTA 11997 Hepal-6 Fltl GTCACTGGAAGGAGGTGCCG 17981 B16F10 Gml2794 TGTCTGCTAAATGCTTCACC 11998 Hepal-6 ck CGTTGGCTGTTACCACTCTC 17982 B16F10 Gml2794 CCATGCTGTGAGTGAACTTT 11999 Hepal-6 ck TCCTTCAGGAGTCGGGTTTC 17983 B16F10 Gml2794 GTAGTGCAGAGCCCATGCTC 12000 Hepal-6 Ick GCCGCAGACTTGCCACTGAC 17984 B16F10 Kbtbdll TGGAGGTGCTCTGTGCGCCA 12001 Hepal-6 Brinp2 AGCCAAAGGAGATTGCCGGT 17985 B16F10 Kbtbdl 1 CTCAACAGGTCATGCCCGCG 12002 Hepal-6 Brinp2 CACGTAGGTTGGCAGCCAAT 17986 B16F10 Kbtbdll GGTGCTGCTGTCAAGGCTGG 12003 Hepal-6 Brinp2 GTTATCTTAAGACACTCATC 17987 B16F10 Kdm5b TAGACTGTTAACTTCTTGAG 12004 Hepal-6 Clecla TGATTATGCTTTAGACTCAG 17988 B16F10 Kdm5b GGATAAACATCCCAGGCGGA 12005 Hepal-6 Clecla ACCTTCAGTGCTACTAGGAG 17989 B16F10 Kdm5b AGAGGTTAACTGAAGCATTA 12006 Hepal-6 Cle l TCAGAITGTGATGCATACTG 17990 B16F10 Ssxb3 CTCTCCCATAGACCTAGTCC 12007 Hepal-6 Runx2 AGGGAGGGAAGAGAGCAAGG 17991 B16F10 Ssxb3 ACTCTCACTCTCAAAGACTC 12008 Hepal-6 Runx2 GGCACCTTGAAACGCGAGGG 17992 B16F10 Ssxb3 TGCACATACACAGTAAGAGT 12009 Hepal-6 Runx2 TGCGAGCTAGACGGCGGCGA 17993 B16F10 Ccrlll GCACTAGTAAATAGTTCAAT 12010 Hepal-6 Zkscan3 ACTAAGAGGAGGGAGAAGGG 17994 B16F10 Ccrlll TTCAGGGTTTAGTAAACTCT 120 11 Hepal-6 Zkscan3 TTACGAGGCAACCAAGAGGA 17995 B16F10 Ccrlll TGTAAACTCTTCTACAGGAC 12012 Hepal-6 Zkscan3 AAACTGGAGGAAGTAAAGGG 17996 B16F10 Nlrpl4 GTTAGATGCAGTTCCTACCC 12013 Hepal-6 Tbce ACTGGTCCCACAGTCCTTCG 17997 B16F10 Nlrpl4 CTCTCTGCTGTTACCGCCTT 12014 Hepal-6 Tbce CGCGTTTGGAAGGGCTAAAG 17998 B16F10 Nlrpl4 AGCTTACCCAGACAGCCAAT 12015 Hepal-6 Tbce ACCCTATTGTCGCGAAGTGC 17999 B16F10 E oc3 AACGCGGTCACTTCCGTTTC 12016 Hepal-6 Lrrkl GCTTGGGTCTTGAAACTTTG 18000 B16F10 Exoc3 TGGCTCCGCCGTCTGACGTT 12017 Hepal-6 Lnrkl AACCGAGGCAGGCCATCCAG 18001 B16F10 E oc3 GGATCAGGGATTACAGATTC 12018 Hepal-6 Lrrkl TCACCGACATCTTGCAGCTA 18002 B16F10 Hep ATATTGITAAAGAACCACCC 12019 Hepal-6 Mteif4 GAGGCCGGACGTTGTGAGCC 18003 B16F10 Hep GGATCTCAGGTTAATGGGTT 12020 Hepal-6 Mterf4 GGAGTTCGGCGGACACAGAT 18004 B16F10 Heph TTACCTGCCTAACACTCATG 12021 Hepal-6 Mterf4 TCCCTTTAGTTGGGCATACT 18005 B16F10 Ddit41 GCAGGTGTCCGCCCAAGGCG 12022 Hepal-6 Par l 4 CTTCTTTCGCTTTCATTTCC 18006 B16F10 Ddit41 GAAGGGAGATGCTCTTTAGG 12023 Hepal-6 Par l 4 ATTCCAATCCTGGGATAGCG 18007 B16F10 Ddit41 ACTCGCTCGGGCCCGTGCCC 12024 Hepal-6 Paipl4 GAAGATAGAAACTAAGGACG 18008 B16F10 Lmtk2 GTAGAGCTGAGGCGGGATGC 12025 Hepal-6 A am6 TAACAGTCACTGGGTGTGGC 18009 B16F10 Lmtk2 CCCACCCTCTCAGCCATAGG 12026 Hepal-6 Adam6b GAGTCTGAATGTGTTAGCTG 18010 B16F10 Lmtk2 TCACATGACGCAGCCCATCA 12027 Hepal-6 A am6 GGAGCTAAATCCCTCTGCTG 1801 1 B16F10 Afg311 ATCATAGTGCACCACGCCCT 12028 Hepal-6 Pitpnm3 ACAGACTCCGGATTACAGCT 18012 B16F10 Afg311 GCGAAGCGACACTCGGGTTC 12029 Hepal-6 Pitpnm3 CTGTCTTTCAGCGAGGGTCG 18013 B16F10 Afg311 GCCTGACAGCTGATGGCGGA 12030 Hepal-6 Pitpnm3 TCTCAGTGGCCGCAATCAGT 18014 B16F10 Rpgripll GCCGTCGGCGGGTCGCGTAG 12031 Hepal-6 Epdrl GGCATCGCACTTAAAGGGTT 18015 B16F10 Rpgripll CAGTGAGTCCCGTTACCCAC 12032 Hepal-6 Epdrl CAGAGGTGTGGCACATTCTC 18016 B16F10 Rpgripll TACCGGTTGCTATAGCGCCC 12033 Hepal-6 Epdrl TGATGCCACTAGCATCCTAA 18017 B16F10 Sgpll CTGGGTCCGGGCTGTGGTGT 12034 Hepal-6 C2cd4a ATCCACGTGGCAGAGGGACC 18018 B16F10 Sgpll GACGTGCGCGCGCCCGACAG 12035 Hepal-6 C2cd4a AAAGCCCGGACCAGCTATCC 18019 B16F10 Sgpll CCCTCCCGGAAATGGCCTTG 12036 Hepal-6 C2cd4a TGAGGAAACAAACTCGTTCA 18020 B16F10 Trp63 TGGAAGTTGATGGATTGGAC 12037 Hepal-6 Ctsf TACGCGAGGCACGTGGACCA 18021 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Trp63 TGAAATGAAGAGTGAGTTCT 12038 ACAGGTCTGCCATGGTTAAA 18022 B16F10 Trp63 ACTACITAATGAGATGGGAG 12039 TTTCCTGCGTAAGATAGAAA 18023 B16F10 Gucala CCACCAGATCCTGTTAAGAA 12040 GGCCACTCTGGTCACTGCTT 18024 o B16F10 Gucala GGCAAGAGGCAGAGCATTGT 12041 GGCTTGCCCAGCTGTTTACC 18025 b B16F10 Gucala CTCTCCGGCATCTCTAGTTT 12042 GTCAAGTTTAGCACTCTGGC 18026 B16F10 Smarcc2 GCAGCCGGGCTGCCGCTGCG 12043 GCTCTGTGTCAACTTGACAC 18027 b B16F10 Smarcc2 CCGGCAGCAGCGGCGGTGGG 12044 TGCTGCAGCCTTGCCCAATC 18028 o 4 B16F10 Smarcc2 TACGCAGGGCCGCCGGCAGG 12045 CCATCCAGGACCACCTGCCC 18029 B16F10 U ql l TGATCAGATCATGCCCTTAG 12046 TGCCCAAGCTCAGCGCGCGG 18030 B16F10 Ubqlnl TTTCATCATGATGTATTGTG 12047 AGCTAAGGACGCGACGATCA 1803 1 B16F10 Slc6al9 CTGACGCCTCCTTTCGGCCC 12048 CTGATGGATTGCATGAGTGC 18032 B16F10 Slc6al9 TGCTTGGGTTGAGGTGCCAA 12049 TAAAGGGCAGGAGAATTCAC 18033 B16F10 Slc6al9 CTCCTGTCCGTGAATGGAGG 12050 TCTTTATCTGTATACCACAA 18034 B16F10 Slc22a6 CACTTTAACTCATTGTCATC 12051 AAAGGTCAGACACACTGATT 18035 B16F10 Slc22a6 ATTTCTCCAATTGGGAATGA 12052 GATAATCAAGTCTACTATGA 18036 B16F10 Slc22a6 TGACACAAGGAATACTCACA 12053 AGGGTGGAGCTTCTTGGGTT 18037 B16F10 Ube2s AAGTTCGAACCCAGTTTGTG 12054 GCTATGAGTCATGTTGCCAA 18038 B16F10 Ube2s GGTCGAGACGTGCCGTGAGG 12055 GCTGTAGGGCGGCGATGCAG 18039 B16F10 U 2s AACGTGCGCGTTGACGTACG 12056 CCTCACTGGAGCGGAGAGAT 18040 B16F10 Piga AGCACGTCTCCTAAGAGCTG 12057 TCTGGGITGCACGCAGGCTA 18041 B16F10 Piga CAATCCCGCGCTAGAGACTT 12058 GGAGTAGGCTAAGCCACCAG 18042 B16F10 Piga GTAGAAGAGAGACGCCCAGT 12059 GACTAGAATGAACGTGAATG 18043 B16F10 Naip2 TGAATGTGAAATACCCACAC 12060 GCCACAGCACGCCCAGTTTC 18044 B16F10 Naip2 CTGTGTCTGGGCCTACACTG 12061 ATTGAATCAGATCCATACAG 18045 B16F10 Naip2 CAGCTCATGGTTTGAGAATT 12062 TTCCTAGGCTTAAGGCCTTT 18046 B 6F1 I830077J02Rik ATCTTTGCGACACAGCCTGA 12063 GTTGACCACCTCTTTGTGTG 18047 B16F10 I830077J02Rik GCAGTATCATTCACAGCAGG 12064 TCGGCTGAGCATATGAGTCC 18048 B16F10 I830077J02Rik CAAAGAGGAAGTCTGTGCCT 12065 GCTAAGAGCCAGCCATGCTA 18049 B16F10 Ltbpl CTCTTTAATCTGCCTTGCCC 12066 GAAAGGTTTCAGAAGCGGAC 18050 B16F10 Ltbpl CTCGACTTCAAATGTGGTTT 12067 GGGCCTTGTTTGTGCCCTGT 18051 B16F10 Ltbpl GCAGACAAAGAGCAACATCC 12068 TTTGACAGCCCTCCAAGGTC 18052 B16F10 Kc a7 ACATACCCAAACCCAGTGTC 12069 GAAGATTGTGGCCACTCTCA 18053 B16F10 Kcna7 GATGTGGACAACTGGTTAAG 12070 CATGCTATAAAGGCAACAGC 18054 B16F10 Kcna7 AGAAAGACTGGAAATGGAAA 12071 GGATGTGGCACTAGGCCCGC 18055 B16F10 Gigyf2 GGAACGATGTCGTGGGAAGC 12072 TGGCCACTGACGTTATGTAA 18056 B16F10 Gigyfi CCTCCCTGAGACCCGGATGC 12073 TGACGCAGAGCTCATCGCTA 18057 B16F10 Gigyfi ACTCAGGCTCCGTCCTCGCC 12074 CTGCTGTCCGTCTGATCCCT 18058 6F1 Rec8 GACTATTCTCCAAGAGCCTA 12075 ACTGTCTTCGGTTCTTCTAC 18059 n B16F10 Rec8 TCAGAATTCTCGTGATTGGC 12076 GCACCACCCGTAGCGCTTGG 18060 B16F10 Rec8 CTTCTGGCGCGGCTTCTCAT 12077 GAGTCTCTTTAGCGCGCTCA 18061 n B16F10 Sash3 TTCTCTGACTGTTCAACTCA 12078 GAGAGCGGCGACTGGTGACG 18062 o B16F10 Sash3 AATCTCTGGAGACTGAAGCT 12079 AGGCGGTGCTTGGGCCTTGG 18063 B16F10 Sash3 TAAGAGCAGGTCACGTGGCA 12080 AGCTCGCTGCAGCACTGCCC 18064 B16F10 1700020A23Rik GAGGACCTTGAATTAAGGAC 12081 TGATAACACAATGCCACGTT 18065 B16F10 1700020A23Rik ATGGTCACCCAAGTGGGAGG 12082 ACGCCTGGGCGCACGTACAA 18066 J B16F10 1700020A23Rik CAGGGACTTCCCACCAGTCT 12083 AGTCCCTGAGGCGCAATCGC 18067 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Arhgap26 TAGGTCATCGCTAGCAGGTT 12084 Hepal-6 Speg AAGGGAAGGGTCGCCAGGTG 18068 B16F10 Arhgap26 TTGGGITCTATAAGAAGAGC 12085 Hepal-6 Speg TGGCAAACTGGAGCTCTTAG 18069 B16F10 Arhgap26 AGGCATGAGATCCAACTGTA 12086 Hepal-6 Maccl GCTACCTACAAAGCAAGTAG 18070 o B16F10 Serpincl TCTTACGCAAGTGTGCTCTT 12087 Hepal-6 Maccl ACATATAAGTAAGTTGACAG 18071 B16F10 Serpincl GATGATACTCGTGTTCAGTG 12088 Hepal-6 Maccl TCTGCATATGTCTCTCATTC 18072 B16F10 Serpincl AGTCTGTTTCAGCGGGTCTG 12089 Hepal-6 Mfn2 GACGGTTACCAGGCACGCGG 18073 B16F10 Stap2 GACAGGAGCCCAGAACTACC 12090 Hepal-6 Mfn2 TGACAGCGTTCAGAGGCCAT 18074 o 4 B16F10 Stap2 ATTGCAAGATCTGGAATGCT 12091 Hepal-6 Mfn GGAGCCTCGAGCTGTCAAGC 18075 B16F10 Stap2 CCCAGAACTGCTAGAGAGGG 12092 Hepal-6 Dclrelb CGATCGGAAATCAACTACTA 18076 B16F10 Ahnak CTCGGGTCCTTGCCCTATTC 12093 Hepal-6 Dclrelb GCGCCGAGCGCAGGTCCGGG 18077 B16F10 Ahnak GTAACTCGGGCGGGTCTGCC 12094 Hepal-6 Dclrelb GACACAAGGAGCAGCTTTCC 18078 B16F10 Ahnak GACTAACACTGAAGCCACCC 12095 Hepal-6 Draxm CGCAGCGCCCGCAGCGCACG 18079 B16F10 Wdr5b GAGAGGCTCAAGTAGAGCCC 12096 Hepal-6 Draxin CGGGAGGTCGCGGAGCTCCG 18080 B16F10 W r b GCGCAGCAGGCACTTCATGA 12097 Hepal-6 Draxin TCGGCGAGCGCAGCTGGCTA 18081 B16F10 Wdr5b ATGCGTACCTAGCGTCGTCC 12098 Hepal-6 Dsel GGGCGGCTCAGGCCTTTCCC 18082 B16F10 Ercc6 TCAGTCTGTAGCCATTTGAG 12099 Hepal-6 Dsel ATCCAGGGAGGCGTGTCCAG 18083 B16F10 Ercc6 CTCCCTTTGGTCAACGCACG 12100 Hepal-6 Dsel TGCTGCATAGAGTTAAAGCC 18084 B16F10 Ercc6 GGCAAACCCTTGCTTACAAA 12101 Hepal-6 AbhdlO ACAAGCCAAATGCCCTTTGG 18085 B16F10 Ansa 10 AAAGCTGATGACTCATGGAA 12102 Hepal-6 AbhdlO GGTTGCTTACAAGCATCACG 18086 B16F10 Ansa 10 CCTTAAACCAACGCATAAGC 12103 Hepal-6 AbhdlO GCATGCGTCTCCGCGCCCGG 18087 B16F10 Ansa 10 TAAGCAGGAGGTTGGGCTAG 12104 Hepal-6 Vglll TGCACTCCAGCGAGTCAACC 18088 B16F10 Nme8 CTCCCTGTGGTGGAGGCTCG 12105 Hepal-6 Vglll CTAGCTATCTATTAAGAATG 18089 B16F10 Nme8 GAGCAATACAGCAGGAGTCG 12106 Hepal-6 Vglll CAACCACTGGAAGCGAGAGC 18090 B16F10 Nme8 CTGCTCACAGCAGGTAGAAC 12107 Hepal-6 Klrc3 AAGGGAGGAGACCAAAGAAT 18091 B16F10 Cyp2c50 TGGGTACCGCATAAAGAACA 12108 Hepal-6 Klre3 TCTACTTGTGTTCTATGCTG 18092 B16F10 Cyp2c50 AAGAATGTTCCAAAGTGCAA 12109 Hepal-6 Klre3 CCAGTGAGTGATATCAATTC 18093 B16F10 Cyp2c50 CAGATCAATCCATTGCACTT 12110 Hepal-6 Zip 184 GTCGCGTAGACCCTTTCCCT 18094 B16F10 Ptrf AATAGTTGGAGCGGGAGTCT 12111 Hepal-6 Zip 184 TGCAGCATTTGTGGAAACCT 18095 B16F10 Ptrf CCAATGGCCGACGGGACTCC 12112 Hepal-6 Zip 184 AGGCGCTCCTGTGTGTTGCG 18096 B16F10 Ptrf CCCACCCTGTTCAGGATGGT 12113 Hepal-6 Cyp2b23 CAATAGAATAGGGAGTAAGC 18097 B16F10 Map2k2 GACGCACACGCAGCCGACCC 12114 Hepal-6 Cyp2b23 AAGTATGGTGCTCACACACC 18098 B16F10 Map2k2 GCATGCGCGAGGTGGCTCCC 12115 Hepal-6 Cyp2b23 GACAGTGAGAGACAGGATGT 18099 B16F10 Map2k2 CGAGGTCCCGCCCTCAACCG 12116 Hepal-6 Akrlcl8 CTGTATGAGAATAAACGGTC 18100 B16F10 Slc30a6 TGGGCATTTATCACCTTGGG 12117 Hepal-6 Akrlcl8 TCGCTGGCTTGTGAAAGCAG 18101 B16F10 Slc30a6 CGGGACTGCGCATGTACCCT 12118 Hepal-6 Akrlcl8 GCTGAITACTCATTCACTTG 18102 B16F10 Slc30a6 GCGGGCCTTCAGAATCCGAT 12119 Hepal-6 Usp40 CCGCGTGGCGCGACGCACCC 18103 B16F10 Gpr26 GAGAAAGGAGAAAGAAAGGG 12120 Hepal-6 Usp40 GTGAAAGCTCTAACAGAATG 18104 B16F10 Gpr26 GGCAGAAAGTGAGAGCACAC 12121 Hepal-6 Usp40 GGGAAGTGTAGTCGCATCTG 18105 n B16F10 Gpr26 GAAACTGGCTGCTTCTGAGA 12122 Hepal-6 Atpl3a3 GGGCGTCCGCGCTCCGCTGT 18106 B16F10 Hsd3b3 TGCATTCCAACATGAGTCTT 12123 Hepal-6 Atpl3a3 GGACGGTCTGTGCTGCGAAG 18107 n B16F10 Hsd3b3 CATTGGTGGAAAGGTTATGG 12124 Hepal-6 Atpl3a3 AGCCGGGCAGGGCGAGAACA 18108 o B16F10 Hsd3b3 GGCTCACATATTTAAACCTA 12125 Hepal-6 C mn GGGCGGGAGGAGCCGGCCTC 18109 B16F10 S d2 AAGCAGGAGTAGAAATAGAG 12126 Hepal-6 C mn CCCGGCGCGCGCTCACTGCC 18110 B16F10 S d2 GCACGCGGCCTCTACCAATT 12127 Hepal-6 Clmn CCCACCCGCAGGGTGGGTGT 181 11 b B16F10 Sod2 TTGCAGCTCACAGCCAGAGC 12128 Hepal-6 Soatl AAACTCTAAGGAAGTTGACT 18112 J B16F10 Maplb GACCACCCGGCACGTCCTCG 12129 Hepal-6 Soatl CCCGAGCTCCGGGATGCCAT 181 13 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Maplb GTGCCGTTTATATGGAGACT 12130 Hepal-6 Soatl GGTACCCTAGATATGGGAGG 18114 B16F10 Maplb GCTAAGGGCTGGAGGAGTGG 12131 Hepal-6 Gml0639 GTAAATTCTTACCCAGGGTG 18115 B16F10 8030423J24Rik TGATAAGACAGTGAATACCA 12132 Hepal-6 1700020D05Rik GACAAACCGTGCTTCCTAGT 18116 B16F10 8030423J24Rik GAACGTGTAGGTAATCGTTT 12133 Hepal-6 1700020D05Rik GAATGGTAATTCTGTCAGGA 18117 B16F10 8030423J24Rik AGAGATGCGACTAGGTTGCC 12134 Hepal-6 1700020D05Rik GGATTTGTGCTGGATCTTCT 181 1 B16F10 Prdml ACGGCTGGGCTGGCCAGGTG 12135 Hepal-6 Hmgn3 TGCGCGTACCGGGTGAACGG 18119 B16F10 Prdml GTGAATCAGACCGTCAGTAT 12136 Hepal-6 Hmgn3 GAACGTTCTCTTAGCCAATG 18120 B16F10 Prdml AAGAAGTCTGCGGCAGGGCA 12137 Hepal-6 Hmgn3 CTGGCAGGGCTCGCCATTGG 18121 B16F10 Rapgefll GGCGGGCCTAAGCAGGGTAG 12138 Hepal-6 Agfg2 GTTCGATTCGAGACGGCCTC 18122 B16F10 Rapgefll GGGITTCTGACAGTCGCAGA 12139 Hepal-6 Agfg2 GCATTGTACTTGCAAGGTGG 18123 B16F10 Rapgefll GGAGAGATCTACCAAAGCAG 12140 Hepal-6 Agfg2 TAGGAGTCCGTGGCGAGAGG 18124 B16F10 Tctn3 GCCGGGTGCTCTTCAGCCAA 12141 Hepal-6 Cdc42epl CAGGGATGCCAAGCCAGGCC 18125 B16F10 Tctn3 ATCAGCTTCCGTCTGCGCAT 12142 Hepal-6 Cdc42epl TGGCCAGCCAGCCCGGGAGG 18126 B16F10 Tctn3 CGCTCAGGGTCGTAACAACA 12143 Hepal-6 Cdc42epl CCGCGAGCGCTGCAGTGGCG 18127 B16F10 Mkml GTTCCTGAGACCTGAGCGCT 12144 Hepal-6 Skint8 GTGTAGGTGAATACTGATAA 18128 B16F10 Mkml GGAGACGCGGTGACACGGCG 12145 Hepal-6 Skint8 GAACTACCTACAGGCACAGA 18129 B16F10 Mkml GCGTGATCACACGCTTAGCC 12146 Hepal-6 Skint8 ACAAATGACAAATATCACCC 18130 B16F10 Cnst GCGACCATAGAGTTCCAGCA 12147 Hepal-6 Ptprzl TTTCTGCTGCTGCGCGACCC 1813 1 B16F10 Cnst GGCTAGAGAGGAAGTGCGGA 12148 Hepal-6 Ptprzl CCACCTCCAGCCCTGGGCGG 18132 B16F10 Wdfy4 CAGTACTTAGTCTGAATGCG 12149 Hepal-6 Ptprzl GGCTGGGCACGCGCAGTGCG 18133 B16F10 Wdfy4 CTCTCAGCAGAGTCTAAAGA 12150 Hepal-6 Gml3078 CATCAGAGGTTTGAGGGAGA 18134 B16F10 Wdfy4 AGAGAGGAGGGACGATTGGC 12151 Hepal-6 Gml3078 GACTTCATCATCCTATCAGG 18135 B16F10 4932438H23Rik CTGCTGTAGACTGACCACAA 12152 Hepal-6 Gml3078 CAGCTTTGATCTGAGAGGTG 18136 B16F10 4932438H23Rik GTTTGGCCTGGTGGTTTCCA 12153 Hepal-6 Mgst2 GCTGGTCTTCTCCTTT ATAA 18137 B16F10 4932438H23Rik AGAGACAGGTTCTCTCCTAC 12154 Hepal-6 Mgst2 GGCAACAGAGTTGAGTCAAC 18138 B16F10 d 55 GGGAACGCCCTCTTGCACGC 12155 Hepal-6 Mgst2 TTGAGTAACAACCTTTGCAC 18139 B16F10 Cd55 ACCTAGTTGTCCGGCGGGAG 12156 Hepal-6 Vmnlr204 AAGTTTCCTGATCTTGTTCT 18140 B16F10 Cd GTGAAGCGCCCTCCTTTAGA 12157 Hepal-6 Vmnlr204 TTGTCAACATCATCACCTCC 18141 B16F10 Cyp21al GAACAAAGGACTGGAGTTGG 12158 Hepal-6 Vmnlr204 TCTGTAGAAGCAAGAATAGA 18142 B16F10 Cyp21al GGACCATCCATCAAGAAGAA 12159 Hepal-6 Igsf23 GTGCCACAATCAGAGAGACA 18143 B16F10 Cyp21al CAGATTCTCCAAGGCTGATG 12160 Hepal-6 Igsf23 AGGTCAAAGGTCAACTCGAT 18144 B16F10 Prtg CCCGCTGGACAATGCACCTG 12161 Hepal-6 Igsf23 TCCCGTCTGACGCGGGCAAG 18145 B16F10 Prtg AGGGACACGCTGAGATCGCC 12162 Hepal-6 Cd96 TAACCTTCACAAGAACAATG 18146 B16F10 Prtg CAGATGTAGAAAGTAGTCCC 12163 Hepal-6 Cd96 TTAAAGGTGAGACAGGCGCA 18147 B16F10 Ankrdl7 GACGCCTGCTCGGCTTTCCC 12164 Hepal-6 Cd96 AAGGAGAGAATCTTGGGATA 18148 B16F10 Ankrdl7 TCGCGAGACGAGGTGAGAGC 12165 Hepal-6 Mapk7 GCGCGTGATTGACAAGGGCG 18149 B16F10 Ankrdl7 GAGAGAGAGCGGGAGGGCTG 12166 Hepal-6 Mapk7 CAATCGTTGAGCGGCCTCCG 18150 B16F10 Mroh2b AGTGGACCGGAATGCCTGTC 12167 Hepal-6 Mapk7 GGGTGATGCGTGCTCCTCAG 18151 B16F10 Mr h b CAGAACTCTAAGCTTCCCAT 12168 Hepal-6 Nr2cl GGGTGGACACGCAGCTGCGG 18152 B16F10 M h2b GGTGAGGTCAGTCACACAAC 12169 Hepal-6 Nr2cl CCGGCGGTGGTGACGTTCCC 18153 B16F10 Itpr3 GAGAACGCCCTAGAGCCTGG 12170 Hepal-6 Nr2cl CTATCATCCTCACAGGGCAT 18154 B16F10 Itpr3 TGTAGAAGAGGCCGAGCCTG 12171 Hepal-6 Heatr5b TGCGCGAGACACAGGTCCTG 18155 B16F10 Itpr3 GGCAAGCTGGGCGCTTTAGG 12172 Hepal-6 Heatr5b ATGCGCCGTGCAATTGGCGC 18156 B16F10 Dscam TACACACGATGGGCTGTGTG 12173 Hepal-6 Heatr5b CCGATTCGCTTCGAAACTTG 18157 B16F10 Dscam CAGTCTTAAAGCAGCAGCAG 12174 Hepal-6 Nmnatl CATGGAGCGAGCACTTCCGC 18158 B16F10 Dscam AGTGCGGCGGATCACGCAGT 12175 Hepal-6 Nmnatl CGCGCACTTCCGGCTGTGTG 18159 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Ptgfm GAGGAGGGCCGCGACGAGCC 12176 Hepal-6 Nmnatl CACCGCCGCCTTGCTCTCAT 18160 B16F10 Ptgfm CCCGGCGGAGCAGCCGACTC 12177 Hepal-6 Lrrc63 TTCTTACCGGGCTAGCTGGG 18161 B16F10 Ptgfm CCGGCGCGGACGTGCGCACC 12178 Hepal-6 Lnrc63 CGCACGAGGGTTGGGCACGT 18162 B16F10 Histlh2bf GAGAATTTCTGGAACTTTCA 12179 Hepal-6 Lrrc63 TTCGGCTGTAGCAGGGCTTG 18163 B16F10 Histlh2bf CACCTTTGATTGGTTTATGA 12180 Hepal-6 Mthfdll GCCCTTGCCCTGAGATTGTA 18164 B16F10 Histlh2bf ATTCAAATGAGGGATGTGAA 12181 Hepal-6 Mthfdll TTGGAGTTGCCAGAAAGTCA 18165 B16F10 Rgsll ACGGTTAACCTTAGCGGGCG 12182 Hepal-6 Mthfdll GCCAGCGGACGTGAAGCTTT 18166 B16F10 Rgsll ACTTGGGATAGCCTGCAGTG 12183 Hepal-6 Galm TGCGCAGGTGCGCGCGCGTA 18167 B16F10 Rgsll TTGCAGGCATCTGAGGTTTC 12184 Hepal-6 Galm ACCCTGACTGCAGTGCATGT 18168 B16F10 Ces2a ACTGATAAGGCAGAAGCCAC 12185 Hepal-6 Galm AGAGAGAGAGAGAAGAGGAG 18169 B16F10 Ces2a TACAAATTCCTGCTTGGACC 12186 Hepal-6 Qpct AAAGAGTTTACCAGGCCCTG 18170 B16F10 Ces2a GGAGACAAGAGCCAACAAGC 12187 Hepal-6 Qpct TTTGTGCAATGCTCTGTACA 18171 B16F10 Pet2 TTACGTCAGTGTGCTGTITC 12188 Hepal-6 Qpct CGTATCTATGGACTACAGGA 18172 B16F10 Pet2 AGCTTCCTTTCTCACATCTC 12189 Hepal-6 TrmtlOa AATGGTTAGTGGCTACCGCG 18173 B16F10 Pet2 GTACATCACAGTAGCCGATG 12190 Hepal-6 Ptk7 GGAGCAGCAGTGGCCGTCTT 18174 B16F10 Fanil 17a TGACTTGATGGCTGAGCACA 12191 Hepal-6 Ptk7 AGGAGCTGGCAATAGAAAGA 18175 B16F10 Faml 17a CCCGCCATGGATTGGTTGAG 12192 Hepal-6 Ptk7 CCAGTGGATAGATTAGGCGG 18176 B16F10 Faml 17a CCTCGGCCCAGAGTTCTAAT 12193 Hepal-6 Rest GGCGCGCGCGGACGGCGAGG 18177 B16F10 Itgax GAGGCAGCCTACACACTTCC 12194 Hepal-6 Rest GACGGCGCGGGCCGGGTGCG 18178 B16F10 Itgax GACTTGGTGACATATTGTTC 12195 Hepal-6 Rest CTCGGTCCCGAGGCTCGAAG 18179 B16F10 Itgax CTGAGATGAAATGGATAGAG 12196 Hepal-6 Stambpll GGCCTATGGCCAGATGGAAA 18180 B16F10 Arhgapl8 TGCTGCAGCCTGGGATTGCC 12197 Hepal-6 Stambpll GAATGAAATTGTCACAGCGA 18181 B16F10 Arhga l CTCACAGCTTTGTTTAAACC 12198 Hepal-6 Stambpll GAGGCGGAGGCCGCACCCAG 18182 o o B16F10 Arhga l TGAATCGCTGGCCCGGACAG 12199 Hepal-6 Sema3g TGCCTTATAAGTGGCTGGCC 18183 B16F10 Ocln CGCACGGAGCAACCGGCTAG 12200 Hepal-6 Sema3g TAGTTTGCTCTGCTGCCACC 18184 B16F10 Ocln AAATTGGTGCGCATGCCCGG 12201 Hepal-6 Sema3g TGCACGGGCATTGAGCGGGC 18185 B16F10 Ocln CGTCGCTAGTGCCCACCTCC 12202 Hepal-6 Oog4 ACTCTAGGTCTCTTGGAGCC 18186 B16F10 Pds5a GGAGAGCGGCAGTGTCGCCC 12203 Hepal-6 Oog4 GAAAGGTATATAGTCACACC 18187 B16F10 Pds5a GCTGCGCTTCCTCAGCCCGA 12204 Hepal-6 Oog4 TTTCGATGGTGTCAATAATA 18188 B16F10 Pds5a GAAGCGGGCCGAGCGTGCGC 12205 Hepal-6 C5ar2 TTCTGAGGAGGGTTCATTCT 18189 B16F10 Dyrk3 GAACTGCGAGCACACCACCC 12206 Hepal-6 C5ar2 GAAGTGGGCTGAGAGCTTGG 18190 B16F10 Dyrk3 TGCGCGGTTGCTAAGCGACG 12207 Hepal-6 C5ar2 AGATAGGTGTGTAAGACCCA 18191 B16F10 Dyrk3 CGGTCCGCAGGGAGACCACG 12208 Hepal-6 Mgat3 GGCGAGGCCGAGCGCTGCGC 18192 B16F10 Itsn2 CCCGGAACCGTGGAAGGCGT 12209 Hepal-6 Mgat3 GCCCGGCATCGCAGGCAGCG 18193 B16F10 Itsn2 GAGCGACGGGCGGGCAGTGA 12210 Hepal-6 Mgat3 CCCGTCCCGCGGGCCCGGCG 18194 B16F10 Itsn2 AGCCGCGGAGCTTCGGGACC 1221 1 Hepal-6 Oasl2 CTGCTATAAATACCATGTCC 18195 B16F10 Mvd CTCACGCGCTGCCATATGAT 12212 Hepal-6 Oasl2 GATATATAGATGTGTTTCCT 18196 B16F10 Mvd CATCATTCGATCCTGTCCAT 12213 Hepal-6 Oasl2 GTTACTATTTGTGGTGACTG 18197 B16F10 Mvd CGTGCTGTCCAATAGGCGAC 12214 Hepal-6 Ugtla9 AACGGTTATGAAATATGCTC 18198 B16F10 Fshb GCATTTAGACTGCTTTGGCG 12215 Hepal-6 Ugtla9 TTGCAAGTGACGTTAAATTC 18199 B16F10 Fshb AGCAGGCTTTATGTTGGTAT 12216 Hepal-6 Gml3084 ACTATATAAAGAGTCAAAGC 18200 B16F10 Fshb AAAGGGAATCATTGTTTAGA 12217 Hepal-6 Gml3084 AGACTCAACTATTGATCCAG 18201 B16F10 He GAGAAAGCTAAACTCAGAAA 12218 Hepal-6 Gml3084 ATTGAATCAGATCCATACAC 18202 B16F10 He TCTTTATTACTGGACATGAT 12219 Hepal-6 Slc22a26 GCCAGAGTGAAACTGTTTAA 18203 B16F10 H TAAACTGAGTTTGAAGAGTT 12220 Hepal-6 Slc22a26 TTTCCAGAAATGACCCAGGG 18204 B16F10 Trim71 GAGGAGGGTGGTGGGAGGAG 12221 Hepal-6 Nlip5 AGTGGCTGGTTGCCAGTACT 18205 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Trim71 GTCGTCACACTGAGGCCTGG 12222 Hepal-6 Nlrp5 AGCACGAGCTTAATGCCCAT 18206 B16F10 Trim71 GCTAATGTTTCCTGTTTGCC 12223 Hepal-6 Nlrp5 AAGTTCTGAGTAGCCCTTCC 18207 B16F10 Vnmlr207-ps ACAAGTTATTCTAACTAGGA 12224 Hepal-6 Zfp541 AAGGACGTATTAGAATCAAG 18208 B16F10 Vmnlr207-ps AGGAAACAGGAGAAATTTCA 12225 Hepal-6 Zfp541 TAAGAACAGACCCATCTCAG 18209 B16F10 Scnlb GGGCGGGATGAATCACCGCG 12226 Hepal-6 Zfp541 CAGGAGCTAGCTGCCAGCGA 18210 B16F10 Scnlb CTCCGGACGTTGCTCGCGCT 12227 Hepal-6 Ms4a2 GCATAATTCTGCCAGAGATG 1821 1 B16F10 Scnlb CCGCCCAGCCTTTGCCGCAG 12228 Hepal-6 Ms4a2 TACTTGTCAGATAAGTCTCC 18212 B16F10 Nckipsd CCTCGCGGCCGAGAGAGGTT 12229 Hepal-6 Ms4a2 GTCACTGATATCAATCAGCC 18213 B16F10 Nckipsd CGCACGCGCGGCGTGTCACG 12230 Hepal-6 Larp4b CTGCGTAGCGATTGGCTAAG 18214 B16F10 Nckipsd TGGGAGTCTCCAGTTCCTTC 12231 Hepal-6 Larp4b AGGAGAGCCTAGCGTCATGG 18215 B16F10 Mta3 GGGCCACCCGCACTAGCCTC 12232 Hepal-6 Larp4b GGCGCCAAACGCCAGTCGGC 18216 B16F10 Mta3 GGGTAGCACACCAGGGTCAG 12233 Hepal-6 Pex6 ACGGAGGCGGTCGTCAAGCC 18217 B16F10 Mta3 CGTCGCTCTGCCGGCGCTGG 12234 Hepal-6 Pex6 ACGCGCCCTTTGAAACTCAG 18218 B16F10 Frmd6 CGGTCTCCGCCTTCAATTTG 12235 Hepal-6 Pex6 TTCCGGTAGGAAAGTGGGCG 18219 B16F10 Frmd6 AGGGAGGGCGTGTCTCGGGC 12236 Hepal-6 Fam214a CAACAGTGCACTCAGCTGAT 18220 B16F10 Frmd6 CCGTGGGCGTGAACTCGAGG 12237 Hepal-6 Fam214a GGTAGATGCGCGCTGCGCTC 18221 B16F10 Gg l TGTTTAGCTCTTAAAGCCCT 12238 Hepal-6 Fam2 14a GTTGTTGGGACACGTGACCA 18222 B16F10 Ggal TTGACATCTTCCCACGTAAG 12239 Hepal-6 Hnmpll GAGCAGTTCTTCCAGCCAAT 18223 B16F10 Ggal TGGCCGCCGCCAACGCGATG 12240 Hepal-6 Hn pll GGAGGCGGAAGTTCGGCAAG 18224 B16F10 Pcdhb21 ACATGGTGGCGCTGCAGGAC 12241 Hepal-6 Hnmpll GGGCGGAAACTCTCGGGCCC 18225 B16F10 Pcdhb21 CAATGACCTGCATAGTCACA 12242 Hepal-6 Safb2 GGTCAGTGAGCGTAGCGAGG 18226 B16F10 Pcdhb21 ATGTTTCTCAACAGCAGCTC 12243 Hepal-6 Safb2 CAAAGCAGTCTCGAGCCTCG 18227 B16F10 4931431F19Rik GGTGCTTAAACCAAATCATG 12244 Hepal-6 Safb2 ACAGCTCTGACGCACCTCCT 18228 o B16F10 4931431F19Rik TTTCTAGACACTGACATGTC 12245 Hepal-6 Histlli2bf GAGAATTTCTGGAACTTTCA 18229 B16F10 4931431F19Rik AGTTGAAAGGTACATCTGAA 12246 Hepal-6 Histlh2bf CACCTTTGATTGGTITATGA 18230 B16F10 Atp2b2 CGCTGTCCGAGCCGAGTTCG 12247 Hepal-6 Histlh2bf ATTCAAATGAGGGATGTGAA 1823 1 B16F10 Atp2b2 GCTCCCACGGGACGCATCCG 12248 Hepal-6 Nekl TTACGGAATAGGAAAGCTAG 18232 B16F10 Atp2b2 GGCCCACCTGCGTGAGTGGC 12249 Hepal-6 Nekl TACAGTCCGTT CGCTTCGCC 18233 B16F10 Prg2 GAGCGAAGAATCCTCACTCT 12250 Hepal-6 Nekl GGGCTGGACTAAGAGTGATG 18234 B16F10 Prg2 TAATCCTTAGTCACCACATG 12251 Hepal-6 Nccrpl GATGTGTATCCTCCTCCTTA 18235 B16F10 Prg2 CACAAACCTTCCTTCCCTAG 12252 Hepal-6 Nccrpl GAGGTCCTCAGCTGGCCCTG 18236 B16F10 Uspl71d CACTTGCAGAGATTCTCTGG 12253 Hepal-6 Nccrpl AGAAGAATGAGAAGTTGAGG 18237 B16F10 Uspl71d AACCACACCCAACTAGGGAG 12254 Hepal-6 Arhgefl5 GAATCCGGCATCCAAGATGT 1823 8 B16F10 Uspl71d TGTAGGTGTGGTCACAAGAC 12255 Hepal-6 Ar gefl CACCGGGCCTAGAGGATGTG 18239 B16F10 Zfp386 CATCAGATAGCACCAACCCA 12256 Hepal-6 Ar gefl AATCCGATCCTCCTCCCAAC 18240 B16F10 Zfp386 CTTGCCTTTCGGACCTCATT 12257 Hepal-6 Crhr2 CCCGTCGGGACCGCGGCTCT 18241 B16F10 Zfp386 CTTCGACGGATTTAG TTTCC 12258 Hepal-6 Crhr2 CATGAATCCTCGGGCCCTCC 18242 B16F10 Dds23 AAGCCGGGAAAGGGAGTTCC 12259 Hepal-6 Crhr2 TTCTCTTGGCCAAGGTCCTG 18243 B16F10 Ddx23 CGAGGGCCGGCCAGGCCGTA 12260 Hepal-6 Cd5 GGGCAGGTGGTTTCACAGGG 18244 B16F10 Dd 23 TGGGTAATGTGGTTTGCCAA 12261 Hepal-6 Cd5 GTGGGCACTACCGCAGTTCC 18245 B16F10 Scap TCCATGCTTTATAGTGCCAA 12262 Hepal-6 Cd5 GTTCTGCCCAGCCATGAGAA 18246 B16F10 Scap GGAAGTACTGGAGTTGCCTG 12263 Hepal-6 9430007A20Rik TTTGAAGGTTATAAGGCACC 18247 B16F10 Scap CCCTGCCACACAACTGCGAG 12264 Hepal-6 9430007A20Rik GGATCCTTCCATTATCTAGA 18248 B16F10 Catsper3 GCATTCTAGCTGTCACTAGT 12265 Hepal-6 9430007A20Rik TGACAAACTATTCTGCCCTG 18249 B16F10 Catsper3 GGGTGAGTACCTAGCAACCC 12266 Hepal-6 Kl d CAGTTCACGTCGCACGCCTG 18250 B16F10 Catsper3 GAAGGGTTCTCTGCnTATG 12267 Hepal-6 lhdc3 TTCTGCGCATGCGCACAAAC 18251 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Megf8 TTGCCTGGCCCGGAGACTCC 12268 Hepal-6 lhdc3 GTCCTCGCTTGCGTCAGTCT 18252 B16F10 MegfS GTAGGCATTAGAGTGAGCCC 12269 Hepal-6 Ccs CCCGCTCAGCCGGAACCACC 18253 B16F10 MegfS GATGTGCTCTACAGCCCAGC 12270 Hepal-6 Ccs AGGACGCCAAATGGTTACTA 18254 o B16F10 9130011E15Rik CGGGAACGCGCCCGTGATTC 12271 Hepal-6 Ccs AGCACTACCGGACAGCTCAG 18255 B16F10 9130011E15Rik CTGAACCCGCTTCAGGAAGA 12272 Hepal-6 Zcwpwl AGGTGCTGCGCGTGCGCAGT 18256 B16F10 9130011E15Rik GAAAGAACCTGAAGAGCGGA 12273 Hepal-6 Zcwpwl ATGGAACTTGTAGTTTCACT 18257 b B16F10 Dnahll AAATGCTCAATGTTTAACTG 12274 Hepal-6 Zcwpwl CTTAAGATGGCGGGCTACTC 18258 o 4 B16F10 Dnahll TCCTGCTAAATTTGCCGCCA 12275 Hepal-6 Ceacam5 TGTTATTCTCTGAGGGCATG 1825 9 6/ B16F10 Dnahll TTATCTAATCCCTAGAAAGC 12276 Hepal-6 Ceacam5 TCTTGGAGGTAGAACATAAA 18260 B16F10 Add2 GCTGCTGCAGGGCGCGGGCG 12277 Hepal-6 Ceacam5 CATCCTACCTAGGTGTCCTT 1826 1 B16F10 Add2 TGGAAGAATGAAGAATCATG 12278 Hepal-6 Mcmbp TTTGGAGACGGAGACAGGTC 18262 B16F10 Add2 ATCTCACGTAATAACCACTG 12279 Hepal-6 Mcmbp GTCGCTGGCAGCGCGGTCGG 18263 B16F10 Jmjdlc TCCAGCACGAGTCACATTAC 12280 Hepal-6 Mcmbp TTTCCCGCCATTGTGA GAAG 18264 B16F10 Jmjdlc GGTGATTACTCATTTGGCTG 12281 Hepal-6 Vmnlr88 AATATACTGATTGACATCTC 18265 B16F10 Jmjdlc CGGCCCACAGGCAAACTGAC 12282 Hepal-6 Vmnlr88 GGTCTAGAGTACTAAATGAA 18266 B16F10 Gcnt7 TGTGCATGACACGCCAGGTG 12283 Hepal-6 Vmnlr88 TAAAGTGGGTCAGGTTGGTT 18267 B16F10 Gcnt7 AGCCCTGAGAGATGCTGATA 12284 Hepal-6 Pou6f2 CCTCAGTATAAAGTCCAGCC 18268 B16F10 Gcnt7 ATCAGGATCAACAAGAATAC 12285 Hepal-6 Pou6f2 TCAGGATGACCAATGTCAAC 18269 B16F10 Dmd TCCATGGGCAGTCCTATTAT 12286 Hepal-6 Pou6f2 ATGTCATAGGACAGACACTA 18270 B16F10 Dmd GGAAAGCAACTTGAGAGAAA 12287 Hepal-6 Ttc CTTTGCTGAGCAACGCGCAA 1827 1 B16F10 Dmd ACTTGCTTGTGCGCAGGTCC 12288 Hepal-6 Ttc TGGCTGAGGTCGGCTCTCAG 18272 B16F10 Kcn 2 CACCTGAAGCAGGATTCCTC 12289 Hepal-6 TtcS CTGCGGACACCTCCTTAGCC 18273 B16F10 Kcnb2 ATAACTTACCTGGTTGTGAC 12290 Hepal-6 Aimp2 CCTTTGAGTTGGCCAATCAC 18274 o B16F10 Kcnh2 GTTATTCACATTGCTCCCAC 12291 Hepal-6 Aimp2 TTCGCTAGCCCGCCCGGAAG 18275 B16F10 Hdac4 TGCTCTTCTCGTGGATTACT 12292 Hepal-6 Aimp2 GCATGCCAAGACCTCTTTAC 18276 B16F10 Hdac4 GACTTCAAGTTTACGCAGCT 12293 Hepal-6 Mdfic GGCTGTCTGCCAAGAGTTCG 18277 B16F10 Hdac4 TGAACACCACTACCTAACTA 12294 Hepal-6 Mdfic ACCCAGACAGCTCCCTCGCA 18278 B16F10 Spinkl CTCTTCCTTATAAATGTGAC 12295 Hepal-6 Mdfic AACAGGGAGGGAGCTAACCT 18279 B16F10 Spinkl GGAGGTAATGCAAATAGCCA 12296 Hepal-6 Slc26a8 ATTAGCTTTCTCGGCTTCTA 18280 B16F10 Spinkl TGTTGATATGTCTCATGCAT 12297 Hepal-6 Slc26a8 ATTCCACTAGGTGGGAATGC 1828 1 B16F10 Desi2 AGTCCTGCGAAGAGTTTGTC 12298 Hepal-6 Slc26a8 ATTCTGACCGCATCTCATTT 18282 B16F10 Desi2 AGCATTCACCAGGATATTGT 12299 Hepal-6 AI837181 CTAACGTTCGTACTTTAGCT 18283 B16F10 Desi2 GAACCTTCGCTGTTCGTCCT 12300 Hepal-6 AI837181 GGGAGGTGCAGGTCTTCGGG 18284 B16F10 Mdml TCGCCCGCCATTAGGGAGCG 12301 Hepal-6 AI837181 CGGAGCCGGCGCGAGAATCC 18285 B16F10 Mdml GGCCGTGCCCTTACGAGTGC 12302 Hepal-6 Mvk ATGTTTGACCCAATCTGTAA 18286 B16F10 Mdml GGTTGGTCTAATCGTAATGA 12303 Hepal-6 Mvk TATCAGATGGGAGAGTTCCA 18287 B16F10 Gpsm2 GCGAGCCTGGAGCTAGGCGC 12304 Hepal-6 Mvk CAATCAGAGAGCTGGAGCTA 18288 B16F10 Gpsm2 ATCAAGCGCTACAGTCCGAG 12305 Hepal-6 Triml7 ATTGTGGCGTCAACTCACGC 18289 n B16F10 Gpsm2 TTTGGACCGGCCAATGGCAC 12306 Hepal-6 Triml7 GTTGCTTGGCAGAGATGCCG 18290 B16F10 Hmg20b CCCAAGGATAGCGCTCTAAT 12307 Hepal-6 Triml7 TCGTTGCTTAGGGTGGAGCC 18291 n B16F10 Hmg20b GCGGGCGGGTGCGTCAAGTT 12308 Hepal-6 Scly GGTCCTATCTAACCGGTCAT 18292 o B16F10 Hmg20b TTGGACCGTCGCCGCGTCTC 12309 Hepal-6 Scly ATGACCAATCAACCAGTCAG 18293 B16F10 Pcbp3 GGTGACCATCACAGCCAATC 12310 Hepal-6 Scly TGGCCAATCTGTGAGCCGCA 18294 B16F10 Pcbp3 GACGCTAAACGGCTTCTAGC 1231 1 Hepal-6 Zfand4 CCTGAAAGCCCGTGCGACCC 18295 B16F10 Pcbp3 AAGGGCGGTTAGGGTTGGGC 12312 Hepal-6 Zfand4 GCAGGCTTTGCATTATAAGC 18296 6/ B16F10 TUI10 TCAGATGGCGTTGTGAACTC 12313 Hepal-6 Zfand4 GGGAGAGGTGTCTGGTTACT 18297 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 TtlllO ATGATTCAGCAGCTGCCCAA 12314 Hepal-6 Adam25 CCTAGCAACAAGAGACTCTC 18298 B16F10 TtlllO GAATGGGTCAAATTGATCTG 12315 Hepal-6 Adam25 GGAITCAATAGAAAGCTAAG 18299 B16F10 Nfikb AAGGCACGATCCATTCTGTG 12316 Hepal-6 Adam25 CAGAACAGTGCAACTAGCTA 18300 B16F10 Nftkb GGCGGTTCAGGTGCTGCCAC 12317 Hepal-6 Usp37 GGAITTCGAATCTACAGTCC 18301 B16F10 Nfikb TTGTGGCACCAGACGCGTCG 12318 Hepal-6 Usp37 CTTTGTTTAGTCAGTCTCCT 18302 B16F10 W o TGCTTACCCAGTCATCATGC 12319 Hepal-6 Usp37 GGAGAGAGGGCACTTTCATT 18303 b B16F10 Wwox TTTGCAGCTACTGGCGGGAA 12320 Hepal-6 Tet3 TGCTGGGCAGGTCCTTGGCG 18304 o 4 B16F10 Wwox AGCAGGAACGGCTCAGAAAC 12321 Hepal-6 Tet3 CGTCTTGTGTATGTTGCCAG 18305 B16F10 Ryr3 AGGAATGGGAAATGGGATCT 12322 Hepal-6 Tet3 TGCCTGGGAAGCAGCCCTTG 18306 B16F10 Ryr3 CAAATCTACTCTTTCAATCT 12323 Hepal-6 Cmya5 ATCCAGAGAAGATAACGTTA 18307 B16F10 Ryr3 TGGTTTATGGAATATCTGAT 12324 Hepal-6 Cmya5 CAGATCTTCAGCGGCCTTTG 18308 B16F10 Cldn4 TCAGTCCCGGAGGCCTCCCT 12325 Hepal-6 Cmya5 CGGGTGCTTCGTGCCAAATG 18309 B16F10 Cldn4 GATACTGGCGGGTGACTCAG 12326 Hepal-6 Nop58 GCAGAGCGTGAGATCATTTC 18310 B16F10 Cldn4 GGGCCAACAAAGGCGTTCAG 12327 Hepal-6 Nop58 TTCCCGCCCACAGTAGAATC 1831 1 B16F10 Denndla GGAAGCGCGCAGCAGGACAG 12328 Hepal-6 Nop58 GTCTCCTTCTCTAAGAATTC 18 1 B16F10 Denndla AAGTGTAGTCCACTCGCGTG 12329 Hepal-6 Car2 GGGAGCGTCCTAGAGGCTCC 18313 B16F10 Denndla GCAGTGGGACAAAGGTCCCT 12330 Hepal-6 Car2 GGCCCGCACGCACGCGGCTG 18314 B16F10 Mup7 ATCAGATGCAACTTTGGATC 12331 Hepal-6 Car2 CCAGGTCGGTGCTCACAATG 18315 B16F10 Mup7 TTCCTTGCCCTTTGCAAACT 12332 Hepal-6 Zfp317 TTTATAACGTGAAACCTTCA 18316 B16F10 Mup7 TGTTCAAGAGAACTGCCAAC 12333 Hepal-6 Zfp317 GCTTCTAAATGAGATTGAAA 18317 B16F10 cn 9 GGAGTCGAAGTTGCAAGCGG 12334 Hepal-6 Ζ 317 CTTAATGAGCCGTGCATTCT 18318 B16F10 TGACCAAGCCTCCTCTACGA 12335 Hepal-6 Gm609 CAAGACCTCCAGCTCAAGGG 18319 B16F10 Kcnk9 GCATTGGGATTCTCGTGGTC 12336 Hepal-6 Gm609 TTCACATGACTTGCTTAGCC 18320 o B16F10 Trp53 TTGTGCCAGGAGTCTCGCGG 12337 Hepal-6 Gm609 GCATGAAACTCAGCCTCATT 18321 B16F10 Trp53 GTCTAAGATATAGAGCTGTG 12338 Hepal-6 Itihl GATGGTTTGTCTACCGTTGT 18322 B16F10 Trp53 GATAGTCGCCATAACAAGTA 12339 Hepal-6 Itihl TGAGCTGGGACGTAGCTCAC 18323 B16F10 D230025D16Rik GCGTGCCGGGCCGTAAAGCG 12340 Hepal-6 Itihl GGAGGCAAATAGCAGGGTTT 18324 B16F10 D230025D16Rik GAGCAGCTGCTTTAGAACTT 12341 Hepal-6 Lilr4b GATATGTGTCCTAAAGGATG 18325 B16F10 D230025D16Rik GATCAGAGGCCAGACCCGCG 12342 Hepal-6 Lilr4b ACATCATAGCTATTATGAGA 18326 B16F10 Gm6086 CTCTCTCATCCACGCACCGC 12343 Hepal-6 Lilr4b CTGCTCTTAGGAAATTACAG 18327 B16F10 Gm6086 GGATACAGGTGAATCCAATT 12344 Hepal-6 Ptprk TGGCGAACAAAGGCGGCGCG 18328 B16F10 Gm6086 GTGTCTTATATGAGGAAGTC 12345 Hepal-6 Ptprk CCCGCGGGCTCCGGCAGCTT 18329 B16F10 SytlO TGCCCGCGCCAGCCTGCCAT 12346 Hepal-6 Ptprk CGCGTCTCCCTAGCAGGAGG 18330 B16F10 SytlO CGCCAACGGACGCTGCTGCC 12347 Hepal-6 Nidi CGGGTTGGATCCGGAATGCT 1833 1 B16F10 SytlO TCCGAGGAGAAGCGCAGACC 12348 Hepal-6 Nidi CCGCCTGTCCCGTCTACCAA 18332 B16F10 Apbbl AAATGGTTGAACATAGAGCC 12349 Hepal-6 Nidi CAACGCCCACTGCTGCGCGG 18333 B16F10 Apbbl GACCGTGGCTGCGCCTCAAG 12350 Hepal-6 Zcchcl8 GAATGAAATGTAAATGGGCC 18334 6F1 Apbbl GACAGGCAGTCTCAAGATCC 12351 Hepal-6 Zcchcl8 GTGGCCAATCAGCTGTTCGC 18335 n B16F10 Gtpbp3 GTGTTCCGGGATAGGCATCC 12352 Hepal-6 Zcchcl8 GCGCGGCGTCAAGTGCAGCT 18336 B16F10 Gtpbp3 GTTAACCCGAAGTTAACTGG 12353 Hepal-6 Dmkn CATGGAAGGAAAGAGGACTG 18337 n B16F10 Gtpbp3 CTGGGCAAGTATCTTTAGCC 12354 Hepal-6 Dmkn AATCCTGAGTTGGGTGGAGT 18338 o B16F10 Far2 CGGCTCAGAAACTGGGTGTG 12355 Hepal-6 Dmkn ACTGGAGGAGGGATCTTAAG 18339 B16F10 Far2 ATATATAGAGAGTCACGTTT 12356 Hepal-6 Larpl GGCGCGCCTAGCCGGCCTGG 18340 B16F10 Far2 CTGGGCGCCCAGCAGCGACC 12357 Hepal-6 Larpl CGGGCGCGCGCCTCGCGACG 18341 B16F10 n l CAGAATAATCCTGAACCGTC 12358 Hepal-6 Larpl GAGCCAGACCACGCGATCCG 18342 J B16F10 Fancl AAGATCACTCACAAGTCCAC 12359 Hepal-6 Dbt TCCCACCGGGCAGCCAACCA 18343 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Fancl CAAAGTAGGAAAGTCAGCTT 12360 Hepal-6 Dbt GCTCGTTCCTTCTCTCCTAT 18344 B16F10 Wbscr28 GTAAAGGGAGCTATGGCAAA 12361 Hepal-6 Dbt AAAGAATTGAGGGAGGGAGA 18345 B16F10 Wbscr28 TAGGTAGACAATTGATCCTA 12362 Hepal-6 AI3 14180 CCCTCTGGGCTTTAACTTCG 18346 B16F10 Wbscr28 TAGTGTGTCATGTGGCAACT 12363 Hepal-6 AI3 14180 GCTCGGGAGGCTAACGTTAG 18347 B16F10 Avprla AAGTCATGCAGCGCGTCAAC 12364 Hepal-6 AI3 14180 CCTGCACCGAGGGCTCACCC 18348 B16F10 Avprla GGGCAGATCCGGAAAGCGCC 12365 Hepal-6 Casp6 GTGGCGTCCTGGCGTTGCCT 18349 B16F10 Avprla AATTGGCTTATAAAGGAGGC 12366 Hepal-6 Casp6 TCTTCCTCCTGCACAGAGCC 18350 B16F10 WntSb GATTGGCTGAAGGACTTAGA 12367 Hepal-6 Casp6 ACAAAGGGCCCAGTTGCTTG 18351 B16F10 Wnt8b TGATCAGCTCAATCTTTCTC 12368 Hepal-6 Tcte2 TAGAACGCACGCGCGCCGTG 18352 B16F10 Wnt8b CCTTCTGCGTTTGTCCGTCC 12369 Hepal-6 Tcte2 CTGCGTACCGCCAGCGCACG 18353 B16F10 Rslldl TGTGCCCAGAGTTATTCTAG 12370 Hepal-6 Tcte2 GGAAGCGTTCTGGACGATCT 18354 B16F10 Rslldl AGATGTTGGGCCCGCCCTCT 12371 Hepal-6 Met GGACGAACAGACACGTGCTG 18355 B16F10 Rslldl GTATCACGTCATTTCCGGCG 12372 Hepal-6 Met GGGACAAACCTAGAGCGACA 18356 B16F10 Slit2 ACCTCTCCCGGGCGAGGTGC 12373 Hepal-6 Met CTTCCCACACGCGCCCTGCC 18357 B16F10 Slit2 GCTTTCCGCGCGCGGCCAGG 12374 Hepal-6 Rwdd3 CCGACCTGGCTGTGAGGCCG 18358 B16F10 Slit2 GCCGGTCTTTATATAGCAGC 12375 Hepal-6 Rwdd3 GATGGGCGTGTTTATGGGCG 18359 B16F10 Bodll TGACAGCAGCAACTCAAGTC 12376 Hepal-6 Rwdd3 GCCCAGAACCTTCTGAGTTT 18360 B16F10 Bodll CGGCTCTCTGTTTCGCTCCC 12377 Hepal-6 Zbtbl7 GCACTAACTTTCGGCTGGCA 18361 B16F10 Bodll GAATTGGCCCGCCGCGGCCC 12378 Hepal-6 Zbtbl7 GACGAGCGCTGCGCCAGCGA 18362 B16F10 Intsl GCATAAACTGTTCCCTCTTA 12379 Hepal-6 Zbtbl7 CCGGTGCACAGCAAGTGTCC 18363 B16F10 Intsl GTGAGAAATCAGCGCTCGGA 12380 Hepal-6 Tbcld30 ACAATITGGGCTGAAGGTTG 18364 B16F10 Intsl AGGGCGGTGCAAACACTAGT 12381 Hepal-6 Tbcld30 AGTATCCTCACGTCTAAGCC 18365 B16F10 Myrf GCTCTGGGCGTACCGCCAGA 12382 Hepal-6 Tbcld30 TGCTTCGTGCTGGAGTGGAC 18366 o B16F10 Myrf TCGACGCGGCGGTGGTGTCC 12383 Hepal-6 Hrli3 TTGGCTGCGCGCTGAGCTAG 18367 B16F10 Myrf CACCCTGCTACCCGAGGTTG 12384 Hepal-6 Hr 3 CGGGCACGCGGCGCTGTCCG 18368 B 6F1 c GCCTTGTTAGAGATAGAGTA 12385 Hepal-6 Hrh3 AGGGCGCCAGCCAATGGCGG 18369 B16F10 c TGAACTTTAAGCCTAACTCC 12386 Hepal-6 Lbx2 AGGCCCTTGGAAGGAGGTGG 18370 B16F10 GATCTGATAAGGTAGTGGAA 12387 Hepal-6 Lbx2 TCGGGTGCCCATAGGTGTAC 18371 B16F10 Chordcl GAAGCGGAAGACTCGGCGAG 12388 Hepal-6 Lbx2 CCAGCGCTCAGCTTCCGATC 18372 B16F10 Chordcl GTGTCTCATCTATAACTGTC 12389 Hepal-6 Atp5j CCGAAGGGAGCTTGAACTAG 18373 B16F10 Chordcl CCGGAAGACGGGCCAGCGTC 12390 Hepal-6 Atp5j CTCCCTCAAGTCTCCACGAA 18374 B16F10 Rre l CCGTCACGAGCACAGGAAGG 12391 Hepal-6 Atp5j GGAGTCTTAGCTGAGGGACC 18375 1 F1 Rrebl ATAAACTCGGCGGCGCGGGT 12392 Hepal-6 Tpmt TATCCAGGCTCCGGTCCTAT 18376 B16F10 Rrebl TGGCTGGGTACGAGCTTTGG 12393 Hepal-6 Tpmt TGGGCAGAGTTCTCACGCCC 18377 B16F10 Nlrp9b ATTTGACTAGTCTCACTTGT 12394 Hepal-6 Tpmt GGCGTGGTCTGCACGCTGGG 18378 B16F10 Nhp9b ACTCTTAGTTGCTAACCAGC 12395 Hepal-6 Fstl5 GCCAGGCTGCCCGTCAACCC 18379 B16F10 Nlrp9b TATTAAGTGTCCCGTTAAAT 12396 Hepal-6 Fstl5 GTTCAGCTACCGCAATCCAG 18380 B16F10 Lenep TTTAGTCATGAGGCCTGAAG 12397 Hepal-6 Fstl5 CTGTGAGGATTTCACACCCA 18381 B16F10 Lenep AAGGTTCTGGGCCTCTGAGC 12398 Hepal-6 Sept6 CGGAGGACGTGGTCACCGAG 18382 B16F10 Lenep GAATGGTGGTTAGGGCGGGC 12399 Hepal-6 Sept6 CCTTCCAGCCTCAGGTCTGG 18383 B16F10 Mast4 CAATGGCAGCGCAGGCGCGC 12400 Hepal-6 Sept6 GCAGAGGTCGGGACGTACCA 18384 B16F10 Mast4 GGGATCGGGTGGCCCGCTCC 12401 Hepal-6 Mpp5 CGGTCTCGCGTCAGCCGCGG 18385 B16F10 Mast4 GGCCGCGCGGGCGTCAGGTA 12402 Hepal-6 Mpp5 CGCCTATCCCAGGCCGTTCC 18386 B16F10 AW551984 TTCCCAGCAGCCAACAGCAG 12403 Hepal-6 Mpp5 CGGCCTCGAGGAGGAGTTGC 18387 B16F10 AW551984 GGACATTGCCTTCCCTTCCC 12404 Hepal-6 Fbxo27 ATTGTCTGGGATTAAGGTCA 18388 B16F10 AW551984 AGCTAACCATGGAGGAGACT 12405 Hepal-6 Fbxo27 AATCTCAGAGAGGTTTCGCC 18389 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Nlrc5 TTCGGTTGGCATTCGGCTAA 12406 Hepal-6 Fbxo27 TGCCTAATACTATCCTTCCC 18390 B16F10 Nlrc5 TCATCTGGGAGATGAGCCTC 12407 Hepal-6 Histlhla GTTAGTITCTGAAATCTTGC 18391 B16F10 Nlrc5 AGCTGGCCGTGCAGAGAGGA 12408 Hepal-6 Histlhla CTAGGTCGGTGGAATCGCAA 18392 o B16F10 Lyst GGACTTTAGGCGCTCGAGGC 12409 Hepal-6 Histlhla TCTATAAATACTCCGTGCAG 18393 B16F10 Lyst CCTCAGGTAACCCGGGAAAC 12410 Hepal-6 Rgsl9 GGTCAGGGATTCGGTGCTTC 18394 B16F10 Lyst AGATTCTCCACGCATCACGT 124 11 Hepal-6 Rgsl9 TCCGAAGTCCTGCTGGTCGC 18395 B16F10 Tssk4 GCTTGAAATGAAGTGCAGTT 12412 Hepal-6 Rgsl9 GGCCCTGGCGATATAGATGC 18396 oi 4 B16F10 Tssk4 CTGTTGTTACTTCCATATCT 12413 Hepal-6 Tekt5 GTGCCAGGTCCTGGTTCTCC 18397 B16F10 Tssk4 TTGTGGCCAATGATGAATAA 12414 Hepal-6 Tekt5 ATCCCAAGAGCTAGGAGCCG 18398 B16F10 Zfp865 ATCTCTGAACGTCCCGTTAT 12415 Hepal-6 Tekt5 GGGCCTCTGTGACTTAGTGC 18399 B16F10 Zfp865 TGGCTTGAGACCCGAGTCTA 12416 Hepal-6 Rail4 GCCCACGGGATCCAGGTCGG 18400 B16F10 Zfp865 GAATAGAACAAACTAATCGG 12417 Hepal-6 Rail4 GGTCAGTGGGCGCTCAGCTC 18401 B16F10 Luc712 AACGCGCTCGGGAGCCGTTA 12418 Hepal-6 Rail4 AGTGGCTAGCAACTCCCTCC 18402 B16F10 Luc712 GGTGGGACCCTTCGTAGGAG 12419 Hepal-6 Khdcla AAACACTCCCACTTCCTGAA 18403 B16F10 Luc712 CGCCTAGTCGTTTCCCGTGG 12420 Hepal-6 Khdcla AATGAGGTTCTGGGCAGCCA 18404 B16F10 Ctr9 GTCCCGGAAGCACTACCAGT 12421 Hepal-6 Khdcla ATGAGGTCCTGTCTCAAGGA 18405 B16F10 Cti9 GTTGTTGTTGTGTCAGCCGT 12422 Hepal-6 Gm648 ATGCCTGTGCTTGTGGAGGC 18406 B16F10 Ctr9 AAGGACGCATCAGAGCCGCC 12423 Hepal-6 Gm648 AAACTAGTGTAGAAGGCACT 18407 B16F10 Arhgap36 TTGGACTCCCTTTGCGTTGG 12424 Hepal-6 Gm648 CCTGAGGCAATCTGACCAGC 18408 B16F10 Arhgap36 TGTTAGCTCCCAGAGGGCAG 12425 Hepal-6 Pwwp2b CTGTGTGCCGGCCGCCACCG 18409 B16F10 Arhgap36 AGCTGCTCTAGACAGGAGCT 12426 Hepal-6 Pwwp2b GCAAGCCCAGCTTTGAGAGC 18410 B16F10 Trpm6 AACCGAACCCAGGGTCGAGG 12427 Hepal-6 Pwwp2b ACGTCAGGCGGCGTCACGCG 18411 B16F10 T pm6 CAGGGCGCGCGTGTGAGTCC 12428 Hepal-6 Tubgcp2 GCAGCGGCACCTGTACTTGC 18412 o B16F10 T pm6 AGACTGCGGGTCCTGCCCTT 12429 Hepal-6 Tubgcp2 CTTCCTGTGGCGACCCTGCG 18413 B16F10 Pelpl TAAGTGCGACGCACGCCGCT 12430 Hepal-6 Tubgcp2 CCCTGCACTATATTCCCGCC 18414 B16F10 Pelpl CGGCTTGCAAACTGCTAACC 12431 Hepal-6 Ggpsl GTTATCCCTCAATACTTTCT 18415 B16F10 Pelpl CCTGCTGGGCTGGATGAATG 12432 Hepal-6 Gg sl ATGTCCGTCAGTTTACCGAT 18416 B16F10 Ne od GATGTGTTTCGCCCTGCCAA 12433 Hepal-6 Ggpsl GCCTGCGTTCGACGAGAGAG 18417 B16F10 Ne od6 TATTCCATTCATTTGCAAGG 12434 Hepal-6 Nlgn2 AAATGTCCAGGGCAGGGTCG 18418 B16F10 Ne ro d TCTAGCTGCTCGGGTCTCAC 12435 Hepal-6 Nlgn2 GCCTGCGGGTGGGAGAAAGG 18419 B16F10 Tgtp2 CCTGGAAATGGCTAGCTTGT 12436 Hepal-6 Nlgn2 GAAAGAGGCACCCTGAGTCT 18420 B16F10 Tgtp2 TGCAGTATGGTGTGTGTGTT 12437 Hepal-6 Farp2 GCTTTGCTTCTGACTTTATG 18421 B16F10 Temn2 GACTGTGATGACAAGCAGTG 12438 Hepal-6 Farp2 CCCGCGGACGCACCACCGAT 18422 B16F10 Temn2 TAGAGGTGTTTGTAGACTGG 12439 Hepal-6 Farp2 AGCTCTGATTGGTGATCACA 18423 B16F10 Tenm2 GGGAAACTGCCAACCITCTT 12440 Hepal-6 Tmem245 TTGTAGTTCCCAGCGTGCGG 18424 B16F10 Dlgap2 CCGGTGCGTGGCTCCATCTG 12441 Hepal-6 Tmem245 GGCGGTGCAGCGAGGATTTG 18425 B16F10 Dlgap2 AGCCTGGCCCAGAGGTCGCA 12442 Hepal-6 Tmem245 GCATTTGCGTTCAGCCTCTT 18426 B16F10 Dlgap2 GGGAGGCACCGGCGCACTGG 12443 Hepal-6 Noct GTAACAGTCCAAATTACGTC 18427 n B16F10 Ape ATCTTGTTGGAGGCGGGAAG 12444 Hepal-6 Noct GGAGGGCTGGAAGTCACACC 18428 B16F10 Ape CGCAGTCCAATCCCTCATTC 12445 Hepal-6 Noct AAATGAAGGCTAAGGGAATT 18429 n B16F10 Ape GAGTGTGGCTGCCGGAAACC 12446 Hepal-6 Mytll TTAACAGAAGGTCATATGCC 18430 B16F10 Parpl4 CTTCTTTCGCTTTCATTTCC 12447 Hepal-6 Mytll GACAGCAGCCCGCCCGAGCA 1843 1 B16F10 Parpl4 ATTCCAATCCTGGGATAGCG 12448 Hepal-6 Mytll GCTTATCAGTCATGCAAATG 18432 B16F10 Parpl4 GAAGATAGAAACTAAGGACG 12449 Hepal-6 Adgrl3 GCATGAGGGCGAGTGTGCGA 18433 B16F10 Rnf43 GAGGACAGTAGCTCTCGTCT 12450 Hepal-6 Adgrl3 ACTCATCTGATCGTGATGCG 18434 B16F10 Rnf43 AGACCAAGTGCTCGCACTAC 12451 Hepal-6 Adgrl3 CGATGGGCTGGCAACCGAGG 18435 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Rnf43 AAGCATTTCCAGAGTTCTTG 12452 Hepal-6 Torlaipl TCATAATTAGGTGACTGACA 18436 B16F10 Abcc5 AACCTTCTCTGCCTTAGTCA 12453 Hepal-6 Torlaipl GGCCAGTTGCCCACCACCGG 18437 B16F10 Abcc5 GGGCAGCACGAGATGCGCGC 12454 Hepal-6 Torlaipl GGATATAACTGAGTCACAGG 18438 B16F10 Abcc5 TTTGCGGTGTGCGGCGCTGG 12455 Hepal-6 Ust CCTTTCTCTCTGGCGCGAGA 18439 B16F10 Rass CTGAGTCACCTCGGTAAAGT 12456 Hepal-6 Ust CCTGGGCTCGACGCTGGACT 18440 B16F10 Rassf8 GGCGTGGACGCTATCACAGT 12457 Hepal-6 Ust TGTCACATTACGGCTTCTGC 18441 B16F10 Rassf8 GGAAGTGTACAATGCTAACC 12458 Hepal-6 Extl3 GGCCGTTTCCGGCCCATCTT 18442 o 4 B16F10 Lrrc c GGCGGCTCCGCTTGCAGGCG 12459 Hepal-6 Extl3 CCTGTGCCTTCGGACGCGTC 18443 B16F10 Lrrc8c GGAACAGGGCTGCGGAGCTG 12460 Hepal-6 Extl3 CAGAGACATTCGTGACTTTC 18444 B16F10 Lrrc8c TCGGCAGCCGACGGCGACCC 12461 Hepal-6 Slc41a3 CATTGGGTCCTTCGGCACCC 18445 B16F10 Syne4 AGGTTTAGGTTCTCCTGCTG 12462 Hepal-6 Slc41a3 AGAGAGCTGTCCTGACTAAA 18446 B16F10 Syne4 ATACCACCCGCTCGCCATCG 12463 Hepal-6 Slc41a3 GGACACCACCCACATGGGCC 18447 B16F10 Syne4 CGTCACCCATCTCAAGACCT 12464 Hepal-6 Rbm26 AAGTTCGGCCGGGTGAGAGC 18448 B16F10 Tyro3 TGCGCCTTCTGGAGGTGGGC 12465 Hepal-6 Rbm26 CACGAAGGCCGATGGATAAA 18449 B16F10 Tyro3 AGGTCGGGCGGTAAGGGCTG 12466 Hepal-6 Rbm26 GCAAATCCAGTAGTGGATCG 18450 B16F10 Tyro3 CGTGGCCGGGTGCCTGTCCA 12467 Hepal-6 Ctdpl CTTGAGAGCACGCAGTCACG 18451 B16F10 Hoxb4 GCTAGAAGGCGGGTGCGCAG 12468 Hepal-6 Ctdpl GAGACCACAGCCATGTCACG 18452 B16F10 Ηο ¾4 TTTAAGTGGTTGGCCGACCA 12469 Hepal-6 Ctdpl CACCACGGACCGGTGCTCCG 18453 B16F10 o b4 TCTTGAAATGGGTACCCACT 12470 Hepal-6 Colecll GCAGGAAGCTCTTGCAGATA 18454 B16F10 Zfp775 GTGCAGATGGGAAGGTTACG 12471 Hepal-6 Colecll CAGCCTCCAGCAGATTCGCT 18455 B16F10 Zfp775 TGAGTTCTATCCACTCCCTC 12472 Hepal-6 Colecll GCAGGACAGCTGATGGTTTC 18456 B16F10 Zfp775 GGCTATGAGATGGGACATGG 12473 Hepal-6 Gykll GAATGACCCAGGTTAACTTT 18457 B16F10 Acot2 CAGCTCAGTCTAAGGACTGC 12474 Hepal-6 Gykll GTCTGCTTTATATCCAAGGT 18458 o s B16F10 Acot2 TAGTAGTGACGCTTTGACTA 12475 Hepal-6 Gykll GGCACGAGACCATAGGTGAT 18459 B16F10 Acot2 CGTTAAGACTCCGTTATATC 12476 Hepal-6 Ptcra TCTGGGAAGCAGTGTAGTAG 18460 B 6F1 Trrap AGTGAAGGTAGCGGCGGCTA 12477 Hepal-6 Ptcra CCCTAGTTCCCAGTGCTTTC 18461 B16F10 Trrap AAGGCCGTTTGCGACGCGAA 12478 Hepal-6 Ptcra TATGAAGTGCTCTTCAGACA 18462 B16F10 Trrap GATTGAGTGAGGAGTCGAGG 12479 Hepal-6 Spaca7 GCCTTGGACTCCTGGATACG 18463 B16F10 Prss36 TCTCAGGTGAGTCATGCCAA 12480 Hepal-6 Spaca7 GGTTAACATACACTCTAATG 18464 B16F10 Prss36 ACTGTGGTGGGTGGAGTGCT 12481 Hepal-6 Spaca7 TTCTTAACCATGTTCTCACA 18465 B16F10 Prss36 CTGAGTCGGTTTAACACACG 12482 Hepal-6 Ppp4r2 GGCGGAGGCGCACGGGATCG 18466 B16F10 Corolb GAATCAGGAAGTGATAGCCG 12483 Hepal-6 Ppp4r2 CTGCGGACGCCGCTGAACAG 18467 B16F10 Corolb GCTTTAGGATGTCCCGCCCA 12484 Hepal-6 Ppp4r2 GAGCGCTCCTGGGCGTGTGT 18468 B16F10 Corolb AAGGCCTAGTCGCCAGGCCC 12485 Hepal-6 Aul GTGGAAACGCTTAAATGAAG 18469 B16F10 Anks4b AACCATGGCAATGACCACTG 12486 Hepal-6 A ACGACAGGCGTCGGTCGCTT 18470 B16F10 Anks4b TGACAGGTGTGTCATGAGTG 12487 Hepal-6 Auh AAACATTAATGCTACCCGGG 18471 B16F10 Anks4b CACTGATTAACCAGCCCTGT 12488 Hepal-6 Vmnlrl88 ACACTATCCCAGAGTCTCCC 18472 6F1 Hosc4 CACTGGAGCTGAGGCCCACG 12489 Hepal-6 Vmnlrl88 GTCCCTGACACTTCCTTTCC 18473 n B16F10 Hoxc4 AATCGTGTTGCAGTCTGTGT 12490 Hepal-6 Vmnlrl88 TGTGTGCTCCAACAGTGAGT 18474 B16F10 TTCCTCTTCCTGCGAAAGAG 12491 Hepal-6 Kankl CGAGCGCCAGCGGTGATCCC 18475 n B16F10 Glrpl TGAGGGAGGGCCTGCGAGTG 12492 Hepal-6 Kankl TGCCTTGGCTAGCAGTCGCC 18476 o B16F10 Glrpl CTGACTCCTGTCTCCGGAAT 12493 Hepal-6 Kankl GCTGGAGCGCACGGCGACAC 18477 B16F10 Glrpl AGTTACAAACTGTGGCGCAT 12494 Hepal-6 Pigb CCCGGAGACTCATCCGCTTC 18478 B16F10 Asxl3 GTAGGTACTGTGCTCTGCCA 12495 Hepal-6 Pigb GCATTGAACACTGGTCAGGG 18479 b B16F10 Asxl3 ATGCTCGCACAGTGTCCTCA 12496 Hepal-6 Pigb GCTGTGCGAGGTGTGTCAGG 18480 J B16F10 Asxl3 GCACACGTGCAGAGAACATA 12497 Hepal-6 Tj pl CAGGATGGATCGCGCGGCAG 18481 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Hpdl AGAACCACGCGGACGCTGTG 12498 Hepal-6 Tjpl GGCTACCCAAGTTACTTGCT 18482 B16F10 Hpdl GAGACAGGTTCTGGACCGGA 12499 Hepal-6 Tjpl GCTCAGTGGCCCGGTCCGGC 18483 B16F10 Hpdl ACGAAGGGCAGTTCCTTCAC 12500 Hepal-6 Slc22a6 CACTTTAACTCATTGTCATC 18484 B16F10 Ephx2 ATAGAGACTAAGTAACCCTT 12501 Hepal-6 Slc22a6 ATTTCTCCAATTGGGAATGA 18485 B16F10 Ephx2 AGGCAGCTGATCAGTAGGCA 12502 Hepal-6 Slc22a6 TGACACAAGGAATACTCACA 18486 B16F10 Ephx2 GGCAAGCAAAGTGAGGGACT 12503 Hep l -6 Orml TGCCACAGCTCTACTGTCCC 18487 B16F10 Srpx2 TTTATGACTCAGCATGACAT 12504 Hepal-6 Onnl GCAACATTTATGACACGATG 18488 o 4 B16F10 Srpx2 CTAGCATAGGACCTCCAGAG 12505 Hepal-6 Orml TGTCAGGACCAGTAGGTTGA 18489 B16F10 Srpx2 GAATTTCACCAGCTCCAGAG 12506 Hepal-6 Spatal6 AAAGGAAACTCACACATAGC 18490 B16F10 Snx5 CTCCAAGATGGACGGCCGCG 12507 Hepal-6 Spatal6 CGTGGTCCGCTAAATGGGCG 18491 B16F10 Snx5 GCGGGCTGGGTGTTACAGCG 12508 Hepal-6 Spatal6 TGCATTCAGAGAGAAGGCTG 18492 B16F10 Snx5 CGGGCAATAGAAGCTACGCG 12509 Hepal-6 Tmeml02 CAACATCTCAGCAGGGTGAG 18493 B16F10 Unci 3a TGTCCGTGCTCCACCTACCT 12510 Hepal-6 Tmeml02 GCACCGCTGCACCTGTATCG 18494 B16F10 Uncl3a GGGCCGGGCAGACGCCTTAA 12511 Hepal-6 Tmeml02 AGATTCTACAGGTAACTTCC 18495 B16F10 Unci 3a GAAACAGATACGACCTGGCC 12512 Hepal-6 Znl TAGCGITCTTTACGGCACGG 18496 B16F10 Mtal GGGACGGGAGGGCCGCGGCG 12513 Hepal-6 Zn tfi ACGTCGTGAAGAGTCGTGGC 18497 B16F10 Mtal CGCGGCCTCGGCGGCCTCGG 12514 Hepal-6 Znhitfi GGCGCTGAAACTGCTGTCTT 18498 B16F10 Mtal CAGAAGGGCCACTCGGCCAG 12515 Hepal-6 Zfp954 CCAAGTTTCAGTGGATTTCT 18499 B16F10 Faml35a CAAATCTCGGTTGGCGCCGG 12516 Hepal-6 Zfp954 GAACCGTTGGGCGGGACTTT 18500 B16F10 Faml35a TTCTCGCGGGAACTCGGGAG 12517 Hepal-6 Zfp954 TCAAGCAGGGCAGTTGTGTC 18501 B16F10 Faml35a GCGGGACTTGGAGCCCAAGG 12518 Hepal-6 Scn9a TTCCGAGAAGCCACTTTATG 18502 B16F10 KM22 CCTATTGAAGGTGCAAACCT 12519 Hepal-6 Scn9a TTAGCACTGAACTGGAGGGA 18503 B16F10 22 GAGGCTGAAGGGTCAGACCC 12520 Hepal-6 Scn9a AAGGCAGAGAAGAATGACAA 18504 o B16F10 FCllil22 CGTCACGTGGGATGCCGCGC 12521 Hepal-6 Cyp3a44 TGCCTGAAGTACTTATATGC 18505 B16F10 Rnasel TAATTCATACCGCCGCTGAG 12522 Hepal-6 Cyp3a44 CCCTATGTTGACCTCCTTTA 18506 B16F10 Rnasel AGCTGAACGTCGCCCTCTGC 12523 Hepal-6 Slcl2a9 GGGCTTGAATCGGGACCAAT 18507 B16F10 Rnasel CTAATTGTTGCCGATTTCCA 12524 Hepal-6 Slcl2a9 GCTAGCATCCTGGCAACGGG 18508 B16F10 Neb AGGCATGTCTCCACCAAATA 12525 Hepal-6 Slcl2a9 AGCGTACGAGAGTGTGGGCG 18509 B16F10 Neb CGCAGCTCTCATGATGGTCG 12526 Hepal-6 Zfp933 CCGTTCGCGCTGGCAAATTC 18510 B16F10 Neb GCAGGCCATGTCAACTCACC 12527 Hepal-6 Zfp933 ACCGCTGTAACACGTGACTG 1851 1 B16F10 Cesld CTTAGATTACATAACTGAGC 12528 Hepal-6 Zfp933 CCAGGAACTTACGTAGTTCC 18512 B16F10 Cesld CCCAGTACTCAGATTACAAG 12529 Hepal-6 Gtpbp6 GGAGGGAGAGCAGGGAGGGA 18513 B16F10 Cesld CTTCCTTCCAAAGAGCTCTC 12530 Hepal-6 Gtpbp6 GTCAGGGAGAAAGGACAGCA 18514 B16F10 Usp51 CCCGGAATCAGGCCTCCAGC 12531 Hepal-6 Gtpbp6 GGCGCATGTGCGTGCCGCGA 18515 B16F10 Usp51 GGTAGAATCCCTTTCAGAAG 12532 Hepal-6 Akrlcl9 GACTGTTCCACGAAGGGTGC 18516 B16F10 Usp51 TCTGTGGCTGTTGTTACCTC 12533 Hepal-6 Akrlcl9 CACTGCTTAGACATTAGAGG 18517 B16F10 Hp GTGAGATACCTACTTATGCC 12534 Hepal-6 Akrlcl9 CAGCACTTACACCTGTCTAA 18518 6F 1 Hpsl GAGCCGTGCCACGTTCACCC 12535 Hepal-6 TtU12 GTGTCTTCTCCATTCATCCC 18519 n B16F10 Hpsl GTGACTCAGCCACATGACCG 12536 Hepal-6 TtU12 AGAATCCCTCGCGGCAGTCC 18520 B16F10 Rbml2bl CTTACAGAATGGATAGGACA 12537 Hepal-6 TtU12 CTCTTGGAACCTCGCAACCC 18521 n B16F10 Rbml2bl AAGATGTGAAAGAGGGTAAC 12538 Hepal-6 Xirpl CCATTCAACCCAAGTCTGCC 18522 o B16F10 Rbml2bl TTCTTTATCCTTCGCTGCTG 12539 Hepal-6 Xirpl GCTATGITCGGAGTATTAAG 18523 B16F10 Adrala CAGAGGAATACGGTAACAGC 12540 Hepal-6 Xirpl GGAATCAGTTACAATTCCTC 18524 B16F10 Adrala TATCAAGCGTGGAGGGATGA 12541 Hepal-6 MovlO CGTGCCGCTCGCTTCCGTAC 18525 b B16F10 Adrala ATGGGACAGAGAAACAGGAA 12542 Hepal-6 MovlO TTATGTCCCTGGCAGTCTGG 18526 J B16F10 Runxl CAGCGTACAGTAGCGCGCGG 12543 Hepal-6 MovlO GCAAGTGTCTCTATAGATAA 18527 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Runxl GGAGACCGACGGCCAATCAC 12544 Hepal-6 Vipr2 GGAGTCTCTCTCTGGCACTC 18528 B16F10 Runxl TTGAGCAGAGCTTAGCAGAG 12545 Hepal-6 Vipr2 TGGACAGAGATCTGGTGGAC 18529 B16F10 Gfodl GCTTGGCGGCCAATGGAGCA 12546 Hepal-6 Vipr2 TGCACTTCAGAGGGAAGTAG 18530 B16F10 Gfodl CTGAGCGCAACGAGTGCCTT 12547 Hepal-6 Tmem30a CAAAGTGAGGGCTTTAGGCC 1853 1 o B16F10 Gfodl GGAGTCAAAGCGGGTTCCAG 12548 Hepal-6 Tmem30a GGGAGATGATTGAGGGACGA 18532 B16F10 Rdh9 CTGAGTCACCAATAGTTATA 12549 Hepal-6 Tmem30a CGTCACAGGGCAGATGATCA 18533 r B16F10 Rdh9 GTGAGATAGGGAGAGGCAAA 12550 Hepal-6 Ayml GCTCTGAGCTAGAGCAGGAC 18534 o 4 B16F10 Rdh9 AGGACTTCACATCAGAAGCC 12551 Hepal-6 Ayml CTCTGCCGGGCACACAGCTC 18535 6 1 B16F10 Prr27 GAACTTGATAGACTGAACTA 12552 Hepal-6 Ayml ATGGGAGGGAATCTCCCTAA 18536 B16F10 Prr27 GCTGAATCTTTGTACTATAC 12553 Hepal-6 Nrlh5 AAGTCCGTTGACTTCCCAGC 18537 B16F10 Prr27 ATCATCAGATTGCTAAGGAA 12554 Hepal-6 Nrlh5 GGCACTTCCCTGCTTATCAG 18538 B16F10 Tubdl ATGCGTAGCATTAGCTCCCG 12555 Hepal-6 Nrlh5 CAGAGTGTCTGGAGCCTAAG 18539 B16F10 Micall2 ATGTGGGCGTGCCCTTTGTG 12556 Hepal-6 Zfp932 TCGAGTCACTCAAGACTTAC 18540 B16F10 Micall2 CAAGAGGCGTGATCTTGTGG 12557 Hepal-6 Z p9 CGCGGACCTGCCAGTCAGAG 18541 B16F10 Mrcall2 GGTGTGGCCTGACCAAACTG 12558 Hepal-6 Zfp932 AGGCACTGGACTTGAAGCTA 18542 B16F10 Rfx8 GCCCAACGTTGGCCAGAGAG 12559 Hepal-6 Cops7b TGAGGAGAGGAGTGTGCCCT 18543 B16F10 Rfx8 ACCTTTGGTGGCGGTGGGCG 12560 Hepal-6 Cops7b GAGCGGGAACATTGTGTAGG 18544 B16F10 Rfx8 GGCCCACGCCTTGCACCCAG 12561 Hepal-6 Cops7b GCCACCTCCCACCTAGATTG 18545 B16F10 Rfx3 AGTCTTAAAGCGCACCTCGG 12562 Hepal-6 Trim56 GGGCTACAGGTTAGGGCGAC 18546 B16F10 Rfx3 TGCGGTCGGGATTCCGACGT 12563 Hepal-6 Trim56 CAGAGTAGTTGTCCCGGGCC 18547 B16F10 Rfx3 GGGCTCCGAGCTGTCAGTCA 12564 Hepal-6 Trim56 GGTGGTGCAACTTCCGTCCC 18548 B16F10 Speer4a CATGGAGTACATACAGCCTT 12565 Hepal-6 Pgk2 TGAACTCACAAAGAAAGGCG 18549 B16F10 Speer4a GAAGCTGAATGGCCCTTTCC 12566 Hepal-6 Pgk2 TGGCAGTTTGAGTCTGTACC 18550 o B16F10 Glisl CGCTGCTGCCCACAGCCGCT 12567 Hepal-6 Pgk2 CCATCCTGTCTATCTTGATT 18551 B16F10 Glisl GCCCGCGGCGAGGTGAGAAG 12568 Hepal-6 Ripkl CCCGCGCTGACTTACCTCAG 18552 B16F10 Glisl ACAGCACGGCGCGCCTCCTC 12569 Hepal-6 Ripkl GTTTCCGGAAGCCGGGTGGC 18553 B16F10 Zfp57 CGCCTACTGTTGGTCTTCAC 12570 Hepal-6 Ripkl GGCGGGACTTCAAACGTTCC 18554 B16F10 Zfp57 CTAAGATAAGTATTTACTCC 12571 Hepal-6 Cars ACTGCAAACTGACGCCGACG 18555 B16F10 Zfp57 TTTCCGTAATTCCTTGTACT 12572 Hepal-6 Cars CGGAACTTAATAGACACCAA 18556 B16F10 Csmd2 GAATGAACCAAGTGTCCGCC 12573 Hepal-6 Cars GACAGTGAGAAGCGCAAACC 18557 B16F10 Csmd2 TCGCCCGCCGCCGAGGAGAA 12574 Hepal-6 Trappcll GGAGACGCGATCGTGAGAAG 18558 B16F10 Csmd2 GCTCAGGGCTCCCGCGTACC 12575 Hepal-6 Trappcll AATGGAACACCTTCCTAACA 18559 B16F10 Cenpf GCTTTCGACCAGTCCTCACC 12576 Hepal-6 Trappcll GAGTGCTGTCACTCAAGCCC 18560 B16F10 Cenpf AGGCGGCTCACCGAGAAGCC 12577 Hepal-6 Rpsl9bpl AGGAGCGAACACCGCCAGGG 18561 B16F10 Cenpf GGAGGCTAGCTGGGCGGGAC 12578 Hepal-6 Rpsl9bpl GCCAITGAGCCTGCGTTCTA 18562 B16F10 Casp9 GAAGCGTTATCATGTGAGGC 12579 Hepal-6 Rpsl9bpl ATTTCTAAGCAACAGGTCTC 18563 B16F10 Casp9 GGTCGTAGGGCGTGGCGAAG 12580 Hepal-6 Ttl AATAGTCGCCTTCTGGCTCC 18564 B16F10 Casp9 GTCCGTACGGCGAAGTGATG 12581 Hepal-6 TtlB GGCCTTAGGGAAGTCGAATA 18565 B16F10 Tdid6 GGCTGCCTGCCTTCTCGGCG 12582 Hepal-6 TtlB CCAATAAGGTACAATCACTG 18566 B16F10 Tdrd6 GGACTACCAGCAAGCCTGTG 12583 Hepal-6 Pil6 CCAGTACCACGGAAAGAGCA 18567 v > B16F10 Tdrd6 TCGCAGGCTCAGATAGCGCG 12584 Hepal-6 Pil6 CTACAGGATTGGGTAAGATG 18568 o B16F10 Sycp2 CAGCATCACCACTCTGGGCG 12585 Hepal-6 Pil6 GGGAGGGAGAGATGATGCAA 18569 o B16F10 Sycp2 GTGCCGTGCCAGTTCCACCT 12586 Hepal-6 Dscam TACACACGATGGGCTGTGTG 18570 o B16F10 Sycp2 ATGAGGATTGCCTAGTTGAG 12587 Hepal-6 Dscam CAGTCTTAAAGCAGCAGCAG 18571 B16F10 Srebf2 CCCATTGACAACAAACTTGG 12588 Hepal-6 Dscam AGTGCGGCGGATCACGCAGT 18572 SO 6/1 B16F10 Stebf2 GGCGCGCGAAGCGGCTCATG 12589 Hepal-6 Psg27 CTTATCATCTGTGTTGCTCA 18573 e Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Srebf2 CCAGGCTTGCATTAGCCAAT 12590 Hepal-6 Psg27 AGTCAGCAGATATCAGCGCC 18574 B16F10 Tspan5 GGTGGCGCGGCTGCGTCGTG 12591 Hepal-6 Psg27 GGGACACATAGGAAAGATAG 18575 B16F10 Tspan5 CTCGTCTCTCTCGGCGGCAA 12592 Hepal-6 Mipl55 GGGTITCTGGTTAGTTGTCC 18576 B16F10 Tspan5 AGACACGCGGACCGCGACAG 12593 Hepal-6 Mrpl55 GCCTTACTCCGCCCTTAATG 18577 B16F10 Xirpl CCATTCAACCCAAGTCTGCC 12594 Hepal-6 Mrpl55 ACTGAAGTAGGCTAGGTCGA 18578 B16F10 Xirpl GCTATGTTCGGAGTATTAAG 12595 Hepal-6 App GGTGCGGCGTCTTGGGCTAA 18579 B16F10 Xirpl GGAATCAGTTACAATTCCTC 12596 Hepal-6 App TGTCGGGTGGCGAGCCGGGT 18580 o 4 B16F10 Pptc7 CCGGAATCGAGCGTGCGCAA 12597 Hepal-6 App GCGGGATCAGCTGACTCTGC 18581 B16F10 Pptc7 AACTCITAACTACGACTTCC 12598 Hepal-6 Hoxa5 CATCGCTTCGCTTCCGACCT 18582 B16F10 Pptc7 CGCGGCCCGGAACACGCTAG 12599 Hepal-6 H xa5 CTGTAACCTCAATTCGACCC 18583 B16F10 Trip4 TTTGTCCTATCAGAAGAACG 12600 Hepal-6 Hoxa5 AACGGCGGCAACGGGTGGCG 18584 B16F10 Trip4 GGCAACTCCAGGACGACCAG 12601 Hepal-6 Tmeml32a CACCTTGTGCTTCCTGGCAG 18585 B16F10 Trip4 CTTCCGGGTCGTTAATGCTG 12602 Hepal-6 Tmeml32a ATCAATCTGCTTAGTCTCCA 18586 B16F10 P2rx7 AAACAAGAACCAAGTCCTAC 12603 Hepal-6 Tmeml32a TCCTAGGCACCCTAGGCACG 18587 B16F10 P2rx7 CCCAGACGCCCGCACAAAGA 12604 Hepal-6 PilS CTAAGAGAGCCTGCCCTTTC 18588 B16F10 P2rx7 GACCTCCCTCTTCAAAGAGC 12605 Hepal-6 PilS TCAGTTTGCAAAGTCCAGAA 18589 B16F10 Fndc3b CGGGAACCGGCGGCCGCGGC 12606 Hepal-6 Pil5 AAACAACCAACAACAGAGAT 18590 B16F10 Fndc3b AGGGAGGACGTGGCGCGCAG 12607 Hepal-6 Ecml CCATTCTTCCCAGGCTAAGG 18591 B16F10 F dc3b CCCGCGAGCATCCCGGGTCC 12608 Hepal-6 Ecml GTGATGGAAGGGAGCACTCC 18592 B16F10 Smad5 AACTTGGGCACGCATGCCCA 12609 Hepal-6 Ecml TCCTCTGCATCAGTTTGGAG 18593 B16F10 Smad5 GCTGCGCTAAACTTTGTGTG 12610 Hepal-6 Slc22a28 CTGTAGTGCATAAATGTAAT 18594 B16F10 Smad5 TGCCACTTCCAGGCTCGCTG 12611 Hepal-6 Slc22a28 ACGATTCCCATGGTCAAATA 18595 B16F10 Dnaj TGTGTGGTGCTCGGTTGAGG 12612 Hepal-6 Pannl CATCCCAGCTGCCTGAGCCC 18596 o B16F10 DnajbS TGTGGTGAGGCTGATCACTG 12613 Hepal-6 Parml CCAGGAGTCCCGGCCCAGAG 18597 B16F10 Dnajb8 GGCTGTTTGITTGACTCCCT 12614 Hepal-6 Parml TAGCTCCCGCTGTCCAGCAG 18598 B16F10 Angptl3 TGCAAGTTAGCACAGCTTAA 12615 Hepal-6 Klrbl GTCTCCAAAGATATTAAATG 18599 B16F10 Angptl3 TATATAAAGTCAAGAGGTCC 12616 Hepal-6 Klrbl CTGAGnTGTTCTCACTCAA 18600 B16F10 Angptl3 CAAGGAAATGAGCAACTAAT 12617 Hepal-6 Klibl AGAGAGCATAATGTTGATAG 18601 B16F10 Bc GCGCACGCCGCTATTGTGTG 12618 Hepal-6 Clec GCTTTATATAAAGGAGCTGC 18602 B16F10 Bcr TGCGGCCGTGGGCCGGCGGT 12619 Hepal-6 Clec3a CCTGTTCTTACACCTCACGC 18603 B16F10 Bcr GGAGCCGTCCTCCGCAGAGC 12620 Hepal-6 Clec3a GTTGGCTGGAAGCCTGCTGA 18604 B16F10 Dmsll GCCGGCGGGCGTCCGCTCAC 12621 Hepal-6 Adhfel GAAACTCTGAAATGTCTCAA 18605 1 F1 Dmxll TGCACCTGTCACGGCCGCCC 12622 Hepal-6 Adhfel AAATGAGCTAAGACTGGGTC 18606 B16F10 Dmxll GAAGCCGCAGACGTTCGGTC 12623 Hepal-6 Adhfel AAACTTCTGCCTCCAATGCA 18607 B16F10 Medl21 GTCTGCAAAGTGCTGCTCCC 12624 Hepal-6 Zfp804a GCGCACCGCAGCCGGGCATA 18608 B16F10 Medl21 CTCGCCGTGGCGCTGCAGGC 12625 Hepal-6 Zfp804a GCTCGCCTGGAGATAGGAAC 18609 B16F10 Medl21 ATGAGAGTTGGAGCTGGAGC 12626 Hepal-6 Zfp804a GGGAGGATGCAGCCACAAGG 18610 6F1 Uspl71b GCCACGCCTACAGTCTTCCC 12627 Hepal-6 Zfp318 CCCACCGGCCAGCGGTTGGA 18611 n B16F10 Uspl71b AACCACACCCAACTTGGGAG 12628 Hepal-6 Zfp318 CCTCAGGAGCCGGGAGCCGT 18612 B16F10 Uspl71b CTACAGCAAGTTATTTGAAG 12629 Hepal-6 Zfp318 GCTGAGCCTGCGCGAGCACC 18613 n B16F10 Wwcl GCGGCTCGGGCTGGCCGCTT 12630 Hepal-6 Cdhl9 GAGAGAGAGAGAGAGAAAGT 18614 o B16F10 Wwcl CATGGACAGAGGCGCCACCC 1263 1 Hepal-6 Cdhl9 CTTATGGTACTTTGAACAAA 18615 B16F10 Wwcl GGGAGTGGCGCCCACGGATC 12632 Hepal-6 Cdhl9 TGATGTCCGTTCTTAGTCTG 18616 B16F10 Emel TTTGCTTCACGTTCACTTCC 12633 Hepal-6 Ankrd27 ATCATTAAGTCTAGTTCAGT 18617 b B16F10 Emel CTATTGCGAGGCGAGACAGC 12634 Hepal-6 Ankrd27 CGTGCCCAGAATTCGAGAGG 18618 J B16F10 Emel GCCCATGGTGAACCTAGATA 12635 Hepal-6 An rd27 TAGGAAGCGCGGAGTCGCCT 18619 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Kdfl TAAAGGGCATGCATGCCTCC 12636 Hepal-6 Flrtl AGAAGCTTCTGAAGTGGGTG 18620 B16F10 Kdfl ATCATCGGGCAACAGTGCTT 12637 Hepal-6 Flrtl AACATCTGAACTCCTCAGAG 18621 B16F10 Kdfl TAGGAGCTTTGCGGCCCGGT 1263 S Hepal-6 Flrtl TGCTTGGCTGCTCCTGTTTG 18622 B16F10 Gsdmd TTTCAAGGAGCCCTCCCTCC 12639 Hepal-6 Thada ATCAAGAACTGTTTAGTCGC 18623 o B16F10 Gsdmd TACGTCGGGCTGAAGCTTTA 12640 Hepal-6 Thada GCACGGAAATATCGCGAGAG 18624 90 B16F10 Gsdmd AGCGAAGCTCCCGGATCGCA 12641 Hepal-6 Thada GGGITGTGACGTCATCAAAG 18625 r B16F10 Nlrp4c TGAATCTTGGTGTAGGATTC 12642 Hepal-6 Irs3 CACCAGGACTCCTAGGTCTA 18626 o 4 B16F10 Nlip4c ATCTGCTATCTGTAGATACC 12643 Hepal-6 Irs3 ACAAGGAGGCTGACCCAGCT 18627 6 1 B16F10 Nlrp4c TGCCGTATCCGGAGTGCATC 12644 Hepal-6 Irs3 AAACTCAAATTCCTGCACTC 18628 W B16F10 Slc48al ATGATCATTGTAGCCGGCTC 12645 Hepal-6 Ppan TCTCGGTCCTTTAAGCCGTC 18629 B16F10 Slc48al GCTAGATAGGTGGCGTTCTG 12646 Hepal-6 Ppan CGAACCCTCAAATAATTGTG 18630 B16F10 Slc48al CGCCGGCCTTTGCCAAGCGG 12647 Hepal-6 Ppan GGGTCTTTATAAAGATGCCG 1863 1 B16F10 Dhx57 AGGAACCTCTGCCATTGATC 12648 Hepal-6 Capn9 CATTTCACAGGGAGGTGCCC 18632 B16F10 Dhx57 CTTACTTCACTGTATTACAT 12649 Hepal-6 Capn9 ATTGCCCACTCAGGGTTCCA 18633 B16F10 Dhx57 CGTTTCCACATTCAAATTTC 12650 Hepal-6 Capn9 CTATGCTCTAAAGTTGACTC 18634 B16F10 Arfip2 GCTGTGCGCCCTTGGCGTGA 12651 Hepal-6 Rhoq CAGGGCTCCTCGCGAAAGTG 18635 B16F10 Arfip2 GAGCTTGAAGGCGTAGCTCC 12652 Hepal-6 Rhoq CTCTTGGGCAGCCGCTAGGA 18636 B16F10 Arfip2 AGTTGTGGGCAGGACGAGCC 12653 Hepal-6 Rhoq AGGAGGAGGCGCCCTGTATC 18637 B16F10 Tnfrsf25 GTGAAGACTACCCAGCCCGC 12654 Hepal-6 Gm8369 ATGAGTGGATGTGTACTCTG 18638 B16F10 Tnfrsf25 GGCTATGTCCCTCTACGTGA 12655 Hepal-6 Gm8369 TATGATGGCTGAGGTGGGTG 18639 B16F10 Tnfrsf25 AGAGGAAGCACAAGCTCCCG 12656 Hepal-6 Gm8369 TCTGCCTCTAAGTCAATTGG 18640 B16F10 Colecl l GCAGGAAGCTCTTGCAGATA 12657 Hepal-6 S sf TCTCTCCCTAGAGATGCGAG 18641 B16F10 Colecl l CAGCCTCCAGCAGATTCGCT 12658 Hepal-6 Srsf9 TGCATTGTGGGAACGCGGCG 18642 o B16F10 Colecl l GCAGGACAGCTGATGGTTTC 12659 Hepal-6 Srsf9 GCAAGCGCACCTCGCGGCGG 18643 B16F10 Arhgefl8 GCTGAAGTTGATATAAGGAC 12660 Hepal-6 Armc9 GCTAGCGGTAGCGGTTGCCC 18644 B16F10 Arhgefl8 AGACCAAGCTGCGCATGAGT 12661 Hepal-6 Artnc9 CTTCCGGTACTCACCACGTA 18645 B16F10 Arhgefl8 GGAGGAACTACCTATTGCCG 12662 Hepal-6 Armc9 CCGTACAGGCGTGTGGCGTG 18646 B16F10 Ctsq GGTGACTAGATTAAGCCTCT 12663 Hepal-6 Co124a 1 GGAAGTGGGTACATCTCAAG 18647 B16F10 Ctsq ATCTGAAGTATCTGTAGGGT 12664 Hepal-6 Co124a 1 AAAGGTCACTTGAGAGCTCA 18648 B16F10 Ctsq GGATGATCAGGTTCAGGGTC 12665 Hepal-6 Co124a 1 TAGCCCAGCCTGACCCTGCT 18649 B16F10 BC051 142 AGGATATGAGTCTCCTGAAG 12666 Hepal-6 Lrp5 GGAGGGAGCGGAAGCCGAGC 18650 B16F10 BC051 142 CTGAAGGAGTGCGGATTCCC 12667 Hepal-6 Lrp5 GGAGGGCGCGGCTTGGCGGG 18651 B16F10 BC051 142 TAGCTACGTCATCAGTTACC 12668 Hepal-6 Lip5 TGCCAAGTCTCTGTACTGAC 18652 B16F10 Zfp27 GTAAGCACGCTGTGGGTTAT 12669 Hepal-6 S k3 GAGGTGAGAGGCGGGATAAA 18653 B16F10 Zfp27 AGCATTACCTCCGATGCCAG 12670 Hepal-6 S k3 CCTCGAGACCACCGAGGATG 18654 B16F10 Zfp27 GGAAGAAACCATGCGGTGCA 12671 Hepal-6 Sbk3 CTATTGTCCCTCCTTGAATC 18655 B16F10 ApollOb TCAGAGATCATGGACAGCTA 12672 Hepal-6 Spicel GTTGGTGTGCAAGTTTCTTT 18656 B16F10 ApollOb GGGAGGATTCCTCTGACTTG 12673 Hepal-6 Spice 1 CTTATGACAGGCGCGCCATT 18657 B16F10 ApollOb TCTTCCCTGGTGCCTGTCCT 12674 Hepal-6 Spicel CCCACGCCTTTGCGTACATC 18658 B16F10 Cubn ATCATTGACATTCTTCAGGA 12675 Hepal-6 Sycpl CCGCGACCGGCTCAATTTAA 18659 v B16F10 Cubn CTAGTACTGTTCAACTTGTG 12676 Hepal-6 Sycpl ATGGCTATACACCAACGAGG 18660 o B16F10 Cubn TTTGCTGATCAAAGAGCAAC 12677 Hepal-6 Sycpl AGATITCCCTTCCCACGTGC 18661 90 B16F10 Slcl4a2 AAGCATTCAAGTTCAGAAAG 12678 Hepal-6 Adgrg3 GCTCCTGAGACCACCTGCAG 18662 B16F10 Slcl4a2 CATGCGTCTTATTTGGGAAA 12679 Hepal-6 Adgrg3 ACCTTCCACCACTGTATGAG 18663 B16F10 Slcl4a2 AGGATTTGCTTCTTACCGAG 12680 Hepal-6 Adgrg3 CGTTCTTCCTGACCAATGAA 18664 90 6/1 B16F10 Raetle TTTCTGTTTAGCTCTGTCCT 12681 Hepal-6 D16Ertd472e GAGCGAGATGCTCTCCGCGG 18665 0 Table 5 “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Raetle CAGCATTCCCTGGCGCGAGG 12682 CCACGTGGCCACCCTAGCGC 18666 B16F10 Raetle TTCCAATTAGAAGCTTCTTC 12683 GCGCAAGAGGATGCGCACGG 18667 B16F10 Trabd2b GCGTGGCTGGATGTCCCTGT 12684 TCGAGGACGCCAGGTCACGT 18668 o B16F10 Trabd2b GGGCTCCAGGCGCGAGATGC 12685 TTGCTGAACCTCCTCCTCIT 18669 B16F10 Trabd2b CCGGAATTCTGAGAGCGCGC 12686 TGTCATCCGAAGCCTCCAGG 18670 B16F10 Kcna2 GCTCGCCGCCGCCGCCAAGC 12687 CGGCGCGCGACATCGCCACC 18671 b B16F10 Kcna2 GACACAGGGATCTAACCCAG 12688 CCTAGAGCCTTCCGCTCGAG 18672 o 4 B16F10 Kcna2 CCGCAGCGAACTCGAATTAA 12689 GATAGGGAAGCGCAGGCGCT 18673 B16F10 Dennd5a GGTGGCTGCTCTGGAAGCCC 12690 CCCAAAGACTCCGCCTTCCC 18674 B16F10 Dennd5a GCTGACCGCTGGCCACTCTG 12691 CCTGAGGCCCGGAGGCGCCC 18675 B16F10 Dennd5a AAGGATGACGTGATGCTCTT 12692 CCATCTTCGCAGGGCCGCGG 18676 B16F10 Itga7 CGCAAGGCAATGGGTGCGGC 12693 GGTCCAGCCTAGTTTAGCCA 18677 B16F10 Itga7 ACTGCACGCC1TGGGAGCAC 12694 GATCTTGGCGATTCTTGACC 18678 B16F10 Itga7 GCCGCGGGTCTGGGCATCCC 12695 GGAGTTCTGGTCCCGCGCGC 18679 B16F10 1700016H13Rik GGATCCTCGAGAGTGGGCGT 12696 TTTCCACCAATGGGTACCAT 18680 B16F10 1700016H13Rik GGGCTCATCAGGCGCTCACC 12697 TGCATTCCAACATGAGTCTT 1868 1 B16F10 1700016H13Rik GGTGACGCAGGGTAGGCGCC 12698 CATTGGTGGAAAGGTTATGG 18682 B16F10 Faml79a GAGCCCAAGTCCCTGTGTGG 12699 CAACCAGGCCGCTAGGCGCC 18683 B16F10 Faml79a CAGAGGCCAACCTGTCCTCT 12700 GCAGAGATAAGGTAACTTTA 18684 B16F10 Faml79a GCATGGCAACCGCTCTCTGA 12701 GAGTGGAGGGAGGTGGATAA 18685 B16F10 Ammecrl TCGCGGTCTGCGCGCACACG 12702 CGTACTTGCATATATACATC 18686 B16F10 Ammecrl AGTGAGGCGAGCTGGCGGCG 12703 AGGCTAGTATTTATACTGTG 18687 B16F10 Ammecrl CACGCCCGAGAGCCTTGGCG 12704 AAAGTGAACTGGCAAGCAGC 18688 B16F10 Oca2 AGAGCCTTGCTGTAGAAGCC 12705 GGAGTCATGTGATACCAAGA 18689 B16F10 Oca2 GCTGGACCATTCTCAAGAGG 12706 TTATGACAATGGGTAGTTAA 18690 B16F10 Oca2 TTTGTGAAGGTCTGTGGGCG 12707 GGGTCACGCGACGCTGATGC 18691 B16F10 Wdr3 TAGAAGGTAAGGGAAACGCC 12708 TGGACTTGGATCAAAGTCTG 18692 B16F10 Wdr3 CGACAGCGATCTGACAGCGA 12709 GGAGGCATGACATTGCCAAT 18693 B16F10 Wdr3 GATTGGAAGTTTCTTCCGCC 12710 TCTAGTTCGTGGGCTAGGAA 18694 B16F10 A4gnt TAAAGGGTGTGTGTGTTGGG 12711 GAGCCGTAAGAGATTGCACT 18695 B16F10 A4gnt CACAGAGGAAAGTAAATTAT 12712 ACACTTGG CTCTGTG ACCAA 18696 B16F10 A4gnt ACACACTTGTCAAGCCTGCT 12713 CAGGCTGAGGTACCCTGCTC 18697 B16F10 Texl5 AAGAAGAGATGATCATCATT 12714 AACATCATCGGGATCTAATC 18698 B16F10 Texl5 TGCAGTCAAGTTGCTAGACT 12715 GTGGAGAAATTCTGGAGTTG 18699 B16F10 l dc7a AGCCACAGTTAACAGGCGTA 12716 TTTAAATCGAGTTCCTGAGA 18700 B16F10 l dc7a TTTGCCTTGGTTCCCGGAGC 12717 GGTGAGGCCCAGGTGCGGAC 1870 1 B16F10 Klhdc7a GATGGCCTTGGCCCTAACTG 12718 TGCCAGGAGGATATTCAAAC 18702 B16F10 RpU2 CTGTGGGTGAGCTCGGGATT 12719 CTCAGGAGCTGTTACTCTAG 18703 n B16F10 Rpll2 AATGTTCGGAGCACCTTGCC 12720 TCTACCTGTCAGAACAATGG 18704 B16F10 Rpll2 GCTCCGCCCACGCCGGATAT 12721 AGAATTACTTGCATGCTCAG 18705 n B16F10 Insm2 TCGACTGTCCTCACATAAAG 12722 GGGCCCAGTGCACACGCAGC 18706 o B16F10 Insm2 ACACTTATCAGCCAAGAGCT 12723 AGAGTCTTGCTCTGCAGACA 18707 B16F10 Insm2 GCGCCGCAGATCGTGCGTGC 12724 TGCTCGGCTGTCCTGCACAG 18708 B16F10 Dnaaf3 GTCGTTATGACAACCGCGTC 12725 AGGCTAAGGGACAGTGGAAG 18709 B16F10 Dnaaf3 ACTGACCAATTAACGTGAAA 12726 CGCAGTGTGGTGAGCAGCCC 18710 B16F10 Dnaaf3 CCAATAGAAGCTCCGGGAGA 12727 CGCAGATGCCTGCCCTTTAG 1871 1 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 WntlOa GCACCAGGAGTTGTCGCAAG 12728 Hepal-6 Pgam5 GCGTTTCCTGATTCGTCGGG 18712 B16F10 WntlOa TGCACCTCCTTACCCTCTAG 12729 Hepal-6 Pgam5 CCCAGGGCGCCACCTGCCGG 18713 B16F10 WntlOa GGGTCCAGGGAATTTCCCAA 12730 Hepal-6 Chek2 AGGGTGGAGTTTGTATCCGT 18714 B16F10 Lbp AGAGTCAAGAAGGTTGGCAG 12731 Hepal-6 Chek2 TAGCGCCACTCCACTGGCGG 18715 B16F10 Lbp CAGAACCTCCAGAGAGTGTG 12732 Hepal-6 Chek2 TAATCGCGGCAGTCATCTTC 18716 B16F10 Lbp CATTGTTGTGATCACTGCAC 12733 Hepal-6 Ahil CCATTTGAACTTCTCTCCAA 18717 B16F10 Gmc TGCTTATGCCTAACAGATCT 12734 Hepal-6 Ahil TAGAGGGCGTGGCCGTGGTC 18718 B16F10 Gmcll GCGGAAGTCAGACACGCACC 12735 Hepal-6 Ahil CTGCAGCCGGAAGCGAGTCC 18719 B16F10 Gmcll GAGGACGGAGCCTGCGCTGC 12736 Hepal-6 Eci2 GAGGAGGAGCCTAGAATGCC 18720 B16F10 Zglpl TGATGACGATGGGCGCCACC 12737 Hepal-6 Eci2 GACTCCTTCAGAGTTGAGAA 18721 B16F10 Zglpl AACGGAGCATGAGAGAGGCG 12738 Hepal-6 Eci2 AAGACTGGCGGAGATAATCT 18722 B16F10 Zglpl GCTGAGGCTCCTGGCAGCCA 12739 Hepal-6 Vmnlr207-ps ACAAGTTATTCTAACTAGGA 18723 B16F10 BC016579 TCAGGAAAGGTAGATGCAAG 12740 Hepal-6 Vmnlr207-ps AGGAAACAGGAGAAATTTCA 18724 B16F10 BC016579 CAAGGTCAGCTAACCAAAGC 12741 Hepal-6 Gipr AAGAGTGGGAACCGTGGAGC 18725 B16F10 BC016579 GGCGCCAGATAGGCCTGCGG 12742 Hepal-6 Gipr GCCAGGGCGGACCAGAGAAC 18726 B16F10 V ol ACCTGAATCTTGATAGGGCC 12743 Hepal-6 Gipr ACAGCCATTGTGTCACGTAG 18727 B16F10 V ol AAACTAATCTGCTCCAGTCC 12744 Hepal-6 Ttk GTCCGGCCTCAACGCAGGAG 18728 B16F10 Vmol AGATGGATTTATATCAGTCC 12745 Hepal-6 Ttk CCGCTACCTCTCATTGGTTA 18729 B16F10 Pten CCCGCCACATCACCGTGCGC 12746 Hepal-6 Ttk CACCCACTTCAAGCGGCCCG 18730 B16F10 Pten GGAGGCGGGAGGCGGGCGGG 12747 Hepal-6 FbxwlO TACCGTAAATCTCCTAACCC 1873 1 B16F10 Pten GGCGCCCTGCTCTCCCGGCG 12748 Hepal-6 FbxwlO AGAAACTGCCTGTAGAAGTC 18732 B16F10 Adcyl CGCCGCAGAGGACCACTGCC 12749 Hepal-6 FbxwlO TACTGACTTCCTTAGAAACA 18733 B16F10 Adcyl CCCGGGCGCTGAGTTGGGCG 12750 Hepal-6 Ccngl TCAGTTCCGCAGCTTAAGGA 18734 B16F10 Adcyl ACTCTGTCCGCCCAGGATCG 12751 Hepal-6 Ccngl AGTCGGGCGTGGCTCGAAAG 18735 B16F10 Papin GGTGTCAGCCGACTGGGTGG 12752 Hepal-6 Ccngl AACGGGAAGTGTGCGCTGAT 18736 B16F10 Papin GAGGAAACCAGCCAGCCGCG 12753 Hepal-6 n rd TCCCAGCACTTGGGAGGCAG 18737 B16F10 Papin CTCCTTCAGGGATTGGAGGT 12754 Hepal-6 Ankrd61 TGGAAGTCTCTGTGTAGATC 18738 B16F10 Zfp457 GCTGCACATGGGCATGCACA 12755 Hepal-6 Ankrd61 CTGGTGGGTCTCTACATTTG 18739 B16F10 Zfp457 GCTCTTTCTGATGACGTCAC 12756 Hepal-6 Bcorll CCCAGCCAGTCCTCCGCTCC 18740 B16F10 Zfp457 CTCTCAGTGGACTGTAATCC 12757 Hepal-6 Bcorll GGGAAGGAGGAGGAAGAAGG 18741 B16F10 Ctsd TCCAGTCATTCTCCGGTCCC 12758 Hepal-6 Bcorll CAGGGAAGCCGGAACCTCGC 18742 B16F10 Ctsd CCCGCITGTTTGGCCCTCAA 12759 Hepal-6 1810062G17Rik ACGCAGGCGCAGGAGCATAG 18743 B16F10 Ctsd GCAGTGTTGGAGGCGGGTTC 12760 Hepal-6 1810062G17Rik TACGGTACTTTCCTCAGACA 18744 B16F10 Epsl511 AAACTTCTCACGGGAGGACT 12761 Hepal-6 1810062G17Rik GGCTTATAGTGCAGCGTCTC 18745 B16F10 Epsl511 GCACGTGTACTCTGGTCCTG 12762 Hepal-6 Arg2 CCTCCGAGAAGGTGCGCCGG 18746 B16F10 Epsl511 GTGCCTGCGCACTAGTACGA 12763 Hepal-6 Arg2 CAGGTCCAATGGTGACTTAA 18747 B16F10 Exoc314 ACTGCCAGAGGTAAGATAAA 12764 Hepal-6 Arg2 CTTGGTGGCTTAGGCATCGG 18748 B16F10 Exoc314 CAGGATCTGACAATCCTCGG 12765 Hepal-6 Myb AATGGGAGCGGCGGCCAGGC 18749 B16F10 Exoc314 TTCTGGGCTTGAGCACTAGG 12766 Hepal-6 Myb AGGGCGCGTGCGCACTGCAG 18750 B16F10 Nxph2 GGAAACACTATCGCGACTGC 12767 Hepal-6 Myb GAGCAGCTCCGCGGCGCGAG 18751 B16F10 Nxph2 ACAAGAGCCTCTAGCTGTCC 12768 Hepal-6 Triml6 AGAGGCTTACAATAGAGCTC 18752 B16F10 Nxph2 CTGTTAGGTGTGCCTAGCGC 12769 Hepal-6 Triml6 AGAAGTTTCAGGGCTGGGCT 18753 B16F10 Gpatch3 ACGAAACTTCAAGTACCAAA 12770 Hepal-6 Triml6 GGTCTCCGGAAGAGCCTATG 18754 B16F10 Gpatch3 ACGTGGTGCTCTCGCGAGAG 12771 Hepal-6 Gp5 CTGGTAAGGTCTTTATCTTG 18755 B16F10 Gpatch3 ATGCTGGAGTTTGGTCAATG 12772 Hepal-6 Gp5 TTGCAGCTCTGCTTGTGACT 18756 B16F10 Ccll2 AGTTTAGACAGCGAAACAGA 12773 Hepal-6 Gp5 ATCTCCATAGGGCATATTCT 18757 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Ccll2 AAGTCAGATGGAACTTCCAG 12774 Hepal-6 Pspn CCCTGGATGCCGAGAGACCT 18758 B16F10 Ccll2 TAAGACACAAAGAGCCTGAC 12775 Hepal-6 Pspn GGTTTATGGAATGTCTGGGT 18759 B16F10 Adam26b GATGTGGTAGAGGAACAATT 12776 Hepal-6 Pspn TCTTAGGGATGAGGATGTGG 18760 B16F10 Adam26b AAGTGGAAACCAAATAACTT 12777 Hepal-6 Akrlel ACCTCAGGAAATGCCGTGAT 18761 B16F10 Adam26b GTGTATAAGGAGAAAGAAGC 12778 Hepal-6 Akrlel TGGAGTTCTGGCAGTTTAAT 18762 B16F10 Sirpa CACACAAGCAGGGCCTCTCG 12779 Hepal-6 Akrlel CTTAGGATCATAGAGGATTT 18763 B16F10 Sirpa GGGCCAGCTAGGAAAGATTT 12780 Hepal-6 Filip 1 ACTGTTTGCAGACTGCGAAG 18764 B16F10 Sirpa GCAGGTCCGAGCGGCTGGCG 12781 Hepal-6 Filipl AAAGGGTCTGCCGGCTTCCC 18765 B16F10 Ipol3 GGAAACTCATTCCGGGTCTT 12782 Hepal-6 Filip 1 ACAGCTGAGAAGTTTGCAGC 18766 B16F10 Ipol3 TCGATGTGCTTGGCCGTGCC 12783 Hepal-6 Rftl CCGATCCCTGTAGACCATGT 18767 B16F10 Ipol3 CACGGCACGGCGGAACTACG 12784 Hepal-6 Rftl CGGACAGGCTCGCTCCTGAT 18768 B16F10 Actn4 CGCAGGCGTCAGTCTTGGGC 12785 Hepal-6 Rftl GATTGGGTCTTTGACAGCAG 18769 B16F10 Actn4 GGGAGCCCAGGCGCTTCTAG 12786 Hepal-6 Klrel TCCACTACTCAATACTCATG 18770 B16F10 Actn4 CTCCGGCTGCCCGCCCAGCG 12787 Hepal-6 Klrel TCCGTTTAGCACCCATAATA 18771 B16F10 Cacnalb CCCACGCCACGCCCTATAAG 12788 Hepal-6 Klrel TTAGTGAGGACTTTGCTATG 18772 B16F10 Cacnalb TGACGCGGATTGGCTAGGCT 12789 Hepal-6 Spata3 GTCTTTGGGCCTAAGAGAAC 18773 B16F10 Cacnalb AAGCAACTCGGCGTTCCCTG 12790 Hepal-6 Spata3 TGCCTCCTGCCGGTTCAAGC 18774 B16F10 Jph2 GAGATCCAATGGCCTTGTTA 12791 Hepal-6 Spata3 AATTAGACCATGGAGGAACA 18775 B16F10 Jph2 GGTCTGCAGGCCCAGCGGAT 12792 Hepal-6 Vmn2r95 CATTGGATTTAGAATGACTT 18776 B16F10 Jph2 ACTGACCTTTCTATCCTGGG 12793 Hepal-6 Vmn2r95 TATATGTACTGGACACTATT 18777 B16F10 Gml3078 CATCAGAGGTTTGAGGGAGA 12794 Hepal-6 Vmn2r95 TAGTTCATGGGTCTGCTTCA 18778 B16F10 Gml3078 GACTTCATCATCCTATCAGG 12795 Hepal-6 Cttn GGTGGGTAGAAGATTGACAG 18779 B16F10 Gml3078 CAGCTITGATCTGAGAGGTG 12796 Hepal-6 Cttn ATGGITGGAAGCTGGGTTGA 18780 B16F10 Pcdbbb TTTCAGGAGTCCTTTCTCCC 12797 Hepal-6 Cttn AGAAGGACAGATTGGTGGAT 18781 B16F10 Pcdhb6 CATTCAGCATTCTGAATCCC 12798 Hepal-6 Mdcl CAAACGCCTACCAGAGAGTC 18782 B16F10 Pcdhb6 AATTCAGTAAGGTTTATTCG 12799 Hepal-6 Mdcl AGTTACCGGCGGCGGCTAGA 18783 B16F10 Gmll487 AATCTGACCCACCCAATCCA 12800 Hepal-6 Mdcl TCTGCGCGGGAAGTAGTCCG 18784 B16F10 Gmll487 AGGAGACTCCTGTGCAAATG 12801 Hepal-6 Gm n AGGCGATTGGCTGAATGCCG 18785 B16F10 Gmll487 AAAGAAACAGGCTCATGAGC 12802 Hepal-6 Gmnn CACTTGGAGCCGGAAGCGGA 18786 B16F10 Cd8a AACACTTGGAAGGGACCCTT 12803 Hepal-6 Gmnn GTGCGTGCAGTCTCTGGAAG 18787 B16F10 Cd8a GTGGTTGACACTCTTTGGTG 12804 Hepal-6 Mbd2 GGACCTAAGAGGCGCGGCCG 18788 B16F10 Cd8a ACCCTTGCAGAGCAAGTGGG 12805 Hepal-6 Mbd2 GCGCTCTGCCTGCCCAGTGG 18789 1 F1 Cntn3 AACTCTCTCTTTAAAGGAAC 12806 Hepal-6 Mbd2 GCGGAGCAGGTGGTCACGGG 18790 B16F10 Cmn3 TAAACAGTATGTGCAACTGA 12807 Hepal-6 Aga ATCTGATACTGTTTCTTTAG 18791 B16F10 Serpinb6d CCCTGGCTTCAAATACTGGC 12808 Hepal-6 Aga CGCGAGAGTTGAGGAAGTTG 18792 B16F10 Serpinbbd AGGCTGCAGCAGAGGATACC 12809 Hepal-6 Aga GCCTTCTATTGGCCCAGTGA 18793 B16F10 Serpinbbd CAAGGGTGAGGCTAAGGTCC 12810 Hepal-6 Vgf AATGAACATTGACGTCAATG 18794 6F1 Nkapl AGGGCTCTTGCGCAGGCTCT 1281 1 Hepal-6 Vgf GACGGTGAAAGTCCAATGAT 18795 B16F10 Nkapl GCGCTGTGTGCGGGTTGTGC 12812 Hepal-6 Vgf GCGCCGCCTCTGCCTTATAA 18796 B16F10 Nkapl CAGCGCCACGGTTCGGACTA 12813 Hepal-6 Rtkn TTTGTTCTGGGCAGCCTAGA 18797 B16F10 Flii CCTCCCTGGGACCAGAGTTC 12814 Hepal-6 Rtkn TGGAITAGCTCACCAGCACT 18798 B16F10 Flii AAGTGTTGATCATCTCCAGC 12815 Hepal-6 Rtkn TTCTCTGAGTCAGAAGAGAG 18799 B16F10 Flii GCGGCGCGCGCGGGTTAAAG 12816 Hepal-6 Map2k3 GGGTITGTGCGTGACAGTCC 18800 B16F10 Hydin GTGGCTCACACTCTAGTAAG 12817 Hepal-6 Map2k3 CGGAGCCGAGCTGTACTAAG 18801 B16F10 Hydin GGAACGATGATTGGAGGAGG 12818 Hepal-6 Map2k3 GCCAATCAGTACGATGGGCG 18802 B16F10 Hydin TGTGGGTCAGGAAACTGTAA 12819 Hepal-6 Klrblc AGTGTGTAAGCTGTGTGGGT 18803 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Gjel GAGAAATTTGCAGACATAGG 12820 Hepal-6 Klrblc CAAAGGAGCAGTGGATCTGG 18804 B16F10 Gjel GGTGATAGGAAAGTTGACTA 12821 Hepal-6 Klrblc GAGGCCTGTTCCTTTCTGAA 18805 B16F10 Nd s6 TAACTGTGCGCAGTGTTCAA 12822 Hepal-6 Ralgps2 CGCAGACTGCGCCGAGACCC 18806 o B16F10 Ndufs6 TCGTCCTATGCCTGAGCGGC 12823 Hepal-6 Ralgps2 GGCGGGCTGCGGGTCGCTCG 18807 o B16F10 Ndufs6 GTTACTAGTGTGACAAAGGC 12824 Hepal-6 Ralgps2 CGCGCCTCGGACACCGGTAC 18808 80 B16F10 Nrgl CGATAAGGCACCCAAGTCCA 12825 Hepal-6 BC027072 TGCTCATGTCCTGACAGATG 18809 r B16F10 Nrgl TGCTGTATCATTTGGTTGGG 12826 Hepal-6 BC027072 ATCTTGGGAACCGATTATTC 18810 o 4 B16F10 Nrgl CGGATCACCTCCAGAAGGCC 12827 Hepal-6 BC027072 AGCCGTGCTTTAAGCTTATT 1881 1 6 1 B16F10 Spen GCGCACTAAGCTGACTGCGC 12828 Hepal-6 Zfp850 TGGGACCTTTCGGAAACGCC 18812 B16F10 Spen CTGGGAGGCCCTCCGCGTCG 12829 Hepal-6 Zfp850 TTGAAGGCTCCACATAGCTC 18813 B16F10 Spen AGGAATGCGGAGCCGGGAAG 12830 Hepal-6 Zfp850 GCAACTTAGCCCGGCCCATC 18814 B16F10 Ush2a AATCACGCTCATCGACCTAT 12831 Hepal-6 Atl2 CCGCAGCTCTCAGACTTCTA 18815 B16F10 Ush2a GACAAAGATCTGAACGTTAT 12832 Hepal-6 A112 GCTCCGCGGCAGGTTGGCCC 18816 B16F10 Ush2a CTAAGTTGTGTGGTTCATAA 12833 Hepal-6 A112 GGGCCGCGCAAGTCAGAGGG 18817 B16F10 Kl d GAAGCCAGTAAATATCCTAA 12834 Hepal-6 Lamal CGCCGTGCGGAGTCCTTCCT 18818 B16F10 Kl d 9 AAGATCGCGGTAGCTTAACC 12835 Hepal-6 Lamal GGAGGTCCTGGGTAGGACAG 18819 B16F10 lhdc TCGCAAAGCGCCTGTTACCT 12836 Hepal-6 Lamal GGCCTGGTGCGCAGGCCCTT 18820 B16F10 Gcm2 CTGAAAGAGAGATAAAGCTG 12837 Hepal-6 Vcpipl CGTCGAGTCGCTTTGCATCA 18821 B16F10 Gcm2 GGAGGAAATAGGAGGGAGGG 12838 Hepal-6 Vcpipl CGCCTGCGCAGTCTCAGTGA 18822 B16F10 Gcm2 TCACTTACCTCCTTCTCACT 12839 Hepal-6 Vcpipl CTCTGGGAACCAGAGTCTTC 18823 B16F10 Zkscan3 ACTAAGAGGAGGGAGAAGGG 12840 Hepal-6 Rnaseh2c TTAGGGCTGGGTGGGCACGG 18824 B16F10 Zkscan3 TTACGAGGCAACCAAGAGGA 12841 Hepal-6 Rnaseh2c GGCTCTGCATCTAGTGTGCT 18825 B16F10 Zkscan3 AAACTGGAGGAAGTAAAGGG 12842 Hepal-6 Rnaseh2c AGACITGAGCACAGGAAGGC 18826 B16F10 Herc2 TGAGAGACGGCTTCAGCCAA 12843 Hepal-6 Stl8 TATCACTCCTCTGCAGCAGA 18827 B16F10 Herc2 TGCGCCCGCCCAATAGCGCA 12844 Hepal-6 Stl8 TGAGCCATTGTTATCATCCC 18828 B16F10 Herc2 TGAGCGGGTGAGTCTCAAGA 12845 Hepal-6 Stl8 CACTGAGTGGCACAGCCTTC 18829 B16F10 Rprdla CCCAGGGAGAGCAGCGCGAG 12846 Hepal-6 Gata4 GAGTCCTGCGGGCGGGCGCC 18830 B16F10 Rprdla GTGTGACGTCACTGCCGGCC 12847 Hepal-6 Gata4 CGCAGGCGATCGCTACGCGG 1883 1 B16F10 Rprdla CAATCCAGCAAGATGGCGCC 12848 Hepal-6 Gata4 GCATGGACTTTGCCTGTTGG 18832 B16F10 Ephb3 GCACTCTGCTGGAGTTCAGT 12849 Hepal-6 Skint5 TCTGACTCTGGAGTGCTTTA 18833 B16F10 Ephb3 CTGCCTGCCCGTCAACACTC 12850 Hepal-6 Skint5 GCTGGGCATGTTAACCCACA 18834 B16F10 Ephb3 CTCACTTCTGCTGGTCCTCG 12851 Hepal-6 Skint5 TCAGGGTAGGTGAAGGGTGT 18835 B16F10 Rtt CACAGCCCGCGTCTGAAAGC 12852 Hepal-6 Pxdcl GAACGGGCTGCGGCTTTATA 18836 B16F10 Rtn CTCAGTACCAAGGAGCGAAG 12853 Hepal-6 Pxdcl CAGTTGGCAGACCAGGGAGG 18837 B16F10 Rtn ACGGAAATTCTGTAGGCAGC 12854 Hepal-6 Pxdcl TCGACGTCGCCGCCCGCGAT 18838 B16F10 Ttlll2 GTGTCTTCTCCATTCATCCC 12855 Hepal-6 Ttc9c TTCCCGGCCACTTCTCCAAT 18839 B16F10 111112 AGAATCCCTCGCGGCAGTCC 12856 Hepal-6 Ttc9c ATTGGTCCTCCGATATCGTG 18840 B16F10 TdU2 CTCTTGGAACCTCGCAACCC 12857 Hepal-6 Ttc9c GGCTAAACTGCTGGCAGGTC 18841 B16F10 Scn7a CTCTAGAAGCTAGATAAGCG 12858 Hepal-6 Itgb21 GAAGCATTCTCATAGACCAG 18842 B16F10 Scn7a AAACAGCTACAAGGCTTGCT 12859 Hepal-6 Itgb21 AGTTGCTCTCAGCGGCTACA 18843 v > B16F10 S 7a GGCAATAACAGCTTCAGCAG 12860 Hepal-6 Itgb21 GCAGACACACCTTATGAGTC 18844 o B16F10 Pde4a GTGTGGAGTATGTTTCTATC 12861 Hepal-6 Rpl29 AAAGCTTCCCTCACTGCTGG 18845 80 B16F10 Pde4a GCGTTGTTTGCTGCTCCAAA 12862 Hepal-6 Rpl29 GAAAGGCCCGCAGTGCAGCA 18846 B16F10 Pde4a ACACATCTCATCCAGAGACA 12863 Hepal-6 Rpl29 GGAAATAGGGCCGACACCGC 18847 ~ B16F10 Usp53 AGCCGGGAACTCACGTGCGG 12864 Hepal-6 Wdr70 CGAGACCGCGTCGCCAAGAG 18848 80 6/1 B16F10 Usp53 TCGCGCCTCACACAAGCCCT 12865 Hepal-6 Wdr70 ACGCATCTGAAACCACCGAA 18849 0 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Usp53 GGAAAGGGAGCATCACCCGC 12866 Hepal-6 Wdr70 AGCCACGAGGAGGTCTAGTT 18850 B16F10 Dclrelc AAACAGCTGTGCGTAGTTTG 12867 Hepal-6 Dsp CTTCTTCCCAGGGCGAGGTG 18851 B16F10 Dclrelc GATCAGGATTGGATGCCCAT 12868 Hepal-6 Dsp CCCGCGTGTCACCGACGCCT 18852 B16F10 Dclrelc AAGGGTCCTTTGATTGGATG 12869 Hepal-6 Dsp AGCCTGAAGCAAGTCCCGCG 18853 B16F10 Slc35a4 GCTGGGCAAGGATTATATGC 12870 Hepal-6 Mbd4 GCGCGTAGGGACGCAGGAGG 18854 B16F10 Slc35a4 GCACCGCGCAAACAAACGCT 12871 Hepal-6 Mbd4 TCCAAGTGCGCATGTACAAA 18855 B16F10 Slc35a4 CGGGATAGGGACGGCCTTGG 12872 Hepal-6 Mbd4 TTGGTCCGGAAAGGTGGGTG 18856 B16F10 Kdr TGCCGCCCGGCACAGTTCCG 12873 Hepal-6 1127 TGTGTTCACTAAGTCTTCCC 18857 B16F10 Kdr CAAACCTGGTATCCAGTGGG 12874 Hepal-6 1127 AACGTAATTTCCCTTCCCAG 18858 B16F10 Kdr GCCGGCTACACACTAGCGAA 12875 Hepal-6 1127 GATGGCTGCACACAGAGGCT 18859 B16F10 My AGGGAATCTTTGACAGCGCC 12876 Hepal-6 Xpa CGTACTGCCTCGCCCTTCAT 18860 B16F10 M h AACTTATGAGAAGGCCCACC 12877 Hepal-6 Xpa CCACCACTCCTCGGCTGCGC 18861 B16F10 Myh8 GTCGCTACAAACTTCGCCGA 12878 Hepal-6 Xpa GCACTTGTTGACAAACAATC 18862 B16F10 Taar9 TTTACAATTACCAAGACTGG 12879 Hepal-6 Irgq CAACGCTAAGCTTACTGCGT 18863 B16F10 Taar9 GGTTAACAACTGTCTTAGTC 12880 Hepal-6 Irgq ATTGGTTGCTGGTCTTGGTG 18864 B16F10 Taar9 GATTGCTAGAATGGAAACCT 12881 Hepal-6 Irgq AAACCCTGCACGTACTGCGC 18865 B16F10 Tbcld5 GTTACTAGAGGTGGAGCGCC 12882 Hepal-6 Almsl AATCATGGGTGACTTTGTGC 18866 B16F10 Tbcld5 CCTAGGCAACACAGTAGAGC 12883 Hepal-6 Almsl GAACCAGCCCGCGCGTTGCT 18867 B16F10 Tbcld5 TAAGCCAGCCAAGGCAGTGC 12884 Hepal-6 Almsl AGCATACGGTACTGTGAGCG 18868 B16F10 Soxl2 GCGGCCCGCAGACGGCGAGG 12885 Hepal-6 Mclr CAGAGGCAGCACCGAGAAAC 18869 B16F10 Soxl2 CGCGCAGCGAGCGCGAGGCG 12886 Hepal-6 Mclr AAGAGATTGGTAAGTCACAG 18870 B16F10 Soxl2 GGCACCTCGGTGTTTACACG 12887 Hepal-6 Mclr CTAGCTTTGGACTCCAACAC 18871 B16F10 Tnpo3 CTCCTTTCTGGCCGTTACCA 12888 Hepal-6 Ccdcl3 AGGCAGCACATGCCGGCGTC 18872 B16F10 Tnpo3 CGAGAGTCTGCGATTCTGGC 12889 Hepal-6 Ccdcl3 CAGACCTTTAGAGGCTCTCT 18873 B16F10 Tnpo3 CAGAAGCCAGAACCCGTGTC 12890 Hepal-6 Ccdcl3 CTACGAAGCCTCCACTCTTC 18874 B16F10 Mtmrl GTTGGCGACCCGCAGGTTCC 12891 Hepal-6 Fmtpdl CTTGGGCTCCGGCTCGGCTC 18875 B16F10 Mtmrl GCTGGTTGAGGGTAGGGTGT 12892 Hepal-6 Frmpdl ACCGTGGCCGCCGCTGGGCG 18876 B16F10 Mtmrl CTGTCCTGATTGCTCAGGCT 12893 Hepal-6 Frmpdl TCTGGCGGCGGCAGGTGCTG 18877 B16F10 Hk3 GAGACCAGCCTAGAAATTTG 12894 Hepal-6 Paxipl TTTCCCTCACATGGCCGCAG 18878 B16F10 Hk3 GCGCTGCTGAGAGAATATTT 12895 Hepal-6 Paxipl GCGCTGTCAGGTGGCCGCAC 18879 B16F10 Hk3 AACCCTAGGATTTAAACTCT 12896 Hepal-6 Paxipl ATGGTCTACAATAGTTCGTA 18880 B16F10 Al sl AATCATGGGTGACTTTGTGC 12897 Hepal-6 Unc80 CGCGCGCGGAACATGGCTGA 18881 B16F10 Almsl GAACCAGCCCGCGCGTTGCT 12898 Hepal-6 Unc80 GGTTCTGCGGTAGGACTCCC 18882 B16F10 Almsl AGCATACGGTACTGTGAGCG 12899 Hepal-6 Unc80 GCCGGCGAGGAACCCGCGCT 18883 B 16F10 Ccdcl85 AGCATCAGTGTTTCCATTAG 12900 Hepal-6 Cdkn2a CCGCGCGCCTTGGGACTCGG 18884 B16F10 Ccdcl85 ACAGGATCTGAGCGTGGGCT 12901 Hepal-6 Cdkn2a GTGGAGCAAAGATGGGCCGG 18885 B16F10 Ccdcl85 CACCAGGATGCATTGTGAAG 12902 Hepal-6 Cdkn2a CTATGGCGGGCTGTGGAGCC 18886 B16F10 Slcl7a6 AAGCTGCATTTGGCTCTGCA 12903 Hepal-6 4932429P05Rik ATCTTCACTCATTAGAAATG 18887 B16F10 Slcl7a6 TGGGCGGATCGCCCTGACCA 12904 Hepal-6 Ceacaml5 GGGAGAGGAGGAAGGAAGAA 18888 B16F10 Slcl7a6 GGATGCTATGGAAACCAAGT 12905 Hepal-6 Ceacaml5 GTTCTGTGAGTTTGAGGTCT 18889 B16F10 Pop7 TTTAAGGCTCGCGAGACTTG 12906 Hepal-6 Ceacaml5 TTGACACAGATCATGGCCTT 18890 B16F10 Pop7 ACGCGCACGAGGAAAGGAGG 12907 Hepal-6 Dek GGCGTCTCTCGCGGGCTGCC 18891 B16F10 Pop7 GGTTCTAGTGAGCGCTTCGA 12908 Hepal-6 Dek CTGCGGTCCGCGGGAGGACC 18892 B16F10 Adamtsll AGACATGCTGAATAACAAAG 12909 Hepal-6 Dek GCGCTGGGAGTTGGCGCGCG 18893 B16F10 Adamtsll TTAGCAGGAGTCTGATTGGC 12910 Hepal-6 Bag3 GACACCGGTGCGTGTCAACC 18894 B16F10 Adamtsll GAATGGAATCTCTCTAGAGC 12911 Hepal-6 Bag3 CTCCTTCTCCTAGACTACCC 18895 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Kcnbl ATGGCTGCTGTTCCTCCCGC 12912 Hepal-6 Bag3 GGAGCTCCGCCCTGAGTCAT 18896 B16F10 Kcnbl GGTGGCCCTCCAGGCGGGAG 12913 Hepal-6 Xkr9 ATGGTAACTATGTTAAAGGT 18897 B16F10 Kcnbl GGGAAGGTCAAGGCCGGTAG 12914 Hepal-6 Xkr9 ACTCCTATCAATAGATAGAG 18898 B16F10 Cntnap4 GGAACCAGTACTGAGGGCAG 12915 Hepal-6 Xkr9 ATGCTTTGTCTTCTCAGTGA 18899 B16F10 Cntnap4 GAAGGAAGGAGGAGCAAGGG 12916 Hepal-6 Eifiakl CTAACCCGGGCAGAGCGGTC 18900 B16F10 Cntnap4 CGCGCGTGAGAGGAGGGAGG 12917 Hepal-6 Eif2akl CTGGTGAGTCTGGTTAGGAA 18901 B16F10 Tmeml32d GAGAGGGCGACTGCGAGGCT 12918 Hepal-6 Eif2akl TTGCATACCATGTGCGCCTC 18902 B16F10 Tmeml32d GGGACCTACTTTGCGGATTG 12919 Hepal-6 Cacnali ACAATTTAGGGTCGCACCGC 18903 B16F10 Tmeml32d AATAGGAGGGAGATGTTCAA 12920 Hepal-6 Cacnali AGGAGGTGGCTGCACTCCCG 18904 B16F10 Nr2el GGTCTGACGTCAGCCATGTG 12921 Hepal-6 Cacnali GCGGGCGACAGACTGAGTGA 18905 B16F10 Nr2el GATATTAATGAACCTCCAAG 12922 Hepal-6 Mkm2os GGATGATGTCACTGTAGATT 18906 B16F10 Nr2el ATCTCCAGTAGCGCTCTGAC 12923 Hepal-6 Mkm2os TAGATGCTGCCGTTTGCAGC 18907 B16F10 Apob GGCTTAAGGAGAATTGCCAA 12924 Hepal-6 Mkm2os ACTGGTTAATCTACCTAGCT 18908 B16F10 Apob TTCCATACAAGCGCATTTCT 12925 Hepal-6 I i I TGGCGTCCCTCTCTGGGCAC 18909 B16F10 Apob GCTCCATTTATAGGAGGAGC 12926 Hepal-6 Limdl GGGCGCGGGCGGAGGCTCGG 18910 B16F10 Klklbl6 AGCAAGCTGAAGCCAGAGCC 12927 Hepal-6 Limdl GCGCATCACTGGCCTGCAGG 1891 1 B16F10 Klklbl6 AGTCACTACGTAGACTAAGA 12928 Hepal-6 Esxl TAGGGAGCTCAAAGTCCGAC 18912 B16F10 Klklbl6 GACAGCTCTATATATAAACC 12929 Hepal-6 Esxl TGTGCGAGCTGGTGCGAACT 18913 B16F10 Sema3b AGGATCTGACTCTCATCTGT 12930 Hepal-6 Es l CTAGGCGTCCCAGAGCACTA 18914 B16F10 Sema3b GGTAAGAAAGTGACAGGCTG 12931 Hepal-6 Ncf4 GAAGTGGCACCCTTGGGTGC 18915 B16F10 Sema3b GGAGGAATGTGCACGAGGGA 12932 Hepal-6 Ncf4 GATGCITGAGAAAGGGATTC 18916 B16F10 Ascc2 GGGTCAAACTGCGATTCCGT 12933 Hepal-6 Ncf4 TAGCCCTGGGTAGTCCATCA 18917 B16F10 Ascc2 CAAATTCCTGCGCCTCCAGG 12934 Hepal-6 Foxql CACAGAGTCTCCGCGGGCGC 18918 B16F10 Ascc2 CCCGGCGCCAACTGTGGAGG 12935 Hepal-6 Foxql AAGCTCCTACCTGCGCAGCG 18919 B16F10 FzdlO AGCGAAGTTTGCAAACAATA 12936 Hepal-6 Foxql CGCCCTTTCGGTCTCGCCAA 18920 B16F10 FzdlO TCGCCCGCGCCCGGAAGAAG 12937 Hepal-6 Tln2 AAGCAATGTATTAGTTAGCC 18921 B16F10 FzdlO GCCGCTCAGCGCGCAAACTT 12938 Hepal-6 Tln2 AAGGTGTGTGCTGCCATGCC 18922 B16F10 Col4a6 TTGCATAGATTCTTGTGTAT 12939 Hepal-6 Tln2 GGCAGGCAGATCTAAGTGTG 18923 B16F10 Col4a6 TTTGGAACGGTTATGTGCAG 12940 Hepal-6 Didol TGGGAGCCAATGCCACTAAA 18924 B16F10 Col4a6 AAGCAGCTTCCCAAGGTAGG 12941 Hepal-6 Didol AGATGCGAACTGGCAACCAA 18925 B16F10 01frl274-ps GGAGAGAGAGTGCAAATGGC 12942 Hepal-6 Didol GCGCATGCGTGCAAGAAGGG 18926 B16F10 01frl274-ps TAGCAAGAATGTCTATTATC 12943 Hepal-6 C gd GGCTTTGGTTCTATTCACTC 18927 B16F10 01frl274-ps GGGAGTTAGTAACATGAAGA 12944 Hepal-6 Crygd CTCTTTGCTGTCATAGCCCA 18928 B16F10 Acaalb TGGCTGCAGAATGGGTAGGC 12945 Hepal-6 Pdzd2 CAGGCCAGCAGATGAGCTCT 18929 B16F10 Acaalb TGGACAAACTTAAGAAGGAG 12946 Hepal-6 Pdzd2 CATGGGCAGAGCTGATGATT 18930 B16F10 Acaalb GTACACACTTGCACCATCAC 12947 Hepal-6 Pdzd2 GGGATGCCTCCTGTGAGGCT 18931 B16F10 Wdr3 1 GGTATGTGAATATTCTATGC 12948 Hepal-6 Clip GCTGGAGATGTAGGGATGGG 18932 B16F10 Wd 1 GGAGTTCCACCTAAACGCTC 12949 Hepal-6 Clip GGGAGTCTCATGCTCAGATC 18933 B16F10 Wdr3 1 CACGTGGAACCTGGGTTCCG 12950 Hepal-6 Cilp CATCAAGATCCTTAGGGATG 18934 B16F10 Blocls3 CTTTCCTATTGGCCATAACT 12951 Hepal-6 Fgf3 ACCGGGAAGAGGTGGGAGAC 18935 B16F10 Blocls3 GACAAGTCGCTTCCGTAGTG 12952 Hepal-6 Fgf3 GGTGGAGATGGAGATAAGGA 18936 B16F10 Blocls3 CACGTGACGCTGCGAGAGAC 12953 Hepal-6 Fgf3 GTGGAGAGAAGACAAGAAAG 18937 B16F10 Rad5412 AGTCTCACTTATTCATGAAA 12954 Hepal-6 Zrsr2 CGCCTTGAATTCTGGGCAAG 18938 B16F10 Rad5412 CGGCGATTCTTGGGTGAGTA 12955 Hepal-6 Zrsr2 CTTGGAATTTAGATGGGAGG 18939 B16F10 Rad5412 TCACAGCGGAACTTTGCTGC 12956 Hepal-6 Zrsr2 GGAITCTTAAACTTCGTCTG 18940 B16F10 Rpll3a CGGTGAGTGCGCGTCTATCG 12957 Hepal-6 Cntn3 AACTCTCTCTTTAAAGGAAC 18941 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Rpll3a TCTTGGCGGCCATGACTGTG 12958 Hepal-6 Cntn3 TAAACAGTATGTGCAACTGA 18942 B16F10 Rpll3a ATTAGAAGACGGAAACTCTT 12959 Hepal-6 Hoxa9 TTCAAGGATAACCAAGGCAG 18943 B16F10 Pou6f2 CCTCAGTATAAAGTCCAGCC 12960 Hepal-6 Hoxa9 TTGAGCTGTAGTTTGACTAT 18944 B16F10 Po 6f2 TCAGGATGACCAATGTCAAC 12961 Hepal-6 Hoxa9 AAAGAGAGGAAGGGAGGGAG 18945 B16F10 Po 6f2 ATGTCATAGGACAGACACTA 12962 Hepal-6 Sfswap TGTCCAACTTGATCTTGCGA 18946 B16F10 Def8 ATGCAATTACTAAGGCGTGG 12963 Hepal-6 Sfswap GCTCAAACAGCTTGCGGACG 18947 B16F10 Def8 GGCAAAGGTAATGGACTCTA 12964 Hepal-6 Sfswap CGCTTTCGTCACATCCTAGG 18948 B16F10 Def8 AATCGGTGTCATGAACCTCC 12965 Hepal-6 TnfsflS AGTGCTTAGCAGTGTTCCAA 18949 B16F10 Nkx2-6 TGTGCATCCCAGAATCGATT 12966 Hepal-6 Tnfsfl8 GCACCAGGCCAAACATACAA 18950 B16F10 Nkx2-6 GGACCGCGCCTTCCCTTGAC 12967 Hepal-6 Tnfsfl8 CACTACAAGGGAAGTTCAGA 18951 B16F10 Nkx2-6 GCGATCTTATCACCCGGTCC 12968 Hepal-6 Utpl4a GGAGGCTTGCAAAGTATTGT 18952 B16F10 Zfx CGGTGGGCCACGGCCTCGTG 12969 Hepal-6 Utpl4a GGCGCTCCAGGATTGGTCGA 18953 B16F10 Zfx CCGTCGAGAGGCGGGAGGCC 12970 Hepal-6 Utpl4a GCGTTGTCGCGCGTGATTAG 18954 B16F10 Zfx CGGCCCACAAACATGGTGGG 12971 Hepal-6 Dnaicl GAGGCGGAACTTGGGCGCGC 18955 B16F10 Ceacam5 TGTTATTCTCTGAGGGCATG 12972 Hepal-6 Dnaicl GCGGTTACCCAGCAACCGAC 18956 B16F10 Ceacam5 TCTTGGAGGTAGAACATAAA 12973 Hepal-6 Dnaicl TATCTTTCTCTGCGGAGGCG 18957 B16F10 Ceacam5 CATCCTACCTAGGTGTCCTT 12974 Hepal-6 2300002M23Rik GGAACTGGGTGTTCCTCACC 18958 B16F10 Ehd2 GTCCTAGCCCGCGCCAGCCT 12975 Hepal-6 2300002M23Rik GTGTCACTTGAAAGTTCCTG 18959 B16F10 E d2 TCAACTTATTTGCTAAGAGA 12976 Hepal-6 2300002M23Rik ATCAAGAATGAGGGTGGACT 18960 B16F10 Ehd2 TGATCAGACAAATTATTGGT 12977 Hepal-6 Sh3rfl CCCAGCGGGCGGCAGCTTCG 18961 B16F10 Slcl5a2 ACAGTGCTAGAGAATCGATT 12978 Hepal-6 Sh3rfl GGAACGCGACGCCGCCAAGG 18962 B16F10 Slcl5a2 TACTCAAGAATGCAGCATCT 12979 Hepal-6 Sh3rfl GGACGCACTTAGCGGGAGGA 18963 B16F10 Slcl5a2 TATCTAGTCCTCATTTGCAG 12980 Hepal-6 Lrm4cl AAACATCTGTGGATGGCTTG 18964 B16F10 Rasal3 AGACAGGGTCACGTGGAGCT 12981 Hepal-6 Lrm4cl GAGAGGAGTATTATCGGAGG 18965 B16F10 Rasal3 GGCTTCTGACGAGAAGGTCT 12982 Hepal-6 Lrm4cl TCTGACAGAGGAATGAAATG 18966 B16F10 Rasal3 CCCAGCCTGACTGTAAAGGG 12983 Hepal-6 Mfap3 TCGGATCGGCGAGCGAGCGG 18967 B16F10 Dapk2 GCATCCAAGTCCTCACCTCG 12984 Hepal-6 Mfap3 GCAACGCTTCCAGCCATGTT 18968 B16F10 Dapk2 CGGACACTCGGCCCGGAGCT 12985 Hepal-6 Mfap3 GGAGTACTTCCGCGACGGTC 18969 B16F10 Dapk2 TCAAGTTGATTCGTTCCAGG 12986 Hepal-6 Dctnl GGCACTGAGCTAGACACCTG 18970 B16F10 Sphkap GAGGCGGGAATTAGGCTGAA 12987 Hepal-6 Dctnl TGACAAGGTCTCGCCAAGCG 18971 B16F10 Sphkap ACAACTTCAGGGCTGAGACT 12988 Hepal-6 Dctnl TTCTGGGACCCGAGGGCTTT 18972 B16F10 Sphkap TGTTCACCAGAGAAAGCAAG 12989 Hepal-6 Prss52 CATCTACAAACCAGTCTGTT 18973 B16F10 Ggact TTTCGGAGGAATGTGGCTTC 12990 Hepal-6 Prss52 CTGCTTAGGGTGGCCCACCC 18974 B16F10 Ggact CTGCGCGGTTCCGGCACATG 12991 Hepal-6 Prss52 GGTGGCCTCCTGAGACCTCC 18975 B16F10 Ggact GTGTCGCAACCAAACCGCCC 12992 Hepal-6 Dctn3 TAGGCGGACGTCCCACCCTC 18976 B16F10 Pdzkl CCCTTCCCATTGTTAGGCTG 12993 Hepal-6 Dctn3 GCGTGACGGTGCTCTCGGAT 18977 B16F10 Pdzkl ATGTATITAACAGGGACGTG 12994 Hepal-6 Dctn3 GGTTACCTAGGTAACGTTCT 18978 B16F10 Pdzkl GGTTAGACAACAAAGCACCT 12995 Hepal-6 2810021J22Rik CACAGGTTCTGAACTCCGGA 18979 B16F10 Fam205al GGTAATTCAGTCTACAGCAG 12996 Hepal-6 2810021J22Rik GGAAATAGACCGGAAGTTCG 18980 B16F10 Fam205al TGAATGTCACATTCACAAGC 12997 Hepal-6 2810021J22Rik AATACATCGAAGCTCTAAAG 18981 B16F10 Kptn GTTACTGCCCTCTACAAATA 12998 Hepal-6 Pldl GCCGGCCTTCCTCCATGCCT 18982 B16F10 Kptn TCTCTGAAAGCAGTGTGTAA 12999 Hepal-6 Pldl TCCCTAAAGGCAATTCAAGC 18983 B16F10 Kptn GGGCCTTCCAGGATTTGAGA 13000 Hepal-6 Pldl GTGTGTGCTCTGGCTTTCTT 18984 B16F10 D930015E06Rik CTCGGGAGCAAGCGGCGCGC 13001 Hepal-6 Prrl3 TTGCGTTGTGAAATACATAC 18985 B16F10 D930015E06Rik GCGTGTGCTCCGCAGATAGA 13002 Hepal-6 P rl AACTGACTTGTCAATCGCTG 18986 B16F10 D930015E06Rik CAGCAGTCCAACAGCTGCGG 13003 Hepal-6 Prrl3 GATCACTTTGACACGATGAT 18987 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Dock2 GAAGGCAATCTTCTAGCCCT 13004 Hepal-6 Cyyrl TATGAGGGTGGCACCAAAGT 18988 B16F10 Dock2 CCACCCTCATTTGTCTCTTC 13005 Hepal-6 Cyyrl AGCACCCTGCCATTCTATAG 18989 B16F10 Dock2 GCCTTGTAGCCACTTTCCTC 13006 Hepal-6 Cyyrl GTCCTTGGCCACCCAGGTTC 18990 o B16F10 Urbl GGGCGTGTCTCTGGGTGGTG 13007 Hepal-6 Trim39 GGCCTGCGCGGCTAGTTTAC 18991 B16F10 Urbl AGCCGGTCTTCGGGTGAGAA 13008 Hepal-6 Trim39 GGCGATGGAAGACAGCTGCG 18992 B16F10 Urbl CGTGGAGAAGGTAGAACACC 13009 Hepal-6 Trim39 GCGGCGGGTTCCCTCTCGCC 18993 B16F10 Kif27 GCTCTGCITTGAAACATGAA 13010 Hepal-6 Wdr43 CTTCTTAACTTGTCCTGCGA 18994 o 4 B16F10 Nup214 GCGTGGTAGATGCGCGTTTC 13011 Hepal-6 Wdr43 GACGCAGGCCAGCGTTTAGC 18995 B16F10 Nup214 ATCCAAAGGAAGGCGGACTC 13012 Hepal-6 Wdr43 CACCGTCCACAGGGTGGGCC 18996 B16F10 Nup214 AGTGTGCTCGGAGGCAGTCG 13013 Hepal-6 Mgmt TGCAGITGATTACTGAGCTG 18997 B16F10 Pnrcl AGAGATTTCGGAGAACACTA 13014 Hepal-6 Mgmt ACGGGCCGCAGGCGCGTGCA 18998 B16F10 P cl GAAGCTTCTGACCTCCAGAA 13015 Hepal-6 Mgmt TGTAGTCCGAGGGTGTAAAG 18999 B16F10 Pnrcl TCACTAAGGATTTACAGCAC 13016 Hepal-6 Qiil6 TAGAAACTTGCACTGATGCC 19000 B16F10 Ptprq GTATAAATTTCAGCACCCAG 13017 Hepal-6 Chil6 TCTGTTAAGATAAGGCAATC 19001 B16F10 Ptprq ACTCTTGGATGGATGGCTGT 13018 Hepal-6 Chil6 ACAGAGCTAATACTTTCCAA 19002 B16F10 Hdac9 GTTGTTGATTCATATGCAAA 13019 Hepal-6 Atp2b2 GCTCCCACGGGACGCATCCG 19003 B16F10 Hdac9 GTTCTGCTCAGACAATAAGA 13020 Hepal-6 Atp2b2 AGGAGGGAAACGAGTCCTCA 19004 B16F10 Hdac9 TAATGCAGGCTGCAATCACT 13021 Hepal-6 Atp2b2 CGCTGTCCGAGCCGAGTTCG 19005 B16F10 Eif4al GGCTTTCAAACTACCCAATA 13022 Hepal-6 Yaeldl TCAGTTTCTGCAAGTGCTGA 19006 B16F10 Eif4al CGGAAGTGACATACTTAAGT 13023 Hepal-6 Yaeldl CGGGACGAAAGGACAAGGCG 19007 B16F10 Eif4al ACTTTGTAGGCGCTTTAGTT 13024 Hepal-6 Yaeldl TGGGTCTCTTCCTACGCCTC 19008 B16F10 Nipbl TTTGTTCTGAGAGGGAGAGA 13025 Hepal-6 Syne2 TTGCGGTGGCCGCAGGGAGG 19009 B16F10 Nipbl CCGACCGGAAGTGCAGCTGC 13026 Hepal-6 Syne2 GAGGAACTAACTCCGAACGC 19010 c B16F10 Nipbl GAGTCGGTACCGACGGAGGG 13027 Hepal-6 Syne2 TCCGCCTTACAGACCCTTGC 1901 1 B16F10 Ankrd24 GGCTGCCCATCTGAGCAAGC 13028 Hepal-6 Zfp446 AGCGCTAGCTCTGATTGGTC 19012 B16F10 Ankrd24 GCTGCCATTGACCCATCACA 13029 Hepal-6 Zfp446 CCCTGCCTCGGAGAAGGCCT 19013 B16F10 Ankrd24 GGTGGGAGAGGCCGTCCTTG 13030 Hepal-6 Zfp446 TTGTGCGCTAGCTGTTACCT 19014 B16F10 Ddx50 ACGCACGGTCCTGGCCGGCG 13031 Hepal-6 Otog GGTAGTTACAAAGGCATAGA 19015 B16F10 Dd GACCGTGGGCGGGCCCATCG 13032 Hepal-6 Otog TCAACTTATGGTAATGAGCT 19016 B16F10 Dd AAAGCAAGCCGGAACTCTAC 13033 Hepal-6 Otog ACAAAGACTGGTCTGTAGCC 19017 B16F10 UncBO CGCGCGCGGAACATGGCTGA 13034 Hepal-6 Wdr62 CACCGCCCATTGGACGCAGC 19018 B16F10 Unc80 GGTTCTGCGGTAGGACTCCC 13035 Hepal-6 Wdr62 CGGGTAGGCTCATTGCCCAA 19019 B16F10 UncSO GCCGGCGAGGAACCCGCGCT 13036 Hepal-6 Wdr62 GCTTTGTGATTGGCCAGCCG 19020 B16F10 Rplll CAAACCTCCTCTCAGGCCGA 13037 Hepal-6 Terf2 AGCATTGCAGCAGACACAAG 19021 B16F10 Rplll TCCAAGAGAGCTGGAITATA 13038 Hepal-6 Terf2 TGAAGACTACGCTGCAGACT 19022 B16F10 Rplll GCAGTTGCACAAATGGCTTC 13039 Hepal-6 Terf2 ACTACGGATGCCGAGGAGGT 19023 B16F10 Tlrl2 AAATGACACCAGGGCAACGT 13040 Hepal-6 Acsll TTCCCAATAAGAACGAACAA 19024 6F1 rl CTGAGCTCGTGGGACAGCCT 13041 Hepal-6 Acsll GGGACCAGCATCAGTGAGTG 19025 n B16F10 Tlrl2 TCTGTTTGCTTTCTCCTAAC 13042 Hepal-6 Acsll AGTGGGCGCGCTAAGAGATG 19026 B16F10 Respl8 GTCGCGTCTCTAGCGCTAGA 13043 Hepal-6 Cxxlc AGGCTTAGCTGAAAGTGCAG 19027 n B16F10 Re p l AACTTGGGTAAGCAGCTGCA 13044 Hepal-6 Cxxlc CTTGGTTGTCGCCTTTGTGT 19028 o B16F10 Re p l GGGCAGAGCCTGCTTGTGAT 13045 Hepal-6 Cxxlc TGGGCCGAAGAGAATGCTTC 19029 B16F10 Fmipdl CTTGGGCTCCGGCTCGGCTC 13046 Hepal-6 Cpsf4 CAGAGTCCGGCCACTCCTTC 19030 B16F10 Fmipdl ACCGTGGCCGCCGCTGGGCG 13047 Hepal-6 Cpsf4 CGATCGGTCGGCGGCTAGTC 19031 b B16F10 Fmipdl TCTGGCGGCGGCAGGTGCTG 13048 Hepal-6 Cpsf4 GATCTCCGTAGTCTGTGCTG 19032 J B16F10 Antxrl CAGTGCCAAGAGACAGTCAC 13049 Hepal-6 Jmjdlc GGTGATTACTCATTTGGCTG 19033 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Antxrl CTTTGCAGGAGTCTCAGATG 13050 Hepal-6 Jmjdlc GAGAACGAGTACTTGGCTTA 19034 B16F10 Antxrl AAACACTGTAGGGTTATGAT 13051 Hepal-6 Jmjdlc CCGGGTCGTCGAGCGTGCAG 19035 B16F10 Abcal7 GTTGAGCTICTTCTTCAGCT 13052 Hepal-6 Tcfl5 TTGAACTCAAGGCCACTGGG 19036 o B16F10 Abcal7 AGTCTTTCAGCTAGACTCAG 13053 Hepal-6 Tcfl5 CTGCGCAATCCCGCCCACAA 19037 B16F10 Abcal7 ATTCCTTATATAGACCAGGC 13054 Hepal-6 Tcfl5 GGGAAACCGCTGAGCACCTC 19038 B16F10 Heyl CACAGAACTAGGGACAGATC 13055 Hepal-6 Cyp8bl AGCGCTGGAATTGCTTTATG 19039 B16F10 Heyl AGGTTTGGAAAGGTTACTGG 13056 Hepal-6 Cyp8bl ATACATGACACAGCAGAGTT 19040 o 4 B16F10 Heyl ACTGAAGAATTACTTCCAAG 13057 Hepal-6 Cyp8bl GGTAAATAACTCTAGTTAGC 19041 B16F10 Hipkl TCTGGTGACAACGGCGGCTG 13058 Hepal-6 Vmnlr86 TAATGTGCTTCAGGTTTGAA 19042 B16F10 Hipkl TGAATGGTTCCGGCGAGGCG 13059 Hepal-6 Vmnlr86 GGTCTAGAGTACCAAATGAA 19043 B16F10 Hipkl GGGATGGAGGCGGTCGCTCG 13060 Hepal-6 Vmnlr86 AATATACTTAGTGACAGCTC 19044 B16F10 Xylb TCTCAAATTCAAGACCAGCC 13061 Hepal-6 Bdpl CCGACGATGACGTCAGACTC 19045 B16F10 Xylb ATTATATTAGGTCGGCGCAG 13062 Hepal-6 Bdpl TTGCTATGGCTCCCGGCGCC 19046 B16F10 Xylb CACCACCACTGCTGTTACCC 13063 Hepal-6 Bdpl GGAAGCAATGCGTAATCATT 19047 B16F10 D GGCGGAGTCAGGGCGTTTCT 13064 Hepal-6 Adamtsl2 CAGCTGCCTTTATAGCTGTC 19048 B16F10 D TCAGTGGAGTAATGGAACAG 13065 Hepal-6 Adamtsl2 CACTCACTGATCCTGGACTG 19049 B16F10 Dhh GCTTCAGGGATTTCCTAAGC 13066 Hepal-6 Adamtsl2 AGCGGGTTAAAGTGTGCGCC 19050 B16F10 Dync2hl TTTGCACGAGAAGTGGAAAC 13067 Hepal-6 Azgpl GAGCAGAGAAAGCCAGTCTA 19051 B16F10 Dync2hl TCGACCCTGATACTTGATTG 13068 Hepal-6 Azgpl GATTCCACAGCCAATGAGAG 19052 B16F10 Dync2hl CACATCCAATCGATGAGTGC 13069 Hepal-6 Azgpl AAAGAGCCACACAAACAGGT 19053 B16F10 1700020L24Rik CTAGAATCTCAGCTGCCCAT 13070 Hepal-6 Coq8a GACAGGGTGACCTGAGTCAC 19054 B16F10 1700020L24Rik TAGGGCATCTGTTAGATCAC 13071 Hepal-6 Cnq8a CCCAGTTCTTGACTGTTAAC 19055 B16F10 1700020L24Rik CCTCACTGAAATCTTCCCTG 13072 Hepal-6 Coq8a TGATGGGAATGGGCGTGAAG 19056 B16F10 D1K37 GAGCCGCGCCTCAGCAGTTG 13073 Hepal-6 Fam71f2 GAGGGCCTGTCAGCTCACAA 19057 B16F10 D1K37 GAACTGGAGGCCCGACGCGC 13074 Hepal-6 Fam71f2 AGAATCTGGAAGTTTACAGC 19058 B 6F1 Dhx37 AACCCGGAAGTCTCCTAGCC 13075 Hepal-6 Fam7112 GGTCATCGCTCGGCTGCCTG 19059 B16F10 Sgol2a GGGCTGCAGCGAGCGTGAAA 13076 Hepal-6 Morc3 CTACGCATGCGCCCAACGCC 19060 B16F10 Sgol2a ACGTACTGGAGAGGGTCGAG 13077 Hepal-6 Morc3 AAAGTGTAATCCATGGCCGC 19061 B16F10 Sgol2a GGGCCATTCACCACGGATAA 13078 Hepal-6 Morc3 CGCGCCAATCTTCAATCTCA 19062 B16F10 Mrps36 CTAGCTATCTAGGAGGGAAA 13079 Hepal-6 Sbk2 TGCAAGGCGCTAACTGCAGT 19063 B16F10 Mrps36 TTCGTCATCCTAAATTATCT 13080 Hepal-6 S k2 CGTGTGTTGAATCCTAGTAC 19064 B16F10 Mrps36 CGTTGTAATTGGAAGGCCAG 13081 Hepal-6 Sbk2 GTGGCTGGACCACACCAGTG 19065 B16F10 Dynclhl CTCCGACTACAAGTCCCAAA 13082 Hepal-6 Musk CACCGGCTCTAAGTAGAATC 19066 B16F10 Dynclhl GTTACGCATGCGACTGGAGG 13083 Hepal-6 Musk CCTTCTGCCACCGTCTTAAA 19067 B16F10 Dynclhl ATGAAGACAGACGCGGTTCC 13084 Hepal-6 Musk ACTCAGGCCAGTAATGCAAG 19068 B16F10 Am CCTTGGAGGAATCTTCTCAG 13085 Hepal-6 Katnal GCGCGCGCAGGCGGAACCTG 19069 B16F10 Am CAGATGCGGACTTCGCTCCG 13086 Hepal-6 Katnal GTGGACCATTATCTCTTCCC 19070 6F1 A n GATCGCCCAGCTGTCTCCTG 13087 Hepal-6 Katnal CTAGGAAATGGGAGTAGGCG 19071 n B16F10 Slc22al2 TAGGAGCCATTTAATAGAAG 13088 Hepal-6 Wdrl2 TGCACACAAGACGAACAGAT 19072 B16F10 Slc22al2 CATTTCTTCAAAGTTTAACC 13089 Hepal-6 Wdrl2 GCGAGGTGTCTGTCCCGCAG 19073 n B16F10 Slc22al2 CATCTGCAGTGGTGTTGTCC 13090 Hepal-6 Wdrl2 CTGAGAAGGGTCTAATCTGA 19074 o B16F10 Zfp598 GAGCAGCAGTCATGAGCGAA 13091 Hepal-6 Cldn24 ATCTTGAGCCTGTGCTGCCC 19075 B16F10 Zfp598 CCTTTCCAGTCATTTAAATG 13092 Hepal-6 Cldn24 CCGTCCCTTGTGGTTGACAG 19076 B16F10 Zfp598 GGGCAGTGACGTCGACGGAA 13093 Hepal-6 Cldn24 AATGACCAAAGCTTATACCC 19077 B16F10 Defb8 CCTATCCAGGAGGCAGCACC 13094 Hepal-6 Gripl GGCAGCAGTGGTGGTGTTGG 19078 J B16F10 Defb8 TCAGTGCCTTATATAGTGCC 13095 Hepal-6 Gripl GTTTCCTCTGTGACATAGGT 19079 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Defb8 GACACTGAGTGTGCTCTCCA 13096 Hepal-6 Gripl GGAGCTTTGTGCGGCCGCGG 19080 B16F10 Anapc2 GTGTGAGCGTCGGGCACTGA 13097 Hepal-6 Fut4 GAGGTATCCAGTGCAAGGCG 19081 B16F10 Ampc2 AGGTGCGGACTTAGCTGTGC 1309S Hepal-6 Fut4 AACAACGAAGGCGCAGCAAG 19082 B16F10 Anapc2 GAACGTCACGGCTGCGCCAC 13099 Hepal-6 Fut4 GGGTITGCCAGCCTAGGCGC 19083 B16F10 Npdcl GACTTGGAATTGACTAACGG 13100 Hepal-6 Agl CGAGAGGTGGGCACGGCTTG 19084 B16F10 Npdcl TTCTTGGGTAATGAATGAGG 13101 Hep l -6 Agl ATGGCTCCCGGAAGTGGGCG 19085 B16F10 Npdcl ATTCTGCTGTAGAGGCTAGA 13102 Hepal-6 Agl TCAGTGGTCTGTGCTAGCGG 19086 B16F10 Ppp4r4 TCTGGTCCCGCTCTCGGCCG 13103 Hepal-6 Vmnlrl93 AAATTTCCTGATCTTGTTCT 19087 B16F10 Ppp4r4 CGACGAGAACACGAGCGCGG 13104 Hepal-6 Vmnlrl93 TTGTCAACATCATCATCTCC 19088 B16F10 Ppp4r4 AGAACAGGGAGCCGCCTCAG 13105 Hepal-6 Vmnlrl93 TCTGTAGAAGCAAGAATGGA 19089 B16F10 Prkg2 GCTGCCGCCTGGCTGCTCTG 13106 Hepal-6 Ms4al0 TAGCTGGGAGTGTGAGCAAG 19090 B16F10 Prkg2 GCCGCGAGAAGGAGGCGCGC 13107 Hepal-6 Ms4al0 AAACCATCTGCTTCCAAACC 19091 B16F10 Prkg2 GGGTCAGCCCGGCGTGGCGT 13108 Hepal-6 Ms4al0 ATCTTTATGGCTTTAGACTT 19092 B16F10 Eva la AGGGCAGGTCCGGAGCCGAG 13109 Hepal-6 Lepr TCTCTGGCCTTTACAGCAGC 19093 B16F10 Eva la CGTCTCGCGGCGCCCACGTG 13110 Hepal-6 Lepr ATGCTGCAGTAATAATCGCA 19094 B16F10 Eva la CTAAGTTGGAGCAGCCGTTC 13111 Hepal-6 Lepr GGAGCTTGGGCGAAGCTTTG 19095 B16F10 Zfp273 CCCTGAACCAAAGAAGTCAG 13112 Hepal-6 ffitl TTTAAAGGGCTGGGTGAGCT 19096 B16F10 Zfp273 ACTCTGCTCTCTGTGCTTCC 13113 Hepal-6 ffitl CTGAAGCCTGCAGTTTATCC 19097 B16F10 Zfp273 GGTCATGGATTGTATTTAAC 13114 Hepal-6 ffitl TTTCAGTGGAGAATGCAGTA 19098 B16F10 Mthfdll GCCCTTGCCCTGAGATTGTA 13115 Hepal-6 Pickl TCTAGACATGTCGGCGGCCC 19099 B16F10 Mthfdll TTGGAGTTGCCAGAAAGTCA 13116 Hepal-6 Pickl CACAGGCTTTCCTTAGGAAG 19100 B16F10 Mthfdll GCCAGCGGACGTGAAGCTTT 13117 Hepal-6 Pickl AGGGTTGCCTGCAGGGATTG 19101 B16F10 Zfp553 GTCGGCCCACGACCGGGACG 13118 Hepal-6 Famll7b GTCAGCGCGCTCGAGCCACT 19102 o B16F10 Zfp553 GGAGCCCGTACCCGTGCGGC 13119 Hepal-6 Famll7b GGTCGGGCGGCGGAGGAAAC 19103 B16F10 Zfp553 TGGGTTCCTGTTGTACCGAG 13120 Hepal-6 Famll7b CTATTGTTGATGAGGAGCCG 19104 B16F10 Cyp2jl3 GGGCTGTCTAATTAGAGGTA 13121 Hepal-6 Tsc22dl GTTGGGCGCCACCTCCTCCA 19105 B16F10 Cyp2jl3 TTTAGCTGAGAGCCCTGCAA 13122 Hepal-6 Tsc22dl GGTTGAGCTGGCTCCGGAGT 19106 B16F10 Cyp2jl3 CCACTCTTTCCTGTTAGCAC 13123 Hepal-6 Tsc22dl GTGAAGCGGAATATAAAGGG 19107 B16F10 Fzd7 CCCATTCACAAACCACTCCG 13124 Hepal-6 Pign TTGGCTGGAGTTACAGGACC 19108 B16F10 Fzd7 CTCTGTGGACCTGTTCCGAT 13125 Hepal-6 Pign TAGTCTCGCGAGAACTGGCT 19109 B16F10 Fzd7 TTGGATGTCCAGAGGGCTCG 13126 Hepal-6 Pign TCGCGAGAGCAGCGAAGGCC 19110 B16F10 Ttcl6 TCTGGGCTAAGCATACTCTG 13127 Hepal-6 Ubiadl AAGCAGCTGTTTAGCCCTCC 191 11 B16F10 Ttcl6 CTTAGGGATGCCTGACGTCA 13128 Hepal-6 Ubiadl GCGACACGCCCTGAAATCCC 191 12 B16F10 Ttcl6 TGGACATGTCGTGATGCTAT 13129 Hepal-6 Ubiadl TTTAGCTAATTTGTTGAACC 191 13 B16F10 Pcdhgal 1 GCGCCGCTGTTGACCAATCG 13130 Hepal-6 Plcxdl GGCTCCAGAGCCAAACTGCC 191 14 B16F10 Pcdhgal 1 CAATAATAAGATTGGGCTCT 13131 Hepal-6 Plcxdl CTCTCTTCTAACCTACCACA 191 15 B16F10 Pcdhgal 1 AATGTTAGGATCCACGGAAA 13132 Hepal-6 Plcxdl TAGTGGGACAGCGTGGACTT 191 16 B16F10 Nr3c2 CCCTACATCCAACCACATCC 13133 Hepal-6 Nvl CAGGCGGAGCTTTCGTGCTG 191 17 B16F10 Nr3c2 TCCCGGGCCCAATGACACCC 13134 Hepal-6 Nvl AGGGAGGACTACGCTGCTCA 19118 B16F10 Nr3c2 GAAGCTTGTGCAAGTCACCT 13135 Hepal-6 Nvl CTAGGGACCACGCGTGGGCG 19119 B16F10 Frasl TAAATGCGAGGATCCACTCG 13136 Hepal-6 Csf2rb GAGCTGACTGGGAGATGGTG 19120 B16F10 Frasl GACTCAGAGACTACGAGCTT 13137 Hepal-6 Csf2rb CTTCAGGTCTCAGCCTGAAA 19121 B16F10 Frasl AAAGATTCCAGAGAGTCACG 13138 Hepal-6 Csf2rb AATGTCGTGAGTATTATCAG 19122 B16F10 Prrc2h CTCGGCGCTCGCTGGAGCCT 13139 Hepal-6 Vmnlr203 AGTGCTCAGACAGGGAAGAT 19123 B16F10 Prrc2h CCCTGTCCCGGGAGGGAGGG 13140 Hepal-6 Vmnlr203 GACAAATACTGTTGCAGATT 19124 B16F10 Prrc2b CGCCGCCTCCCGCCCGCGCT 13141 Hepal-6 Vmnlr203 AACCTCTTCAATTGTAGACG 19125 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Bfar AGATCTATTACGATGCATTC 13142 Hepal-6 Ifit2 TGTAGTCGAGCCAGGTTGCC 19126 B16F10 Bfar TGTGCTTGGCTCGGACGAAA 13143 Hepal-6 Ifit2 GGGAGGAAGCAGCGCTAAGA 19127 B16F10 Bfar GAATAAAGCTAGCTAAATAC 13144 Hepal-6 Ifit2 GCGACAATAGCAGGACACAG 19128 B16F10 Lrrc30 GACGAGGTCGGAAACCTACA 13145 Hepal-6 W c2 GAGCGACGAGGCCAGGTGGG 19129 B16F10 Lrrc30 GGGAAGTGAGCAGTTCTGTT 13146 Hepal-6 Wwe2 ATGCAGATGAGGCGGGCGCG 19130 B16F10 Lrrc30 AGCTGTCTTGTGCTGCACGG 13147 Hepal-6 W 2 AGCTCAGGAATGTGGCGGCG 1913 1 B16F10 D7Ertd443e ACTTGTGCTAAGAACTTTCC 13148 Hepal-6 Faml63a GCAATCCTCCTTGCGGGTTG 19132 B16F10 D7Ertd443e GTCAGTTGGATCAGGGTGGA 13149 Hepal-6 Faml63a CTCGGCCACCTGGAGGAGCC 19133 B16F10 D7Ertd443e ACTGCITGTCTCCACTAATT 13150 Hepal-6 Faml63a CAGCCTCACGTGGGCCGGCA 19134 B16F10 Ttn TTGGGCTGTCAGCAGATCTG 13151 Hepal-6 4931408C20Rik GGAAGTGGGTGTGGCTCCTG 19135 B16F10 Ttn GCTCTGITAGGAAGGCATGA 13152 Hepal-6 4931408C20Rik AGGAGGGAGTATGGAAAGCC 19136 B16F10 Ttn TTACAGCCCGGCTCTGTGAT 13153 Hepal-6 4931408C20Rik TATAGCCCTTTGTGATGAGG 19137 B16F10 Krt76 GAAGTAACTTGTTGCCTGTG 13154 Hepal-6 Hr CCAGGTGATGATGAAGAATG 19138 B16F10 Krt76 CAATTACCTGAGAGTCATCT 13155 Hepal-6 Hr TAAGCCACTCTTCATAGTGT 19139 B16F10 Krt76 ACACCTCAAAGATAATCCTC 13156 Hepal-6 Hr AACAGACCAGATATCAGGTC 19140 B16F10 Vpsl3d AATTCTAGACTAGGCAGGTC 13157 Hepal-6 Slc47al CTGGCGCTGGGCGGGTTTAG 19141 B16F10 Vpsl3d GGTGTGGCACGCCATAATGC 13158 Hepal-6 Slc47al GCTAGCCAGCACCCTAATGT 19142 B16F10 Vp d AAAGTTAACAGAGCACAGCT 13159 Hepal-6 Slc47al AGTCCAAGGTTGCAGATCCT 19143 B16F10 Stl8 TGATATATGGGCGGTTTGGA 13160 Hepal-6 Hnmpal CGCCCTTACTTGAGTCTTAT 19144 B16F10 Stl8 CAGTGGTCCAGTGATGGCTA 13161 Hepal-6 Hnmpal GTCTGAATAGAACGCCCAAA 19145 B16F10 StlS CACTGAGTGGCACAGCCTTC 13162 Hepal-6 Hnmpal ATTAAGGATAAGATCCCTTG 19146 B16F10 Serpinb6c GGGCGCTGGCCTATTGTGTT 13163 Hepal-6 Htr7 GCAGGGTGGCGAGCCGAGCC 19147 B16F10 Serpinb6c CCGCAGCTGGATTGGCAACC 13164 Hepal-6 Htr7 GCGTCACCCGCAGCGTCTGG 19148 B16F10 Serptnbbc GCTGCTGCATTGTTAGGCTC 13165 Hepal-6 H r7 GGGTCCGGCGCTGGCCACTG 19149 B16F10 Pcdh20 CAAGATCAGTCTCAACTTCT 13166 Hepal-6 Zfp426 GGAGAAACTAGAAATCTGAC 19150 B16F10 Pcdb20 AAGCAAAGCTATGAAATCGG 13167 Hepal-6 Zfp426 TTCAACCGAGGTAGACTCCC 19151 B16F10 Pcdli20 ATTGACAAGGAGGAATTTGT 13168 Hepal-6 Zfp426 GGGCTGTAAGGGCTTCACCG 19152 B16F10 Heatr5a ATAGTTGTGGCCGGAATCTC 13169 Hepal-6 Me k GGATGTCAAATGCTCAGGAT 19153 B16F10 Heatr5a CTCCACCGCCGAGAGAGCGA 13170 Hepal-6 Melk AAACTGGGCGGAGCGATGGT 19154 B16F10 Heatr5a CTGAGGCAGAAGTCACTTCT 13171 Hepal-6 Melk TGATGGGATACTAAATGTGT 19155 B16F10 Rnfl46 TCTAGCITCCTATGCTGTTA 13172 Hepal-6 4 CTGTTTGTCTACCCTGTGTG 19156 B16F10 R fl46 ACCATTAAGTGGCTAAGGCA 13173 Hepal-6 Tr 4 AGTGATAAGGAAATTTACTC 19157 B16F10 Rnfl46 GAAATTTATTCTAGATTCGC 13174 Hepal-6 Try4 TGTGCTTGTGAAGAAGTAGA 19158 B16F10 Chdll CGTGCTAAGGAAGCGTGGGA 13175 Hepal-6 Acacb AGCAACGTGCCCTGGGCCAC 19159 B16F10 Chdll GCGTTGTACTCCGCACGCGC 13176 Hepal-6 Acacb TTGTACTTCGTCCAGTACAA 19160 B16F10 Chdll CTAAGTGTGCGTCTGCGACT 13177 Hepal-6 Acacb AACAGACTTCTCTCCTAACA 19161 B16F10 Klrgl AGGATGGGTTGTTCCCTCAT 13178 MC38 Cyp2c70 GTCCAAACTCTGTGTACTTT 19162 B16F10 Klrgl GGGAATGTGGGCTGTAAGTG 13179 MC38 p2c70 AAATTGCATTTATAGTCCCT 19163 B16F10 Klrgl CTGACAATTTGCTTCTGTTT 13180 MC38 Dkcl AGCGCCTTGGAACCTTGGCC 19164 B16F10 Ssxb8 ATCAAGGATAGATGATCTTG 13181 MC38 Dkcl CTATTTATAGCGCGCTAAGA 19165 B16F10 Ssxb8 TGCAGATAGACAGTAAGAGT 13182 MC38 Dkcl GCTGAAGCTAGACTGGAGGA 19166 B16F10 Ssxb8 ACCAAATGTCCTGTGAAGGA 13183 MC38 Gsn GAAGCGAAGCGGTTGTGCAC 19167 B16F10 Rblccl CTCAGGTGTCTGCGCAGATC 13184 MC38 Gsn ATGCCAGGCCATGAGCTCCT 19168 B16F10 Rblccl CTTTCCGCCGCAGAGCACGC 13185 MC38 Gsn CACCCAGAGCATGTTAGATG 19169 B16F10 Rblccl ATACCITCCAGGGTCAGGGA 13186 MC38 Acot7 GCCCAGTGCAACTCGCGAAA 19170 B16F10 Cacna2dl AGGCGGCTGTGGGTGGGCAG 13187 MC38 Acot7 ATGCCTACCTGGAGGGAGTG 19171 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Cacna2dl CGGGCGCAGCCCTCCGTACA 13188 MC38 Acot7 GGTCGGTCGGCCCTGCAGAG 19172 B16F10 Cacna2dl GGAGGGCCGGGCGTCAGAGC 13189 MC38 Gabrb2 CCTGGCACTCTTTGATGAAG 19173 B16F10 Slc25al CTTGGCITAGCGTTGCTGTC 13190 MC38 Gabrb2 ACTCTAGGGCATCCCAGTCC 19174 o B16F10 Slc25al GGCTTGGGCGGGATGCACTG 13191 MC38 Gabrb2 GAAGAGGATGCCGAGAGCAC 19175 to B16F10 Slc25al CCCGCCGGAGGCGTGGTCTC 13192 MC38 Prrt4 GGCGCTGGCAGCCACAGGCT 19176 B16F10 F l MC38 TGTAGTATCCTTCGCCAATC 13193 Prrt4 CATTCCCGAGAAACACCCTC 19177 to B16F10 Fryl CCTCGCCTCCAACGTTGCTT 13194 MC38 Pnt4 GCACACATGCAACAGTAGTC 19178 4 B16F10 Fryl TAGAGGTAGGTCCAACCCGG 13195 MC38 Bestl GGCAGAGGGCAGTAAGCAGT 19179 6 1 B16F10 Sctr ACGTGCCTTCAGCAGTGACA 13196 MC38 Bestl CAGAGGGCCTGACCTTTGCC 19180 W B16F10 Sctr GACCCTAGACACCCGCATAG 13197 MC38 Bestl TGCCATGGCGATCTTAGATG 19181 B16F10 Sctr CCTCCAGAGAAAGTACTTTC 13198 MC38 Tacol GAACGAGTACCGCGAGGCAG 19182 B16F10 Bora GCCATTGGCTGGTTCGCGGA 13199 MC38 Tacol ACTGCCTTGAGTGACCGCGA 19183 B16F10 Bora CTCGCTCTACGTTCCGCGCA 13200 MC38 Tacol GAAGTGTACTGCACCATTTA 19184 B16F10 Ankrd44 GGCTGGCTCCTGGCGGAGCG 13201 MC38 CcpllO TACGCAATCGAGATGCACGC 19185 B16F10 Ankrd44 GCAGGAGGCAGCGTCGGCCC 13202 MC38 CcpllO CAGGCGGCAACGCGGGATCC 19186 B16F10 Ankrd44 AGTGGCGGCCCGGCTGGCAG 13203 MC38 CcpllO CTCAGGGCCGGTACTTCCGG 19187 B16F10 Gykll GAATGACCCAGGTTAACTTT 13204 MC38 Hmgcs2 GTTGGGCTTTATAAGACTCC 19188 B16F10 Gykll GTCTGCTTTATATCCAAGGT 13205 MC38 Hmgcs2 GGCCTCGATAAGCGGAGGCG 19189 B16F10 Gykll GGCACGAGACCATAGGTGAT 13206 MC38 Hmgcs2 GTACATAGCTGCACTGTTCC 19190 B16F10 Lamal CGCCGTGCGGAGTCCTTCCT 13207 MC38 Slc30al0 ACAGATCTGTAGTAGCCCAG 19191 B16F10 Lamal GGAGGTCCTGGGTAGGACAG 13208 MC38 Slc30al0 ACCAGCCTGTGTCTCCTTCT 19192 B16F10 Lamal GGCCTGGTGCGCAGGCCCTT 13209 MC38 Slc30al0 GGGCTGGAGACCGGAGCTGC 19193 B16F10 Svs5 GGCCTTGCCTGCAGGTTTGA 13210 MC38 Dnaafi GTCGTTATGACAACCGCGTC 19194 to B16F10 Rlpk3 GTGCCTGGGCGCTTCTCGGG 13211 MC38 Dnaafi ACTGACCAATTAACGTGAAA 19195 B16F10 Ripk3 TCAATCGTTCCTGGATGGTG 13212 MC38 Dnaafi CCAATAGAAGCTCCGGGAGA 19196 B16F10 Ripk3 CAGTTTCAAGGCACGTGCAC 13213 MC38 Rnftl GGACTCGGGACAGGGCCTAA 19197 B16F10 Dlg3 TGAGGAGGTGAACTGTACGA 13214 MC38 Rnftl CACTGGGCGAGGGCGTGGCC 19198 B16F10 Dlg3 CGCACCAATGGTTGTCCAGC 13215 MC38 Rnftl CCGCCTTCACTGGGAGGAGG 19199 B16F10 Dlg3 GAGATGTGTCTGAGTCCGGG 13216 MC38 Mical3 CAGGTTGTCATCTGGTGACC 19200 B16F10 Lrpl GACAGGGAGAGGAGGGAAGG 13217 MC38 Mical3 TTGAGGCTCAACCGATGCCC 19201 B16F10 Lrpl ATCAGCGCATGCGCACTGTC 13218 MC38 Mical3 GTGCCGTAGCAGAGCTGTCT 19202 B16F10 Lrpl CTGATTTGGCGCGCTGCCCT 13219 MC38 Tchh TGAATACTATATTCAGGAAG 19203 B16F10 Serna5b TGGAGCTAGTTGGAGCGCGG 13220 MC38 Tchli CAAATCTCTGCTTCTGACTT 19204 B16F10 Serna5b GTTGGAAGCCAGAGGAGAGA 13221 MC38 Tcbli CACTGAITTAAACAGATCTr 19205 B16F10 Sem b TGGAGAGGACCTGCGACTGC 13222 MC38 Fbxw7 TTTAACTTACTGCTGTCAAG 19206 B16F10 Mtf2 GCTCACTATTGTGTCTGCAC 13223 MC38 Fbxw7 CCGTCCTGGGCCACTTGTCC 19207 B16F10 Mtf2 GAATTAAGTCCTCTTGCTGC 13224 MC38 Fbx 7 TTTCTGATCGTGACTGTCCC 19208 B16F10 Mtf2 GTAAGGCAAGCATCAGCGTC 13225 MC38 Cltd5 GTTAACAGCCGAGAACAAGT 19209 B16F10 Ill 8rl GGTTTCAGGTGGGCACCGCC 13226 MC38 Chd5 GCTGGCGTAACGATGGGATG 19210 B16F10 Ill 8rl GCGCCACACCCTTCAGGCAG 13227 MC38 Chd5 CCGGATTGTGACGTCCAGTC 19211 v B16F10 Ill 8rl CTATGTTGGCTCTGCGAGCC 13228 MC38 Nkap CTCTCATCCAGTTCCTAGTG 19212 to o B16F10 Tm9sf3 AGGACTTCCGGCGTGTGCCG 13229 MC38 Nkap AATTGGCGGTGTTGCTTATA 19213 o 90 B16F10 Tm9sf3 TCTGACTCAGCCACGTCATC 13230 MC38 Nkap TTCTGAAACCTAAACCGCAC 19214 B16F10 Tm9sf3 GCAGCACAGCAGCGGCGACT 1323 1 MC38 Serpinb7 ACAGGGAGTGTCTGAGTCAG 19215 to B16F10 Pexl TGGTGATCGAATACGCCACC 13232 MC38 Serpinb7 ACTATTGTGGTCATCACAAT 19216 90 6/1 B16F10 Pexl GCGTCGGCCCTCCCGGTATT 13233 MC Setpinb7 TGAGCATAATTTCACTTGAA 19217 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Pexl ACTCTACCTTGACCGCGCGA 13234 MC38 Rhou CGGATAGAAGAAGGAGCCGC 19218 B16F10 Abca8b CTGGCCATGTGGCTGTATAA 13235 MC38 Rhou GAGCAGGCTCGGCCACATCG 19219 B16F10 Abca8b TAACTGGCACCGCCCTGCGG 13236 MC38 Rhou CAGCTGCCACCGGCGGACAA 19220 o B16F10 Abca8b TAAATGTTGCTCTCCAGCTT 13237 MC38 Mxdl CCCGTCCCTTGACAGGCCCG 19221 B16F10 Popl GCCTAGGGCTGTCTGGTCAG 13238 MC38 Mxdl GTGCCTCATTGGGCCGCCCG 19222 B16F10 Popl GCTTCTTCCTCCACGTGTCC 13239 MC38 Mxdl CAAGCCCGGCCAACCGGCGG 19223 B16F10 Popl GCGAATTCGCACGGCCCGAT 13240 MC38 Adh5 GCGTTTCGGAGCCTGAGTTT 19224 o 4 B16F10 Kcnjl5 GAGGGTAGGGCTGAGCTTGC 13241 MC38 Ad 5 AGGGCCCAGCACATTGTGAG 19225 B16F10 Kcnj 1 AATCTGAATCCACAGCTCCC 13242 MC38 Adh5 CTGGGAGGCGGGCCTAATAC 19226 B16F10 Kcnj 15 CTACCCAGGGAGAAAGACAC 13243 MC38 Stab2 GGAAATCCTGTCACTCAGCC 19227 B16F10 Cyp4al4 TAGACACACCTACTTGTGGG 13244 MC38 Stab2 TTTCCTTTCCCTGGTTAGGA 19228 B16F10 Cyp4al4 TTAATCTGCAACATCAGCTT 13245 MC38 Stab2 TCTGAGCTGTATATAAGTCC 19229 B16F10 Cyp4al4 AAATCTCTAGTATCTAGTCT 13246 MC38 Setd6 GCGCGATTCCTAAACCGGAG 19230 B16F10 Itgb6 TGCCAGCGCATTCGCTCCTC 13247 MC38 Setd6 ACCGGCCTCCACCCTAGTTC 19231 B16F10 Itgb6 TAAAGAGGCTCATTTGCTCT 13248 MC38 Setd6 ATGCCGTAGTGACCGACTGA 19232 B16F10 Itgb6 GCATGTGGGTGTACACCGCT 13249 MC38 AW551984 GGACATTGCCTTCCCTTCCC 19233 B16F10 Kifc2 GTACTTAAGGCCCTATCAAG 13250 MC38 AW551984 ATAAATATCAGGAAGTCTTG 19234 B16F10 Kifc2 CCGTGGAAGATCGTCCGTGG 13251 MC38 AW551984 AGCTAACCATGGAGGAGACT 19235 B16F10 Ktfc2 GGGTGCAGAGACCTGGTGCG 13252 MC38 BC005624 CAAGGGCAGGTATTGCCGCG 19236 B16F10 Itg GGTACCGCGCTGAACCACCG 13253 MC38 BC005624 TTGCCTGCCCTGCTGAGGCG 19237 B16F10 Itgbl GACCGGACACAGACTGCGGC 13254 MC38 BC005624 AACCATGCTCACCGCTCAAC 19238 B16F10 Itgbl GGGCTTTCCAGCCGGGCGGC 13255 MC38 Cbfa2t3 GACGGAGGGTGGGAGTCTGC 19239 B16F10 Acnatl CCAAGGCAAGGCTGTCCTCA 13256 MC38 Cbfa2t3 GAGCCGCTCTGGGCATTGGG 19240 B16F10 Acnatl ATCTTCAAGATCCTGGTTGG 13257 MC38 Cbfa2t3 CGCGATGGGCGTCGGGCTGG 19241 B16F10 Acnatl CGCTTCCTCCCTGTGATGAA 13258 MC38 Ppmlj GTTTGTTAAGGACCAGGAGT 19242 B 6F1 Mapkapk5 GCTGGGTGAATGACGTAAGA 13259 MC38 Ppmlj CCGCCCACCTGGAACCCTAG 19243 B16F10 Mapkapk5 CTGGCCTGCCGAAAGAGAAG 13260 MC38 Ppmlj GGTCTATTGTGGGAAAGAAG 19244 B16F10 Mapkapk5 CACGTCAGTGGAAGGCCCGG 13261 MC38 Fam217a TGAGITGCCATGTGGGCCAG 19245 B16F10 Mter GGCGATTCGCCACGCTAGGC 13262 MC38 Fam217a TTACCTAAGAGCCGTAAGCA 19246 B16F10 Mterfl AGTGACTGATCCTGGGAACG 13263 MC38 Fam217a TGGGATCAATTTAGTTAATG 19247 B16F10 Mterf3 ATGGGCGAGACCATCTGCGG 13264 MC38 Adamts8 CTTCCCGGCTTTGACATAAG 19248 B16F10 Kcnh5 TGTAGAAAGCTCCCGTGTGG 13265 MC38 Adamts8 CTTCCTCGGGAAACACCGAG 19249 B16F10 Kcnh5 TGCGCCGAGTAGGAAGTGAC 13266 MC38 Adamts8 AAGTATAAATACGAAGGGCT 19250 B16F10 Kcnh5 GGCTTCTGCTCCAAATAGTG 13267 MC38 Klhl30 GGCAGACCACGTGGGAACTT 19251 B16F10 Pnisr CTTCGCTCAGCTACTCTTTA 13268 MC38 K 30 GGAGGTCTCTGGGTTACAGT 19252 B16F10 Pnisr TCCTTACCTAAACTCCAAGA 13269 MC38 Klhl30 TTAGCTTCTGTATGGGTGAA 19253 B16F10 Pnisr GAGTAAATGTTCCCACCAGG 13270 MC38 Cd244 GCCACTAAGAATTCAGCACC 19254 6F1 Gr 3 ACCCAGTGGTCTTCAGCAGA 13271 MC38 Cd244 ACAAGCTAAGATGCCTCCAG 19255 n B16F10 Grm3 TCCTCCTTGACTCGGAGGCC 13272 MC38 Cd244 ACTTCTGCTGTGCACTGACA 19256 B16F10 Gr 3 TGCCCGGTGGCCCAGCATCC 13273 MC38 Zkscan4 AGTAAGTTATCCGGGACCCT 19257 n B16F10 Mkx GGGATGTTCGTAGGCTGGGC 13274 MC38 Zkscan4 AGGAGTATATGTTTAAGCAG 19258 o B16F10 Mkx GAACATGGATACCGCGTCCG 13275 MC38 Zkscan4 CCAAATTAACCCATTATTGT 19259 B16F10 Mkx CGGGAAACATGAGAAGGCTT 13276 MC38 Apip GGCGTGCCCGTGAAGGTTGG 19260 B16F10 Sec23a ATGAACCGGGAGTAATAAAG 13277 MC38 Apip AGGACTAGTCCTCCAGTCCA 19261 b B16F10 Sec23a TGAAAGACGGCCAAGCAAAG 13278 MC38 Col28al GTTGGCAAGCTTCCCTGTAA 19262 J B16F10 Sec23a GAGGTAATGGGCGCGTTGAG 13279 MC38 Col28al AGAAACTTGTTGAAGTAGAT 19263 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Fanca GGCGCAGGTGTATTGCACCA 13280 MC38 Co128a 1 TGGAGCACTCAGTTCCAAAT 19264 B16F10 Fanca TCCCGGAGTCTGGCTGCGTT 13281 MC38 Katnall TTGTAGTTCGGTGGCTCATC 19265 B16F10 Fanca GGGTGGCAGAGAAGGCAGTA 13282 MC38 Katmll CACCAGTCGCAGGGTATCAT 19266 B16F10 Zbtb39 GCCTCCTCCGGGACGGCGGG 13283 MC38 Katnall CGGCCCGAATCACCCAGCCA 19267 B16F10 Zbtb39 GGCTCCGCCCGGCCGTCGGG 13284 MC38 Tmem205 GGCGTAGGGACCAAGAACCG 19268 B16F10 Zbtb39 AGCGGGCTGGTGTGGGCTCG 13285 MC38 Tmem205 CCACTTAGGGATTGCCCAGT 19269 B16F10 Gamt CAAGGCTAATCTCTGTGCAG 13286 MC38 Tmem205 CCGTTGGAGCACACGAGCTC 19270 B16F10 Gamt GTGGGTCCAGTCATTAGAAG 13287 MC38 Exoc4 TGACCCGGAACATCCACCAA 19271 B16F10 Gamt CGGAGTTCTTTAGGGCGCAT 13288 MC38 Exoc4 CGGGACTGAGACTCAGCTGG 19272 B16F10 Gja3 GGGATGCAGACTTGTTCCTC 13289 MC38 Exoc4 AGAAGAGAAGCGCTTAGGCG 19273 B16F10 Gja3 TTATAGCTTGTTGCCCGCGG 13290 MC38 Proserl GGCGCGACACGCTCTATCAA 19274 B16F10 Gja3 AGCGCGCGTGGTGCGCACTG 13291 MC38 Proserl TTACGGGCTTTCGTAGCTTC 19275 B16F10 Vwa5bl AGGGTCACACATTCATATGC 13292 MC38 Proserl CGCACTAGGAGCCGGACGAA 19276 B16F10 Vwa5bl AGAITTCCTCCAGGTGCTTG 13293 MC38 Apc2 AATAGTGTCAACCAGTCACC 19277 B16F10 Vwa5bl CCAAATCCTTCCATCAAAGT 13294 MC38 Apc2 GAAACAGGAGGAATTGAACC 19278 B16F10 Dip2a CATTGGCCAATAAGACACGC 13295 MC38 Apc2 TACACATCAAATAGCCTCCC 19279 B16F10 Dip2a AGTAAAGCTCCGGGCTGCTC 13296 MC38 Rsadl TGTGTGCAACAGTGTCCACC 19280 B16F10 Dip2a CAACGCTTGCGCGGGTACGC 13297 MC38 Rsadl TGACCTCGTATTGCCTCTCC 19281 B16F10 Zfp768 TGAGGGCCACGAGACAATCG 13298 MC38 Rsadl CTGTGTCCTTGAGAACGAAT 19282 B16F10 Zfp768 CCCGCGCGTCGTGGCCTCGG 13299 MC38 Zfyve26 TCACGTGATTCAAACAAACA 19283 B16F10 Zfp768 GTCTTGACCCTGGGCCTCTC 13300 MC38 Zfyve26 AAAGAGAGCGCCACTCTTAT 19284 B16F10 Mgam TATTATGAACACGTGAGTAT 13301 MC38 Zfyve26 ACAAGTCCCATTGCGAAGAG 19285 B16F10 Mgam CACGACACCTTGCAGCTTTC 13302 MC38 Pigs CTACACTTTCAATCTGACCC 19286 B16F10 Mgam TGCACGCAGAAATCAAGGAA 13303 MC38 Pigs CCCGTGAGAGGGTACGCGCT 19287 B16F10 Slc22a30 ACAATTCCCATGGTCAAATA 13304 MC38 Pigs GCTGACGCACGCCAGTGCGC 19288 B16F10 Ceslb GTTAGAAGTGTTTGCATAAG 13305 MC38 Lmxlb GGGACCTGTTGCTATATCCA 19289 B16F10 Ceslb CCCTCTCCAAAGAGCTCCCA 13306 MC38 Lmxlb GCGCAGTCCGTCTGCCCGCG 19290 B16F10 Ceslb TTGGCTTGATATCAGAGAGT 13307 MC38 Lmxlb GAAGCACCTCTCCAGCGACT 19291 B16F10 Tekt5 GCCAGGGCATCCCAAGAGCT 13308 MC38 Abliml GGAITGAAAGCAGCTGTCAT 19292 B16F10 Tekt5 GTGCCAGGTCCTGGTTCTCC 13309 MC38 Abliml GCCTGAAAGAGGCTGTAATC 19293 B16F10 Tekt5 GGGCCTCTGTGACTTAGTGC 13310 MC38 Abliml GAACATGGACTGGCCCGTCG 19294 B16F10 Died CAGTGGTGACGCTCTTCTAA 13311 MC38 Matn2 ATGCACCAGGAGTCTGAGGG 19295 B16F10 Died TTCGCCTATGTCCAGCCCTC 13312 MC38 Matn2 CGAGGAGGCGGTGCCGTACA 19296 B16F10 Died TGCATTCCTAACGTCCAGCT 13313 MC38 Matn2 GCAGGCAAGGAGAGCGTCTT 19297 B16F10 Pkdl ACCCAGCGGTGCAGAAGGCG 13314 MC38 S13b2 CGGGACGTGGATTACGCAAC 19298 B16F10 Pkdl CTGCAGACCAGGCTTGAAGG 1 1 MC38 Sf3b2 GTATTACTACTGCTGCATAC 19299 B16F10 Pkdl TTGCAGATCCTGCAGTAGGC 13316 MC38 S13b2 TTTGCGGATGCGCCATCTAG 19300 B16F10 Trim42 GTGGTAGCTGGGATACATAC 13317 MC38 Son ATGGCGGCCGAGTTCGTGCG 19301 B16F10 Trim42 AGGAAGTTGGCCAGTTTATG 13 1 MC38 Son GTTGACGCAGGCGCCATTAC 19302 B16F10 Trim42 GCTCAGTAGTAGGTAAGAGG 13319 MC38 Son GCGGGCCGGTGTTCGCTGAT 19303 B16F10 Fatl ACTCATAGTCAGTGTGGGTG 13320 MC38 Zfp663 GGGACGAACTTGATCTTCTT 19304 B16F10 Fatl TTCTTCTATTACAGGTGGCC 13321 MC38 Zfp663 TGCAGCGGCTGAGTCGTATT 19305 B16F10 Fatl AAAGAGTGTCACTTGCTGGA 13322 MC38 Zfp663 TTCTCTTCCACGACCTCTGC 19306 B16F10 St6galnac3 GTGGAGTAGCAAGCAGTTGC 13323 MC38 B l b9 ACTACAGTGGGTCCAGGAGG 19307 B16F10 St6galnac3 TTTCCAAACCCTTCTGCAGA 13324 MC38 B l b9 CCCACTCCTCTTGGAGAGGT 19308 B16F10 St6galnac3 CACGGAGGGCACGTGACTAG 13325 MC38 B lh TGCCACAACAGTGTGTGAGA 19309 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Zkscan4 AGTAAGTTATCCGGGACCCT 13326 MC38 Cyp26cl GGTGAGCTAGGCCACTGGGA 19310 B16F10 Zkscan4 AGGAGTATATGTTTAAGCAG 13327 MC38 Cyp26cl GCGAGAATGCAGGGTTGAGA 19311 B16F10 Zkscan4 CCAAATTAACCCATTATTGT 1332S MC38 Cyp26cl TCACCTGCACAGTCCAGAAA 19312 o B16F10 Mpo TGACTTTGAGGCCCTCAAGG 13329 MC38 Pigt AGGITACCGGAGGGACACGG 19313 B16F10 Mpo TGAAGACAGTTAGGCTTCTC 13330 MC38 Pigt ACCAAAGGCGGTCATCCAAT 19314 B16F10 Mpo CCTCACTAAGGTTGGAGTGG 13331 MC38 Pigt TTGAGGGCCCGCGCACCTAT 19315 B16F10 E mp GTTTCCGTCCGCTCACTAGG 13332 MC38 Fbxo40 AGCTGAAGACACTAGGTGAG 19316 o 4 B16F10 Ermpl CTGCTCAITTCTAGGTTTAT 13333 MC38 Fbxo40 TAGGGATGCTCAGGTCAAGC 19317 B16F10 Ermpl CTAAGCAAGAGAGAAGTGCA 13334 MC38 Fbxo40 TTCTGCCTTTAGATGAAATG 19318 B16F10 Pcdha2 TGGTAGACAGCGACACCCTG 13335 MC38 Rpsl8 GGGACCGGAGCTATAACTTC 19319 B16F10 Pcdha2 CCAAGAGAGAGATCACTCTC 13336 MC38 Rpsl8 AATACAACTCCTCCCTTAGG 19320 B16F10 Pcdha2 ATTCTAACCAGTTTAGCCAC 13337 MC38 Rpsl8 AGTCTTATATAGATTCCTGG 19321 B16F10 AI464131 CCACATTGGACGGCTGGGAG 13338 MC38 Phf21b GGGCGCCCGAGCGATCTCCT 19322 B16F10 AI46413 1 GTGCAAGGCACGCAGAGTGG 13339 MC38 Phf21b TTGCGTTCGGCCCAGCGACC 19323 B16F10 AI464131 GGGCCCAAAGGGCAGATCTG 13340 MC38 P lb CTGAGCGGAGCGCAAAGTCG 19324 B16F10 Wdr64 TGACCTCATAATGTTAACAT 13341 MC38 Nme5 ACCCAAAGCTGGTTTCCTAA 19325 B16F10 Wdr64 TACACACACCCTGCAGGAGG 13342 MC38 Nme5 TTTCCTAACGGTGGCTGCAG 19326 B16F10 Wdr64 CTGTAAGTCCCACAGCAGAT 13343 MC38 Col6a4 GCATTAAATGCTGGGAAAGC 19327 B16F10 Clip GCTGGAGATGTAGGGATGGG 13344 MC38 Col6a4 GGCTCTGAGGGATGAGGACA 19328 B16F10 Cilp GGGAGTCTCATGCTCAGATC 13345 MC38 Col6a4 GGGCTGTTTATGCTGTGATG 19329 B16F10 Cilp CATCAAGATCCTTAGGGATG 13346 MC38 Mtol CCCGCAGGTACTTTCAGCGC 19330 B16F10 Zmym4 GGAGCTGCGGCTAAGCGCGC 13347 MC38 Mtol GGCGGGAGATTCTATCTTGG 1933 1 B16F10 Zmym4 GGGTCCCACGGGCGGGCGCG 13348 MC38 Mtol GTGGACTTGTCTTTATCGCC 19332 B16F10 Zmym4 CACCGGCGCTTCACCCGCTG 13349 MC38 Isynal TCGCAAGTCACGCCCATCAG 19333 B16F10 Cy a AAATTTGGGCAGTGTGCAAG 13350 MC38 Isynal TGGTACAAGGGTGCGCAGCG 19334 B16F10 Cy a59 TTGGCACTTTGACAAATGCC 13351 MC38 Isynal GTTTAGAGCACCCAGAACCC 19335 B16F10 Cy a 9 ACAGGGATACAGCCAGTACA 13352 MC38 Col4a4 CTTCGGTGCCTAGCGGGTGC 19336 B16F10 Evx2 TGGCTGTCCCGTCTTAATGA 13353 MC38 Col4a4 GCAGCCCTGCCCAGATTAAG 19337 B16F10 Evx2 GCTGAATGAGAATCAGCCCT 13354 MC38 Col4a4 GGTCAACGTGAGGAATTTAG 19338 B16F10 Evx2 AATTGTGGGATGCCAGAGCG 13355 MC38 Foxpl AAGCGTAAGGCTCACAAGCA 19339 B16F10 Adam5 CGCAGGGCTGCAGAATTAGA 13356 MC38 Foxpl CGGGCGGAGCCCATTGTGTG 19340 B16F10 Adam5 CCCTGCGTTTCTCCTTGTAT 13357 MC38 Foxpl CTGTAGCCACACCGTCAGAA 19341 B16F10 Cnksr2 AAGGAAGAGGCGCCGGCGCA 13358 MC38 Fos AAAGATGTATGCCAAGACGG 19342 B16F10 Cnksr2 CCGGGCGGCTCGTCGTGCCG 13359 MC38 Fos GGATGGACTTCCTACGTCAC 19343 B16F10 Cnksr2 GTGCATGGCTCGAGCCGCCG 13360 MC38 Fos CTTTATAGAAGCGCTGTGAA 19344 B16F10 Rintl CATGACATCCAACCAGCAGG 13361 MC38 Usp54 AATGAATTGTTCCTGGTAGT 19345 B16F10 Rintl TCCGTTCTCTTGGCCTAGAG 13362 MC38 Usp54 AACTGTTCATCTAACCACAA 19346 6F1 Rintl TCGGTGATAGGAAGTCGAGG 13363 MC38 Usp54 GAAGGAACTAACCAGAACTC 19347 n B16F10 Ai AGGTGTGTTTGACAATGAAT 13364 MC38 Thap4 TACGGCGGTGGGCACGCGGG 19348 B16F10 Aiml AAAGCTACTGCGAACCACCT 13365 MC38 T ap4 GTGTGGTTCCTAACCGGACG 19349 n B16F10 Aiml TAGTCGCGTGCTGCCACACC 13366 MC38 Thap4 GCAGTAGTCCGTCGGAGCGA 19350 o B16F10 Ap5bl AGGAGCCGACCGAGCGCCCG 13367 MC38 Lomf2 AGCAATAATGAGTTGTCATC 19351 B16F10 Ap5bl CGAGTCGGCACCTGCCGGCC 13368 MC38 Lomf2 GAACTCTACATATGAGCACC 19352 B16F10 Ap5bl TTACTCAGACCTGGCGAAAC 13369 MC38 Lonrf2 AAATCTGAAGCAACTCCTCC 19353 b B16F10 Macfl AGAGAGTATACTATCCTTGT 13370 MC38 Kel AAGITACAGAGCCAAACACA 19354 J B16F10 Macfl CATGCCAAGACTAATTTATG 13371 MC38 Kel GTGGAGCCTGCTTATCAGTG 19355 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Macfl CTCATATATGAGAGACAGAG 13372 MC38 Kel CTGCGTCTGCTCCTTGTGTT 19356 B16F10 Slcl0a2 GTGTTGAAAGCATACTCAGC 13373 MC38 Ptpn4 ACTTCGGCCCGCAGCTTGCG 19357 B16F10 Slcl0a2 GCTAGTATGTCAGTTTCGAG 13374 MC38 Ptpn4 AGGCGCGCGCTCGCACCTCG 19358 o B16F10 Slcl0a2 TTAAACCCTTTCTCAACATG 13375 MC38 Ptpn4 GTGCAGGCGGCCCGCGGCCG 19359 B16F10 Plod2 CTACGTGCACCGCCTCACGC 13376 MC38 Txndc2 GGGCITCATTCCTTGGATGT 19360 B16F10 Plod2 GTAGGCGACTCGGAGGGTGG 13377 MC38 Txndc2 GAGGCTGTGGATGTATAAGC 19361 B16F10 Plod2 CGAGGAAGCTTCTGGAACCC 13378 MC38 Txndc2 CTCTCAAAGTCCACTGTTGG 19362 o 4 B16F10 Dgkg GCGCGCGCGGGTGTGTGGCG 13379 MC38 Hlfx CGGCCGGGCCTGGGACCAGG 19363 B16F10 Dgkg GGGAACCTCTGTACATGATC 13380 MC38 Hlfx AGCGCGCACGCCCAGAGCTC 19364 B16F10 Dgkg GCAGGGCTCCGCAGCGAGAG 13381 MC38 Hlfx GGGAGCGCGGCAGCACTGCG 19365 B16F10 Rad 9 GGCAAGAGCCTGTCTTACGG 13382 MC38 Arhgap24 GGACCCAAGCAGCACTGGTG 19366 B16F10 Rad b TAAGGGTCATTTCCCGTCAA 13383 MC38 Arligap24 GTGAACACAAGCAGAATGGG 19367 B16F10 Rad9b CCACCAATGAGACGCGAAGT 13384 MC38 Arhgap24 TTCAGCCCAAATGCAGCATG 19368 B16F10 Prr23al AGTCTCGTGCTCTACAGCTC 13385 MC38 Faml3b GGAGGATTCGGGAGGGATGA 19369 B16F10 Prr23al ATATAAATGTATCCGGCGTG 13386 MC38 Faml3b CGCCGAATCCGGGTTGACCG 19370 B16F10 Prr23al TGCGCGGGAAATCACGTCGA 13387 MC38 Fami 3b GGGTGCGGAGGTCCTGTGCC 19371 B16F10 Ric3 CTCGCCGGTCGAGTGTGAGC 13388 MC38 Gitl GGGCTITCACTGCTTCCTGC 19372 B16F10 Ric3 GAGCACTTTGGTAGAGTGGA 13389 MC38 Gitl AGCGGCCTGGGCCGCGCAGG 19373 B16F10 Ric3 CTTGCGTTCAGCTGTCACCC 13390 MC38 Gitl CGGCGCTCCGCTCAGCTCCG 19374 B16F10 Fig4 AGATGATTGGGTTCTCCTTT 13391 MC38 Mtchl TGAGTTACTCAACTATTGAG 19375 B16F10 F g4 TTTAAAGGTCAACATAAGTC 13392 MC38 Mtclil GACTGGCCTGGTCCGCAAAG 19376 B16F10 Fig4 GTTGCTGAGGGCGGACGCTA 13393 MC38 Mtchl GAGACTCGTAGGCACGATTG 19377 B16F10 Arsj CCTTGTCCATCCCGAAACGT 13394 MC38 Atp2b3 GGGAGGGAGGGAGCTGGTGG 19378 B16F10 Arsj AAGGATGGACCCGAGAAGGG 13395 MC38 Atp2b3 AGCGCGGAGGGAGGGAGGAA 19379 B16F10 Arsj GGTGAAAGACCATCTTTCTG 13396 MC38 Atp2b3 GGTGGTGGTGGTGGTGGTGG 19380 B 6F1 Aebpl AGTTTAGAGGGTCTGGGTGC 13397 MC38 Rab43 GCCAGCCGTCGGTGCCGTGC 19381 B16F10 Aebpl AAGGGAGTGTGCGGAGTCTA 13398 MC38 Rab43 CCTGTCACCTAGTGCAGCCC 19382 B16F10 Aebpl GCTGACGCTGCTATTAGTCT 13399 MC38 Rab43 CTCAAGTGCACAGTCCATCC 19383 B16F10 ZLC2 GCGCTGAGCTCGCCCTCCGG 13400 MC38 Pkdll2 CGATCTCCACCCTGCAGCCC 19384 B16F10 Zic2 TGTATTAAAGGAGCTGCGGC 13401 MC38 Pkdll2 GGTCATCCTAGGACCACTGC 19385 B16F10 ZLC2 CGCTAGCTGCCTTGTACTGC 13402 MC38 Pkdll2 ACAGGCTTTGAACAATTGCC 19386 B16F10 Kifl2 TTAACTTGCTAGCTCTGGGC 13403 MC38 Med24 ACTTGTCTAAGCTGCCAAAC 19387 1 F1 Kifl2 CATGCCAGGGCATTCCAGCT 13404 MC38 Med24 AGTCCTGCCACAATACCTTC 19388 B16F10 Kifl2 TTTCCTCTAGAGAGATCTAA 13405 MC38 Med24 GGCAGAAGGATTAATCTAAT 19389 B16F10 Obsll AAGTCACTCAAGCCCAAGCC 13406 MC38 Acsm3 CGTGAATGTTTACATAACCC 19390 B16F10 Obsll ATATTCTCTGATGACACAGC 13407 MC38 Acsm3 AAGGTTAAGTAAGACAGGCC 19391 B16F10 Obsll GGCCTCCAGGTCTCCAACTG 13408 MC38 Acsm3 CGGCAGTGCCTTTCCTTAAT 19392 6F1 Slcl5al GGGTTAAGCGATGTTAGCCT 13409 MC38 Aebpl AGTTTAGAGGGTCTGGGTGC 19393 n B16F10 Slcl5al TGTGTGACTGTAGGAGTGCA 13410 MC38 Aebpl AAGGGAGTGTGCGGAGTCTA 19394 B16F10 Slcl5al CGGCTGGGCTCCACCCTTGA 1341 1 MC38 Aebpl GCTGACGCTGCTATTAGTCT 19395 n B16F10 Aca GTGGCTGGCTGACTAGGTTT 13412 MC38 NeklO TACTGGTTGTTTACTTTCAA 19396 o B16F10 Acan CACCTGCGTCAGATGCTAGC 13413 MC38 NeklO ACTGCAATTATTAGATTGAG 19397 B16F10 Acan GAAAGGTGCCCGAACTCCCT 13414 MC38 NeklO GGAATGCAATGTTAATTCTG 19398 B16F10 Fbfl ACGGTGGCGTGGAGGATTCT 13415 MC38 Ndufs6 TAACTGTGCGCAGTGTTCAA 19399 b B16F10 Fbfl GCCGAACCACAGGACTTGAC 13416 MC38 Ndufs6 TCGTCCTATGCCTGAGCGGC 19400 J B16F10 Fbfl GTCCGTCGCCCGTTCACTAG 13417 MC Ndufs6 GTTACTAGTGTGACAAAGGC 19401 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Dmrtc2 GAAGCGGGTAGGCAAGAAAG 13418 MC38 Manic 1 GGGAACCTAGCCGGGAAAGA 19402 B16F10 Dmrtc2 GGCTGGCGTGATTGTTGCCG 13419 MC38 Manlcl GCGCCAGCATTTGGAGCGGG 19403 B16F10 Dmrtc2 GACTCAACTCGACGCGCTAT 13420 MC38 Manlcl CGCGAGGCGCGCTGTAGGCG 19404 o B16F10 Teddmla GGGAACTGAGTGGGTTCTTG 13421 MC38 Vcp GAGTCITGACCAATCGACAA 19405 B16F10 Teddmla GGGCTTCTCCTGAGTGGCTT 13422 MC38 Vcp CGTGTTGCAGCCTTGAGGCG 19406 B16F10 Teddmla CCCATTCTCCTCTGGTGCAT 13423 MC38 Vcp CCAAITGACGTGGCGTTACT 19407 B16F10 Prdm6 GGGCGTGCGGGAGGATCGCA 13424 MC38 l ri l ACTCTGGTGCACGTTTAGCC 19408 o 4 B16F10 Prdm6 GACGACAGTACCGCGGGCCG 13425 MC38 Pkhdl CCACTTAGAGACCCAAAGAA 19409 B16F10 Prdm6 GCAAAGTTTACTCGGAAGCC 13426 MC38 Pkliril TCTGAGACACATGCAGTAAG 19410 B16F10 Akl GTGGCAGACACACTGTGTGC 13427 MC38 Tle3 CATTGTGACGTCGCGCCTGG 1941 1 B16F10 Akl GTGGTTGCCACAGTACTGCT 13428 MC38 Tle3 CACGGGACTCGGACTGCGAC 19412 B16F10 Akl AGAGTCGTGCGGGCATAGAG 13429 MC38 Tle3 GTGGCGGCTTCGCCTAGCGT 19413 B16F10 C77080 AGAGGACATTGTGCCTTAGG 13430 MC38 Usp29 GGGTCITGGATTGGTTAGAG 19414 B16F10 C77080 AAGACTGGCTGAGTCAATCC 13431 MC38 Usp29 AAGGCAACAGCTTGGCGCCA 19415 B16F10 C77080 TAGCGGATGGGCGGGCTCTA 13432 MC38 Usp29 ACAACAGCAGTCTGATTGGC 19416 B16F10 Dlg4 AACTGGATTTCGGGAAGCCC 13433 MC38 Amyl CAGCAGCCAAGGGAAGGCAG 19417 B16F10 Dlg4 GGGTCTTGCCAAACGGCCAG 13434 MC38 Amyl GCTAATAAATTGTCCTGCTC 19418 B16F10 Dlg4 GGCAGCGGCCGATGTAGCCG 13435 MC38 Amyl AATCTCTGTAATGCACGATG 19419 B16F10 Tnfsfll ATAAGAGTTAGGGCTGCCTG 13436 MC38 Kcnh6 GTGACCGGTGCCCTGGCTTC 19420 B16F10 Tnfsfll CCCATCAGGGCCCTCTGAGG 13437 MC38 Kcn 6 GGGCTCAGCAGCGTCGGGCT 19421 B16F10 Tnfsfll CCCTGAGAGCGAAGAAGAGT 13438 MC38 Kcn 6 TTTCTGTAACACCACTTGCT 19422 B16F10 Ddx 9 ACTTGAAACTTCAAGTGACC 13439 MC38 Iqsec3 GGGITCCTCACGAAGCCCAG 19423 B16F10 Ddxl9b TAATGCTGGCTACCTCAGTT 13440 MC38 Iqsec3 GGGCGTAGGAGAGGCGGGTG 19424 B16F10 Ddxl9b CAGTAGTGGCGCTGGATCCC 13441 MC38 Iqsec3 GTGTGCGAATGCCTGTGTGG 19425 B16F10 Mfhasl CGGGAGTTGCAAGTAAGCGC 13442 MC38 Bazlb GCGGAGGCTCCGATAGGCGG 19426 B16F10 Mfhasl CAGGGCGAAGTCCACGTCGC 13443 MC38 Bazlb CTTGCTTCTCCGTGGCGCCC 19427 B16F10 Mfhasl AGGACCGCATCTGGTGCGCC 13444 MC38 Bazlb CGTCGGCCTTCGCAGCCTAT 19428 B16F10 Cdkall CCATGACACTTGTGTCCCGC 13445 MC38 Smarcall ATTTGAGAGGCGTAACGTTG 19429 B16F10 Cdkall GGAGCATGCGCAAATCAGCC 13446 MC38 Smarcall ATCACCCACAA1TTATGACC 19430 B16F10 Cdkall ACCTCTCCGGTCTACCGTCG 13447 MC38 Smarcall GAATCGGAAAGCCTGCCCAT 19431 B16F10 S100al3 TGCAAATGTGGCCACTGGAC 13448 MC38 Aebp2 GACGAGGGCTACGGCACCGG 19432 B16F10 S100al3 CCTTTGGGTGTCGTTTGTGA 13449 MC38 Aebp2 AGTAGCGTGGTGTCGAGCGG 19433 1 F1 S100al3 AAAGACAGGTCTCCTCACAC 13450 MC38 Aebp2 GGGAGCAGCGCGACCTCCGG 19434 B16F10 Prkx CAGGTACATCCCATGGGCGT 13451 MC38 Adaml7 TCTTCCGGCTGTGGGCCGCG 19435 B16F10 Prkx GGGTGTCTGGATGACGCGAG 13452 MC38 Adaml7 GACGCCGCCAGCTGAAGGCC 19436 B16F10 Prkx AACAAGGCGGAGCGAGATGA 13453 MC38 Adaml7 GAGAGAGAGAGGGTCGAGTC 19437 B16F10 Freml CTGAGCCTTTGTTAATAGGT 13454 MC38 Tm9sfl GACCGGTTATTGTTGGCAAC 19438 6F1 Freml GGCTTCCTTGCCCTTTGGAT 13455 MC38 Tm9sfl GCCTCCAGAAAGCCTCGGAG 19439 n B16F10 Freml GGATGCCTGCAACTGTTTGC 13456 MC38 Tm9sfl TTGTGCCGCGTTCCCACGCC 19440 B16F10 Tmem62 CTCTTAAAGTACAAATGCGA 13457 MC38 Zfp316 AGGAGCAGGTAATAAGCAGG 19441 n B16F10 Tmem62 AATGACACCTTGCGTGCGTG 13458 MC38 Zfp316 ACCATCCTCCATGCATATGG 19442 o B16F10 Tmem62 TGAGAATCAAAGTGAGTATC 13459 MC Zfp316 CCGGAGCTCTGGATGTAGAC 19443 B16F10 Dusp27 CCCATAGGATGGCAGCTCTC 13460 MC38 Illrapll GACACCTTCCCAAACAGCAG 19444 B16F10 Dusp27 TTTAGCAGTGGGTTTAGAAC 13461 MC38 Illrapll GCTGAAGAGAGCTAGGACCC 19445 b B16F10 Dusp27 ATCAATGTCTGAGAATCAGC 13462 MC38 Illrapll TCACATAGCAGTACTGTACA 19446 J B16F10 SLcla5 GCCGTCCCGCAAGCGCTGAT 13463 MC Tra£2 CGCGCCTACCAGGAGCTCAC 19447 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Slcla5 GTTATGGAACATTCGGCGCC 13464 MC38 Traf2 GACGGAAGCAGGAACCTACC 19448 B16F10 Slcla5 TATGCATTGTTATTCACCCT 13465 MC38 Traf2 CGGCCGTCGATTTGTCAAAT 19449 B16F10 Foxo6 CGGTTGAGCCGGCGCCGCCA 13466 MC38 Actrtl CCTATGTCATAATGTAGCCA 19450 B16F10 Foxo6 GACAAACTGGCGAGCACGGA 13467 MC38 Actrtl CTGAGCCAACACTATTCATT 19451 B16F10 Foxo6 AGGCAAAGACCCAGGCAGTG 13468 MC38 Actrtl GAGGCAATATTCATGGGCTG 19452 B16F10 Dpf2 TCTCGAGCGCTCGCTCTCGT 13469 MC38 Ccrlll GCACTAGTAAATAGTTCAAT 19453 B16F10 Dpf2 GACCTGTCCTGAAGGAGCCT 13470 MC38 Ccrlll TTCAGGGTTTAGTAAACTCT 19454 B16F10 Dpf2 TGAGGCGTCACTAAATGGAG 13471 MC38 Ccrlll TGTAAACTCTTCTACAGGAC 19455 B16F10 Numal TATAGITGCAGCAGACTCTG 13472 MC38 Lrtnp TCGAGTGACCATTGTGGAAA 19456 B16F10 Numal AACCTAATCCGCTGTTCCTG 13473 MC38 Lrmp CTGGCCTTTAGCCTGCGCAG 19457 B16F10 Numal TGGCAGCACAGCTGGGATTT 13474 MC38 Lrmp CTCAAAGGGAGTGACACTAT 19458 B16F10 Ftem3 CTGTTAGTTGCTGCAGCTCC 13475 MC38 Peg3 CTGCGGGACACCTCCTTGTC 19459 B16F10 Frem3 GCTTGGATCCCGCCAGATCC 13476 MC38 Peg3 TTGACGTCAACTCCGTGCCT 19460 B16F10 Frem3 CGCTATGTGTCGGTGTGCTG 13477 MC38 Peg3 CGTGGTGAGGGCCCAAAGCG 19461 B16F10 Cxcll6 CGTCAGGCAGTATCAGGCCA 13478 MC38 Gdil CATTGTCAGGATTCCTCCCA 19462 B16F10 Cxcll6 CTTGTTTGACTGCTTCACCT 13479 MC38 Gdil CTGTGCAACAACACACAGCA 19463 B16F10 Cxcll6 GTGGTGGCGGCTGTAGGTAC 13480 MC38 Gdil AACAAGCCTCTACTCTAAGT 19464 B16F10 Cesla TCATCTCATGATTAGGCCAC 13481 MC38 Rt l GCGGCTGCTCTATGCGACCG 19465 B16F10 Cesla GCTTGAACTAAGGCTATGTA 13482 MC38 Rtnl TGTCCCTGGGATGGTAGAGC 19466 B16F10 Cesla TGTAATCTGATAGTTGAGTC 13483 MC38 Rt l TGATTCGCTGTCGCGCTCTG 19467 B16F10 Ubr3 AATTGACTGCTGCGATGGCT 13484 MC38 Tntnd GCACAGAATTCCATCCAGAA 19468 B16F10 Ubr3 CAGAAGTGCTCTGCAGCGCC 13485 MC38 Tmnd AAATCATTTCAGTGTGTCCT 19469 B16F10 Ubr3 CGCCCAACTCTCGCGATACC 13486 MC38 Timid CTGCTCTGTTTGCTTACTTC 19470 c B16F10 Deaf 13 AAGACGCGAGCGACAGCTGA 13487 MC38 Gimap6 GAAACACTGGTCCCAGCTTT 19471 B16F10 Deaf 13 TCCGCAGAGTGGCAGCCGGA 13488 MC38 Gimap6 TACCTTGACACAGGATAACA 19472 B16F10 Deaf 13 AGAGACTACGGAACGCCGCG 13489 MC38 Gimap6 GACAAGCTTTCTGGAGTCTA 19473 B16F10 Fmnl GGGCAGGTAGGCTGATCTTC 13490 MC38 Sptbn2 TACTTTCAGAGCTGGAGTGG 19474 B16F10 Fmnl TCGCACTCGGTCAGTTATTT 13491 MC38 Sptbn2 CACAGAGTGGGTGCTAGCAG 19475 B16F10 Fmnl GCTGCACACCTTACTACACA 13492 MC38 Sptbn2 TAGTTAGCTCTCCAATCTGG 19476 B16F10 Lipk TACTGCCAGAACAATCTTGC 13493 MC38 Ces3b ATTAACTTGGTCTGCCCGAT 19477 B16F10 Lipk ACTGGGCCTCAAGGAAGATG 13494 MC38 Ces3b GCTCTGCCTGTTCTCAGAGC 19478 B16F10 Lipk AGGTCTGATTTGGCAGGAGC 13495 MC38 Ces3b ACCAGCAGAGTCTTCTGGAG 19479 B16F10 Osbpl3 TTTCACGTTATTCCGCCCAG 13496 MC38 Gtpbp3 GTGTTCCGGGATAGGCATCC 19480 B16F10 Osbpl3 ACTCACCAGCTACCAAGCCC 13497 MC38 Gtpbp3 GTTAACCCGAAGTTAACTGG 19481 B16F10 Osbpl3 CGGAITCCGTGACGCCAGCC 13498 MC38 Gtpbp3 CTGGGCAAGTATCTTTAGCC 19482 B16F10 Plbl GTGGCACAGACTGCACCATG 13499 MC38 Prss29 TTCAGGGTTTGAGCTTGACC 19483 B16F10 Plbl GGCAAGTGGAGATGTGGGCG 13500 MC38 Prss29 AGCATCATAACAACAGAGTC 19484 B16F10 Plbl AAAGCCTTAACTCAGGAATG 13501 MC38 Prss29 GGACATGCTAACAGTGTTTG 19485 B16F10 KM41 ACTGGGACTTCTGGTCACTA 13502 MC38 Lritl GCTGCTGAGTGCTAGGGCTG 19486 B16F10 KM41 GGCTCTAACAACGGGAATTT 13503 MC38 Lritl GCCTGAATCACCCAGTCTTG 19487 B16F10 KM41 TGCTAAGAAACAGGGCATTC 13504 MC38 Lritl TATCCCATGGCCTTGGATGG 19488 B16F10 Cecr2 GGGCCCGGCAGAAACCTGGG 13505 MC38 Lrrc2 CAGATGTGAGGCCACAAGCC 19489 B16F10 Cecr2 GTTGTTGTTGTGGTGCGCGC 13506 MC38 Lrrc2 GGTGGGAGAGCAAGCGGCAA 19490 B16F10 Cecr2 ATTATAITGTATGGGATTGG 13507 MC38 Lrrc2 CATTACTAAATGGTTCTCGC 19491 B16F10 Cspg4 CAATTCAAGTCCAAAGTCGA 13508 MC38 Nlrxl TGGAGGCGTTCCTTGTTTGA 19492 B16F10 Cspg4 CCAGACCCGCGCTTAGATTT 13509 MC38 Nli l GACGCTTGGGAACCTGCAGG 19493 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Cspg4 GGCTGTCCAGTACTTAACTC 13510 MC38 Nlrxl GGGACTGAATAACACAGAAG 19494 B16F10 Cd209a ACTTCCAGTATGGTCAGCTC 13511 MC38 Trmtl3 AAACAAACATTTCTGTGTGC 19495 B16F10 Cd209a TGAGAAGTGAGTAATGACAC 13512 MC38 Trmtl3 TTACATTTCTCTGATGTGCA 19496 B16F10 Cd209a CTATTTCTGCTGAGAAGTAC 13513 MC38 Tmitl3 AAGACAGGCAAACAACAGCC 19497 B16F10 Crb2 GGCTTGTGCACTGAGACCCA 13514 MC38 Myof GTGGATTTGGGACGAACTGC 19498 B16F10 Crb2 CCTCCGGGAGGATCCTGTCC 13515 MC38 Myof TTTCACGAGTTACTGCTAAA 19499 B16F10 Crb2 TGGTGTITGTGAGGAGCGGT 13516 MC38 Myof TTGCGCAGCCAATGAAACGG 19500 B16F10 Nftbiz CCTGGCCTCCTTTATAGGGC 13517 MC38 Anks6 GTACCCATCAGGCGCGACCC 19501 B16F10 Nftbiz ATACACCCTATGCTCATCCT 13518 MC38 Anks6 CGGATTCAGTAGGAACGAAC 19502 B16F10 Nftbiz ACTAGACACATCCGGAGGCG 13519 MC38 Anks6 AGGGTGGGCCTGTGACTGTG 19503 B16F10 Ab 8 CTAGATAACCGTCCAACCAG 13520 MC38 1700019N19Rik GATTAGCGGCTAAGTTTACT 19504 B16F10 Abhd8 CTCTTCCCAGGATCAGCGCG 13521 MC38 1700019N19Rik GGGCAGATGCTGGATTCATA 19505 B16F10 Abhd8 TATGGCAGCGGCGAGCCGTC 13522 MC38 1700019N19Rik GACATTGGAACAAGAACTAC 19506 B16F10 Dabl CGGGTCTGCGCACCGCACGG 13523 MC38 Gpatch21 TTAGGCCCAGACCGGAAATG 19507 B16F10 Dabl AGTCGCCGCGGCGCCGACGA 13524 MC38 Gpatch21 GGGCTGAAGTGGTAAGGGAG 19508 B16F10 Dabl TCGCTCGGAACGCGTTCCGG 13525 MC38 Gpatch21 GCGCGCCCACTTCCGCTCCA 19509 B16F10 Cacnalf TGTCAGTTGGGAGGGTGAAC 13526 MC38 Gtsel GTTTAAACAGGAGACGCTCT 19510 B16F10 Cacnalf AATCGATATCTGCACCAAGC 13527 MC38 Gtsel CCTTCCCGGTCAGAGGCGAG 1951 1 B16F10 Cacnalf GGAGCAAATGGGATATTTGT 13528 MC38 Gtsel GGATITAAGCGTTCCGCCTG 19512 B16F10 9930012KllRik GGTGACCTCTCGCAGCCAGC 13529 MC38 Naip2 TGAATGTGAAATACCCACAC 19513 B16F10 9930012KllRik CCTCCAAGAGCACTTAATTG 13530 MC38 Naip2 CTGTGTCTGGGCCTACACTG 19514 B16F10 9930012KllRik ACCCACTCGAGGGCTTTAGC 13531 MC38 Naip2 CAGCTCATGGTTTGAGAATT 19515 B16F10 Ifrd2 TGCACTGCGCACAACTTGGG 13532 MC38 Adh4 GCATGCTGGGTAGAGGTGAA 19516 B16F10 Iffd2 GGCGTCGGCTTATGTGTCTC 13533 MC38 Adh4 GCTGGGAGTGATGAGTTTGT 19517 B16F10 Ifrd2 TCTGTGTACGCTGATGCCTG 13534 MC38 Ad 4 GCGTCCTGTGCTGGAGACTC 19518 B16F10 Fam65a GCGGGAACCGGACAGCTTCC 13535 MC38 P kg CAGCCCAGGATGAACCTGAA 19519 B16F10 Fa 65a TGTCAACCAGCTTGTGGAAA 13536 MC38 Prkgl TGGCTTTGGTCTCAAGTCGA 19520 B16F10 Fam65a GGTAGGCAGACCACTCTGCC 13537 MC38 Prkgl GCTAATCCCTAGCGTCTCTG 19521 B16F10 X 2 GGAGGAAGTGCTGGTGCCCG 13538 MC38 Gprl55 CCGGTCTCCATTCTGCCGTG 19522 B16F10 X 2 TGGAAGTTCATTTAGACTGC 13539 MC38 Gprl55 GGACCTCCATGCTGGAGGCG 19523 B16F10 X 2 GTTACGTCATACCACCACCG 13540 MC38 Gprl55 GGGCCATGTCCTGAGCTTGG 19524 B16F10 Egf AAATATTCAGGGTAGAGAAG 13541 MC38 Slc26all CGCAACGTGCTACTGATAGT 19525 B16F10 Egf CTCTCATGGTGTTTGCAAAG 13542 MC38 Slc26all CCGGAACCGCTTACCCTGAC 19526 B16F10 Egf TTCCACCAGAGCAAGCAGGA 13543 MC38 Slc26all ATTGTGCAGCAGGCCAGTCC 19527 B16F10 KiflSb GGTGGCAATTCCGCTCCGTC 13544 MC38 Ptchl ACTCACGCGCAATGTGGCAA 19528 B16F10 KiflSb CACTGCTAGAGACTCGATTC 13545 MC38 Ptchl ACCCGCTGCTGCCGCTCACA 19529 B16F10 KiflBb ACTAGTTCTCTTGCGCGCCT 13546 MC38 Ptchl AGGCGCAGGGTCTGAGTCCC 19530 6F1 Rimbp3 CAGGCGGATATCTGAGTTTG 13547 MC38 NrObl CCATGACCTCGAAAGCTCAA 1953 1 B16F10 Rimbp3 CTGTGTAGCCCTAGCTGTCC 13548 MC38 NrObl GGCAAACACTCCCTAGAAGC 19532 B16F10 Rimbp3 CTCCCAAATGCTGGGATTAA 13549 MC38 NrObl CCAAGGGAGAGTCTCAGCAC 19533 B16F10 Mup3 TGAGATTGCCAAGTTTGAAA 13550 MC38 Guca2b TGAAGAAGAATCCAAGCTTG 19534 B16F10 Mup3 GAGGTAATGCAGACCCATAC 13551 MC38 Guca2b CACAGAGCCCTATTCATGCC 19535 B16F10 Mup3 CACTTAITGATGATAGGCCA 13552 MC38 Guca2b AACATGGTCTGCCAAGGGCC 19536 B16F10 Probl ACTGCGCGGGAGGTAGTGCT 13553 MC38 Dus31 GAAGTGCTCAAGGGTCCCGG 19537 B16F10 Probl AGCGTCAACGCCTGAGCTAG 13554 MC38 Dus31 TTGATCCGTGGAAGTGAATC 19538 B16F10 Probl TTGGAGAAAGTTCGGCATGG 13555 MC38 Dus31 GGGTTCTTGTCGGTCATCCG 19539 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Siglech GGGTGTGGTTCAGAGAATAA 13556 MC38 Gjc2 TTGTGCTTGGTGGCGAGAGG 19540 B16F10 Siglech GCAGATAGGAGGGAAGACTT 13557 MC38 Gjc2 GAGAGCAATCCCAGCAGGGA 19541 B16F10 Siglech CTCTTTAATGTCTGACTGCT 1355S MC38 Gjc2 AAATTTGCGATCTTTACAGA 19542 B16F10 Itgb21 GAAGCATTCTCATAGACCAG 13559 MC38 Zfat GGAACCGCCCTCGGCACGCA 19543 B16F10 Itgb21 AGTTGCTCTCAGCGGCTACA 13560 MC38 Zfat CTACGTAGGCGTCGGATCCC 19544 B16F10 Itgb21 GCAGACACACCTTATGAGTC 13561 MC38 Zfat CGCATGCTCGCGGCTACCCT 19545 r B16F10 Nlrp3 GCTTTCTCAGTGTCTGAAGG 13562 MC38 Sia l GGCTGCGGCGTGAGGTAAGG 19546 o 4 B16F10 Nltp3 GTCCTCACCTTGGTGCTCTG 13563 MC38 Siahlb TCAGGAGTCAAGGTCTCGCG 19547 6 1 B16F10 Nlrp3 CTGAGGTTGAGAAACAGTGA 13564 MC38 Siahlb AGGTTOAATTCGGTAAGGAT 19548 B16F10 Clqtnf9 AGATGTCTTGGATTAGCTTC 13565 MC38 Serpinfl GGGTGGCCAACGTGTGGTCT 19549 B16F10 Clqtnf9 CTGCTGTGAAGGGAGGCTAC 13566 MC38 Serpinfl GGACCTTCATTGGGACATGA 19550 B16F10 Clqtnf9 GAGGGAGGCACAAGATGTCT 13567 MC38 Seipinfl TGAAGAGAGATAAAGATCCA 19551 B16F10 Gm7173 GCACGTGGGATTCCAACCGT 13568 MC38 Abca7 TCTATGGTGCCTTGTTTGCC 19552 B16F10 Gm7173 TGCCTTACAATTGGATCTCA 13569 MC38 Abca7 ATCCTCATCCTTCCGAACAT 19553 B16F10 Gm7173 TTGTGTCAAATTTACACAGC 13570 MC38 Abca7 TCTTTGCGGGAGATTTATTG 19554 B16F10 CK137956 GGTAGAGGGCAACTTTCTTT 13571 MC38 Pdgfc TGAAAGACAAGTTACAGCCA 19555 B16F10 CK137956 AAGGGAGCTGAAGACAGGGC 13572 MC38 Pdgfc CACTCCCAAAGCGCTTTGTC 19556 B16F10 CK137956 GCCAGAACTGACTACTTCCC 13573 MC38 Pdgfc GCCCGCAGACTCCTTATTTG 19557 B16F10 Smgl GTGCCGGCGCCCTAGGAGCC 13574 MC38 Actrla AATCCGATCGGGCTGGGACC 19558 B16F10 Smgl GGGCTATTGGTCACAGAATA 13575 MC38 Actrla CGCATGCGCAGTCTAGTCGC 19559 B16F10 Smgl CCCAGCATGCCGTGCGGCAG 13576 MC38 Actrla CCAGGGCTTGCGCTCCAAAC 19560 B16F10 Kcnh6 GTGACCGGTGCCCTGGCTTC 13577 MC38 Plk5 CGCCTGCACCCGAAGCCGAG 19561 B16F10 Kcnh6 GGGCTCAGCAGCGTCGGGCT 13578 MC38 Plk5 TGGGACTTGTTAACAGCGCT 19562 o B16F10 Kcnh6 TTTCTGTAACACCACTTGCT 13579 MC38 Plk5 TTCACCCATCCGGGAAACTG 19563 B16F10 Zfp541 AAGGACGTATTAGAATCAAG 13580 MC38 Abcc3 ACCCAGAGGGCCTGAGGGCG 19564 B16F10 Zfp541 TAAGAACAGACCCATCTCAG 13581 MC38 Abcc3 CCTAAAGGATAATGTAAGAA 19565 B16F10 Zfp541 CAGGAGCTAGCTGCCAGCGA 13582 MC38 Abcc3 AGGCTGTGTTGCAATCGCTG 19566 B16F10 Nod2 CCCTAGAGGGAAATCAGGAG 13583 MC38 Trim56 GGGCTACAGGTTAGGGCGAC 19567 B16F10 Nod2 TGAGACAGGTATCCGGGAAC 13584 MC38 Trim56 CAGAGTAGTTGTCCCGGGCC 19568 B16F10 Nod2 GGGACCGGTTTCAATCACAA 13585 MC38 Trim56 GGTGGTGCAACTTCCGTCCC 19569 B16F10 Wdr82 GCCTCCCGTTGCTGAGGCCC 13586 MC38 Golga7b AGAAGATGGGCTCTGCTGCA 19570 B16F10 Wdr82 TTTAGATGCTCCACGCCCGC 13587 MC38 Golga7b CACCCGGCCTGCAATACGGA 19571 B16F10 Wdr82 AGGGCGAGGAGCTTGTGTCG 13588 MC38 Golga7b TGGTGGAACATGGAATGCTG 19572 B16F10 Ranbp2 CGAGACGAACTCCCTTTCCC 13589 MC38 C b 5 TATCCTTCCCATTTGATTCC 19573 B16F10 Ranbp2 TCGTTTGCGAAACGGTCACG 13590 MC38 Creb5 ACTCAAGCTAGTTAAGGCTT 19574 B16F10 Ranbp2 AAATCTATAAAGCCTTTCCC 13591 MC38 Creb5 CATTACATCATCTCTTGGCC 19575 B16F10 Tmem45b GTACTGTGCTGAGCCACCTG 13592 MC38 Slc22a2 GAGCATTAGCTTATTTAGAG 19576 B16F10 Tmem45b AGCAGGGTTAGGGCCATCTG 13593 MC38 Slc22a2 GGGAAGTCTGACCCGAAGGC 19577 B16F10 Tmem45b GACACTCGGAAGCAGGGAAA 13594 MC38 Slc22a2 AGACGAACTCACAGGGAATG 19578 B16F10 Celsr2 CTTCGAGAGTGGTGGGAGCC 13595 MC38 Gucy2e TTTAATCAAGCAGAACAGGG 19579 v > B16F10 Celsr2 CGCATCGTGGGCTAAGAGCG 13596 MC38 Gucy2e ACAGGGAGAGAAAGCGAATC 19580 o B16F10 Celsr2 AGCCGCCGCGGCTGTTGACC 13597 MC38 Gucy2e GAGGGATTAAGGGCTGCAGC 19581 30 B16F10 Aoxl TTTGGCATCGATGGGAGAGA 13598 MC38 Zfp28 GGACCCTCAGGCAGTTCCTC 19582 B16F10 Ao l GGGAGACAAGCTGAAATCTT 13599 MC38 Zfp28 AGTCCACTTCCGGTGCGTTC 19583 B16F10 Aoxl CAATGCTGCAGAGGTCCTAA 13600 MC38 Zfp28 TCTAAAGGATTTCTCCGCTG 19584 30 6/1 B16F10 Dnahl TAAAGAACCAGACCTCTTGG 13601 MC38 Huwel GAATTACGAAGGTCTCGGCG 19585 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Dnahl CGCCCACCTACAGACCGGAC 13602 MC38 Huwel CGAGATCTCATGTTTCCTAA 19586 B16F10 Dnahl GGCGGGACCATTCGGCACCG 13603 MC38 Huwel GGAGGAAGCTCTCGTCCTTT 19587 B16F10 Lyzll GTCCATTAGACAGCTTATCC 13604 MC38 Dbt TCCCACCGGGCAGCCAACCA 19588 B16F10 Lyzll GAATCCCAAATTCTAATTAC 13605 MC38 Dbt GCTCGTTCCTTCTCTCCTAT 19589 B16F10 Lyzll TTCCAACACCCATAACTAAG 13606 MC38 Dbt AAAGAATTGAGGGAGGGAGA 19590 B16F10 Armc4 CGCGGCGGGCGGGTGTTTAC 13607 MC38 Faml34a CACGCGCGGGCGTCCCATCC 19591 B16F10 Armc4 TGCAGTGTCGCCTGGCACCC 13608 MC38 Faml34a TGGGTGCAGGATCACGACAG 19592 B16F10 Armc4 CAACGAAGCACGCGGGCACC 13609 MC38 Faml34a CGTGACGTGCCCTAACAGCC 19593 B16F10 T i AGCTGTACGGGTCGGCGCGC 13610 MC38 Gmll23 GTAACCGTACATGGTGGGTG 19594 B16F10 Tril ACACTAAGTGGCTCCGCGTC 13611 MC38 Gmll23 AACTTAGCTCAAGCAGCACT 19595 B16F10 Tril CTCACTTGGCGTCCGGGCTA 13612 MC38 Gmll23 TTGTGCTCCTTGCCCTCTAT 19596 B16F10 Ccdcl30 TCCTCCCGGAAGATCTACTT 13613 MC38 Unc80 CGCGCGCGGAACATGGCTGA 19597 B16F10 Ccdcl30 TATTGCAGACTGACCAATTC 13614 MC38 Unc80 GGTTCTGCGGTAGGACTCCC 19598 B16F10 Ccdcl30 CCAGCTTGCGCAGGCGCTTT 13615 MC38 Unc80 GCCGGCGAGGAACCCGCGCT 19599 B16F10 Pcdhacl GGGACCATGCTCCGAACTCC 13616 MC38 AtplOb TTGAGTAGGTGTAGCCTTGT 19600 B16F10 Pcdhacl ACGCCAGTGGCCGCAACACT 13617 MC38 At l b CCCTCTATACCAGGTTGTGA 19601 B16F10 Pcdhacl CTGGAGCGTGGAGGCCGAAA 13618 MC38 AtplOb AGGTATGTCAGTGTGGATGT 19602 B16F10 Ptcra TCTGGGAAGCAGTGTAGTAG 13619 MC38 T po3 CTCCTTTCTGGCCGTTACCA 19603 B16F10 Ptcra CCCTAGTTCCCAGTGCTTTC 13620 MC38 Tnpo3 CGAGAGTCTGCGATTCTGGC 19604 B16F10 Ptcra TATGAAGTGCTCTTCAGACA 13621 MC38 Tnpo3 CAGAAGCCAGAACCCGTGTC 19605 B16F10 KM26 GGGAGGAGCCTGAAAGACCA 13622 MC38 E[iiilin2 AGAGCCAAAGGGTTAGGAAC 19606 B16F10 KM26 GGTGGGCGGAGCTTGGGATC 13623 MC38 ili 2 GAAGAGTCACGTTTCGGAGA 19607 B16F10 KM26 GAGTAAGGCCAAAGAAAGTG 13624 MC38 EmiUn2 GCGGTCCCTCAATGACGCAC 19608 B16F10 Piezo 1 GAGCGCCGGCCCTACTAGCC 13625 MC38 Luc71 GATTACAGGCATACCACGAC 19609 B16F10 Piezo 1 GCTTATAAAGGCCCGCAGGC 13626 MC38 Luc71 AGGCCAGCGTCCTGGGTGTC 19610 B16F10 Piezo 1 CCGGGTCACCGGCACCAGCC 13627 MC38 Luc71 ACTCCTGTACACTTCCCGAC 1961 1 B16F10 Pnpla5 TAGGCTTGTAATGTAATGCC 13628 MC38 Dnajcl4 GCGCAGCTGCTTGAGGAGGG 19612 B16F10 Pnpla5 ACCCTCTCCACGTGTACACC 13629 MC38 Dnajcl4 TGAGCGGGAGGCGGAGCCGG 19613 B16F10 Pnpla5 GAGGTTAGGTGAGTGTAATT 13630 MC38 Dmjcl4 GGAAGTAAGCGGCCGTGGCG 19614 B16F10 Oog3 TCTGAATATGAGCAAGTGGG 13631 MC38 Sall4 TAAGCCCTCATTGATCAGGG 19615 B16F10 Oog3 ATTATATAAAGGGTCATAGC 13632 MC38 Sall4 TTAAATGATCTCTGAGGTCT 19616 B16F10 Oog3 AGAGGCCTACTTTGGCTTGG 13633 MC38 Sall4 GCCTTTGTCACATGTAGGGC 19617 B16F10 Sez6 GAGAACAGGCTTTCGAGCCC 13634 MC38 Dna2 GGATGCCTGCATGAACCTGC 19618 B16F10 Sez6 CAAAGGCGCAGAAGACCCAG 13635 MC38 Dna2 ATGAGACGCGTGCAGTTGCG 19619 B16F10 Sez6 AAAGGACTGCCCTGCTAATG 13636 MC38 Dm2 CGCGCCGGGAAGCACAGCGC 19620 B16F10 Cyp2a5 CACAATAGTGGATAGTCTGG 13637 MC38 Tas2rll7 GCTCCTCTGTTAGTGTGTTG 19621 B16F10 Cyp2a5 CTCCCTGTTAATCTGTCATG 13638 MC38 Sass6 CAAACGTGGCCGCCTGAGGG 19622 B16F10 Cyp2a5 TGTTGGCAATGTCCCAAACT 13639 MC38 Sass6 GGTTCGGGCACCGACCGAGC 19623 B16F10 Mtssll GGGCTTTGAAATCCGAGCTC 13640 MC38 Sass6 ACCCAGCGTTATGGAGGCTC 19624 B16F10 Mtssll CCCATTCACGGCCAGAAACC 13641 MC38 Sartl CCATCTTAGATGGCGCGAGA 19625 B16F10 Mtssll TGCCAGACTGGTCCGGCAAG 13642 MC38 Sartl CGGTCCCGCCTGCCAGCTAC 19626 B16F10 Msantd3 GTGAAGGCCTTGTCGGCAGA 13643 MC38 Sartl AGTTTCCGGCAACAGGAACG 19627 B16F10 Msantd3 CGGCTACGTGCACCGACCTC 13644 MC38 Dcstl ACTATGGCTGCTGGGACCCA 19628 B16F10 Msantd3 GCGGGATGTGTCTCCAGAGA 13645 MC38 Dcstl GTCTTCAGGTTCTATGGACC 19629 B16F10 Dock 11 GGAGGGTGTGTCTCCTGGAG 13646 MC38 Dcstl TGGGTTCTGAGACACGCCCA 19630 B16F10 Dock 11 TTGCAGGCTCTGGGTCCTGC 13647 MC38 Plxnb3 CAGTGGCGACGGGCACAAGA 1963 1 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

B16F10 Dock 11 CCGACCTGAGTGGCCTAAGA 13648 MC38 Plxnb3 TGTGGTGGAGCCCGATCTCC 19632 B16F10 Eif3h GGCTCCGTGACGCTATGTTA 13649 MC38 Plxn GGGCATTGTCCTGAGTGGGA 19633 B16F10 Eif3h GCGCCGGAAGCGGAACTACG 13650 MC38 Pygb ATTGACGGGCTCTTTCTCCG 19634 o B16F10 Eif3h GGCGGTGTCTGGAAGCAGGC 13651 MC38 Pygb TTTCAGCCGGGAAGAGAACG 19635 (O B16F10 Jagl CCTGAGCCTAGCTCGCCGGC 13652 MC38 Pygb CAGGCGCAATCCGTATGAGC 19636 o o B16F10 Jagl CGTGCCCGCCTGGCTCTCGA 13653 MC38 Cdanl CTGGCTGGGCAGATCTTCCC 19637 r B16F10 Jagl GTCATTGTGTTACCTGCAGC 13654 MC38 Cdanl CGGCGACCGGGATCGACCGT 19638 o 4 B16F10 Ylpml GATAGAGGGAACCTTGGCGC 13655 MC38 Cdanl GAGCAGGCGCACTCGCGCCA 19639 6 1 B16F10 Ylpml CATAGAGTCTCACAGCCGAA 13656 MC38 Lamal CGCCGTGCGGAGTCCTTCCT 19640 B16F10 Ylpml TACCATCGAGCGGAGAACAA 13657 MC38 Lamal GGAGGTCCTGGGTAGGACAG 19641 B16F10 Tpo ACTTGATCTCCCTGTATAAA 13658 MC38 Lamal GGCCTGGTGCGCAGGCCCTT 19642 B16F10 Tpo TAACTTCTGAAATGTGAATC 13659 MC38 Dab2ip GGCAAGCGCTGGCAGCCGAG 19643 B16F10 Tpo CTGATGCCCACTCAAGCTTC 13660 MC38 Dab2ip GAAGGGCAGGCCGGTGGCCG 19644 B16F10 Radii GACCAGCCACCTATTGGCCA 13661 MC38 Dab2ip GACCTCTGGGCCAACGITCC 19645 B16F10 Rad21 GCGCAAAGGGTTCCTTGAAG 13662 MC38 Cecr2 GGGCCCGGCAGAAACCTGGG 19646 B16F10 Rad21 GGTTTGCGGAGCGTCAGAGT 13663 MC38 Cecr2 GTTGTTGTTGTGGTGCGCGC 19647 B16F10 Cmya5 ATCCAGAGAAGATAACGTTA 13664 MC38 Cecr2 ATTATATTGTATGGGATTGG 19648 B16F10 Cmya5 CAGATCTTCAGCGGCCTTTG 13665 MC38 Rhpn2 GGTCCAGGTCTTGCTAAGAG 19649 B16F10 Cmya5 CGGGTGCTTCGTGCCAAATG 13666 MC38 R pr AGGAGGACTGCAAATGCGGG 19650 B16F10 Mrpsl5 TAGCGTTCACACAGTGCTCC 13667 MC38 R p 2 TCCAGGCTCGGGATCTGCCT 19651 B16F10 Mrpsl5 AGGACCAGGTCAGGAACATA 13668 MC38 Brd9 GATCCACCTTGGCTAAGGGC 19652 B16F10 Mrpsl5 AATTTAGAAAGTGATTAGGC 13669 MC38 Brd9 TCGGGCGGCGGAAGTGGATT 19653 B16F10 Lpcat2b GAGAGGCTATCCCAAGACAG 13670 MC38 Brd9 CGCGCGGCAGATTCGAAGCT 19654 B16F10 Lpcat2b ATTGTGTCATAGTAACCTCT 13671 MC38 Klra9 AAAGAGGTACTGAAGTTCAT 19655 B16F10 Lpcat2b TCTCATAGTGAAGGAGAACG 13672 MC38 Klra9 GAAGACACACTCCTGCAGAG 19656 B16F10 Gnat3 AAGCTTCCATTGGAGTTGCA 13673 MC38 Klra9 TTTGCTTTGTTGACAAGGAG 19657 B16F10 Gnat3 TTAAATTAAGTGGTCACATC 13674 MC38 B3gnt6 TTCTTGCATTTGACCAATCC 19658 B16F10 Gnat3 TTTGTGCTAAACTCTCAGGC 13675 MC38 B3gnt6 AAACTAAGCCACTCTCACAG 19659 B16F10 Mrpll AAAGGGTTCCGCGCGGAAGC 13676 MC38 B nt6 ATGCAAGCAGTTAGTTGCAC 19660 B16F10 Mrpll GTCTCAGACAGGGAACCGAC 13677 MC38 Ogfod2 CGCGTAGAAAGACGTCTTCC 19661 B16F10 Mrpll CTTTCGTGGCTCGGGTTCAA 13678 MC38 Ogfod2 CCGCTGACAATTCTTAACTT 19662 B16F10 Pofutl CATTGTGGGAGCCGCGCGAG 13679 MC38 Ogfod2 GAGGGTAACGAAGACTGGGC 19663 B16F10 Pofutl GCGGCGGTCGGGCCATTGTG 13680 MC38 Lame3 GGACTCGGGAACTGTGAACC 19664 B16F10 Pofutl GCGGGACCATAGAGAGCCCG 13681 MC38 Lame3 TCTGAGGGCGGGACCCATGC 19665 B16F10 Tab2 GGCAAACACCGCGAGATCTG 13682 MC38 Lame3 GGGACGGAGCTCGGATGGTG 19666 B16F10 Tab2 AGGGCAGGCGAGCGGCAGGG 13683 MC38 AW549877 TGTGCCCTTACATCATCGAC 19667 B16F10 Tab2 AATACGGCCACACAATATGG 13684 MC38 AW549877 CCCTCGCAGCACGGGATTGT 19668 B16F10 Lhb CGAGTGTGAGGCCAATTCAC 13685 MC38 AW549877 CGGAACGACCTTTGCGGGCC 19669 B16F10 Lhb GGCGAGACACAGACAAGGTC 13686 MC38 Casp2 GCGGGAATCGATAGCCAATC 19670 B16F10 Lhb GTGGCAAGGCCACTAAGTAG 13687 MC38 Casp2 AGAGCGAGGGTTCTCCTACT 19671 v > B16F10 Hephll ATTTATAACTCGCTCTGAGG 13688 MC38 Casp2 GGAAGAGAGGAGGCGCTAGA 19672 O o B16F10 Hephll CTCCGGTAGGCAGCCTGAAA 13689 MC38 Kank2 GCGAAGTTGAAGGGTGGTCG 19673 o o B16F10 Hephll TGCAAGCAGACCTCCCTCAA 13690 MC38 Kank2 TGAGACCCTAGGACGTGCTC 19674 o GL261 Ankidll GGCGGATACGGCGAGCCAAT 13691 MC38 Kai*2 GGGTGCACGCGCTCTCGCTG 19675 GL261 Ankrdll GCGGGAGGCTCTCATGCGGC 13692 MC38 ri s TCGAGCGGAGCGTCCGATCC 19676 SO 6/1 GL261 Ankrdll TGCCTGTTACGGAAGCCGTC 13693 MC38 Iris AGGAAACGCGAAGCGCCCTG 19677 OS Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Fstl5 TACATATGTTGTTGTGCAGC 13694 MC38 Jik GGTGGTGTCTAGGTCGCTAA 19678 GL261 Fstl5 TAGGGCTATTTCTGCCAGGC 13695 MC38 ei 2 TGAGAGACGGCTTCAGCCAA 19679 GL261 Fstl5 GCCAGGCTGCCCGTCAACCC 13696 MC38 Herc2 TGCGCCCGCCCAATAGCGCA 19680 o GL261 Histlhlt GATATGCAAGATTCTACTTT 13697 MC38 ei 2 TGAGCGGGTGAGTCTCAAGA 19681 GL261 Histlhlt ATTGCTCAGGTTATGACACC 13698 MC38 Medl31 AAACAAGGCGGCCGACGAGG 19682 GL261 Histlhlt AGAGCAGGGCGCGCTGTGAT 13699 MC38 Medl31 ACAGAGGCGGGCGGCGTTGC 19683 GL261 Nup2101 TAGCAAAGAACCAGACAGAA 13700 MC38 Medl31 GGGCGAGTCGCCCGCCGGCT 19684 o 4 GL261 Nup2101 GCCTTTCTTGCTAAGAATTG 13701 MC38 Cascl GACTACAGGCAGCAGTGTAT 19685 6/ GL261 Nup2101 AAATTTCGAGCAGAGACCCA 13702 MC38 Cascl CGAGGCCGCTTTCTTTGCTG 19686 GL261 Phf23 TGACTGGAGAGGCTGGGAGG 13703 MC38 Cascl CAAGCCACACTTCCCACATA 19687 GL261 Phf23 CCTCCGGAACTTCAGTTCCC 13704 MC38 Nr2f6 AAGGCTGCGCGGCCGCGTGG 19688 GL261 Phf23 AGCCCGAAGAGCTCGAGACG 13705 MC38 Nr2f6 TATAAGGGCGGCCGTCGCCG 19689 GL261 Adamtsll AGACATGCTGAATAACAAAG 13706 MC38 Nr2f6 CCGCGCGCCGCCCGGAGCCG 19690 GL261 Adamtsll TTAGCAGGAGTCTGATTGGC 13707 MC38 Dact2 TGCGACGCCCGAGGTCACAG 19691 GL261 Adamtsll GAATGGAATCTCTCTAGAGC 13708 MC38 Dact2 GAGGGCGCGGCCGGTCGACG 19692 GL261 Cdkl2 AATAAACTACTAGGCTCTTC 13709 MC38 Dact2 CCCTCCGCAGAGGGACAGAG 19693 GL261 Cdkl2 GGGAGGCTCCGCCGTAGGCG 13710 MC38 Trp63 TTGTGACCACAACAGGCGGT 19694 GL261 Cdkl2 GGGACCTTTCTGCCGGCGCC 13711 MC38 Trp63 TATACCCAACTATAGGCATG 19695 GL261 Sptbnl AATTACAATGTTCAGTTGGG 13712 MC38 Trp63 TGAAATGAAGAGTGAGTTCT 19696 GL261 Sptbnl CGGGTTAGGGTCTGCAAGGT 13713 MC38 Exoc7 GGTCGACGCCATCTTGAATG 19697 GL261 Sptbnl AGATGTGCCTTCTAGAGCCA 13714 MC38 Exoc7 GGGTCTTTCCTCGTAGCCAG 19698 GL261 Jade2 TACTTTGCGCCCACTCCTAG 13715 MC38 Exoc7 CTGGAAGAGCCGCTCACCTG 19699 GL261 Jade2 GCCTCCAACTGCGATGGCCG 13716 MC38 Vps41 CCCAGTAGGCTGTGGCCCAG 19700 GL261 lade2 GGCACCAGCTCTGAGCTGGA 13717 MC38 Vps41 AAGGAACCAGATTAGTGTGC 19701 GL261 Cttn GGTGGGTAGAAGATTGACAG 13718 MC38 Cenpj TTGTAGTTTGCATGTGTCCG 19702 GL261 Cttn ATGGTTGGAAGCTGGGTTGA 13719 MC38 Cenpj ACGTTTATGGCGGTGTTGCT 19703 GL261 Cttn AGAAGGACAGATTGGTGGAT 13720 MC38 Cenpj CACTGGACCAGAGTTGGGCG 19704 GL261 9230110F15Rik CTTCCTTACACACCTGCCTG 13721 MC38 Opnlsw TTTGGGCTCATGAAAGGTTT 19705 GL261 9230110F15Rik TCTGTAGGAGTTAGTTCTGT 13722 MC38 Op l s AACTAAGAGATCTCTAATCT 19706 GL261 9230110F15Rik TTTGAGCTGCTCCCAGGATA 13723 MC38 Op l w CAGTATTGGTTTCTGTGGCC 19707 GL261 Zfp689 TTCTGATTGGTCATCAATGA 13724 MC38 Tlxl GCACAGCCAATGGAGAGACC 19708 GL261 Zfp689 CACAACCGGCTTAGAGACAC 13725 MC38 Tlxl GTCAACAGCGAGCGAGCAGC 19709 GL261 Zfp689 GCCCATTTGAATGAAGCCAA 13726 MC38 Tlxl CAGCTAGGCTCGCTCGCTCA 19710 GL261 Col4a6 TTGCATAGATTCTTGTGTAT 13727 MC38 Tssk5 TGGAATGAGAATGAGTATGA 1971 1 GL261 Col4a6 TTTGGAACGGTTATGTGCAG 13728 MC38 Tssk5 GGATTAGCCCTACCCAATGC 19712 GL261 Col4a6 AAGCAGCTTCCCAAGGTAGG 13729 MC38 Tssk5 CTAGCACTAGGATGTGGCTT 19713 GL261 Cyyrl TATGAGGGTGGCACCAAAGT 13730 MC38 Ctsa TAATCTGTGGGCCTGAGGGT 19714 GL261 Cyyrl AGCACCCTGCCATTCTATAG 13731 MC38 Ctsa TTCCACCAAGAGCGTGCGTC 19715 n GL261 Cyyrl GTCCTTGGCCACCCAGGTTC 13732 MC38 Ctsa ACATCTACCACAGCGTAGAG 19716 GL261 Cnfcsr2 AAGGAAGAGGCGCCGGCGCA 13733 MC38 Lgmn TCGTAGTCTTTCTGGCTTGC 19717 n GL261 Cnksr2 CCGGGCGGCTCGTCGTGCCG 13734 MC38 Lgnui GCCTCGGAGTGTGGCGTATA 19718 o GL261 Cnksr2 GTGCATGGCTCGAGCCGCCG 13735 MC38 Lgnrn GCCGCAGCTCAATCACAGCG 19719 GL261 Ids CTCAGACGTCCGGCGCCATC 13736 MC38 Pmel ATGACAGTTTCTGGTTTCGC 19720 GL261 Ids TACAGTAGGCAGTGATAACT 13737 MC38 Pmel GTGTGGGATGAAATCAGTTC 19721 GL261 Ids AAGGTGGGCAGAACCTTAAC 13738 MC38 Pmel GACCATCCCTTTCTATATAG 19722 6/ GL261 Exoc7 GGTCGACGCCATCTTGAATG 13739 MC38 Dyrk3 GAACTGCGAGCACACCACCC 19723 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Exoc7 GGGTCTTTCCTCGTAGCCAG 13740 MC38 Dyrk3 TGCGCGGTTGCTAAGCGACG 19724 GL261 Exoc7 CTGGAAGAGCCGCTCACCTG 13741 MC38 Dyrk3 CGGTCCGCAGGGAGACCACG 19725 GL261 Slc36a2 GGTGTCCATGCAGGTGGGCG 13742 MC38 Pdlim5 CACGTCGCTCAGGGCTTAGA 19726 o GL261 Slc36a2 TCTTTAAGCAAGAGGAGGCG 13743 MC38 Pdlim5 CGCCCACCGAAACTCCACAG 19727 GL261 Slc36a2 TAACTGCACTGTGGTTGATT 13744 MC38 Pdlim5 GCAAGTCACAGAGCACAACA 19728 GL261 Uspl71b GCCACGCCTACAGTCTTCCC 13745 MC38 Zfp217 TCTGTCCATTTCCGGTTGCC 19729 r GL261 Uspl71b AACCACACCCAACTTGGGAG 13746 MC38 Zfp217 GTTGGTATTTAAGGCTGGGC 19730 o 4 GL261 Uspl71b CTACAGCAAGTTATTTGAAG 13747 MC38 Zfp217 CGCGTGCGCGGGAGCCCACG 1973 1 6 1 GL261 Scgb2b24 TATGTCGAGCTCTTGGAGGC 13748 MC38 Brca2 TAGCCGGGAACAGGCACAGA 19732 GL261 Scgb2b24 GATTGGTGGTGGGTGTGGCT 13749 MC38 Brca2 GGAAGAAAGGAATTCGGCTG 19733 GL261 Scgb2b24 ACTCCTGCCTCTATGCAACT 13750 MC38 Brca2 GGACGCGGCGCGAGTGCCAC 19734 GL261 Srrml CTAGCGAAAGGCTGCCGCCC 13751 MC38 1700080016Rik ACAGGCATCCGGGAACTTGG 19735 GL261 Srmil GTTCTCGTGGCGCACTGAGC 13752 MC38 1700080016Rik TAACGGCCGGCCTGAGTCCC 19736 GL261 Srmil AGCTGGGCGACTGGAACCAA 13753 MC38 1700080016Rik AACATGGATTCCGTTGTAGA 19737 GL261 Cacnalg GCCGTTGCCGTAGCTGTCGC 13754 MC38 Per3 CCGGCAACACGAGCTCCCAT 19738 GL261 Cacnalg ATCCAGCTGTGGTGTGCGCC 13755 MC38 Per3 GGGTGCAGGTCGTGCACGGC 19739 GL261 Cacnalg CTCTCCCTCCGCGTCTCGGC 13756 MC38 Per3 GTTACATAACCGCGGGCGGG 19740 GL261 Cenpq AGACGCGCGCCCGCAATGTC 13757 MC38 Sppl2c CTCTTGGTCACAAAGCAGCT 19741 GL261 Cenpq GGATTGGATTGGCTAATCCG 13758 MC38 Sppl2c AGTGAGGTAGAGCACTCAGT 19742 GL261 Cenpq AAGACATACGCTCCGCAGGC 13759 MC38 Sppl2c ATTGGGAGATGATCTGAGAG 19743 GL261 Ubacl CACATITCCCGGCATACCCA 13760 MC38 Seracl CCAACAAACCAGAGCTGGCC 19744 GL261 Ubacl GGGCGCTCATTACGCACTTC 13761 MC38 Seracl CCCACCTACTAGGGTGTCGC 19745 GL261 Ubacl TAAAGTGCACCAAGGCACGC 13762 MC38 Seracl GGCGCGATGACGTACGGCGC 19746 GL261 Ctmbp2 AGAGATGCGCGGCCTCGCGC 13763 MC38 Ppfibpl CGCGCTTGCGGCCCGCTGAT 19747 GL261 Cttnbp2 CGCACAGGGTTAAGCGGCAG 13764 MC38 Ppfibpl CCGGGCGCGCGGTCACTCCG 19748 GL261 Cttabp2 GTGCTGGTICTTGGTCCCGT 13765 MC38 Ppfibpl CGCCTGGTCTCCCACATTCC 19749 GL261 Pla2g5 GGAGGCTGAGAGATGAACAG 13766 MC38 Sis AACATGGAGAGAGTGTTAGA 19750 GL261 Pla2g5 TGTAGTCAGCCAGTCACATC 13767 MC38 Sis GAAAGGAAACTGTGTTTAAA 19751 GL261 Pla2g5 CTAAGTGTCTTGACTGTCTG 13768 MC38 Sis AACAATCACAGATGAAGTCA 19752 GL261 Gcat GGAATCTGGTTCTTTCAGCC 13769 MC38 Cap TTTCTTGGCATTGAGAGTCC 19753 GL261 Gcat TTGATTTGTAAGTCGACACC 13770 MC38 Cap GGAAGCAGCGGTCTGAGCCT 19754 GL261 Gcat ACTGTCTCACATGCTGACTT 13771 MC38 Cap TATATAAGTTAGGGCTGACA 19755 GL261 Ogdhl TTCCGCGCGTCGTGACGTCT 13772 MC38 Pigk GGTTTGGTTTGTTCTTCCCA 19756 GL261 Ogdhl GGAAGCACCTGGCTCTTTGG 13773 MC38 Pigk ATGGAGGAAGGTGTATGCGG 19757 GL261 Ogdhl GATCTGGGAGGTCAGCACCT 13774 MC38 Pigk GCAGCGGCAGCGCTGCTTTA 19758 GL261 Fam46b CAGCACAGCTGTCACACAGC 13775 MC38 Dcafl7 CAGTGGGTCGGGTAGCCTTC 19759 GL261 Fam46b CAAGGGAATCGCTGGCTCTC 13776 MC38 Dcafl7 CAGGTITACCGCGTGCAGCC 19760 GL261 Fam46b CGGGCCCAGCTGACACTTAT 13777 MC38 Dcafl7 CCCTACGGCGCAGCCTATTA 19761 GL261 Shrooml CGCAGAGAACTCGAGCCGGA 13778 MC38 Pdzd7 TAGGGCTTCCAGATCTGTGT 19762 GL261 Shrooml TGGTTAGAGGTCCAGGGCCG 13779 MC38 Pdzd7 CCCTCTCTTCCAAGTGGCCT 19763 v > GL261 Shrooml GGATCCGCAGGCAAGACTTA 13780 MC38 Pdzd7 GGATCAGCTGCTCTGTCTTG 19764 o GL261 Aire ACTCTGITATACTTTCAACC 13781 MC38 Tab3 GAGATCGCTTACAGCAGGCC 19765 o GL261 Aire AACGCTTACAGGTGCCTCTC 13782 MC38 Tab3 ACACAAAGATGGCACCGCCC 19766 o GL261 Aire ACGTCGCCTTTCCGCCGCTG 13783 MC38 Tab3 CGCCTCGTATTTCCTGGATC 19767 GL261 Mbnl3 ACGACGCAAGTGCGTCCTAC 13784 MC38 Ivl ACTGGTTTCACCACTCCAGT 19768 SO 6/1 GL261 Mbnl3 TTTGCGAGCGAGCCGCAAGG 13785 MC38 Ivl GTAGGCTAGAACAATATAAA 19769 OS Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Mbnl3 CGGAAGACGGTCCCGGGCCG 13786 MC38 vl GTTCCAACAGCAGCTAGAAA 19770 GL261 D630003M21Rik GGGTGACAGGAGCCCGACGT 13787 MC38 Lamcl TCTCTGGCCCACCGCCCTCC 19771 GL261 D630003M21Rik CCCAGGCTGAGGAGGCGAAA 13788 MC38 Lamcl AAACCCAAGGCCGGCCTCCT 19772 GL261 D630003M21Rik AGAGCAAGGCGTCGCACAAA 13789 MC38 Lamcl CCAGCGACTCCCGGCGGCGG 19773 GL261 Hyal4 ATTCACCTGCTCCAGAGCAG 13790 MC38 Ercc612 CTCCAGATATCGCGAGAAGA 19774 GL261 Hyal4 ACAGGCTTCCGGGAGCAGTG 13791 MC38 Ercc612 AGCGGCTTCCCTTCCAGACG 19775 GL261 Hyal4 CTCAGTCCTCCAAGCTAAAC 13792 MC38 Enx612 GAGGCTGACCTCGTCTGGAA 19776 GL261 Nlip4c TGAATCTTGGTGTAGGATTC 13793 MC38 4931440F15Rik TATAAGGATATGCCCTATGG 19777 GL261 Nlrp4c ATCTGCTATCTGTAGATACC 13794 MC38 4931440F15Rik TGGTGAGGTATGGAGGAAGG 19778 GL261 Nlrp4c TGCCGTATCCGGAGTGCATC 13795 MC38 4931440F15Rik GTCTCAGCCGGCCCATGTAG 19779 GL261 0610040J01Rik GTGATCTATGTTTGAGTGAG 13796 MC38 Csnklal GGCCAGGCCGCGGTTCGTGA 19780 GL261 0610040J01Rik GTAACCCTTTACCTGCGCCT 13797 MC38 Csnklal TGGTCGCGGCTGCTGAAGCT 19781 GL261 0610040J01Rik ATCTAGCAACTAATGCGGGC 13798 MC38 Csnklal TCGTGGTCGCGGCGACGTCG 19782 GL261 Tywl AGTGCTCTAGCATCTTTCCC 13799 MC38 NudtlS GCTGAAGGCTTGGTAAGGTC 19783 GL261 Tywl GAACGACCCGCCTTCCTTTG 13800 MC38 Nudtl6 ACCTGAGTTAGAATTTACGC 19784 GL261 Tywl TGAGCCAATCCGAGAAGTAC 13801 MC38 Nudtl6 CCTAGCCTAAGGGCCAATCC 19785 GL261 Clint 1 AAGTCTTGCAACTGTTGTGA 13802 MC38 Msh6 TGGGCTACGGATGCTCGGGT 19786 GL261 Clint 1 TCACGCGGAGGCTGTGTCAG 13803 MC38 Msh6 CGGCCAATCCGAAGGCGTGT 19787 GL261 Clint 1 TCAGCCCTCTCACGCTCCGG 13804 MC38 Msh6 TGGAGCTCGCGGTGGCTACC 19788 GL261 Gatad2b CAGAATAAAGTTCCTCATGT 13805 MC38 Klrblf TTTAATCGGTGTGGGCATAA 19789 GL261 Galad2b GTGAAGTGAAAGAAATGCTG 13806 MC38 Kltblf GTTGCAAGTGTGGGCGGGTG 19790 GL261 Gatad2b CGTTGGACAGTAATAGCATT 13807 MC38 Kliblf TTCTCTGTAGTTACTGAACT 19791 GL261 Hsd3b3 CATTGGTGGAAAGGTTATGG 13808 MC38 Syngrl CGAAGCTCGCGCTCAGAAAG 19792 GL261 Hsd3b3 GGCTCACATATTTAAACCTA 13809 MC38 Syngrl CAAGCACTAGCCGAGCGCAG 19793 GL261 Hsd3b3 CTCTTCTTGATCATTCCTGC 13810 MC38 Syngrl AATAGCGCGTGATCAGGGTG 19794 GL261 Siglech GGGTGTGGTTCAGAGAATAA 13811 MC38 Sncaip GCGGCGGAGGTGAACGCGCG 19795 GL261 Siglech GCAGATAGGAGGGAAGACTT 13812 MC38 Sncaip TGGAACCTTGGAATGGTTTG 19796 GL261 Siglech CTCTTTAATGTCTGACTGCT 13813 MC38 Sncaip TGATTCATGGATCGCGGTGA 19797 GL261 Yb l GACCCGGTCAGGTGGTGAGA 13814 MC38 Gucala CCACCAGATCCTGTTAAGAA 19798 GL261 Ybxl AAAGATACCAATGAGAGCGC 13815 MC38 Gucala GGCAAGAGGCAGAGCATTGT 19799 GL261 Ybxl GCCTATTGGCTCACGCTCCG 13816 MC38 Gucala CTCTCCGGCATCTCTAGTTT 19800 GL261 Nbea TGCGCCTGCGCGCAGCTTGG 13817 MC38 Vsigl CGACCTAGTCCCTGCCTAAA 19801 GL261 Nbea TGGCCGCTACCGCAGGCAGG 13818 MC38 Vsigl TCAGTCACAGCCTGGCTTAT 19802 GL261 Nbea CCGCGCACCTGCTCACCTGT 13819 MC38 Vsigl ACAGTAGCAAATATATCAAG 19803 GL261 Prrl3 TTGCGTTGTGAAATACATAC 13820 MC38 Lrriq3 AGACGCCATGGCCGACTTCC 19804 GL261 P rl AACTGACTTGTCAATCGCTG 13821 MC38 Lrriq3 AAGGCGCTCTCCGTGCAGGG 19805 GL261 Prrl3 GATCACTTTGACACGATGAT 13822 MC38 Lmq3 GTGCGTGCTAAGTGTGCTCC 19806 GL261 Pml GGGAGCTATGGAAGTAACTC 13823 MC38 Des CTGCTGGGTTTCACAGGGCA 19807 GL261 Pml ATGAGCCATGCCCGCATGCC 13824 MC38 Des AGGGATCCTGCAGCTGTCAG 19808 GL261 Pml TCTTTCTCTTAACTTTGGAA 13825 MC38 Des AAAGGGCGGCCACAGGCGAG 19809 GL261 Gml2171 TCACCACACTGTGTCTGAGA 13826 MC38 Gria4 GCGGTAAAGGTACTCAGAGA 19810 GL261 Gml2171 ACTGAAGGCCATATGTGGGA 13827 MC38 Gria4 TCTTTGCTGCAGTTGCAGCA 1981 1 GL261 Gml2171 TGGTGACCTGGAGGACAATG 13828 MC38 Gria4 AATCTGCAAAGCCCTTGATG 19812 GL261 Tcergll ACTCACTTGGTTGCGCGACG 13829 MC38 Mylk3 TTTGGCCCAGGCCCTTCTCC 19813 GL261 Tcergll GGGACACAGCGCGGCACGAT 13830 MC38 Mylk3 CTCGGGCTTAGCGATAAGCC 19814 GL261 Tcergll GCTGGCGCGGGCAGGAGGAG 13831 MC38 Mylk3 GCTAAGTGATGCAGGAAGTG 19815 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Nkapl AGGGCTCTTGCGCAGGCTCT 13832 MC38 Lingo4 GGGATGACGAATCGAATCGG 19816 GL261 Nkapl GCGCTGTGTGCGGGTTGTGC 13833 MC38 Lingo4 GGGITGCTGCAGACTCATTC 19817 GL261 Nkapl CAGCGCCACGGTTCGGACTA 13834 MC38 Lingo4 GGTCTGCTACGGAGACAGCC 19818 GL261 Aars2 GTCAAAGAGTGACGTTCGAA 13835 MC38 Car7 CAGGTGGCTTAGGGCGACGG 19819 GL261 Aars2 TATGCTGAGCCGCTCGCCAG 13836 MC38 Car7 TGCTCCTTGAGTATCTTCCC 19820 GL261 Aars2 ACGCCTAGTGTTTCCTACAG 13837 MC38 Car7 TTTAAGAGGCTGCTCCACCG 19821 GL261 Slc36al GAGGCAGTCTCCAGGGAAGT 13838 MC38 Dds41 CCAGAGGGCACAACGCTCCC 19822 GL261 Slc36al CTGAGACCACCACAGAGCTA 13839 MC38 Ddx41 AGGAGTTTCAGCCCTGCAAG 19823 GL261 Slc36al GAATGGAGCGGCACGTGACC 13840 MC38 Ddx41 TGGCGAAGCCTTGTGGGTAG 19824 GL261 Itga7 CGCAAGGCAATGGGTGCGGC 13841 MC38 Eftud2 AAGGCCGGAGGATTCTGATC 19825 GL261 Itga7 ACTGCACGCCTTGGGAGCAC 13842 MC38 Eftud2 ATTTCTCGAAGCTGTTCCTT 19826 GL261 Itga7 GCCGCGGGTCTGGGCATCCC 13843 MC38 Eftud2 CCCGGAGACAGAAATGGGAA 19827 GL261 Otof TGGATTCAGCATGCGTTCCT 13844 MC38 Slcola4 TCACAGTTAGAGGCAATTTG 19828 GL261 Otof GCTGGGCTGACAACCCAGAG 13845 MC38 Slcola4 TTAGCTGGACAGCACCCAAG 19829 GL261 Otof GCACAGCTCTGATGAGCTGA 13846 MC38 Slcola4 GATTTGCCAAGAAAGGACTT 19830 GL261 Ascc2 GGGTCAAACTGCGATTCCGT 13847 MC38 Slc25al0 TGAGAATGGCAGAGCGCCTT 1983 1 GL261 Ascc2 CAAATTCCTGCGCCTCCAGG 13848 MC38 Slc25al0 CCGCAACGAGGAGCAATGAG 19832 GL261 Ascc2 CCCGGCGCCAACTGTGGAGG 13849 MC38 Slc25al0 CTCCCAAGGCTGGAGTCCGG 19833 GL261 Aniacr TTGGTTTAGCTGCTCAACTT 13850 MC38 Itgb3 TACCCATCACACTCAGCCTC 19834 GL261 Amacr CATGTTGTGCGAGTCCTCTT 13851 MC38 Itgb3 CGGTCTCCTCTAGTGAACGC 19835 GL261 Amacr GGTGAGGGTAGCGATTCAGG 13852 MC38 Itgb3 CCCAGATGCACACAGGACCC 19836 GL261 Lamal CGCCGTGCGGAGTCCTTCCT 13853 MC38 Smc5 ACTCACGAAACATTACAAAC 19837 GL261 Lamal GGAGGTCCTGGGTAGGACAG 13854 MC38 Smc5 GAGGTTGGAAACGATTGTTC 19838 GL261 Lamal GGCCTGGTGCGCAGGCCCTT 13855 MC38 Sm 5 TAGGTAGAATGTAAGAACAT 19839 GL261 Zfp354a GATGTTGCAGGTTAGTGGAA 13856 MC38 Tsc22dl GGTTGAGCTGGCTCCGGAGT 19840 GL261 Zfp354a ACAAGCAGGTGTTTGATTCC 13857 MC38 Tsc22dl GTGAAGCGGAATATAAAGGG 19841 GL261 Zfp354a TGTCTGATGCACAGATTACT 13858 MC38 Tsc22dl GCGCCGATTGGCCGCGCCAT 19842 GL261 Setpinb9c AGACAGTAACACCCATCTTC 13859 MC38 Cdc25a TCAGCTGTCATTCGGGAGCG 19843 GL261 Serpinb9c GACGTCATGCTCAGTGCCCG 13860 MC38 Cdc25a CTTTCCTAGTTGGCGCCAAA 19844 GL261 Serpinb9c GATGGTATCAGCCTGTCTTC 13861 MC38 Cdc25a GGTCACGCCCTCTCTCGGTG 19845 GL261 Cabinl GTGTCTTTGACTCGCGCGCG 13862 MC38 Adamtsl3 CTTCAACTGGGAATCATTCC 19846 GL261 Cabinl TGTCAGCCTTATCAGCCAAT 13863 MC38 Adamtsl3 AGCAAGCCCTAATAGGACCC 19847 GL261 Cabinl CCAACAAGGAACGCTCTCAT 13864 MC38 Adamtsl3 GCAGCAAGCAGCTTCTTGCC 19848 GL261 Tiel GTCCCTTCCATCTGCATTGC 13865 MC38 Cacnalf TGTCAGTTGGGAGGGTGAAC 19849 GL261 Tiel GGGCATTAGAGGTGGGAGGC 13866 MC38 Cacnalf AATCGATATCTGCACCAAGC 19850 GL261 Tiel GCTGGACACGGGAGGACTAC 13867 MC38 Cacnalf GGAGCAAATGGGATATTTGT 19851 GL261 Fuom CTCTGAAGCCAGGCAGATTG 13868 MC38 Ly6c2 AGGTITCAGGAACAGTGGTA 19852 GL261 Fuom CATCAGAGATCATTGGGCTA 13869 MC38 Ly6c2 CAATAAACATGTTGGCCCTG 19853 GL261 Fuom TGTTGGGCCCGCCTCTCCTC 13870 MC38 Ly6c2 GGGAGGAGGGCAGTGGGTTT 19854 GL261 Mat2b CGTGTGGAATATTTCACAAC 13871 MC38 Piezo 1 GAGCGCCGGCCCTACTAGCC 19855 GL261 Mat2b CGCTCTATCTCCTTAAGAAC 13872 MC38 Piezo 1 GCTTATAAAGGCCCGCAGGC 19856 GL261 Mat2b GAAAGACAAGAATGAGCCAA 13873 MC38 Piezo 1 CCGGGTCACCGGCACCAGCC 19857 GL261 Ctrl TTATCAAGTACCCAGGTGTG 13874 MC38 Ngef CTATAGGGAGGCAGGTCTGA 19858 GL261 Ctrl ACTTCTCAGACCAAAGTCCT 13875 MC38 Ngef CCCTGGCTGCAAGGTAATAT 19859 GL261 Ctrl GAAGTCTTGGGCCTGAGACT 13876 MC38 Ngef CCGGCACCCGGCGGCCGCGG 19860 GL261 Bche CGAGTTAGTTTGCACTATCC 13877 MC38 Nqol TGGACTAGGACTCCTGTATA 19861 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Bche CTATCCCGGACTTTAACATT 13878 MC38 Nqol TGGGCTGGGCGGGCATAAGC 19862 GL261 AW551984 TTCCCAGCAGCCAACAGCAG 13879 MC38 Nqol TTTGGCAGGGAGAAGCAGTT 19863 GL261 AW551984 AGCTAACCATGGAGGAGACT 13880 MC38 Duspl2 AGTCTCCATTCATCCGTTGC 19864 o GL261 AW551984 GGATGGGCCTCCTGAATAAG 13881 MC38 Duspl2 ACAAACTTGTACAGTCACTA 19865 GL261 Msl3 GCAGTGGCGATGGAAGCGCG 13882 MC38 Duspl2 ACCCAACCTTCTAAAGTCCA 19866 80 GL261 Msl3 TCGTAGCCTCCACCACTCCC 13883 MC38 Ush2a AATCACGCTCATCGACCTAT 19867 r GL261 Msl3 CCGCGCCACTGCGAGGACCT 13884 MC38 Ush2a GACAAAGATCTGAACGTTAT 19868 o 4 GL261 Tlr8 AAGAAGATGTGCTCTATAGC 13885 MC38 Ush2a CTAAGTTGTGTGGTTCATAA 19869 6 1 GL261 TlrS TTCGCACAAACTCATCAGAC 13886 MC38 Didol TGGGAGCCAATGCCACTAAA 19870 W GL261 TlrS GAACAGCCCAAATTCTTTCT 13887 MC38 Didol AAATCITACGATCTCGCGAG 19871 GL261 Cbrl ATACACAGCAATTTGACAAG 13888 MC38 Didol AGACACAGAGTTTAAGCTTT 19872 GL261 Cbrl GGTGTGTTTGTTGTTTAGTG 13889 MC38 Hapl GCAGCCAGTGGTGACGAGAT 19873 GL261 Hfe CAGCAATCCTGACTCAGCAG 13890 MC38 Hapl GGAAGAGAAATCCATCACCG 19874 GL261 Hfe GTTTCTTCCCATCAATGTCC 13891 MC38 Hapl CTAGTGCCTAGCTTATTCCG 19875 GL261 Hfe TGACAAGCTAGATCCCTTTC 13892 MC38 Camsap3 CGTGTGTTCCTGCTCACTCC 19876 GL261 Ptprt GTGGCCGAGGCGGAGCGCCC 13893 MC38 Camsap3 CCTAAGCCTCTCCAGGGTCC 19877 GL261 Ptprt TACGCGCTTGAGTGCGCGAG 13894 MC38 Camsap3 TGATCCCACACATATGCAGG 19878 GL261 Ptprt CACATCGCTCTTGCACACAC 13895 MC38 Prss44 GGAGTCAGTCGTGGATCAGG 19879 GL261 Osm TTACATCATCCTTGGGCGTG 13896 MC38 Prss44 ACAGTTCTGCAGGAAACGGG 19880 GL261 Osm CCAACATCTCGTGAGGTGGG 13897 MC38 Prss44 AGAGTGGAGAACTGGGATCT 19881 GL261 Osm TTCTTCGAATTCGTTCTTCG 13898 MC38 Ubqlnl TGATCAGATCATGCCCTTAG 19882 GL261 Mytl TTTGGGCACATTTGTTGGTG 13899 MC38 Ubqlnl TTTCATCATGATGTATTGTG 19883 GL261 Mytl ACATAATCACAAATTGATGC 13900 MC38 Cpne3 TCGTGGGCGGAGTCCCGGAG 19884 GL261 Mytl TCCAGCCCAGTCAACTCTCA 13901 MC38 Cpne3 GCGAGGGCGGAGCTTGTGGG 19885 GL261 Cede 163 GTTGAGACCTCCACAAATCA 13902 MC38 Phkal TGGGCGTAGCGCGCAGCTGC 19886 GL261 Cede 163 GGGTAGAATGAACCGAATTT 13903 MC38 Phkal CGCCTCGGGCGACACATTCT 19887 GL261 Cede 163 ATACTGTGAATCTAGAACTA 13904 MC38 Phkal GGCGGAGGGTGGCGGGCTAC 19888 GL261 Traf2 CGCGCCTACCAGGAGCTCAC 13905 MC38 Med 13 TGGGTGCCTCCGGGCGGCGG 19889 GL261 Trafi GACGGAAGCAGGAACCTACC 13906 MC38 Med 13 CGGATGGTGGGTTGTGGCGC 19890 GL261 Traf2 CGGCCGTCGATTTGTCAAAT 13907 MC38 Med 13 CTGGTCGGAGGCGGCGGTAA 19891 GL261 Arhgap40 ATGTGTGAGCACAGACTTCC 13908 MC38 Ccdcl55 ACTGCGCATCATTGTGACAG 19892 GL261 Arhgap40 GAATGAATCACAGTGAGAGT 13909 MC38 Ccdcl55 TGGGTACCTATTAATGCGGG 19893 GL261 Arhgap40 TCAGCCTCACCTCAATATGG 13910 MC38 C d l 55 ACTGCTTAGCTATGTAGCCC 19894 GL261 Sc5d GCGGATCGCGCGACCTGGAC 13911 MC38 Iffo2 GCTCGCAGAGGACTCTCAGC 19895 GL261 Sc5d GAGTGCTGGACCTGGTTCGG 13912 MC38 Iffo2 CTTCCCGGCCCGCCCTCTAT 19896 GL261 Sc5d ATGAAGCGCCTGGATAGTCC 13913 MC38 Iffo2 AGAGACAGGAGCTTCAGTTG 19897 GL261 Nlrp5 AGTGGCTGGTTGCCAGTACT 13914 MC38 Nup2101 TAGCAAAGAACCAGACAGAA 19898 GL261 Nlrp5 AGCACGAGCTTAATGCCCAT 13915 MC38 Nup2101 GCCTTTCTTGCTAAGAATTG 19899 GL261 Nlrp5 AAGTTCTGAGTAGCCCTTCC 13916 MC38 Nup2101 AAATITCGAGCAGAGACCCA 19900 GL261 Runx2 GGCACCTTGAAACGCGAGGG 13917 MC38 Col4a6 TTGCATAGATTCTTGTGTAT 19901 xi GL261 Runx2 TGCAAAGAGCAGGAGAGACG 13918 MC38 Col4a6 TTTGGAACGGTTATGTGCAG 19902 o GL261 Runx2 AGGGAGGGAAGAGAGCAAGG 13919 MC38 Col4a6 AAGCAGCTTCCCAAGGTAGG 19903 80 GL261 H13 AAAGGAGCTCTGGACCACTA 13920 MC38 Slc7a8 TCGCGAATGTGCTTCCCTTT 19904 GL261 H13 GTAATCCATCCTGAGATTTG 13921 MC38 Slc7a8 CGGCGTTTATTTGCGGACCG 19905 GL261 H13 ATCGCCTAGGACTAAGGGAT 13922 MC38 Slc7a8 CGCAGATCGCTCCATCTGTG 19906 80 6/1 GL261 Cspg4 CAATTCAAGTCCAAAGTCGA 13923 MC38 Plxnbl TCCCGCGGGACCGGAATGCG 19907 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Cspg4 CCAGACCCGCGCTTAGATTT 13924 MC38 Plxnbl GCCGGAAGCTGCCGGGAGAA 19908 GL261 Cspg4 GGCTGTCCAGTACTTAACTC 13925 MC38 Plxnbl CCGAGTTTGTGAAGGGCCTG 19909 GL261 Slc25a53 GAGTGACGAAGGTAGTGGCG 13926 MC38 Phldb2 GGCGGCTACCAAGTCGGCTG 19910 GL261 Slc25a53 AAGCTGCCACGAGATTCTGG 13927 MC38 Phldb2 GCGATAAGGTGGCCGAATGC 19911 GL261 Slc25a53 TGTTGCTGGTTGTATGGAGT 13928 MC38 Phldb2 CCCGACCTCCGCAGAGAGAC 19912 GL261 Mllt3 CGCCCACTGTATATTTAGAT 13929 MC38 Apof AGAGATCTACCTCTGTTTCC 19913 GL261 Mllt3 ACAGTAGTGTCAGATAGAAG 13930 MC38 Apof TTGTGAGGCCACTCAGCAAG 19914 GL261 Mllt3 TCGGAGAGCAAGCATTCTGC 13931 MC38 Apof AGTTTGAGGCCTATTCAAAC 19915 GL261 Gliprll2 GGCTCITAATTGAGAAGAGA 13932 MC38 Taflc GGATGGAAATTTCATAGCTT 19916 GL261 Gliprll2 TTAATCTGTCTTTGGTCATT 13933 MC38 Taflc GTGCTCACTTGTTCGTTGAG 19917 GL261 Gliprll2 CCCTGTGACCTGCCAATCTA 13934 MC38 Taflc TACAGTGCGTGGCTCATCGG 19918 GL261 Cd276 GGCCAGCCGAGTGATAAGGC 13935 MC38 Thsd7a CCCGCCGCCAGCTGTAGGGA 19919 GL261 Cd276 GCTACTTCGATAGCATGTGC 13936 MC38 Thsd7a AGCCGGCCCAGAGCTCTGAG 19920 GL261 Cd276 GGTAGACTTTAGACAGACTT 13937 MC38 Thsd7a TTTCAGCGCACCATGTGCCG 19921 GL261 Calcocol GGGCGGTGATGGACTCAGCG 13938 MC38 B4galnt3 GCCCGCTGGAGAGCGACCCG 19922 GL261 Calcocol TCATGGGCCGTGAAGTCCTT 13939 MC38 B4galnt3 TCGTTCTCCGGCCGCGGAGC 19923 GL261 Calcocol CCTGTGGAACTACATGTCCC 13940 MC38 B4galnt3 ACGCGTCGAGCATGAGCAGT 19924 GL261 Ncorl TTACCTCGGCCTCGCTTCCT 13941 MC38 Spin4 GGAGAGAGCCTGTGTCAGTG 19925 GL261 Ncorl GGAGCTTIGCCTGGAAATTG 13942 MC38 Spm4 GTGGGAATGAACCGGCTGGG 19926 GL261 Ncorl GCCGGGCGGCCGCGCTGAGG 13943 MC38 Spin4 GGTGITGTACTGTCTGGTTC 19927 GL261 Mrgpie CGCTGCTCATTAGAGACAGA 13944 MC38 Zyx TGAGCTGCTTCAGGACCGCT 19928 GL261 Mrgpre CTGTCTAGGCTCAGATACCC 13945 MC38 Zyx GACATCAGAGGCCTGTGCTG 19929 GL261 Mrgpis AACATAGAGGCTGCTGGCCC 13946 MC38 Zyx AGTCAGTTCTCCAGCACTCG 19930 c GL261 Dync2hl TTTGCACGAGAAGTGGAAAC 13947 MC38 Osmr CGGGAAATTGCAACAGTACT 19931 GL261 Dync2hl TCGACCCTGATACTTGATTG 13948 MC38 Osmr CGGGAGTTACGGGAAAGCGC 19932 GL261 Dync2hl CACATCCAATCGATGAGTGC 13949 MC38 Osmr TTGGCACTCCTGGGACCCAC 19933 GL261 Arhgap4 AGACTTTCAGAGGCCCACCC 13950 MC38 Zmym3 GCAATITCCAGGCGGCCACT 19934 GL261 Arhgap4 GACTTGGACCTGGCACTGCC 13951 MC38 Zmym3 GTGGGAAGCGGAGAGCCACG 19935 GL261 Arhgap4 GGCTCAAGGTATCTAGGTAG 13952 MC38 Zmym3 AAAGATAGCCTCTGGAGCTT 19936 GL261 6030419C18Rik GGAGATGAGTGCACGAGGTC 13953 MC38 Rhpnl ACTTGATGTTGTCCAATCAG 19937 GL261 6030419C18Rik GGACCCGGTGTCGAGCACAG 13954 MC38 Rhpnl GAGITACCAGATCCCTTACC 19938 GL261 6030419C18Rik GGGCTCAGCCGAGGAAGCAA 13955 MC38 Rhpnl TGGTAGTAGTTTCTATCCAT 19939 GL261 Zfp879 TGTAGTCCACAGTGGAAACC 13956 MC38 Met GGACGAACAGACACGTGCTG 19940 GL261 Zfp879 GGCTTCATTCATAATTACAA 13957 MC38 Met GGGACAAACCTAGAGCGACA 19941 GL261 Zfp879 CTGCACCATACAGGGTGGGT 13958 MC38 Met CTTCCCACACGCGCCCTGCC 19942 GL261 Adil GGGTGTAGGGCGGAGTTGTC 13959 MC38 Prune2 GGTGTGCCGCCCGGGAGCCC 19943 GL261 Adil TGACCGCTCAGGTAGAATTC 13960 MC38 Prune2 AGCAGGCTGGTGGCGGTCCC 19944 GL261 Adil AGGAAAGGCGTCTCACCCTC 13961 MC38 Prune2 TCTGTCCTAATAAGGAAAGT 19945 GL261 Cngal TTTCAGACAGGTTAGGCGAC 13962 MC38 Asap2 GGGCGGGCCCGACTAGGGAG 19946 GL261 Cngal AGATGAGAATAACAGCCGCC 13963 MC38 Asap2 GCTTCTCGGCGGCGCAGTGG 19947 GL261 Cngal CCACTAGGCAGTATTCCTTT 13964 MC38 Asap2 GCACATCGCCCTCCTTCCTG 19948 GL261 Gja4 GGGAGTGCAGTCTGGGATAC 13965 MC38 Gstzl GGAAAGTGTGGTGGCCGCCC 19949 GL261 Gja4 AGCACAATCTGGGCGGGTCC 13966 MC38 Gstzl GGAITCATCGGAGGCACGAC 19950 GL261 Gja4 CCTGGGAGGGACAGACTCCC 13967 MC38 Gstzl GAGTGACGCCACCCTCTGAT 19951 GL261 Tuscl CCTTGTCTCTCGCGGCTGAG 13968 MC38 Erapl ACTTTGAGTTCCCGAAGCCC 19952 GL261 Tuscl CTCAGCCCTGTGTCCGTGCC 13969 MC38 Erapl CAAGCCTAAGGGATCTAGCC 19953 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Tuscl GGCGGAGGAAGAAAGGTGGC 13970 MC38 Erapl TGATAGGGAATGCATTCTCC 19954 GL261 Tbcld21 CAAATGTAGGGAATCAAGAG 13971 MC38 C8g CTAGCTAGGACTGCCATGTC 19955 GL261 Tb ld 1 CCAGCTAGATGTGTGTCACA 13972 MC38 C8g CGGAAAGTAAGAGTTTGCGC 19956 o GL261 Tbcld21 TCATTGTGATGGCAGTTCCA 13973 MC38 C8g CACAGAACAGTACTCACTCC 19957 GL261 Wisp2 AGGCTCAGTCTGCTTAGGCT 13974 MC38 Gadl AATCACGAGGCCGTTGCTCG 19958 30 GL261 Wisp2 CAAGAGCCTCCCTATCCTCC 13975 MC38 Gadl GCGAITATAAATCCAGCTCA 19959 r GL261 Wisp2 CTAGGCCACCTTCAGAGCCC 13976 MC38 Gadl AGGCAGTCAGACACCTGCAA 19960 o 4 GL261 Frem3 CTGTTAGTTGCTGCAGCTCC 13977 MC38 Dnaicl GAGGCGGAACTTGGGCGCGC 19961 6 1 GL261 Frem3 GCTTGGATCCCGCCAGATCC 13978 MC38 Dnaicl GCGGITACCCAGCAACCGAC 19962 GL261 Frem3 CGCTATGTGTCGGTGTGCTG 13979 MC38 Dnaicl TATCTTTCTCTGCGGAGGCG 19963 GL261 Focad CCTCGCGCGCATGCGTGACA 13980 MC38 Coll5al CATGCAAGTGGGATCTTGGC 19964 GL261 Focad CTAACTGCAGTGAGCCGCCA 13981 MC38 Coll5al GACTTCAACCGCGTAGCTTT 19965 GL261 Focad GCGGGACTGGTTCTTGAAGT 13982 MC38 Coll5al CGGAAGTCATACACAGAGCG 19966 GL261 Itgall CACCGGCTCAGGTGGCAGAG 13983 MC38 Dclrela TTCGGCACGGCAGTGACAGT 19967 GL261 Itgall GTTAGATGGGCTGGGAGTGG 13984 MC38 Dclrela AACCCATTGCCTTTGAAGCC 19968 GL261 Itgall CGATACTGGCGAGGGCGTCG 13985 MC38 Dclrela GGTCGCGCTCCAGAGGAGCT 19969 GL261 Seipini2 AATTAITCCACAACCATAGC 13986 MC38 Limdl TGGCGTCCCTCTCTGGGCAC 19970 GL261 Serpini2 AGCACAGTGCACACCTGCTA 13987 MC38 Limdl GGGCGCGGGCGGAGGCTCGG 19971 GL261 Serpini2 ATAAGCTGCTTCATATAAGA 13988 MC38 Limdl GCGCATCACTGGCCTGCAGG 19972 GL261 Krt23 TGGTAACTGGCATATTCACG 13989 MC38 4833420G17Rik TTACCAGGCGACACTGTCAC 19973 GL261 Krt23 GCACAATGATAGGATCTTGT 13990 MC38 4833420G17Rik TCGGGTGCTCAGTGTCGGCA 19974 GL261 Krt23 GTGTTTCCTCTTGGTCAATC 13991 MC38 4833420G17Rik GGAAGCGCCGAGTTTCCGTG 19975 GL261 Ptchdl GGCAAGACCCTGAGCTCTCC 13992 MC38 Stkl7b TGCTGGATGTAGCCTAGAAC 19976 GL261 Ptchdl AGGAGGGCGAGGCGCACGCT 13993 MC38 Stkl7b GCGCCGAGCGCCTGAAGACT 19977 GL261 Ptchdl GATGGTGGTGCCGCGGCTCC 13994 MC38 Stkl7b CCCTCCGTAATCGCTCCGAT 19978 GL261 Yt d ATGCGCGGTACCGTGAGCGT 13995 MC38 Tmc8 GGGTCACGGGCACAGGTGAG 19979 GL261 Ythdf3 TAAAGTACAGCTGCGCCTCC 13996 MC38 Tmc8 AGGTCGGGAAGTGCACGCAG 19980 GL261 Ythdfi TCCGATGACGTGCACGGCGG 13997 MC38 Tmc8 CTCAAGGGACCCAGAATAGA 19981 GL261 Kdm5a CCCTCCGTGGCTAGTCGGCC 13998 MC38 Rlim TGGGACGCCCACCATGTGAC 19982 GL261 Kdm5a TTAACATCGTTGTCTAGGTT 13999 MC38 Rlim GGACAGACTACCCGCCCAGA 19983 GL261 Kdm5a GAAACGGAGACGCGGAAACT 14000 MC38 Rlim CTGGCCAGCAGTCTGGGCGG 19984 GL261 Neol CTGCCCGCGAAGCGACCGCC 14001 MC38 Tmeml50b CCTAAGGGAACCCGGAGCCT 19985 GL261 Neol GTGCGCGGCACGGCGCGCTC 14002 MC38 Tmeml50b GATTGGGTCTGAAGAAGATA 19986 GL261 Neol GGCGCGAAGAGGGTGCTCGT 14003 MC38 Tmeml50b GAAGGCAGGCCTCCGAATTC 19987 GL261 Ceacaml3 GTGTAGAGAACAGGAGATAG 14004 MC38 Fryl TGTAGTATCCTTCGCCAATC 19988 GL261 Ceacaml3 ATTATGAGAGCAAAGGAGAA 14005 MC38 Fiyl CCTCGCCTCCAACGTTGCTT 19989 GL261 Ceacaml3 ATTGTAGTCTCCTCCCAGGT 14006 MC38 Fryl TAGAGGTAGGTCCAACCCGG 19990 GL261 U l7 GCTGGACGGCCATTTATAAG 14007 MC38 Clcal TACTGGAGGTGATTTATTAT 19991 GL261 U 7 TGGCAATGCTTCCGGGTCCT 14008 MC38 Clcal ACATTTGCCTACAATATAAG 19992 GL261 U l7 GTGCGAGCACGAGCAGTTTG 14009 MC38 Clcal TTTAACCTCTTGACCCTAAA 19993 xi GL261 Ms4a4b GGAGGAAATGTCAGAGGCAA 14010 MC38 Trpv6 CTGGGTATCCCAAAGTCCAG 19994 o GL261 Ms4a4b TCTGCCTCTTAGTCAGTGGG 14011 MC38 Trpv6 CTTTGAAGACCTAAGAACAG 19995 30 GL261 Ms4a4b TATGATGGCTGAGATGGGTG 14012 MC38 Trpv6 AGAGAGTTGCAGCTGACGCA 19996 GL261 CcdcllO GTCTGCATCAGCTCCGGAAA 14013 MC38 Pgam2 CCAGGTGCCAGCTGGTTATG 19997 GL261 CcdcllO TACTAGGCAACGGGATGCTG 14014 MC38 Pgam2 GGCAACCAGTAGCAGAACTG 19998 30 6/1 GL261 CcdcllO CACTCAAGCTCTGCTTCCCG 14015 MC38 Pgam2 GCAGAACTGGACCAGGGTGA 19999 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 GGAGTTCCACTCACCTGCTC 14016 MC38 Pkd211 GGGAGCAGGAAGGATGCAGA 20000 GL261 TGTGTGTGTACACGCTTGGG 14017 MC38 Pkd211 AGAGAGAGAGAGCTCATTGA 20001 GL261 GTTCTCCTGGTCAAGTCAGG 14 1 MC38 Pkd211 TGTTATGCAGACAGACTAGA 20002 GL261 CCAGGTGACCGGCAGGGCTC 14019 MC38 Bcor TCGAGCGCTGCGCCTGAGGG 20003 GL261 TAACAATGTCCTGCGTTTCC 14020 MC38 Bcor CTTGCGAGAGCTGGAGGCGG 20004 GL261 TTGCCGGAGCCGCCTCGAGG 14021 MC38 Bcor GATAGTCTCCAAACTCACTT 20005 GL261 CGAGCGGGCGGTGTTACGGG 14022 MC38 Crtc2 TGTTGTAGAACTACCTTTCC 20006 GL261 ACCCAGAGCATCTGAAGAAG 14023 MC38 Crtc2 TCCCAGCAGTCGTGTGACCC 20007 GL261 CGGACTGGGCTAGGTTAGAG 14024 MC38 Crtc2 GTGCGCCGGGAGTAGGTGAG 20008 GL261 ACTAATTGGAGCCCATGAGA 14025 MC38 Dnahl TAAAGAACCAGACCTCTTGG 20009 GL261 GAGTCTTCAAGAGAGCTCCT 14026 MC38 Dnahl CGCCCACCTACAGACCGGAC 20010 GL261 CCTAGAAGGAATGCTAACAG 14027 MC38 Dnahl GGCGGGACCATTCGGCACCG 20011 GL261 ATAAACCAGTTTACCCGGCA 14028 MC38 H x l AATCCTCCCGCAGAAATTGC 20012 GL261 ACCGATCCGTCTCTAGGCAG 14029 MC38 H x l TTGCGTCTCTTGCGTCAAGA 20013 GL261 CGTGACCACAGCCTATGCCG 14030 MC38 Hoxbl3 TAAATCGCTCCCAGCTCGAA 20014 GL261 TGGCATCTCAGGTTGCAGCC 14031 MC38 Dusp9 TGGTGGGAGTTGCAAGCCGC 20015 GL261 TTGGCTGTGCATCTTCAAAC 14032 MC38 Dusp9 CCGACTAAGTAGCAGCTCAA 20016 GL261 CTCCTGTATCAGGAGAGCAA 14033 MC38 Dusp9 CTGAGCTAGGGCTTCCACCC 20017 GL261 TGCAGGACAGCATACACCCG 14034 MC38 St8sia6 ACTGTTGCAGGCTGGGCTCT 20018 GL261 GAAGAGAGAATTCAACCGCA 14035 MC38 St8sia6 CGAGCCGAAGAAGCCGCGTT 20019 GL261 AAAGGATGTAAACTTTACAG 14036 MC38 St8sia6 CCACCGCCTTTGAACGCTGG 20020 GL261 TAGTCTGACCTGTCCTCCTC 14037 MC38 Cntnap2 CAGCCACAATGAAGTACCCA 20021 GL261 TTCCTAGACAGCCGTGCTCC 14038 MC38 Cntnap2 CTGGAGAGCACTCAGACCGC 20022 o GL261 CGGGCAGTCCAGAGACGCTG 14039 MC38 Cntnap2 GAGACGCCTAATACATGGAC 20023 GL261 TGATGTGTAGTGTTGGCAAG 14040 MC38 Rtfl AACGGCGTGCGCCAGGCGGG 20024 GL261 CTTCGCGCCCACCAATCATC 140 1 MC38 Rtfl TCCGGAAGCTTCTGCAGTGT 20025 GL261 GAACGCTACCGCCAGCTCCG 14042 MC38 Rtfl TAGATCAGGGAGCGTTGGTC 20026 GL261 GGGATTGCTATCGCTTTAAA 14043 MC38 S f CCCGGGCCGGAGCCCGTAGG 20027 GL261 CGTGATGATGCAAACCGGTG 14044 MC38 Shf GAGCACCTGGGCTITCGCGG 20028 GL261 GAGAGATGGATAGCAAGCAA 14045 MC38 Shf TGGAGTCGCAAAGTGGCTGC 20029 GL261 CCGGTCCGCTTCCGGCCTCG 14046 MC38 A4gnt TAAAGGGTGTGTGTGTTGGG 20030 GL261 ACACGCTTCACACTTCCCTT 14047 MC38 A4gnt CACAGAGGAAAGTAAATTAT 2003 1 GL261 AGAGAGCAGGCCGGAAGAGG 14048 MC38 A4gnt ACACACTTGTCAAGCCTGCT 20032 GL261 GCCTGGGAGGGTCTACCTAT 14049 MC38 Fail CTGTCATCGAGGTCGCAAAG 20033 GL261 AGAGGCGTGGTCTTGCGTAG 14050 MC38 Fail TGCCCTCCTGTCAAGCGCTT 20034 GL261 GGGTACAAAGGTGCCTAGTC 14051 MC38 Fail GGTCGCCGGCCTGTGTGGCA 20035 GL261 ACCTCCCTTGGATCTCGCCC 14052 MC38 Zzz3 GGGAAGCTAATCACTACTTC 20036 GL261 TAAACAAGCCCTTCCGCTGC 14053 MC38 Zzz3 TAGGTGGCGCGCCGAGCGCC 20037 GL261 TCCTGCGGAGCGCTCCTAGA 14054 MC38 Zzz3 TCCTCCACTTCCCGCAGCAG 20038 GL261 CACCCGTCACCATAGCAACG 14055 MC38 Phf l CTAGTTCTTAGGCAGATGGA 20039 GL261 GTGAGGGCCAGCCGGAGCCT 14056 MC38 Phf l TACTATGGAAATCAGAGTAC 20040 GL261 GGGTTCCCACGGTGCGGCGA 14057 MC38 Phfl4 GCCCTCAGCTTCGGCTGCCC 20041 GL261 GCTGCACGAGCTAGGTCCGC 14058 MC38 Neb AGGCATGTCTCCACCAAATA 20042 GL261 GAGCCGCGGCTTCAGGCGCG 14059 MC38 Neb CGCAGCTCTCATGATGGTCG 20043 GL261 CCCAGTGGAAGTCGTGACGT 14060 MC38 Neb GCAGGCCATGTCAACTCACC 20044 GL261 CGGAACCGTGGTCCCACTTC 14061 MC38 Ube2o TGCCGCCGTCGTTAGGGCGC 20045 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Isg2012 GGCAAGTGCGCCTTGTTCTA 14062 MC38 Ube2o GGCTCCTAGCAACAGCATCC 20046 GL261 Nktr ACTCTCGCGACGCTTGCGTC 14063 MC38 Ube2o CAGGCCTACGTCAGCGCGCT 20047 GL261 Nktr CCGCGAGATTTCTGATTGCG 14064 MC38 Atp8bl CTGCTTCAGTGACACGATCT 20048 GL261 Nktr CGTGTGCGAGCTGTCAACCA 14065 MC38 Atp8bl GGAGGCGAGAGGCTCCTCCC 20049 GL261 Pent GCGATAGGTAGCACCGCCTC 14066 MC38 Atp8bl ATCGAGGGAGGGCGGACGGC 20050 GL261 Pent CGATGTGTTTCTGCGAACAC 14067 MC38 Usp8 TCCCTCCCTACGGGACAGAA 20051 GL261 Pent AAACGACTTTGGCAAAGTGC 14068 MC38 Usp8 GAACCGGCCTGAGCATGCGT 20052 GL261 Adm2 GCTGGGCAGGAGTAGCCACC 14069 MC38 Usp8 AAAGAGACGCGCGAGGACAC 20053 GL261 Adm2 GAGCATTTCCCAGCAAGGAT 14070 MC38 Notchl GCAGAACCCACCAAAGCGCT 20054 GL261 Adm2 GAAAGCAGTAGAGCCACAGG 14071 MC38 Notchl AGATCCTTAGATCCTGGCTC 20055 GL261 Adgrg2 GGGCGAGCGCTCAGTGTGGC 14072 MC38 Notchl ACGCGCTCCCTAGCCCGGAC 20056 GL261 Adgrg2 GACACCGGGAAGCAGCCTCG 14073 MC38 Itgae GGGAAGCTGAGTACTTTCTG 20057 GL261 Adgrg2 AAGTGGTCCGGGAGCGGCGG 14074 MC38 Itgae ATGCTTCTGTCTCCACCTCC 20058 GL261 Tmem225 GAAAGAGCTACAATGTGATG 14075 MC38 Itgae ATAAGGGACCACAGGCCCAC 20059 GL261 Tmem225 GTTGGTITGACCCTTGACCT 14076 MC38 Napll2 ATGGCTGATTCCTCCACCTA 20060 GL261 Tmem225 CTAGGGCATTGGAACCACTA 14077 MC38 Napll2 AGAGAATCTGGGAAGGCAAG 20061 GL261 Dtx2 TTATATCTGCTGGTGTGCTT 14078 MC38 Napll2 ATCTACTAATTTACTGGCTC 20062 GL261 Dtx2 AATGCATCAGTGATTAGCGA 14079 MC38 Pcdhb3 AGGGTCAAGAGATTTGATAA 20063 GL261 Dtx2 ATTATGTGTGTATATTCTGG 14080 MC38 Pcdhb3 TGTGCCACACAAGTTAAACT 20064 GL261 Qpct AAAGAGTTTACCAGGCCCTG 14081 MC38 Pcdhb3 TACTGAGAACGAACGCATGG 20065 GL261 Qpct TTTGTGCAATGCTCTGTACA 14082 MC38 Kcnmal CGGGCCGGCCGGCAGCCCGG 20066 GL261 Qpct CGTATCTATGGACTACAGGA 14083 MC38 Kcnmal GGAGGGCGGGCGGCGGCGCT 20067 GL261 Pnrc2 TGTCATGGTTTGAAATCCTG 14084 MC38 Kcnmal GGCGCTGTGCGCGACCTGGC 20068 GL261 Pnrc2 AGGAGCATGTCGGGAATAAC 14085 MC38 Pcdhl5 GCCCTCCGCAGCGTGAACAG 20069 GL261 Pnrc2 GGCGGTGGCTGGCGTCTCAT 14086 MC38 Pcdhl5 CTGCATGCTTTGCACCAATT 20070 GL261 Kcnh4 CCGGTGCGGAGCCACGTGGT 14087 MC38 Pcdhl5 GTTGGATGTGCTAAGCCACG 20071 GL261 Kcnh4 AGGGCTTCGGGTGTCTCTGG 14088 MC38 AtfiS CAGCACTTTCTGTCCCGCTG 20072 GL261 Kcnh4 AGCGGCCCACGCGTGTCTCT 14089 MC38 Atf6 AAATAAGCTGAACGCTGACA 20073 GL261 Ne AGGTCTGCACTTGTCCGCTC 14090 MC38 Atf6 TGAGTAAATATTTCCCTACG 20074 GL261 Nefh GGGACGACCCAGGAGTGAAG 14091 MC38 Zfhx2 TAATCAATGCTATTTGGCTG 20075 GL261 Nefh ACCAAGGAGTAAAGGACTTC 14092 MC38 Zfhx2 CATCTCCGTCCCTGACGCCC 20076 GL261 Ai AGGTGTGTTTGACAATGAAT 14093 MC38 Zfhx2 TAAATAAATTCACGGCGGTG 20077 GL261 Aiml AAAGCTACTGCGAACCACCT 14094 MC38 Tnfrsf21 TTCCTCCAGCTAACGCCAAG 20078 GL261 Aiml TAGTCGCGTGCTGCCACACC 14095 MC38 Tnfrsf21 TCAAGGCGCTCCAGAAACCG 20079 GL261 SlC 2 GGTCACTGTCCTACACAAAT 14096 MC38 Ttrfrsf21 CGACCCTTTGTGATGTCACC 20080 GL261 Slcolb2 TGATGATTAACTATCTCTTC 14097 MC38 Rhov GACATGCAGATGAGGTGGGC 20081 GL261 Slcolb2 TAAAGTGGGACTTTCAGATC 14098 MC38 Rhov GCCCGCTAGAGGCTGACAGA 20082 GL261 Jmjdlc GAGAACGAGTACTTGGCTTA 14099 MC38 Rhov CCAGGCTCCACGAAGGTACA 20083 GL261 Jmjdlc GGTGATTACTCATTTGGCTG 14100 MC38 Entpdl AGTACGCGACTCTTCTTCCC 20084 GL261 Jmjdlc CCTCGGCATGGGCGGCCGGT 14101 MC38 Entpdl ACGGGAACCACGCGCCGCTA 20085 GL261 Smurf 1 TACGCGGACCGCGCTTGTCC 14102 MC38 Entpdl TAAAITAGCCAGCCCGGTTT 20086 GL261 Smurf 1 AGCTGCAAGGTTCCTGCAGC 14103 MC38 Emcn GGTCAGGATGGGATTTGAAC 20087 GL261 Smurf 1 CGCAAGCGCGAGGCCGCGCA 14104 MC38 Emcn ATACACGCACTCCCTTTGGG 20088 GL261 Siit6 AGGCACGTATCTAGGGAAGG 14105 MC38 Emcn GAAGAGACCCTTCTTGAGAA 20089 GL261 Sirt6 GGGACTTCCCTGGAAGGAGG 14106 MC38 Adtrp AGAGGGTTGGGTGAGTTCAG 20090 GL261 Strt6 GAACACTGCAGCTCTCACCT 14107 MC38 Adtip GTAAGGTGGCGATCTGGGCC 20091 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 AI4641 1 CCACATTGGACGGCTGGGAG 14108 MC38 Adtrp TCGGTGGGAGTGGATGATCA 20092 GL261 AI464131 GTGCAAGGCACGCAGAGTGG 14109 MC38 Xpnpepl TGGTGTTCTGTGCAACCAAT 20093 GL261 AI464131 GGGCCCAAAGGGCAGATCTG 14110 MC38 Xpnpepl AAGCAACAGCCCAAAGGTTT 20094 o GL261 Se a6a CACTGGAGAGGCCGACGCTC 14111 MC38 Xpnpepl CCCACTCCGGTGAACGGGCG 20095 GL261 Se a6a CAGGAGTAGTGTGCCGCACG 14112 MC38 Tsrl GAGAGATGGAGGATGCCGGC 20096 GL261 Sema6a TCCGACCCGAAGGAGAGCTG 14113 MC38 Tsrl GACGTCTCTGCGGACACTCA 20097 r GL261 Nr3cl CTTTGTGGATGGGAGCAGGG 14114 MC38 Tsrl GACCCGAGCGTTTCCGGCCC 20098 o 4 GL261 Nr3cl GCCTATTAAATAAACCCTTT 14115 MC38 Fasn TGCTCCACATCGAAACCAAT 20099 6 1 GL261 Nr3cl TAATCGGATCAGAGATAATG 14116 MC38 Fasn AAGTGCTTTGCCGCTGTTGC 20100 GL261 Iqsec3 GGGTTCCTCACGAAGCCCAG 14117 MC38 Fasn GTTGCTAGGCAATAGGGTGA 20101 GL261 Iqsec3 GGGCGTAGGAGAGGCGGGTG 14118 MC38 Ifnal GTGAGTGTTGCCAAAGCTTC 20102 GL261 Iqsec3 GTGTGCGAATGCCTGTGTGG 14119 MC38 Ifnal ACTCATTCTCTGCTTGCGTC 20103 GL261 Hexa GGAGGGTCACGTGAACGGGA 14120 MC38 Tmprss6 AACACAGGTAAACAGGCAGG 20104 GL261 Hexa AGCGGCGCCCGCGTGACAAT 14121 MC38 Tmprss6 TTTCCCATTCACCCTGTTAG 20105 GL261 Hexa TCTCAGAGATCCGTAAGCAA 14122 MC38 Tmprss6 TATCACCAAGCAACAGGCCC 20106 GL261 Rfpl4 ATGTTCTCTCATCAGTTAGA 14123 MC38 Btbdl6 TCAATAAGGCACAGGAATGG 20107 GL261 Rfpl4 GAATTAAGAAGAGACAGGTG 14124 MC38 Btbdl6 GTCACTAGCATAACCATGCC 20108 GL261 Rfpl4 GAGTGGTACCCACCTCCATG 14125 MC38 Zfpl89 TTGGCTGAGTCGGGCACGTC 20109 GL261 Frmd3 GCTAGCTAGGAAAGGAGGCG 14126 MC38 Zfpl89 CTTGGGTTGCTTGTCGAGAA 20110 GL261 Frmd3 AGAGGGCACCTCCCTTGGCT 14127 MC38 Zfpl89 GTGTCTCGGTTAGCAAGAAG 2011 1 GL261 Frmd3 CTCGCGGTTGGAGGAGGCAC 14128 MC38 Zbtb3 CCCACCTCCGCTATCTTAAT 20112 GL261 Tubb6 CCCTCCCAAAGACTAGCGGG 14129 MC38 Zbtb3 GGCAATCCCTGCCATTGCTC 20113 GL261 Tubb6 TCCCGACTGCGGCGTGACTG 14130 MC38 Z b 3 GAGCTCTCCTAGTAGCTGCT 20114 GL261 T b 6 ACAGCCAGCTGCTATTGGAG 14131 MC38 Dnajcl AGCTGCACGTGTGTCAGCGC 20115 GL261 Bik GTAGCTACTTATTGGGACCG 14132 MC38 Dnajcl AGAGAACAGCTTTCCGTGGC 20116 GL261 Bik AGCAGGTCTACAGGCGACAG 14133 MC38 Dnajcl AGGTGAATAATCAACAATCG 20117 GL261 Bik TGGAGGCGGGTTATTGTGAG 14134 MC38 Ppp4rl CCGAGGCGCGCTCCCACCCG 20118 GL261 Rgs9 AGTGCATGCTAATGAGCGCG 14135 MC38 Ppp4rl GCGCCCTGGCGCCGAGCGTG 20119 GL261 Rgs9 TCCTACCTGAGGTTTGGTCC 14136 MC38 Ppp4rl GCGCGGCACGAGCTGCCCGC 20120 GL261 Rgs9 TAGCTTCAGCATCCCTGATC 14137 MC38 Tcn2 TAAGCGACGTTCCTAGTTCA 20121 GL261 Ncmap GAGCGCTGGGCAGGTGATGG 14138 MC38 Tcn2 GAGACTTGTTTGTCTGGGCC 20122 GL261 Ncmap GTCACTAGTTGGGAGGGATG 14139 MC38 Tcn2 AAGGAAACCCAGGCTGTGTC 20123 GL261 Ncmap AGCCGTCCAGCGCTCACCGC 14140 MC38 Hsh2d AAGCCAGCTCAAGAGCCCTT 20124 GL261 E212 AAACTATATGCCGCCAAATT 14141 MC38 Hsh2d AGTAAGTACTGAGCAAGGCT 20125 GL261 E212 CTTAGACTAAGCCTTTCCGG 14142 MC38 Hs 2d CAGGAACTGACTGAGGCTCC 20126 GL261 E212 TGTAGCAGCCAATCGAGGCG 14143 MC38 Bfsp2 GTGCCTCTCACAGGCTGGTG 20127 GL261 Ddo TCTCTAAGCTTACCCTCCAT 14144 MC38 Bfsp2 CTACTGCCTTCCATGAGCTT 20128 GL261 Ddo TTACACGTGCCTCTCTCCTG 14145 MC38 Bfsp2 GGGTGTAGCAGTGCAGCCTG 20129 GL261 Ddo TGCCTCTCTGCCAAGCCTGC 14146 MC38 Ago2 AGGCTGGAGGCGGCGCGCGC 20130 GL261 Krtapl6-1 ACAGGGCCCAAACAACAATG 14147 MC38 Ago2 GGCGAGAGGGACGACGAGGG 20131 v > GL261 Krtapl6-1 CGCCAGTGAGGGAGTATAAA 14148 MC38 Ago2 AGGGAAGGTGGCAGGGAGAG 20132 o GL261 Krtapl6-1 ACTTCTAGATCAACACATGT 14149 MC38 Osbpl3 TTTCACGTTATTCCGCCCAG 20133 GL261 Zfp3612 CGACCAATGAGAAGCCGAGA 14150 MC38 Osbpl3 AGGCGGTGAGGCGTTGGACT 20134 GL261 Zfp3612 GGGACTGAACGCTGACCGGC 14151 MC38 Osbpl3 ACTCACCAGCTACCAAGCCC 20135 GL261 Zfp3612 TATAAAGGGCGCACGCTCTC 14152 MC38 Nifill CCTCACAGTGCAGAGGTGAA 20136 6/1 GL261 C2cd2 TTACAGCTCCGCCTCCTTAA 14153 MC38 NiCll AATGAAGAGGTCAGATGACT 20137 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 C2cd2 GGGAACTGTGCGCTGGCGCG 14154 MC38 NiCll ACTGACCCAGAGTCAAACAG 20138 GL261 C2cd2 GTGCCTCGCTTGGCGCGCCT 14155 MC38 Agl CGAGAGGTGGGCACGGCTTG 20139 GL261 Zc3hl2d CTCAGTCCCTCAGGAGTTGC 14156 MC38 Agl ATGGCTCCCGGAAGTGGGCG 20140 o GL261 Zc3hl2d TCAGAGGAGGGCCAGCGCCC 14157 MC38 Agl TCAGTGGTCTGTGCTAGCGG 20141 GL261 Zc3hl2d CTTGGATCAGCTTCTAGCAG 14158 MC38 Nop2 TGCTAGGTGGAAGGAGCGTG 20142 GL261 Rimbp2 CCTTGATGCAGGCAGGGCTG 14159 MC38 Nop2 CCCTCACCCGCGGTTCAGAG 20143 r GL261 Rimbp2 TGAGAGACACCGGCAGGGAA 14160 MC38 Nop2 TCCCTGGATCACGTGTGTTC 20144 o 4 GL261 Rimbp2 TGCACACACGCATCCCAAGA 14161 MC38 Pebpl CGTTAACAGCGCTCGGGACT 20145 6 1 GL261 Gucala CCACCAGATCCTGTTAAGAA 14162 MC38 Pebpl AGGGTCACTGCGAAACTTCG 20146 GL261 Gucala GGCAAGAGGCAGAGCATTGT 14163 MC38 Pebpl TGCGCAGTTGACTGCCGCCC 20147 GL261 Gucala CTCTCCGGCATCTCTAGTTT 14164 MC38 ffit3b GACTCAGAGGATTATATAAG 20148 GL261 Pttgl CGAGCACGACAAGAGCGCCT 14165 MC38 Iflt3b AAATCTCAGTCCACTCTAAG 20149 GL261 Pttgl CAATTGGTCCCTCCGAGAGG 14166 MC38 Metml GCGTGACACCAGGGCGTTCC 20150 GL261 Pttgl GGGCGTCTTGGGCGAGCTTG 14167 MC38 Metml GCTGGCAAGTTCCCGGACCG 20151 GL261 Z 4 GGACGCTGCCCGGCCCAGGC 14168 MC38 Metml GATCTGTGAGCTGGCGCACG 20152 GL261 Z 4 CCTGACCTGTCGTCAGGGAG 14169 MC38 Mgat5b TCCGGTCTGCTGGATGCCCT 20153 GL261 Zc3h4 GGGCCGGGCCGCGGAGGAGG 14170 MC38 Mgat5b AAGITGCATGGTCCAGGGAG 20154 GL261 Kcnj8 GGCCAGACCTCCGAGCGAGC 14171 MC38 Mgat5b TTCCCTCTGAGGAGGCGGCC 20155 GL261 Kcnj8 GCTGAGGAGCTGGCGGAGCA 14172 MC38 Dctppl GAAGAACTCGAGGGCACAGA 20156 GL261 Kcnj8 TGGAAGATGAGGGTTGGGTT 14173 MC38 Dctppl ATTGGTCAGAACTCTGGAGG 20157 GL261 Rab22a GGTGGCTGCCGAAGTGGGCG 14174 MC38 Dctppl ATTGGTTCAGGCCGGAGAAG 20158 GL261 Rab22a GCGGGTGGGCGGAGCACCAA 14175 MC38 Pygm TGAAGCTCAGGGAGCTATTT 20159 GL261 Rab22a GCGGCCGGCTCGCAGCTCAC 14176 MC38 Pygm GGCAGCATGCCACGCCTCCC 20160 GL261 Fscn2 AGCCACTGAAATCCAAGCTG 14177 MC38 Pygm GGGATTTAAAGCCTGGCTCA 20161 GL261 Fscn2 ACTCTGGACTTGGTGCATCC 14178 MC38 Gprl61 GGAGATACAAATTTCTGACC 20162 GL261 cn2 GTTGGCTACTGCTTCTAAGC 14179 MC38 Gprl61 TTCTGCTGAAGACATAAATA 20163 GL261 Ac l l GACTCAGAACGGACCTATCT 14180 MC38 Gprl61 ATGGAGATCTTGAGGAATAG 20164 GL261 Acyrll CAACTAACTGTCAAGCCTTG 14181 MC38 Tas2rll8 TCCGTTTCATATTCGGAAAG 20165 GL261 Acvrll CGCCCnTGGATTCTCCAGT 14182 MC38 Tas2rll8 TATGTCAAATGTGTGTAAGG 20166 GL261 Radii GGCAGAGACGGAGCCTCGAG 14183 MC38 Tas2rll8 CTTAGCACTCTCAGTATAAG 20167 GL261 Radii CCTATCTTTCTCGGTCGGCC 14184 MC38 Siglech GGGTGTGGTTCAGAGAATAA 20168 GL261 Radii CACATGTATTAGGGCGGGCC 14185 MC38 Siglech GCAGATAGGAGGGAAGACTT 20169 GL261 Isir AACAGGCCACAGAGTGGGAG 14186 MC38 Siglech CTCTTTAATGTCTGACTGCT 20170 GL261 Isir AAAGATGAGGCCAGAAAGTT 14187 MC38 Shroom3 GGGTCTCCGCAGACTGCTTT 20171 GL261 Isir GAGGTTCTGTGCAGTGCGGG 14188 MC38 S ro m3 CGGACGTCCCTGACATCAGG 20172 GL261 Zcchc5 TAGGATGCTGCGCCAATGTG 14189 MC38 Shroom3 CTGGCTAGAACCAAGAGAGC 20173 GL261 Zcchc5 AGCTTCGTGCACTCAGTCCT 14190 MC38 Fam45a GACGGGACTTGTTATGGGCG 20174 GL261 Zcchc5 CCTCACAGTTCCGAGCTAGA 14191 MC38 Fam45a AGGTACTAGACAAACGAACA 20175 GL261 Sycell CGTGCCACTATAGACATTGT 14192 MC38 Fam45a TCAGTGAACGGACACTTCAC 20176 GL261 Sycell CCGAGTCTCTATAAGAGGGC 14193 MC38 Serp CAGAAGACCCTTTCCCATCA 20177 v > GL261 Sycell GCACGCATGCGCGCAACCAC 14194 MC38 Serpinf2 TAAATATTGACCTGTACATC 20178 o GL261 Gm 2 CCCAATTTGGCCTGCACCTC 14195 MC38 Serpinf2 ACTGAACACAAGCTGAACGG 20179 50 GL261 Gmr2 AGTCCGGAGGAACGGAGGAG 14196 MC38 1700006AllRik GCTGAAATCTGAAGATTCTG 20180 GL261 Gmr2 GGGCAGGCTGCGATTGAAAG 14197 MC38 1700006AllRik ACTGTCATGTCAAGACCATG 20181 GL261 Tas2rl 13 AAACAATACCCAAACTTCTG 14198 MC38 1700006AllRik ATAACTGACCAAATGACACA 20182 50 6/1 GL261 Tas2rl 13 AGCAGTTACCTCAGAAGTTT 14199 MC38 Tmem28 GGCCGCATGGCTAGGCAGGC 20183 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Tha |j4 TACGGCGGTGGGCACGCGGG 14200 MC38 Tmem28 GCGAGGCCGGACGGCCGTCT 20184 GL261 Thap4 GTGTGGTTCCTAACCGGACG 14201 MC38 Tmem28 CCCGCTCAGGCCGTTGTGGC 20185 GL261 Thap4 GCAGTAGTCCGTCGGAGCGA 14202 MC38 Dytn GTACTGCTCCCTAAGCTCTA 20186 GL261 4930503L19Rik TTTCTCTGGGTCGGGTAGGA 14203 MC38 Dytn CTTGCTCCCAGCAGAACTGG 20187 GL261 4930503L19Rik GGCGTTAGGTCGCCGTCCTC 14204 MC38 Dytn ACATGAAACTAATACGGAAA 20188 GL261 4930503L19Rik TACACATGCGCCCTGCGGCC 14205 MC38 Cammtl AGCGCGTCGTAGCGGAAGCC 20189 GL261 Gart AGCATCATCAGCTCTAATCG 14206 MC38 Caramtl GTCCGAATACGCTTAGAGGG 20190 GL261 Gart GTTCCTCCCGCCTTAGGGTG 14207 MC38 Cammtl GGGCCACGAATCTGGCCCGC 20191 GL261 Gart AGCCGAGTCCATCGGAGGCG 14208 MC38 Phlppl GGCGATCCGGAGCATTCCGT 20192 GL261 Sikl TTTGACGCCAGAGCGACGCG 14209 MC38 Phlppl AGGCTGTCCAGCAGCGGGCG 20193 GL261 Sikl TGGGCTGTGCCTGCCGCGGG 14210 MC38 Phlppl GAGCTCGGGCCGCAGCTCCC 20194 GL261 Sikl TCGGGCGGTTGCCAAGAGAC 14211 MC38 Pgpepl CCAAGCGCACCACTACACCC 20195 GL261 Arhgap26 AGGCATGAGATCCAACTGTA 14212 MC38 Pgpepl GGGAGCGTACAGCTGGTCGG 20196 GL261 Arhgap26 TTGGGTTCTATAAGAAGAGC 14 1 MC38 Pgpepl ATGGCCTGGCCCGGGCGTTG 20197 GL261 Arhgap26 TTCTCAATTAGCAATCAAGG 14214 MC38 Ank3 TCAACACATGTGTCCTCTGG 20198 GL261 Prapl AGGTCTTAGAACTGGCAGGT 14215 MC38 Ank3 TTGTTCTCGGCTGGGAACAC 20199 GL261 Prapl TCTGCTCACGCTACATGGTG 14216 MC38 Ank3 CAGAGCATTTACATTCGGCT 20200 GL261 Prapl ACATGGGTGTGTCTGACCAG 14217 MC38 Lrrc45 GGGTCGCGTTCCACGTTCAT 20201 GL261 I122ra2 CCATTAGAGAATATAGAGAG 14 1 MC38 Lrrc45 GGTAGACCAATGAAAGTGAA 20202 GL261 I122ra2 CGGAAGTGACGGTCCATTTG 14219 MC38 Lrrc45 ACGCITGGATGATTGGCTGC 20203 GL261 I122ra2 AAGGAAACATTTGCCATTGG 14220 MC38 Pde6b AGTCTTTCTTAGTGATGATT 20204 GL261 If g TTAAGATGGTGACAGATAGG 14221 MC38 Pde6b TCAGGCGAGCTGGGACTTCC 20205 GL261 Ifng ATACCTGATCGAAGGCTCCT 14222 MC38 Pde6b GCTGACTCATACCACATGAG 20206 GL261 Ifng AGAGTTTCCTTTCGACTCCT 14223 MC38 Ill lral CCCGTCTGGAACTTAGAGGA 20207 GL261 Npclll TTCTCTTCCCTTACATCAGA 14224 MC38 Ill lral GGGAGGCCTCTTTCCTTCCC 20208 GL261 Npclll GACGCAACTGAAGTCTAATG 14225 MC38 Ill lral CTAAGGAACGCAGCAGTTTC 20209 GL261 Npclll CCAATAGGACTGGGCCGTAC 14226 MC38 Kcnhl AGCACGGTGAGCAGCTTTAT 20210 GL261 Adcyl CGCCGCAGAGGACCACTGCC 14227 MC38 Kcnhl CCTACCGTGCGCGCATCCCT 2021 1 GL261 Adcyl CCCGGGCGCTGAGTTGGGCG 14228 MC38 Kcnhl ACAGCCGTAACCAAGAGCCA 20212 GL261 Adcyl ACTCTGTCCGCCCAGGATCG 14229 MC38 Hars ACCTGAGATCGGAGTTAGTT 20213 GL261 Acsm5 CTGCAAGATAAACCTTGGCC 14230 MC38 Hars GATGGTGGGATTGAACACCG 20214 GL261 Acsm5 ACACTAGTACACGTGCTCCC 14231 MC38 Hars TCTGGAAAGCTACCGAGAGC 20215 GL261 Acsm5 GGAGTCAGCCTGTTAGGGAC 14232 MC38 Slc35gl TCCTCTGTCTTTGCACAGAC 20216 GL261 Zfp691 CACACTGCACAAGACCTAGT 14233 MC38 Slc35gl GGACGCTTGGTTCTCAGCCC 20217 GL261 Zfp691 TAGAGAGGAAGAACGTTCCC 14234 MC38 Slc35gl TGTCTAGCCCGACTGCCCTG 20218 GL261 Zfp691 GACTCTAAAGACACGGTGTG 14235 MC38 Irx3 TCCTTCGCAGTCCTGGACGC 20219 GL261 V CATGGGAAACCTACTGTCCC 14236 MC38 Irx3 CCTGGCCGCTTCCGCTCCCG 20220 GL261 V l CCCTTTAGGCAGCCAGGACC 14237 MC38 Irx3 TTTGCTCTTTCTGTTTCTCA 20221 GL261 V f GGCCTTCTCTTAATTACCAG 14238 MC38 Lrpl GACAGGGAGAGGAGGGAAGG 20222 GL261 Mtmr3 CTCCGGCGCGCTGTCCGCTG 14239 MC38 Lr l ATCAGCGCATGCGCACTGTC 20223 GL261 Mtmr3 GGCTGCAAGTCACCAGACTG 14240 MC38 Lrpl CTGATTTGGCGCGCTGCCCT 20224 GL261 Mtmr3 GAAGACTGGCCGTCACGGGA 14241 MC38 Kifl8b GGTGGCAATTCCGCTCCGTC 20225 GL261 Fbxol7 GCAGAGACAGGATCGGTTCT 14242 MC38 Kif l CACTGCTAGAGACTCGATTC 20226 GL261 Fbxol7 TTTACCCTGACGACGGTGTT 14243 MC38 Kifl8b ACTAGITCTCTTGCGCGCCT 20227 GL261 Fbxol7 CCTAGCGAAAGGCTCAGCTG 14244 MC38 Inpp5d AGTTCCACACGAGGGACGCA 20228 GL261 Tdpozl GTGTCTTCTAGTCTCAAAGC 14245 MC38 Inpp5d GGAGGTTAGGTCCCATTCAG 20229 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Tdpozl CCAGTTCAAATACAGACTCC 14246 MC38 Inpp5d CGGCTGATAATGGACGCTTC 20230 GL261 Tdpozl TAAAGGTGTGTGTTTCTACC 14247 MC38 Tmem201 CCTACGGAAGCCCTCGGCAC 2023 1 GL261 Shcbpl AAGTTCTTCCCAGTAACAAA 1424S MC38 Tmem201 GCACTCACCTCCGCGCAATC 20232 GL261 Shcbpl GAGATGTCGTCATCGCGTTC 14249 MC38 Tmem201 CTCCTTCCAGCTCTAGAGAG 20233 GL261 Shcbpl TAGTCCITCAGCGCCACCTG 14250 MC38 Kif3c CCCACCGAACCCGAGCATGC 20234 GL261 Oxctl GATGCCAAGCCTTGCGCGAG 14251 MC38 Kif3c ATTAGCAACCTGACAGAACC 20235 GL261 Oxctl ACTCAITCCAGAGGGCGATT 14252 MC38 Kific ACTACCCACGCGTGTTCTCT 20236 GL261 Oxctl ACCAGGGTTTCGGGTTGCCA 14253 MC38 Itpr2 GGCGCGTGGCCAATCAAGCC 20237 GL261 Mbip TTCACATACACAAGTTCCCT 14254 MC38 Itpr2 CCTCTGTCCTGGCCGCTTCG 20238 GL261 Mbip CTCACTTAGAGCTTGAGGAT 14255 MC38 Itpr2 AGCCACGCTGGGCGGCGCTG 20239 GL261 Mbip AGTAGGTTTCTAAACCAAGG 14256 MC38 Perp TGGGCTGGCGGCAATCTGGT 20240 GL261 T im3 CTAATACATCACCCAACCGG 14257 MC38 Peip GGCGGTGCGCTCTGAGTCAC 20241 GL261 Trim39 TAGAGAGAGAAACATTCACT 14258 MC38 Perp CCGGGTGACCCAGCAGGTCG 20242 GL261 Trim39 GGCGATGGAAGACAGCTGCG 14259 MC38 Coll7al TTGTGAAGGGTATTTCCCAT 20243 GL261 Arhgap25 CCCGCTCTGTGCTTAGAGTA 14260 MC38 Coll7al ATTTATAGACCTGCGGGAAA 20244 GL261 Arhgap25 TAAATGGAAAGAGACTCCCA 14261 MC38 Coll7al TAATCTACCTGAGCTGGCAG 20245 GL261 Arhgap25 AGGCACATGGCGAGAGCCTT 14262 MC38 Gclm CTCTCGAAGAGGGCGTGTCC 20246 GL261 Celsr3 GAGGCCGTGACGGGAGGCGG 14263 MC38 Gclm TCACGAGGCGCTGGCGGCGT 20247 GL261 Celsr3 GCGCGGAGCGACGGGCAGAG 14264 MC38 Gclm CGGGAGCGCCGCTCAGCCAA 20248 GL261 Celsr3 CCCGCCCGGGTCCGGGCCTT 14265 MC38 Insc GCTGTCATCTGTGGGAGCTC 20249 GL261 Pbxipl AAAGCTGGACTTGAACGCCC 14266 MC38 Insc TTGGCATGTAGGACACATGT 20250 GL261 Pbxipl GGTCTCCAGCAAAGTAAATT 14267 MC38 Insc GCGGTCTCCACCGTGGCCAG 20251 GL261 Pbxipl TACGCAGTACCTCTCTCCCT 14268 MC38 Ngf CAGCAGGTGCGGGCTGGGAT 20252 GL261 Sppl2c CTCTTGGTCACAAAGCAGCT 14269 MC38 Ngf GGTCCGGGTTGTAAGGGTCC 20253 GL261 Sppl2c AGTGAGGTAGAGCACTCAGT 14270 MC38 Ngf GTGTGACGAGCCTGGAGGAG 20254 GL261 Sppl2c ATTGGGAGATGATCTGAGAG 14271 MC38 Itpr3 GAGAACGCCCTAGAGCCTGG 20255 GL261 Timd2 TGAGATGCAGTTAGACTTAC 14272 MC38 Itpr3 TGTAGAAGAGGCCGAGCCTG 20256 GL261 Timd2 GTCAGCATGATCTCCAGACC 14273 MC38 Itpr3 GGCAAGCTGGGCGCTTTAGG 20257 GL261 Timd2 GTTGAGCAATTATAGGAGCT 14274 MC38 Slco6dl GGGACGTTGGTTCCCTGCAC 20258 GL261 Fndc3cl AGTTTCTGAGTTTGGGATCG 14275 MC38 Slco6dl GCGTCACTCAACAGGTCTGT 20259 GL261 Fndc3cl GGAGACGAAAGCCCAGATGT 14276 MC38 Slco6dl CGTTCCCTGTAGAGTTCTAG 20260 GL261 Fndc3cl ATAGGGTTACACCGCTGCTG 14277 MC38 Faml79a GAGCCCAAGTCCCTGTGTGG 20261 GL261 Kcnkl2 AAAGGAAGGGAGCGCTTCCC 14278 MC38 Faml79a CAGAGGCCAACCTGTCCTCT 20262 GL261 Kcnkl2 GTAGCTCTTCAGCGGTAGCA 14279 MC38 Faml79a GCATGGCAACCGCTCTCTGA 20263 GL261 Kcnkl2 TGGGCTGCTGCGAAGCCTCC 14280 MC38 Nxpe3 CGTAGCGCGGTCAGGAAGCC 20264 GL261 Wwpl CCAGAGGCTCAGAGCGGCCC 14281 MC38 Nxpe3 ACATCCCGTGGGAGGGCGAG 20265 GL261 Wwpl AGGAAGGGAGGTGTAGGCCG 14282 MC38 Nxpe3 GTCGGACCAATCGTAGCCGG 20266 GL261 Wwpl GGGCAGCTGGATTCCCGGTC 14283 MC38 Adam28 GAAACAATAGCTCCTAATAG 20267 GL261 TbcldlOa CGGGACCCTCGGCACCCATT 14284 MC38 Adam28 GTGGTTCTGCCGCAATGGCA 20268 GL261 TbcldlOa GCGCGTGGTGGGAGCTCCCT 14285 MC38 Adam28 ATGAACTATTATAGCTCAAG 20269 GL261 TbcldlOa GGGCGGGACAACCGTCACCA 14286 MC38 Ankl GGCCGCGGAGGGCGGACTCG 20270 GL261 Nadsynl CTGTGGAGGGCGAAAGGACG 14287 MC38 Ankl GAGGGTTTGTAGGACAGCAC 20271 GL261 Nadsynl GGCGCAGACCGTGTCTTACC 14288 MC38 Ankl GGGCGCTGCGAGCCGGCGCT 20272 GL261 Nadsynl GCTGGGCTATGACGGCAGAG 14289 MC38 Dgkz GGTTGTTGTCTCCGGCTTGG 20273 GL261 Syne2 TTGCGGTGGCCGCAGGGAGG 14290 MC38 Dgkz TGCCTGCCTGCTATAGGGCC 20274 GL261 Syne2 GAGGAACTAACTCCGAACGC 14291 MC38 Dgkz TGAAGCGGAGGCTGCTTCCC 20275 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Syne2 TCCGCCITACAGACCCTTGC 14292 MC38 Pttgl CAGACGCGAGAGCTGGGCGG 20276 GL261 Vm3 GTACTGGTCAAGTTCTTAAT 14293 MC38 Pttgl CAATTGGTCCCTCCGAGAGG 20277 GL261 Vm3 TTAGTATGGACTCAACTGGT 14294 MC38 Pttgl CGAGCACGACAAGAGCGCCT 20278 GL261 Vm3 AGTTCAGAATTGCATGAGCA 14295 MC38 Med21 TGGCCAATTTATGACGCCTC 20279 GL261 Habp2 TGCATCCTCTCCATTCGTTC 14296 MC38 Med21 AGGCGGGTGGGATCCAGGGC 20280 GL261 Habp2 TGATTAAACAAATGGCAACT 14297 MC38 Med21 GCGTGCAGGCTGAGCTGCTA 20281 GL261 Habp2 ATGTCAGTCTCGAGGGATTC 14298 MC38 Sm l2 CCAGGACTGGGCGCTGAGTG 20282 GL261 Kifl2 TTAACTTGCTAGCTCTGGGC 14299 MC38 Smtnl2 GCCGCGGCTGGCTGAGCCCG 20283 GL261 Kifl2 CATGCCAGGGCATTCCAGCT 14300 MC38 Sm l2 GGGACTGGCCGGGTCGGTGC 20284 GL261 Kifl2 TTTCCTCTAGAGAGATCTAA 14301 MC38 Pdzphl GGCTAATAATAGACTGATTA 20285 GL261 Abca6 TTGATCTCATCATATCTGAA 14302 MC38 Pdzphl TGACTCGTCTTGTTCTATTT 20286 GL261 Abca6 TCTCAACCAATCACAGAACA 14303 MC38 Pdzphl GTTATTAGGACCAATTAAGA 20287 GL261 Papin GGTGTCAGCCGACTGGGTGG 14304 MC38 As l7 AAAGGATAGCAATGGCATGC 20288 GL261 Papin GAGGAAACCAGCCAGCCGCG 14305 MC38 As l7 CTGCAGAGCCGTCATCAGCC 20289 GL261 Papin CTCCTTCAGGGATTGGAGGT 14306 MC38 Asbl7 CCGCCTCAGGTTTCTGACCC 20290 GL261 Fam205al GGTAATTCAGTCTACAGCAG 14307 MC38 Nid2 CGCTGGGCGGGCCCGTATTG 20291 GL261 Fam205al TGAATGTCACATTCACAAGC 14308 MC38 Nid2 CAGAGTCGCTGATTGGTCAG 20292 GL261 Gp 5 CTTCAAITCTCTAGGTTTGC 14309 MC38 Nid2 CCGTTGGCCCGGTCTGGTCT 20293 GL261 Gp 5 TGAATTCGGAGTGCTCGTGG 14310 MC38 Adhfel GAAACTCTGAAATGTCTCAA 20294 GL261 Gpx5 TGGTCTTAATAGGTGTGGGC 14311 MC38 Adhfel AAATGAGCTAAGACTGGGTC 20295 GL261 Canx TGGGAAGGCGCTTCGAGCGA 14312 MC38 Adhfel AAACITCTGCCTCCAATGCA 20296 GL261 Canx TTCTTAGATCTTGCGCAAAG 14313 MC38 Psen2 GTTCAATCGATAAACATCTG 20297 GL261 Canx CCACGAAGAATAGCCCTAGG 14314 MC38 Psen2 CTTATTCGAGGCTAGAGCTC 20298 GL261 Aga ATCTGATACTGTTTCTTTAG 14 1 MC38 Psen2 TTTGTTCTTACGAGACGAGA 20299 GL261 Aga CGCGAGAGTTGAGGAAGTTG 14316 MC38 Wm CTGAGCATGCGTGCTGCGCG 20300 GL261 Aga GCCTTCTATTGGCCCAGTGA 14317 MC38 Wm GGGAAATGTAGTCTCAACGC 20301 GL261 Fcrl5 TTTCACTTTGTCTGTAGGGC 14318 MC38 Wm CTGACGGCCGCTGGGCACGC 20302 GL261 Fcrl5 ATGCTTTCAACACCACATTT 14 1 MC38 Abca8b CTGGCCATGTGGCTGTATAA 20303 GL261 Fcrl5 TTAAGGAGATTATGAGAAGA 14320 MC38 Abca8b TAACTGGCACCGCCCTGCGG 20304 GL261 Csf2 GGGTTTGGGAGATACTGAGT 14321 MC38 Abca8b TAAATGTTGCTCTCCAGCTT 20305 GL261 Csi2 GAGCTTGCCCAAAGGCCTCC 14322 MC38 Gm7173 GTAGCTAGGTAACAAGCACT 20306 GL261 Csi2 CTGGAATGAGCCACCAGAGT 14323 MC38 Gm7173 TGCCTTACAATTGGATCTCA 20307 GL261 Paldl GTGCCTATCCGACCGTGGTG 14324 MC38 Gm7173 TCTTGGTTCTATAATAGAGC 20308 GL261 Paldl CGCAGGTTCCCTCTACCCTA 14325 MC38 Usp40 CCGCGTGGCGCGACGCACCC 20309 GL261 Paldl CCGGCTGGATTGAAAGAGGG 14326 MC38 Usp40 GTGAAAGCTCTAACAGAATG 20310 GL261 Osbpl2 ATCATAATCCGGCTCACACG 14327 MC38 Usp40 GGGAAGTGTAGTCGCATCTG 2031 1 GL261 Osbpl2 ACCATGCCGATCACGTTCTC 14328 MC38 Xnal GGAATCTCGGAGTCGCTCCA 20312 GL261 Osbpl2 CGAGCAGCACGGCGGGCTGT 14329 MC38 Xrral CGGTTACTAAGGAGTGGGTG 20313 GL261 Ret ATATGTTGTACACTGGAAGC 14330 MC38 Xnal GAGGCGATGTCCCTGTCAGG 20314 GL261 Ret CATCCTCCGCCATTTATCAA 14331 MC38 Spire2 CTCGCGGGCAGATGCAGGTG 20 1 GL261 Ret GCGGGAGTGAGAAGCGCGTT 14332 MC38 Spire2 GGAGGGAAGGGAAGACCGGT 20316 GL261 Plekhdl TCCTGGTCGGTCACTCAGCC 14333 MC38 Spire2 ACAAAGCACACGGGCGGCGC 20317 GL261 Plekhdl AGCGTTGGGCGCCTGAGTGG 14334 MC38 Brd3 TTGTACACTCTGGGCGGCGG 20318 GL261 Plekhdl CAGCCTCAATTCTGGTAGCC 14335 MC38 Brd3 AAAGGCGTACTTGGCCTAGG 20319 GL261 Pfkl TCAGTCAAACGTTATACTGG 14336 MC38 Brd3 CGCGGACTACGACTCCCGCC 20320 GL261 Pfkl CTGCGCAGACATTTGTAGAC 14337 MC38 I o Od AGCTGAAAGGTAAGCAGAGG 20321 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Pfkl GGTAGCTGCGCTAAGAAAGG 14338 MC38 InoSOd CGCCGCCCGCCCTGCCTACG 20322 GL261 Asb4 ATTCTTGCAGAGAATTTGTT 14339 MC38 InoSOd GGCCCAGCCCGCCGCCCTAC 20323 GL261 Asb4 TATCATGCAAATGAAGCTGC 14340 MC38 Celsr3 GAGGCCGTGACGGGAGGCGG 20324 GL261 Asb4 CAGATATTCTTGCTATAGAA 14341 MC38 Celsr3 GCGCGGAGCGACGGGCAGAG 20325 GL261 Creb3L4 TCTCGAGGCTCACGCCCTCG 14342 MC38 Celsr3 CCCGCCCGGGTCCGGGCCTT 20326 GL261 Creb314 TCAGCCATTGGCTAGAAACC 14343 MC38 B he CGAGITAGTTTGCACTATCC 20327 GL261 Creb314 TAATTGGGCATTGAAGACTT 14344 MC38 Bche CTATCCCGGACTTTAACATT 20328 GL261 Cdl6311 TGGAACTCTACAAATCTCCA 14345 MC38 Fbxw21 AAAGGCTGATGAGCTGTGGT 20329 GL261 Cdl6311 AGATAACTGTGTAAGAGCTC 14346 MC38 Fbxw21 CATCTGGCACCAGTGTGTGG 20330 GL261 Cdl6311 CTGCACGAAATGCTTCTCTT 14347 MC38 Fbxw21 GACTCGGCCAAAGATTTAGC 2033 1 GL261 Setdlb CAGCTGCGCCGCCAAAGCCC 14348 MC38 Fn3krp TTCTCTGGCTGCTGGAGCGC 20332 GL261 Setdlb GAAGCGGCGAGGAAGGCGAG 14349 MC38 Fn3krp GTGGCCTGACTGGTTAGGAT 20333 GL261 Setdlb CGCCGCCGGGAGAGTGCCTG 14350 MC38 Fn3krp GAGTTCAGCACACCAGAGCG 20334 GL261 Trim72 GCGATATACGTGCCCACTCT 14351 MC38 Ddx28 GAATGGGAGTCCGCAGTAGG 20335 GL261 Trim72 CCTGGGCTAAATCAGTAGCA 14352 MC38 Ddx28 TACGGTGGCTGGCGCGGATC 20336 GL261 Trim72 ACCATCTGGTAAAGAGGATG 14353 MC38 Ddx28 GAAGGGTACTCGGTGGAGGC 20337 GL261 Fancd2 AGTAACGTCACGCCACGGCG 14354 MC38 Ptpn23 TCTTCTCGCGCGAAGGGTCT 20338 GL261 Fancd2 TCTGGCTGGCGTGGAATCTG 14355 MC38 Ptpn23 TGGAGAGACGACCCAATCCA 20339 GL261 Fancd2 CGCACCGGAAGTTGACGGCC 14356 MC38 Ptpn23 CACACCTCTTCGCGCATGCT 20340 GL261 E330021D16Rik CTGAGGTTTGCTACTGGGAG 14357 MC38 Zfpm2 CCGGGCTGTGAGTTTGCATC 20341 GL261 E330021D16Rik CTTGTGATAGCAGCTGAACT 14358 MC38 Zfpm2 CTCGGTCGCGTGGAGTGCAA 20342 GL261 E330021D16Rik TGCACAAACTTGGCCACTTC 14359 MC38 Zfpm2 GAGACTATGCCATCAGCGAA 20343 GL261 Csi2rb2 GAGCTGATGTGGAGATGGTG 14360 MC38 Ccdc73 CATTTGTGCGGCTACATTTA 20344 GL261 Csi2rb2 TCCAGAGAAGTCAGGGAGGT 14361 MC38 Ccdc73 CCGGAAGCGCCTTTGGGTAG 20345 GL261 Csf2rb2 GGTGTGGAGGAGGCCATTCC 14362 MC38 Ccdc73 AGTGAGTTTCATAACAAACA 20346 GL261 Azin2 TGCTTAGCTGCGCAGCTTTG 14363 MC38 Fbxo46 AATTCTCCCGCGAGGGTATC 20347 GL261 Azin2 ATAAAGCATTCAGCCCTGCG 14364 MC38 Fbxo46 TTAGTGTGCCCTTAGCCTCC 20348 GL261 Azin2 TGGCTGACTGATGTCCGCGG 14365 MC38 Fbxo46 CGGTAACTTGGAGGTGGAGT 20349 GL261 Ermap CTGAACGCTCGCTTTATCAG 14366 MC38 Crisp1 TGGTTAACCAGGTATGACAC 20350 GL261 Ermap GTAAAGGTCCTTCTTTGCCG 14367 MC38 Crisp1 CACAATCTGCTTGTGCAAGC 20351 GL261 Ermap GTAGACGGGTCCCTTGCTTT 14368 MC38 Crisp1 ACTCTGCATAGTTCCTGTTT 20352 GL261 K 15 GGGCCCGGGCCAGGGTCTCG 14369 MC38 Faml 14al TGCTTCGTAATGGAAGGCAG 20353 GL261 K 15 CGGCTCCCTCGGCCCGCAGG 14370 MC38 Faml 14al GGGAAGCCCTGCAGGTTGTA 20354 GL261 K 15 GCGTGAGAGGGCCACGAGCC 14371 MC38 Faml 14al CGAACTCCGCCGTCCCAGAT 20355 GL261 T l ATAGACACTCAGCGCGCGCA 14372 MC38 Mllt6 GCGCGAGTCTCATTGTTGGG 20356 GL261 T l GGGTCAACTTCCGTTCCGAG 14373 MC38 Mllt6 GCCGGCGAGCGGCGCGGAAG 20357 GL261 Toel CTTCGTCTCCAGAAGCGACA 14374 MC38 Mllt6 GAGGGCGAGAGCACGGCGGG 20358 GL261 U φ GGCGAGGGAGAGGACGCCCT 14375 MC38 Tnsl GACGCGGACTACCCGCGAGC 20359 GL261 Urgφ CGGAGGCTGGAACTCACCTG 14376 MC38 Tnsl GGCCCGGGACCCGGCGGGCC 20360 GL261 Ι ¾φ GGCGGAGTTTAGGGAAGCAG 14377 MC38 Tnsl GGCGGAGGCGGACTCCGACG 20361 GL261 Prkdl TAGAGTCCGCCGAGTGGGCT 14378 MC38 Atp7a AAGCGCCTAACTTTACATCT 20362 GL261 Prkdl AGCCGCGGACCCGCCCATTC 14379 MC38 Atp7a AATGGTCCACGTCACGTGAA 20363 GL261 Prkdl CCACGGCGGGTCCGCGCGAC 14380 MC38 Atp7a CCCACTTCCGGGCGATGCCA 20364 GL261 Tc 20 TTAAGGGCGAAGGAGGGATC 14381 MC38 Slc32al GGAAGATAGTTCCGAGGGTG 20365 GL261 Tc 20 GCAGAGGTGTGATCCGGCAG 14382 MC38 Slc32al GAAGGAGCGCGCGAAAGGGT 20366 GL261 Tcl20 CTCAGCTGATGTCACCGCCC 14383 MC38 Slc32al GAGGTGCTAAGCAGACGTCC 20367 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Pdzkl CATGTAGGTAGCATGGGAAG 14384 MC38 Spata21 TTCCACAAACCACAGATTTA 20368 GL261 Pdzkl CCCTTCCCATTGTTAGGCTG 14385 MC38 Spata21 CTGTCAGCTAGCTACAGATG 20369 GL261 Pdzkl ATGTATITAACAGGGACGTG 14386 MC38 Spata21 GGGATGGAGACGGTGAACAA 20370 o GL261 Vp d GAGGCACCCGCCGCCCTTAC 14387 MC38 Sa b TTACCCAAGCGCAGTGTGCG 20371 GL261 Vpsl3d GAACGGCTGCGGACGCTAGG 14388 MC38 Sa b CCTGTAGCACGCATGCGTCT 20372 GL261 Vpsl3d AATTCTAGACTAGGCAGGTC 14389 MC38 Safb ACGACGTAGGCGCGCCTCGC 20373 r GL261 Tnfrsf21 TTCCTCCAGCTAACGCCAAG 14390 MC38 Was AGGAAGTACAATAAACCACA 20374 o 4 GL261 Tnfrsf21 TCAAGGCGCTCCAGAAACCG 14391 MC38 Was AGGAGAACAGGCCCTCTGGG 20375 6 1 GL261 Tnfrsf21 CGACCCTTTGTGATGTCACC 14392 MC38 Was TGGGCCCTCCTCCATTTGCG 20376 GL261 Dd 2 GGGATCGCCACGGCTAGACT 14393 MC38 Fancm GTATTGCGCGAAGTGTGTGA 20377 GL261 Ddti21 TCTGCGCGGTCTAACGACAG 14394 MC38 Fancm AAGATGATTGGTTGCCATTC 20378 GL261 Dd 2 TTGGGTGAGACCCGTGTGTG 14395 MC38 Fancm CATGCGCTTCTTCTGATTTC 20379 GL261 Col6al GCCCTCTCCTCTCGGGTACT 14396 MC38 Kif24 CGCGTTCGAACTGGCGCTTG 20380 GL261 Col6al GGAGGGAGGGAGGTGCAAAG 14397 MC38 Kif24 GGCGGTTCATTCTCCACCAA 20381 GL261 Col6al CTGTGACTCACTCAGCTTTG 14398 MC38 Kif24 CCTGTCACCTCTCCTCTAAA 20382 GL261 Scrib GTTGTTACACCTGCTAGTAT 14399 MC38 Ranbp9 GAGCGTTGGCCAGGCGCTGG 20383 GL261 Scrib GCGTCTCCGACGACCCGTAG 14400 MC38 Ranbp9 GCACGCGACCGGGAGCGATG 20384 GL261 Scrib CGGGATTTCCGGCCTCGCTC 14401 MC38 Ranbp9 GGACTCTGGGCGCCTGGTGC 20385 GL261 Metap2 TCAAGCCTTCTGCCACACTT 14402 MC38 Atp6v0c CAAAGTGGTACAGCCCGTGG 20386 GL261 Metap2 AAACATTCCTCAGGATGACT 14403 MC38 Atp6v0c CAAGGCTGAGCGTTGGGCCC 20387 GL261 Metap2 GATAGGGATGCTAGCAGCAT 14404 MC38 Atp6v0c GGCAGCCCTTGGACAATTTA 20388 GL261 State GGAGCTCCATTGAACCACAC 14405 MC38 Ruscl GGGATGTGGCTAGAATCTCC 20389 GL261 State GTGAACCTGTATGTACCCGG 14406 MC38 Ruscl GCTTTGTAGATGGGTGACAT 20390 GL261 State AGAGCGCCAGGGAGGGACCT 14407 MC38 Ruscl AAGGTGCAAGGTGACTACGT 20391 GL261 Slcl7al CATGATGAGGTCAAAGAATT 14408 MC38 Rps3al GAGCATCTCTGACAATCTGC 20392 GL261 Slcl7al TAAACATTAAGCATTACCCT 14409 MC38 Rps3al GCGCGACCTCCCGACACACG 20393 GL261 Slcl7al TTCCCAGAAGGTTCTAGTCC 14410 MC38 Rps3al GGGCGCTGTCGCAGCACGGC 20394 GL261 Mpi AGTTCTCAGTATTTACATAC 14411 MC38 Rcbtb2 ACGATGTTTGAGGCTAACTT 20395 GL261 Mpi TTTCTGCGCGCGGAGCTTCA 14412 MC38 Rcbtb2 CTAGTGATCAAATTTCAGTT 20396 GL261 Mpi CTGCTCAGGGAAGAGGCGGT 14413 MC38 Rcbtb2 TAATGTTATGGCTTTGAAAC 20397 GL261 Kdm4a CGTAGTTCCAGACGCCGAGT 14414 MC38 Ly6f GGAGGGAGGACCACTCAGTT 20398 GL261 Kdni4a GAGTGTTCATTGGTTAGCTG 14415 MC38 Ly6f AGCAAGGTTTGTTGGTGATC 20399 GL261 Kdm4a ATCCAGAGTTAGCCTATCAG 14416 MC38 Ly6f AGCAAGATTTATAGCTGTTG 20400 GL261 Myof GTGGATTTGGGACGAACTGC 14417 MC38 Tip53bpl AACACGGCGGCGTGTTTCCA 20401 GL261 Myof TTTCACGAGTTACTGCTAAA 14418 MC38 Trp53bpl GTCATGCTGGCTGTATTAGG 20402 GL261 Myof TTGCGCAGCCAATGAAACGG 14419 MC38 Trp53bpl GGCAGACAACAGCAGCGAAT 20403 GL261 Dnah9 GGAAGCTCTCACATCCAAGC 14420 MC38 Ltnl GTTACGTTTCAGGCAGCGGA 20404 GL261 Dnah9 AGACGTGCTCTGAAGACTAC 14421 MC38 Ltnl GCTCAACGCTGGTTTCTTAT 20405 GL261 Dnah9 CCTACCITATTAACTTAGTG 14422 MC38 Ltnl TCGGACAGGTTTGGCGCCAC 20406 GL261 Sync GCGGGACGCGCCCACTTGGC 14423 MC38 AMcl GCCCGGAGCGGACCCTATGC 20407 xi GL261 Sync AAGGTTCGCGAAGTGCCGCT 14424 MC38 Ahdcl AGGACTGCTGATCCTCCTCA 20408 o GL261 Sync GGACGATTACCCGCGGGAGG 14425 MC38 Ahdcl CATCCGGGCCAGGGATACTC 20409 o GL261 Myolf MC38 Slcl6a7 TTTAGTGGGCACGCTTTCAA 20410 TGAGCTCTAGCAGCAATGAC 14426 o GL261 Myolf CCGTTTGGAGCTTACCCTGA 14427 MC38 Slcl6a7 CCCTGGCTATAATTTAAGCC 20411 GL261 Myolf ATAAAGGACTTTCTCTAGTC 14428 MC38 Slcl6a7 TGCAACAGTGCAACGTAAAC 20412 SO 6/1 GL261 Havcr2 GGTTAGCACTCGTGATTCTG 14429 MC38 4933434E20Rik TCCAACAATGACCCTAGTCC 20413 OS Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Havcr2 CTAGATTAACAGTACTAACG 14430 MC38 4933434E20Rik GTGAAGGGTCTCAAGAAATT 20414 GL261 Havcr2 AGTGTGTCATTACACAGAAC 14431 MC38 4933434E20Rik AGGCGCAACACAATCCACGG 20415 GL261 Gpatch3 ACGAAACTTCAAGTACCAAA 14432 MC38 Upf3b TCACTAGGGCTATTTGTTAG 20416 o GL261 Gpatch3 ACGTGGTGCTCTCGCGAGAG 14433 MC38 Upf3b CCTAGCGGCCCAGATTCCCT 20417 GL261 Gpatch3 ATGCTGGAGTTTGGTCAATG 14434 MC38 Upf3b GCAGGCGGGAAGTAAAGGTC 20418 GL261 Proml CAGGCACCCTTAGCCAACCC 14435 MC38 Radl7 TTTCGGGTCAGGCAGTGCGC 20419 r GL261 Proml ATCACTCTTGTGGTGCCCTG 14436 MC38 Radl7 CCCGGCTTCCCACCATTAGA 20420 o 4 GL261 Proml CTAGTCCCTACCTGTAGCTC 14437 MC38 Radl7 GGCAAGCGAGCAAGGGACGT 20421 6 GL261 Paox GAGAGGAGATGGATGTCCCT 14438 MC38 Ppplr26 GGGCTITAAACTGGAGGCTC 20422 W GL261 Paox AACATTCGGAACTGGACTGA 14439 MC38 Ppplr26 TCAGGTTTCCAGGGTGGTTG 20423 GL261 Paox CCAAGACGGGAGGAAAGCCT 14440 MC38 Ppplr26 GACAGCTCCCAAGATTGACC 20424 GL261 Nrsn2 GTCTGCAGAGCCAGCCTCCG 14441 MC38 Ubxn8 GTCCCTGTCCTGTGGATCTG 20425 GL261 Nrsn2 CCAACAGAAGCTGTCGGAGC 14442 MC38 Ubxn8 AGTGGCTTATCAGACTGTGC 20426 GL261 Nrsn2 TCGCGCCTGCGCTACAATCC 14443 MC38 Ubxn8 CCCGGATGCGATTGCTCAGA 20427 GL261 Zfp709 GGGACTTCCGCTACGCCCGC 14444 MC38 Nedd4 CCAGAAACAAGGAGCTCGTC 20428 GL261 Zfp709 AGAAGCTCCTGCGGACAAGG 14445 MC38 Nedd4 GGAAGGGCGGGCGAGGTTGG 20429 GL261 Zfp709 CGCTGTCCCGCGCATCCTTG 14446 MC38 Nedd4 TGCGGAAGAGCCACGTTTCT 20430 GL261 Pnliprp2 GCATCCGGTCCCGCCCACTG 14447 MC38 Nsun2 GGGAGCATGTTGTGTCTTTC 2043 1 GL261 Pnliprp2 TTCAGGAGAAGACTTTGAGC 14448 MC38 Nsun2 TTCACGCTCAGTGGCGTTTA 20432 GL261 P liprp CTCCCAGAGTTTAATGATCG 14449 MC38 Nsun2 TGAGGAAACACGTTCTCTAT 20433 GL261 Adgrf2 TACTGGGAGAGGCACGGAGC 14450 MC38 Kansll AGGGACAGCAGCGCCTCCGC 20434 GL261 Adgrf2 GAGAGAGTGTCAGAGTCACT 14451 MC38 Kansll GAATGGAGCGAGCAAGCGAG 20435 GL261 Adgrf2 TGGCGGTGGCATGAGAATTG 14452 MC38 Kansll CGCCTCCTGGCAGCCCGCGG 20436 GL261 Myolg CTTAAAGCTCTTCCCAAGCT 14453 MC38 Gpa33 CACCCAGTCAACGGACTGGC 20437 GL261 Myolg TCAGGACAGACAGTTAGGCA 14454 MC38 Gpa33 AAGGAAGAAGACTCTTGTTG 20438 GL261 Myolg ATGGGCAGGGCCAAACTCCC 14455 MC38 Gpa33 ATGTGGGCCCAGTCTGGCCC 20439 GL261 Heatr5b TGCGCGAGACACAGGTCCTG 14456 MC38 Sox9 AGTGTTGGCAAGTCGCTGAT 20440 GL261 Heatr5b ATGCGCCGTGCAATTGGCGC 14457 MC38 Sox9 CTCCTTCACGTTAGATACCT 20441 GL261 Heatr5b CCGATTCGCTTCGAAACTTG 14458 MC38 Sox9 ACTCAAGAGCTAGCCGTGAT 20442 GL261 Gbp2 CGAACTCCTCACAAGTTCTC 14459 MC38 Exol ATGGCATTGGCCATTGGCGG 20443 GL261 Gbp2 CTCAGGTAGAGATTGATAAA 14460 MC38 Exol TGAGCCCTTCCTTGCAAGGT 20444 GL261 Gbp2 GCTCATGGGAGGAGGGTCTC 14461 MC38 Exol CGGCITGTTTGTGAGAGAAG 20445 GL261 Nd fa GTCACCTGTTTGGGACGCCA 14462 MC38 Fmipd4 AAGGACCGCCAGGCGCCCTG 20446 GL261 NdufaH TGCTTGGCAAGGAACGCCAC 14463 MC38 Fimpd4 CCCATCAATGGTCCTGCTTG 20447 GL261 Nd fa TCCTGAATCGCCCTCGCAAT 14464 MC38 Frmpd4 TACAAGGCAAACTGCCTCTG 20448 GL261 Prss39 CGGTTGTCTTCACGTGCTTT 14465 MC38 Acsl5 AGAATTGGAAGAGAGATGAC 20449 GL261 Prss3 CCATAAACATACGCACCTCC 14466 MC38 Acsl5 CCGAGGTCTCCTTGTGTCCC 20450 GL261 Prss39 GAAGAGCATAAGGACAACCC 14467 MC38 Acsl5 GATTAAGACAACTGTGAACC 20451 GL261 Kcna7 ACATACCCAAACCCAGTGTC 14468 MC38 Narf TTGGTCTACTACAGTCCTTG 20452 GL261 Kcna7 GATGTGGACAACTGGTTAAG 14469 MC38 Naif GGGTGTGGCTCATCTTGCTT 20453 xi GL261 Kcna7 AGAAAGACTGGAAATGGAAA 14470 MC38 Naif TGAGAGTGTGAGGAAGTGGC 20454 o GL261 Neil3 CTGAGCCAGTGCACAGTGAA 14471 MC38 Lmtk3 TCTGGTCCAGCCTCATTGAG 20455 30 GL261 Neil3 AGGTCTCACACTTGTGTCAT 14472 MC38 Lmtk3 GGGAATGGGATTGCAGTGAC 20456 GL261 Neil3 GAGCAGAGTCCGCACCACCT 14473 MC38 Lmtk3 GGGAGCGTTGTCATGGCAAC 20457 GL261 Muc5b AGACCGTGCCTTACATGGCC 14474 MC38 Evc2 GAGGCCGCAAGCTGCGTAGG 20458 30 6/1 GL261 Muc5b CAAACACACGTGGCTGTGCA 14475 MC38 Evc2 CATGCTCAGTGCGAACCGCC 20459 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Muc5b GCCTGGACTTATGTAGCCAA 14476 MC38 Evc2 GAACGCTGGCATCTGGAGTT 20460 GL261 Ocrl GCTATCTGCAACATCCTAGA 14477 MC38 Synm CGCGACCGGGCCACTAAGTG 20461 GL261 Ocrl AACTGCAGCTAGGCACCCGA 14478 MC38 Synm AGTGCTGGGCAGCCTCGCCA 20462 GL261 Ocrl ATTTGAAGAGGGACCTGCTA 14479 MC38 Synm GGCCCGATCTGTCCGGCAGG 20463 GL261 Snhgll TTTCGGTTCTACTCCTGCAG 14480 MC38 Gm5878 TGGGCAGGTGCCGCATCAGG 20464 GL261 Snhgll CAGCTTCGCCTTTGCGCAAC 14481 MC38 Gm5878 AGGGCGAGGCGATGGATTGC 20465 GL261 Snhgll CTAAGGAAGGAGAGCCTCGA 14482 MC38 Gm5878 ACGCACAGCGCGCGCTCCGG 20466 GL261 Slc26a7 ATAAAGGGAATTACTGGCAA 14483 MC38 Fgfl3 GAGTACGAGCTTGATGTTTC 20467 GL261 Slc26a7 TGCATTCCCAATGGTTAATG 14484 MC38 Fgfl3 ATGATCTGTGAGAGTCATAA 20468 GL261 Slc26a7 TGGGCTATGCTAATGAAACC 14485 MC38 Fgfl3 CGGTATAGAGAGATCATTAA 20469 GL261 Gas211 GCCGGATCCAAATTCCAGGG 14486 MC38 Rfx8 GCCCAACGTTGGCCAGAGAG 20470 GL261 Gas211 CCGTGCCTTTCTCGGGCCTT 14487 MC38 Rfx8 ACCTTTGGTGGCGGTGGGCG 20471 GL261 Gas211 CCAGACCCGGAGTTAAAGGG 14488 MC38 Rfx8 GGCCCACGCCTTGCACCCAG 20472 GL261 Arhgap21 AGGCTAAAGATCGGCGCCTG 14489 MC38 Ubiadl AAGCAGCTGTTTAGCCCTCC 20473 GL261 ArhgapH TTCTTCGTATTGTGGGAGAG 14490 MC38 Ubiadl GCGACACGCCCTGAAATCCC 20474 GL261 ArhgapH TCTTTCTCTAACCGACCTTC 14491 MC38 Ubiadl TTTAGCTAATTTGTTGAACC 20475 GL261 1112*2 AAAGGGAACTTGCCCAGTGC 14492 MC38 Pdzm4 ATTAAGAAGCAAATGTAGTG 20476 GL261 1112*2 AGTGGCCATGACAAGTGTCC 14493 MC38 Pdzm4 CACTATTAATATTCATGAGC 20477 GL261 1112*2 GGCGTGGTGAGAGCGCAGAA 14494 MC38 Pdzm4 GGCTTGGAGTTTCAAAGCTG 20478 GL261 2810006K23Rik CTCGGAAGAGAGGGCCGAGC 14495 MC38 Wbpll GGCTCCTACTTTCTGTCCAT 20479 GL261 2810006K23Rik AAACTGCGGGAAAGACGCCT 14496 MC38 Wbpll CTGGGCGGGCCCTTTGCCTG 20480 GL261 2810006K23Rik ACCTCTGCTGATTGGTTCTC 14497 MC38 Wbpll GATATGTCACGAGAAGGTGG 20481 GL261 Cpe 4 GTGGTGTCGGATTGGTC1TC 14498 MC38 Syne2 TTGCGGTGGCCGCAGGGAGG 20482 o GL261 Cpeb4 TTTCACTCGGCTCGGTCCTG 14499 MC38 Syne2 GAGGAACTAACTCCGAACGC 20483 GL261 Cpeb4 TGTCTCTCGGTCITTCCAGC 14500 MC38 Syne2 TCCGCCTTACAGACCCTTGC 20484 GL261 Thsd4 CTTCATGTAATAACTTCTCC 14501 MC38 Pus71 ACATTTAAAGGGACAGGCTC 20485 GL261 Thsd4 ATCTGGCCTCATTCATGAAA 14502 MC38 Pus71 AGCTAAGGGTGAGAGTATAG 20486 GL261 Ttisd4 GTTAGTGACTTTACTGCATG 14503 MC38 Pus71 TAAGAGGCTAGGCGGCGGAA 20487 GL261 Hdac5 CCAATGCCCAGCCCAAGGTT 14504 MC38 Clcn2 GAGCAGAGGTCGCTCCTCCC 20488 GL261 Hdac5 ATTGGTCCCGCCCATCTGAG 14505 MC38 Clcn2 GCACCTGGAATGGCTAGGCC 20489 GL261 Hdac5 CCACCGTGACAGCTTCTTAA 14506 MC38 Clcn2 GCCCGAGGGAAGGGAGCTAT 20490 GL261 Sipal AGAGAACTTCAGGCTGTCCG 14507 MC38 C2cd4a ATCCACGTGGCAGAGGGACC 20491 GL261 Sipal TCACTGACTGGGCTAGGACC 14508 MC38 C2cd4a AAAGCCCGGACCAGCTATCC 20492 GL261 Sipal GACTACCCGGGAGCTGTCTA 14509 MC38 C2cd4a TGAGGAAACAAACTCGTTCA 20493 GL261 Cyp2c29 GTCTATTAGAGAGAGATAAA 14510 MC38 Tpm3 GGAACAGTGAAGGGATGGGA 20494 GL261 Cyp2c29 TTAGTCAATGATGCTCAAAG 14511 MC38 Tpm3 CAGATAAAGGTTCAAACCTG 20495 GL261 Cyp2c29 GGGCACTCTGTAAAGGTCAA 14512 MC38 Tpm3 TAAGGAAAGACGGCCCTGAG 20496 GL261 Inpp5j GCACCCACTTCCCATATTGA 14513 MC38 Atxn712 TGCGATTGTGCATTTCGGAA 20497 GL261 Inpp5j AACATAAGCACCCATCAGCT 14514 MC38 Atxn712 GAGTGAACTGGCAAGGTAGG 20498 GL261 Inpp5j GGGCTAAGTGGCTACCCGCT 14515 MC38 Atxn712 GATGCTTACGGAGCTAGCCG 20499 GL261 Fam83d GCAGAGCCTTTGGTACGCAT 14516 MC38 Mypn CCATTGCGGGACAGCACCTA 20500 GL261 Fam83d ATCAAACCAGCCCGCTCTAT 14517 MC38 Mypn CAGTGTTCTCCTGTCCAATC 20501 GL261 Fam83d AGACTACCACCGTAGACAAG 14518 MC38 Mypn GGCGGTAAATGAAATTCCGT 20502 GL261 Myom3 TCTCTTCCTGCCAGCACTGC 14519 MC38 Synjl AGGACGGACCCTCCCTCTGC 20503 GL261 Myom3 CTATATTTAAGACGGTTACA 14520 MC38 Synjl GAGCTACAGGGCTCCACGCG 20504 GL261 Myom3 CTGAGACAGTGCGGTGACAA 14521 MC38 Synjl CTGCCGAGCAGGGCGCTTAC 20505 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Rbm7 CGTCGTGACGTCTGAACGGG 14522 MC38 Arf5 CTTCCGCAAACGCGCCTGGG 20506 GL261 Rbm7 GCGGGACAAGCGCCCGTTTC 14523 MC38 Arf5 GGCGCAACAGCAGAAGGAGG 20507 GL261 Rbm7 GGTAACGGTTGCGTCTGACG 14524 MC38 Arf5 GGGAGGCCTGGCAGCCTGCC 20508 o GL261 C d 170 AGACAGATTGCTCTCTTACT 14525 MC38 Nop 14 GTCGAGGAAGTGTGGCCTCC 20509 GL261 Cede 170 GCTTATAATAACAACAAAGG 14526 MC38 Nop 14 GTGTACTTCTCGCGAAATAC 20510 GL261 Cede 170 TAGGGTTCTACAGTTCAGAA 14527 MC38 Nop 14 AGGATACTGTGGCGGCTCTC 2051 1 r GL261 Tbrgl GGCTATCAGCCGGGTAGGAC 14528 MC38 Notch4 AAGACAAGGGAGAGTAAGAG 20512 o 4 GL261 Tbrgl TAAACTCTTCCCTACTTCGC 14529 MC38 Notch4 CTGGTTTGCTCTTAGGGCCC 20513 6 1 GL261 Tbrgl TGTGGACGTGCATTCCCTGA 14530 MC38 Notch4 TGTCCTGGACACCCTACTGA 20514 W GL261 Pars2 AAAGCCGCACTCACGGGAGG 14531 MC38 2700081015Rik TGGCAGGAGGAAATTGCGCG 20515 GL261 Pars2 GGCACTTCCGGAATCTTGGC 14532 MC38 2700081015Rik GGGCGCTTGTTACGGACGCG 20516 GL261 Pars2 GAACCTTGCTAATTCCTAGA 14533 MC38 2700081015Rik GGGAGGTGGCAAGTCCGCAA 20517 GL261 Rrpl5 GGAGAGAGGACACGACCTAC 14534 MC38 Rnil33 TGGCTTGAATGTTTCCAGTG 20518 GL261 Rrpl5 TCTCCGGCAGAGTCGGTTCC 14535 MC38 Rnfl33 TCTCATACCCATAACCACAC 20519 GL261 Rrpl5 TTCAGGCGGGACAACTGTTC 14536 MC38 Rnfl33 CTCTGAGCTAATTGGCTGCT 20520 GL261 Poteg CTGTGTTTAGAAGCGTTGCT 14537 MC38 Katnal GCGCGCGCAGGCGGAACCTG 20521 GL261 Poteg TATGGGTAAAGGTGCTGAGT 14538 MC38 Katnal GTGGACCATTATCTCTTCCC 20522 GL261 Poteg CTAGTTTACCCAAATGAGAA 14539 MC38 Katnal CTAGGAAATGGGAGTAGGCG 20523 GL261 Cdl9 GCCTAGTGGGCAATGAACCA 14540 MC38 Effia AGGCCTGCCTCCTACATCCG 20524 GL261 Cdl9 GGAAGAGTGCCTGCAAATGG 14541 MC38 Eifia GGTGTTCTTTGGTTGCGGGA 20525 GL261 Cdl9 GGGTGGTCACACCTTAGGTT 14542 MC38 Eifia GCGCGCTGGCGTCTCGAGCG 20526 GL261 Aunip GGTCACTACCAAGTTTGGTT 14543 MC38 Cobl GTGACTCGGTGCCCACCGCG 20527 GL261 Aunip AGCGCACTGGGCGTGGTTAG 14544 MC38 Cobl ATGGGAGCATCAGTTGAGGT 20528 GL261 Aunip AAGAGCTCCCGGGAACCGCC 14545 MC38 Cobl GTTGTCAACTTGACATATCT 20529 GL261 Sh2b2 GGACTTGGGAGCGTGGCTAG 14546 MC38 Mfsd9 TGAATTAAGACGCCCGCGGT 20530 GL261 Sh2b2 AGCGGTTAGCCGGCGCCACT 14547 MC38 Mfsd9 CAGTAGTCACACCCACCCAG 2053 1 GL261 Sh2b2 GGGCTCCGGAGAGAGAGCCG 14548 MC38 Mfsd9 GATCGCTTCCGCCATGGGCG 20532 GL261 Vhl GAGGTGGAATTTATAACCCG 14549 MC38 Cilp GCTGGAGATGTAGGGATGGG 20533 GL261 Vhl ACAAACAGAAACCCAACTGT 14550 MC38 lp GGGAGTCTCATGCTCAGATC 20534 GL261 Vhl GCCGCCGGGAGCCCTCAAAC 14551 MC38 Cilp CATCAAGATCCTTAGGGATG 20535 GL261 Cyplal TGGGCTCAGATAAGGAGGCG 14552 MC38 Synpo GGGACCCAAGCGGGAGCCGC 20536 GL261 Cyplal CGTGGGACAACTCAAAGTCC 14553 MC38 Synpo GGGTGGAGAGGCCATTTAAA 20537 GL261 Cyplal CATGAAGGGACTGCTTCTAC 14554 MC38 Synpo CTGGTGAATCTGGCTGCGTG 20538 GL261 Ha rl TGGCTGGCTGTACGTGAGAA 14555 MC38 1700013H16Rik GAATGCCGCGCATGCGTGTG 20539 GL261 Havcrl GACAGGGTATCCTAGCGGAG 14556 MC38 1700013H16Rik AGTCTCAACCAGTAGCTTCG 20540 GL261 Havcrl GCTGAGCTTATGGTGGCCTC 14557 MC38 1700013H16Rik GTGTAGCAGAAATCTGAGTG 20541 GL261 Emibn3 CTTAACCTCGTGTTTGCACG 14558 MC38 Cwfl912 CCGAATGTTTCGCCTGTGAA 20542 GL261 Emilin3 GACGCAGGGCGCTAAATTCC 14559 MC38 Cwfl912 AGGACGCCGTCGGGAAACCT 20543 GL261 Emilin3 CGGGCGTCAGCTTGGAGCTG 14560 MC38 Cwf l 12 AGCGGAAACTTGTAGCCTGC 20544 GL261 Mc5r GCGGCGATATGGGCGGGTGG 14561 MC38 Cart GCAAGGTAGCAAGGTAGGCG 20545 xi GL261 Mc5r GTGAGGTGCTAGTTTAGGTC 14562 MC38 Cart AGTTAACAGGAGTAGGATGG 20546 o GL261 Mc5r TGGGCACCTGATGTCCACCT 14563 MC38 Cart CGCCTTGTCCAGTCTCAGAT 20547 90 GL261 Ccdc69 CTCAGCTCTTTCTCATCAGA 14564 MC38 Fiy TCAGTCCATCCCTCAGCGGG 20548 GL261 Ccdc69 AGAACCATCTGTGGCTCCTG 14565 MC38 Fry AGCAGCTCACAGTGCGGGTG 20549 GL261 Ccdc69 CTTCTGGCGTGGAGCGCCGC 14566 MC38 Fry CACCCGGGTGGACAGATGTC 20550 90 6/1 GL261 Enppl GTCCTCGTTGGGCTACGCGG 14567 MC38 Abhdl6a TGCGCTGAACACTCCTCTCG 20551 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Enppl GGGATTCCGCAAGGGTTCGT 14568 MC38 Abhdl6a CGCCCAGGAGACTACGGGCG 20552 GL261 Enppl TTAAAGACACGCCCACGTCA 14569 MC38 Abhdl6a CTGACGTCACGCACGCACAC 20553 GL261 Trim54 TTAATCTCTCTAGGGAGGAA 14570 MC38 Zfp341 GGGTCTCCGGCCGGACAGCG 20554 o GL261 Trim54 TTGGGAACTGGAATGTCACA 14571 MC38 Zfp341 TGTAGAATTGGAACTACTAG 20555 GL261 Trim54 GGGTGGCTAGGAATGGTATG 14572 MC38 Zfp341 CGCAAGCATTGTGAGAACCG 20556 GL261 Tlrl2 AAATGACACCAGGGCAACGT 14573 MC38 AdcylO GTCTGGACATGTGAGACAGT 20557 GL261 Tlrl2 CTGAGCTCGTGGGACAGCCT 14574 MC38 AdcylO AGTAGACCACTCAGTGTTGG 20558 o 4 GL261 Tlrl2 TCTGTTTGCTTTCTCCTAAC 14575 MC38 AdcylO CTTCTGATGAGGGTGTGGCC 20559 GL261 Parvg TGAATGAGTCTTTCGCCAAT 14576 MC38 Trim37 GACTTGGAGAGGCGGTGCCG 20560 GL261 Parvg GCAGTCTTTCAGTGGATTTA 14577 MC38 Trim37 CTGCGCGCACCGCGGGAACC 20561 GL261 Parvg CTGTCTGAAACATAACAGCA 14578 MC38 Trim37 AGGCGTGTCGGGCGTCGGCG 20562 GL261 Ndufs6 TAACTGTGCGCAGTGTTCAA 14579 MC38 C 25 AAAGGGAGGTGGGAAGGAGA 20563 GL261 Ndirfs6 TCGTCCTATGCCTGAGCGGC 14580 MC38 C 25 GGAAGGGTGACGTCACTGGG 20564 GL261 Nd s6 GTTACTAGTGTGACAAAGGC 14581 MC38 C 25 CTATAAACCAGGACATAGAC 20565 GL261 Asxl3 GTAGGTACTGTGCTCTGCCA 14582 MC38 Bean CTGCGCGACTAAGTTTGAGC 20566 GL261 Asxl3 ATGCTCGCACAGTGTCCTCA 14583 MC38 Bean CAGGATGGAGAGTTAGAACA 20567 GL261 Asxl3 GCACACGTGCAGAGAACATA 14584 MC38 Bean AAGTCTTGGGCTCCCGTCCG 20568 GL261 Grwdl GCCACAAAGTAACCGCGTCC 14585 MC38 Ncapd2 TTTCAAGCTAGCGGAGGAAC 20569 GL261 Grwdl AGGTAACAGTACAGTGGGAC 14586 MC38 Ncapd2 CAGGAGGCCAATCGCGACAG 20570 GL261 Grwdl ATAAGTCTTCTCACTGAGCC 14587 MC38 Ncapd2 AGGTITGAACAGGGAATTGC 20571 GL261 Cdlil6 AAGTTATGTCTAAGCCCAGA 14588 MC38 C uk AATAGGAACCGCACGCACGA 20572 GL261 Cd l CTCATTGGGCTGTGTCAAGG 14589 MC38 Chuk TCGCAGGTTGGAAGTTGCCC 20573 GL261 Cd l GAACAATATCTGGAGAGATC 14590 MC38 Chuk ACTCTGCATGCGGAAGCTAG 20574 GL261 Myol5 CTGGTGATTATAGAGAAATA 14591 MC38 M ll 2 GGCGTGCGGAACACGACTGA 20575 GL261 Myol5 AAGGGAGAGAGCTCTAAGGC 14592 MC38 Mppll2 AGCGGAAGCGACGCTCTATC 20576 GL261 Myol5 CAGCCTGGAAAGCAAGTAGT 14593 MC38 MipU2 ACCGCCTAGTGCGTAATACC 20577 GL261 Gpat2 ATATAGGGTGTCAAGGGATG 14594 MC38 5730455P16Rik AAAGGACAGCCCGGCCGCGG 20578 GL261 Gpat2 GAGCAGTGATCATGTGGTAC 14595 MC38 5730455P16Rik AACTCAGATGTGCGAGGGCG 20579 GL261 Gpat2 TGTGACTGAGCCGACGAAGC 14596 MC38 5730455P16Rik GTTGGAGAAACCTGTTCTTC 20580 GL261 Trpnr5 CCCAGTTATTCACAACCGCC 14597 MC38 Nacc2 GGGCAAGCACAGTCAGGAGA 20581 GL261 Trpnr5 ACTGTCAAGAGCTGTCATGA 14598 MC38 Nacc2 GGCGCCCGCGGGCTGTTTAA 20582 GL261 Trpnt5 AAGGAGCTGGATAGATCAAC 14599 MC38 Nacc2 TTGAACGCTAAGTGCTCGGA 20583 GL261 Bace2 GGCCTCCCGGGCACGTTCCG 14600 MC38 Poteg CTGTGTTTAGAAGCGTTGCT 20584 GL261 Bace2 CTCGTCATATCCGTTAGCCG 14601 MC38 Poteg TATGGGTAAAGGTGCTGAGT 20585 GL261 Bace2 CTCCTCCGTGGCCAAGGTCA 14602 MC38 Poteg CTAGTTTACCCAAATGAGAA 20586 GL261 Stag2 AAACACATTAAGAGACACTG 14603 MC38 Ppplrl2a AGTCTCGAGCGTCTCCTCCC 20587 GL261 Stag2 AGGCTCGTTTGTGTCTAITT 14604 MC38 Ppplrl2a CTCGCGGCTCCGCTCCGCTC 20588 GL261 Stag2 GGTGGCGCTTCGGGATTGTT 14605 MC38 Ppplrl2a CTCTCTTTCTGTCGCCGACG 20589 n GL261 Pla2g3 GATGCTTCCAGGGCAGCCCG 14606 MC38 Caapl ATTAAATCTTCCCAGAGGTT 20590 GL261 Pla2g3 GACACGATGAGTGGAGGCGT 14607 MC38 Caapl TTACTACGCGTAGCTTCTGG 20591 n GL261 Pla2g3 GGGCTTGTAACCGAATCCAC 14608 MC38 Caapl AAAGGTGACGTGTGGTCCAA 20592 o GL261 Uaca CTCGCTCAACCGGGTCCCTC 14609 MC38 Gm597 AGCAGCAGGATTTAGAGGGA 20593 GL261 Uaca AGACGGGCCCGATTGGCTGC 14610 MC38 Gm597 AGAAAGCCAAGAGTTGGGTG 20594 GL261 Uaca AGAGTGTTACGAAGTTTAAA 146 11 MC38 Gm597 AAAGGTCAGATCTGTACTCC 20595 GL261 Faml96a GGCTGAGGAGCTCCGCGCAC 14612 MC38 Zfp248 GCGCCCAACGGTGCTCGTAG 20596 J GL261 Faml96a GTAGACTCAACAAGTTCCAG 14613 MC38 Zfp248 CCACGTCCAGTGTTGGAAGA 20597 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Fanil 96a ACCCTATTGATTTCTTCTTC 14614 MC38 Ζ 248 GTTGAAGGCGTCTAGAAACC 20598 GL261 Gja3 GGTGAGACAGGATTCCGGCT 14615 MC38 Steap4 TTTAAGCCAAAGAGCGGAGG 20599 GL261 Gja3 GGGATGCAGACTTGTTCCTC 14616 MC38 Steap4 GTGCAGCTCTGGCTCGCAGA 20600 o GL261 Gja3 CCCTCACCGGGTCCCGTCTG 14617 MC38 Steap4 GGCCCGCTTGATTTCGCAAG 20601 GL261 Rpp251 TGGGCCCTCTGCAGGTAGCG 14618 MC38 Zfp275 TGAATCCTAAGTGATGAGTG 20602 50 GL261 Rpp251 CCGATAGCCGTTCCTTTCCC 14619 MC38 Zfp275 GAGGTGGGATAGATGAGACT 20603 r GL261 Rpp251 TCGCCTGTGATGGTGGCATC 14620 MC38 Zfp275 CCAATCGCAGCCGACAGGCC 20604 o 4 GL261 Phykpl GCCCTTCTCTCCTACGCCCG 14621 MC38 Ucp2 GACTTAAGTTCTGTAGGCGC 20605 GL261 Phykpl GGATACTCTCCGCTGATCCA 14622 MC38 Ucp2 GGAAACGCCTCCTCACCCGG 20606 GL261 Phykpl GCTTGCAGTTCACGTCATCA 14623 MC38 Ucp2 GGGTITCAGGCAACCACAGA 20607 GL261 115 TTTCAGGACTCGCCTTTATT 14624 MC38 Slc35a3 GTCCCGCAAGCGCGAAGCTG 20608 GL261 115 AATTGCTAACAATCAGATAG 14625 MC38 Slc35a3 CGCCGGAGAGTTTGATAGGA 20609 GL261 115 TGTTTGAAGACCCAGGGCAC 14626 MC38 Slc35a3 CAGCTCCCGTGACAGTCTCA 20610 GL261 Cbwdl GTGTATCTATCTCTGCGTAG 14627 MC38 Rin2 TATGGCAGATCGCAGAAGAA 2061 1 GL261 Cbwdl GATGTCACCACAACGCGTCG 14628 MC38 Rin2 CAACTAATATTGGTTCCTTT 20612 GL261 Cbwdl AGTTTGAATAGTGGCGTAGC 14629 MC38 Rin2 AGCTTTCACAGCAGATTATG 20613 GL261 Gm884 TTAATCTCCTTTGGATTTAG 14630 MC38 Algl2 AGATGGCCACTCGTGGAGGG 20614 GL261 Gm884 AGGTTCAACTACCGTTCCCA 14631 MC38 Algl2 CAGAACCGTAATCTTCTATC 20615 GL261 Gm884 GGGTTGTGATTCCAAGCAGG 14632 MC38 Algl2 GTCAGCGTCCCGCGAGAATG 20616 GL261 Cilp GCTGGAGATGTAGGGATGGG 14633 MC38 Stxbp3 ACACTACGCAGCCGCAGTCC 20617 GL261 Cilp GGGAGTCTCATGCTCAGATC 14634 MC38 Stxbp3 TCAGACTTCTGTGCACTGTC 20618 GL261 Cilp CATCAAGATCCTTAGGGATG 14635 MC38 Stxbp3 TGACGTCACGCGCATCAACT 20619 GL261 Peakl GGAGCGCGCTGTGGACTCCG 14636 MC38 Deimdlb ATGCGCAAACCAGCTGTTAT 20620 GL261 Peakl GGAGGAGCGAGCGGACTGGT 14637 MC38 De dl b ACCACAGAGCCATTACACGA 20621 GL261 Peakl AGACCGCCGAGGTTTGGTGC 14638 MC38 Deimdlb CGAACCAGGAAGTCGGCGGG 20622 GL261 Sucla2 TGCTTTGTGCCTGCCAAACC 14639 MC38 Cep83 GGGACGCGCGCGGTCCGCTC 20623 GL261 Sucla2 GGCGCTCCCGGCCCGAGACA 14640 MC38 Cep83 GGGAAACTCGGAGGGCTGAG 20624 GL261 Sucla2 CACTGAGGTCAAAGTTCTGA 14641 MC38 Cep83 GGTGCTGATGACGTAGGACG 20625 GL261 Nlrxl TGGAGGCGTTCCTTGTTTGA 14642 MC38 Pdia2 GAGGTCTAGGGAATGCTTGC 20626 GL261 Nlrxl GGCCTCTGACCACTTTGGCC 14643 MC38 Pdia2 GGGACATCTGGTCACCAACT 20627 GL261 Nlrxl GGATGTCAGACAGGAAGAAC 14644 MC38 Pdia2 GGTAACATTTAATAGGCACC 20628 GL261 Synpo GGGTGGAGAGGCCATTTAAA 14645 MC38 Map7 AGCTCCGACCTCGTCCGTCG 20629 GL261 Synpo CTGGTGAATCTGGCTGCGTG 14646 MC38 Map7 GTGGCTAGGACCCGCCGCCT 20630 GL261 Synpo GGTGAGGCCTTGGCCACAGG 14647 MC38 Map7 GAGCGCTGGCCCGACGCCGC 2063 1 GL261 Col4a4 CTTCGGTGCCTAGCGGGTGC 14648 MC38 Acini GTCAAGTGGCTTCAGAGGCC 20632 GL261 Col4a4 GCAGCCCTGCCCAGATTAAG 14649 MC38 Acini TGATCTCTGGGCGTCTTCCA 20633 GL261 Col4a4 GGTCAACGTGAGGAATTTAG 14650 MC38 Acini AGAGTTGGAGCAGGAGCTGA 20634 GL261 Itgb21 GAAGCATTCTCATAGACCAG 14651 MC38 Co 4a 3 CGCGCGGGAGTCTGCAACTC 20635 GL261 Itgb21 AGTTGCTCTCAGCGGCTACA 14652 MC38 Col4a3 CTGCCAGCAAACTTGGCCTC 20636 GL261 Itgb21 GCAGACACACCTTATGAGTC 14653 MC38 Sspo GCTCCACCACAGGTCGCCTT 20637 v > GL261 Gjb5 GGGCTGCCTAGCCATTGGCT 14654 MC38 Sspo GATAGCACTGTCCCACAATG 20638 o GL261 Gjb5 GAGGCAGTCTTTGAGAGTCC 14655 MC38 Sspo TTTGAACAGCTGGTACCCAG 20639 50 GL261 Gjb5 CCAGGCGTGTCCTGTTGGCC 14656 MC38 Shc4 AGAGCTAATAAATCTGTGAA 20640 GL261 Six4 GACATCCTCTTGTACACCGT 14657 MC38 Shc4 GCTACTAGTTAGTATATTCA 20641 GL261 Slx4 TGTGTGATGTGCTCTGCACT 14658 MC38 Shc4 TCATGAAGCTGCAGCCTGAT 20642 50 GL261 Slx4 GAAAGTCTCCAAATACAGTC 14659 MC38 Srrm2 GTAGCACGTCCCTTCGCCTA 20643 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Spag7 GTCTGATTCCCTGGCGCGGC 14660 MC38 Srrm2 TGATTGCGTGCTGACGCACT 20644 GL261 Spag7 ATTTAAGGCGCTGCGCGGCC 14661 MC38 Srmr2 GGCTCCGTACCGAAGCTGCA 20645 GL261 Spag7 TTTCTACTTGTGCATGGGCT 14662 MC38 Pop5 GTGTGGTCCCTGACAGCACC 20646 o GL261 Pik3ipl CACTAACCCTGAGCCAAGAG 14663 MC38 Pop5 TGGGATTGCACCGGCACGGG 20647 GL261 Pik3ipl TGGTAAGGTCTAGGAGGCTT 14664 MC38 Pop5 TTAATAATCGGAACTAGAAG 20648 30 GL261 Pik3ipl GCAGTTGTGCAGGTCTCACG 14665 MC38 Usp53 AGCCGGGAACTCACGTGCGG 20649 r GL261 Neill AGAGAGGCATAGCGCCATAT 14666 MC38 Usp53 TCGCGCCTCACACAAGCCCT 20650 o 4 GL261 Neill TAGGCAAAGAAATGGTGGCC 14667 MC38 Usp53 GGAAAGGGAGCATCACCCGC 20651 6 1 GL261 Neill GAATGGCTGGGCCCTGTAGT 14668 MC38 Inpp5j GCACCCACTTCCCATATTGA 20652 GL261 Gm7173 GCACGTGGGATTCCAACCGT 14669 MC38 Inpp5j AACATAAGCACCCATCAGCT 20653 GL261 Gm7173 TCTTGGTTCTATAATAGAGC 14670 MC38 Inpp5j GGGCTAAGTGGCTACCCGCT 20654 GL261 Gm7173 GTAGCTAGGTAACAAGCACT 14671 MC38 Ralgpsl GCGGAGACACGCAAATGAAC 20655 GL261 Vsigl GTCATCACACATCATAAAGC 14672 MC38 Ralgpsl GTATGGTGCCGCGCGCCGAT 20656 GL261 Vsigl CTGGGCATCACCAAGCAAAT 14673 MC38 Ralgpsl TGCAGACGCTCAGGCTTGCA 20657 GL261 Vsigl GGTGCAACTGAGACTGGACA 14674 MC38 Alb CCTTGCGTATGTTTGCCATC 20658 GL261 Ccdcl5 CTAGAGCGGGTTGTTGAATC 14675 MC38 Alb GGTTAATGATCTACAGTTAT 20659 GL261 Ccdcl5 ATTTGTCACCCGTCTTGGGC 14676 MC38 Alb AATGAAATGCGAGGTAAGTA 20660 GL261 Ccdcl5 GCCGAGTCTAAGCTCGCTGC 14677 MC38 Mapklipll TTTCGTGGGCGGCCGGCTGG 20661 GL261 Mon2 TTTGGCTGGCTGGTAACCTG 14678 MC38 Mapklrpll GACAGCGACACGGCTCCTCC 20662 GL261 Mon2 GCCACCTGCGTCGACGGCGG 14679 MC38 Mapklipll GAAATAACGGGCGGCCAGGT 20663 GL261 Mon2 ATGGATCACAAACAGACGTA 14680 MC38 Mbnl2 CGTCTGAAACTGGTCCTCAT 20664 GL261 Xirpl CCATTCAACCCAAGTCTGCC 14681 MC38 Mbnl2 CTGACACAGCAACACAGCGC 20665 GL261 Xirpl GCTATGTTCGGAGTATTAAG 14682 MC38 Mbnl2 ATGACTGCTTTCCTCGGAGA 20666 GL261 Xirpl GGAATCAGTTACAATTCCTC 14683 MC38 Rapgef2 TGCAAGCCTCACACTCGCTG 20667 GL261 Angel2 CTTTGAACTTGTAAAGACTG 14684 MC38 Rapgef2 AACGGTACACACGTTCCTTA 20668 GL261 Arrgel2 TGACGGCTTTCTTAAGACAT 14685 MC38 Rapgef2 TGAATATTTCAGCGTATATG 20669 GL261 Angel2 GTGCGCGGACAGCCATTTCC 14686 MC38 Ligl CGCTGTCCCGCACAGCATGC 20670 GL261 Nckipsd CCTCGCGGCCGAGAGAGGTT 14687 MC38 Ligl GGTGAAGAGCTCCACACGTG 20671 GL261 Nckipsd CGCACGCGCGGCGTGTCACG 14688 MC38 Ligl TTGCGGCACGCGCTACTCGC 20672 GL261 Nckipsd TGGGAGTCTCCAGTTCCTTC 14689 MC38 Grin CTTTGCGTACATCCGCCAAA 20673 GL261 Alxl TAGGACTGGGAGGTTGCCGG 14690 MC38 Grin3a AGGAGAATCTCACCATCAGT 20674 GL261 Alxl TGTCTGTCTGAACTAGGCCG 14691 MC38 Grin3a GTTTAGCGCAGCCAAGCGAC 20675 GL261 Alxl TTTATATCTTGAAACTCAGC 14692 MC38 I118rap GGTACAGGAAATTCCTGTAA 20676 GL261 Klra5 TGAGGTTGAGTATCACTAGG 14693 MC38 I118rap TTCATCAGAAGAAAGCCTTT 20677 GL261 Klra5 TTTGCTTAGATAAAGAGGAG 14694 MC38 I118rap CCGTGTCGAATGTTAACATT 20678 GL261 Klra5 GATAGACACTCCTACAGAGA 14695 MC38 Acsl3 GGGCTCGGCCTATCAAATGC 20679 GL261 1112*1 AAGCCAGGAAGTCAGCCCAA 14696 MC38 Acsl3 GGTTACTATGGGTCATTCTG 20680 GL261 1112*1 GGTGGGTTTGTAGTGCAGAG 14697 MC38 Acsl3 CGCCGACGGCTGGACCCGAC 20681 GL261 1112*1 GAGTAAGCCTAGAAATCTCT 14698 MC38 Cep192 CCGCGTGTTCCTGGATTTGA 20682 GL261 Zfp354b GGATATAAAGTTGACCGCTT 14699 MC38 Cep192 CCGAAGCCGCGCAGTTTAGA 20683 v > GL261 Zfp354b TTCACAGAGCTAGTGACCCG 14700 MC38 Cep192 GGCGGGCAGAAGCCTGTGAT 20684 o GL261 Zfp 5 b AATGAGGATAGCTGATGCAG 14701 MC38 Noc31 TGTCTTCTCCAGGACTGAAA 20685 30 GL261 Pdella ACAACTAGAGGCCTCGGGAC 14702 MC38 Noc31 GACTCAAGCAGGTTCCCGCC 20686 GL261 Pdella CCAGGCAGCCGGAGGTTGAC 14703 MC38 Noc31 CGAGTGGGCGTCCCAGCTGA 20687 GL261 Pdella AGGAAGGTAGTGCCGAGCTG 14704 MC38 K 32 CAGGGCCATAGTAGCAGCAG 20688 30 6/1 GL261 Rhd GAAGCAACATTTATTCAGTA 14705 MC38 Klhl32 TGTCACGGGCGAACGCGGCG 20689 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Rhd CCTAGCTCGGAGGGATGTCA 14706 MC38 K1M32 TGACCCGCGACAAGCGGCTC 20690 GL261 Rhd TAGGGAGAGACACCCGCCAA 14707 MC38 Spaml AGAGCAAATTCCAAGATTCT 20691 GL261 Sirt7 CAAGGGTGGGAAGGGCGAGC 14708 MC38 Spaml AGTTGAAGGAAGAGGGAAAG 20692 o GL261 Sirt7 GTATTTCTTTGAAATCCCGA 14709 MC38 Spaml TCATAGGAAAGAAGTGAATC 20693 GL261 Sirt7 TCTGTAGCTGCCGGATGAGG 14710 MC38 Snmp70 GCAGTACGACAGCCGGGCCG 20694 90 GL261 Ec l CCATTCTTCCCAGGCTAAGG 147 11 MC38 Snmp70 GACCGCGAGACACTTATGGA 20695 r GL261 Ecml GTGATGGAAGGGAGCACTCC 14712 MC38 Snmp70 ATGCGTGATCGGACCTAGGT 20696 o 4 GL261 Ecml TCCTCTGCATCAGTTTGGAG 14713 MC38 Tmeml45 CAGCTGTGATCCTCTTCTAC 20697 6 1 GL261 Didol AGATGCGAACTGGCAACCAA 14714 MC38 Tmeml45 CTCTCTCAGGTGGGAAGAGT 20698 GL261 Didol AGACACAGAGTTTAAGCTTT 14715 MC38 Tmeml45 GCGGAGACCGCTGCGTCCAG 20699 GL261 Didol GGGTTGGCGCGAGAGTCAAA 14716 MC38 R3hccll ATGGACGATACAGGAGATAG 20700 GL261 Epts CAGTCGTGGCGCGTGGAGTG 14717 MC38 R3hccll ACAGCTGAGGGTTGAGATGG 20701 GL261 Eprs GAGAGAGGCTGAAATGTCGT 14718 MC38 R3hccll ACAACTCCCAGGAGGTCCCG 20702 GL261 Eprs TCATAAATATGCGCCCGCCA 14719 MC38 Uspl8 GGACCTGGCCCGGTAACTCC 20703 GL261 Fucal AAATTCCGTAGACTCGCCTA 14720 MC38 Uspl8 TACACCAGGACACGACAAGC 20704 GL261 Fucal TTGGAAGGGAGAAAGACTTA 14721 MC38 Uspl8 TCGCTTTCCTTTGGATCTAG 20705 GL261 Fucal CCGCCTCTCAGAGTAACGAT 14722 MC38 Pdelc CAAGTTCCATTCATATGATT 20706 GL261 Mfsdl3a GATAAGTACTTCAGGAATCC 14723 MC38 Pdelc TCATTGTAGGGCATAGGGCT 20707 GL261 MfsdBa CGGCTCTCCCGATAGCAGCT 14724 MC38 Pdelc TCTCTTGGGAAGTTAACTAA 20708 GL261 MfsdBa AAACGGGCATCAGGCAACAG 14725 MC38 Sipall2 CAAACAGCATCCTCAAAGCA 20709 GL261 Atg2b CGAGTACGTGCCGGGAGTCT 14726 MC38 Sipall2 GGCCACGACGAGTGTGCTCC 20710 GL261 Atg2b TCCTCGTCCGGAGACTGCTG 14727 MC38 Sipall2 ATGAGAAATCGCCTGTAGAC 2071 1 GL261 Atg2b AGTCCGGGCCGGAGCATTTC 14728 MC38 Pipfi CACCGGAACCGGAAACCTTC 20712 GL261 Ccdc33 AACGGATTCCTGGCAGCCTC 14729 MC38 Prpfi GTCCCTACGGCACGTGACTA 20713 GL261 Ccdc33 TGAGAGATCAAATGCTAAAT 14730 MC38 Prpfi ACGGCGGGCCGTAGGGCAAC 20714 GL261 Ccdc33 CCACGCAGATGCAGTACAGC 14731 MC38 Gstm4 TACGCTTTCCGGTCTGTTGG 20715 GL261 Gbp3 GTTTCTATTTCCCAGATCCC 14732 MC38 Gstm4 CCTTCTTACCCTGTTGCCTT 20716 GL261 Gbp3 TCGGTGATGGAACACACTGT 14733 MC38 Gstm4 AGAGCGGTACGGCAAAGGCA 20717 GL261 Gbp3 AAAGATGATTGCTCAAGCCC 14734 MC38 Afmid CATTTGCCCGCGAACTCAAA 20718 GL261 Rtell CTAGACGATATTAAGTGCTT 14735 MC38 Afmid GGGCAGATTGATGTAGCTCA 20719 GL261 Rtell TCAGCAGGTTCCCTCGCCTC 14736 MC38 Afmid TAGCACCGAGAGTCCGTGGG 20720 GL261 Rtell AAAGTAGCGGACCGGAAGGG 14737 MC38 Krt CTTTGGCTTCCTGCTATGTC 20721 GL261 Zmf3 CGTGGCTAAGAACGGAGTCG 14738 MC38 Krt33b GAGGTGGCTAAATAACAAAT 20722 GL261 Zmf3 AGCGGGTCACGACGCTGCGG 14739 MC38 Krt33b ATAAAGCTCCAAAGAGGACC 20723 GL261 Zmf3 ACCTTGTGTGACAGTGGCAC 14740 MC38 Syte CTGCATGATGTGGGACAGCG 20724 GL261 Pdzd3 GGGTAATGGTTAACAGCAAT 14741 MC38 Syt6 GCCGCGGGATGCCACGTGAG 20725 GL261 Pdzd3 AGGTAGGGCGCAAGACCTGG 14742 MC38 Syt6 GCTGTCTGCGTCTCGCCGGG 20726 GL261 Pdzd3 AAGACGCTGCAAGGAAGCAT 14743 MC38 Vstm4 CCAGGAGGACGTTGTAACGT 20727 GL261 Ano6 AGCGCTGCAGCCGCAGAGGC 14744 MC38 Vstm4 CTGTACAACGTGAATCTCCA 20728 GL261 Ano6 CCGGCTTCTATGAGCTCACG 14745 MC38 Vstm4 AGACGTGGGCGTGGTGAAAG 20729 v > GL261 Ano6 GGGAGCGGCGGCGTCCCTCT 14746 MC38 Obsll AAGTCACTCAAGCCCAAGCC 20730 o GL261 Cars ACTGCAAACTGACGCCGACG 14747 MC38 Obsll ATATTCTCTGATGACACAGC 2073 1 90 GL261 Cars CGGAACTTAATAGACACCAA 14748 MC38 Obsll GGCCTCCAGGTCTCCAACTG 20732 GL261 Care GACAGTGAGAAGCGCAAACC 14749 MC38 Milt 10 TCCAATACCCTCAATTCTAC 20733 GL261 A3galt2 TTTAATGTTGGGTGGTGATG 14750 MC38 Milt 10 GCGGAGTCGGCTGCTCAGCG 20734 90 6/1 GL261 A3galt2 AAGCTATTTAGAAAGCGATG 14751 MC38 Milt 10 GGCCGGAGTGAGTCTACCGG 20735 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 A3galt2 TTCAGATTGTACTCTGTACG 14752 MC38 Dhx9 GTCGGCGACTCGCGCCTGCG 20736 GL261 Bcor CGCGTTGGGATCGCGGCGTG 14753 MC38 Dhx9 AGCGACTGACAGGAAATTAT 20737 GL261 Bcor CTAAGATTICACTCCGCGCC 14754 MC38 Dhx9 CGCGCGAGATCTGCTGGCCT 20738 o GL261 Bcor GATAGTCTCCAAACTCACTT 14755 MC38 Sall3 TCGGCGCGGCCCTCCGCTAA 20739 GL261 Tdrd6 GGCTGCCTGCCTTCTCGGCG 14756 MC38 Sall3 GGCCGGCCTCCAGCGGACTC 20740 50 GL261 Tdrd6 GGACTACCAGCAAGCCTGTG 14757 MC38 Sall3 TTAGGCTGGTGAATAATGCA 20741 r GL261 Tdrd6 TCGCAGGCTCAGATAGCGCG 14758 MC38 Pent GCGATAGGTAGCACCGCCTC 20742 o 4 GL261 Crta GAGAGGTGTGAACGAGGTGT 14759 MC38 Pent CGATGTGTTTCTGCGAACAC 20743 6 1 GL261 Crtam CACAGGTGTCCTATCCATTG 14760 MC38 Pent AAACGACTTTGGCAAAGTGC 20744 GL261 Crtam CACCTCCTGGTGGAACATCT 14761 MC38 Vav2 CCCGGCGAACAAAGCGACGG 20745 GL261 Propl AGAGCAGCATCGGGAAGTAG 14762 MC38 Vay2 GGAGCGAGCAGCTCAGGCGC 20746 GL261 Propl AAGGATGCAGGGTTAGGAAA 14763 MC38 Vav2 TCAGAATGCGGCGCCCAGAG 20747 GL261 Propl AGAATGAGATGTCAATTCAG 14764 MC38 Abca6 TTGATCTCATCATATCTGAA 20748 GL261 Ttloc5 GGCTCGCGACCATAGAGAAG 14765 MC38 Abca6 TCTCAACCAATCACAGAACA 20749 GL261 Thoc5 TAATTCACACTCCGGTGAAG 14766 MC38 4931423N10Rik TTCAGGTAGTCGAGGGTCAC 20750 GL261 T o 5 CGAGTCTAGTTCTATTAAGT 14767 MC38 4931423N10Rik ACATGCGCATTAACCTTTAT 20751 GL261 Ttc3 d TAGCTGTGAGATGCAGCGTT 14768 MC38 4931423N10Rik TTTGCAGAGATTTGACAGGC 20752 GL261 Ttc d TCTATGATCTATGTCAGACA 14769 MC38 Tln2 AAGCAATGTATTAGTTAGCC 20753 GL261 Ttc39d TTTGCTTTCTCGGTTAGAGG 14770 MC38 1η2 AAGGTGTGTGCTGCCATGCC 20754 GL261 Sox30 GCCCGTCTGTGGAGCGCGTA 14771 MC38 Tln2 GGCAGGCAGATCTAAGTGTG 20755 GL261 Sox30 GAAGGGTCTTAACCGAAAGG 14772 MC38 Foxi3 ATGCTCTCTCCGAAGTGCCG 20756 GL261 Sox30 TGAGCTCACAATCCCGGCCG 14773 MC38 Foxi3 GGTACCGCGTCTCTTATACC 20757 GL261 Dlgap4 AAACCAGGCGCGGATCAGGC 14774 MC38 Foxi3 CCGTAGGGTTGGTCCGCCAA 20758 GL261 Dlgap4 GGGCATGCGCGAGTTGGCGC 14775 MC38 Plekhsl AGCATTACACCTGATGTTCC 20759 GL261 Dlgap4 CCCGCCAAACCGGTTCCAGC 14776 MC38 Plekhsl GTTCACATTTCAAACAGAGC 20760 GL261 Gucy2c ACCCGTTTGTGACACATCAC 14777 MC38 Plekhsl TGTGAGGGTGGATTAAGTAC 20761 GL261 Gucy2c CTATAAACGACAGGATTACC 14778 MC38 Padi6 CCTGTGAACCCTTAACAAGG 20762 GL261 Gucy2c CCTGCTAATTACTGGCAGCC 14779 MC38 Padi6 AAACTITGATGCTGAGTAGA 20763 GL261 BC003331 CTACATITCCCAAGAGTCTC 14780 MC38 Padi6 CTGGCCTTCCTCTTTAGTAG 20764 GL261 BC003331 TGTGACGAGTGCCCGCGCGG 14781 MC38 Ppplrl5b ACGCGGCGAGTTGCATCAGC 20765 GL261 BC003331 GCGGCCTGAGCGCGCGTAAG 14782 MC38 Ppplrl5b AAGGGCTCGGGAGAATTCTC 20766 GL261 Anxa7 GAATTGTGAGTAGACAGAAC 14783 MC38 Ppplrl5b GCAAGCGTACATCCTAGGTC 20767 GL261 Anxa7 AGCAGGGTTCAAAGTTCTAC 14784 MC38 Apbal CGGGTGGGCGTGGGAGGCAG 20768 GL261 Anxa7 TATGGTGAGTTTAACACTAA 14785 MC38 Apbal CCCGACGCGACAGTCCAGCT 20769 GL261 Shank2 TGCTAGCTGACAAATAGACT 14786 MC38 Apbal CAGTCGCAGCCGCCCGGCCC 20770 GL261 Shank2 CTCTGCGCGGGATGACGCCC 14787 MC38 Ncoa3 CGCCCAGCACTACGGGTCCC 20771 GL261 Shank2 CGCCATGGAGGCCAACGCTG 14788 MC38 Ncoa3 GGAGGTGAAGAGGACGTTCT 20772 GL261 Vas CTGCGCTTGCCCGGGAACCC 14789 MC38 Ncoa3 CCGTTTGCCTGTCTCCATCC 20773 GL261 Vash2 TCATTGCTGCAGAAGGCTGT 14790 MC38 Xirpl CCATTCAACCCAAGTCTGCC 20774 GL261 Vash2 GCCGGCCCGAGGTGGGTCCC 14791 MC38 Xirpl GCTATGTTCGGAGTATTAAG 20775 v > GL261 Tas2rll5 AAGAATTTCAGCCAAGCTGG 14792 MC38 Xirpl GGAATCAGTTACAATTCCTC 20776 o GL261 Tas2rll5 CACTAAGAAATATTCACCAA 14793 MC38 R y2 GCCAAGGGAGGATGTAGATG 20777 50 GL261 Tas2rll5 GACTTTAAAGTCTATTCCAT 14794 MC38 Rufy2 ACGCCACGGCCGCGTGAAGC 20778 GL261 Prickle3 TTCCGTAAACTTGACTTAGT 14795 MC38 R y2 GGGCCTCAAGCTACCTGTCA 20779 GL261 Prickle3 CCATTAITGGCGTTCATCCC 14796 MC38 Tox4 GGGAACAGGGTCTAAGGCAG 20780 50 6/1 GL261 Prickle3 AGGCACTCACCTTTAGATAG 14797 MC38 Tox4 CACCGTTCTTTCGCAGGTGT 20781 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Abca8b CTGGCCATGTGGCTGTATAA 14798 MC38 Tox4 TCACTAGACGCACGTCACCC 20782 GL261 Abca8b TAACTGGCACCGCCCTGCGG 14799 MC38 Xkr8 GCCGCGGGCTCGCTCCACCC 20783 GL261 Abca8b TAAATGTTGCTCTCCAGCTT 14800 MC38 Xkr8 CGGGAGGCTGGGCTGCTGGG 20784 o GL261 Mfsd4b3 ACACTGGCTTGTGCAAGATG 14801 MC38 Xkr8 CTCTGCACAGGGCAGGCTGG 20785 GL261 Mfsd4b3 CCAGGAACCTTTCTGATATT 14802 MC38 Dhxl6 GGCGACGGAGAGCTTGGACG 20786 80 GL261 Mfsd4b3 CTCCTGCTGGAAGCGAAACG 14803 MC38 Dhxl6 CCCGCGCACAGATCATTAGG 20787 r GL261 Raplgdsl CGCTCGGCCGCGCGTCGGGA 14804 MC38 Dhxl6 CTCTTCCGGCCAGGGATCGA 20788 o 4 GL261 Raplgdsl GGAGGCGCCGAGCCGTCCTG 14805 MC38 Utpl4b GCGGGAGGAAGGATGCACCG 20789 6 1 GL261 Raplgdsl GGGCGGCCGGGCGCAGCCTG 14806 MC38 Utpl4b TACCTCCCACGGACGCCGCG 20790 W GL261 Stard6 AACCGACCCAACATGGCGCC 14807 MC38 Utpl4b AGGGCGTCCTCGCGGATTCG 20791 GL261 Stard6 GGAAGGCGGTGACGCGCTCC 14808 MC38 Prickle2 CGTGCTCTCCCGAACCAGGC 20792 GL261 Stard6 GAGCCCGGCGAAGAGTTCAG 14809 MC38 Piickle2 TTTGCATTCTGCCAGCTAAG 20793 GL261 Clcal TACTGGAGGTGATTTATTAT 14810 MC38 Prickle2 AGCAAGTCAGTCACAGCATC 20794 GL261 Clcal ACATTTGCCTACAATATAAG 14811 MC38 Fam64a CGTGACTGTAAATCCTGCTT 20795 GL261 Clcal TTTAACCTCTTGACCCTAAA 14812 MC38 Fam64a GGCCGCGCGGAGTTTCAAAT 20796 GL261 Manic 1 GGGAACCTAGCCGGGAAAGA 14813 MC38 Fam64a GCGGTGGTGGATGGCTGATA 20797 GL261 Manic 1 GCGCCAGCATTTGGAGCGGG 14814 MC38 Nrg2 CGCTAACGTTACGCTGTTTC 20798 GL261 Manic 1 CGCGAGGCGCGCTGTAGGCG 14815 MC38 Nrg2 GTGGGCCGCGATGCGCAGCC 20799 GL261 Caidll GGCCTGGCTGTAATGAGGGA 14816 MC38 Nrg2 GCTGCCGGTGGAGGGCTTCG 20800 GL261 Caidll TGAGCTTGAGCCTAAGGCTT 14817 MC38 Tscl CCACTTATGACGATACAAGC 20801 GL261 Caidll TTCAAATCTCATTTCCTGTC 14818 MC38 Tscl GCGTGAAGCGTCTCGAGCGG 20802 GL261 Zfp62 CGCACGTGACCCGCAGTTTG 14819 MC38 Tscl GCGTAGTAGAGACCCGAATA 20803 GL261 Zfp62 GGGCACTTCCGAGGCCGCTC 14820 MC38 Ints5 TAGGCATAGGAAAGCTTCCG 20804 GL261 Zfp62 CTCTGCTGGCCTCCTAATCC 14821 MC38 Ints5 GGGCTCCAGACTTAGCCGGA 20805 GL261 Cd 16412 ACATAGTAGCTATGTTGACA 14822 MC38 Ints5 CGACGCGGAACCAAAGTACT 20806 GL261 Cd 6412 GGGAATCACTTGTGTAGCTC 14823 MC38 Kifl4 TATCTACTGAGGGTTCCCTT 20807 GL261 Cd 16412 CCGCTCTGCTGTGCGATTTA 14824 MC38 Kifl4 TGAGAGTTTGCTTCTGTAGT 20808 GL261 Map3kl5 ATGACGGACGGGCGGACCGG 14825 MC38 Kifl4 TGTGGAGGTGCAGTGGGAAG 20809 GL261 Map3kl5 GGCTGGCGGCTTCGAAGCCC 14826 MC38 1700017B05Rik CGGGAAAGTTGGTTCCACTC 20810 GL261 Map3kl5 CGAGACACCTGCTGCACAGG 14827 MC38 1700017B05Rik GCAGAACCCGGCTGTGCCTC 2081 1 GL261 Cnksrl GAAGACAGGCGGTGGACCAA 14828 MC38 1700017B05Rik CCTGGGTCCTCCCGTGCCGA 20812 GL261 Cnksrl CAACTAGGCAGTTGGACTCC 14829 MC38 ZbtblO ACCGTGCGCCCACAATGCAC 20813 GL261 Cnksrl GTTGAATCCCATGCCAGTTC 14830 MC38 ZbtblO GGGTAGCAGTAACCGCTGGA 20814 GL261 Zfp362 GGAGCGGCGCGCAAACCTTC 14831 MC38 ZbtblO GTGCGGCCACGGGAAGGAAG 20815 GL261 Zfp362 GAAGTGAACAGCAGGCGACC 14832 MC38 Atnl GGGCGCGGGCGGCGCGTTCC 20816 GL261 Zfp362 CTGCGCAGCCGAGAGGCGGG 14833 MC38 Atnl CCGAAACGCGTCCTGGCCCG 20817 GL261 Ppara GGCGCATGCGCGCGGACTAG 14834 MC38 Atnl ACCAGCGGCGGGAGGGTCGG 20818 GL261 Ppara GTGTGTCTCGCCCTGAGCCG 14835 MC38 Tlkl CCACCGCCCGGGCGACGCCG 20819 GL261 Ppara CCGCGGCGAGGTGACCGCCC 14836 MC38 Tlkl GGAAGTGGCCTCGGTCGGCG 20820 GL261 Acan GTGGCTGGCTGACTAGGTTT 14837 MC38 Tlkl GTGCCGGCAGGTTCCGCCCG 20821 v GL261 Acan CACCTGCGTCAGATGCTAGC 14838 MC38 Taar7e AAAGATCCTCAGAGAAATAC 20822 o GL261 Acan GAAAGGTGCCCGAACTCCCT 14839 MC38 Taar7e GAATAGGGAGCAACTCTTTC 20823 80 GL261 Tnipl GGCTGGCTTCTCCATCATGG 14840 MC38 Taar7e GTCATTTGGAAGGTTTACTG 20824 GL261 Tnipl CCCAGGCTGCCTGTCACTTG 14841 MC38 mer3 CCCGAGAGGGAAGAAGAGGA 20825 GL261 Tnipl GCTCTGCCAGAGGCGGGATG 14842 MC38 Homer3 CCCTGCTGGCCAGCTACGGA 20826 80 6/1 GL261 Pcdhgal2 CAACCTGCATTAACTTGAAC 14843 MC38 Homer3 GAGGGCACCAGGAGGTCAAG 20827 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Pcdhgal2 ATGGACACCTTTAGAGTAAG 14844 MC38 Zfp609 GCCCTGGTTGTCCCGGATCG 20828 GL261 Pcx CCCTCCAAAGATTGGATGAC 14845 MC38 Zfp609 ATCCAGTGTCCAGGTCTTCC 20829 GL261 Pcx CCCGTAAGACTTTCCATTGG 14846 MC38 Zfp609 AGCTGAGGGACCCGCAGCCC 20830 o GL261 Pcx GCCGCCTCCTGAGGCCATCA 14847 MC38 Rassf5 TTCGCGAGCTCGGTAGGCGC 2083 1 GL261 Duspl8 GACTGGCTAGAGAGCGACTC 14848 MC38 Rassf5 TGAAGGTCCGAGCACCCGAG 20832 50 GL261 Duspl8 CTCTGTTGGGCGTGTTGCCT 14849 MC38 Rassf5 GGAGTGACTCGGCGACTAGG 20833 r GL261 Duspl8 CTACACTGGAGTGCGTTGCC 14850 MC38 Dctn4 GTGACGGGTGCGCCGGGCGT 20834 o 4 GL261 N d2 TAGGTGGCAAAGTTGGCTCA 14851 MC38 Dctn4 ACCGACCCAGCAGGACGTTG 20835 GL261 N d2 GGCCTGAATCACTTTCTTTG 14852 MC38 Dctn4 TACGTCAACGTCTACGTAAA 20836 GL261 N d2 TGGTAATCTGCACTCACTGA 14853 MC38 Gimapl ATGCTAAGACCACAACTACA 20837 GL261 Gpb l l GCTCACGCCTGCGCGTGCGC 14854 MC38 Gimapl TAGAGTGCGTGATTTCATAG 20838 GL261 Gpbplll AAATGGCTGCCCGGCCCACA 14855 MC38 Gimapl CTGCCTGGGTCTTAGAGATC 20839 GL261 Gpbplll CTAGTGGGCGTGAAGGAGGC 14856 MC38 Exosc6 CTTTAGCTAGTCCTAAGGAA 20840 GL261 Cypllal AGTGTGGCTCTGGAGGTTTG 14857 MC38 Exosc6 GTATAGCTGGACTCCTATGC 20841 GL261 Cypllal TCTTTCTCTGAGTTTGGGAG 14858 MC38 Exosc6 TTTAAGCGAGCGGAAGAGCC 20842 GL261 Cypllal CTCTCTTAGCCTTGAGCTGG 14859 MC38 Pikg2 GCTGCCGCCTGGCTGCTCTG 20843 GL261 Chchd6 TGTCTCAGCGTCTATTTGGC 14860 MC38 Pikg2 GCCGCGAGAAGGAGGCGCGC 20844 GL261 Chchd6 GGAITTGTAGTCCAGCATTC 14861 MC38 Pikg2 GGGTCAGCCCGGCGTGGCGT 20845 GL261 ChcM6 GGGCGTGGCTCTCTGAGGTA 14862 MC38 Csmp2 CCAGGGTGGGCGAGGGCTTT 20846 GL261 Ccdc30 GACGCTGTACACTGTTGTTA 14863 MC38 Csmp2 TCCCGGCTCCGGCTAACAAT 20847 GL261 Ccdc30 TTGTAGITCTGAGACTCAAA 14864 MC38 Csmp2 CTACACTTGGCCCACACCCA 20848 GL261 Ccdc30 CATGGAGACCATGCACGCTT 14865 MC38 Rcll TGCTCATGCCGCGTTGCCAT 20849 GL261 Mbd2 GGACCTAAGAGGCGCGGCCG 14866 MC38 Rcll GCACCGCCCTCTTTCACTAC 20850 c GL261 Mbd2 GCGCTCTGCCTGCCCAGTGG 14867 MC38 Rcll CCAGATCCCTCGTGGGCCAA 20851 GL261 Mbd2 GCGGAGCAGGTGGTCACGGG 14868 MC38 D130043K22Rik GCGGCGCAGGCCATCCCTAG 20852 GL261 Carl2 ACCCTAAACATGATGTCATC 14869 MC38 D130043K22Rik CGCGTGCGTATGCGTCGCCC 20853 GL261 Carl2 CCCAGGTCCGAGGTGAGTTG 14870 MC38 D130043K22Rik TCAGAACCATGGCAGGAAAG 20854 GL261 Carl2 CTGACITAAGTGGTCCTCAG 14871 MC38 Xlr3c ATGGAGATGGACTGTAGCTG 20855 GL261 Ankrd36 GTGCTTTGATTGGTTGCCTG 14872 MC38 Xlr TTTGCTTTCCTGGTGATGGA 20856 GL261 Ankrd36 TGCACACGTTTGATGCTTGA 14873 MC38 Xlr3c GGAGAACATTATATCAGCCG 20857 GL261 Ankrd36 CATCGGGACCATCTGCCTAG 14874 MC38 Clqa CCAGGGCCAGACACCACACA 20858 GL261 Mafa GCTCTGGTCGCGCCGCCGAA 14875 MC38 Clqa GTCCTGCCCAGCCACAGTTG 20859 GL261 Mafa AAGTTTCCTGCTGTCAACTC 14876 MC38 Clqa TAAGCGGACCTCAGCACGTT 20860 GL261 Mafa TGAGCCCACCGCGGCCCGGG 14877 MC38 A2m CTTAATCCTTCTGGGAATTC 20861 GL261 Dst ACGCCTCCACCCGGGTCGCG 14878 MC38 A2m TGATGGCCTAG1TACTGCCA 20862 GL261 Dst GCTCTCCATCAGTCGTTCCG 14879 MC38 A2m TTAATTCCTGACCCGTTAGC 20863 GL261 Dst GGGCGGGCAGCCTCCAGACC 14880 MC38 Mettll7 AGGGATCAGTCTCACGGGTT 20864 GL261 Defa35 TCTGCCCTATAAATGCAGGT 14881 MC38 Mettll7 GGCTGCGGGCGAGACCAACC 20865 GL261 Defa35 TTAGAGAAGGCACTCTTTGA 14882 MC38 Mettll7 AGGTACATAAGGTCGCTTAT 20866 GL261 Defa35 TTGATGTTCCTCTGTTCTGA 14883 MC38 Zfp410 ACGGCTAGACTGCACTGACC 20867 v > GL261 C2cd4a ATCCACGTGGCAGAGGGACC 14884 MC38 Zfp410 GGTCCGCGAAATCTGAAACC 20868 o GL261 C2cd4a AAAGCCCGGACCAGCTATCC 14885 MC38 Zfp410 AGGTGCTCTTCATGGGCTTT 20869 50 GL261 C2cd4a TGAGGAAACAAACTCGTTCA 14886 MC38 E pl GTTTCCGTCCGCTCACTAGG 20870 GL261 Rhox2g GAGGTGTGGCAGCAGACCAT 14887 MC38 Eraipl CTGCTCATTTCTAGGTTTAT 20871 GL261 Rhox2g TGGCTTAGAAGCTCTACTTC 14888 MC38 Ermpl CTAAGCAAGAGAGAAGTGCA 20872 50 GL261 Lars TGTAGTCCACGGACGCTTGT 14889 MC38 Prss40 GAGAAACTCTGGGATGTAGT 20873 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GTATGTCTACAGATAACTTC 14890 MC38 Prss40 CAGCTCCCGCGAGGGAGGTG 20874 GACTTCAATACTCGTTGTTT 14891 MC38 Prss40 AGTCAGCGGTTGTTTGCACG 20875 GAAGCTTAGTGCAGGAGGTG 14892 MC38 Rarresl GTCGGAGTGTGCCCTCAAGG 20876 CTGCATACTTAGGCACTGCA 14893 MC38 Rarresl ACAAGCTAAGTTCCCAGAGT 20877 TGGAAACAGGATCCTGCAAG 14894 MC38 Rarresl GTCCTTCTGCTTGGACAGGG 20878 AACCGTATGGCGCGGCTCCT 14895 MC38 Zfp280c GCAGGACGTCCGGAGCTCAG 20879 GTGACGCACTTCCTATTGCG 14896 MC38 Zfp280c AAATAAGTGGAAGAATAGGA 20880 AGATGCAACGTCATCACGCC 14897 MC38 Zfp280c TGGAAGAGCATCTTGAGTTC 20881 TGAACCCGAAAGGTTAGCGT 14898 MC38 Plxna3 CGCTCTGCTTCTTAGGGCCC 20882 GCTGCITCGGGAGTGCGCTT 14899 MC38 Plxna3 GCTTCTTGCACTAGAGTCCT 20883 TCTAACTCTGGAAGGCGCAG 14900 MC38 Plxna3 TGGTACGGTCCGGGTTTAAA 20884 CCGAAGGGCCCGGTGTCGGG 14901 MC38 Capn8 CAGAGTCAAATATGTATCCA 20885 GGTGGGTGCGCCTCTTGGTT 14902 MC38 Capn8 GCCCTTTAAGGCAGCTCCCA 20886 TCAGACAAGAAATCCAGTTC 14903 MC38 Capn8 ACACCACAATGGAGGCTATC 20887 TTGAGGAGTAAATAGCACCT 14904 MC38 Spsb2 TAATCGTCCACAGAGCCCAG 20888 CCCGCGTCGCCTGCCGTGGG 14905 MC38 Spsb2 TCTCAAGGCGGTAAGTGGTG 20889 GGCTGAGGTGAGAACCGCGA 14906 MC38 Spsb2 TATCGTCACCTCCCAGACCA 20890 TGGTTGGATGCCGGAACCTT 14907 MC38 ffi30 GCCTTCAGGAAAGGAGTCCC 20891 TTCCAAGCGGTGCAACGAGC 14908 MC38 ffi30 ACATGCTAGCCGCGGAGGAC 20892 GTGGCTAGAGGGATTGGCGC 14909 MC38 ffi30 GGGCGTGGACTTAGTGGGTG 20893 CGCGTAGCAGCGTCGAGGCG 14910 MC38 Gsg2 CTAGGACCCAGCGGGCCGAC 20894 GGGCAGGAGCATACCCACAG 14911 MC38 Gsg2 CTGACCTCCCGGAAGCCGGC 20895 GGAGTGGAGATTGATTTCGG 14912 MC38 Gsg2 GGCAGATGCCTAGCGGGACT 20896 TGTGGGCAGCCACAATTAGC 14913 MC38 1700010I14Rik TATTCTGCCACCCTGTGGCC 20897 AAGATTCCAGTAGGGACTTT 14914 MC38 1700010I14Rik GCGCCAGAGTTACACTGAGG 20898 ATTCACCACAAGCACAGCAA 14915 MC38 1700010I14Rik AAACCAGTGAGCATCCCTCC 20899 TCCTTGGCTGGGTCCAGTGA 14916 MC38 Bcorll CCCAGCCAGTCCTCCGCTCC 20900 GTACTGGGTTCTTTAGCTCC 14917 MC38 Bcorll GGGAAGGAGGAGGAAGAAGG 20901 TTATCCCACCAATCGGTCTC 14918 MC38 Bcorll CAGGGAAGCCGGAACCTCGC 20902 ACGGGTCAGGCCTTGGTTCA 14919 MC38 Slcl9a3 GCGCTTTACAAACTGGCTGA 20903 TTCTAGAAGAGACTGTCAGG 14920 MC38 Slcl9a3 GGTCACCGGGTCAGTCCCGC 20904 CCCGAGCCAGAGGTGAGGGA 14921 MC38 Slcl9a3 TGCAAAGTTGGGCGCGGCTT 20905 GGGACCATCCCAACAACTTC 14922 MC38 Ccdcl81 CGGCCAGCGTTTCCAAGACC 20906 GTTCTGTACCGGGCAGGAAC 14923 MC38 Ccdcl81 GATCGCGCGCAGGCGCAGAA 20907 TAGGGAGAGGGCTTAGGGCT 14924 MC38 Ccdcl81 GTAAGGCGCAGGTGTTCGCG 20908 CTGTTAGGTTCATAAACACT 14925 MC38 Pam GGAGTCCCGGGCGGGTCGGA 20909 GGAAAGGTAAGGTATCTTCC 14926 MC38 Pam GGCCAGGGCCCGATAGTCTC 20910 CGTCCGCTGCTCGGCGGCCA 14927 MC38 Pam GGCCACTGTCCCAAGGTCTC 2091 1 AGGCGGGAAAGGTGTGAGCA 14928 MC38 Scg2 CAGCACAAATTCCCTTAGAA 20912 GGCGCCACAGCGCCCTCGTG 14929 MC38 Adgrfl AACGGGAAGTCTTTGGTCTC 20913 GAGGAGCTGTGGGATTGGCC 14930 MC38 Adgrfl TTTCAGCAGAGGCAGCAACC 20914 GGGACCATGAGAATCAAGGT 14931 MC38 Adgrfl GTTGGCTTTCCCTCTGCAGG 20915 GTCACTAAGTGGATGAATAG 14932 MC38 Cpeb4 GTGGTGTCGGATTGGTCTTC 20916 CACTCCITCGTCAGATTTAG 14933 MC38 Cpeb4 TTTCACTCGGCTCGGTCCTG 20917 AAACTGCAGTTCTAAAGCTC 14934 MC38 Cpeb4 TGTCTCTCGGTCTTTCCAGC 20918 TAGTCCCGAGAATTTGCTGC 14935 MC38 Zfp74 CCATCCAATGCAGTCACATT 20919 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Cyptl TATCCCTGTCAGAACAATGG 14936 MC38 Zfp74 CTGCTGTGTCAGGGTTGGCA 20920 GL261 Cyptl GATTCTCAGGCAGTCTTATC 14937 MC38 Zfp74 TTGTGATTTGTTTCCTAAGG 20921 GL261 Cyptl CTCCCAGCCAAAGGCAGCTA 1493 S MC38 Dst CGGTCCTGAAATGCTGTCCT 20922 GL261 Hmmr AGCTGTTTGCGGCGACGATC 14939 MC38 Dst ATGCGAGGAGAACTTCTACC 20923 GL261 Hm r AATCTAGTGCGCATGCTCTT 14940 MC38 Dst ACGGATCCTTAAATATGCTG 20924 90 GL261 Hmmr CCTTCCGATTGGGCGGCGGT 14941 MC38 Pparg GACGCGGAAGAAGAGACCTG 20925 r GL261 Vpsl3c GGGTCACGCCTGCGCACTGG 14942 MC38 Pparg GCTTGGCGGGTGCTGTGCGT 20926 o 4 GL261 Vpsl3c CCCACCTCCGCGATTGCGGG 14943 MC38 Pparg AGGACAGTGCCAGCCAATTC 20927 6 1 GL261 Vp c GGCGCAGAGACTGACAGCTG 14944 MC38 Esytl GAGCACCATATATTACTGGG 20928 GL261 Elmsanl ATTTGGTCGCAGGAAGTGGG 14945 MC38 Esytl GGGCAGCGCCGCGTAGACTT 20929 GL261 Elmsanl GGAACCGAGGGTCTGGCTGG 14946 MC38 Esytl GTCAAGATGGGAGGGTTGGA 20930 GL261 Elmsanl TGCTGATGAAGTGGTAGAGC 14947 MC38 Rmdn2 AAACCAGTCTTCTTGGATTC 2093 1 GL261 Klfl7 CTGAGCACTGGGCGGAGTCA 14948 MC38 Rmdn2 GGACAAAGAGGCTGGGAATT 20932 GL261 KH17 AGTGGTTTCCCGGACCCTGC 14949 MC38 Crk ATCAGTCAATTTGTAGGTTG 20933 GL261 Klfl7 CATAAGGCCTACAGAGTTCT 14950 MC38 Crk CGACGCCCGCCATTGGGAGA 20934 GL261 Col23al TCGCAGGCCGCCTGAGGTTG 14951 MC38 Crk GGAGGCGGAGTCTAGGTCTA 20935 GL261 Col23al GGCACTCACTGTTCGAGCCT 14952 MC38 Camkv GTTGGCGGCGAACACCTGCT 20936 GL261 Col23al GAGCCGAGCCCGGCCGCATA 14953 MC38 Camkv CTGGAATCCCACTCGAGGGA 20937 GL261 W k l TGTGTGGAGGCTTCAGACAT 14954 MC38 Camkv CAGCATCGCCAGTCGCTCTC 20938 GL261 Wnkl GCGCAGGCGTGCCGAGCTCG 14955 MC38 Gabrr3 CATTTCACTAGCTGTGTTGG 20939 GL261 Wnkl AACCGTGAAAGGAACCCGGG 14956 MC38 Gabrr3 AGTAGATTGGCATCACTCAC 20940 GL261 Tmem69 TGGGTCCGGATGGGAATTAA 14957 MC38 Gabrr3 GAAACAACAAGCAGCATTGA 20941 GL261 Tmem69 TCCTGCACTCAGGAAGTGGG 14958 MC38 Tnkslbpl AGCTCTTGAGTGCTGGAGGG 20942 o GL261 Tmem69 GTTCATGCATGTGCCCACTC 14959 MC38 Tnkslbpl ATTTCTTATGTCCCTGTGTT 20943 GL261 Tnfrsf26 TTCTTTGGACCGGAAGCAGG 14960 MC38 Tnkslbpl CACTCCCAGCCGTGGAGGGA 20944 GL261 Tnfrsf26 GGCAGCATCTGGACTGCAGC 14961 MC38 Top3a GGAGTCATGTGATACCAAGA 20945 GL261 Tnfrsf26 AGAGCCGAGAGAGATGCTTG 14962 MC38 Top3a TTATGACAATGGGTAGTTAA 20946 GL261 Polg2 AGGCAGGTGGAGTTACCAAA 14963 MC38 Top3a GGGTCACGCGACGCTGATGC 20947 GL261 Polg2 CAGCCGCCTTGGGCGTATCC 14964 MC38 Sm 4 AGCGCGAGCGCGGGAGTTAG 20948 GL261 Polg2 ACTCTATAGTAACAGGATTG 14965 MC38 Smyd4 CATGGTGGGACACCTGAGCG 20949 GL261 Arid3b AACTCATATGGGTTGGAGGG 14966 MC38 Smyd4 GTAGCCAATGCGGTGGCTAT 20950 GL261 Arid3b TCATCCTGAAAGTCAGGGTT 14967 MC38 Gapt TGACCCTCCCTCTTTGTAGG 20951 GL261 Arid3b GGGAAAGTTATAAAGAGAAC 14968 MC38 Gapt TATAATTCTGCAGTATCTGA 20952 GL261 Dis31 AACTTCACCCGAAGAATCCT 14969 MC38 Gapt GCAAAGTTTCCTGGTTCGTG 20953 GL261 Dis31 GTGTGAAGGTAGGATGTGGC 14970 MC38 Cfap61 CCGTGGAACTCGAGCGATCC 20954 GL261 Dis31 TGCCTGTGCCGGCCACTGGG 14971 MC38 Cfap61 AACAAACTAGATACCGGAAC 20955 GL261 Ocstamp ATCAGGAGGGTTTGATTGAA 14972 MC38 Cfap61 CTCAAGTCCGGTTGTCGGCC 20956 GL261 Ocstamp AGGCAGTCAGGAGCAGCCAG 14973 MC38 Stxl7 TAATATAGTGTGCCAACCAC 20957 GL261 Ocstamp AAGCAGTGCCCGTGACCCTG 14974 MC38 Stxl7 CCCTACCCGGCCAGTGGGCG 20958 GL261 Cln6 GGCAAGACCGGAGAGGAGGA 14975 MC38 Stxl7 ACTTGGAATTGTTCATCCAG 20959 v > GL261 Cln6 GGAGAACTGGTGAAGGGAGG 14976 MC38 Slc22a3 GCAGAGACAGACTGTTACAA 20960 o GL261 Cln6 AGGGAGGAGGAATGAGAGAG 14977 MC38 Slc22a3 CAGGTATGAAACTCTGTTCC 20961 90 GL261 Aldhlbl CCTTCCAGAGGATTCTGATT 14978 MC38 Slc22a3 GCTTAGTCCCAAAGTTCAAA 20962 GL261 Aldhlbl TGGACCTAAGATTAGGCTAG 14979 MC38 Ms4al3 GAACCAGTGCGCAGACTCAC 20963 GL261 Aldhlbl ATCTCAAGTCTGAGAGCCTA 14980 MC38 Ms4al3 ATGCTTCTCCTAAGATAGAA 20964 90 6/1 GL261 Txndcl2 CGGATGTGGGCGGTGCCTCG 14981 MC38 Ms4al3 TCCAGAAGAGGATCGAAGTG 20965 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Txndcl2 TCCCTAAGTCCTTGATATCC 14982 MC38 Wdr77 TTCTCCTCTTCTCGCGATAG 20966 GL261 Txndcl2 ACTTCCTTCAGTGTTTGGCT 14983 MC38 Wdr77 GAGCGAATTCCCTCGGAGAG 20967 GL261 Zfp385c CTTTGTCAGCAAAGACCTCC 14984 MC38 Mpg TTGATGGCAATCGGGCCATT 20968 GL261 Zfp385c GCCCTTTGTTTCAGCAGAAG 14985 MC38 Mpg TGTAGAAACCTTTCACCAGT 20969 GL261 Zfp385c GTGAGGGTAGTACCTGTCCC 14986 MC38 Mpg GAACCCAGGTTCTCTAGATC 20970 GL261 Gucyla3 CACACACACACACACATAGC 14987 MC38 Ect21 TGCACTCCAGTGGCCAACCT 20971 GL261 Gucyla3 TTGGAGGATGGCGACTGGGC 14988 MC38 Ect21 TTGCTTCAGGAGGCTCCTGA 20972 GL261 Gucyla3 GTGTGTGTGTCTGCCTTTGG 14989 MC38 Ect21 CAAGGGACACCGGACCTGTG 20973 GL261 Ptprq GTATAAATTTCAGCACCCAG 14990 MC38 Edeml GGGATTGGCCTCCACCGGCC 20974 GL261 Ptprq ACTCTTGGATGGATGGCTGT 14991 MC38 Edeml GAACTCCCTCGTGACGCACC 20975 GL261 Stra6 TCCTATCCTCCCAGAGGAGC 14992 MC38 Edeml GGGACTCCCTCCGGCTCTAT 20976 GL261 Stra6 GGGTGATTCTGAGGGCCAGG 14993 MC38 Rest GGCGCGCGCGGACGGCGAGG 20977 GL261 Stra6 GACCCACAGACAGAGTAGAA 14994 MC38 Rest GACGGCGCGGGCCGGGTGCG 20978 GL261 Slc22a4 GCCACTGCACTCCACCGATC 14995 MC38 Rest CTCGGTCCCGAGGCTCGAAG 20979 GL261 Slc22a4 CGCCGGGAAGCCGAGTCCTC 14996 MC38 Fga TTCCGATAAGTTGTTGCAAA 20980 GL261 Slc22a4 TTCGCTGCCTAGCCGCACGG 14997 MC38 F a AGCTCCAACCCTACTTAAAC 20981 GL261 Hspg2 GGGCGGAACCTGGTCTTGTG 14998 MC38 Fga TGGCTGCTTGAGTGGGCCAA 20982 GL261 Hspg2 CTCCTGAACTTGGCGCCTCG 14999 MC38 Zfp281 GACAGTGGCTGAGGGTTTCT 20983 GL261 Hspg2 TGGCTAAATGTTTGGAGGTG 15000 MC38 Zfp281 AACTGAGGCGCAGGCGCACG 20984 GL261 1 10008F13Rik GAAGCTTCCGGCGGACGCCA 15001 MC38 Zfp281 CGTGATTGGTGGCCCTGCTG 20985 GL261 1 10008F13Rik GCTGCGTGCGCACGTCATCA 15002 MC38 Papd5 CGGTTCCGGAGCGGTCTCAG 20986 GL261 1 10008F13Rik GTCACITCCGCCCACCGGAG 15003 MC38 Papd5 GAAGGGCGGGCTTCCGCTCA 20987 GL261 F5 GGGTTAGACAGCCACCACAG 15004 MC38 Papd5 CGTGCAGCCGCGTGCTAACC 20988 GL261 F5 ATGCCAGACAAGGAATGTAG 15005 MC38 Mctpl ATCTGCTGCCCGTGGCTAAG 20989 GL261 F5 TGGCTCTGGAGCAGTGCCCA 15006 MC38 Mctpl GCTGTGAGGAGGAGAACACT 20990 GL261 Mkml GTTCCTGAGACCTGAGCGCT 15007 MC38 Mctpl GAGCAGGCAGAGCCGAGCAA 20991 GL261 Mkml GGAGACGCGGTGACACGGCG 15008 MC38 Tnfaip3 CGCTGAGAGAGAGACAAACT 20992 GL261 Mkml GCGTGATCACACGCTTAGCC 15009 MC38 Tnfaip3 CCTTCCACGTCACATCCATG 20993 GL261 Rfx5 TCTCTAGGAGAAAGGAAGCT 15010 MC38 Tnfaip3 GAAGGCGGAGCGTGGTACTG 20994 GL261 Rfx5 TTTAGAGAAGGCAAGTGGTG 15011 MC38 Rep 15 CTATATGGCTAGCCACATCA 20995 GL261 Rfx5 AGATCTCTTTGGGTATACAA 15012 MC38 Rep 15 CGAGGCTAGACAAACATGTG 20996 GL261 Faml20c CCCGCCTCCAGCTTCGCGCG 15013 MC38 Rep 15 ACACACCCAGTTGACAAACG 20997 GL261 Faml20c GCGGAGAGAGGGTTTGAGAA 15014 MC38 Aka l GATTCCGTGTTAGCTCATAA 20998 GL261 Faml20c AGGAGACCACAGACTGGGTG 15015 MC38 Akapl GGAGCTCTCCGCTGACATCC 20999 GL261 Gtf2irdl GGATGAGGGATGATGGAGAT 15016 MC38 Akapl GTGTAGGGCTAACCTTGGGC 21000 GL261 Gtf2irdl GAATGGCTGGCAATCTTACT 15017 MC38 Zfp791 GTTTGGAGAGTCAGTTGTGT 21001 GL261 Gtf2irdl CAATTCTAAGGCCCGCCTTT 15018 MC38 Zfp791 GATCTTGTTATGTTGTAAAG 21002 GL261 Slc22a20 CATTGTAGAGAAGGCCTGTG 15019 MC38 Zfp7 1 TGTGTCACTGAAGCAGACAC 21003 GL261 Slc22a20 GGACCTAGAGGTAGAGGATC 15020 MC38 Ranbp2 CGAGACGAACTCCCTTTCCC 21004 GL261 Slc22a20 AGGATCAAGTTACACCTCAC 15021 MC38 Ranbp2 TCGTTTGCGAAACGGTCACG 21005 GL261 Tbxa2r TGTCACCCTTGTGCCCTGCT 15022 MC38 Ranbp2 AAATCTATAAAGCCTTTCCC 21006 GL261 Tbxa2r GAGAGACATCAGTTGTTGAA 15023 MC38 Mqjs31 TTTGGATGGAGTGGATATCG 21007 GL261 Tbxa2r TTCCCACCCTAGCGGCTGAG 15024 MC38 Mrps31 ATCGAGCCAGCCAAAGACCC 21008 GL261 Mppel AAACGTAGCATGTTTAACTT 15025 MC38 Mrps31 GAGACCAATCATTATGTTCC 21009 GL261 Mppel GAAGAATGGGTTAATGACCC 15026 MC38 Nup43 ATCTTGTTGCCAAAGGGTTT 21010 GL261 Mppel AGGCTTGAGAAACTGTGTAC 15027 MC38 Nup43 GACAGCCAATTCTCGTCAGC 2101 1 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Coro l a TGGGCTCAGAACCTATGCCC 15028 MC38 Nup43 TCATCCAATCAGAACTGCGC 21012 GL261 Coro l a GGGTTGGAGCTGACAGCATG 15029 MC38 Psme4 TAGGGTCTCTTGT1TCTCGC 21013 GL261 Coro l a GAGGGAGCTTCTGAAGGTGG 15030 MC38 Psme4 CGAGTITGGTGTCAGCGACT 21014 o GL261 Sult6bl GGTGAGGCCCAGGTGCGGAC 15031 MC38 Psme4 GACCGGCCTCAAGTCACTTC 21015 GL261 Sult6bl TGCCAGGAGGATATTCAAAC 15032 MC38 Klb ACAGGTTGTTGACGGCAACG 21016 o GL261 Sult6bl CTCAGGAGCTGTTACTCTAG 15033 MC38 Klb TGACAGGGCTTTACAATCAC 21017 r GL261 Trim27 TTTAGGGTGGAGATAGAACT 15034 MC38 Klb TAGCCTGGATCGGGAGACTT 21018 o 4 GL261 T 27 TTCTAGCGATTGTTAACGCC 15035 MC38 Taxlbpl TAACTGACTTACCAGCGAAA 21019 6 1 GL261 Trim27 AGATGGCTTTGCATAAATGC 15036 MC38 Taxlbpl GCTGTCAGGGAAACCACTAA 21020 GL261 Bpi GGAAGGAGGAAGGCAGCCGT 15037 MC38 Taxlbpl CTCTTTACAGCTAGCGAGTG 21021 GL261 Bpi CAGACCTCTAGGCTCCACTG 15038 MC38 Fbxo9 TTGACGTGGAATCGGATGTT 21022 GL261 Bpi GGCAGGGCAGTAGTAGAAAG 15039 MC38 Fbxo9 TCAAATGTTCCACGTTGAGC 21023 GL261 Topors GGCTACACAGGGAAAGGACC 15040 MC38 Fbxo9 TCGGGTTTCAGGCCTTGAAA 21024 GL261 Topors GTTGCAGGCCTGCTTGCCTC 15041 MC38 Cyp27al AAGGCGGCGTTTGTGTGTTC 21025 GL261 Topors AAAGAAGAAATCAATGTGCC 15042 MC38 Cyp27al AGAACTCGGGCTTTGCGACC 21026 GL261 Gohm4 TTGCGCGGGCCCAATGAGCG 15043 MC38 Cyp27al GGACAGATCCTGATTGGAAG 21027 GL261 Gohm4 GGCTCCACGTGGGCGCACCC 15044 MC38 Bahccl ATTGGCTGCTCGGCCCTCCA 21028 GL261 Golim4 GAGCTAATGCTGGGCTCCAT 15045 MC38 Bahccl TTATTAGTATGCAGGGCCCG 21029 GL261 Vwa5a TCTGCTTCAGTTCTGATAGA 15046 MC38 Bahccl GCGTAAACAGGCCTCCCAAT 21030 GL261 Vwa5a AGTTACACTTGTAGGAGGAC 15047 MC38 Sgcd GCAGAGTAGGGTTTCAAAGC 2103 1 GL261 Vwa5a TCAGAGTAGACTATGCAGAG 15048 MC38 Sgcd AGAGAGCGGGAATGCTGTTC 21032 GL261 Elp5 AGAGATGAGCACGGAGTGGG 15049 MC38 Sgcd CTTGGCTGCAGTTGTGCGGC 21033 GL261 Elp5 TTTATGCTCCGTATTCTCAG 15050 MC38 Tkl TCAAGITCCAGCAGGAACTA 21034 GL261 Elp5 AGATTAAGGATGTTGTCTCT 15051 MC38 Tkl GCAGGTTTAGCTTGTTAGCC 21035 GL261 Cep295 GTCTTGTCCCACTTGCTCTG 15052 MC38 Tkl AGGGTTTGGACCTTACTCTG 21036 GL261 Cep295 CATTATCCCTCTCAACTGTC 15053 MC38 Rhoq CAGGGCTCCTCGCGAAAGTG 21037 GL261 Cep295 CGCACGCGCAGCTTGCGCAA 15054 MC38 Rhoq CTCTTGGGCAGCCGCTAGGA 21038 GL261 1127 TGTGTTCACTAAGTCTTCCC 15055 MC38 Rhoq AGGAGGAGGCGCCCTGTATC 21039 GL261 1127 AACGTAATTTCCCTTCCCAG 15056 MC38 Rasl2-9 ACCCGGCAGAGCGCAACACG 21040 GL261 1127 GATGGCTGCACACAGAGGCT 15057 MC38 Rasl2-9 GCTGCACGTGCGCCCTCTAA 21041 GL261 Pigv CAAACTGCTGGCGAGTCAAG 15058 MC38 Rasl2-9 GCAGACTCTGTACCAGACTG 21042 GL261 Pigv CAGGTGTCACCACGCCGGGA 15059 MC38 Fasl GAAGAGCTAATGTCCTCAAG 21043 GL261 Pigv AACATGGCCGCCGAGGAGGG 15060 MC38 Fasl CAAGTCTTCGAAGTTCCAAT 21044 GL261 Kdm3b GGGAATTGCAATTTCCACTG 15061 MC38 Fasl CGTCTCTGTGCTAACTGAGA 21045 GL261 Kdm3b CACCAGCCACCACCAACCAC 15062 MC38 L3mbtl3 TGCTGGGTGGCGGCGCTGGG 21046 GL261 Kdm3b GCCCAGCTCCGGAGCGCTGG 15063 MC38 L3mbtl3 GGTCGGCCTGAGCCTAAGGG 21047 GL261 Dmbtl ATAAATCAATATGACGGAAG 15064 MC38 L3mbtl3 CGCCGCACCGATCGTGCCCG 21048 GL261 Dmbtl TAGGTGTGTTTGACTGATTG 15065 MC38 Srfbpl GCGTTGCTTTAGTTGATATG 21049 GL261 Dmbtl TTAACAGTTTGACTAATCCG 15066 MC38 Srfbpl TTTCCGGCAGTGCCGCAAGT 21050 GL261 Viprl TGAGCACAGAGTCCCGCTAG 15067 MC38 Srfbpl CCGGCGCGTGTACGACTAGC 21051 xi GL261 Viprl CTAGCTAGCGAGCATCCTCT 15068 MC38 Prrl 1 ACAGGGTTCGTTGTCTTGAA 21052 o GL261 Viprl GTTAGCCAATGGCACGGCGG 15069 MC38 Prrl l AGCACAGCTTGGACTACGAT 21053 o o GL261 Coch GGCCGGCCACCGCCCTACGG 15070 MC38 Prrl 1 GTCTACGATTGGTCGCTCGT 21054 o GL261 Coch AGGAAGAGGCGCCAGTCCGC 15071 MC38 Toporsl GACGCTTCACTCATGAAAGG 21055 ~ GL261 Coch CGGCGCGCATGAGCACTGTG 15072 MC38 Toporsl TGCAAGAACAACTGACAATG 21056 SO 6/1 GL261 Plin2 TGTACTGATCTGGGATCTCA 15073 MC38 Toporsl TAGATTTATTAGTTGAGGCT 21057 OS Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Plin2 CGTGATAGCCCAGCTGCCTG 15074 MC38 Ugt2b35 TTCAGCCACCAACTTCAATC 21058 GL261 Plin2 CCAACCTGGTGCCACAATAT 15075 MC38 Ugt2b35 AAGTTTGCTTGCACCAACTC 21059 GL261 Adh7 GATAATCAAGTCTACTATGA 15076 MC38 Ugt2b35 GAGGACAGGCAGTAAAGCAA 21060 o GL261 Adh7 AGGGTGGAGCTTCTTGGGTT 15077 MC38 Egf AAATATTCAGGGTAGAGAAG 21061 GL261 Adh7 GCTATGAGTCATGTTGCCAA 15078 MC38 Egf CTCTCATGGTGTTTGCAAAG 21062 GL261 Ccngl TCAGTTCCGCAGCTTAAGGA 15079 MC38 Egf TTCCACCAGAGCAAGCAGGA 21063 r GL261 Ccngl AGTCGGGCGTGGCTCGAAAG 15080 MC38 Vpsl3a ACAGAACACCAGTCGAGCGC 21064 o 4 GL261 Ccngl AACGGGAAGTGTGCGCTGAT 15081 MC38 Vpsl3a GGGCGTGACCGACGCGGAAC 21065 6 1 GL261 Bbofl GGGCGGAGATCGCTCCGAGG 15082 MC38 Vpsl3a CGACGGATAGGAGGCGCGGC 21066 GL261 Bbofl CGGTGAGTGTGCACGAGCCT 15083 MC38 Zfp93 ACCGAAGCTTTGCCATTCCG 21067 GL261 Bbofl GCACGCGCGTGACGTGACCG 15084 MC38 Zfp93 GTCGTTTCCGCTCCCGGGAG 21068 GL261 Pkn3 ATCAACCTAGCTGAGGCCTG 15085 MC38 Zfp93 CAGAAGAGCGACCTACCAAA 21069 GL261 Pkn3 AAAGAATGGCTACTCTGTTT 15086 MC38 Snx9 TCCTGAAAGTCCCGGCTGCG 21070 GL261 Pkn3 GTCCTGCCTTAACTGTCAGA 15087 MC38 Snx9 CCCGCCGGCCAAGCCTCCCA 21071 GL261 Cede 172 GTCTGCAGGGTCTGCGCTCA 15088 MC38 Snx9 CGCTTCCGCCGCGCACGCCG 21072 GL261 Cede 172 GGTGGGACGCCCAGTCTTCA 15089 MC38 C77370 GCTGCTGCTGCTGATGCTAC 21073 GL261 Cede 172 ATCTCGCGAGAAGTCAGCTA 15090 MC38 C77370 GCAGCCCAGGGAGGAGAAGG 21074 GL261 Tex2 GGTCATGTCTGGTGCGCGGC 15091 MC38 C77370 AGCAGTGGCAGTAGCGGCAG 21075 GL261 Tex2 GCGCGCGGCACTGGCTGGAT 15092 MC38 Trim46 TTTATGTGAGTAGTATGACC 21076 GL261 Tex2 GCGGGACGGCCGGTGCCCGG 15093 MC38 Trim46 CCAAATTGGGAACTGCACCC 21077 GL261 Slcl5a2 ACAGTGCTAGAGAATCGATT 15094 MC38 Trim46 CGCAGTTCGAAGCTAGTCCC 21078 GL261 Slcl5a2 TACTCAAGAATGCAGCATCT 15095 MC38 Arid3a TCTTCGGGATTCCCGCGATG 21079 GL261 Slcl5a2 TATCTAGTCCTCATTTGCAG 15096 MC38 Arid3a TGACTTTCCGCTCAGAGGTG 21080 GL261 Pawr GGCAGTCCCTGGCTGGAGGG 15097 MC38 Arid3a TCTGAGAGCAATTTGTCACA 21081 GL261 Pawr CTCAGGCCGGCGAGTTTGCC 15098 MC38 Wdhdl GTGGGAGCCGAACCCGGAAG 21082 GL261 Pawr CGGAAAGGGCCGAGTCCCTG 15099 MC38 Wdbdl GCCGCCTCGAAGCCGAGAGC 21083 GL261 Slcl2a3 GGGCAGGACAGCAGTTGCTA 15100 MC38 Wdhdl GGCAGCGGCAAGTCTGACTC 21084 GL261 Slcl2a3 CCAATITGGAGCAGGAGGGC 15101 MC38 Set GGGCTTCCCGGCGATGGAGA 21085 GL261 Slcl2a3 AGCTTGGTCCAGACCGCCCA 15102 MC38 Set GGCGCGAGCCTCTCCGGCCG 21086 GL261 Sema7a GCGGTCACCGCACAAGCAAG 15103 MC38 Set GGCCGCGGCCAATCGCTGTA 21087 GL261 Sema7a AAACCTTCGCTACCCGCACG 15104 MC38 Ore3 TCGTAGGTCGATCGCCTGTC 21088 GL261 Sema7a GCCACCGGCAAAGCTAGAAA 15105 MC38 Ore3 AGAGGCGACTTCCGGCGCGG 21089 GL261 Fam91al GGAGCTCCACGCTCGGACCT 15106 MC38 Ore3 AGTCCAGAGCGGCGAGCCAG 21090 GL261 Fam91al GGCTCCCTGGTCTGCACCTC 15107 MC38 Zip882 AAACCTGAAGCTGAACAGTT 21091 GL261 Fam91al ACCGTTCAACCACGTGCGGG 15108 MC38 Zfp882 TGAGAACAGAGTCGCAACTA 21092 GL261 Chma9 TTTCCATTGTCCCACTGGCA 15109 MC38 Zfp882 AAGTGATCCAATCAAGACTG 21093 GL261 Chma9 TTCAGAAACAGGGAGCGAAG 15110 MC38 AI597479 GTCGCGGAAGTGACGTGAGG 21094 GL261 Ch a 9 GATGCTGCGGAGTAAGCAGG 15111 MC38 AI597479 TCAGTCCCAGTTCGTCCTCT 21095 GL261 Nkg7 GGTATCTACCCTCGTGTTCT 15112 MC38 AI597479 AGCGGAGCAGAGTCCTGCCC 21096 GL261 Nkg7 CCCTCCCTTCCTGAGTGGTT 15113 MC38 Acvrlb CGAAGGAGCCGGGCGCGCGC 21097 xi GL261 Nkg7 AGCAAGTAAAGGCTTCTGCA 15114 MC38 Acvrlb GGCGGGCGCACGCGCGCACC 21098 o GL261 Robo4 CTAAGGCATGAGGGCCAGGC 15115 MC38 Acvrlb CGCGCCGGCACGTGAGCTCC 21099 80 GL261 Robo4 TGCTGTGAGCTCAGAACAAC 15116 MC38 Hdlbp CCAACTCTTTAAGAGTTCTG 21100 GL261 Robo4 GACTGAGACTCTGTCCCAGT 15117 MC38 Hdlbp ACACITACCCGCTCACACGC 21101 GL261 Pkhdlll ACACACCGCGGACGAGCTGG 15118 MC38 Hdlbp GTTAAITACCTACAGAGAAC 21102 80 6/1 GL261 Pkhdlll CCCAGAAGCCAGGGCGAACC 15119 MC38 H2-M10.6 TGATAAGTAGGGCTTCAATC 21103 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Pkhdlll GGGCGACTTCTGCAATCAAG 15120 MC38 H2-M10.6 TGTATAACAGGTGCAAAGTG 21104 GL261 Pou6f2 CCTCAGTATAAAGTCCAGCC 15121 MC38 H2-M10.6 GTCTTGGAGAGACCAACTCC 21105 GL261 Pou6f2 TCAGGATGACCAATGTCAAC 15122 MC38 Plau CGCCCAGGTTTGCTGGAGGG 21106 GL261 Pou6f2 ATGTCATAGGACAGACACTA 15123 MC38 Plau TTGCGGTGGGATGCAGGAAA 21107 GL261 Gabrq GCAGAGACCTGAAGGGCCTG 15124 MC38 Plau GGCGCTGCTCGCCCTTTATT 21108 GL261 Gabrq CAGGTGACTAGTGCTGGTCA 15125 MC38 Eln TTCCCTCACAGCAGCCTACC 21109 GL261 Gab q ACCTGCTGAGCCAATCCCGC 15126 MC38 Eln CCCAAAGCGTAATTGCTGCC 21110 GL261 P3hl TGTGCGCATGAGATTAGAGG 15127 MC38 Eln GCCAGACTTGCAAGCCTCCT 2111 1 GL261 P3hl CTTCTGCAACATCTTCCTTC 15128 MC38 Gm5136 GTGGATGGAGCCTAGGGTGC 21112 GL261 P3 l GATTGCCACGTCGCCAGCAG 15129 MC38 Gm5136 TTCTTGTTAACATGGTTAAG 21113 GL261 Atp6apl CGTACAGCCAACCAGCGAAA 15130 MC38 Gm5136 GGGAGTGGCTGGGTGCCACA 21114 GL261 Atp6apl TCATAAGGAGCGTGCGCGAC 15131 MC38 Akrlb8 TCCGGTTCATTGCGGGAGGG 21115 GL261 Atp6apl TCACAGACGAGTATGTGAGA 15132 MC38 Akrlb8 AAAGATTAGTCATAAACCAG 21116 GL261 Sto l CCTGCGCTGGGAGGACCGAA 15133 MC38 Akrlb8 AAGAGCCGGCCTCTTCATCC 21117 GL261 Stomll AGCGGCAGGCATGGTGGACC 15134 MC38 Trim42 GTGGTAGCTGGGATACATAC 21118 GL261 Stomll ACTAACAACAGTGGCTGAGT 15135 MC38 Trim42 AGGAAGTTGGCCAGTTTATG 21119 GL261 Slc25al4 TGTAGTAGCTTGTGCAGCTT 15136 MC38 Trim42 GCTCAGTAGTAGGTAAGAGG 21120 GL261 Slc25al4 TGCAGCGTGGGCGGGTGACA 15137 MC38 Patll CGTGCGCAGTGTCTCGCCTA 21121 GL261 Slc25al4 GGCTTCGGGAGAGAGAGCTA 15138 MC38 Patll CACTGCGCAACTGTGCAGTT 21122 GL261 1700017B05Rik CGGGAAAGTTGGTTCCACTC 15139 MC38 Patll TCTGGGTCATCCCTCTCCGA 21123 GL261 1700017B05Rik GCAGAACCCGGCTGTGCCTC 15140 MC38 Atmin CCTCCGGGCTCATTAGCATC 21124 GL261 1700017B05Rik CCTGGGTCCTCCCGTGCCGA 15141 MC38 Atmin GAGGTTGAAGTCCCATGTGC 21125 GL261 1600014C23Rik CCAGGCCTGGGCAATGCCTT 15142 MC38 Atmin GGAGAACAGGTGAATTGGAT 21126 GL261 1600014C23Rik GCAGCTGACCCGCTGGCGAT 15143 MC38 Zscan2 TAGAGATGATTGAAGGTATT 21127 GL261 1600014C23Rik CGTGCGGCGCGGCATGTCGC 15144 MC38 Zscan2 GGATCTGGGAGATTATCTGA 21128 GL261 Mefid GCGTCCCAGGCCTCCCTGCC 15145 MC38 Zscan2 TACTAATGGATCGCATGTCA 21129 GL261 Mefid GACGAGAGTGATGGACAAGC 15146 MC38 Ddrl AGCGAACGCTGCTTTCGACC 21130 GL261 Mef2d AGGCTGCGCGGTGCCTACGT 15147 MC38 Ddrl CCCTCGCTCCTCTCCTAGTG 2113 1 GL261 AcotlO ATGTCATGGAACCCTATCCC 15148 MC38 Ddrl AGCATTGCTAGTCCTGTCCC 21132 GL261 AcotlO GCCTCTCTTCCCAAATATGC 15149 MC38 Secl411 GGCTCAGGACTTGGTCTGCC 21133 GL261 AcotlO TATCAGGCCTTCTAATATAA 15150 MC38 Secl411 AGATCTGCGCGTGCGTAGGA 21134 GL261 Lrig3 GAAGGCGGGCGCGCGCCCAT 15151 MC38 S c ll TAACTCGCGCCGGCGCAGTA 21135 GL261 Lrig3 AGACTGCTGGCTGCAGACGC 15152 MC38 SIH19 AAGTGTCCGTGGGCCGCGCG 21136 GL261 Lrig3 GGCGCGATGTCCCGGCGCGG 15153 MC38 Snxl9 CGAAGCAGCAGCCGGCAGAT 21137 GL261 Cry2 GTGATTGGGTGAGACCCGGT 15154 MC38 Snxl9 TGCTGGCCGCGGCGGTCGGA 21138 GL261 Cry2 CACATGGTGGGAACGTGAGG 15155 MC38 Apoa4 GACTGGTGGCTGTCTCACTG 21139 GL261 Cry2 GAGGCGATCCAGACTCCTTG 15156 MC38 Apoa4 GGAGTCCCTGAACAGAACTG 21140 GL261 Nipsnapl AGAGCTCGGAGGTGTGGGTA 15157 MC38 Apoa4 TGAGACAAAGTTCAGGTTGG 21141 GL261 Nipsnapl CTGTGCAACTGTAGAGTTGG 15158 MC38 Acrbp AAAGTGGTACCGAGCAATAG 21142 GL261 Nipsnapl TTGAAAGGGAAGCTGGCGAG 15159 MC38 Acrbp CTGTTGAAGACCGACTGGAA 21143 GL261 Fgd5 TGGAGTGGTGTCCGTCGTAC 15160 MC38 Acrbp CGCGGCTGCTACGTCACAGA 21144 GL261 Fgd5 GCCTCGGCAAATGCAGCAAT 15161 MC38 Ahnak CTCGGGTCCTTGCCCTATTC 21145 GL261 Fgd5 GGGCCAGTCAGTCTGGGCTT 15162 MC38 Ahnak GTAACTCGGGCGGGTCTGCC 21146 GL261 SlOOpbp CTGCCGCTCGCCCAGGCTTT 15163 MC38 Ahnak GACTAACACTGAAGCCACCC 21147 GL261 SlOOpbp GCGCCCGTCGTCTAGGCGAG 15164 MC38 TmemllO CCGAGATCGTAGAGCTTGAT 21148 GL261 SlOOpbp AGCGGGCGGGACGTAAGGGT 15165 MC38 TmemllO ACCTAGAACACAGGGCTCTG 21149 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 TTCTTCCTGAAGGCAGAGAC 15166 MC38 TmemllO GGTGAGCCAGACTGTGTAAA 21150 GL261 GCTGTACTTACAAAGGAGAG 15167 MC38 Tmeml78b AGCAAAGCAGATGGAAACTC 21151 GL261 CCAGAGCCCTTCAGCACCAT 15168 MC38 Tmeml78b GCTAAGAGGTCAAGGAAATG 21152 GL261 AGGGAGCCAGGATGAACTGT 15169 MC38 Tmeml78b GAGAGCTGCATTGAGTCCCG 21153 GL261 GAGGGAAAGTTGCACGCTGA 15170 MC38 Fvl GACGCAGTAGCCGAGTTCTA 21154 GL261 AGGTGGAGTCTCAGGATAGG 15171 MC38 Fyl AATTTGGATCCGAGGCTTGT 21155 GL261 GATCAGAGCTTTAGTTGCTC 15172 MC38 Fvl CTAATGGCAGTGGATAGGTG 21156 GL261 CTGTATGCAAATATCTCAAG 15173 MC38 Ddc CAAGGCGTGTAGCCCTTCTT 21157 GL261 GCTTAGTTTCTGCACACCTT 15174 MC38 Ddc CTGTGTGAGAAAGCATTAGA 21158 GL261 GAGTCTTGACCAATCGACAA 15175 MC38 Ddc TGCTGATTGGCTTCGGGAGG 21159 GL261 CGTGTTGCAGCCTTGAGGCG 15176 MC38 Rgmb GGTGGGAGCCTGGTAGGGCG 21160 GL261 CCAATTGACGTGGCGTTACT 15177 MC38 Rgmb CTTGAGTGAGACGCGAGGGC 21161 GL261 CTTCTGCGCAAGCACAT1TG 15178 MC38 Rgmb GGAGGCACGCTCGCAGCCAA 21162 GL261 CGAAAGCTAAGGCGGGAGTT 15179 MC38 Tor2a CGCGGGACTGGGTGGTTCGC 21163 GL261 GCTCAACGACGCCCTACGAG 15180 MC38 Tor2a CCATGGTCACGGGTAACTAG 21164 GL261 GAACTGATGGACACCGAGTG 15181 MC38 Tor2a ACTGCTGCGAGACAACCTGT 21165 GL261 ACACTCAAGAGTTCTTGACC 15182 MC38 Pp l r3c AGGGACCGGTTCACGTGATC 21166 GL261 ACTTGAGGAGTCCGTGACGC 15183 MC38 Ppplr3c CTGACCAACCACTGTGCAGC 21167 GL261 GCCTCCTCCGGGACGGCGGG 15184 MC38 Ppplr3c GCGCACGGCCTTTGATTGGT 21168 GL261 GGCTCCGCCCGGCCGTCGGG 15185 MC38 Osbp2 GTTCCTTCCCACCCATCGGC 21169 GL261 AGCGGGCTGGTGTGGGCTCG 15186 MC38 Osbp2 TGCCTAACTCTTGGCCCACG 21170 GL261 r CACACAACGTTTGCAGAACG 15187 MC38 Osbp2 CAGGGATGTGTTTACTAAGC 21171 GL261 r GCACTGATTGATCCTGGGAG 15188 MC38 Ablim3 ATAACTTTCCTTCCTTATGT 21172 GL261 r GGGAAGGCAGCGGAAAGTAG 15189 MC38 Ablim3 GCGGAGCCTCAGACACGCGC 21173 GL261 AGGAAGTCAATACCGTCAGG 15190 MC38 Ablmi3 CGCTCGCTGCTGCCACCTGC 21174 GL261 ATGGTGGGATTGGGCTTCTG 15191 MC38 Ankzfl GGGTGACAGTGAATGACAGA 21175 GL261 TTGGATTCGCGCGCCGGCCC 15192 MC38 Ankzfl TTCATTGGCCAGACTGGCTG 21176 GL261 CAAGTTGGCTAGGAGCCCAG 15193 MC38 Ankzfl AGTGTGCTCTACGTGATGAG 21177 GL261 GAGAAACAGGATGTGTGTTT 15194 MC38 Mkl2 AAGGGAAAGCTTCTAAATCA 21178 GL261 TGGCCTAAGCCAAAGAACAG 15195 MC38 Mkl2 TGCAGAGTTCCCATCATCTG 21179 GL261 GACACCGGTGCGTGTCAACC 15196 MC38 Mkl2 GAAGCAGGGTGTAAACCTCC 21180 GL261 CTCCTTCTCCTAGACTACCC 15197 MC38 Gdfl GGATGGGATAGAGTCCTGGA 21181 GL261 GGAGCTCCGCCCTGAGTCAT 15198 MC38 Gdfl AGCATCCTGAATCTTAGGGC 21182 GL261 GGAGTCTAATAGGGAAGGGC 15199 MC38 Gdfl GGGCGAGGCCATGCCGCCAA 21183 GL261 GTGGATTCTTGCTCCGCTCG 15200 MC38 Sema6b CCATGACACCAGATTCCAGG 21184 GL261 TGCTACITCTGGTCTATCAG 15201 MC38 Sema6b AAACCCGGAGCAGACCACCA 21185 GL261 GGCGCACAAGGTCAAGTCAC 15202 MC38 Sema6b AGTCACAAATCCTGGAAGCC 21186 GL261 AAGCGGGCAGGAGGTGGCCT 15203 MC38 Zfpl42 TTCTCGATGGTTCCGCTTTG 21187 GL261 GGGTCGGACCGCACGGGACG 15204 MC38 Zfpl42 AGCCACTCTGTCTCTCTTCA 21188 GL261 TCCCAGTTCCTCTTCCACTG 15205 MC38 Zfpl42 CCTAGAGGCGCCTGGGCCGG 21189 GL261 CCTGCCAAAGCTCAGCTAAG 15206 MC38 A830018L16Rik AACTGCGGGTGTAGCTGCCA 21190 GL261 ATTAAACTTAGGGCATTGCC 15207 MC38 A830018L16Rik CACATAAATCTGGTGCTTGT 21191 GL261 GATTCTTAGGAGGnTCTCT 15208 MC38 A830018L16Rik GAAAGAAGCACCTTTACCAT 21192 GL261 AAGTTCTCACCAAGCCAGAC 15209 MC38 Ankid40 CAGCAGATAATCCAGTGCGG 21193 GL261 GTCAGTGGAGACAGCTATGC 15210 MC38 Ankid40 GTTACATAAACAGCCGGCCG 21194 GL261 CGCGTGCGCACAGGACGGGA 15211 MC38 Ankid40 CAGACACAGGAATAGTTGCG 21195 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 2300009A05Rik GGTGAGAGCGCCTTGAGGTG 15212 MC38 Mpp6 GCGGCCAGGCCACAACCGAG 21196 GL261 2300009A05Rik CCCTGGCCTAGGGTGGTGAG 15213 MC38 Mpp6 GGCCCTCTGGTGGTAGCACC 21197 GL261 9530003123Rik GTATCTCAATTCAAACATTG 15214 MC38 Mpp6 CCCTAAGGGACCCGCCCGCA 21198 GL261 9530003J23Rik GGGAGCTAGCCCTGCTTCCA 15215 MC38 Rpll2 CTGTGGGTGAGCTCGGGATT 21199 GL261 9530003J23Rik AGACTTGGCTCACAAAGAAC 15216 MC38 Rpll2 AATGITCGGAGCACCTTGCC 21200 GL261 Atplb4 GGGAGATATTCTGGGTCACG 15217 MC38 Rpll2 GCTCCGCCCACGCCGGATAT 21201 GL261 Atplb4 TGGCTCCTTCCTGGAATCAA 15218 MC38 Slc7a5 CGGGTAACGGTAGAGATAAA 21202 GL261 Atplb4 AAAGCAAGCTCATCATTACA 15219 MC38 Slc7a5 GCGTTAAGATCCTGAAACTG 21203 GL261 Brp AGCGGGAGCGCGAAAGCGCG 15220 MC38 Slc7a5 CCCAAGTCTGTTAGAGCACG 21204 GL261 Brpfi GCCGGGCTGGGCTCGGGCGG 15221 MC38 Pde4b GGGCTCTGAAAGACTAAGAA 21205 GL261 Brpf3 CGCGTGCGGCGGCTCGATCC 15222 MC38 Pde4b CCCAGGATTCTTTAAACAAC 21206 GL261 Lypla2 TGGAACGGAAGTTCCGGCGG 15223 MC38 Pde4b GAAAGAGATTCCCTGCTCCC 21207 GL261 Lypla2 GCAACATGGCAGCTTCTACC 15224 MC38 Hmr CAATCTCAGGTTAACGTGTA 21208 GL261 Lypla2 ACGCTGCCACCTACAGCGTC 15225 MC38 Hmr AAGTAAGAAGGTAAACACCT 21209 GL261 Ctcl GGATCCTAGTGTTTCACGTG 15226 MC38 Hmr TTATAATGTCCATCTGAGGG 21210 GL261 Ctcl TTCTATAGTGACGGCGCGTC 15227 MC38 Sytl6 TTGCTAGCTGCTTTGTCTTA 2121 1 GL261 Ctcl ATCTCTGCTTGACAAGATCA 15228 MC38 Sytl6 GTCGGCTCCGCTAGGGTGTG 21212 GL261 Cul7 GGGAAATGGGAAGGCACTTC 15229 MC38 Sytl6 GGGAGCGTCTGTGCGCGTCG 21213 GL261 Cul7 TGGGAGGGCGCGGTACAGAA 15230 MC38 Almsl AATCATGGGTGACTTTGTGC 21214 GL261 Cul7 GTCCTATCCAGTTCTGGCTT 15231 MC38 Almsl GAACCAGCCCGCGCGTTGCT 21215 GL261 Cep 192 CCGCGTGTTCCTGGATTTGA 15232 MC38 Almsl AGCATACGGTACTGTGAGCG 21216 GL261 Cep 192 CCGAAGCCGCGCAGTTTAGA 15233 MC38 Sydel CGCTTCCTGCTGGAGCGGGC 21217 GL261 Cep 192 GGCGGGCAGAAGCCTGTGAT 15234 MC38 Sydel CTCTTCAACTATGAATGTCA 21218 GL261 Z c2 GCGCTGAGCTCGCCCTCCGG 15235 MC38 Sydel AAGTTAAGGCCAAGCATTCC 21219 GL261 Zic2 TGTATTAAAGGAGCTGCGGC 15236 MC38 KlralO AGTACAAGAAGTCTGTTCTC 21220 GL261 Zic2 CGCTAGCTGCCTTGTACTGC 15237 MC38 KlralO CTGATCCCAATTTCCATCAC 21221 GL261 Ttc231 AGCAGTAAGGATGAACGCCA 15238 MC38 KlralO ATAATCCAAATACCCTGACA 21222 GL261 Ttc231 TTGATGCAGGGAGCACCAAA 15239 MC38 Drd2 CGCCGCGCCGTTCAGATCCC 21223 GL261 Ttc231 TTGCAGTGCCTTGTCGCACA 15240 MC38 Drd2 GAGCCGAGGGACCCGCAGAG 21224 GL261 Cd38 AACTTTGGAGCAGGAGTAGG 15241 MC38 Drd2 GAGCAGTGGACGGGCCGCGG 21225 GL261 Cd38 AGGTTCTGGTCAGTTTGCTC 15242 MC38 Lnpep GGCAACAACACCTTCGTTCC 21226 GL261 Cd38 CGGAGGTGACTGGACTAATA 15243 MC38 Lnpep ATGCCCAGCAAAGGCCTCCG 21227 GL261 Tmfl CGGTAGCGTGAAGCCACATC 15244 MC38 Lnpep CTTAGCGTCCACGCCTCAGT 21228 GL261 Tmfl ACGTACACAACCACCAGATC 15245 MC38 Flil AGGGCGAGGAGAGGACGAGG 21229 GL261 Tmfl TCGCGTCCCTCAGTTGAGAA 15246 MC38 Fill GAGAGAGCAGAGAGTGGAGA 21230 GL261 Fam208b GTCGCTGTGCTCCTTGTGAT 15247 MC38 Flil ACTCGCTATATAAATATACG 2123 1 GL261 Fam208b GGGCAAAGCTAGCTCCGGAT 15248 MC38 Dcstamp AAGATTGATTCAGGGTGATG 21232 GL261 Fam208b TGTAGGCGGCGGGATCTAGA 15249 MC38 Dcstamp ATAACITCGTCACTTTGTGG 21233 GL261 Hnmpll GAGCAGTTCTTCCAGCCAAT 15250 MC38 Dcstamp GAAGCTCGTAGGCTTAATAT 21234 GL261 Hnmpll GGAGGCGGAAGTTCGGCAAG 15251 MC38 Rrml CCACCCAACCGCGCGCTCCG 21235 GL261 Hnmpll GGGCGGAAACTCTCGGGCCC 15252 MC38 Rmi2 GTCTTTGTGCGGAAGGCCTG 21236 GL261 Scnlla CTCCAGGAGATTCTCGCTCT 15253 MC38 Rmi2 CTCGCAATCCTAACCGGTTC 21237 GL261 Scnlla CAGTCACTTCTCTGGTTACA 15254 MC38 Mail TAACCAATCAACACCAAGAG 21238 GL261 Scnlla TGGGAAGCTGGGTGGAGCTC 15255 MC38 Slcl5a2 ACAGTGCTAGAGAATCGATT 21239 GL261 Ptbpl GCGTCCCACGGGTCGAACAA 15256 MC38 Slcl5a2 TACTCAAGAATGCAGCATCT 21240 GL261 Ptbpl TCTTGAGAGTGGGTACGTGG 15257 MC38 Slcl5a2 TATCTAGTCCTCATITGCAG 21241 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Ptbpl GTTGCCTCCATATTGCAAGC 15258 MC38 Tmeml32c GGGCGGGATCAGCAGGACCG 21242 GL261 Adssll TGCTTGCCCAAGTCGTGTCG 15259 MC38 Tmeml32c ATCCGGAGGGTGTAGTGGGC 21243 GL261 Adssll AGAACACCCTAGGACGTGAG 15260 MC38 Tmeml32c CCCGCTCGCGGCCAGAGGGA 21244 o GL261 Adssll GCGCACGCGGTGACGCACCT 15261 MC38 Ier51 TGGCCAGTCAAGTGGTCCCG 21245 GL261 Pwwp2b CTGTGTGCCGGCCGCCACCG 15262 MC38 Ier51 CTATTGGCTAATCTACAGTG 21246 GL261 Pwwp2b GCAAGCCCAGCTTTGAGAGC 15263 MC38 Ier51 GCTGCCCAGCTAAATAGTTG 21247 r GL261 Pwwp2b ACGTCAGGCGGCGTCACGCG 15264 MC38 Spice 1 GTTGGTGTGCAAGTTTCTTT 21248 o 4 GL261 Slc2al2 TGGGACTCAAAGGCAGTGTT 15265 MC38 Spice 1 CTTATGACAGGCGCGCCATT 21249 6 1 GL261 Slc2al2 AACAGCCTGTGTCACCGAAA 15266 MC38 Spice 1 CCCACGCCTTTGCGTACATC 21250 GL261 Slc2al2 TGCTTCCAACTCGCATCTAA 15267 MC38 Dzip3 TTCCTGTTCCGGTCGGACTC 21251 GL261 Fam71b GACTGCTGGTGGTATGGCTG 15268 MC38 Dzip3 TGGAATCCATGCCGACGAGC 21252 GL261 Fam71b CAGGTCACAAAGGACGGCAG 15269 MC38 Dzip3 GCGGCGACCGCTGAAGACAG 21253 GL261 Fam71b GGGTGTTGGTCTGATTTGAG 15270 MC38 A430105I19Rik CACAGGAGATCTAGGCACGA 21254 GL261 Zfc3hl AGGGACACAAGGGCGAAGCC 15271 MC38 A430105I19Rik GGGTGGCGGCTAGGCGTTCC 21255 GL261 Zfc3hl AGACTCGGAGGGTCGCCTTC 15272 MC38 A430105I19Rik TCAGGATCACAGGTGAAAGT 21256 GL261 Zfc3hl AGGAAATGACGCTCGGGACC 15273 MC38 Cops3 ATCTCGCGGCGCTTGGCCGG 21257 GL261 TspanS GCAAATCGAAGTGAGACACA 15274 MC38 Cops3 CCCGGCGACCCACTAAAGCC 21258 GL261 TspanS TGATATCTGTTTACTCTAGA 15275 MC38 Cops3 AAAGCGACTGCTCTAGGAGG 21259 GL261 Tspan8 GAATGGCACAGCGAGATAGT 15276 MC38 Fosll AACCTTGGCTAGTCTGAACG 21260 GL261 Ceslc TTGTTCCTGCCTCTTTGCTG 15277 MC38 Fosll GCAATITCCTTGCCGCGCCC 21261 GL261 Ceslc GGAGGTCCTAACAAACACCC 15278 MC38 Fosll GTGGCCGCCGCGGATGCTAG 21262 GL261 Ceslc CCCTCCTCCAAAGAGCTCCC 15279 MC38 Theg TCCAACACTGGGATGGAATG 21263 GL261 Pla2g7 GGGCTAGAAAGATAGGCTTG 15280 MC38 Theg AACAGAAGAATGCCCACCCA 21264 GL261 Pla2g7 GCGGATATGGAGAACAGAAC 15281 MC38 Theg AGTGGGAGACAAGAGGCGAC 21265 GL261 Pla2g7 ACACTAGTCGAGAATCTAAA 15282 MC38 Hipk3 GCGGCTGCAGGCGGACCCTG 21266 GL261 Mboat4 ACTGGAGATAAGCAATGTAA 15283 MC38 Hipk3 TTGGATCCGCGCGGGCCGCC 21267 GL261 Mboat4 CCATGGAAACCAAAGTATGC 15284 MC38 Hipk3 GCCGCTCTGAGCGCCGAGCC 21268 GL261 Mboat4 TAGGATGTAGAAAGGCCTGC 15285 MC38 Usp34 GGGCCGGCGGGCCCGGGAGC 21269 GL261 Abcg5 AATGGCATCGTTGGCCAAAT 15286 MC38 Usp34 GGGCGCCTAGGCGCCGGCGG 21270 GL261 Abcg5 AGAACACACGGTGTGTTTAT 15287 MC38 Usp34 GAAGCGACGAGGGCGGGCGG 21271 GL261 Abcg5 GGGCTGGGTAGGATCGGACA 15288 MC38 Pgapl GCGCTGAGCGGCAGGCGAAG 21272 GL261 Asl TCATCAATCACGCTTATGGG 15289 MC38 Pgapl CCTGCGCAACTGCGAGCAGC 21273 GL261 Asl AGTCAGCACTAGTTGTACTG 15290 MC38 Pgapl AATGGAATGAGAAAGCGGAG 21274 GL261 Asl GCTAGTAGCTTAGCCAGAGG 15291 MC38 Nr2fl GAAATGGCACAGGCGGCAGC 21275 GL261 Smtn TCCCAATGGGACCAGAGCAG 15292 MC38 Nr2fl GCGAGAGTGTGCGCGCGCCG 21276 GL261 Smtn GGCGTGTCTCAACAGAGAAT 15293 MC38 Nr2fl GCGAGTGTGTGTGTGCGCGG 21277 GL261 Smtn TGCGAGGTCCTAGACATCCT 15294 MC38 Cpeb3 GGTTCCTGCCGGTCCGCCCA 21278 GL261 ZbtbSa ATTGTACTTTACGTTGGGAA 15295 MC38 Cpeb3 GAATCTGTCAGGCAGCTAGG 21279 GL261 ZbtbSa CACATGTATACAGTATTTGT 15296 MC38 Cpeb3 TTGGATTTGAGGTCAGAGGG 21280 GL261 Zbtb8a TATGTGGAGATATTGGTTCA 15297 MC38 Tmem255b CCCTTCCAGTCTCTAGTCCC 21281 v > GL261 Phactr4 GAGGGTAGGAAGTGCCGCCG 15298 MC38 Tmem255b TTCTTAGACTCTTAATTTCC 21282 o GL261 Phactr4 AGTGGACTACAAGTCCCGTG 15299 MC38 Tmem255b GGAGGTGTAGGAGATGGTGG 21283 30 GL261 Phactr4 TGCCCAGATCGGCAGAGTAG 15300 MC38 Cabinl GTGTCTTTGACTCGCGCGCG 21284 GL261 Ankrd24 GGCTGCCCATCTGAGCAAGC 15301 MC38 Cabinl TGTCAGCCTTATCAGCCAAT 21285 GL261 Ankrd24 GCTGCCATTGACCCATCACA 15302 MC38 Cabinl CCAACAAGGAACGCTCTCAT 21286 30 6/1 GL261 Ankrd24 GGTGGGAGAGGCCGTCCTTG 15303 MC38 Cxcrl GAGAGAACACCCTTAACTGC 21287 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Slc30a2 TTCTAGAAACTTGGATTCCA 15304 MC38 Cxcrl GGGTCACCCTGCTAAGCCTA 21288 GL261 Slc30a2 TACAGGATTCCAGGAAGAGT 15305 MC38 Cxcrl CCCAAATGCAGATGTGGGCG 21289 GL261 Slc30a2 TTGCCTAGAGTTGCTAAGTT 15306 MC38 Axin2 AACTCCGGCCGAGAACACCC 21290 o GL261 Tmprssl3 GGACAGGTCTGGCGAGTTCT 15307 MC38 Axin2 GGGCCAAGGAAGGGTTAACG 21291 GL261 Tmprssl3 TTAGCTGAGTAACTGGGATG 15308 MC38 Axin2 GGGAGCTGAGTGTGCCACGG 21292 GL261 Tmprssl3 GGAAGTCGGTGGGACGTGTG 15309 MC38 Smg5 GTTGACTTCCCGGAGAGAGA 21293 r GL261 Pgbdl AGCCCTGGCGAAGGCACTAC 15310 MC38 Smg5 TTCTGCTGGGCTTAAGTCCT 21294 o 4 GL261 Pgbdl GTACATCTATTACGTTCGTC 15311 MC38 Smg5 CGATAGCTGCCGCCAAGCCG 21295 6 1 GL261 Pgbdl CTAAGGAGCACAACGCTTGC 15312 MC38 Gprl76 AGAGGATCAGAGCGTGCGCG 21296 W GL261 Cd GACAGGAAGAGCCAGCATCC 15313 MC38 Gprl76 CCTAGTGGGATGGGAGCATT 21297 GL261 Cdh23 GCTCTTATGGCATGTCTGCC 15314 MC38 Gprl76 GCACGGTCACAGAGCATCGC 21298 GL261 d 23 ACACATGGACCACCATTATG 15315 MC38 Hecwl TGCTAAGTGTTGGAAGGATA 21299 GL261 Gcnlll CCACGCGGCAAGGCGAGGCC 15316 MC38 Hecwl CTGGTTCCAGATAAGCCTCG 21300 GL261 Gcnlll AGCTGCAGGGCGCTGTCCGG 15317 MC38 Hec l GGGTGCGTGAGGCTGCAGGG 21301 GL261 Gcnlll CGAGGAGATCCCGCGCCCAG 15318 MC38 Gprc5a CTGTGCTTCTGACGTCAGGG 21302 GL261 4922502D21Rik AAACAACTCTAAAGTTACAC 15319 MC38 Gprc5a ACACGCCTAATCCAGTTCCG 21303 GL261 4922502D21Rik GAAGGGAGAGGATGCTAATC 15320 MC38 Gprc5a GTTATAAAGGCTTCTGTCGC 21304 GL261 4922502D21Rik CTTTATCAGATAGTTTACAC 15321 MC38 Hnmpk GATAGCCCAAGCCGCCATCC 21305 GL261 Dyne lhl CTCCGACTACAAGTCCCAAA 15322 MC38 Hnmpk CGCTGCTCACGTGTGCCGGG 21306 GL261 Dyne lhl GTTACGCATGCGACTGGAGG 15323 MC38 H mpk CCGAGGGAGTTTGGCGCGAT 21307 GL261 Dyne lhl ATGAAGACAGACGCGGTTCC 15324 MC38 Ankibl GCTCGCCATCCCACCGCTAC 21308 GL261 Mrps35 GGTTGACTGTTGTGGAATGA 15325 MC38 Ankibl GCGCCGGGCAATAACTTCCG 21309 GL261 Mrps33 GGGACCGGAAGTGTGTAACC 15326 MC38 Ankibl GAAGGAGAAGTTACCA AGTT 21310

S GL261 Mrps35 ACGTAGACTGTGAGACTTCT 15327 MC38 Slc6al2 CGATCACAATTGCTCAGGAA 2131 1 GL261 Ifi47 CATTTCCACTTGGCCTGTGA 15328 MC38 Slc6al2 GAAGGTGTGGTCTCTAAGTA 21312 GL261 Ifi47 AAAGCACTCAGTTAGCTGGC 15329 MC38 Slc6al2 TTAAAGGGCAGGTGTGGCCG 21313 GL261 Ifi47 CCTGCAGCATAAACATTTCC 15330 MC38 Octf2 CTTCATAAGGAGACGGTTCT 21314 GL261 Inhbc GCCAAATGAGCTGCCAGACC 15331 MC38 Odf2 GGCAGGGCGTAGAGTGCCGC 21315 GL261 Inhbc AAGCCAGTTCAGGTGGAACT 15332 MC38 Odf2 CGCGTGTCTCCCTGACGACG 21316 GL261 Inhbc TGTAGCCAGTGAAAGTACAG 15333 MC38 Pbk AGCGTGCTTCTTACACACCG 21317 GL261 Bboxl ACAATACTGCAAGTGGACTC 15334 MC38 Pbk GAAGAAATCTTCCAGAGCGA 21318 GL261 Bboxl CTCTTGATTTGGATTTGATG 15335 MC38 Pbk AAGGTCCCGCCAGAAGACTA 21319 GL261 Bboxl CACTGCTGAGTGGTAGGCAG 15336 MC38 Dbf4 ACGCGGGAGAGCCGGGTCTG 21320 GL261 Rsrpl CGGATGTCTGTGCGCATGCT 15337 MC38 Dbf4 AGCGGAGCCGGAACTCGAGG 21321 GL261 Rsrpl GACGCGCATGCGTGTCTCCA 15338 MC38 Dbf4 AGCCTGCGCGAGGCCGGCCC 21322 GL261 Rsrpl CTTGGCGATTGGACGAGAGT 15339 MC38 Chad ACGCATCTCTGGGCGGGAAG 21323 GL261 Cst7 ACCAGAAGCGCTTCATCTTC 15340 MC38 Chad AGCGACAAGTCCTCGACTCT 21324 GL261 Cst7 AGAGAGGGTGCTGCGCTCGT 15341 MC38 Chad TCGGTGCTCCACGTAGTAGC 21325 GL261 Cst7 TCCAAGCTGTGATCATTTGC 15342 MC38 Ptpro AACTCCTCAAGTGCAGATCT 21326 GL261 B4galnt4 CGGGATTCGGCCACTACTCC 15343 MC38 Ptpro TACAAGGGCAAAGGAACGGG 21327 xi GL261 B4galnt4 AGCGCAGCAGGGTGGGCCGG 15344 MC38 Ptpro CACAGAAACTATTAATAGTC 21328 o GL261 B4galnt4 AAAGGACCATGCGGTGCTGC 15345 MC38 Svil TGGTGCATTGCTGGAGCGAA 21329 o GL261 Kiflc CGAGCGGGCACGCGCTGTCC 15346 MC38 Sril GTTTACTTGCTAGCAGAGTG 21330 o GL261 Kiflc GGGCTCGCCGGGCAGAGACA 15347 MC38 Svil AAATACAGTGTGGTGTTTAG 2133 1 GL261 Kiflc GGGCAGTGCACTCTGACAGT 15348 MC38 Fign GTGATTTGAATTTGGCTCGG 21332 SO 6/1 GL261 Ctsa ACATCTACCACAGCGTAGAG 15349 MC38 Fign GGCGTTGGAGCGCGGCGGGC 21333 OS Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Ctsa TCCAGCTGGAGTATGGCTGT 15350 MC38 Fign GGGAGGCAGTGGCGAGAGGC 21334 GL261 Ctsa TAATCTGTGGGCCTGAGGGT 15351 MC38 Wscdl ACGTGGTGGCAGACGCACAG 21335 GL261 Pgrl51 TGTACCACGAGATGCTGTCT 15352 MC38 Wscdl TGGCGGCGTACTGCTGCGAG 21336 o GL261 Pgrl51 ACCCAGTCCCACTGACGCGG 15353 MC38 Wscdl CACTCACTCAGAAGCAAGCT 21337 GL261 Pgrl51 GGTCCGCAACACACAGGGTG 15354 MC38 Rpal AAAGTTCCGACAGCTGGCGG 21338 30 GL261 Obsll AAGTCACTCAAGCCCAAGCC 15355 MC38 Rpal CTCTTCCGAGGCCGGGTTCG 21339 r GL261 Obsll ATATTCTCTGATGACACAGC 15356 MC38 Rpal TGCGGTGGCTATCGGCGTCT 21340 o 4 GL261 Obsll GGCCTCCAGGTCTCCAACTG 15357 MC38 3830417A13Rik GGATGTTGATGCGGAAGTTT 21341 6 1 GL261 Laspi GGGCTGCACTGGCTAGGGCG 15358 MC38 3830417A13Rik CGCTGAGTCATCCAAGTCCC 21342 W GL261 Laspi CGCGCCTCGGGCGCGGAAAG 15359 MC38 3830417A13Rik GAGGGTCTCACATAAAGTCG 21343 GL261 Laspi GCGGGTTCCAGGGAGGACTG 15360 MC38 Gpm6b TCACAAGTCTATTATTTCCT 21344 GL261 Lnc27 AGGAGAGTCTGTGCAGATCC 15361 MC38 Gpm6b GGGCCCTGACGTCAGCGCCG 21345 GL261 Lrrc27 AGCAGGGTATTCTGGGAGGC 15362 MC38 Gpm6b GGCTTTGTGCGCCCGGAGCG 21346 GL261 Lrrc27 AGGTTTAGGGTCTATGGACT 15363 MC38 Kcp AGAAGCCCTAGGTGCGATAG 21347 GL261 Iars2 GAGAGGTGTTTACTATCACT 15364 MC38 Kcp TCTGTGCTCAGCCGGCGCTG 21348 GL261 Iars2 GGTCTTTCATGAGGTCTAGT 15365 MC38 Kcp CTATGGGTCAGGATCCTCAG 21349 GL261 Iars2 GCAAAGCTAAAGCCGTGCAG 15366 MC38 Emp2 ATGTCAGGAGCCGCCGATCC 21350 GL261 Ago4 CCCTTCGCTAGCCGGGACCC 15367 MC38 Emp2 TCTGTAAAGTTCGAGGGAGC 21351 GL261 Ago4 CCGAGCCCAGAGGACGCGTC 15368 MC38 Emp2 AGGGCAGCGATGATCCCAGC 21352 GL261 Ago4 GGGTCCAGCGAGCCTGACCG 15369 MC38 Aoxl TTTGGCATCGATGGGAGAGA 21353 GL261 Fam219b CCGAAGTCTGTCTGAGCCTG 15370 MC38 A l GGGAGACAAGCTGAAATCTT 21354 GL261 Fam219b GGGTTTCCCTTGGCGCnTC 15371 MC38 Aoxl CAATGCTGCAGAGGTCCTAA 21355 GL261 Fam219b AAGGTTCCGCCCTACCCGTC 15372 MC38 Lonrf3 GCAGCGTGGTAGGAGTCACG 21356 GL261 Hhatl AGGGAGGTCAAGTGAGGCCC 15373 MC38 Lo r AGCTTTGCGCTTGCTTCTTT 21357 GL261 Hhatl AGATTGCCTGGAGGCCTTCC 15374 MC38 Lomf3 GCTGCTCATTGGCCGGCAGC 21358 GL261 Hhatl TGAGAGGGAGAGGAGGTTTC 15375 MC38 Spbkap GAGGCGGGAATTAGGCTGAA 21359 GL261 Tm9sG AGGACTTCCGGCGTGTGCCG 15376 MC38 Spbkap ACAACTTCAGGGCTGAGACT 21360 GL261 Ttn9sG TCTGACTCAGCCACGTCATC 15377 MC38 Sphkap TGTTCACCAGAGAAAGCAAG 21361 GL261 Tm9sG GCAGCACAGCAGCGGCGACT 15378 MC38 Armcx4 GAGGAGGGCGAGCGATGACG 21362 GL261 Caa l ATTAAATCTTCCCAGAGGTT 15379 MC38 Armcx4 ACTGCTTTCTGACCAGTGGG 21363 GL261 Caapl TTACTACGCGTAGCTTCTGG 15380 MC38 Armcx4 TTGCCTGTGCGTACAGAAGG 21364 GL261 Caapl AAAGGTGACGTGTGGTCCAA 15381 MC38 Klklbll GGCCCTCCAATTCCACAGCC 21365 GL261 Fbx 21 AAAGGCTGATGAGCTGTGGT 15382 MC38 Klklbll CGTTGCGCCCGCTGTACAGT 21366 GL261 Fbxw21 CATCTGGCACCAGTGTGTGG 15383 MC38 Klklbll ACTCCCTGCTTGCACCCTCC 21367 GL261 Fbxw21 GACTCGGCCAAAGATTTAGC 15384 MC38 MaplO AAGTCTCGCGAGGGCGCGGC 21368 GL261 Zbbx GCAGCAAAGAATTGAACGGA 15385 MC38 MaplO AGAACTCCCAAGAGCACTCG 21369 GL261 Zbbx AAGGCCTATGTACCCTTGGG 15386 MC38 MaplO GGAGCAGCTGCGTGATGCTG 21370 GL261 Zbbx GTCATTCAGCATGGGTTTCC 15387 MC38 Plppr5 TCGCGGATGCTCCCGAGCTG 21371 GL261 Nags AACTTGCCGCTGATCTGGGC 15388 MC38 Plppr5 CGGCCCGAGGCAAGCGGCGT 21372 GL261 Nags GGGTACGGAACCGTTAGTGA 15389 MC38 Plppr5 CGGCACTGTGGTCAAGCCCT 21373 xi GL261 Nags CACGAAGGTCAGATTTAGAG 15390 MC38 Prmt5 CCACGTCACTGTGAGAATTG 21374 o GL261 Actr5 CCACGCCTCTTCGCGCTAAC 15391 MC38 Prmt5 ATGAGAGTCTGTCATTGGTG 21375 30 GL261 Actr5 GGTCCCTTAGTTAGAGCAAG 15392 MC38 Prmt5 ACAAATGGACTGGGCATTCT 21376 GL261 Actr5 AACTAAGGGCTAGATCTGCA 15393 MC38 D430041D05Rik GGGITCCCACGGTGCGGCGA 21377 ~ GL261 Herc2 TGAGAGACGGCTTCAGCCAA 15394 MC38 D430041D05Rik GCTGCACGAGCTAGGTCCGC 21378 30 6/1 GL261 Herc2 TGCGCCCGCCCAATAGCGCA 15395 MC38 D430041D05Rik GAGCCGCGGCTTCAGGCGCG 21379 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Herc2 TGAGCGGGTGAGTCTCAAGA 15396 MC38 Xpc CATGGCGGACGACGTAGATC 21380 GL261 Zfp384 TGCACATTGAAGCTGTTGGG 15397 MC38 Xpc CGCCCTCGTAGTTTGCATGG 21381 GL261 Zfp384 GTGCTGCGGCTCGTGCTCCC 15398 MC38 Xpc TATAGTTCGCCTTCAGTGCG 21382 GL261 Zfp384 GGGCGGCAGCAGGAAAGGAA 15399 MC38 Ddx20 CACTCAGAGCCGCGGGAGGC 21383 GL261 Gpatchl 1 GAGACACAGGTCCTGCGGAC 15400 MC38 Ddx20 AATGTAGCCTGAGAAAGAGG 21384 GL261 Gpatchl 1 ATCCGGGTCCCTCGGCAGAG 15401 MC38 Ddx20 TACCGGTGTGTTGCCGCCTG 21385 GL261 Gpatchl 1 TCGAAGCGAATCGGCTGTCG 15402 MC38 Cacng4 CGCCCTCCTCCCTCGGCGCG 21386 GL261 Nmur2 ATTGGCCTACAGCGTGCCGG 15403 MC38 Cacng4 CCGGAGCGCAGGCACGCCCG 21387 GL261 Nmur2 AAAGGCATTAACAGCGTGAG 15404 MC38 Cacng4 CCTCATAGTCCGCCGCCCGC 21388 GL261 Nmur2 AGGGTGTTAAGCTGCACTGT 15405 MC38 Grin2b TCTTAGCAGTGGGAGTGAGG 21389 GL261 Trpm6 AACCGAACCCAGGGTCGAGG 15406 MC38 Grin2b GGAGGAGGCACCACGGCCTC 21390 GL261 Trpm6 CAGGGCGCGCGTGTGAGTCC 15407 MC38 Gnn2b CTGCTTCTCACGTCATGAGC 21391 GL261 Trpm6 AGACTGCGGGTCCTGCCCTT 15408 MC38 Laol TTATCCCACCAATCGGTCTC 21392 GL261 g 3 ACCGGGAAGAGGTGGGAGAC 15409 MC38 Laol ACGGGTCAGGCCTTGGTTCA 21393 GL261 Fgi3 GGTGGAGATGGAGATAAGGA 15410 MC38 Laol TTCTAGAAGAGACTGTCAGG 21394 GL261 Fgi3 GTGGAGAGAAGACAAGAAAG 15411 MC38 Ugtla2 GACCTAGGTAAACATTAATC 21395 GL261 Do\l2 GGTGCTCTTGAGTGCTGGCT 15412 MC38 Ugtla2 AGGAGAATTCCGACTTTATC 21396 GL261 Do l2 TCTGGAACTCAGCAGAAGAG 15413 MC38 Ugtla2 TAGGATCCTGCACTTAGTTA 21397 GL261 I o l2 CACAGTTCACAGTGCTGTTC 15414 MC38 Usp9x GAAAGAAAGGAAGAGCGCTG 21398 GL261 Notch4 AAGACAAGGGAGAGTAAGAG 15415 MC38 Usp9x CCCGCCCTCAGCGCCCGGCC 21399 GL261 Notch4 CTGGTTTGCTCTTAGGGCCC 15416 MC38 Usp9x CTGAGGTGGACAGGGAGAGG 21400 GL261 Notch4 TGTCCTGGACACCCTACTGA 15417 MC38 Dhrs4 GGGAGCGCTCGCAACCGCCG 21401 GL261 Cyp39al AGCTTTGATTTGAACTGGGC 15418 MC38 Dhrs4 AACTTGGACTGAGAATTTGC 21402 o GL261 Cyp39al AGTAAACTAGCTGTTTGCAG 15419 MC38 Dhrs4 GAGTCCCAAATCAGGCAAAG 21403 GL261 Cyp39al GGCGGGAACACATCCTGAGG 15420 MC38 D630045I12Rik GGCGGGCCGGGCCGGATCCG 21404 GL261 Ush2a AATCACGCTCATCGACCTAT 15421 MC38 D630045J12Rlk GGAGACTGGGCGCCTAGCAC 21405 GL261 Ush2a GACAAAGATCTGAACGTTAT 15422 MC38 D630045J12Rik CGGGACGCCGGCGTCCGCTG 21406 GL261 Ush2a CTAAGTTGTGTGGTTCATAA 15423 MC38 Zbtb34 CCGGTCGGAATCCCAGCTCC 21407 GL261 AdamS ACCTAGAAGTTACTTCGGAG 15424 MC38 Zbtb34 GTCGGCCTGCAGCACTAGCC 21408 GL261 Ada S GGCACTCAGAAAGAAGTACC 15425 MC38 Zbtb34 CGATATGGCCGGACTTCTCG 21409 GL261 AdamS CCAGTTCCGATCAGTGGGAA 15426 MC38 Spata20 GCTATTGCTAGTGTCTAGAC 21410 GL261 Trafiipl GGGCCGCGCGGCCTTGGCAA 15427 MC38 Spata20 AGGCATCCTTAGCATTCATG 2141 1 GL261 Trafi i ACACACGCGCTCCGCCTCTG 15428 MC38 Spata20 GGTGATAGAACAGAGCAGGA 21412 GL261 Trafiipl GCAAGCGCGGTGGCGAGCTG 15429 MC38 Paid6a GGACGCGACACCGAGAAACG 21413 GL261 Dnah6 AATACTCTGGGAACACCGAT 15430 MC38 Panl6a AGAGGAAGCACGTGACCGCC 21414 GL261 Dnah6 GTCATTAGTTGTCAGGGAGC 15431 MC38 Paid6a AAAGGACTCGACCAATCCGA 21415 GL261 Dnab6 AGTGCAGTAAGCGTCCTTGG 15432 Pan02 Rgs9 AGTGCATGCTAATGAGCGCG 21416 GL261 Ipo8 AGCATCATGGCGTCTCTGGC 15433 Pan02 Rgs9 TCCTACCTGAGGTTTGGTCC 21417 GL261 Ipo8 TGGTCAGTGCAGCACGCCAG 15434 Pan02 Rgs9 TAGCTTCAGCATCCCTGATC 21418 GL261 Ipo8 AGCCGGCATTCATTGCACAG 15435 Pan02 Gm4559 CTATGACACATCCAGGATCC 21419 GL261 9130008F23Rik GAAGTGGGTGGAGATCAATA 15436 Pan02 Gm4559 CTCTTGTGCATGGTGTTGTC 21420 GL261 9130008F23Rik AAACTCCAGCTAAACTCGGA 15437 Pan02 Gm4559 GGCTGCCCATGCTCACTTCC 21421 GL261 9130008F23Rik TTGAGCGAGGCACTGACTAG 15438 Pan02 Itga9 GCAGTGAGCGTGGTTCTCTG 21422 GL261 Tcea3 GGCACTAAATATAGACTTCA 15439 Pan02 Itga9 CCTCCGCTTGAATCCATACG 21423 GL261 Tcea3 GGGAGGACCAATCTGGAAGA 15440 Pan02 Itga9 AGGTGCAATGGGAGATGCAA 21424 GL261 Tcea3 GGGCAAAGATTGCCTGAGCC 15441 Pan02 Rrbpl GCGGCCGTCCGCGGTCTGAT 21425 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Tecta GCTAGACAGTTGCCTTCTTT 15442 Pan02 Rrbpl TTGGCCAATGGTCGCCACCG 21426 GL261 Tecta TGGATTCAGATGGAAATGTC 15443 Pan02 Rrbpl GCTAGTGAACCAATAGGAAG 21427 GL261 Tecta GGTACTTGGAGCTGAAACCT 15444 Pan02 Ssxb9 CTAGATATAATTGAAAGCCC 21428 o GL261 Lee lb TCAGGCATGGACTATGATTT 15445 Pan02 Ssxb9 TACTTCCTGCCTTGAACACT 21429 o GL261 Le lb TCACAGGTTGGGCAGAGCCC 15446 Pan02 Ssxb9 CAGGAGTAAGCAATGCCAGG 21430 GL261 Lee lb CCTGACTCCTGACACCCATG 15447 Pan02 Kifl2 TTAACTTGCTAGCTCTGGGC 2143 1 r GL261 Zmiz2 GTGCATGTATGCATGCATGT 15448 Pan02 Kifl2 CATGCCAGGGCATTCCAGCT 21432 o 4 GL261 Zmiz2 AGTCGTCTGGATCAGCTTGA 15449 Pan02 Kifl2 TTTCCTCTAGAGAGATCTAA 21433 6 1 GL261 Zmiz2 GAGGGTGGCAGAAGGGCTTC 15450 Pan02 Fmnl GCTGGTGTCACTAGTTGCCA 21434 GL261 Gdf9 TGGGTITGAAATAAATGTCC 15451 Pan02 Fmnl CCCAGAGCCTACGATTCTCC 21435 GL261 Gdf9 TCCACTAGGGTGACGATACT 15452 Pan02 Fmnl GCTGCACACCTTACTACACA 21436 GL261 Gdf9 TGTACAGCTAGGCATGCTTG 15453 Pan02 Cabinl GTGTCTTTGACTCGCGCGCG 21437 GL261 Hormad2 CAACCTTAGACTTAGGCATG 15454 Pan02 Cabinl TGTCAGCCTTATCAGCCAAT 21438 GL261 Hormad2 GTAGAGCAAGGCCTGCTGAG 15455 Pan02 Cabinl CCAACAAGGAACGCTCTCAT 21439 GL261 Hormad2 CCCTCGGCTTTACGACTTTC 15456 Pan02 Mup3 TGAGATTGCCAAGTTTGAAA 21440 GL261 Ctimbll CGGCAGTGTGGCGGGCTCAC 15457 Pan02 Mup3 GAGGTAATGCAGACCCATAC 21441 GL261 Ctimbll TCTGCTCTACTCTTGGATAA 15458 Pan02 Mup3 CACTTATTGATGATAGGCCA 21442 GL261 Ctimbll TGCTTCCGCCTGTAACCTGA 15459 Pan02 Fbxl2 TGATCCGTAGGCACGCCCTT 21443 GL261 Aimll AGGAATGAATGGCCATCAGG 15460 Pan02 Fbxl2 TGGCAGTCGCAGGCCAATAG 21444 GL261 Aimll TGAAGGAAGGCAGTCCGCAC 15461 Pan02 Fbxl2 CCGAGCCCACCTTGAGGCCG 21445 GL261 Aimll GCTTCTGCTTGAATACTTCT 15462 Pan02 Sstrl GCGCTCTGACGTTCTTTGCA 21446 GL261 Dph2 GGCTTTGCGGCACTTCCGAT 15463 Pan02 Sstrl AACTAGACCTAAGCCAATAG 21447 GL261 Dph2 GGACCTACGGAGATTACTTC 15464 Pan02 Sstrl GCCCTTGCAAAGTGCTTGTA 21448 GL261 Dph2 GCTTCTTCCCGGATACCCTA 15465 Pan02 M s31 TTTGGATGGAGTGGATATCG 21449 GL261 Crbl GACACGAATCCAATCCAGGC 15466 Pan02 M ps 1 ATCGAGCCAGCCAAAGACCC 21450 GL261 Crbl TTCTCTATTAGGAGCAATCA 15467 Pan02 Mips31 GAGACCAATCATTATGTTCC 21451 GL261 Crbl AGACGGTAACCAGTCAATCC 15468 Pan02 Pask TCGTTCTGCGATTGGTCGGT 21452 GL261 SlclSbl TTGCTATGTCTTTGAATGAT 15469 Pan02 Pask AACAGTTGCTAGGGACGCAC 21453 GL261 SlclSbl CTTACTTTCTCCTCTTTATT 15470 Pan02 Pask CGCGAAGAAATCGGGTCTTT 21454 GL261 Slcl8bl GTCTCCGCCCATGCTGATCG 15471 Pan02 p2c TTACGTTTACTAGCAATACT 21455 GL261 Zscan20 GGTACCGGAACAAATCTTGC 15472 Pan02 Cyp2c39 ATTTACCCTTGACCATTTCA 21456 GL261 Zscan20 GCCGATAGAGGAGTGGCCAC 15473 Pan02 Cyp2c39 TGTTAACCAGATAGTCAAAT 21457 GL261 Zscan20 GGTGCTCGCGCGTTGCCTTT 15474 Pan02 Fbxw21 AAAGGCTGATGAGCTGTGGT 21458 GL261 Zfp773 AGTTCAGACAGCGTGCACCC 15475 Pan02 Fbxw21 CATCTGGCACCAGTGTGTGG 21459 GL261 Zfp773 ACGGAAGCGCCAGTTTCCAT 15476 Pan02 Fbxw21 GACTCGGCCAAAGATTTAGC 21460 GL261 Zfp773 TACTTTATCCTTGATGATCA 15477 Pan02 Mapk7 GCGCGTGATTGACAAGGGCG 21461 GL261 Z 3 6 CAGCGGAGGCAGCAATCTGA 15478 Pan02 Mapk7 CAATCGTTGAGCGGCCTCCG 21462 GL261 Z 6 TGACGGGCAGTTTCCTCCAA 15479 Pan02 Mapk7 GGGTGATGCGTGCTCCTCAG 21463 GL261 Z 6 GGCCTITAATACGCTCGCTG 15480 Pan02 Nacad GCTCAGCCCAAGAGATTGTC 21464 GL261 Rps2 GCGCAGACAGATCACGGCGG 15481 Pan02 Nacad GAACTGAGTGCGCCAGAGAG 21465 v > GL261 Rps2 TTCGGCGAGGGAAAGTCCGC 15482 Pan02 Nacad ATCTTTGACTTCTAGCTTGG 21466 o GL261 Rps2 CCAACGTCGCCACGGGTTCC 15483 Pan02 Ptbp2 GCGGGCTCGTCTCCGAGGGC 21467 90 GL261 Aoah CAGTGACCACATGAACCTTG 15484 Pan02 Ptbp2 GCACACACGGTGCAGGCTGC 21468 GL261 Aoah GTTTGCCCGAAGCACTCTGT 15485 Pan02 Ptbp2 CCTGGGTTCTTTCTCTTCCG 21469 ~ GL261 Aoah GAAACAGTACTTCCGGCCTC 15486 Pan02 4933402E13Rik GGTAACCTCTGACCCAAATC 21470 90 6/1 GL261 Ewsrl GCTACCATCGGGCCAGGCCT 15487 Pan02 4933402E13Rik CTAGATAGCCATTGGGAGGG 21471 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Ewsrl GTGGCCGAAGAGGAGCGAAC 15488 Pan02 4933402E13Rik GACCAGAGAAGTACTTATAG 21472 GL261 Ewsrl AGGCGCGAAACCCGCAACCT 15489 Pan02 Gucy2d GATTTCTCTGGAATCCTAAG 21473 GL261 Po l 1 CTGTCGTCGACGCGGCGCGC 15490 Pan02 Gucy2d ATTGAATCTGTTCAGACACC 21474 GL261 Poml21 ACGCCTTGCCTCTCAGAACG 15491 Pan02 Gucy2d AGACACCACACAGACGTGGG 21475 GL261 Poml21 TACAGCTTAGGTAGGCGGAT 15492 Pan02 Zc3h8 CATGCGTGGTAGGGCTGGCC 21476 GL261 Rad50 TCGTCCTGCTCGTGTTGCTT 15493 Pan02 Zc3h8 TGCTGCACTAAGGAACGAAT 21477 GL261 Rad50 TCAAAGCAAACAGTGATAGG 15494 Pan02 Zc 8 GCGCTCGCGCTCATGTTGCT 21478 GL261 Rad50 GAGATCGGGTCTAGCTCTGT 15495 Pan02 Hbb-bh2 GCTCATAGGGTAGGGAGGGC 21479 GL261 4930595M18Rik TATGTACACATTGCCTCCTC 15496 Pan02 Hbb-bh2 CTAGTGTAAACTGGAGAGTG 21480 GL261 4930595M18Rik AACCATTCTAGAATGTCTGG 15497 Pan02 Hbb-bh2 TCCCTCTGTTTATCTCCCAT 21481 GL261 4930595M18Rik TTCAGCCTTATGACTCAGTG 15498 Pan02 Scn7a CTCTAGAAGCTAGATAAGCG 21482 GL261 Bpntl TCGTCAGAGCCTGAGTTCCC 15499 Pan02 Scn7a AAACAGCTACAAGGCTTGCT 21483 GL261 Bpntl CGTTTCTGAGCGTTCTGCGC 15500 Pan02 Scn7a GGCAATAACAGCTTCAGCAG 21484 GL261 Bpntl ACCAGCACCCAGGAACGGCC 15501 Pan02 Alx4 GCCAGCTGTAGGGAGCAAAG 21485 GL261 Secl4l3 CCCGTGTTTGGCTCTGGGAC 15502 Pan02 Alx4 AGATCTCCCAAACCCTCTTA 21486 GL261 Secl4l3 AATCTAAAGAGTTGTCCCAG 15503 Pan02 Alx4 CAGGAAGGAGCAAGTCAGGG 21487 GL261 Secl4l3 TACATAACTGAGATTAAGTG 15504 Pan02 Pnisr CTTCGCTCAGCTACTCTTTA 21488 GL261 Mrgp GCCTTGCACGCCGCCCATTC 15505 Pan02 Pnisr TCCTTACCTAAACTCCAAGA 21489 GL261 Mrgplg ACAGATGTCATCTCTTCCTT 15506 Pan02 Pnisr GAGTAAATGTTCCCACCAGG 21490 GL261 Mrgpig TTCCTTTGATTTCCGTGAAA 15507 Pan02 Xpo7 CGGAGGGCCGTGGAAGCGCA 21491 GL261 Npcd CGGGCCTGAGCGCCGTTGCC 15508 Pan02 Xpo7 GGAGAATGCGCAGCGTGGCT 21492 GL261 Npcd ATCACGTGACGGCCCGCAGC 15509 Pan02 Xpo7 GACTCGGCGCGCTACGCTCG 21493 GL261 Npcd GGCAGCAGCCAAGCATCCAT 15510 Pan02 Usp29 GGGTCITGGATTGGTTAGAG 21494 GL261 Agm GGACCGCAGCGCGGCGGAGG 15511 Pan02 Usp29 AAGGCAACAGCTTGGCGCCA 21495 GL261 Agm GGAGGGAGGGCGGACGGCGT 15512 Pan02 Usp29 ACAACAGCAGTCTGATTGGC 21496 GL261 Ag GGGCGGGCTGAGCCCTCAGG 15513 Pan02 Uni GGGTCGTGCCTGAGGTTCGG 21497 GL261 5430427O19Rik GGTAACTGACAAAGCCACAC 15514 Pan02 Tlnl CGAGCCGACTGGACAGACTG 21498 GL261 5430427O19Rik GAGGAAGAAACACCATTCTG 15515 Pan02 Tlnl GTGCACCACTTCCGTTGTGT 21499 GL261 5430427O19Rik CACAAGACAGTTTCACAGAT 15516 Pan02 Rimbp3 CAGGCGGATATCTGAGTTTG 21500 GL261 Th TGGGCACAGAGCGAGGGCGA 15517 Pan02 Rimbp3 CTGTGTAGCCCTAGCTGTCC 21501 GL261 Th AAGAGGCCGCCTGCCTGGCA 15518 Pan02 Rimbp3 CTCCCAAATGCTGGGATTAA 21502 GL261 Th CAGGCACAGCAGGCGTGGAG 15519 Pan02 Rnfl38 AGCGTGAAGGCGGAGCTTAG 21503 GL261 Asap3 GAGGTAGACAAGTGGTCTGG 15520 Pan02 Rnfl38 CTCAGGAAGCGGCCTGCGTC 21504 GL261 Asap3 AGGGAGTTACCAGCGAGTCG 15521 Pan02 Rnfl38 GCGGATTGTGACGAAAGCAA 21505 GL261 Asap3 GGGCGTGACCAGGGAGTTAG 15522 Pan02 Vatll TGACTTAGTACTAGCACAAA 21506 GL261 Tspan32 TTCTATACCAGCTGTTGCTC 15523 Pan02 Vatll TGGGATGCTCTTCAGTGCAA 21507 GL261 Tspan32 GTCCTCCCATCTGAAGACCC 15524 Pan02 Vatll AACCTCTGTGAGCGGAGCCG 21508 GL261 Tspan32 AAGGGTTGCTGACAGATAGG 15525 Pan02 Prickle2 GCGGGTGGACTGGGCTGGTG 21509 GL261 Nepn GGTTAGCAATCATTACAAAG 15526 Pan02 Prickle2 GAGAGGATGGGACTGGCTGG 21510 GL261 Nepn TAAGCTGCCTTAATATCTCT 15527 Pan02 Prickle2 CTTATGATTGGCCCGCAGCT 21511 GL261 Nepn GATTCTGTTATCAGACTCCG 15528 Pan02 Zf 3613 CAGACGTACGTAAGATGTGC 21512 GL261 Efcab5 GGTTCAAAGTACAGCTGCCG 15529 Pan02 Zfp3613 AGAATGCATGAGCGTGAGAG 21513 GL261 Efcab5 CGATAAACTGAAGAAGGAAC 15530 Pan02 Zfp3613 AAAGGGCAGGTAGGCGGAGC 21514 GL261 Efcab5 GGGATGACTTGGCTAAAGAG 15531 Pan02 E ud2 AAGGCCGGAGGATTCTGATC 21515 GL261 Sult6b2 AATAGACATTGGCTCAGTTG 15532 Pan02 Eftud2 ATTTCTCGAAGCTGTTCCTT 21516 GL261 Sult6b2 AGACACATGGAATATCAGCT 15533 Pan02 Eftud2 CCCGGAGACAGAAATGGGAA 21517 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Sult6b2 TTCTTCTAGAGAGCTGCAAA 15534 Pan02 Slc7a2 GGAGTTAGACACCGCCTTCC 21518 GL261 P4ha2 GCCGGTGGTAATGGATGTGG 15535 Pan02 Slc7a2 GGGTCGCGAGCACGAGGGAG 21519 GL261 P4ha2 CTCCGAGCCACTGGAGCCTT 15536 Pan02 Slc7a2 CGTGACAAACGCTCCAGGCG 21520 o GL261 P4ha2 GCACACCTCCTTGCGCCGCG 15537 Pan02 Eln TTCCCTCACAGCAGCCTACC 21521 o GL261 Cd33 GTCGAAGACTATGGTGTCAC 15538 Pan02 Eln CCCAAAGCGTAATTGCTGCC 21522 GL261 Cd33 CACTGAGAAGAACCCACCTC 15539 Pan02 Eln GCCAGACTTGCAAGCCTCCT 21523 r GL261 Cd33 GGACTGAGAAGAAATCTCAC 15540 Pan02 Plekhg3 CGGACCAGGAATGTTTCCAG 21524 o 4 GL261 Mpl AGAGACAGGGACAGGACGTG 15541 Pan02 Plekhg3 GCGTTAATCATTAGCCACGG 21525 6 1 GL261 Mpl GTATCTGACAGGAACCTGAG 15542 Pan02 Plekhg3 CGCGGCTGCGATCCAGCAAT 21526 GL261 Mpl GGGCCCATCCAGACCACACT 15543 Pan02 Gal3st2 GAGGGCTAACATGGACGGTG 21527 GL261 Tbcld9b CTCTGCCTACTGTGCAGCCC 15544 Pan02 Gal3st2 CTTGACCAAGGAAATC1TCA 21528 GL261 Tbcld9b GGGTCGAGACGTCGGCCCGA 15545 Pan02 Gal3st2 CCCTTCCTGTATCACCAGGG 21529 GL261 Tbcld9b TCGCCCTCCTCGACCTCTCC 15546 Pan02 Esrra CACGCGTGCGCGGCCTCCTG 21530 GL261 Hr 3 TTGGCTGCGCGCTGAGCTAG 15547 Pan02 Esrra GAGGAGCGAAGACTAGGAAC 21531 GL261 Hrh3 CGGGCACGCGGCGCTGTCCG 15548 Pan02 Esrra GGATATTAGCATAGGGCACC 21532 GL261 Hrh3 AGGGCGCCAGCCAATGGCGG 15549 Pan02 Gm906 CCTCCCAAGCCTCCAGGACA 21533 GL261 Nacad GCTCAGCCCAAGAGATTGTC 15550 Pan02 Gm906 GCAGTGTGAGATGTGTCAGG 21534 GL261 Nacad GAACTGAGTGCGCCAGAGAG 15551 Pan02 Gm906 CCAAATCCTGCTGCTGAGTC 21535 GL261 Nacad ATCTTTGACTTCTAGCTTGG 15552 Pan02 Slcl6al3 CTGGAGACCTGCATCCTAAT 21536 GL261 Shbg GGTAGGTAACCTGGCGCACA 15553 Pan02 Slcl6al3 GCGAACCAAGTGTTGGATGT 21537 GL261 Shbg TGGAGGGTTAAAGGTTGCTC 15554 Pan02 Slcl6al3 GGATITAACACCTGCCTAAG 21538 GL261 Shbg TATAGATCTCTTGGCTGCAG 15555 Pan02 Insc GCTGTCATCTGTGGGAGCTC 21539 GL261 Tcl21 AGGAAGAAGGAATCCGGTAC 15556 Pan02 Insc TTGGCATGTAGGACACATGT 21540 GL261 Tcl21 GAGGCGGATCCATGCAGCCC 15557 Pan02 Insc GCGGTCTCCACCGTGGCCAG 21541 GL261 Tcl21 TGAAAGAGCGCCGAGGAATT 15558 Pan02 Dmrta2 TGTTGTCCAATTCTGTCTAA 21542 GL261 Nfsl GCGCGACGCAGGCCACTGTC 15559 Pan02 Dmrta2 TTCGGACACTGTAGAATGAG 21543 GL261 Nfsl GTGCTCCGGAAGCGATCCCA 15560 Pan02 Dmrta2 GAGACAGTCGGCGCTCTGAT 21544 GL261 Nfsl GTCGAGCTGAGCGATCGCAG 15561 Pan02 Smg5 GTTGACTTCCCGGAGAGAGA 21545 GL261 Pesl GAAITTGGTTGTAAATAACG 15562 Pan02 Smg5 TTCTGCTGGGCTTAAGTCCT 21546 GL261 Pesl AACTTTCTCTGGATTTGTAC 15563 Pan02 Smg5 CGATAGCTGCCGCCAAGCCG 21547 GL261 Pesl AGCCCTCAGCTGGCGGCGTG 15564 Pan02 Spata3 1 TAAGATCTGCAAATGAGAAA 21548 GL261 Csl CGCATTCGTACTTATAGACT 15565 Pan02 Spata3 1 CCAGGAACTCATATATTACC 21549 GL261 Csl AAGCTGTAGCAACTGTTTCC 15566 Pan02 Spata3 1 GCCAGGACTCCACATCACAA 21550 GL261 Csl AAGGGCCTGGCAGTGACATC 15567 Pan02 4930595M18Rik TATGTACACATTGCCTCCTC 21551 GL261 Gsc2 CTCTAGACGTGGCAGAGTGC 15568 Pan02 4930595M1 8Rik AACCATTCTAGAATGTCTGG 21552 GL261 Gsc2 GCTCTCTGAGGACTGGCGAC 15569 Pan02 4930595M18Rik TTCAGCCTTATGACTCAGTG 21553 GL261 Gsc2 CGAACGCGGCGCCCGGTCTG 15570 Pan02 Ttn TTGGGCTGTCAGCAGATCTG 21554 GL261 Zkscan8 AAGCTCTCTAGGAAGCTCGG 15571 Pan02 Ttn GCTCTGTTAGGAAGGCATGA 21555 GL261 Zkscan8 CTCTATGGTAGGCCAGCAAA 15572 Pan02 Ttn TTACAGCCCGGCTCTGTGAT 21556 GL261 Zkscan8 CGAGCGCCCTCAGCTACACC 15573 Pan02 Edar TGCCTGGCGCGGCCTCTAGG 21557 v > GL261 Aebpl AGTTTAGAGGGTCTGGGTGC 15574 Pan02 Edar CGAGTITACAAACAGTCGAG 21558 o GL261 Aebpl AAGGGAGTGTGCGGAGTCTA 15575 Pan02 Edar GCTCTGCCGCTGAGTGCACC 21559 o GL261 Aebpl GCTGACGCTGCTATTAGTCT 15576 Pan02 Ccdcll3 TCAGAACAGTGAGATGGATT 21560 o GL261 Tdg GGTTAAGGGTGATGGCCTTT 15577 Pan02 Ccdcll3 GGAAGTCACAACAACAGCTC 21561 GL261 Tdg GGGAAACGTGGATCTCGGCG 15578 Pan02 Ccdcll3 TAAACAGCGTTCAGTTGTCT 21562 SO 6/1 GL261 Tdg CCGACCGCCGCTTAGCCTTT 15579 Pan02 Foxb2 AGTCTCTCTGGCTACTGTGA 21563 OS Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Gata4 GAGTCCTGCGGGCGGGCGCC 15580 Pan02 Foxb2 GGATGACTAGACTTGAGCTC 21564 GL261 Gata4 CGCAGGCGATCGCTACGCGG 15581 Pan02 Foxb2 TTTATGGCGCTCACAACTTC 21565 GL261 Gata4 GCATGGACTTTGCCTGTTGG 15582 Pan02 Adcy2 GAGCCCAGCCTGGCCGTCGG 21566 GL261 Serpinfl CAGAAGACCCTTTCCCATCA 15583 Pan02 Adcy2 ACTCGGTCTGAAGCTTTCTC 21567 GL261 Serpinfl TAAATATTGACCTGTACATC 15584 Pan02 Adcy2 CTTGCCCTCCAGCCTGTCGC 21568 GL261 Serpinf2 ACTGAACACAAGCTGAACGG 15585 Pan02 Lamal CGCCGTGCGGAGTCCTTCCT 21569 GL261 Btnl9 TTTGGATGTGGGCTGGCAGC 15586 Pan02 Lamal GGAGGTCCTGGGTAGGACAG 21570 GL261 Btnl9 TCCGTCATATCCCGTCCTCG 15587 Pan02 Lamal GGCCTGGTGCGCAGGCCCTT 21571 GL261 Btnl9 ACTCGCCCACCTTTCACCTT 15588 Pan02 Dusp9 TGGTGGGAGTTGCAAGCCGC 21572 GL261 leal CTCAGATCTAGTTGCATGAT 15589 Pan02 Dusp9 CCGACTAAGTAGCAGCTCAA 21573 GL261 leal ACGCGAACGCTATGGACACG 15590 Pan02 Dusp9 CTGAGCTAGGGCTTCCACCC 21574 GL261 leal ATAGAGTTTGGTTACTTGAA 15591 Pan02 Psg25 GGGACACATAGGAAAGATGA 21575 GL261 9430038I01Rik CGACAAGCCACTCACGGCTT 15592 Pan02 Psg25 GATGAGTTGTTATTCTCTGA 21576 GL261 9430038I01Rik GGAAGAATTACCCGCACTTC 15593 Pan02 Psg25 CTTATCAGCCITGTTACTCA 21577 GL261 9430038I01Rik GCCGAAACCCGAATCTCCTA 15594 Pan02 Radii GGCAGAGACGGAGCCTCGAG 21578 GL261 Ttn TTGGGCTGTCAGCAGATCTG 15595 Pan02 Radii CCTATCTTTCTCGGTCGGCC 21579 GL261 Ttn GCTCTGTTAGGAAGGCATGA 15596 Pan02 Radii CACATGTATTAGGGCGGGCC 21580 GL261 Ttn TTACAGCCCGGCTCTGTGAT 15597 Pan02 Pcdhga8 GCACITAGATGCAGTTACTT 21581 GL261 Fat2 AAAGAAAGGAGCATGATGAT 15598 Pan02 Pcdhga8 GGGTGCATCTCTCTCCCAGT 21582 GL261 Fat2 TAAGAAGAGGGAAAGGGTTC 15599 Pan02 Pcdhga8 GCGGCGCTTAGAGTCTTAAA 21583 GL261 Estll GAGCCAATCAGAGCTGGCGG 15600 Pan02 Robo3 TGGCCATCCTGGTGGAGGTG 21584 GL261 Extll CCCTTGCAACCTCTTTCGCT 15601 Pan02 Robo3 TCCGCCCGCCCAGCTCCCAG 21585 GL261 Extll CTGCTGCTGCGAAAGAGAGC 15602 Pan02 Robo3 TAATTACGGCGTGATCCGAG 21586 GL261 170012201 IRik TCACAATAGGTTTGGAGGTG 15603 Pan02 Emilin2 AGAGCCAAAGGGTTAGGAAC 21587 GL261 170012201 IRik TAGATITGGTAAAGACATGA 15604 Pan02 Emilin2 GAAGAGTCACGTTTCGGAGA 21588 GL261 170012201 IRik CTTGTGAGCCATAAGTCCAA 15605 Pan02 Emilin2 GCGGTCCCTCAATGACGCAC 21589 GL261 Paqr6 GGAGTCTTTCTAGGATCTAG 15606 Pan02 Fxr2 GCAGAGAGGCGACCAGGAGG 21590 GL261 Paqr6 CCCAGCACATTCCTTGGCAC 15607 Pan02 Fxi2 GAGCCGGAGGGCCAAGGCGC 21591 GL261 Paqr6 GGCCACTGACCTGGACCGAT 15608 Pan02 Fxr2 GCTGCCGCCGCCTACTGCGC 21592 GL261 Adgrfl AACGGGAAGTCTTTGGTCTC 15609 Pan02 Arfgefl GGCCCGGGCGGCCGTCTTCC 21593 GL261 Adgrfl TTTCAGCAGAGGCAGCAACC 15610 Pan02 Arfgefl GAGGCTTTCGACGCCCTTGG 21594 GL261 Adgrfl GTTGGCTTTCCCTCTGCAGG 15611 Pan02 Arfgefl CGGGCGCGGCCCTCGAACGG 21595 GL261 Catsper4 AAGAACCAAGTATTCAGCCA 15612 Pan02 D6Ertd527e GCTCTGTGTCAACTTGACAC 21596 GL261 Catsper4 TAGAATGTCTGGGTGGAACA 15613 Pan02 D6Ertd527e TGCTGCAGCCTTGCCCAATC 21597 GL261 Catsper4 CCCTTGTGGTGAGATCACAG 15614 Pan02 D6Ertd527e CCATCCAGGACCACCTGCCC 21598 GL261 T 7 AACGAGGCATCATTCATGCC 15615 Pan02 Cts3 TTATAAAGAGTTGTTGGCCC 21599 GL261 Trim7 GAGATCAGACCGACGTATGC 15616 Pan02 Qs3 TCATATGGTACTTGTCCCAA 21600 GL261 Trim7 CTGAAACGGAACGGAATGCC 15617 Pan02 Nppc AGATGACATCAGCGGCAGGT 21601 GL261 Trp53 TTGTGCCAGGAGTCTCGCGG 15618 Pan02 Nppc ATGTGGGTTGGAGCAGAAGA 21602 GL261 Trp53 GTCTAAGATATAGAGCTGTG 15619 Pan02 Nppc TAAAGGCTCCAGCGGAGCCA 21603 GL261 Trp53 GATAGTCGCCATAACAAGTA 15620 Pan02 Lrig3 GAAGGCGGGCGCGCGCCCAT 21604 GL261 Nfaml CTGGAGAGGCCATGGGCTGG 15621 Pan02 Lrig3 AGACTGCTGGCTGCAGACGC 21605 GL261 Nfaml AGAGCATGCGGTAGGAACCT 15622 Pan02 Lrig3 GGCGCGATGTCCCGGCGCGG 21606 GL261 Nfaml CCATGAGTTTGTGGAGAGGG 15623 Pan02 Pfkfbl CACGGTGAACAACACATGGT 21607 GL261 Murc TCGGCAAGCATGTTTGGAAC 15624 Pan02 Pfkfbl GGGTGGCTCAGGAACTTCTT 21608 GL261 Murc GCTCAGTATGAGTAACATAG 15625 Pan02 Pfkfbl ATCTTGCTCACCTCAATAGC 21609 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GGACCTCAAATAAGTCTGTG 15626 Pan02 Dip2b CCGGAGACGCAGGACGGGCG 21610 GTCCAAAGACCCGTCGCAGC 15627 Pan02 Dip2b AATGITTGCAGGGCGAAGTG 21611 GTTTGATCTCTCGGTGCTAG 15628 Pan02 Dip2b GAACGGCTACAGTTAGAATT 21612 CCTGGAGTTCCCATGGGTCT 15629 Pan02 f t TTTAAAGGGCTGGGTGAGCT 21613 AGTCTGTGTTGTATCTTCTC 15630 Pan02 ifiti CTGAAGCCTGCAGTTTATCC 21614 TACACAATCCTCGAAGCTGT 15631 Pan02 Ifltl TTTCAGTGGAGAATGCAGTA 21615 GCTTGACAGACCCACTGTGG 15632 Pan02 Sugp2 CCCACGTGGCTGCGTAGACC 21616 AGTAAGTTATCCGGGACCCT 15633 Pan02 Sugp2 GTGCTTGTGGCTGGCGCAGT 21617 AGGAGTATATGTTTAAGCAG 15634 Pan02 Sugp2 CCTCTGCGCTTGCGCTTATA 21618 CCAAATTAACCCATTATTGT 15635 Pan02 Thoc5 GGCTCGCGACCATAGAGAAG 21619 GCAGCCGCCTAAGCTGTCTT 15636 Pan02 Thoc5 TAATTCACACTCCGGTGAAG 21620 ACGCCCATTGGGCCTCCCAC 15637 Pan02 Thoc5 CGAGTCTAGTTCTATTAAGT 21621 GCCCACGCGGGAGGGACATG 15638 Pan02 D113 GTTACTGTATCCCTITCCCT 21622 AATAGTCTAAAGTGCCGAGG 15639 Pan02 D113 ATGCCGGAGTCTTATATTTG 21623 GTTGAGTCGATGAGAACACA 15640 Pan02 D113 TGGCGCATGCAATCACACTC 21624 GACCCTCCGTTCTCATCTAG 15641 Pan02 Ccdc63 GCTTGGTGACAAGTGGAACC 21625 GGTTACTGGGTGCGGCCTTG 15642 Pan02 Ccdc63 CAGGGACACAAAGGATGGAA 21626 GTCCTCTAGACGGGTGGGCG 15643 Pan02 Ccdc63 AGTCTGGAGCAATGCATTGT 21627 TTCGGGCCGGACGGTCCTCC 15644 Pan02 Acsf3 TGAGCAGGAACGTTCGTTCC 21628 TTCGCAGACAGGCGTGCGGA 15645 Pan02 Acsf3 ATCTGCTCGCAAGTCTTGAG 21629 CGCCGCCGGGCAGGAAAGAG 15646 Pan02 A f3 TCCGTCGATCTAATACGTCC 21630 GCCGCCCAACCTGACAGCCC 15647 Pan02 Abcc4 TACAGTCAAACAAAGATGAG 2163 1 GTCCGAGTCCCAGGTCGTGC 15648 Pan02 Abcc4 GGAGCTGACTCTGATGTTCT 21632 CAGCGCCCGACCGCTTATAT 15649 Pan02 Abcc4 GACAGAGACCAACCGCGCGC 21633 GTCTATTTAGAACCCAGCCC 15650 Pan02 Cul9 GGAGTATGGGTTAACTAATG 21634 GGCAGTGGGAGGTGCTGAGC 15651 Pan02 Cul9 AGATGGACCCGGTGGAGCGC 21635 GATTACCCTTCTTACCCTCG 15652 Pan02 Cul9 GGAGCATGCGTATTAGCCGA 21636 GAGCCGTAACCTGCTCTTGC 15653 Pan02 Tmem44 AAAGGGACTGGGTGCTGGCG 21637 ATTACTGGTCCCGTGACGCC 15654 Pan02 Tmem44 CTGGCGCGGACCAGCGCTAG 21638 GCAACTCAGGTCACAATCCC 15655 Pan02 Tmem44 ACCAGGGACAACGCTCCTCG 21639 AGGCGTCCGTACCGCTTGAC 15656 Pan02 g CCCATCTGAGTCTACTCATC 21640 TGCCCGGGTCGAGGTCGGGT 15657 Pan02 g CCTGTTCAAGGACACTTGAC 21641 TCCGCTGGGTCCAGGAGCAG 15658 Pan02 Tg TCCCACTAAGAATACTCAAG 21642 GAGTTCCGGCCAGGACCTGG 15659 Pan02 Napll2 ATGGCTGATTCCTCCACCTA 21643 TTTGGAGACGGAGACAGGTC 15660 Pan02 Napll2 AGAGAATCTGGGAAGGCAAG 21644 GTCGCTGGCAGCGCGGTCGG 15661 Pan02 Napll2 ATCTACTAATTTACTGGCTC 21645 TTTCCCGCCATTGTGAGAAG 15662 Pan02 Oas3 AACACCCTGAGCCTGAGTCA 21646 CAGTAGTCCTAAATCATCAG 15663 Pan02 Oas3 AGAGGGTCAGAAGTCACACC 21647 AGTGGCTGGTGCAGAATTCA 15664 Pan02 Oas3 TTTATGGTTCTGCTGTCTCC 21648 TTTATTGTCCCTCCAATTTC 15665 Pan02 Lcp2 TAAACAAGGAAGGACAGCTC 21649 CCTGGAGGGCGTCCTGGCGG 15666 Pan02 Lcp2 GTCAGCAGAGGAAGTGGTAA 21650 ACGGCTTCCGGGTTGGCGGG 15667 Pan02 Lcp2 GAGACCATATTTGTTCACAG 21651 GCCCACCTGAGCCGCAGACT 15668 Pan02 Slc27a3 GGAGCCAGGAGTGCGAGAGT 21652 TGGTGGCCGCCCAGCTGAGC 15669 Pan02 Slc27a3 GGCCACCAGCGGTCAAATTC 21653 GCGCCAGCCCTTTAAGTACG 15670 Pan02 Slc27a3 CTTTGGACCCGACAGGCTGC 21654 TGCAACAGCAGCGAGAACGC 15671 Pan02 9130019022Rik CACGTGGTGCAACCCTGGGC 21655 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Gprl39 CCGCACCTGCCCTCCTAGAT 15672 Pan02 9130019022Rik ACAGGCAGGGTGTCTCACGT 21656 GL261 Gprl39 TACTGGCTGGTGTCCTCGGG 15673 Pan02 9130019022Rik GGGCATGAAGACATTGGTGC 21657 GL261 Gprl39 GGCAGCTCGGTTCTCTGGCA 15674 Pan02 Slcl8a2 TCACGGACAGCGCTGAGAGG 21658 o GL261 Ak7 GGCAGTTAGACAGTTCTCCA 15675 Pan02 Slcl8a2 GAGCCCACCCTATCAGATTC 21659 o GL261 Ak7 TCCTACAGGAGATGTGCCGA 15676 Pan02 Slcl8a2 GGGACGTCTGCAGTGGAGGA 21660 GL261 Ak7 AAAGCAGATGTCACGAGTTT 15677 Pan02 Mafa GCTCTGGTCGCGCCGCCGAA 21661 r GL261 Rfx4 GCTAATGCTATAATAGAAGG 15678 Pan02 Mafa AAGTITCCTGCTGTCAACTC 21662 o 4 GL261 Rfx4 TGAGAAGTAGAAGGCCCAGA 15679 Pan02 Mafa TGAGCCCACCGCGGCCCGGG 21663 6 1 GL261 Rfx4 TTTCGTCTATAATGAGTGCC 15680 Pan02 Pcsk4 AGTGAGGTTCCCGAAGGCTT 21664 GL261 Krt86 ATTAGATGGCTTTATGAGCT 15681 Pan02 Pcsk4 TTCGCGTTGCTATGGTGTCC 21665 GL261 Krt86 GGACCCTGACTGTGACCACG 15682 Pan02 Pcsk4 ACTAGGAGTGACACATTCAT 21666 GL261 Κ 86 CCTCCTTAAATGTGCTAAAT 15683 Pan02 Ranbp3 GGAAGAGGGTGTGGCTAGCG 21667 GL261 Scol GCTCTTTCCTCTTGGCTCGT 15684 Pan02 Ranbp3 AGGCAGCGCCAGTTTGCTAT 21668 GL261 Scol CGCTGTITGCCCTCTGGTTG 15685 Pan02 anbp3 GCTGCCAATGCTAGGAGCTC 21669 GL261 Scol CCGGGTCCGGCGGCTGATAG 15686 Pan02 Slc7al0 GACTGGGATCAGACTTAGAA 21670 GL261 P l TTTCATCCTTTATATGACAC 15687 Pan02 Slc7al0 GTTCCCTTTAAGGGCGGTGG 21671 GL261 Prhl TTGCCCATCAGGATGAGGTA 15688 Pan02 Slc7al0 CCGGGCGGCTGGATCCAGGG 21672 GL261 Prhl AGTTTCTCCCAAGTCTGTGC 15689 Pan02 Smad4 TGGCAGCAACAACACGGCCC 21673 GL261 Papola GAAAGCGTGAGATCACCGGG 15690 Pan02 Sma GGACACTGAGCATGCGCGCG 21674 GL261 Papola ATGTAGTTCTCGGCGTGAAG 15691 Pan02 Smad4 GACCACATCCGGGTAATTTC 21675 GL261 Papola CGCGACGCCGCAAGACCTGA 15692 Pan02 Ζ 579 GGCTGAGAAGCCGGAAGCGG 21676 GL261 Znfxl GCTGGATTCCAGGGCGACTA 15693 Pan02 Zfp579 GAGGCCAGAAGAGGAAAGAC 21677 GL261 Znfxl CTGGACAACCATTAGCTAGC 15694 Pan02 Z¾579 CCAAGCACCGGGTTTCCGGG 21678 GL261 Znfxl AGGTCCTCGGTTATCTGCAC 15695 Pan02 AI837181 CTAACGTTCGTACTTTAGCT 21679 GL261 Ugt2b37 GACTCACTCTCATGTAAACA 15696 Pan02 AI837181 GGGAGGTGCAGGTCTTCGGG 21680 GL261 Ugt2b37 AAAGACCAGAACTAAGGTTT 15697 Pan02 AI837181 CGGAGCCGGCGCGAGAATCC 21681 GL261 Mtgl AAAGAACCTCACATAAGCTC 15698 Pan02 Qcn7 GGTGCCCACGTGACTGACGA 21682 GL261 Mtgl TATCCCAGAGTGCTCGAGTC 15699 Pan02 Clcn7 AGTGAAGACACTAATTGCTA 21683 GL261 Mtgl CCCGGTAGTGCTCCATTCTC 15700 Pan02 Clcn7 GAGGACTAGGCGTGCATCTC 21684 GL261 Acot9 GGCGGGTCCTGCTATTTGAT 15701 Pan02 Fm TGGGAGTATTTAAGAGATGG 21685 GL261 Acot9 AATTTCCCACTCAATCAGCT 15702 Pan02 Fmo2 CTCAGCCAGCTAAACCTCTA 21686 GL261 Acot9 CGGGACTTCTGCGTAGAGAA 15703 Pan02 Fmo2 AACACTGAACACATAGCATT 21687 GL261 Pacsl GGCGCGGAGCCTGCACGCCG 15704 Pan02 Tcirgl AAAGTCTTGGTGTTGAAACT 21688 GL261 Pacsl CCCACCCAGACCGGCGCCGA 15705 Pan02 Tcirgl CTAGACAGCTCAGAGGCATT 21689 GL261 Pacsl GCGGCCCTGGAGTCCCTAGC 15706 Pan02 Tcirgl GCAATGTTGCGGGCAGCCAA 21690 GL261 Ube2u GTTGTCATCTAATCAGCTAC 15707 Pan02 Tecta GCTAGACAGTTGCCTTCTTT 21691 GL261 Ube2u CTCAGCGGGACAAAGCAAAC 15708 Pan02 Tecta TGGATTCAGATGGAAATGTC 21692 GL261 Ube2u GGCCAATGAAGTCAGCATTC 15709 Pan02 Tecta GGTACTTGGAGCTGAAACCT 21693 GL261 Pnisr CTTCGCTCAGCTACTCTTTA 15710 Pan02 L x l GGCGCTGCATTAAGGCGAGG 21694 GL261 Pnisr TCCTTACCTAAACTCCAAGA 15711 Pan02 Lhxl CAGACTGCCGTGACGTCGGC 21695 GL261 Pnisr GAGTAAATGTTCCCACCAGG 15712 Pan02 Lhxl GACCGCGTTTAGAGGATCAG 21696 o i GL261 Rab3gap2 TTGTGGCGGAGAGTTAGACG 15713 Pan02 Gucy2e TTTAATCAAGCAGAACAGGG 21697 90 GL261 Rab3gap2 AGCTTCGGACACGTGACTCG 15714 Pan02 Gucy2e ACAGGGAGAGAAAGCGAATC 21698 GL261 Rab3gap2 AGTGCTGACAGCTTCCGGTC 15715 Pan02 Gucy2e GAGGGATTAAGGGCTGCAGC 21699 GL261 Elp2 ATGCCGGAGTATCCGCGGCT 15716 Pan02 Bpifa2 ATAGGGCTTGATTCTCATCC 21700 90 6/1 GL261 Elp2 GGTAGAGTAGTTCCGCTCTG 15717 Pan02 Bpifa2 GGAGTATCTTTAGAACATCC 21701 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Elp2 AGAACCACGCCAGCAGACGG 15718 Pan02 Bpifa2 GCACGATCTCCTGGGATTCT 21702 GL261 Tc l 5 TTGAACTCAAGGCCACTGGG 15719 Pan02 GdflO GGGTGTGCGCTCCCGAGTGT 21703 GL261 Tcfl5 CTGCGCAATCCCGCCCACAA 15720 Pan02 GdflO GACGCACGCACAGCACACCG 21704 GL261 Tc l5 GGGAAACCGCTGAGCACCTC 15721 Pan02 GdflO GAGGTGGCCGATAGCGCCCT 21705 GL261 Dmd TCCATGGGCAGTCCTATTAT 15722 Pan02 Fosb ACCTGCCCATAGTGTGACCC 21706 GL261 Dmd GGAAAGCAACTTGAGAGAAA 15723 Pan02 Fosb AGGAGCTCAGTCGGCGGGAA 21707 GL261 Dmd ACTTGCITGTGCGCAGGTCC 15724 Pan02 Fosb TGCGGGTGACGCAAGCGCGG 21708 GL261 Ccdcl57 CCGCCATCTTGTCATTGAGT 15725 Pan02 Neb AGGCATGTCTCCACCAAATA 21709 GL261 Ccdcl57 CTTTAATCTTGTCGTCGCAC 15726 Pan02 Neb CGCAGCTCTCATGATGGTCG 21710 GL261 Ccdcl57 TCCACCTCGGTGGCGACAAC 15727 Pan02 Neb GCAGGCCATGTCAACTCACC 2171 1 GL261 Neurl4 TCAGTGCCGTAAAGCACACC 15728 Pan02 Gm382 TCTATGACAACTGAATTGTG 21712 GL261 Neurl4 ATGGCAGAATCGCCCGCCGC 15729 Pan02 Gm382 TACTATCCTCATTCTGACAC 21713 GL261 Neurl4 CGTCCGCAGCTAAGGAACCG 15730 Pan02 H1204 CAGTTGGGTGTAAAGGAAGA 21714 GL261 R bdd3 ACCATCGGGCCAGGCCTCGG 15731 Pan02 Ifi204 TGAGAAGTGCTGAATCAGCC 21715 GL261 Rhbdd3 ACACGCCTACTTCTCCCACA 15732 Pan02 ffi204 TTTCATTTCTTGAACAGCAC 21716 GL261 Rhbdd3 AAGCCACGCCCATCCTCAGA 15733 Pan02 Xpo4 GACAAGCGTGAGCCCGGTCG 21717 GL261 Nrlh2 TGTGAGGCCTCGGCCGGAAG 15734 Pan02 Xpo4 CGGTCCCGTCAGGCCGCTGG 21718 GL261 Nrlh2 TCGGTGGCGCCCTGGCAGAC 15735 Pan02 Xpo4 ACGCGCCATGCGCTGCATTC 21719 GL261 Nrlh2 CACCGGAAGTTTATTTCTTC 15736 Pan02 Ces2c AACTTTCACCCGTCACACAA 21720 GL261 Snai3 GGAACCCGCCGCGTGGTCGG 15737 Pan02 Ces2c TTTAAATAGCTGCCTGTGCA 21721 GL261 Snai3 ACCACCTCAGCCAACCAGCG 15738 Pan02 C s2 AGTAATTAGTCACAAGTGAT 21722 GL261 Snai3 CGGGCCAGCGGAGTCCCGTG 15739 Pan02 Fbfl ACGGTGGCGTGGAGGATTCT 21723 GL261 Sytll ACAGTCGGGCCCAACCACAG 15740 Pan02 Fbfl GCCGAACCACAGGACTTGAC 21724 GL261 Sytll GGAGGAGGAGACACCTCAGC 15741 Pan02 Fbfl GTCCGTCGCCCGTTCACTAG 21725 GL261 Sytll GGTTCTCTAACAGCTGTTGT 15742 Pan02 Hephll ATTTATAACTCGCTCTGAGG 21726 GL261 Dpysl3 CGCCAGAGCCTTCGCGCCAG 15743 Pan02 Hepbll CTCCGGTAGGCAGCCTGAAA 21727 GL261 Dpysl3 CGAGGAGTTACAGCTGGAGC 15744 Pan02 Hepbll TGCAAGCAGACCTCCCTCAA 21728 GL261 Dpysl3 CGAGGAGCAGGCTGACTCCG 15745 Pan02 Rars CGGAAACGGAAATTCCTACC 21729 GL261 Magea5 GCTATTGATATTGAGGTCTC 15746 Pan02 Rars GTCTCCTGGATCCCGTTAGG 21730 GL261 Magea5 AAGGTTCAGCCCTCTATATC 15747 Pan02 Rars AAAGCAACCTACCCTCTGCT 2173 1 GL261 Magea5 TGTGGITCCTTGATATTAAA 15748 Pan02 [ffo2 CTTCCCGGCCCGCCCTCTAT 21732 GL261 Edar TGCCTGGCGCGGCCTCTAGG 15749 Pan02 [ffo2 GCTCGCAGAGGACTCTCAGC 21733 GL261 Edar CGAGTTTACAAACAGTCGAG 15750 Pan02 [ffo2 GCAGAGAGCAGCTAGGCAGG 21734 GL261 Edar GCTCTGCCGCTGAGTGCACC 15751 Pan02 Gmnc CACTTGTTATCCTGTGACCA 21735 GL261 Tipin GGCGCCAAGGGTAGGCGAAG 15752 Pan02 Gmnc GTTAACTCAAGAGTCCGGTG 21736 GL261 Tipin GCCTACCCATCCGGAATGTC 15753 Pan02 Gmnc ACAGAGTGCCGCTCAAACTA 21737 GL261 Tipin GCGAGACAAGCTGAGAAATT 15754 Pan02 L cam GGCCAGGTTCAGATGAAACA 21738 GL261 Slc22al8 GGAGGACCCAAGCTATTGTG 15755 Pan02 L cam CGAGGTCCCTATCACGCGCG 21739 GL261 Slc22al8 GAACAGGGAACCCTAGAACC 15756 Pan02 L cam AACGAGGGTGTGGCGAGGCG 21740 GL261 Slc22al8 AGAACTAGCCCTGGTGAAGT 15757 Pan02 Dkkl TTCAAAGCTTTGGGAGGAGC 21741 GL261 Naip2 TGAATGTGAAATACCCACAC 15758 Pan02 Dkkl AGTGTITGTGTGTCGGAAGC 21742 GL261 Naip2 CTGTGTCTGGGCCTACACTG 15759 Pan02 Dkkl GGAAGACAACAAAGCCGGGA 21743 GL261 Naip2 CAGCTCATGGTTTGAGAATT 15760 Pan02 Rbm28 CAGACTGGAAGGAATAGTTC 21744 GL261 Tcn2 GAGACTTGTTTGTCTGGGCC 15761 Pan02 Rbm28 GGGCGGAGCTTCTTGAACGA 21745 GL261 Tcn2 AAGGAAACCCAGGCTGTGTC 15762 Pan02 Rbm28 GTCCGGGAGGAAACGCAGAC 21746 GL261 Tcn2 TAAGCGACGTTCCTAGTTCA 15763 Pan02 Slcolcl AAACAAAGCTTTATCACGTG 21747 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 TCAGCCCGCACCCGCTCCCT 15764 Pan02 Slcolcl GGGTGAGGAAACAGAAGCCA 21748 GL261 CAGCTGGCTGAGGCACTTGG 15765 Pan02 Slcolcl ACTAACTTCCTTCCCTGCCC 21749 GL261 GTGCGCCCTGTGCTCAGGCG 15766 Pan02 Zan GCTGTTGAGAGTCACATGAA 21750 GL261 TCCGAAGTCCTGCTGGTCGC 15767 Pan02 Zan GTAGCAACCATAGGTTCTAA 21751 GL261 ACTGGAGCTACAAGTGGGTA 15768 Pan02 Zan CATTCTACAACTGAAGACAG 21752 GL261 TCACCATGCCACGCTACCGC 15769 Pan02 Kiflc CGAGCGGGCACGCGCTGTCC 21753 GL261 CCAGACACATTGATGTAGGG 15770 Pan02 Kiflc GGGCTCGCCGGGCAGAGACA 21754 GL261 TTGGGACATGGATTGGACAA 15771 Pan02 Kiflc GGGCAGTGCACTCTGACAGT 21755 GL261 AGTCAAAGGTCGGTAAATAG 15772 Pan02 Tceal5 TCTGCTCCTGATCACGTGAC 21756 GL261 CTGCGGGTGGGCGATGCCAC 15773 Pan02 Tceal5 GGAACGTCACCAGTGGGCTC 21757 GL261 CGGAGCAGAGGCTCAAACCT 15774 Pan02 Tceal5 CACTTTCTTGTGCTTGGGAG 21758 GL261 TAGGGCGTCGCTGTCACTCC 15775 Pan02 Arbgap28 AATCTGCCGCTGTACTCTGT 21759 GL261 TCAGGTCAAGCCCGGTTCTC 15776 Pan02 Ar gap CCAAGGCTCTGCGACTAGGA 21760 GL261 GCTCGCTGTGCGTCAGAGCG 15777 Pan02 Arhgap28 TGGCTCTTAGTTATGCTAAT 21761 GL261 TCCAACGCGCCATCAGCTGG 15778 Pan02 Slc6a7 TACGGTCTTCTGTGTGACCT 21762 GL261 ACTGCAGTTGCACAGGAGAG 15779 Pan02 Slc6a7 GGGCAAGTGACTGCTATCTC 21763 GL261 ACGCCTACCTGACTTCTCGC 15780 Pan02 Slc6a7 GGGTGCGTGACAGAAACCAT 21764 GL261 CTGCCAGCTTCTCCAGGTTT 15781 Pan02 Pil5 CTAAGAGAGCCTGCCCTTTC 21765 GL261 GCAAGAAGCACTAATTATGG 15782 Pan02 Pil5 TCAGTTTGCAAAGTCCAGAA 21766 GL261 GAGGAGGAGCTTCGGCTCAG 15783 Pan02 Pil5 AAACAACCAACAACAGAGAT 21767 GL261 AATACTCCAGGGCAGCCGTG 15784 Pan02 Noval GAGCAGCTGCAGTGCAGTGT 21768 GL261 CTAGTTCTTAGGCAGATGGA 15785 Pan02 Noval AGTGTGGCTGATGTGCTCAC 21769 GL261 TACTATGGAAATCAGAGTAC 15786 Pan02 Noval ATCGGATCAATAGCAGTCTG 21770 c GL261 GCCCTCAGCTTCGGCTGCCC 15787 Pan02 X 2 GGAGGAAGTGCTGGTGCCCG 21771 GL261 AATGATCCTTTACTGTACGT 15788 Pan02 X 2 TGGAAGTTCATTTAGACTGC 21772 GL261 ATCTAGAGCTTATCCATGTA 15789 Pan02 X 2 GTTACGTCATACCACCACCG 21773 GL261 CACAAGGTAGTGTTGACAGA 15790 Pan02 Fus GAAAGCGCGTGCGAGTGTTT 21774 GL261 ACTCGCCTCCAAACCTGGAC 15791 Pan02 Fus GGCGTACTTAAGGCGGGCGC 21775 GL261 GAGnTCATTCAGCCTTTGC 15792 Pan02 Fus GTACCAAGTGGAGAAGCGCG 21776 GL261 GGAGCTGGCTATCACCTAAC 15793 Pan02 Plpp4 AGGCTGGTGTCTGGGTGTCC 21777 GL261 GCTGGAGGCGGGACGACGAC 15794 Pan02 Plpp4 TCTCCGGAGCCTGGGCGGTG 21778 GL261 GGTTCGCTCTGTTTAAGTCT 15795 Pan02 Plpp4 CTCCCACGGCTCGGCCGGAG 21779 GL261 CCCAGTTATGGGTGGAGCTA 15796 Pan02 Jmjdlc CCGGGTCGTCGAGCGTGCAG 21780 GL261 GAGAGCTGCAGCCGGCTGTG 15797 Pan02 Jmjdlc CCTCGGCATGGGCGGCCGGT 21781 GL261 GGTTCATAAATGTCTCACCT 15798 Pan02 Imjdlc GAGAACGAGTACTTGGCTTA 21782 GL261 CAGTCATGCCAGAGTGACAG 15799 Pan02 Ttl CCCGCCACTCAGTGTGTGGC 21783 GL261 ACGTTGTTAACCAAATCAAA 15800 Pan02 Ttl CGGAATCACGGTCGTGGGCG 21784 GL261 TAACTTATCCCATTTCAAAC 15801 Pan02 Ttl GCTGCAGTAATAGCAAACTG 21785 GL261 ATGTCTTTAGAAATACTGCA 15802 Pan02 Clasp1 CAGCGCTTGTACGCATATTC 21786 GL261 TGAGGGTTTGCACCAATCCG 15803 Pan02 Clasp1 GAAGTCGCCCGGTAAATAGC 21787 GL261 ACATTTGCCGGGCAGGCAGG 15804 Pan02 Clasp1 TCAGCTACGGGAAGTCGCGG 21788 GL261 TGCGTTGGTTTGGCGGGTTG 15805 Pan02 Tniem30c CTATCTGTTCAGGTCTTTAA 21789 GL261 GAGGCGTGGTTATATATTGG 15806 Pan02 Tniem30c GAACCGCACTCACATTATGA 21790 GL261 AGGAGGCGTGGCTTTACTCG 15807 Pan02 Tmem30c TTCCGTTAGAATTCTGTTAC 21791 GL261 GACCAGGAGTCGAGTAGGCG 15808 Pan02 Dnah9 GGAAGCTCTCACATCCAAGC 21792 GL261 TTCTAGAAATCGTCAATATC 15809 Pan02 Dnah9 AGACGTGCTCTGAAGACTAC 21793 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

TCCAAGTACAAGCCCTGCTG 15810 Pan02 i il ' CCTACCTTATTAACTTAGTG 21794 GGCTTGGATTACCCACTGTT 15811 Pan02 Snx32 TTTAAGCGGCACCAGAAAGC 21795 TTAGGTAGGCGGCATTCGTG 15812 Pan02 Snx32 TGAGGCCTATCAATCTTACG 21796 GAGGCCAGTCAGCGCCATTT 15813 Pan02 Snx32 TTTACCACATGAGCCTCTAT 21797 GAGCTTCCCATGATCCTCAC 15814 Pan02 Naip2 TGAATGTGAAATACCCACAC 21798 TTCAGGAGCTACGCCAACAC 15815 Pan02 Naip2 CTGTGTCTGGGCCTACACTG 21799 GATGGCGGAAGTGAATACGA 15816 Pan02 Naip2 CAGCTCATGGTTTGAGAATT 21800 TCACTAAGCTCCCGTGGCTT 15817 Pan02 Acssl CTCAAGGAAGCTGCTTCTCC 21801 TCATCCTGCTAATTAACATA 15818 Pan02 Acssl GAAACTGAAGCCGAGAGCGC 21802 TTCCAGCAAAGCATTATCCA 15819 Pan02 Acssl TTTGTTGTGCGCCCAGTCCG 21803 AAGGACCGCCAGGCGCCCTG 15820 Pan02 Abcbla TGTAGATGAAATGTGCAGTC 21804 GGAGTATGGGTTAACTAATG 15821 Pan02 Abcbla TGCTGGAGAAATTGCGAAAC 21805 AGATGGACCCGGTGGAGCGC 15822 Pan02 Abcbla TACTTGAGTCAAGCTGGGCC 21806 GGAGCATGCGTATTAGCCGA 15823 Pan02 Faml74a CGCTCTGAGAGGTCCCAACT 21807 ATTGTCACAGGTATGCCAGC 15824 Pan02 Faml74a CTATTGCGCACGCGTAGCTG 21808 TGAACTGGCCCTCCTGGGAA 15825 Pan02 Faml74a CCTCCGGTTGCTAATATGTA 21809 GAACTGTTTAAAGACAAGCG 15826 Pan02 Kif7 GTAGTACAGGCCAGTGGCAA 21810 GTTCCTTCCCACCCATCGGC 15827 Pan02 Kif7 AGTTCAGAGCATCTGCCCAA 2181 1 TCTGGCCCTAGATATAGCAG 15828 Pan02 Kif7 GGGCCAGACCACATAGCTTT 21812 CAGGGATGTGTTTACTAAGC 15829 Pan02 Rnfl69 GGGCGGGAACCTAGTCCGCC 21813 TTGTCGCCGTCAGGCACAGC 15830 Pan02 Rnfl69 CCTAGGGCCTTTCGCTTAGC 21814 GCAGGGCGACCGCCCATCCG 15831 Pan02 Rnfl69 CAGCTATCTGCATATTCATG 21815 TGACGCGAGCGGGCTTCCGG 15832 Pan02 Spagl7 TGCCAAACTCCAGAAATACC 21816 GCAGATTTAATCCGAATGCA 15833 Pan02 Spagl7 GGGTCCGGAACCGGTTTGGG 21817 GCACACAACACATTCAGTTT 15834 Pan02 Spagl7 AGTAAGCCAGCTCGACCCGC 21818 CCACCTACGGGCGGAGAGAA 15835 Pan02 Rtrfl7 GCCTCCTGATTGGCTACCTA 21819 TGTTCAGCCTCTAAGTGATA 15836 Pan02 Rnfl7 TTCTTGACGCGAGGGCTGCT 21820 CTGTAGTATCCTCTAAGATT 15837 Pan02 Rnfl7 GGTCGCCGGAGTCCTGTGAT 21821 GGTTTGGTATGTTCTAAATT 15838 Pan02 SMsa6 AGCGGCGGCGTGGTCCCGTC 21822 GCCGGCGAGGGCGGGTAGCC 15839 Pan02 Shisa6 CCGCGCGACTCGGCTCAGGC 21823 GAGGAAGAAGAGGGTAGGTG 15840 Pan02 Shisa6 CCTCCGGGAGCCGCGCTTCG 21824 GTCACTGGAAGGAGGTGCCG 15841 Pan02 Scn9a TTCCGAGAAGCCACTTTATG 21825 GGAAGGCCACAGTCTTTATA 15842 Pan02 Scn9a TTAGCACTGAACTGGAGGGA 21826 CCAGCCTCCACTTGAAGTCC 15843 Pan02 Scn9a AAGGCAGAGAAGAATGACAA 21827 GGGAACAATGGAGCCCTTGA 15844 Pan02 Grhl3 GGAAGGAACGGGAGAACTAG 21828 AAATTTGCGATCTTTACAGA 15845 Pan02 Grhl3 AAAGGGAGGAGACAAACGTT 21829 GTTGGGCTCATTTCTGTAGA 15846 Pan02 Grhl3 GGCCAATTCCTTCTTAGCTG 21830 CCTTGAGAATCGTCTATAAA 15847 Pan02 Co126a 1 GCCGGTGATGGCGTGAAGTC 2183 1 CTTGCTGAGGCTGGCAAGCC 15848 Pan02 Co126a 1 GTCGGAGGTGGAAGTCGTCT 21832 AGAGTGGGTGGTGTTATAAA 15849 Pan02 Co126a 1 CCCTCAGCGGTCCAGGACTG 21833 CCTCAGTTCCACCTTTCACT 15850 Pan02 Renl GAAITATGGAGCTGGGTCCT 21834 CAATTCITGGCTTCAAGCCA 15851 Pan02 Renl TTATACACACCATGTATCAC 21835 CTATTGGAAGCATTAGTAAA 15852 Pan02 Pcolce TATATGTCCAAGACCTAGAG 21836 GAGAGATTGAACTAACACCT 15853 Pan02 Pcolce GATGTGTTCCCAGCATTCTC 21837 GGAGATTTGCTTGTGGAGAA 15854 Pan02 Pcolce CAGTGCTTGAGTCCCTTCAG 21838 CAATTCTCTGAGCCAGCCAT 15855 Pan02 Iraki GGGAAGGAGCTCTGCTACGT 21839 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Kpna7 TGCTGTGGCTTCTACGTCAC 15856 Pan02 Iraki AGTCCCTAATGGGAGAACCG 21840 GL261 Kpna7 CTGTAGGCCCAGCATGTGAA 15857 Pan02 Iraki ACTTCCAGTTCTAGAGACAA 21841 GL261 BC048562 TGACTGCACAATGCTGCTGT 15858 Pan02 S 2 GTTCGCGGACGCCGGGCACT 21842 GL261 BC048562 AGTCAATCATGACAGGAGCT 15859 Pan02 Sbf2 TAAGCGCCCGGCCTCGGTGG 21843 o GL261 BC048562 AGCTCTGCACGTTTGTACAA 15860 Pan02 Sbf2 TCGTCGAGCCCTTTCGGGTG 21844 80 GL261 Cog2 GCAGCCTCACGCATGCACCG 15861 Pan02 Ccdc88b CCGGAAGAAGGAAGCTGTAC 21845 r GL261 Cog2 CGCACTGTTGGTGATAAGAG 15862 Pan02 Ccdc88b ACAAAGCTGTAAGTTAGCTG 21846 o 4 GL261 Cog2 CAATAGACGAGCGTCGCGGG 15863 Pan02 Ccdc88b TCTTACCTTATCTGAGACCC 21847 6 1 GL261 Prr TACTCCTTCAAAGCTAAATG 15864 Pan02 Dgke TTGTAGGCGGGACCAGGTGT 21848 GL261 P r 2 TAGTGAAGTCATCAGTTGCT 15865 Pan02 Dgke CGGTGCITTCCGATGGTGGG 21849 GL261 P r 2 GAGTGAGGAAGGCAGACAAC 15866 Pan02 Dgke GGCCTGACGCGCCCACAACT 21850 GL261 Nlip3 GCTTTCTCAGTGTCTGAAGG 15867 Pan02 Zfp940 CTGGCAAGGTGAGGACTAGC 21851 GL261 Nlrp3 GTCCTCACCTTGGTGCTCTG 15868 Pan02 Zfp940 TAAGAGTCGCATGGACTCCT 21852 GL261 Nlrp3 CTGAGGTTGAGAAACAGTGA 15869 Pan02 Zfp940 ACGCGGTAGCCAACCTAGAC 21853 GL261 Vsxl AGAGAGACCCATTACGAATG 15870 Pan02 Tldcl CCGAGTCAGATCTTAACCAA 21854 GL261 Vsxl CTGGGAGGCCAACAACTCAG 15871 Pan02 Tldcl AGGCTCAGTTCTTCGATCCC 21855 GL261 Vsxl TTGTGGGTTTCATAGGAGAG 15872 Pan02 Tldcl GGACGGTCATGAGCACCAAT 21856 GL261 Cyp2c68 CTGTTTAACTCTCTTCCAAT 15873 Pan02 Lrrc66 TAAGGTGGGCGGAGTCTCAA 21857 GL261 Cyp2c68 TAGCGTGCCTGTAAGACATG 15874 Pan02 Lrrc66 AAAGGGTGTGGACTCAGTAA 21858 GL261 Cyp2c68 TTGTTGAGTTGTGACAAGTA 15875 Pan02 Lrrc66 TGTCTCCAGCTGATCCAGCC 21859 GL261 Sowahb CCGCGCGCAACCCTGGTGGC 15876 Pan02 Nfat5 GCCACGGAACAGCATCAACA 21860 GL261 Sowahb GACAGGCCAGCGTCGTTCAG 15877 Pan02 Nfat5 GGCCGCTGCTGATCCCGGGC 21861 GL261 Sowahb AGTCGGTTTCACCTGCGCTC 15878 Pan02 Nfat5 TCCGGGAGCCCGGAAGAGCC 21862 o GL261 Nsun4 CCCACCCACCAGAATCCTCG 15879 Pan02 Psg28 ACAGGGACATGTAGGAAAGA 21863 GL261 Nsun4 GCTCTAATTTCGTTCTACCT 15880 Pan02 Ly6cl TAAACATGATGGCCTGGAAA 21864 GL261 Nsun4 GGCTGTGCTAGAGCATCTAA 15881 Pan02 Ly6cl GTGGCAAGTTCTGTCAGATG 21865 GL261 Gramd2 CCTAAAGCTCGGTTAATGCC 15882 Pan02 Ly6cl TGCCTGCAACCTTGTCTGAG 21866 GL261 Gramd2 TAGTTGACTAGAAGGTTGAC 15883 Pan02 Slcl5a5 ACTCACATAAGTGATAGTCT 21867 GL261 Gramd2 ATTTGCATATCATCACTGAT 15884 Pan02 SIcl 5a5 ATGCTCAGGTCTTCTCTCTT 21868 GL261 Ttll6 CCAAGCGCGCATTTGGAGCG 15885 Pan02 SIcl5a5 AAGCTCAAGAAATTCTAGCA 21869 GL261 Ttll6 CAGAGCGATCAGCAGTTGTG 15886 Pan02 Intsl GCATAAACTGTTCCCTCTTA 21870 GL261 Ttll6 TAAACTACAACCAGTTGTTT 15887 Pan02 Intsl GTGAGAAATCAGCGCTCGGA 21871 GL261 Aqp9 CAAACAAATAGCAATGAGCT 15888 Pan02 Intsl AGGGCGGTGCAAACACTAGT 21872 GL261 Aqp9 TACCTTTATTCTCTGTTCTC 15889 Pan02 Hps5 GGTGCGTCGTCGGCCCGAGG 21873 GL261 Aqp9 GTTGATAGGAGTGGAGAAGG 15890 Pan02 Hps5 CGGAGGAGGAGAAGCGAAAC 21874 GL261 Trp73 GGACAGTAAGGGCAGCGAGG 15891 Pan02 Hps5 TCGAGCGGCGGAGAGTTTCG 21875 GL261 Trp73 CAGAGGGAGTACAGGGCGTC 15892 Pan02 Trappc9 CCTGTGTAAGCATGGGACTC 21876 GL261 Trp73 GGGCGCCAGGAAGGGTGCGC 15893 Pan02 Trappc9 TACATGTAGTGTGTAGCTCT 21877 GL261 MovlOll GTTCTATGACAGGCAGGCGC 15894 Pan02 Trappc CATGCTCACCCAATGCTAAG 21878 GL261 MovlOll CGCTGGTAGAAACCAGCCAA 15895 Pan02 Rabgapl CTCAGCTAACACAGCGACTG 21879 v > GL261 MovlOll TGCGTGCTGGCCCATGGGCG 15896 Pan02 Rabgapl GCCGGACAAAGACAACTTCC 21880 o GL261 Csmd2 GAATGAACCAAGTGTCCGCC 15897 Pan02 Rabgapl AGAGGGACTTTCCGCGTTGT 21881 80 GL261 Csmd2 TCGCCCGCCGCCGAGGAGAA 15898 Pan02 Zfp553 GTCGGCCCACGACCGGGACG 21882 GL261 Csmd2 GCTCAGGGCTCCCGCGTACC 15899 Pan02 Zfp553 GGAGCCCGTACCCGTGCGGC 21883 GL261 Eya3 GGTCCCGCATCTACTTCCGG 15900 Pan02 Zfp553 TGGGITCCTGTTGTACCGAG 21884 80 6/1 GL261 Eya3 CATCTCGTGCGTAAGATCCA 15901 Pan02 Adam25 CCTAGCAACAAGAGACTCTC 21885 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Eya3 CCCGTTCCGACAGAACCCAG 15902 Pan02 Adam25 GGATTCAATAGAAAGCTAAG 21886 GL261 Set ACGTGCCTTCAGCAGTGACA 15903 Pan02 Adam25 CAGAACAGTGCAACTAGCTA 21887 GL261 S t GACCCTAGACACCCGCATAG 15904 Pan02 Actr8 AGATGTAGCTCATTGGTAAT 21888 o GL261 Set CCTCCAGAGAAAGTACTTTC 15905 Pan02 Actr8 CTCACTATTCAATGGTGCCT 21889 GL261 Katnbl GCGGAAGCGCTTGCTTCCAT 15906 Pan02 Actr8 GCATGACAGGGTTGGAGTTT 21890 80 GL261 Katnbl GTCAATTCTAGAGGAAGGCG 15907 Pan02 Otopl AGGGTGTACTGGAGGAGAGC 21891 r GL261 Katnbl AGCGCTTACGGACCGCCCTT 15908 Pan02 Otopl TCTGAGGGCACTGGCAAGCC 21892 o 4 GL261 D7Ertd443e CGTAGCTTCTGCTATGTGGC 15909 Pan02 Otopl GGAGCCAGGAGCAACGTGCG 21893 6 1 GL261 D7Ertd443e GGGAACAGTTAGACATGAAA 15910 Pan02 Mtus2 CTGGATGCTCCGGACCACTG 21894 GL261 D7Ertd443e ACTTGTGCTAAGAACTTTCC 15911 Pan02 Mtus2 CGACACGACCCGGCAGCTCA 21895 GL261 Krtap4-1 GGTGTTCAGCGAGGTATAAA 15912 Pan02 Mtus2 GAGTCTAGGTCAGCGACCTC 21896 GL261 Krtap4-1 TTGCAAACACAGGAGCCATC 15913 Pan02 Hn pu GGGCCGGACCGCGCAAATGG 21897 GL261 Cux2 TAAGACAATGGCTGTGTGTC 15914 Pan02 Hnmpu GTTAAACGGACCCGCCGCAG 21898 GL261 Cu 2 TGCATAGTTCCAGAGCTCAG 15915 Pan02 Hnmpu CGGCGCCGCGCACGTAATAT 21899 GL261 Cux2 TGAATCGATATAAAGAGGAG 15916 Pan02 X r l CCATTCAACCCAAGTCTGCC 21900 GL261 Gm7534 AGACGGACTTAAGCGACAGC 15917 Pan02 Xirpl GCTATGTTCGGAGTATTAAG 21901 GL261 Gm75 CTGTGGCTTGCTCGTCATTG 15918 Pan02 Xiipl GGAATCAGTTACAATTCCTC 21902 GL261 Gm7534 GCATCTGTGTGACTGTGTTG 15919 Pan02 Ubrl CAGGGCTAACTAACCATCAG 21903 GL261 Helz2 GAGGCTATCACTTGAGGGCG 15920 Pan02 Ubrl CCTGCTTCCGGGAAGCCGAC 21904 GL261 Helz2 GGGAAATCTTCCTAGGGCCA 15921 Pan02 Ubrl AGCTGTGAGGTCTTCCCTCG 21905 GL261 Helz2 CCTGCTGTGTTGACCTCAAG 15922 Pan02 Gfil CAGTTCAGCAAACCTACCTT 21906 GL261 Trip 10 AATCGAGGCGTACTTTGAGG 15923 Pan02 Gfil TGTGCCTCCCGCTCAGGCGG 21907 GL261 Trip 10 AGGCGTGGAAAGGCACGAAG 15924 Pan02 Gfil GGACTATGTGCTGCAGTGGC 21908 GL261 Trip 10 GCGCATGGCCCTTTAATGGG 15925 Pan02 Ano3 GGGTTTGGTGCACGTGGGAG 21909 GL261 Lrifl TCTACTTATGCGTGTTTCCC 15926 Pan02 Ano3 CAGCCTTCAGAGCTAAGTGC 21910 GL261 Lrifl TTCAGTTGTGACATCACGCC 15927 Pan02 Ano3 GCTATGACGATGAGACTGGC 2191 1 GL261 Lrifl AAGGTTGAGGTCTCTTCTTC 15928 Pan02 Fam46c AGGCCGGTTAAGATCGGAGG 21912 GL261 Mysml GCCTTGGCGTGGCGCACTTC 15929 Pan02 Fam46c CCGAGGAGCCAATCAGAGGG 21913 GL261 Mysml TCTTACTCGCCGGAGTTCCC 15930 Pan02 Fam46c ATCAGAGGGCGGCGTTCGTC 21914 GL261 Mysml GCAGCTTTCACGCAGTCTCC 15931 Pan02 Cyp7bl CAGGGTTCCTGTCACCGGAG 21915 GL261 Ttc41 GGCCCGCGGAGCCATCTGAT 15932 Pan02 Cyp7bl CAAGGAAGAGGGAAAGGATT 21916 GL261 Ttc41 AGTTCTTCAGCCAAAGCTTG 15933 Pan02 Cyp7bl GGCGGAACGCTTGGGTCAGG 21917 GL261 Ttc41 GACAGTGGGCTGGGACTCTG 15934 Pan02 Mtcll GCGTGGACGCGTGGGCACTC 21918 GL261 Orel CGTACTTCCGCCAATTTGCT 15935 Pan02 Mtcll AGAGGACCACTCTTTGCCTT 21919 GL261 Orel GTGGCGTAGAACTCTTTCGC 15936 Pan02 Mtcll CCCGCCTCCTGCTAGCGGGA 21920 GL261 Orel TCAGAATCACACTGTGGGCG 15937 Pan02 Rhbdfi TGAGGTAACTGTGTGTTGAT 21921 GL261 1700001J03Rik TAGATAGAGCATATGAGGAG 15938 Pan02 bdf2 TTGGTGTGTGGGCGGTGCTT 21922 GL261 1700001J03Rik TAGGCCCTATCTGACTTTCA 15939 Pan02 Rhbdf2 TCTCCAGGGCTAGGGCGGCA 21923 GL261 1700001J03Rik TACTTGCTTAACATTCCAGA 15940 Pan02 Ccdcl4 GAGTCTGTTGCGCACGCCCA 21924 GL261 Tln2 AAGCAATGTATTAGTTAGCC 15941 Pan02 Ccdcl4 GCGTGGCAAGCTGGAGCACG 21925 v > GL261 Tl 2 AAGGTGTGTGCTGCCATGCC 15942 Pan02 Ccdcl4 CTTTGCAGCATTCTTCAAAC 21926 o GL261 Tl 2 GGCAGGCAGATCTAAGTGTG 15943 Pan02 IfU22 CTCCTGCGTCCCTACGCGCC 21927 80 GL261 Kdelc2 TGACTAGGAGCGTAAGGCCT 15944 Pan02 IfU22 GTAAGTATGACACGAGCGAT 21928 GL261 Kdelc2 AAACTCAGGCAACTAGTGTA 15945 Pan02 IfU22 TTGACGACAGAGGGTTTGAT 21929 GL261 Kdelc2 CGCGGTACACGAGCCAGTCG 15946 Pan02 Stmn2 GCCGATCAATATTTAATGCT 21930 80 6/1 GL261 T pm2 CTCCTGAGATGCTCCACTTG 15947 Pan02 Stmn2 GCTCAAGCAGATTGGCTCTC 2193 1 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 T pm2 GTTGCGGCTGCCAAGCAATC 15948 Pan02 Stmn2 CTCTGCGGGAGTCATGTCAG 21932 GL261 Trpm2 CCTCTTCGGGACACCTAGAA 15949 Pan02 Armc2 GTGGCTAGAGGGATTGGCGC 21933 GL261 Syl2 CGGGAGGGACGACAAGGATG 15950 Pan02 Armc2 CGCGTAGCAGCGTCGAGGCG 21934 o GL261 Syi2 TCAACAACGCTGAGCACTTC 15951 Pan02 Armc2 GGGCAGGAGCATACCCACAG 21935 to o GL261 Syi2 CATCGGGAAGGCTTGAGTCT 15952 Pan02 Ltbp4 GCGCITAGCCAGAGGCGCGA 21936 GL261 Plod3 Pan02 GGTTAGTACGCGTGCGCAGT 15953 Ltbp4 CTTTCTCCACCGTGCAAGCC 21937 to GL261 Plod3 CATCACGTAATGACTTCAAG 15954 Pan02 Ltbp4 GGGCTAGATGGACAGGTGCC 21938 4 GL261 Plod3 TGTCAACTGTGTTGCGCCAA 15955 Pan02 K1M7 ATCATCACGAAATCTAAACC 21939 6 1 GL261 Egflam CCCGCGGGTGACCTAGATTG 15956 Pan02 K1H7 CTACCAAAGGCCGACTTCCC 21940 W GL261 Egflam AGGATCCAGCCGAGGACCCT 15957 Pan02 K 7 CCACGCGACGCCCTAGCAAC 21941 GL261 Egflam TGTCGAAGTCGGTCCCACCC 15958 Pan02 Tnrcl8 AAGTGTGAGGCGGCTGCGGG 21942 GL261 Pabpcll AGGGTGCAGGTTCAAACATC 15959 Pan02 T l GAGCTCGGCGGGAGGAAAGC 21943 GL261 Pabpcll TGGAGTCCTTTAGAAGAGGC 15960 Pan02 Tmcl8 TTCTTTAAACCGGCGCTACC 21944 GL261 Pabpcll GCAGCCAAAGCAGATCGTGA 15961 Pan02 Zfp TCAGTGCAATCTGTCACTGT 21945 GL261 Dnahl TAAAGAACCAGACCTCTTGG 15962 Pan02 Zfp TGCCAAACTCCTCAGGTCTG 21946 GL261 Dnahl CGCCCACCTACAGACCGGAC 15963 Pan02 Zfp938 TGGACCGAGCAGTTAGAATG 21947 GL261 Dnahl GGCGGGACCATTCGGCACCG 15964 Pan02 Spaml AGAGCAAATTCCAAGATTCT 21948 GL261 Lama5 GACCTTAACCCTTCCGACCC 15965 Pan02 Spaml AGTTGAAGGAAGAGGGAAAG 21949 GL261 Lama5 CCCGCCTGTCCGAGGACGTC 15966 Pan02 Spaml TCATAGGAAAGAAGTGAATC 21950 GL261 Lama5 CGAGCCTTATGCCCTGGAGA 15967 Pan02 Cantl CTACTCCATCCACACCAGCG 21951 GL261 Ttil CGCCAAAGTCTCTAGGGATG 15968 Pan02 Cantl TTCGCTTGAGCTTGTAATTG 21952 GL261 Ttil AGAGAAGCTTCTGAGTAAAC 15969 Pan02 Cantl ACGACAGACAACTCCTTTGC 21953 GL261 Ttil TTATATCCCTCACTAACCTG 15970 Pan02 SalM TAAGCCCTCATTGATCAGGG 21954 to GL261 P k AGTGAGGTTCCCGAAGGCTT 15971 Pan02 SalM TTAAATGATCTCTGAGGTCT 21955 GL261 P k4 TTCGCGTTGCTATGGTGTCC 15972 Pan02 SalM GCCTTTGTCACATGTAGGGC 21956 GL261 Pcsk4 ACTAGGAGTGACACATTCAT 15973 Pan02 Ubqln3 AGAATGAGTTCCAGCCCAGA 21957 GL261 Kif3a CATGCGTACTTCAAGAGCCC 15974 Pan02 Ubqln3 TCCGAGGTGATCAGAGTTCC 21958 GL261 Kifia CCGCCCAATCTCGGGTGTCC 15975 Pan02 Ubqln3 TCTCTAGTATCCATGGTGAG 21959 GL261 K a CTGCCAGGAGCTTCCGGCGC 15976 Pan02 Foxfl CTGCACCTCTGCCGTCACTG 21960 GL261 Mrpsl8b GCAGTTTAAATTCGCGTCTG 15977 Pan02 Foxfl GGAGGAGAATAGCGCGCCTG 21961 GL261 Mrpsl8b GTCTAAGGGCGGAAGCGTCA 15978 Pan02 Foxfl CGTGGCCTCCCGCAGGGAGG 21962 GL261 Mrpsl8b AGCATGCGCAGTCGCTCTTC 15979 Pan02 Arfgapl GGCTGAGCGCCAGGTTTGCA 21963 GL261 Dnajc6 CCGGGCACAGCGCACCCAAC 15980 Pan02 A fga l TCTGAGCGCCTAGTCCAGCT 21964 GL261 Dnajc6 GCAGTTGGATCCTCACTCCA 15981 Pan02 Arfgapl CAGGGCAGCGCAGATGGATC 21965 GL261 Dnajc6 GCCGTGCGTTTGCCTGTGCC 15982 Pan02 K CCCACTCCGGCCTGGCACGG 21966 GL261 Grhl3 GGAAGGAACGGGAGAACTAG 15983 Pan02 K CTCTCTCTGGGCACCCTGGC 21967 GL261 Grhl3 AAAGGGAGGAGACAAACGTT 15984 Pan02 K TTCCACATCGCACAATCCTG 21968 GL261 Grh GGCCAATTCCTTCTTAGCTG 15985 Pan02 Loxhdl GGGACAGAACTTTGGGATTG 21969 GL261 Txlnb AACCCAGATGAATGGCCTCC 15986 Pan02 Loxhdl TGCCTCTTCTGGGACCCTAT 21970 GL261 Txlnb GTGCTTCAGTAGGTGTCGCC 15987 Pan02 Loxhdl TGACCTGAAACCCTAGTGGG 21971 xi GL261 Txlnb CTTCTTTCTTGCTGCGTCAC 15988 Pan02 Atpl3a4 AAAITAAGGTGTGACGAAAC 21972 to o GL261 Zbtb4 AGGCCTGGTGGATCCCTCAC 15989 Pan02 Atpl3a4 GTTCCTATAGCTTTCAAACG 21973 90 GL261 Zbtb4 CTCTGGACTCTGAAGTCTGA 15990 Pan02 Atpl3a4 TACGCTGGCAGGCTGTGGGC 21974 GL261 Zbtb4 CGGTGTCGTCTGCGCTTTGC 15991 Pan02 Ndufs6 TAACTGTGCGCAGTGTTCAA 21975 to GL261 Prfl GACACCTGCGTTGTCAATGG 15992 Pan02 Ndufs6 TCGTCCTATGCCTGAGCGGC 21976 90 6/1 GL261 Prfl AAGTAGTAATGATATGACGT 15993 Pan02 Ndufs6 GTTACTAGTGTGACAAAGGC 21977 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Prfl CTGTCACAAGCCGGATGAGG 15994 Pan02 Rmnd5b AACTCGTGACAACCCGTCGG 21978 GL261 Sycel CACCTGCGCAGTACGCTGCG 15995 Pan02 Rmnd5b GTTCTGACGCGCGGAAACCC 21979 GL261 Sycel TCCGATITAAACGTGATAGT 15996 Pan02 RmndSb ACCTAGTTTACTGTGGTTGG 21980 o GL261 Sycel GGAAACACGAGAGGACCGCG 15997 Pan02 Slc6a20a TAATCTCATTAACGCGCGCG 21981 o GL261 112 TTTCAAAGAGTCTACCTGTG 15998 Pan02 Slc6a20a CCCACCCTAGCCTCGGCGGG 21982 GL261 112 GCAATTTATACTGTTAATGC 15999 Pan02 Slc6a20a CCACACGCAGGGCCAAGGAG 21983 r GL261 112 TCCATTCAGTCAGTGTATGG 16000 Pan02 GjalO GTTCAGAAACTAATACTCCT 21984 o 4 GL261 Scgb3a2 TCATTTCTATGCTAGGGCTT 16001 Pan02 GjalO CAGAGGGACGTCACTTATAA 21985 6 1 GL261 Scgb3a2 ACAGGCAGTGGTTGAAATTC 16002 Pan02 GjalO TCAAGTATGAAGTTGCTGTC 21986 GL261 Scgb3a2 CCCAGCAAAGAAGAGCATGC 16003 Pan02 Atp8bl CTGCTTCAGTGACACGATCT 21987 GL261 Huwel GAATTACGAAGGTCTCGGCG 16004 Pan02 Atp8bl GGAGGCGAGAGGCTCCTCCC 21988 GL261 Huwel CGAGATCTCATGTTTCCTAA 16005 Pan02 Atp8bl ATCGAGGGAGGGCGGACGGC 21989 GL261 Huwel GGAGGAAGCTCTCGTCCTTT 16006 Pan02 Wtip GCGCGGTCTCGAAGCGGAGG 21990 GL261 Vn l 209 AGTAAACAGGAGAAATTTCA 16007 Pan02 Wtip GCGCAGACTTCGCGAGGACG 21991 GL261 Hy in GTGGCTCACACTCTAGTAAG 16008 Pan02 Wtip CCTTCCTCACATTCCTGACG 21992 GL261 Hydin GGAACGATGATTGGAGGAGG 16009 Pan02 Pnpla7 AGGAGACCAGAAGTGTAAAG 21993 GL261 Hydin TGTGGGTCAGGAAACTGTAA 16010 Pan02 Pnpla7 TGGTGGGACAGCTAAGAAAG 21994 GL261 Gsxl TCCTATTTAAGCGGCGCCGC 16011 Pan02 Pnpla7 GGGAGTTGAGCAGCACAGTC 21995 GL261 Gsxl CTAGTGGTGCTGAAAGACGC 16012 Pan02 Gtf2ird2 GGGTGCCTGAGTAACACGTG 21996 GL261 Gsxl GCCATGTGATGGGCTACGCC 16013 Pan02 Gtf2ird2 AATGTGGTTGTGCGTGCACG 21997 GL261 Dscam TACACACGATGGGCTGTGTG 16014 Pan02 Gtf2ird2 GCGCCITCCCTGGATGTGCA 21998 GL261 Dscam CAGTCITAAAGCAGCAGCAG 16015 Pan02 Ggt5 GAAGAGTTAACAGCGGCAGC 21999 GL261 Dscam AGTGCGGCGGATCACGCAGT 16016 Pan02 Ggt5 GCCATGGGATCAACTGGCGA 22000 GL261 Gml2169 GTGAGGATCTTTGCTGCAGA 16017 Pan02 Qgt5 TAGATGCCTGGCTTGCCTCC 22001 GL261 Gml2169 CTCACTGATATAAACATTAC 16018 Pan02 Gucala CCACCAGATCCTGTTAAGAA 22002 GL261 Gml2169 TGAGGTGTGGCTCTAGGCCT 16019 Pan02 Gucala GGCAAGAGGCAGAGCATTGT 22003 GL261 Wdrl CTATATATGGTCAAAGCTGG 16020 Pan02 Gucala CTCTCCGGCATCTCTAGTTT 22004 GL261 Wdrl GTCCGCAGCGGTAGCGCGCG 16021 Pan02 Mytll ATCTATGAGGCCATCTGTTG 22005 GL261 Wdrl CGGGTCTCGGAGCCGGGTCT 16022 Pan02 Mytll TTAACAGAAGGTCATATGCC 22006 GL261 Usp24 GCGTGCGCCGAACGTGTCTG 16023 Pan02 Mytll GTCAGCAGGATGCTCCCGGT 22007 GL261 Usp24 GACGCGTGTGTGTTTCTCCC 16024 Pan02 Irs4 GGCTCGAGAAGGGAGGGCTT 22008 GL261 Usp24 CGTGCTCTCTCTGCGCTCCG 16025 Pan02 Irs4 TGAGCCCAGTGAAGTGGGCG 22009 GL261 Skorl GCCGCTGGTCCCTGAAGTCC 16026 Pan02 Irs4 CACGTGACCGTCGCCTCACG 22010 GL261 Skorl CGTGCCTGTTGAGAGCGGGA 16027 Pan02 Kcntl ATTACTTCTGGTAGGAGTCG 2201 1 GL261 Skorl GCGCCATGAGCTCTAGGCTT 16028 Pan02 Kcntl GGGCGCCTCCCGGGTCCTCC 22012 GL261 C77080 GAGCGGGCAGGCCTTGCGCC 16029 Pan02 Kcntl GGGCTGAGGGCGGAGCTCGG 22013 GL261 C77080 CGGAGGCTGAGCGATCGCTG 16030 Pan02 Emcn GGTCAGGATGGGATTTGAAC 22014 GL261 C77080 GTCTCCCTGGTCTCTCGGAG 16031 Pan02 Emcn ATACACGCACTCCCTTTGGG 22015 GL261 Zkscan3 ACTAAGAGGAGGGAGAAGGG 16032 Pan02 Emcn GAAGAGACCCTTCTTGAGAA 22016 GL261 Zkscan3 TTACGAGGCAACCAAGAGGA 16033 Pan02 C2cd3 GTAGGGAAGCAAAGCATCAT 22017 v > GL261 Zkscan3 AAACTGGAGGAAGTAAAGGG 16034 Pan02 C2cd3 CAGCATGCATTGCCTTCAAG 22018 o GL261 Enpp5 GACAAGCTGGCGGGAGCCAA 16035 Pan02 Mapk8ipl AAAGGGCCAGCGACACACTC 22019 90 GL261 Enpp5 CCTGTCAATTAGCGGAAGCA 16036 Pan02 Mapk8ipl CCAGTGCTTGGAATGTCCCT 22020 GL261 Enpp5 AGCACAGCTACTCCTAGGAG 16037 Pan02 Mapk8ipl GGCGAGGCTTCTGCAAGCCC 22021 GL261 Neb AGGCATGTCTCCACCAAATA 16038 Pan02 Cylc2 AACAAGAACCCTGTGACATA 22022 90 6/1 GL261 Neb CGCAGCTCTCATGATGGTCG 16039 Pan02 Cylc2 TTCTGATAGCCACTTATGCT 22023 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Neb GCAGGCCATGTCAACTCACC 16040 Pan02 Prdx2 TGTGGGCTCCTCGCGAGCCT 22024 GL261 Slcl6al0 GCGGATGCCCAATCACCTGT 16041 Pan02 Prdx2 GACAATCTTGGCGTCCGAAA 22025 GL261 Slcl6al0 TTTAAGAGGCGGCTGGAGGC 16042 Pan02 P x2 AGCGTGTGGACCGGGCCACG 22026 GL261 Slcl6al0 CAGGGTGTAAGGCCCTCTGG 16043 Pan02 Tr AGCGGCGCCTGTGAGGTCAG 22027 GL261 Ralgapb CCTTTCGGGCTTCGGTGGAG 16044 Pan02 T TCTCGAGCGCATATAAGCCT 22028 GL261 Ralgapb CGCAGTAGTCCCTTCGGCTG 16045 Pan02 Trh CCGCCCGCTTTCCGGAAACC 22029 GL261 Ralgapb CTTATTTGACGCTGCCCACT 16046 Pan02 Lama5 GACCITAACCCTTCCGACCC 22030 GL261 Sema3b TTCTTCATTGCCCAGTAGAG 16047 Pan02 Lama5 CCCGCCTGTCCGAGGACGTC 2203 1 GL261 Sema3b AGGATCTGACTCTCATCTGT 16048 Pan02 Lama5 CGAGCCTTATGCCCTGGAGA 22032 GL261 Sema3b GGAGGAATGTGCACGAGGGA 16049 Pan02 Slcl5a2 ACAGTGCTAGAGAATCGATT 22033 GL261 Dsg3 CACCTCAGTTCCTACAGCAA 16050 Pan02 Slcl5a2 TACTCAAGAATGCAGCATCT 22034 GL261 Dsg3 GAACAGACTAACAGGCCACC 16051 Pan02 Slcl5a2 TATCTAGTCCTCATTTGCAG 22035 GL261 Dsg3 GGCAGTGATGCAAGCGTTTC 16052 Pan02 Rcbtb2 ACGATGTTTGAGGCTAACTT 22036 GL261 Pbp2 ACTTTGGGAGTCATTCATTG 16053 Pan02 R btb CTAGTGATCAAATTTCAGTT 22037 GL261 Pbp2 GCGCGTGCTGCGCTGAGAAC 16054 Pan02 R btb TAATGITATGGCTTTGAAAC 22038 GL261 Pbp2 CTGCAGAGCTTGTGTGGTCA 16055 Pan02 Ntn5 AGCGGAGAAGACTTTCAGCC 22039 GL261 Foxa2 GGTATTGGCTGCAGCTAAAC 16056 Pan02 Ntn5 CCCAGCCTCAGATCAGCTGT 22040 GL261 Foxa2 GGAGTGGGCGGGAAGGTGGC 16057 Pan02 Ntn5 TTTATCCACCAGTGGCTGGG 22041 GL261 Foxa2 ATGAGGGCCTCGGTGTTTCA 16058 Pan02 Riel CGCCTTGCTGGCTGGCGACC 22042 GL261 AtplOb TTGAGTAGGTGTAGCCTTGT 16059 Pan02 Riel CTGAGCCTGTCGCCTCATCC 22043 GL261 AtplOb CCCTCTATACCAGGTTGTGA 16060 Pan02 Riel GGGCAGGACGTCGAGGGCTC 22044 GL261 AtplOb AGGTATGTCAGTGTGGATGT 16061 Pan02 Lrrcl4b TTGGTCCTTAGGTACCAGTT 22045 GL261 Muc5ac ACTAGCCTGAAATGACTGAG 16062 Pan02 Lrrcl4b GGAGGCATCTGTCTGTCTTA 22046 GL261 Muc5ac TTCCTCAGAGGCTGCCAGTG 16063 Pan02 Lrrcl4b TAGCAGTCAGATGACCACAA 22047 GL261 Muc5ac CCCAGTGACTTCACGTGGGT 16064 Pan02 Txlng CCGGCGTCCAGCCATGAATC 22048 GL261 Zmyml CATGCGCACCGCGGTCCGCC 16065 Pan02 T ng ACGAGTCCCAGAAGAATGTG 22049 GL261 Zmyml GGGCAGCTAAGGTGACATTA 16066 Pan02 Txlng TTTGGGCTGGGCTTCTGTTA 22050 GL261 Zmyml GACTAAGCAGGAGAGGTTGA 16067 Pan02 Myh7b GGGATCACAAAGGCGGAGAG 22051 GL261 Stm CGGCTGCTCCCTGCTGACTG 16068 Pan02 Myh7b ACCTTGACAACAGCAATAAA 22052 GL261 St GCCGGGAAGTGGGTCAACTG 16069 Pan02 Myh7b GTTGAGCTAGAGGAGATAAA 22053 GL261 Stm CGCAGGCCTACAGGCAAGCG 16070 Pan02 Rpsll TGGAGGAAACGTGCATCATG 22054 GL261 Ptpn6 CAGAGCGAGGGAAGAGGAGC 16071 Pan02 Rpsll CCGGCGAGAGCCCGCGTTCC 22055 GL261 Ptpn6 GGCGGGTAGAAGCAAAGCCC 16072 Pan02 Rpsll GTTATCCTCACGGAGGTGGG 22056 GL261 Ptpn6 GAGCCACCTGCTGTTCTACC 16073 Pan02 Mocsl TTGTGCAGAAATGCCAAGTC 22057 GL261 Lepr TCTCTGGCdTTACAGCAGC 16074 Pan02 Mocsl TGCCTCTCCGCATTGCCCTC 22058 GL261 Lepr ATGCTGCAGTAATAATCGCA 16075 Pan02 Mocsl CACGCITCCGTCCTGGAAGG 22059 GL261 Lepr GGAGCTTGGGCGAAGCTTTG 16076 Pan02 Tbcldl5 TGCGTGGTGAGGATGCTAAG 22060 GL261 Trim38 TAAGTGGCTACATGGGATAG 16077 Pan02 Tbcldl5 GCACGCGCAGTACGGCACGA 22061 GL261 Trim38 TACAATCAACTGACGGCTAC 16078 Pan02 Tbcldl5 GAGGAGCGGGAACAGCAGTT 22062 GL261 Trim38 TAGAGAAATGTTTCCCACAG 16079 Pan02 PctlX GTCGCACGGGCGCCTCCTGT 22063 GL261 Faml61b AGAAGACGCTCTTGCCTCAT 16080 Pan02 Pcnx GGGACCGCTCCGCGGGTGGA 22064 GL261 Faml61b GGGCGGAACAGACTAAAGAC 16081 Pan02 Pcnx CAGGCGCTGCGCGTACCCGT 22065 GL261 Faml61b GGGCAGTCGTCAACCTTGTG 16082 Pan02 U2af2 GAAACTAGCGTTTCAACGTT 22066 GL261 Zfp938 TCAGTGCAATCTGTCACTGT 16083 Pan02 U2af2 ACCCGAAGCGAGGATTATGC 22067 GL261 Zfp938 TGCCAAACTCCTCAGGTCTG 16084 Pan02 U2af2 CTGTTCTCGGACGGAGCAGT 22068 GL261 Zfp938 TGGACCGAGCAGTTAGAATG 16085 Pan02 Strc GGCCCTCAGAGTATTACCCA 22069 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Gatsl3 TCACCCATCTGAGTCCTTCA 16086 Pan02 Strc CTGTTAGAGGGACCAATGAC 22070 GL261 Gatsl3 GGATCCCTGGCTGGGCGGAC 16087 Pan02 Strc GATCAGGTGTTCAGTGGCTC 22071 GL261 Gatsl3 AAAGAAGCACCGCCCGCTAC 16088 Pan02 P2ryl3 GTATTACAGAAGCCCACAAG 22072 GL261 Slc7al AGGAAATGTTTGCGCTTCAA 16089 Pan02 P2ryl3 ATTGAATCCAGTGCTGTCAC 22073 GL261 Slc7al GCCACGGACAGCTGACGACC 16090 Pan02 P2r l GAGCATTTACCAGTAGTTAT 22074 GL261 Slc7al CCCACTCCCTCTTTGATCGA 16091 Pan02 Pla2g6 TGACTGAAGCCAATTCTGCG 22075 GL261 Jhy ACAGGGAGAGAGCCCAGCAT 16092 Pan02 Pla2g6 TTTGGCTGACGTGTTGATAA 22076 GL261 Jhy GTCTAGCCAACCCAACTCTG 16093 Pan02 Pla2g6 CAACAGAAGCGGCTTCCATT 22077 GL261 Jhy TGAGCATCCCGAGCCGAGCC 16094 Pan02 N tc 2 TTTCCCGCAGAAAGAAGCGC 22078 GL261 Zfp941 TGAGAGCCTGCCCACCGCTC 16095 Pan02 Notch2 AAGTITCTGGCTGCGCCGCG 22079 GL261 Zfp941 AGGCCCAATTCCTCTACCTT 16096 Pan02 Notch2 GGTCGAGCGGGCGGAGTACG 22080 GL261 Zfp941 TAACTGTCCAATTAGGAACG 16097 Pan02 Fam71e2 GTGACCTCACTAGACCCTAG 22081 GL261 Efemp2 CGGATTCCTGAGCCCGCGCC 16098 Pan02 Fam71e2 CCGTGGGTGGAACCTTTGAG 22082 GL261 Efemp2 AACTCTGGCTGGGCGTCCGC 16099 Pan02 Fam71e2 GGCCTCACCATTCCAGAATA 22083 GL261 Efemp2 CGGCGCCTCCGCCCGCCCTT 16100 Pan02 Mocs3 CACCATATCTGGAAGTTTCC 22084 GL261 Amdhd2 ACATGATGACAAACCCTGCC 16101 Pan02 Mocs3 GCCAATCGTGACGGCTTCCC 22085 GL261 Amdhd2 GAGAGTCACGTGATGCGACC 16102 Pan02 Mocs3 TCGTTTCACTTTCAAGGGCC 22086 GL261 Amdhd2 ACGTGGCCGCGGTGCTCACG 16103 Pan02 Pramel7 TGACAGATGCCTACTATGAG 22087 GL261 Cnrl CCAGTCCCATTTATGAAGCG 16104 Pan02 Pramel7 AGTCTCCAACATGGCTACCA 22088 GL261 Cnrl GGGTACCGCGCAGCAAAGTT 16105 Pan02 Pramel7 AGCAAATAGTGAGTGAAATA 22089 GL261 Cnrl AAGGCTCATTAACACGTGAT 16106 Pan02 Pnma3 ATGTGATGCACATAAATCTG 22090 GL261 Mgmt TGCAGTTGATTACTGAGCTG 16107 Pan02 Pmna3 GGGAACGCATTAATTTCCTT 22091 GL261 Mgmt ACGGGCCGCAGGCGCGTGCA 16108 Pan02 Pmna3 ACCTATAGAAGTGTCTTTGC 22092 GL261 Mgmt TGTAGTCCGAGGGTGTAAAG 16109 Pan02 Calcrl TGCTCTTGTCAGAGTGAGAA 22093 GL261 Tmem202 CTCTATACCCAGGATTCTTC 16110 Pan02 Calcrl CCTAACACTAAGTGCAGGCG 22094 GL261 Tmeno202 GAGAGAGAGAGAGAACAGTC 16111 Pan02 Calcrl TGTAAGCGATCAGCAGCAGA 22095 GL261 Pdelc TCTCTTGGGAAGTTAACTAA 16112 Pan02 Phkal TGGGCGTAGCGCGCAGCTGC 22096 GL261 Pdelc GCCCGCACTGCATAAAGAAC 16113 Pan02 Phkal CGCCTCGGGCGACACATTCT 22097 GL261 Pdelc AGTGGTATTGTTTACCACAA 16114 Pan02 Phkal GGCGGAGGGTGGCGGGCTAC 22098 GL261 Snape5 GATGACGTCACCGCCGACTG 16115 Pan02 Boc GTAATGGGAGGCTCCTAGGC 22099 GL261 Snapc5 AAGTGGAATCCCAAAGAGCA 16116 Pan02 Boc GCAAAGAAAGTAGGCGTTAA 22100 GL261 Snapc5 TTACTGTGAGGGATTACCAA 16117 Pan02 Boc TCCCATTACCGCTCGAAGAG 22101 GL261 Agfg2 GTTCGATTCGAGACGGCCTC 16118 Pan02 V p TCAAGACCTGTTCATCCCAT 22102 GL261 Agfg2 GCATTGTACTTGCAAGGTGG 16119 Pan02 V p CACTACTGTGACGTCJTTCG 22103 GL261 Agfg2 TAGGAGTCCGTGGCGAGAGG 16120 Pan02 Vip AGCAAACAAGTTCAAGAGAG 22104 GL261 Caly GTTGCTGCAGGACGCAGTCG 16121 Pan02 Nagpa GCCTGGCCTGGAATCACGTG 22105 GL261 Caly GAAGCCTGAGAGCGAGGCTG 16122 Pan02 Nagpa GCATTCGAATTCCATCAGAG 22106 GL261 Caly GGATGTACGTGCAAAGATAT 16123 Pan02 Nagpa AGTTCTGTACAGACTTACAC 22107 GL261 Ankfnl ACCATGCCTCAGTGACACCG 16124 Pan02 MyhlO GAGTAGCAGCCTATGAGATT 22108 GL261 Ankfnl CCAAATCATTGATTGTTCCA 16125 Pan02 MyhlO TGTGGGTCTAGGTCGGGAGC 22109 GL261 Ankfnl GTGACTCACAGGATCCTAGC 16126 Pan02 MyhlO CCAATCACCCGCCACTGCCC 22110 GL261 Clcn7 GGTGCCCACGTGACTGACGA 16127 Pan02 Suzl2 CGCCTCCGCGTGACTGACGG 2211 1 GL261 Clcn7 AGTGAAGACACTAATTGCTA 16128 Pan02 Suzl2 CTGCGGACCAACGGGCTGGG 22112 GL261 Clcn7 GAGGACTAGGCGTGCATCTC 16129 Pan02 Suzl2 TCGCGGAGGCGCGGCTTGGT 22113 GL261 Stykl AGGTAGACAGGGAACTTACT 16130 Pan02 Sntbl AATAGAGGGTTGAGAAGAAA 22114 GL261 Stykl AGGTGTGAGTTGCCTTGTTT 16131 Pan02 Sntbl GTGGGAGTGTGACGCTGCAG 22115 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Stykl GAGACAGAGCAGTTATGCTG 16132 Pan02 Sntbl TTGTGACCCGGTAGGTTTGG 22116 GL261 Poll AAACAGCCCGAGCGTGGCAG 16133 Pan02 Mybbpla CTGGGACGTCCGAGTGAGGG 22117 GL261 Poll GAATGAGAAAGATCTGGTTG 16134 Pan02 Mybbpla GAAGCCACTTCCAACCTGCT 22118 o GL261 Poll AGGCTAGGCCGTGGTTTCCT 16135 Pan02 Mybbpla AAGGGAAAGGCAAGGCCGTA 22119 o GL261 Zfp3613 CAGACGTACGTAAGATGTGC 16136 Pan02 Dock6 GGCGAGGCCGGGCCAACTCT 22120 50 GL261 Zfp3613 AGAATGCATGAGCGTGAGAG 16137 Pan02 Dock6 GGGAGGAGCCTTCTCTGGAG 22121 r GL261 Zfp3613 AAAGGGCAGGTAGGCGGAGC 16138 Pan02 Dock6 CCCAGCCGCGGAACCAAGAC 22122 o 4 GL261 Urocl GCCTGAGTGTTACTTGCCAG 16139 Pan02 Flg2 TCTCTAAGATGATTGCAGAA 22123 6 1 GL261 Urocl GGGTCATACCCAAGTTAGAT 16140 Pan02 Flg2 CTCAAGCTAGAAGCTATATA 22124 GL261 Urocl AAGTGACTGACTGGGTAGTC 16141 Pan02 Flg2 TGTCTTCATTGTGGAAGGTG 22125 GL261 Rbml2b2 CGCGCGTTCAGAGCGCCAAG 16142 Pan02 Trim42 GTGGTAGCTGGGATACATAC 22126 GL261 Rbml2b2 ACTGCTTCGGTTACAGTGAT 16143 Pan02 Trim42 AGGAAGTTGGCCAGTTTATG 22127 GL261 Rbml2b2 CTGTTCTCTGCAGTGTAGTA 16144 Pan02 Trim42 GCTCAGTAGTAGGTAAGAGG 22128 GL261 Prokrl GAGACAGCGTGCTGTGGGCG 16145 Pan02 Cpeb2 GTGCCGGAGCCGGTTCCGGG 22129 GL261 Prokrl GAATATGGGCGGGAACATCG 16146 Pan02 Cpeb2 AAGGGACACTGTGACTGAGC 22130 GL261 Prokrl GACACACTGAGCAGAGGCTA 16147 Pan02 Cpeb2 ATCAGGCCGGCGGCCGCGGC 22131 GL261 Rh g CCCTCAGCTCGAGGTTGGCA 16148 Pan02 Fanil 26b GTCCTGGAGCAAGACAAACA 22132 GL261 Rhbg GAAACAGGACCTGACCTGCG 16149 Pan02 Faml26b AGAGATGACATGAAGGAGCC 22133 GL261 Rhbg ACATCACCGGTGCCTCAGCG 16150 Pan02 Faml26b TTGCAGCTGGAGTCTGCTTG 22134 GL261 Myhi 4 AGAACCTGGCCGAGAATGTG 16151 Pan02 Zfpl09 TCCGGCGCCTGTGTAGGTCG 22135 GL261 Myhi 4 GCTTCTCAAGCATGCAGGAG 16152 Pan02 Ζ 109 ATCAGAAACCTTCCTTAGAA 22136 GL261 Myhi 4 GCGCCAGGCCAATCAGAAGT 16153 Pan02 Zfpl09 CCTGGCTTTGGAGCACATCT 22137 GL261 Dnajcl4 GCGCAGCTGCTTGAGGAGGG 16154 Pan02 Tubgl CTAATCGTTCTCCGCTCCAA 22138 GL261 Dnajcl4 TGAGCGGGAGGCGGAGCCGG 16155 Pan02 Tubgl GTCTGGCGCCTGCGTCTTGC 22139 GL261 Dnajcl4 GGAAGTAAGCGGCCGTGGCG 16156 Pan02 Pgm3 CCCGACCAATCGCGGCGGGT 22140 GL261 Dusp9 TGGTGGGAGTTGCAAGCCGC 16157 Pan02 Pgm3 GGCTGTGATTGGTGTGGGCG 22141 GL261 Dusp9 CCGACTAAGTAGCAGCTCAA 16158 Pan02 Pgm3 CGCCCGCGGAACTGCGGCTG 22142 GL261 Dusp9 CTGAGCTAGGGCTTCCACCC 16159 Pan02 Snapc4 TTCTGGCGGTCCCAGGTTGT 22143 GL261 Zfp395 ACGCGGCCGCGGCCACAACC 16160 Pan02 Snapc4 TTTCCCGTGTGTGTCGTCCT 22144 GL261 Zfp395 TGAGCGCAGTGTCCCGGAGA 16161 Pan02 Snapc4 GAAAGATGAACGCCTCGCTA 22145 GL261 Zfp395 CCGCGAGCCAGCCAGACGCA 16162 Pan02 Cacnala TTCTCCGGAGTGGGTGGCCG 22146 GL261 Aridla GAGCGAGCGCAGCGCAGCAG 16163 Pan02 Cacnala GATCGCCTGGATCGCGTCCC 22147 GL261 Aridla TCTCCGCGGACGAGACAGCG 16164 Pan02 Prkcg GGGCATCTGTCCCGGGCGGG 22148 GL261 Aridla GAGAAGACGAAGACAGGGCC 16165 Pan02 Prkcg AGGCGTTGCCATGACGACCA 22149 GL261 Slc9a2 GCAAGGCTGAGCGCGGCCGA 16166 Pan02 Prkcg CATTCCGCAGGCTCTATGCA 22150 GL261 Slc9a2 CTGTAGCTGCCAGGCATGGG 16167 Pan02 Pabpc4 CCCGGGCGCTGCTGGTCGAA 22151 GL261 Slc9a2 AGCGACAGGAGGCCACTGCG 16168 Pan02 Pabpc4 GGGTATAAATGGAGCGGTGG 22152 GL261 Plac811 GAGCTTAGTGGCACTTAACA 16169 Pan02 Pabpc4 GTGTCCGCACTGCCCTTCGC 22153 GL261 Plac811 AGACAGCACATGCCCAACTG 16170 Pan02 Zfp202 TTCTCCAGTGAGACCCATGC 22154 GL261 Plac811 CTTTAAACAGAATGTTACCT 16171 Pan02 Zfp202 GCAGTCCAGGGAATGCTTCC 22155 xi GL261 Nfatc2ip ACCGGCCTCTACACAGTCAC 16172 Pan02 Zfp202 GTGATGGGTTTGCCGCAAAG 22156 o GL261 Nfatc2ip TAAGTAGACCAATGAGAACG 16173 Pan02 Nrxn2 ACGCAACACTGACGGACGAG 22157 50 GL261 Nfatc2ip CAGACGCTAATACGGTGGGC 16174 Pan02 Nrxn2 GAAAGGGCTCGGATGCCCTG 22158 GL261 Hcnl CGGACGCGTATTTGTACGTT 16175 Pan02 Nrxn2 GCCCAATGCGTGTGCTTGGG 22159 ~ GL261 Hcnl GGAGGGAGGCTCTCTGGATG 16176 Pan02 Slc44a5 ATTCCAGTCAGCAGGA1TCA 22160 50 6/1 GL261 Hcnl GGGAGGAGGGAAACGACAGA 16177 Pan02 Slc44a5 GAAACAGGAATGCCAGACTG 22161 0 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GL261 Ccs CCCGCTCAGCCGGAACCACC 16178 Pan02 Slc44a5 CACCCTCGTCCAGCGACAGT 22162 GL261 Ccs AGGACGCCAAATGGTTACTA 16179 Pan02 Oc stamp ATCAGGAGGGTTTGATTGAA 22163 GL261 Ccs AGCACTACCGGACAGCTCAG 16180 Pan02 c stamp AGGCAGTCAGGAGCAGCCAG 22164 GL261 Tekt3 TAGGGAGTTCCAGTGCCTCC 16181 Pan02 Oc stamp AAGCAGTGCCCGTGACCCTG 22165 GL261 Tekt3 GTTGGGAGACTAGAGCGTCC 16182 Pan02 Obox7 CAAATGTTGGGTGAGAATTA 22166 GL261 T kt ACGAGCGTAGTAACCGTGCA 16183 Pan02 Obox7 CATCTATCTTGACAATTTCA 22167 GL261 Llcam GGCCAGGTTCAGATGAAACA 16184 Pan02 Obox7 TCAATGCTCCTCCTTCACGT 22168 GL261 Llcam CGAGGTCCCTATCACGCGCG 16185 Pan02 Setd2 GGGCGGCCGGCGTCGCTGGC 22169 GL261 Llcam AACGAGGGTGTGGCGAGGCG 16186 Pan02 Setd2 CGCCCGCCCTGCAGCCTTGC 22170 GL261 Nes ATCAAATTGTAGCCTCGCCC 16187 Pan02 Setd2 GCTTCGGGAGTGAGTGTGTG 22171 GL261 Nes CTCTAAAGGGTTAAGGCCTA 16188 Pan02 Dnah6 AATACTCTGGGAACACCGAT 22172 GL261 Nes GTATTCATACTCCCGCCGGC 16189 Pan02 Dnah6 GTCATTAGITGTCAGGGAGC 22173 GL261 Intsl GCATAAACTGTTCCCTCTTA 16190 Pan02 Dnah6 AGTGCAGTAAGCGTCCTTGG 22174 GL261 Intsl GTGAGAAATCAGCGCTCGGA 16191 Pan02 Acaala GGAGAGAAAGCGTCTTAGGA 22175 GL261 Intsl AGGGCGGTGCAAACACTAGT 16192 Pan02 Acaala TTCCAGTCTGCCTTTCAAGG 22176 GL261 Lpin3 TTCTACTGGCTTGTAGAGTT 16193 Pan02 Acaala TTCCGTAGGATTGGCGGGCG 22177 GL261 Lpin3 TTGGTGGAAGGAGTGGAGAC 16194 Pan02 Zfp800 GCGGCCGTTGCCCTGGCGAG 22178 GL261 Lpin3 GTGACTCAGCTAGTCACTCA 16195 Pan02 Zfjp800 CTTGCGGGTAGCAGATGCTT 22179 GL261 Dock 11 GGAGGGTGTGTCTCCTGGAG 16196 Pan02 Zfp800 AACCGGAGCAGGCAGGACTG 22180 GL261 Dock 11 TTGCAGGCTCTGGGTCCTGC 16197 Pan02 Depdc5 CGGCCACCGAGACGAGGCGG 22181 GL261 Dock 11 CCGACCTGAGTGGCCTAAGA 16198 Pan02 Depdc5 ACTTCAAACCGAGTTCCCGT 22182 GL261 Tgm6 TAATCACCCAGTAATTGCTT 16199 Pan02 Depdc5 CTGGGCTAGAGCGGCCAAGC 22183 GL261 Tgm6 ACACTCCTAGGCAGTGAAGT 16200 Pan02 Arid GTCCATGGGCGGGTCCGCGG 22184 GL261 Tgm6 AGCTCTTACTATCTTACTTC 16201 Pan02 Arid5a TGTGCGCCCACTTTGCAGCT 22185 GL261 Tnfrsf22 GTGGCCACGCCTCTCCTCAG 16202 Pan02 Arid CCCTTAGACCCGAGGACGTC 22186 GL261 Tnfrsf22 TGTATGGTTGCCTTATCTCG 16203 Pan02 Ripk2 GGGAGGAGGACGGTCCACCC 22187 GL261 Tnfrsf22 GCACGCCGCTGCTGCTCAGC 16204 Pan02 Ripk2 CAGGGAGCCCGTCGGGTCTG 22188 GL261 FstM AAATAGGGCAGCCGCGGCAG 16205 Pan02 Ripk2 AGCCCGCCGAGTCCAGGAGG 22189 GL261 FstM GCTGCTCTACACCTGCCGCG 16206 Pan02 B3glct GCCGGTTGCGAGCGTACACC 22190 GL261 FstM TGGCGGCGATTGGGCAGGCG 16207 Pan02 B3glct TGACGGCAGAGTTTGTCAGA 22191 GL261 Clk3 CGTTGGACAGTAGGTGGGAG 16208 Pan02 B3glct CAGATGCCCAGAGGAGGGCG 22192 GL261 Clk3 TCAGAAGAGAATACAAGTCG 16209 Pan02 Daglb GGACTTCATACGCCACCGAC 22193 GL261 Clk3 TTTGTCGTGGCAGGATCATG 16210 Pan02 Daglb GTGAAGCTAGGACGTAGGTC 22194 GL261 Nfl GGGCGTTGGCGAGGAGACTG 16211 Pan02 Daglb TTCATAGGCGCGGCTCTCTA 22195 GL261 Nfl CTCGGACTGTGATGGCTGAG 16212 Pan02 S om4 AATGACACGGAGCTGGAGAG 22196 GL261 Nfl GCGGGCAGCTAGCGTTCCCA 16213 Pan02 Sh om4 CCGGGAGAGTAGGCGGAGCG 22197 GL261 TmemlOl AAGCTCTTGCTCCCTAGTTC 16214 Pan02 Shroom4 TCAGGCAGCTTGTGAGCTCT 22198 GL261 TmemlOl AGCTCTGAGTTCTCTTCATG 16215 Pan02 p GCTGGAGATGTAGGGATGGG 22199 Hepal -6 Obscn TTGGTTAAATTGGCCTCTCC 16216 Pan02 Cilp GGGAGTCTCATGCTCAGATC 22200 Hepal -6 Obscn TAGAATGTGGTACAGGCGAC 16217 Pan02 Clip CATCAAGATCCTTAGGGATG 22201 Hepal -6 Obscn CTTGAGTGGGTTGGGAGTGG 16218 Pan02 Foxal TATAATTGGITTAAGCCTCG 22202 Hepal -6 2410089E03Rik CTGGCTACGCCGAGGAGGCG 16219 Pan02 Foxal AAAGTGAGGGCCAGGTTTGG 22203 Hepal -6 2410089E03Rik CTCCGTGGGCGGGCACCTGA 16220 Pan02 Foxal CTGGCGGGCGGCCGCCTCAC 22204 Hepal -6 2410089E03Rik GTCGCCTGGACACGGCTCTG 16221 Pan02 Vmnlr217 AGTATTAGTAATCCCAGACA 22205 Hepal -6 Ahnak CTCGGGTCCTTGCCCTATTC 16222 Pan02 Vmnlr217 CAGGGAAAGGAGGAGTTTCA 22206 Hepal -6 Ahnak GTAACTCGGGCGGGTCTGCC 16223 Pan02 Vmnlr217 TGGAATTAATGAAGCAGCCA 22207 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Ahnak GACTAACACTGAAGCCACCC 16224 Pan02 Nlipl4 GTTAGATGCAGTTCCTACCC 22208 Hepal-6 Pkhdl ACTCTGGTGCACGTTTAGCC 16225 Pan02 Nlrpl4 CTCTCTGCTGTTACCGCCTT 22209 Hepal-6 Pkhdl CCACTTAGAGACCCAAAGAA 16226 Pan02 Nlrpl4 AGCTTACCCAGACAGCCAAT 22210 o Hepal-6 Pkhdl TCTGAGACACATGCAGTAAG 16227 Pan02 Ccl27a TTCAGGGCTTAGAAGCCCAT 2221 1 Hepal-6 Cd72 ACTTGGCGTCACAGCGCAAA 16228 Pan02 Ccl27a AGGGATACCTTCGCATTCTA 22212 Hepal-6 Cd72 TAGCTTCAGCGCCTGTATTT 16229 Pan02 Ccl27a ATTGTTAACGGTCCGTTTCC 22213 b Hepal-6 Cd72 CAATGAAGCAGAGAGGTCCT 16230 Pan02 Pcdhgb5 ATCGTTTCGTGAACTAGAAC 22214 o 4 Hepal-6 Klra6 TTTGCTTTGATGAAGAGGAG 16231 Pan02 Pcdhgb5 CACCGCTTCTTTCCGAGAAA 22215 Hepal-6 Klra6 TGAGGTTGAGTATCACTCGG 16232 Pan02 Pcdhgb5 ATCAAAGACCGATTGGAGCC 22216 Hepal-6 Klra6 CTGAAACAACATATAGTATC 16233 Pan02 Nasp GATGGGCGGGACAAGGGACC 22217 Hepal-6 Cyp2dll CAGCATGCTCTGCTCCTGGA 16234 Pan02 Nasp TGTTTCGTCAGTAGTTGCTG 22218 Hepal-6 Cyp2dll AAGCTTCCTTTATAAGGATA 16235 Pan02 Nasp ATTGGATCAGTCAAAGGCGG 22219 Hepal-6 Cyp2dll CACTGGGTCCTCCCTATCCC 16236 Pan02 Stu l ACGTGACACGCTGACACCGA 22220 Hepal-6 Rbm44 GCTCCTATTGGCTGTGTAAC 16237 Pan02 Stubl CTGGACTCTTGCCCTTCTCG 22221 Hepal-6 Rbm44 ATCTTCTCGCGAGACTTAAA 16238 Pan02 Stubl GGGTCAAAGGGTCTTGGTGC 22222 Hepal-6 Rbm44 AGTAGTGTCCCAGGGTTTAG 16239 Pan02 Arhgap30 GCAACCACAGGCCTCGGGTG 22223 Hepal-6 Clca2 GGCTTCTTTCGGAACTTAGA 16240 Pan02 Arhgap30 ATTCACATCCTCATCATTGC 22224 Hepal-6 Clca2 CCAGGTGAGTACTATTGCCT 16241 Pan02 Arhgap30 CATTCATTGGTCACAGCAGA 22225 Hepal-6 Clca2 GCTTCCTCCTGCATCACAGC 16242 Pan02 Mpdz CTCCTAAATGTGACTTCCAA 22226 Hepal-6 Lyst GGACTTTAGGCGCTCGAGGC 16243 Pan02 Mpdz GAACGACCGGCGCACGGGCC 22227 Hepal-6 Lyst CCTCAGGTAACCCGGGAAAC 16244 Pan02 Mpdz GCTGCGGGAAGCCGTGACGC 22228 Hepal-6 Lyst AGATTCTCCACGCATCACGT 16245 Pan02 Ttc36 GCCAGGGTTACTGACCTGGC 22229 Hepal-6 Zfp39 GGAGCGCAGCCCGGGCACAG 16246 Pan02 Ttc36 CTCCACCTTAAAGCTGAAAC 22230 oo Hepal-6 Zfp39 CCAATCAAGGCACGATGATG 16247 Pan02 Ttc36 AATCCITAGTCCAGCCTCAG 2223 1 Hepal-6 Zfp39 TCATCGATTGGTGCTATCTG 16248 Pan02 Cel GTGCACTGTGGGCACCACTC 22232 Hepal-6 Apohec3 TCTAGGCGATCAAGCCCAGA 16249 Pan02 Cel GGTGAGTGTCTGCCTCTAGG 22233 Hepal-6 Ap ec3 AGACCTGCTCCTCTGTACAG 16250 Pan02 Cel GGTATGCACACACATGACCT 22234 Hepal-6 Apohec3 AGAGAAGCTGATGCCGACCG 16251 Pan02 Kdm6a AAAGCAGCTAGCAAGTTAAG 22235 Hepal-6 Za GCTGTTGAGAGTCACATGAA 16252 Pan02 Kdm6a CAAAGGTCACGTGAGGCGAG 22236 Hepal-6 Zan GTAGCAACCATAGGTTCTAA 16253 Pan02 Kdm6a CAATTACAACAACTTTGTGC 22237 Hepal-6 Zan CATTCTACAACTGAAGACAG 16254 Pan02 Gucy2g GCTGCCTCTGTATTGTGTTA 22238 Hepal-6 Clca4b GTACTATGTCTCAAGAAGAA 16255 Pan02 Gucy2g GAAACCAGCTCTTTCTCAGC 22239 Hepal-6 Clca4b AATCACCTGTTAGCTGATTG 16256 Pan02 Gucy2g GAAGTATCATTATACAACTC 22240 Hepal-6 Clca4b ATGTACAGAAATCACATAGC 16257 Pan02 Fam205c GATAAACTCAAGTGGTGATT 22241 Hepal-6 ZfplOS CTACATITCCCAGAACGAGA 16258 Pan02 Fam205c GAGCCCTTGTTCCACAAATC 22242 Hepal-6 ZfplOS GAAGCAAACTTAGCTGCTAA 16259 Pan02 Fam205c GCCTCACAGAAGATATAACC 22243 Hepal-6 Zfpl08 TCGGCGGAAGTTCATCGGTC 16260 Pan02 Kirrel2 AGGTACGTGTATGGCTTGCA 22244 Hepal-6 Ifitlbll TCAACATACAAACAAGCACC 16261 Pan02 Kirrel2 CAGAGCAGCAGGGAGTATTT 22245 n Hepal-6 Ifitlbll AAGGAGGAAGTATGGTAGGT 16262 Pan02 Kirrel2 TAGGGAGTATTTGGGAAATA 22246 Hepal-6 Ifitlbll TAGGGATTCTAGGATAAGCA 16263 Pan02 Slcl7a6 AAGCTGCATTTGGCTCTGCA 22247 n Hepal-6 Ehbplll GGTACCCGGGTGTCCAAGTC 16264 Pan02 Slcl7a6 TGGGCGGATCGCCCTGACCA 22248 o Hepal-6 Ehbplll CTCGCGGGCGCCCATCAAAC 16265 Pan02 Slcl7a6 GGATGCTATGGAAACCAAGT 22249 Hepal-6 Ehbplll ATGAGTACCGATCGCAAAGC 16266 Pan02 4933409G03Rik CATACATCTTGGAACAACCT 22250 Hepal-6 Clca3b TTAACGGTTAAATGTTAGTG 16267 Pan02 4933409G03Rik CCGGCCCTACACTGAAATGA 22251 b Hepal-6 Clca3b CACATCCATCGTTCTTTCTA 16268 Pan02 4933409G03Rik CAACATAAAGCTGCTTGATG 22252 J Hepal-6 Clca3b CGGCCAGAATATTTGCATAT 16269 Pan02 Sytl AATCAGAGAGCACTGATAAT 22253 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Skint4 TGACAGGTATGGGTCAGACC 16270 Pan02 Sytl CTCTTCTGAGCAGCGTACCT 22254 Hepal-6 Skint4 AATACTAGATAAAGTCACTG 16271 Pan02 Sytl GGAGAGACTCTAACAGTACT 22255 Hepal-6 Skint4 TAGAAAGACTTGCTCCACCC 16272 Pan02 Otog GGTAGTTACAAAGGCATAGA 22256 Hepal-6 Aktia ACAAACACTTGTAGGAAATC 16273 Pan02 Otog TCAACTTATGGTAATGAGCT 22257 Hepal-6 Akna ACAACCGTGCTTGTACGAGC 16274 Pan02 Otog ACAAAGACTGGTCTGTAGCC 22258 Hepal-6 Akna CCAAGAGCTTAACCCTTTGC 16275 Pan02 Wdr62 CACCGCCCATTGGACGCAGC 22259 Hepal-6 Rusc2 GCTGCCTCGGGCGAAGCTGG 16276 Pan02 Wdi62 CGGGTAGGCTCATTGCCCAA 22260 Hepal-6 Rusc2 AGCTAGGCTCGGCTCTCCCT 16277 Pan02 Wdr62 GCTTTGTGATTGGCCAGCCG 22261 Hepal-6 Rusc2 GAACTGAGTGGCTGCACTGT 16278 Pan02 Obsll AAGTCACTCAAGCCCAAGCC 22262 Hepal-6 Klra2 AAAGCTGACTCTGACAGCAA 16279 Pan02 Obsll ATATTCTCTGATGACACAGC 22263 Hepal-6 Klra2 ATACTCCAGCTCATAACATT 16280 Pan02 Obsll GGCCTCCAGGTCTCCAACTG 22264 Hepal-6 Klra2 CAGTATATGCCAGAATACAT 16281 Pan02 Ptprj AGCAGAACAACGCCTAAAGC 22265 Hepal-6 Card6 CCCGGAGCACTCTCGGTCTG 16282 Pan02 Ptprj TCTATACAGAACCCTGTATT 22266 Hepal-6 Fam208b GTCGCTGTGCTCCTTGTGAT 16283 Pan02 Ptprj GAGACGCCAGAGCGTGCACC 22267 Hepal-6 Fam208b GGGCAAAGCTAGCTCCGGAT 16284 Pan02 Lonrfl TCTAATTGGCTTCTCTGACG 22268 Hepal-6 Fam208b TGTAGGCGGCGGGATCTAGA 16285 Pan02 Lonrfl GCGCCCAAGTTATAGGCCTG 22269 Hepal-6 Sis AACATGGAGAGAGTGTTAGA 16286 Pan02 Lonrfl GGATGGACCTCGGTTACAAG 22270 Hepal-6 Sis GAAAGGAAACTGTGTITAAA 16287 Pan02 Pla2g4e TCAGCTGAGAGCCTAGAGGT 22271 Hepal-6 Sis AACAATCACAGATGAAGTCA 16288 Pan02 Pla2g4e CAATTGAGCAATGGCTTTAC 22272 Hepal-6 Arid4b GGCATCCGGGAAAGAGGTAG 16289 Pan02 Pla2g4e AGTTGAAAGAGAATGCACCA 22273 Hepal-6 Arid4b CCATTTACCCACCAGTTCTA 16290 Pan02 AI182371 ATTGTGTAGGATTTCGCATC 22274 Hepal-6 Arid4b CGCCTCITCCAAGTTTCTAT 16291 Pan02 AI182371 ACTTCAATTAACGCAGAATG 22275 Hepal-6 Fat3 GATTAATTCAGAAGAAAGTG 16292 Pan02 AI182371 CTGATTTCAGTTGTCATATG 22276 Hepal-6 Fat3 CTCTGTGTTTACTTCCAGGA 16293 Pan02 Zfp871 GCATCCTCTCGAGTGTACTG 22277 Hepal-6 Fat3 ATCATATCACATGTCCGTCC 16294 Pan02 Zfp871 GAGGCGTGCACGTGACTCAC 22278 Hepal-6 Serpma3k GACAAGTTGTGCCCTGTGTT 16295 Pan02 Zfp871 AAACCTCTAATCCGAACGTA 22279 Hepal-6 Serpina3k GGCTTGTACAGAGAAGAGTT 16296 Pan02 Cep350 ACATGGCTGGCCTTCACCCA 22280 Hepal-6 Serpina3k TCGTCAGACAAGAAGATTCC 16297 Pan02 Cep350 CATTCCTGCGGAACCGTCTC 22281 Hepal-6 Nlrplb TGGGCTTCATAGGACAGAAG 16298 Pan02 Cep350 CCATCTTTGGTGTGGCGCTT 22282 Hepal-6 Nlrplb ATACACAGTACCCATTACCC 16299 Pan02 Gbp2 CGAACTCCTCACAAGTTCTC 22283 Hepal-6 Nlrplb GTTTCACAGCTGAATGATGC 16300 Pan02 Gbp2 CTCAGGTAGAGATTGATAAA 22284 Hepal-6 Ahctfl AAGAGTTTCTCAGTAAGTCT 16301 Pan02 Gbp2 GCTCATGGGAGGAGGGTCTC 22285 Hepal-6 Ahctfl TTTGTCATATATCTGACGCT 16302 Pan02 Rabllfip5 CTATATGCTGGTGGAACTGG 22286 Hepal-6 Ahctfl TGAAGAGTTGGAGCACAGAA 16303 Pan02 RabllftpS GCGCGGCCTCTGCAAAGATG 22287 Hepal-6 Fanca GGCGCAGGTGTATTGCACCA 16304 Pan02 Rabllflp5 TCTGGGTTTCTTTAGCTCTT 22288 Hepal-6 Fanca TCCCGGAGTCTGGCTGCGTT 16305 Pan02 Otof TGGAITCAGCATGCGTTCCT 22289 Hepal-6 Fanca GGGTGGCAGAGAAGGCAGTA 16306 Pan02 Otof GCTGGGCTGACAACCCAGAG 22290 Hepal-6 Tnfrsf22 GTGGCCACGCCTCTCCTCAG 16307 Pan02 Otof GCACAGCTCTGATGAGCTGA 22291 Hepal-6 Tnfrsf22 TGTATGGTTGCCTTATCTCG 16308 Pan02 Tspyl3 AAGAGCAGGCATTAGGAGTC 22292 Hepal-6 Tnfrsf22 GCACGCCGCTGCTGCTCAGC 16309 Pan02 Tspy ATGCTGGGCTGGTATAGACT 22293 Hepal-6 Gm973 CCTGAGTTCCCGTGATTCAC 16310 Pan02 Tspyl3 CCACCTGAGTCAAACAGAAC 22294 Hepal-6 Gm973 TTCCGCTGGGACCGAGGGAA 16311 Pan02 rc b CTCGGCGCTCGCTGGAGCCT 22295 Hepal-6 Gm973 CCAGAAAGTTTCCCAGCGCC 16312 Pan02 Prrc2b CCCTGTCCCGGGAGGGAGGG 22296 Hepal-6 Skint7 CAAGCAAGTCATGATGAAAC 16313 Pan02 c2b CGCCGCCTCCCGCCCGCGCT 22297 Hepal-6 Skint7 CGGTGATGATATCTGAGACA 16314 Pan02 Hs6st3 GCGCCTGAGCGTCTACCGAC 22298 Hepal-6 Lrrfipl GGGTGGAACCATAGAGGAAG 16315 Pan02 Hs6st3 TCGGCTCCGCTCGTAGGCCC 22299 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Lnfipl AGGCGGGCATAGGGTGGGTG 16316 Pan02 Hs6st3 TACCTGGACGCGGCGCTCTC 22300 Hepal-6 Lnfipl TGGTGGTGATGGAGAAACTC 16317 Pan02 Zfp957 TTCTTCATTAACGATTGACA 22301 Hepal-6 Csf2rb2 GAGCTGATGTGGAGATGGTG 163 1 Pan02 Zfp957 TGAGGAATAACTCCATCAGA 22302 Hepal -6 Csf2rb2 TCCAGAGAAGTCAGGGAGGT 16 1 Pan02 Zfp957 GCCCTGTAAGCGCATCTGTG 22303 Hepal -6 Csl2rb2 GGTGTGGAGGAGGCCATTCC 16320 Pan02 Hslbp3 CATCGCAGTGTCTGTGGCCT 22304 Hepal -6 Pappa2 GGTACCAAGAAGCTGACTTT 16321 Pan02 Hslbp3 CCATAGCCACCTCTTAAGCC 22305 Hepal -6 Pappa2 GGTTCTAAGGAACAAGCTGA 16322 Pan02 Hslbp3 GCACATCCGCTGCCACCAGG 22306 Hepal -6 Pappa2 GGCTTGGGAATCGATTTCCC 16323 Pan02 Lrfnl GGGCGGCCACACGCACTCCC 22307 Hepal -6 Muc4 GAGGGCAACTATATGTAATA 16324 Pan02 Lrfnl GCCCGGCACACACAGGGCCG 22308 Hepal -6 Muc4 ACATGCTGATACTGAGCTGA 16325 Pan02 Lrfnl GTGTCCGCGGCGCTGCGGCG 22309 Hepal -6 Muc4 TATAGGTACTATAATGAGCA 16326 Pan02 P km AAGGCATCAGGGTTCTTAAG 22310 Hepal-6 Dmbtl ATAAATCAATATGACGGAAG 16327 Pan02 P km CAGGCTTAGGTCGAGAGGAA 2231 1 Hepal-6 Dmbtl TAGGTGTGTTTGACTGATTG 16328 Pan02 Pfkm AACCAAGAGTGCGTAAGTCC 22312 Hepal-6 Dmbtl TTAACAGTTTGACTAATCCG 16329 Pan02 Wnt3 CTCGCTGACATCCTCAAACC 22313 Hepal-6 Urb2 GTGCCTGAGTATATGCACTC 16330 Pan02 Wnt3 GTAGITCAGCCTGTCAATCA 22314 Hepal-6 Urb2 GGAGTCCAAGAAGGTCAAAG 16 1 Pan02 Wnt3 CAATCAGCGCCCGCGGCCTA 22315 Hepal-6 Urb2 TTTCTGGTGTCTGTTCAGTT 16332 Pan02 Mef2d GCGTCCCAGGCCTCCCTGCC 22316 Hepal -6 Pilra ATTACAAGCCACTTAGGAAA 16333 Pan02 Mef2d GACGAGAGTGATGGACAAGC 22317 Hepal -6 Pilra GGCTTTGTCCTCAGGAGGCA 16334 Pan02 Mef2d AGGCTGCGCGGTGCCTACGT 22318 Hepal -6 Pilra GGGCGGATCTTCTGCAACAT 16335 Pan02 Faml78b CACAGTTGCCCATTGTTTGT 22319 Hepal-6 Impgl GCTGACAAATGTTCCTCCAG 16336 Pan02 Faml78b TAGATGGAAACTTAACCAAT 22320 Hepal-6 Impgl ATTCTCGAGGATCCGGAAGC 16337 Pan02 Faml78b TTCAGAAGCTGAGTGGCGCG 22321 Hepal-6 Impgl GGGAATCTGTCTGAGAACAC 16338 Pan02 CM3 GGTGGTGGTGGTAGCGGTGG 22322 Hepal-6 Serpina3n AAGCCTATTTATTCCCATCA 16339 Pan02 CM3 CCCTCCTCAGACGCCGGCCC 22323 Hepal-6 Serpina3n GCTTGTGTAGAACAGAGGTG 16340 Pan02 CM3 CGCCGCCGAGGAGGAGGAGG 22324 Hepal-6 Serpina3n TGAACAGACTGGATGATTTC 16341 Pan02 Gib 112 GGCGCGCCTCTGAGTGTTGC 22325 Hepal -6 Lama5 GACCTTAACCCTTCCGACCC 16342 Pan02 G b 112 GGGCTGGGCTGGCCGTAACA 22326 Hepal -6 Lama5 CCCGCCTGTCCGAGGACGTC 16343 Pan02 G b 112 GGGCCGCTCACTGGTTACCT 22327 Hepal -6 Lama5 CGAGCCTTATGCCCTGGAGA 16344 Pan02 Piwil2 CGGGCTCCTGGTGTCGAGCG 22328 Hepal -6 Cntnap5b AAATTCATAGGCACCAGCCT 16345 Pan02 Piwil2 CCAGGGCCCGCCCACCCTTT 22329 Hepal -6 Cntnap5b GAAGAGTGTCTGTTTAAGGG 16346 Pan02 Pmil2 GGACTGGAATTCGTTATTCC 22330 Hepal -6 Cntnap5b TGGAAGAATCGCTCACTCGG 16347 Pan02 Scrmla GTCTGGTCTGGGAGCTCTCC 2233 1 Hepal-6 Seipina3a TCAAGGAGGATCGATGTTCC 16348 Pan02 Scnnla CTCATTAGCATCTCAATTAA 22332 Hepal-6 Setpina3a GGCACTCTGGATCTTATCCC 16349 Pan02 Scnnla CAGAGACCGCCCGTCGGCCA 22333 Hepal-6 Serpina3a TCTTTATAAAGCATACATCG 16350 Pan02 Acad11 GCTTAGGAGAAGCCAATCAC 22334 Hepal-6 Serpina3m CAGTTTACAACTCGTCAGAC 16351 Pan02 Acad11 TTTACCCTCAGCGTCAGAGC 22335 Hepal-6 Serpina3m AGGAGGGAGGAGCCCTTGGG 16352 Pan02 Acad11 TCTAAGTCTGGTCCCACAAC 22336 Hepal-6 Serpina3m CATGGACAAGCTGTGCTCTG 16353 Pan02 Armcx4 GAGGAGGGCGAGCGATGACG 22337 Hepal-6 Serpina3i AGCCACACTAGTTCACCCAT 16354 Pan02 Armcx4 ACTGCTTTCTGACCAGTGGG 22338 Hepal-6 Serpina3i AGGACAGACTGGGTGATTTC 16355 Pan02 Armcx4 TTGCCTGTGCGTACAGAAGG 22339 Hepal-6 Seipina3i GGTTTGTATTTAGAACAGTA 16356 Pan02 Dock 10 CAGAGTTTGCAAAGTCGCCG 22340 Hepal-6 Btla GAAGGATTTGTGAGAGCAAG 16357 Pan02 Dock 10 CACAGGAAGTGGTGACTTGT 22341 Hepal-6 Btla TTAAATCAAATCAGGAGACC 16358 Pan02 Dock 10 CCCGCTCAACTCACAAGAGG 22342 Hepal-6 Btla ATTCACACTAGCAGCATCTT 16359 Pan02 Dpp3 CTGCTGTCCGTCTGATCCCT 22343 Hepal-6 Nlic5 TTCGGTTGGCATTCGGCTAA 16360 Pan02 Dpp3 ACTGTCTTCGGTTCTTCTAC 22344 Hepal-6 Nlic5 TCATCTGGGAGATGAGCCTC 16361 Pan02 Dpp3 GCACCACCCGTAGCGCTTGG 22345 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Nlrc5 AGCTGGCCGTGCAGAGAGGA 16362 Pan02 Naa25 CCGACCTATCGCGATAGTGG 22346 Hepal-6 Nuggc ACTATCAATTATGTATGGGA 16363 Pan02 Naa25 GCTCGACGCTGGCCCTTTAA 22347 Hepal-6 Nuggc TCTAACAAGTTAGGAAGAAC 16364 Pan02 Naa25 TGGCTCGCCTCTCCTTTAAT 22348 o Hepal-6 Nuggc GCAGTCTATTCATAATGAAG 16365 Pan02 Pdcl CGGCGTCTGAGGAGGAGCTA 22349 Hepal-6 4930427AOTRik ATTGGAGGTGCCAACTCCGT 16366 Pan02 Pdcl TTGTAATTTGTCTCGAAACT 22350 Hepal-6 4930427 O Rik TGCCTACCAGTCTATCCCGT 16367 Pan02 Pdcl GGAGCTACGGGTCTTAGCTT 22351 Hepal-6 4930427AOTRik TGATAAGTCGAGGTGCTGAT 16368 Pan02 Shank2 CTCTGCGCGGGATGACGCCC 22352 o 4 Hepal-6 Pirb GTCAGAGCATGGTGCTGAGG 16369 Pan02 Shank2 CCCAGTTATCCAAGGAAACC 22353 Hepal-6 Pirb ATGGCAGAGGGTCTACTGCC 16370 Pan02 Shank2 AGTACnTATATTTAGCCAC 22354 Hepal-6 Pirb TGATATATGACCATGTCATG 16371 Pan02 Heatr5b TGCGCGAGACACAGGTCCTG 22355 Hepal-6 Sde2 ACCGCCTTCCGGAAAGGCGG 16372 Pan02 Heatr5b ATGCGCCGTGCAATTGGCGC 22356 Hepal-6 Sde2 GGTCGCATCTCGATGACGGA 16373 Pan02 H tr b CCGATTCGCTTCGAAACTTG 22357 Hepal-6 Sde2 CACTAGGCGACACAGCCATC 16374 Pan02 Peg CTGCGGGACACCTCCTTGTC 22358 Hepal-6 Xirp2 TCTCCTGAGAAATGTATGCA 16375 Pan02 P g TTGACGTCAACTCCGTGCCT 22359 Hepal-6 Xi p2 GGTTGCATCCTTTGGACACA 16376 Pan02 P g3 CGTGGTGAGGGCCCAAAGCG 22360 Hepal-6 Xirp2 AGACTCACTTCTGAAAGGAG 16377 Pan02 Sim2 GTTTATGGCAGACCCGCCTT 22361 Hepal-6 Cnst GCGACCATAGAGTTCCAGCA 16378 Pan02 Sim2 CGACTCACGGGCCGCGGCGG 22362 Hepal-6 Cnst GGCTAGAGAGGAAGTGCGGA 16379 Pan02 Sim2 GCTCGGTCACACGTGGACCG 22363 Hepal-6 Zfp462 GAGAGACATAGAGGGAGGGA 16380 Pan02 Slc27a6 TTGAAGCCCAGGGAGCTGCA 22364 Hepal-6 Zfp462 GCGCGCGCGAGGGAGAGGAG 16381 Pan02 Slc27a6 GCCTGTTGGACAGCCGTGGA 22365 Hepal-6 Zfp462 CTGAATAATGAGCAACCAGA 16382 Pan02 Slc27a6 ACTCACAACACTCACAGCGC 22366 Hepal-6 Cfi GCTAATAGCCAGAGCTTTAT 16383 Pan02 CoxlO CTAGCGGAGCTTATAAAGAT 22367 Hepal-6 Cfi TTCTATTGGTGGCCTGCCTC 16384 Pan02 C xlO GGGCGGAAGGCGAGTCGTGG 22368 Hepal-6 Cfi AAAGTACAAAGCTCTTTAGG 16385 Pan02 CoxlO TTTCAGAGAGCGCTGGGAGC 22369 Hepal-6 Serpma3b TGGACAGATAGGATGATTTA 16386 Pan02 Plekhg2 TCCTGGGCCCTTGCTGTAAA 22370 Hepal-6 Serpina3b GTTGTGTAGAAGACTCTTAG 16387 Pan02 Plekhg2 TTGCAATTATTCAGAGTAGG 22371 Hepal-6 Serpina3b TATCTTGCAGAACCAGCTCC 16388 Pan02 Plekhg2 TGTGGGCGGTGACTCGCCGT 22372 Hepal-6 Emilin2 AGAGCCAAAGGGTTAGGAAC 16389 Pan02 Slcl2al CACACCAGTCATTAGCCCTG 22373 Hepal-6 Emilin2 GAAGAGTCACGTTTCGGAGA 16390 Pan02 Slcl2al TGCGTGTGCGACGCTAATGT 22374 Hepal-6 Emilin2 GCGGTCCCTCAATGACGCAC 16391 Pan02 Slcllal GTTGATGTGGTACTTACAGT 22375 Hepal-6 Poml2112 AGAGGAAGATGGAACTGTTT 16392 Pan02 Adamtsl2 GGCTGGAGGCCTGTCGGGTG 22376 Hepal-6 Poml2112 GGAITTGTAACCTTGCACCC 16393 Pan02 Adamtsl2 GAGACCCTAGACAGCTGGCC 22377 Hepal-6 Poml2112 GTTCTATCAGAGCCTCCTCA 16394 Pan02 Adamtsl2 CTCTGACCCAGTCCATGCTC 22378 Hepal-6 Cdsn GAGCTAAGGAAGGCCAGCTG 16395 Pan02 Myoc GGGACCCAGCCCTGTGTGGA 22379 Hepal-6 Cdsn CAGGAGAAGCTGAGGCAATC 16396 Pan02 Myoc TATAAATGTCTTTGGACTTC 22380 Hepal-6 Cdsn TGAGTAGGCAGATGTGACAC 16397 Pan02 Myoc GAGAGGTGATCACATGAAGC 22381 Hepal-6 Skintll GCAGCTCTGTTCTTGAATGA 16398 Pan02 Stard5 ATTCCGTCCTTTCTTGATAT 22382 Hepal-6 Skintll TTTATGCAATGTTAAGTGAG 16399 Pan02 Stard5 TGACGCTTACTGCGCAGGGC 22383 n Hepal-6 Skintll GACTTGCCTTGGTGTGACTC 16400 Pan02 Stard5 GCCACACAGGTTCTGCTGGG 22384 Hepal-6 Ugtla7c ATAAGCATTTGGACTCCTTA 16401 Pan02 Ovca2 ACTTCGCCGGCTCCCTGAGA 22385 n Hepal-6 Ugtla7c TCAAAGCAGCTTACATTTCT 16402 Pan02 vca2 GCTGCAAATACCTGCTGCTC 22386 o Hepal 6 Ugtla7c TGAGCTTAGAAATAGTTATG 16403 Pan02 vca2 TTGCAACTGCGCAGACCAGA 22387 Hepal-6 Mpdz CTCCTAAATGTGACTTCCAA 16404 Pan02 Ut l 4a GGAGGCTTGCAAAGTATTGT 22388 Hepal-6 Mpdz GAACGACCGGCGCACGGGCC 16405 Pan02 Utpl4a GGCGCTCCAGGATTGGTCGA 22389 b Hepal-6 Mpdz GCTGCGGGAAGCCGTGACGC 16406 Pan02 Utpl4a GCGTTGTCGCGCGTGATTAG 22390 Hepal-6 Serpinald GCTTAAGACTCCATTGATTT 16407 Pan02 Hspb2 CATAGCTGCACTCTAGACTT 22391 J Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Seiplnald CGGTTGTGTTTATGAGGGAT 16408 Pan02 Hspb2 GGGCCTGGTAGGACAGCTGA 22392 Hepal-6 Serpinald GAGGGAGAGAGTCCATCCAT 16409 Pan02 Hspb2 CCAGAGGCTCTGCACTATTT 22393 Hepal-6 4930444G20Rik GCTTTCGCTTGGTACTATAC 16410 Pan02 Cux2 TAAGACAATGGCTGTGTGTC 22394 Hepal-6 4930444G20Rik ACCTTATACCTGGCTCTGGG 164 11 Pan02 Cux2 TGCATAGTTCCAGAGCTCAG 22395 Hepal-6 4930444G20Rik AAGTGATTCTTCGGACATCA 16412 Pan02 Cux2 TGAATCGATATAAAGAGGAG 22396 Hepal -6 Skint3 CGTCTGTGAATGTATCAGTT 16413 Pan02 Pappa CAATTGGGAAGGTGGAGTGC 22397 Hepal -6 Skint3 AATACCAGATGCAGTCACTA 16414 Pan02 Pappa GGCTGTGGCTTGTGTTATAA 22398 Hepal -6 Skint3 TGGCAAGACTTGACTTATCC 16415 Pan02 Pappa CTTGTTTACTCGTCTTCTAA 22399 Hepal-6 Vpsl3d GGTGTGGCACGCCATAATGC 16416 Pan02 Tmpo AGAACGCGCGCCGCCATTGG 22400 Hepal-6 Vpsl3d AAAGTTAACAGAGCACAGCT 16417 Pan02 Tmpo GTTTGCGACATAGTCATTTC 22401 Hepal-6 Vpsl3d AATTCTAGACTAGGCAGGTC 16418 Pan02 Tmpo GTGTCAGAGCGCTCCCTGGA 22402 Hepal-6 SkintlO AGTAAATCTGAGCCACGCCA 16419 Pan02 Pclo GGAAGTGTCCGCAGTTCGCC 22403 Hepal-6 SkintlO TTTCTGGTGCTAACTTGCCT 16420 Pan02 P lo ACGCCTAGACACCGACTTAA 22404 Hepal-6 SkintlO GCTAGATTGACTTTCATAAA 16421 Pan02 Pclo TGGCGGACATCACCTGTTCG 22405 Hepal -6 Irgm2 GGAGGAACTCTGTCGGCCGC 16422 Pan02 Wnt9a GGGCGCCGGCCAGCTGGGCT 22406 Hepal -6 Irgm2 CTGAAAGCTGTTCGGGCACC 16423 Pan02 Wnt9a CTATAAGAGGGCGGCGGTCG 22407 Hepal -6 Irgm2 GGCCAAGTTCTTCTTCAGAG 16424 Pan02 Wnt9a CGGGCGCGCAGCTCGGATTT 22408 Hepal -6 Cfap46 GAACTGATGGACACCGAGTG 16425 Pan02 Shroom2 GCTGAACTTGCTTTGCAACT 22409 Hepal -6 Cfap46 ACACTCAAGAGTTCTTGACC 16426 Pan02 Shroom2 CCCTAATAGGCATGGAGAAT 22410 Hepal -6 Cfap46 ACTTGAGGAGTCCGTGACGC 16427 Pan02 Shroom2 AGCGCTACGCGGGCCGGACC 2241 1 Hepal -6 Col6a3 GTCTGTCCTATGGCAGGGAG 16428 Pan02 Pzp TTACCCAAATGTTTGAAAGA 22412 Hepal -6 Col6a3 GGAGCGAGAGGAGGAGCAGG 16429 Pan02 Pzp TGCAGGCTGCCACTAGCTCA 22413 Hepal -6 Col6a3 AGGAGGAGGAGAAGAAGGCA 16430 Pan02 Pzp GTTTACTTTCACTGCCCATC 22414 Hepal-6 Gml3083 TCATTGCCAAAGATCCTTCA 16431 Pan02 Bdkrb2 GGGAACAGCTCATCTTTCAA 22415 Hepal-6 Gml3083 CCAGTGATTGGACCACATCA 16432 Pan02 Bdkrb2 GTTCTTAGCGGTGGTGCTTT 22416 Hepal-6 Gml3083 GGTCCTCCTGGTAATATATA 16433 Pan02 Bdkrb2 CGGTGATGTCATCACTCTCC 22417 Hepal-6 Faml66b GGTAAAGCCAGCAGAGGTGG 16434 Pan02 Vps72 AACTAGGACCTCTCGACGCT 22418 Hepal-6 Faml66b GGCCGAGAGTTGGCGAATGA 16435 Pan02 Vps72 CGCTGAACTTCCGTCATTGA 22419 Hepal-6 Faml66b GAGGAGCTTCCTGGTCTTCC 16436 Pan02 Vps72 GCACTCGACACTATTACCTG 22420 Hepal -6 Osmr CGGGAAATTGCAACAGTACT 16437 Pan02 Uspl71a GCTCAGAAATGTCATCTCTT 22421 Hepal -6 Osmr CGGGAGTTACGGGAAAGCGC 16438 Pan02 Uspl71a GGAAATTGGAGCTAAATTCA 22422 Hepal -6 Osmr TTGGCACTCCTGGGACCCAC 16439 Pan02 N4bp2 AGCCTCCGTCCCGGTTGCTG 22423 Hepal-6 Gml3119 CAGTAGATTGAATCTTGTGC 16440 Pan02 N4bp2 CGGGCGGGACTGCAGCTGCG 22424 Hepal-6 Gml3119 TTGTGCTGGTGGCGGGTAGG 16441 Pan02 N4bp2 TGGCGGCGCGGGCTGGATCC 22425 Hepal-6 Gml3119 GGTTAAGACACTCAGAGTCT 16442 Pan02 Mkml GTTCCTGAGACCTGAGCGCT 22426 Hepal -6 Lifr GCCCGGAGGCGGCGCCTGCG 16443 Pan02 Mkml GGAGACGCGGTGACACGGCG 22427 Hepal -6 Lifr CGCGCGTGAGTCGGAGCCTC 16444 Pan02 Mkml GCGTGATCACACGCTTAGCC 22428 Hepal -6 Lifr GACGGCGGAGAAGGCTGCGG 16445 Pan02 Pihldl GAAACACTACGGCGGCGTTC 22429 Hepal-6 C9 TTGTTCATAGGTGTTGGCTT 16446 Pan02 Pihldl CAGGACCCTTCAGGAACGGG 22430 Hepal-6 9 AAGTGTCAAGGTCCAACCAA 16447 Pan02 Pihldl CTTCAGCTCTTTCATACAAG 2243 1 Hepal-6 C9 GAATTACAATGACTCTCCAT 16448 Pan02 Cntnap5b AAATTCATAGGCACCAGCCT 22432 Hepal-6 3425401B19Rik TCTATTACTCGTGGCTGATC 16449 Pan02 Cntnap5b GAAGAGTGTCTGTTTAAGGG 22433 Hepal-6 3425401B19Rik TGAGGCTGGAATCGTGGTGA 16450 Pan02 Cntnap5b TGGAAGAATCGCTCACTCGG 22434 Hepal-6 3425401B19Rik GCTCTGCAGCAACACCCGCG 16451 Pan02 Arhgap25 TAAATGGAAAGAGACTCCCA 22435 Hepal -6 Prune2 GGTGTGCCGCCCGGGAGCCC 16452 Pan02 Arhgap25 CCCGCTCTGTGCTTAGAGTA 22436 Hepal -6 Prune2 AGCAGGCTGGTGGCGGTCCC 16453 Pan02 Arhgap25 GAAGTGGCCACAGCATCTGA 22437 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal -6 TCTGTCCTAATAAGGAAAGT 16454 Pan02 Hpx TTCCATGACTATGCCAATAT 22438 Hepal -6 GGAAGCTCTCACATCCAAGC 16455 Pan02 Hpx CTCAATAGGGTGGGAAGTGG 22439 Hepal -6 AGACGTGCTCTGAAGACTAC 16456 Pan02 Hpx AGGTTGAACTTATATAGAAC 22440 Hepal -6 CCTACCTTAITAACTTAGTG 16457 Pan02 Dpy l GCCCGCTAGCTGCGCGCGCC 22441 Hepal -6 TCTAAGTACCTGCTCTCAAC 16458 Pan02 Dpyl911 TGGCGGTCGCTCACTCTGGC 22442 Hepal -6 AGTCCCGGAAGTGGCTGTCA 16459 Pan02 DpyMl GGGAGTCCGGCGCCGCCTCT 22443 Hepal -6 GGTCTGAGGCCTGAAGGCGG 16460 Pan02 Vpsl3b AATTAACTCTACGAAGAGCT 22444 Hepal -6 AGAGAAGCCTGAATGTGAAA 16461 Pan02 Vpsl3b GACGGCGAAGCCCGCACACC 22445 Hepal -6 AGGAGAGACGGAAGGGAAGG 16462 Pan02 Vpsl3b GCGTTTCCGCGGCGGACGCC 22446 Hepal -6 AAGGGAGAAGAGAAGGTGGG 16463 Pan02 Acot2 CAGCTCAGTCTAAGGACTGC 22447 Hepal -6 GTGTGATCTGTTGGTGAGCC 16464 Pan02 Acot2 TAGTAGTGACGCTTTGACTA 22448 Hepal -6 GGATGTTCTGAGAGGCTCAG 16465 Pan02 Acot2 CGTTAAGACTCCGTTATATC 22449 Hepal -6 TGGAAACAGGATCCTGCAAG 16466 Pan02 Stab! GGAAATCCTGTCACTCAGCC 22450 Hepal -6 AACCGTATGGCGCGGCTCCT 16467 Pan02 Stab2 TTTCCTTTCCCTGGTTAGGA 224 1 Hepal -6 GTGACGCACTTCCTATTGCG 16468 Pan02 Stab2 TCTGAGCTGTATATAAGTCC 22452 Hepal -6 GTCCTCTGAAAGACAGTAGT 16469 Pan02 Tmem229a GGCTGCAGAGATGGCCAAAG 22453 Hepal -6 ATTGGGCACGTCTTGAGGCT 16470 Pan02 Tmem229a AGGTCGAGCCGGGCGGAGAG 22454 Hepal -6 GACACACAAACGGAGGGTAG 16471 Pan02 Tmem229a GCGGCGCTCTTCGCCTTTCG 22455 Hepal -6 AATTAACTCTACGAAGAGCT 16472 Pan02 Invs TTTCCCGACGTGCTTCGAGA 22456 Hepal -6 GACGGCGAAGCCCGCACACC 16473 Pan02 lnvs GTCCCAGCTCTCCGATGACA 22457 Hepal -6 GCGTTTCCGCGGCGGACGCC 16474 Pan02 Invs GGCCTCTCTGGAAGTTGTCC 22458 Hepal -6 CTGAAAGAGAGATAAAGCTG 16475 Pan02 Nrk TGGTGGAGCGTCACGTCGCC 22459 Hepal -6 GGAGGAAATAGGAGGGAGGG 16476 Pan02 Nrk CTGAAAGGCGCACCCTGCCC 22460 Hepal -6 TCACTTACCTCCTTCTCACT 16477 Pan02 Nrk GTTAGAGACTCCCTCTGCCC 22461 Hepal -6 GTGCGGGTACTTTCCGACGC 16478 Pan02 Paxbpl TGCACTGCCCTCTAGCGGCG 22462 Hepal -6 TGCTTAGCCTTTGGCGTCTC 16479 Pan02 Paxbpl GAGACTCCGCCCAAGTAGTG 22463 Hepal -6 AAGCTAGCGTGAGGGACAGC 16480 Pan02 Paxbpl GCTCGCTGACTGAGAGGACG 22464 Hepal -6 AGCAGCAGGATTTAGAGGGA 16481 Pan02 Trmtll CGGTGCTCAGTTCCGGTCCT 22465 Hepal -6 AGAAAGCCAAGAGTTGGGTG 16482 Pan02 Trmtll GTCTTATTTCGGTTCGGTGG 22466 Hepal -6 AAAGGTCAGATCTGTACTCC 16483 Pan02 Glrx CATTTAATAAGGAACCTCCT 22467 Hepal -6 TCCGGGTGCGCGCTCGGCCC 16484 Pan02 Glrx GTGACTTAGTTCTGTTCTTG 22468 Hepal -6 GAATGGCGTGGAGCAGCGAG 16485 Pan02 Glrx GGTATGAGTCAGTACTTCCT 22469 Hepal -6 CCCTCCCTCCCATTGTCACC 16486 Pan02 Myo7b AGTGAATACTCCTGAGACAG 22470 Hepal -6 GTGCTAACCTGTGATCACTG 16487 Pan02 Myo7b GGAAGGGCTCCAAGCGGAAC 22471 Hepal -6 GATTTCACTATGCCTTGGCC 16488 Pan02 Myo7b GGGCATACGTAATTTATGAC 22472 Hepal -6 TACCTGATTGGTTATCACCC 16489 Pan02 Peakl GGAGCGCGCTGTGGACTCCG 22473 Hepal -6 ACATGGCTGGCCTTCACCCA 16490 Pan02 Peakl GGAGGAGCGAGCGGACTGGT 22474 Hepal -6 CATTCCTGCGGAACCGTCTC 16491 Pan02 Peakl AGACCGCCGAGGTTTGGTGC 22475 Hepal -6 CCATCTTTGGTGTGGCGCTT 16492 Pan02 Vmn2rl21 GTTTGAAGGCTACTGCTGTC 22476 Hepal -6 AGATAACACTCACCTATAAA 16493 Pan02 P e b AGAGTTGGACTAATCTAGGG 22477 Hepal -6 AGATAAGCCCAGAGAAGTAC 16494 Pan02 Pde4b TCTTCAGTTAGGAACAGTCC 22478 Hepal 6 ACCTTGGAACGCTCAGCCTC 16495 Pan02 Pde4b GGGCTCTGAAAGACTAAGAA 22479 Hepal -6 GGAGAAGTACTCAAGGGTCT 16496 Pan02 Dennd4a GATCCGCCCACCAAAGTCAC 22480 Hepal -6 ATGTGGCTCAGTAGCTGAAA 16497 Pan02 Dennd4a GTCTCGGGACTGAAAGCTAC 22481 Hepal -6 CCGGAGCCGGACCTTGCTTC 16498 Pan02 Demd4a GTGGTTGCTAACCGCTTAGG 22482 Hepal -6 GCGTTGCTTTAGTTGATATG 16499 Pan02 Paip9 CTTGGAGTCGAGATCGGTGG 22483 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Srfbpl TTTCCGGCAGTGCCGCAAGT 16500 Pan02 Paip9 CTTTGTTTCTTCTCTCAACT 22484 Hepal-6 Srfbpl CCGGCGCGTGTACGACTAGC 16501 Pan02 Parp9 TCCAGAACCTTGTGCACGCT 22485 Hepal -6 Skint9 ACCTGAGCCATGCCAAGGAA 16502 Pan02 Atplla AGGGAGTCGCGGCGCGCGCG 22486 o Hepal -6 Skint9 ACACAGTAGCATTGGCTTCC 16503 Pan02 Atplla GCACCCGACGAGCCACGCGG 22487 Hepal -6 Skint9 ATTATGCAGTGTAAATGAGC 16504 Pan02 Atplla AGGCGGAAGCAACAGGGCGG 22488 Hepal-6 H2-M10.5 TAGAGAACTGTTGCAAGTTG 16505 Pan02 Brinp3 GAGAGCAGCAGCACTGATTT 22489 > Hepal-6 H2-M10.5 TGATGAGTGGAGTCTCAATC 16506 Pan02 Brinp3 CAGCGCTTCGGAAATCCTGC 22490 o 4 Hepal -6 Akap9 TGTTCCGAGCACCGGGTCCC 16507 Pan02 Brinp3 CCCTGGCTTGTAAGGCAGGA 22491 Hepal -6 Akap9 TTGGAATTGGAAATGCAGCG 16508 Pan02 Setdla CGAGGGTAGCGGCCTTGCCT 22492 Hepal -6 Akap9 GCGACCGCGGCCTCACAACA 16509 Pan02 Setdla CACTTTCGCTACAAGGACTG 22493 Hepal-6 9130008F23Rik GAAGTGGGTGGAGATCAATA 16510 Pan02 Setdla GGTGTTTGGTGCGCGCGCCG 22494 Hepal-6 9130008F23Rik AAACTCCAGCTAAACTCGGA 16511 Pan02 Bd2ald GAAACAAGATCCCTCTAAGT 22495 Hepal-6 9130008F23Rik TTGAGCGAGGCACTGACTAG 16512 Pan02 Bcl2ald GAGGCTCTTCAAAGTCACTC 22496 Hepal -6 Usp44 GAAACAAACATCATTTACCC 16513 Pan02 Bcl2ald AGCCAAAGTTCAGACTCTGA 22497 Hepal -6 Usp44 AACCGGACGAGTTTCTACTT 16514 Pan02 Ttc29 GGACGCTGAAAGCGTCTCCA 22498 Hepal -6 Usp44 CGTTACAATCAAGCTCTTTC 16515 Pan02 Ttc29 GCTCCAAGACTCTTCAAGTG 22499 Hepal-6 Col27al GATAGGTGGACGGTCGCGCG 16516 Pan02 Ttc29 AGAGTGGGCCTGTTAGTGAG 22500 Hepal-6 Col27al CCCTTGCTGCGTCCGGCAGG 16517 Pan02 Hsphl GGATGGAGGCCGGGCAAGCT 22501 Hepal-6 Col27al ATGAAGGCGATTTAAAGTCT 16518 Pan02 Hsphl CAACTCAGGCCGCCCGCGGA 22502 Hepal-6 Neil3 CTGAGCCAGTGCACAGTGAA 16519 Pan02 Hsphl GAAGTGGCACGTGGAGGCGC 22503 Hepal-6 Neil3 AGGTCTCACACTTGTGTCAT 16520 Pan02 Ces2g GCAAAGTCGCTGTATTTATC 22504 Hepal-6 Neil3 GAGCAGAGTCCGCACCACCT 16521 Pan02 Ces2g TTCTATAAGCCCTGCTACTC 22505 Hepal-6 4932414N04Rik AGCACCTGGGAATGTGGTGG 16522 Pan02 Ces2g ACTGTTTAGTCAGAAGTAAC 22506 Hepal-6 4932414N04Rik TATATGCCTGGCCCAGGGAG 16523 Pan02 Cagel GTCCGGAGGACGTCACACTG 22507 Hepal-6 4932414N04Rik TATTAGGAGGTGTGGCCTGT 16524 Pan02 Cagel TCCTATGACCGTAAACGCCA 22508 Hepal-6 Serpinalb AGTCCATCGGTTGGACACTG 16525 Pan02 Cagel GTGGAGCAAGAACGAAAGGC 22509 Hepal-6 Serpinalb TCTCTCTGGTCCTAAATCAA 16526 Pan02 Thbs2 CCTGGGTGGACCTGTAGGAG 22510 Hepal-6 Seipinalb ACCAATGTCACCACAGTTAT 16527 Pan02 Thbs2 TTTATTTCCTGAGAGAAGAC 2251 1 Hepal-6 Pgbdl GCACTTCCTGTAGTTGGAGC 16528 Pan02 Thbs2 GGAGTCCCAGCCAATCTTGC 22512 Hepal-6 Pgbdl AGCCCTGGCGAAGGCACTAC 16529 Pan02 C a5 ATCCAGAGAAGATAACGTTA 22513 Hepal-6 Pgbdl GTACATCTATTACGTTCGTC 16530 Pan02 Cmya5 CAGATCTTCAGCGGCCTTTG 22514 Hepal-6 Klra7 AACTAGATATGATGATACAG 16531 Pan02 C a5 CGGGTGCTTCGTGCCAAATG 22515 Hepal -6 Klra7 TCTTCTCTCCTTTGTTCTGA 16532 Pan02 Sis AACATGGAGAGAGTGTTAGA 22516 Hepal-6 Klra7 ATGCTATAAACACCCTGACA 16533 Pan02 Sis GAAAGGAAACTGTGTTTAAA 22517 Hepal -6 Vars2 ACGCGGCTTCAGACGTCTGC 16534 Pan02 Sis AACAATCACAGATGAAGTCA 22518 Hepal -6 Vars2 CTCTCGCTCCTCCGGCTTTC 16535 Pan02 Myom3 TCTCTTCCTGCCAGCACTGC 22519 Hepal -6 Vars2 AGAAGCGGGTATCACTGCGT 16536 Pan02 Myom3 CTATATTTAAGACGGTTACA 22520 Hepal-6 Gm8909 GACTTTATAACCAGCGCCCG 16537 Pan02 Myom3 CTGAGACAGTGCGGTGACAA 22521 n Hepal-6 Gm8909 TCTGAGGCCTTCAGGCTGCT 16538 Pan02 Gsap GGGACAGCCGTGCGAAGCGG 22522 Hepal -6 Terf 1 TTTAGCAGTTCTCAGCCAAT 16539 Pan02 Gsap GGGTAGGGAGAAGTGCTCCC 22523 Hepal-6 Terfl GCCGTGCGCTGATTTGCTCG 16540 Pan02 Gsap GGCGGTGCTCGGGATCCTCG 22524 Hepal-6 Terfl CGCCTGGGCTCGGATCGACA 16541 Pan02 Pn-141 CGCATGGCTGGCTTTGGCCC 22525 Hepal -6 Gemin5 GTGCTCAGTGGCTGGTTGGC 16542 Pan02 Pn- 1 ATTGCGCGCGCGCCGTGCGG 22526 © Hepal -6 Gemin5 ATTTAGITCCAGGCGGCGCA 16543 Pan02 Pn-141 TTTAAGAGTCAACGCGGTGG 22527 Hepal -6 Gemin5 AAATATGTAACCTCAGGACC 16544 Pan02 Fdps GTGTGGCCTAGTTCGCTGAT 22528 Hepal-6 Ugtla6a TAAGGCAAGTACTGGCAAGC 16545 Pan02 Fdps TAAATTACCTCGTGTGAGCA 22529 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Ugtla6a TGGCTCACCCAGACCTTGTC 16546 Pan02 Fdps TTCATTGGCCAGCCGTCACA 22530 Hepal-6 Ugtla6a TCAAAGAACAATTTCCTCCA 16547 Pan02 Myhl3 TGGCTGAGAGATCTACAGCC 2253 1 Hepal-6 Serpinal2 TCTGGAGCCTAACCACAGCA 1654S Pan02 Myhl3 CACACACTGAATAGGAATAG 22532 o Hepal-6 Serpinal2 Pan02 TAAGTITCTCAATCACTGTC 16549 Myhl3 GGTGAAGACTCAGGAGCTCT 22533 o Hepal-6 Serpinal2 ATTTCAATATCATCAAAGGC 16550 Pan02 Rfto2 AGAGGAAAGGACAGAGGGAG 22534 Hepal -6 Lmod3 TGGGCTAGACAGCGAGTAGC 16551 Pan02 Rftn2 GGAAAGGAAGGAGAGAGGAA 22535 90 r Hepal -6 Lmod3 CCTGCAGAGATTCCATAGCC 16552 Pan02 Rftn2 AGAGGGAAGGGAGGGAGGAA 22536 o 4 Hepal -6 Lmod3 AGCTGTACTGAAATGTCAGA 16553 Pan02 Anks3 CGCCACAGCAGCCCATGAGA 22537 6 1 Hepal -6 Pfas TCATCAGAGAGCGCCACCGC 16554 Pan02 Anks3 GGGTGGCCGTACTCAGCACG 22538 Hepal -6 Pfas AAAGATACTCCTGTCTGCTC 16555 Pan02 Anks3 CAGATACCGGCCCATTCGCT 22539 Hepal -6 Pfas GCCCGCGCGAATCGCTTCTC 16556 Pan02 Ppplr3d CCCACGCTGTCGGAACCGCG 22540 Hepal-6 Klrblb ACACAGCACAGCATACCCAG 16557 Pan02 Ppplr3d GCGCTTGGAGAAGTTGCGGG 22541 Hepal-6 Klrblb TGTGCCACATACAGAACGTA 16558 Pan02 Ppplr3d CCGGCGGGCGGCGTCACGAG 22542 Hepal-6 Klrblb TTTCTCCATAGCTATTGACC 16559 Pan02 Hdgfll GAGCCCTAACCCAGATGCCA 22543 Hepal -6 Tdrd5 TCGCGTGGAACGTGGCGCAC 16560 Pan02 Hdgfll TGCTGTTTGCTGTAACATTC 22544 Hepal -6 Tdrd5 GACCGCGGCGGAGGCACATG 16561 Pan02 Hdgfll GCAGTGCAACATTCTCAAGA 22545 Hepal -6 Tdrd5 AAATAAGCGCAGACCTACGG 16562 Pan02 A830010M20Rik TGGTAAGCTGTGGGCCTTCC 22546 Hepal -6 Ceacam3 GAGAGGCCACCTAGCTCAAG 16563 Pan02 Obscn TTGGTTAAATTGGCCTCTCC 22547 Hepal -6 Ceacam3 GCTGTGATGACCTCACTCTG 16564 Pan02 Obscn TAGAATGTGGTACAGGCGAC 22548 Hepal -6 Ceacam3 GGCAGCACAGAGAATGGAAA 16565 Pan02 Obscn CTTGAGTGGGTTGGGAGTGG 22549 Hepal -6 Dnahl 1 AAATGCTCAATGTTTAACTG 16566 Pan02 Usp28 GCTCCTCCCACGGCGTTCGC 22550 Hepal -6 Dnahl 1 TCCTGCTAAATTTGCCGCCA 16567 Pan02 Usp28 CTCCGGCGCAAGCCGCAAGA 22551 Hepal -6 Dnahl 1 TTATCTAATCCCTAGAAAGC 16568 Pan02 Usp28 CCACCCACAGCACGCGGCAG 22552 Hepal -6 Ifnl2 TGTGACACAGAAACAGCTGG 16569 Pan02 Herc2 TGAGAGACGGCTTCAGCCAA 22553 Hepal-6 Ifnl2 TGGTTCTTGCTTGGTGTCTC 16570 Pan02 Herc2 TGCGCCCGCCCAATAGCGCA 22554 Hepal -6 I 2 TTAGAGTGAGATGTGTAGCA 16571 Pan02 Herc2 TGAGCGGGTGAGTCTCAAGA 22555 Hepal-6 Cdl09 CTCAGTTCACATAGCTGCCC 16572 Pan02 P 3 ACGAAATCCGTAGTTCCTGT 22556 Hepal-6 Cdl09 TTATTCACTCCGGGCATCCC 16573 Pan02 P 3 CGCCACACCTCTCGTCTGAG 22557 Hepal-6 Cdl09 GTTTACTCTAGCGCTCTACC 16574 Pan02 P 3 CGCTACAATCAGCGGATCCG 22558 Hepal -6 Serpina5 GATGACACCAGTCTCTTCAG 16575 Pan02 Abcc6 TGAGTTCTGAAGGCTGCTCT 22559 Hepal -6 Serpina5 CTGGAGCCTTGAACTTGTTA 16576 Pan02 Abcc6 GGGACCAGGCAGGTTTGACA 22560 Hepal -6 Serpina5 TCTTTGTCTAAGAATGTGCT 16577 Pan02 Abcc6 GGAITGGAGCTGGATAGCGG 22561 Hepal-6 Cede 14 GAGTCTGTTGCGCACGCCCA 16578 Pan02 Zfpml CTACCGCGGAGGACGGTCCG 22562 Hepal-6 Cede 14 GCGTGGCAAGCTGGAGCACG 16579 Pan02 Zfpml GGAAGGACGGCCTGAGGGCG 22563 Hepal-6 Cede 14 CTTTGCAGCATTCTTCAAAC 16580 Pan02 Zfpml GGCCTTCGCGTAGCTGGCGG 22564 Hepal-6 Tniem232 GTACACGCGAGGTGCGGGTG 16581 Pan02 Zfp92 CTGAAGCAGTCTGATTGCAG 22565 Hepal-6 Tniem232 CGGTCGTCTTAAGCCAACGA 16582 Pan02 Zfp92 TGAGACCAGACGCCTAAGTG 22566 Hepal-6 Tmeni232 GTGGAATGACAGCTTGTGAT 16583 Pan02 Zfp92 GGAAGTGTCCCGGGTTCATG 22567 Hepal -6 Torlaip2 GCCCTTTGGGCGCGCACTCC 16584 Pan02 Igfbp7 AAGGGTTGGCCTCCGGGACC 22568 Hepal -6 T l aip2 ACAACCTTCGCTCTCGACCA 16585 Pan02 Igfbp7 TCAGCACGCATGGTGGACGT 22569 v > Hepal -6 Torlaip2 TCTAGGTCTCCTCTTTCTGT 16586 Pan02 Igfbp7 CTCCCACGGAGCACCGGGCG 22570 o Hepal-6 4930503L19Rik TTTCTCTGGGTCGGGTAGGA 16587 Pan02 Fat3 GATTAATTCAGAAGAAAGTG 22571 Hepal-6 4930503L19Rik GGCGTTAGGTCGCCGTCCTC 16588 Pan02 Fat3 CTCTGTGTTTACTTCCAGGA 22572 90 Hepal-6 4930503L19Rik TACACATGCGCCCTGCGGCC 16589 Pan02 Fat3 ATCATATCACATGTCCGTCC 22573 Hepal -6 Map2 CGGGCTCTCGGCGGTGGAGG 16590 Pan02 St8sia6 ACTGTTGCAGGCTGGGCTCT 22574 90 6/1 Hepal -6 Map2 ACCGTGGCGGAGCCAGGCTG 16591 Pan02 St8sia6 CGAGCCGAAGAAGCCGCGTT 22575 0 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Map2 GCGACGGTGGCAGCTTAGCG 16592 Pan02 St8sia6 CCACCGCCTTTGAACGCTGG 22576 Hepal-6 Oog3 TCTGAATATGAGCAAGTGGG 16593 Ctrl_200 01frl387 CTCTTCAGTTAGGAGATCAC 22577 Hepal-6 Oog3 ATTATATAAAGGGTCATAGC 16594 Ctrl_200 01fr828 AGTTTAAATCATACTTCAGG 22578 Hepal-6 Oog3 AGAGGCCTACTTTGGCTTGG 16595 Ctrl_200 Plppr2 ACACACACACAGTTTGCATA 22579 Hepal-6 Pnma2 AACGCAGGATCAGGAGGGAG 16596 Ctrl_200 Olfrl037 TAGAAACCTATTGGGCTGTG 22580 Hepal-6 Pnma2 TGCCAGTTCCCGGCAACGCG 16597 Ctrl_200 Ccdc89 TCTATAGAAACAATTCGCCA 22581 Hepal-6 Pnma2 GATCCAACTTTGCTCGGAGG 16598 Ctrl_200 Map3k20 ACAGCAGGGAAGGCAATGTC 22582 Hepal-6 Gcntl GCAAACTGTGTGTGCAGCAA 16599 Ctrl_200 OLfr924 ATACTTGGATTCATGATTGA 22583 Hepal-6 Gcntl ATCCTCCTGAGTCTTGCATT 16600 Ctrl 200 Ccdc43 GCGTGGTCGCATGGGCACCC 22584 Hepal-6 Gcntl GGTTGAGGTCTGATGAGAAA 16601 Ctrl_200 1700012A03Rik ATCAAGAGTTGACTGAAGAC 22585 Hepal-6 n c l ATTCACCACAAGCACAGCAA 16602 Ctrl_200 AC109138.1 CATCAGATCCCAACACCCTC 22586 Hepal-6 Kndcl TCCTTGGCTGGGTCCAGTGA 16603 Ctrl_200 J nb AGGCGGCTCGCGTCACTGTC 22587 Hepal-6 Kndcl GTACTGGGTTCTTTAGCTCC 16604 Ctrl_200 Prr3 TGGCGACCTTAGGATGCGAC 22588 Hepal-6 Carf GGACAATTAATGACGGTTTA 16605 Ctrl_200 Vmnlr85 AATATACTGACTGACACITC 22589 Hepal-6 Carf CACATGGTCTCGGCCGAATT 16606 Ctrl_200 Ckb CGCGGACCAATGGAATGAAT 22590 Hepal-6 Carf TTCTTTATTCTGAGTGACAA 16607 Ctrl_200 Trapla CAGACACCCAATGAGTGATC 22591 Hepal-6 Tnfrsflb GAAAGCGAAACCCTCAGGCC 16608 Ctrl_200 Fut2 TGACAGAGGTTGAGGCTCTT 22592 Hepal-6 Tnfrsflb TTCATTCCCGGAAGAGATGC 16609 Ctrl_200 D030056L22Rik GGCCGGAAGTGCGCCCTCTG 22593 Hepal-6 Tnfrsflb AGAGGCGTGTCCTCAGGGCG 16610 Ctrl_200 f r2 2 TTCTAAGAGTCTTTGTACTC 22594 Hepal-6 Akrlc20 TTACAAGGACATCTAGGACA 16611 Ctrl_200 Rtn4rll GGACCGAGCGATCCGCCGAG 22595 Hepal-6 Akrlc20 ACTGAGCTGGCTTCTTTCAC 16612 Ctrl_200 Fndc9 ATGAATAATGTGAGCGTTGG 22596 Hepal-6 Akrlc20 TTTCTTCTGTCAAACTGCCT 16613 Ctrl_200 Mtl AGCGATAGGCCGTAATATCG 22597 Hepal-6 Pnliprpl TGTGTATTTACACATGAGCT 16614 Ctrl_200 Rliox2a GCAACAGGAGTACAACCAGA 22598 Hepal-6 Pnliprpl GGCAGATCTTCCCACAAGCC 16615 Ctrl_200 Ddx3y AGCCACTATTTAACTGCCGG 22599 Hepal-6 Pnliprpl AGTTGAAGGACTGATTTAAG 16616 Ctrl_200 Nanp ATAGGGTGCGCGTGCACGAG 22600 Hepal-6 4933427D14Rik GATCATGTCTCTGTAGTCTT 16617 Ctrl_200 Gprl37 GGCGCCCGGCCCTAGTTTCC 22601 Hepal-6 4933427D14Rik ATAATCCAAAGTTTACAGAC 16618 Ctrl_200 Dapll ACAGGACAGAGTGAGGTCTG 22602 Hepal-6 4933427D14Rik GAAATCAATTGGGAAGTTCA 16619 Ctrl_200 Adra2a CCTGCTGGGAGTTGGCCGTT 22603 Hepal-6 Dhx34 CTTCATTGTACGGAGAGGCC 16620 Ctrl_200 1119 ACCAACTTCCCTTGCCAGTG 22604 Hepal-6 Dhx34 GGTGATTTGACGCCCTCTAG 16621 Ctrl_200 Vmn2rl05 TTCTCTCACTGCTGCAGCTG 22605 Hepal-6 Dhx34 AGGCGCAGACCATTTAGGAC 16622 Ctrl_200 Vmnlr41 AGATGCTCCAGTGGGTTGCC 22606 Hepal-6 Helz2 GAGGCTATCACTTGAGGGCG 16623 Ctrl_200 4930453H23Rik GGTTTCCATGGTGCTCATTG 22607 Hepal-6 Helz2 GGGAAATCTTCCTAGGGCCA 16624 Ctrl_200 Dusp2 AGTCCCACGTGAAGCCGCGG 22608 Hepal-6 Helz2 CCTGCTGTGTTGACCTCAAG 16625 Ctrl_200 Hoxc5 GGAGCGGCCACTCATAAATT 22609 Hepal-6 Abi3bp TGGGCGTCCTCCACTGACAG 16626 Ctrl_200 Prl3 l ATACTAACAGATTCTCTCCA 22610 Hepal-6 Abi3bp AGCTGTTGCAGCATTGGAGA 16627 Ctrl_200 Gml3288 ACAGAAGCCCTCCCTGTGGG 2261 1 Hepal-6 Abi3bp GGAGGCTGCTCTCTCTGCTG 16628 Ctrl_200 Apcddl AGGAGTAGGAGGAGATATCA 22612 Hepal-6 Zscan26 ATCACTAGAATAACAAAGCT 16629 Ctrl_200 Cptlb CACAAGGTTGCTGGAAGGTC 22613 Hepal-6 Zscan26 CCATCGTCCTAGAGCGGAGC 16630 Ctrl_200 Ssmeml TAGGGAGTGGCGCGAGTCCA 22614 Hepal-6 Zscan26 CTTTCAACTTAGACCCAGTC 16631 Ctrl_200 Gm5741 AGCAGCCACTGGGCCTCCTG 22615 Hepal-6 Zkscan8 AAGCTCTCTAGGAAGCTCGG 16632 Ctrl_200 01frl317 TACAGAATCACAGAGAGATG 22616 Hepal-6 Zkscan8 CTCTATGGTAGGCCAGCAAA 16633 Ctrl_200 Olfrl030 AGCTCACTAAGTTACAAATA 22617 Hepal-6 Zkscan8 CGAGCGCCCTCAGCTACACC 16634 Ctrl_200 D5Ertd577e TAACTAAGGGCTGCTGAGTG 22618 Hepal-6 Rad51apl GGATCCAGGATGGCGTGCCC 16635 Ctrl_200 803041 lF24Rik TATGGATGTTTGTCATGCCA 2261 Hepal-6 Rad51apl TGCGCACACACACCGTGGCC 16636 Ctrl_200 Gml0142 TATGATTAACCACGAAGCCA 22620 Hepal-6 Rad51apl GCGCCCTCTCTTCAGCACGC 16637 Ctrl_200 Vmnlr211 TCTTGATCATTTCTTCCAAA 22621 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Rasgrp4 TAGATAGCGAACCCGCTGAG 16638 Ctrl_200 AGAATTTCCTCTCTTGCACA 22622 Hepal-6 Rasgrp4 TCCCTGCCTGCTGAGGTTTC 16639 Ctrl_200 ATGATAGTGAGTATGTGTGT 22623 Hepal-6 Rasgrp4 TGCGTGCGTGACAGAGACGG 16640 Ctrl_200 CGCGCCTGCGGTCAGTACCG 22624 Hepal-6 Pfkp GTATGGACACGCGTTCTGTT 16641 Ctrl_200 TTTCTCGGTTCGGGCTCTGT 22625 Hepal-6 Pfkp GCTGGAGTCTTTGACACAAC 16642 Ctrl_200 TGCTCGCTCACTGAAGACTC 22626 Hepal-6 Pfkp CGATGGGCGGGACTCACGCA 16643 Ctrl_200 GTTTAGCTGCCTAGAAACAG 22627 Hepal-6 Fatl ACTCATAGTCAGTGTGGGTG 16644 Ctrl_200 CTAGCTCTAGTTGTGTTGCT 22628 Hepal-6 Fatl TTCTTCTATTACAGGTGGCC 16645 Ctrl_200 TAGACCCGGAATCTGAACCC 22629 Hepal-6 Fatl AAAGAGTGTCACTTGCTGGA 16646 Ctrl 200 TGGTTAAGGAAGTAACATGA 22630 Hepal-6 Adam6a GGGATGTCTATAAATGTGCC 16647 Ctrl_200 GGACAGGCACCAATTCACAC 2263 1 Hepal-6 Adam6a TGGAGTTAGGTAACAGTCAC 16648 Ctrl_200 AAGCAACCCGCAGTGCCTTG 22632 Hepal-6 Haus5 AGCCGCTACGGGTAGCGGCC 16649 Ctrl 200 GGGCGTAGACTGGGCGGGTG 22633 Hepal-6 Haus5 AAGAACAAAGGTGGATAAGC 16650 Ctrl_200 CTTCATTGTTAGACTTCACA 22634 Hepal-6 Haus5 GCGCGACGCTGAGATGTCAC 16651 Ctrl_200 GCAAGCGCTCCTTGTAGCGT 22635 Hepal-6 Sgoll GAGTGTCACGTGATGGTGTC 16652 Ctrl_200 TATAGGGTTGAGTCTCAAGA 22636 Hepal-6 Sgoll GTCTACGGAGAAGGGCGGGC 16653 Ctrl_200 GCTGCCTCAGTGCTGACTTG 22637 Hepal-6 Sgoll TCGCTAGATCTCTAGGCTGT 16654 Ctrl 200 CCTGAGGTTAACCAAGCAGA 22638 Hepal-6 Ptprq GTATAAATTTCAGCACCCAG 16655 Ctrl_200 GGTCGGAGAGGCCAGCCGTG 22639 Hepal-6 Ptprq ACTCTTGGATGGATGGCTGT 16656 Ctrl_200 TGGACAACTTGAACAATTTC 22640 Hepal-6 Myrip GCCGCAGTCACAGCGGGAGC 16657 Ctrl_200 TTTGTTCTTCAGATTGGGAG 22641 Hepal-6 Myrip CCTGTGATTGGCGGTCAGCG 16658 Ctrl_200 TGCCATTGGTCGCATGGCCC 22642 Hepal-6 Myrip GATCGCCGGTGCGCCCGAGC 16659 Ctrl_200 ATATCTGGAGGTAGCTGCTC 22643 Hepal-6 Hspbapl AGACGCTAAGGGTGGAAGAA 16660 Ctrl_200 AAACCCGGGCCCGGAAATAG 22644 Hepal-6 Hspbapl GCGCCGCCGCGGTCACGTGA 16661 Ctrl_200 TAAATGGTTTCAAGCGGCTC 22645 Hepal-6 Hspbapl GGCGCTGGGCGTGGCCACGC 16662 Ctrl_200 GTGTCCAGTACATATATGCT 22646 Hepal-6 D x57 AGGAACCTCTGCCATTGATC 16663 Ctrl_200 TGCGAATGACTCAGAGCATT 22647 Hepal-6 Dhx57 CTTACTTCACTGTATTACAT 16664 Ctrl_200 CCTGAATTGTGATCATGGCC 22648 Hepal-6 D x CGTTTCCACATTCAAATTTC 16665 Ctrl_200 GTGTTGCGCAAAGAGGCCGG 22649 Hepal-6 Col5a3 GAGATCAGGGCCATTCTTGC 16666 Ctrl_200 GGACTATCTGGCCAGTCGAG 22650 Hepal-6 Col5a3 AGTGTGCACCACGCGCTGAT 16667 Ctrl_200 TCTGATCCAGATCCACCGCT 22651 Hepal-6 Col5a3 TCTAGAGCCCTTGCCGGGCG 16668 Ctrl_200 GCGGTGAAGGGCGAAACTTG 22652 Hepal-6 Clca4a ATATTGTGTCTCAAGAAGAA 16669 Ctrl_200 TCACATCTCGACCACATCTG 22653 Hepal-6 Clca4a TGTATAGGATACACATAGCC 16670 Ctrl_200 TTGAAGTGCATCACCTAAGA 22654 Hepal-6 Clca4a TGAGCTAACAGGTGATGTTT 16671 Ctrl_200 CGCGTGCCGAACTAGAACTG 22655 Hepal-6 Zfp607b AGAGAGAAGGGCACCATCCC 16672 Ctrl_200 CACACAAGACAGACACACTC 22656 Hepal-6 Zfp607b ACAACTCCCAGGCGGCATCG 16673 Ctrl_200 TAGGCATCCCGGCGGCCGGC 22657 Hepal-6 Zfp607b TGTGCTTTGTGGGAGTTCCC 16674 Ctrl_200 AAACCTCTCGTGGGCGGGCT 22658 Hepal-6 Cagel GTCCGGAGGACGTCACACTG 16675 Ctrl_200 GTCATGGTGAGAACAGTAAG 22659 Hepal-6 Cagel TCCTATGACCGTAAACGCCA 16676 Ctrl_200 AGTAACTGGCAAAGCATGAA 22660 Hepal-6 Cagel GTGGAGCAAGAACGAAAGGC 16677 Ctrl_200 GTGTATGTAGACCGGGAAGG 22661 Hepal-6 Abca4 GTTTCTTTATAGACGGAGAA 16678 Ctrl_200 GTAGCITGTGGGTGGATCTG 22662 Hepal-6 Abca4 GGCTTACAGGTAATTAGAGG 16679 Ctrl_200 CGGAAAGCTGAGATTGAGGG 22663 Hepal-6 Abca4 GGCCCTAAATACACAAGTGC 16680 Ctrl_200 GGCAGGTCACTTGCAGTGCT 22664 Hepal-6 Zfp30 CTCTCTTGCAACCCAACGTT 16681 Ctrl_200 ATGGGAGTGCATTGCTTTCT 22665 Hepal-6 Zfp30 TGGCATACACCTGACTTCTC 16682 Ctrl_200 CAAAGGTCACTCTCTTGAGT 22666 Hepal-6 Zfp30 CTTCCAAGCTTCAGGGCTCC 16683 Ctrl_200 GGGCGCGTCGTGGAGGAGCC 22667 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Cyp3a57 TTGACAAATGTCAGGTGGAG 16684 Ctrl 200 01frl484 CCTAAAGAGAGTTACTTACC 22668 Hepal-6 Cyp a 7 CACTTACACACTGCCCAAAC 16685 Ctrl_200 Gm826 CTCATCAGCCTGCTATAAAT 22669 Hepal-6 Cyp 7 ACAGGGATATAGCCTGTACA 16686 Ctrl_200 H2afbl GCCTCAGAGTGCGATGTCAC 22670 Hepal-6 Tmeml32c GGGCGGGATCAGCAGGACCG 16687 Ctrl_200 Aupl GTCCTCTAGAACCCGGCAAG 22671 Hepal-6 Tmeml32c ATCCGGAGGGTGTAGTGGGC 16688 Ctrl_200 Cnotll TTTGCGACGCTGTCGCGGAA 22672 Hepal-6 Tmeml32c CCCGCTCGCGGCCAGAGGGA 16689 Ctrl_200 Olfr308 CTGGACITTAAGTTTCAGTG 22673 Hepal-6 Ms4a4b GGAGGAAATGTCAGAGGCAA 16690 Ctrl_200 Fthll7b CACGACAGGGTTTAAGTCCC 22674 Hepal-6 Ms4a4b TCTGCCTCTTAGTCAGTGGG 16691 Ctrl_200 Gml28 GTCTGTGCCTAGGGACCAAC 22675 Hepal-6 Ms4a4b TATGATGGCTGAGATGGGTG 16692 Ctrl 200 Hus lb CCCAAATGCAGGCAGTGCTG 22676 Hepal-6 Masp2 ATCCTTGGTTTGTGGAGGTG 16693 Ctrl_200 Anapcl3 TGCCCGCCGTTCCTCCGGCC 22677 Hepal-6 Masp2 ACCGAACCTTCCTGCCTGGA 16694 Ctrl_200 Mtpap TGGAGTAGCAACACTTCACC 22678 Hepal-6 Masp2 GTGGGACCAGGAAGGTCTGG 16695 Ctrl_200 Polh CGCGCGGAAGTGGCCGCTTC 22679 Hepal-6 Vezt CCAATAAGCAGGTCGGAAAG 16696 Ctrl_200 Slc22a7 GAGAACAGGTAGCAGAGCCA 22680 Hepal-6 Vezt CGTGGGTCGCGATGCATGCC 16697 Ctrl_200 Olfr805 TAAACTTACTAAGGATATGG 22681 Hepal-6 Vezt GGGCGTTCCAGAGCTCCTAT 16698 Ctrl_200 Pacsin3 TCTGTATGGCTAACCCTAGT 22682 Hepal-6 Famll4a2 TCGCCGTCGAGGAGTACTTC 16699 Ctrl_200 Dnajc22 GGGAAAGCTTCCCGTAGAGA 22683 Hepal-6 Fanil 14a2 GGGTCAAGCATCCTCTAGGG 16700 Ctrl 200 01frl463 AGTCACTGAAGTAACTTGAT 22684 Hepal-6 Famll4a2 GGTGGCTTCCTGAGAGGTAA 16701 Ctrl_200 AF529169 GATGATGGAGAGGCTAAACT 22685 Hepal-6 Tdrd6 GGCTGCCTGCCTTCTCGGCG 16702 Ctrl_200 Zfy2 ATTGACCAATCAAGGCTGAG 22686 Hepal-6 Tdrd6 GGACTACCAGCAAGCCTGTG 16703 Ctrl_200 Hc rl GAGGACGGGTAGTCAGGCAA 22687 Hepal-6 Tdrd6 TCGCAGGCTCAGATAGCGCG 16704 Ctrl_200 Btg2 GAGCCGTCGGTGGCGCCCAT 22688 Hepal-6 Eif2ak2 ACTGCAGTTGCACAGGAGAG 16705 Ctrl_200 Gml4597 CAGCATTCAGAGAACATTCC 22689 Hepal-6 Eif2ak2 ACGCCTACCTGACTTCTCGC 16706 Ctrl_200 Rsgl CTGATGAAGCCTCCTTTCTG 22690 Hepal-6 Eif2ak2 CTGCCAGCTTCTCCAGGTTT 16707 Ctrl_200 Srsf4 GGGCTTTACTGGAGGCGCGC 22691 Hepal-6 Tor3a CTCTGGTCTGAATCGAAACT 16708 Ctrl_200 Defb45 GAATAAAGGAGTGTCAGCCT 22692 Hepal-6 Tor3a GACTGAGCAACCCATCCTAA 16709 Ctrl_200 T 2d CCCTTCACTGCTGCACGGAG 22693 Hepal-6 Tor3a GTTTGAGTTTCATTTCGGAT 16710 Ctrl_200 Siglecg AAATITGAACATCAGCCAGG 22694 Hepal-6 Gp TGCCTGCTCTTGTGTCACTG 16711 Ctrl_200 Ermard ACCAGCGCGAAACTGAGTTT 22695 Hepal-6 Gp GAGCTCTCAGTCAACTTTCC 16712 Ctrl_200 Rabl9 CCTCTTGTCTTGCAGCGCAG 22696 Hepal-6 Gp GTGTTGGATAGTTCATGTCA 16713 Ctrl_200 Polr21 CAGGGTAATCATGGGAGCCG 22697 Hepal-6 Lefty 1 CTGTCTGGACTGAGAACATC 16714 Ctrl_200 Pcbdl TGCCCTGTGCTCTGTGAGCA 22698 Hepal-6 Lefty 1 GAGCTCCCAGGAGGTCCCAG 16715 Ctrl_200 Tmem27 TCAGCGAGCCACCATCTAAA 22699 Hepal-6 Lefty 1 GTACGGAACAGCTTTATAGC 16716 Ctrl 200 Gm5111 GTACCTCAGGTTTCCTGCAG 22700 Hepal-6 Zfp386 CATCAGATAGCACCAACCCA 16717 Ctrl_200 01fr6 TAAGATCCATGAGAGTACCA 22701 Hepal-6 Zfp386 CTTGCCTTTCGGACCTCATT 16718 Ctrl_200 Pcedla TGGACTGTTACACTGCGAAC 22702 Hepal-6 Zfp386 CTTCGACGGATTTAGTTTCC 16719 Ctrl_200 Gprl ATCTTCTAACTCAACTGCCC 22703 Hepal-6 Mt GTTGGTCGTTACCCAATCGC 16720 Ctrl_200 Acp5 TGGTATTGAAATCAGGTCCC 22704 Hepal-6 Mtr GGGCCACGGAGCAAAGCCTC 16721 Ctrl_200 Aqpl GAGGCAACCGTTGCTCTAAT 22705 Hepal-6 Mtr CGGCGGCGAGGAGCTGTTGA 16722 Ctrl_200 0 1 l 95 CTATATCTTTGTGATTCCAG 22706 Hepal-6 Zkscanl6 ATTATCTGGCCTGTTGCGCA 16723 Ctrl_200 Defa28 TGATACCGATAATCATGAAG 22707 Hepal-6 Zkscanl6 AAATCCAGGCCAGCGGACCC 16724 Ctrl_200 Serpina6 ATCCTAGCACACGTACAGTA 22708 Hepal-6 Zkscanl6 GAAACTCCAGTGCTTTCCAT 16725 Ctrl_200 1810009A15Rik TTTATATGCGAGGGAACTAC 22709 Hepal-6 Gli3 GCGCGAGGGAAGAAGGAGCC 16726 Ctrl_200 Olfrl402 TCTGGATAGTGGTCACCTGC 22710 Hepal-6 Gli3 TCAGACTCTGCTCTCCTTCC 16727 Ctrl_200 Fatal 18a CCAATCGTAGCTTCTCTTGG 2271 1 Hepal-6 Gli3 TGGCGGAAATTAGAGGGACG 16728 Ctrl_200 Patj GGCCGGAGGCCTTTGCGTCC 22712 Hepal-6 Slc22a29 ACAATTCCCATGGTCAACTA 16729 Ctrl_200 Atp6vlg3 GATCAAAGAGTTGGATGCCA 22713 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

AGTGAGCTAAATGTTAGGTA 16730 Ctrl_200 C t GCTCTTCGCTGATGCGGCTG 22714 TAACTTCCGCTGCAGGTGGG 16731 Ctrl_200 Lynxl GCACTGCGGATCTGTTGCCC 22715 GTTCATGACCCTCCCATCCC 16732 Ctrl_200 HEallm ATGTGCTCCTGTGTCCTGTG 22716 o CTCCATGGCACTTCCGCTCG 16733 Ctrl_200 Dyne i1 TGCAGCAGCGCCCTGCTCCT 22717 CGTTTGTTCAGCTAGCTTAC 16734 Ctrl_200 Krt87 CTTCGTGGCACCATAAAGCC 22718 TCTCGTGTGTGTGACCACGT 16735 Ctrl_200 Hrh2 AACGAGGAGGAGCGAGTTGG 22719 AACGGAATCAGCTTACCACC 16736 Ctrl_200 C87436 CTGGTGTGTTCTGTACGTTT 22720 o 4 GGCAGGACACTGCTACCCTC 16737 Ctrl_200 Sh3kbpl CTCCCACTACACACTCAGGC 22721 CTGTCCCTACATTGTTCTCC 16738 Ctrl 200 Gmll992 CGCGTGTGCCCGGAGCCAAT 22722 CACAATAAAGGAACTITGCC 16739 Ctrl_200 Epm2aipl TCACGGTCCGCTCTTCCTAT 22723 TCTGTGTGGCTGACGTGGCA 16740 Ctrl_200 Mrln TTGAAGTCAAGCAAGCCGCT 22724 AAGTACAGTGGAGCTACAGC 16741 Ctrl_200 01frl259 ACTAGGTTTCATCTGTGACT 22725 TTTGGGACAGTCCCACTAAA 16742 Ctrl_200 Zfp710 TTTCTCTTTCTACCGCAGAG 22726 TAAGTGGCTACATGGGATAG 16743 Ctrl_200 Hba-al TAAGGATTCCCTGCACCCAG 22727 TACAATCAACTGACGGCTAC 16744 Ctrl_200 Tmeml47 CTGCACGCGACGTACCAGGC 22728 TAGAGAAATGTTTCCCACAG 16745 Ctrl_200 Cmal GTTATAGATCCCTAGAATCT 22729 CTGTCTTATGCTAAAGAAGG 16746 Ctrl 200 01fr698 AAAGTATAGGAAGCCATGTT 22730 CACAGGAAGTGGTGACTTGT 16747 Ctrl_200 Fabpl2 GCACGGAAATCCTCTAACCC 2273 1 GAGAGCAGCGGTTCAACAGC 16748 Ctrl_200 Neur CGCAGTGGCAAAGCTGGACC 22732 AGCTGTTTGCGGCGACGATC 16749 Ctrl_200 01fr792 TCATTTCACAATTACAGACC 22733 AATCTAGTGCGCATGCTCTT 16750 Ctrl_200 Vprebl ACTACAGATCTGCTTATTTG 22734 CCTTCCGATTGGGCGGCGGT 16751 Ctrl_200 Shisa8 TGCAGCAAGCGCGCCCGACC 22735 CTCTGGCGCCTTCACGGGCC 16752 Ctrl_200 Kcnjl ACATGACAAACCACCAGCTG 22736 GCACCGCGCAAGTGCGTTCC 16753 Ctrl_200 01*437 TCCTCTTATTrCACACTTCC 22737 AGCTGTCTCGGCGGGCGCGC 16754 Ctrl_200 Mog AAAGAGAAATGCCCAGTACC 22738 TCTGAATATGAGCAAGTGGT 16755 Ctrl_200 01*1497 ACAGCAAAGTTTGCAGACTA 22739 ATAAAGGGTCATACAGGTAG 16756 Ctrl_200 01*117 TTGAGAGACATGGACCCTAA 22740 TTTGGATCAGATCTGTACTC 16757 Ctrl_200 Pgls TCTCGCCCAGGGAAGCGCCG 22741 AGGACACTGCTGGACCCGTG 16758 Ctrl_200 01*134 GGCTATAACTATAGAAACCA 22742 GGATTAGCATGTGCAGAATC 16759 Ctrl_200 F a ACGCTGCGCCTAGCCCACAA 22743 ACTAGATGGGCCGGGTGCAA 16760 Ctrl_200 Nipal4 GGAGGAGTCACCCTGTGCCT 22744 CACACGGACAGAGGCACAAC 16761 Ctrl_200 Pnck CAAGGCTCTCTGCAGTGCTG 22745 TCTGCCAAGTTGAAGGTGAG 16762 Ctrl_200 Tmem210 GGGACAGGGTTGGTAAACCC 22746 AAACAGGAAAGCTATTGGTT 16763 Ctrl_200 Mesp2 GTAGATGGCTGCTGGGTACC 22747 CGATGTTTCCGGCTCTGCCA 16764 Ctrl_200 S y TTAAGATATCATGTGGCTGT 22748 ACCTTCCCGATGACCTTGAG 16765 Ctrl_200 Twist2 TTTGGAAACTCTATCCCGGC 22749 CACGCAACCCTAGCGACGAT 16766 Ctrl_200 Asbl2 TTATCTTGCCAGTGACATTC 22750 GGGTCTCCCGCAGACTCAGT 16767 Ctrl_200 Atad2b CGCAGCCCTTCCTTCTGCAC 22751 n CCGAGAGTGCCACGTCTAGC 16768 Ctrl_200 Ndufbll CTTGCCAATCAGAGAATGCC 22752 GGGTAGCGGAATCCAGAGGC 16769 Ctrl_200 01*1161 AAGAAGAGAATGAGGGAAAT 22753 n AGAACATACATTTGGAAACA 16770 Ctrl_200 Tas2rl36 AAAGCATCCCTGTGTGCTAA 22754 o CCCGCGGGTGACCTAGATTG 16771 Ctrl_200 01fr854 ATCCCTGAAGTCTGAAGTTA 22755 AGGATCCAGCCGAGGACCCT 16772 Ctrl_200 Sco2 ACCTACTGGAGGCACGTGCC 22756 TGTCGAAGTCGGTCCCACCC 16773 Ctrl_200 Cmtm5 GGAAGAAACCAGAGGAATTG 22757 GAGCGCTCAGACGGAAGGTG 16774 Ctrl_200 Citxlb TGTCAATTACAAGGCGTCGC 22758 J CCGAGGCTCCCGGCTCAGGT 16775 Ctrl_200 01*1331 TCAGGTGTTACATATATGGC 22759 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Fbxo43 GCTGCGAAGGGATGAGGGCG 16776 Ctr OO ACTTGGAGGCGCCGGGCGTG 22760 Hepal-6 Nup210 GGGCGAGCGCAGTGATGGGC 16777 Ctrl_200 ACGACCTGCGCCGGGAATCC 22761 Hepal-6 N p 0 CAGGATTCGGCGCGCTCTAG 1677S Ctrl_200 AGGCGGCGCTGCCCGACGGG 22762 Hepal-6 N p2 0 ACCGGCGCGCGCTGGGTAGC 16779 Ctrl_200 CGGGCAGAGCTTGACCGGAG 22763 Hepal-6 Zkscan5 AGCTCGTACTTGGTTACTTC 16780 Ctrl_200 GACAACGACAACGACAATGT 22764 Hepal-6 Zkscan5 GACCTCCGGGATTCCTAGAG 16781 Ctrl_200 CCAAGCACTAACGAGTCACA 22765 Hepal-6 Zkscan5 GATTGGTCAGCTCCACAAGG 16782 Ctrl_200 TCAAGTGAGGAATGTGGGCA 22766 Hepal-6 Mgarp CTCTATTAGAGCTGGGTAAG 16783 Ctrl_200 GTCTGTATTGCAGGGCTACT 22767 Hepal-6 Mgarp CAGCCATTAAGCGACTGCTG 16784 Ctrl 200 GCAGAGTAACTTCACCACAA 22768 Hepal-6 Mgarp CGAGTTAGTGGTTAGCACCT 16785 Ctrl_200 TAAAGGACTTAGAGTATCTT 22769 Hepal-6 Prrc2c TTCGTCAAGCAGAGCCATTT 16786 Ctrl_200 CCCTGCTACTCACAGGAACC 22770 Hepal-6 Prrc2c AGGGCAACGCTACCTCCTAC 16787 CtrlJOO GGCCGAGCGCCTCCGACGTC 22771 Hepal-6 Prrc2c CCTCCGCCGCTTCTCGACTG 16788 Ctrl_200 TCCCAGACCGTGCGGTGCAG 22772 Hepal-6 Cep97 TAGATAAACCATTTCACTCC 16789 Ctrl_200 GGGTGACTGACGGCCCGGTT 22773 Hepal-6 Cep97 GAGGTAAAGCTTAGAAGACC 16790 Ctrl_200 CATCATAGCTTCAGAGACAA 22774 Hepal-6 Cep97 TCAACTITAGGTGTCAACCC 16791 Ctrl_200 GCACTCCGGAGAGACTATGA 22775 Hepal-6 Zfp235 TTTGGGAGCTCGCTCACCGG 16792 Ctr OO TGCGGTTTAGCGGAAGGATC 22776 Hepal-6 Zfp235 CAATTCCCAGAATGCGTCAG 16793 Ctrl_1000 GAACTGGAGAGGACCGCGAG 22777 Hepal-6 Zfp235 ATGGAGGCTTTAGTAGTCTG 16794 Ctrl_1000 GAGCGGAGTGGCAACGTAAC 22778 Hepal-6 Tnfaip3 CGCTGAGAGAGAGACAAACT 16795 Ctrl_1000 ATTATGAGGTCATTGCCAAG 22779 Hepal-6 Tnfaip3 AGATTAGTCTAAACAAGAGA 16796 Ctrl 1000 AACCCGAGGCTGGAGGGTGG 22780 Hepal-6 Tnfaip3 GAAGGCGGAGCGTGGTACTG 16797 CtrlJOOO TGAGAGGTGTACTCGCAGGG 22781 Hepal-6 Nptis2 GAAGGAACAGCAATTTGGTT 16798 Ctrl_1000 TGGCTCTGAGCGGTCCACGT 22782 o o Hepal-6 Nptis2 ACAGGATGCAATGCTCTCAG 16799 Ctrl_1000 GCTGGCCACCACACATACAT 22783 Hepal-6 Nphs2 GCAAGGTCCTTAGGGCCTTG 16800 Ctrl_1000 TTCACTCAGAGTTAAAGAAA 22784 Hepal-6 Gml3023 AAAGGGAGGGTTCAGCGGAA 16801 Ctrl_1000 TGGAAGAGTGCTGGCAGCAC 22785 Hepal-6 Gml3023 GGTGAATGGAGACTCAATGA 16802 CtrlJOOO CTTTCTCCTGCTGATCTGCC 22786 Hepal-6 Gml3023 AGCCTCAATTATTGAACCAG 16803 Ctrl lOOO CAGAGTCTATGACGCTACTC 22787 Hepal-6 Zscanl2 ACGCGAAACCGGATAAGGAC 16804 CtrlJOOO ACATGGTGGCAGAAATAGAG 22788 Hepal-6 Zscanl2 CAACAGGGCTCCACCGCTTC 16805 Ctrl_1000 CATTGGCTGGCGGGCCGACT 22789 Hepal-6 Zscanl2 TCTAATCATAGTGAGCATGC 16806 Ctrl_1000 AATGCAGTAGAAAGAAATTG 22790 Hepal-6 Akrlc21 ACACAGATTATATAATAGCC 16807 Ctrl_1000 ACAAGGCTTTGCTGCCCATT 22791 Hepal-6 Akrlc21 TAAAGCTAACTTAAGCTAAC 16808 Ctrl 1000 GGGAGGTCGCGGCCAGGTCA 22792 Hepal-6 Pnplal AGGATGGCTTTGGCTTTCAA 16809 Ctrl 1000 CGCTTCCCATTGGGTGTGGG 22793 Hepal-6 Pnplal CAGCCCACAATGGAAGTGAG 16810 Ctrl_1000 TTTCTTCCTCTACTCCCTCT 22794 Hepal-6 Pnplal AACTTTCCAGAGTCTGAATG 16811 Ctrl_1000 GACATGGCTTCATAGCACAG 22795 Hepal-6 Pitrml GGAGGGAGGATCCTCCGCCG 16812 Ctrl_1000 CCTGCTCTGTGAGGTAGGCC 22796 Hepal-6 Pitrml ATGGAGACGACGTCTCTAAT 16813 Ctrl_1000 ATCAGGATAATCTTCTCAGC 22797 Hepal-6 Pitrml GGTTAAAGGCAGTCCCACAC 16814 CtrlJOOO AACTACAGAGAAAGCTTGGT 22798 Hepal-6 Myolh CACATTACCAGAAATGTCCT 16815 CtrlJOOO CCCAGATTCTGGTTGCTCCC 22799 Hepal-6 Myolh TTATCCAGAACCGTCGATTG 16816 CtrlJOOO TTGTTGCTCAGGTTGCTCAA 22800 Hepal-6 Myolh CTCACCTCAGCTTATTCTCA 16817 Ctrl_1000 GAAATAACAGGTATTCCAGA 22801 Hepal-6 Dock5 CTGCGATTGCCCAGCGCTCC 16818 CtrlJOOO ATGGGAGCGCAATGTATGAG 22802 Hepal-6 Dock5 GAGGAGCTGGTGAGAGTCAC 16819 Ctrl_1000 ACCTCTCGTGGGCGGGCTTG 22803 Hepal-6 Dock5 CGCTGGGAGGACCGGGCGGG 16820 Ctrl_1000 CCACTATGGGCTTGTGCCAT 22804 Hepal-6 Rad23b GGCTGGAATATCGTGCGGCG 16821 Ctrl_1000 GCGCATAAGATACTTCCGGC 22805 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Rad23b GCGTGAACAGGAACTCCGCC 16822 Ctrl 1000 01*601 TATAATGAGACTTCGCTGCA 22806 Hepal-6 Rad23b GGTGCGGCGACGCAGTGCGC 16823 CtrlJOOO 01*1166 CTTAATGGAACTTGAGAGAG 22807 Hepal-6 Ppmln GGATAGGAAAGAGATTTACT 16824 CtrlJOOO Otud5 ACCGGTTCGAGGACCGCAGA 22808 Hepal-6 Ppmln TTCAGGCCAGGTCAAGGGAT 16825 Ctrl_1000 Serpina7 TCATCCCAGAGTTCATGGCA 22809 Hepal-6 Ppmln TCTCTTAGTGACCCGACTTC 16826 CtrlJOOO Gpr75 CTGACCGCTGATACACAGCA 22810 Hepal-6 Fmo4 GTTTCAAAGACAGGGCATGA 16827 Ctrl_1000 Pfn4 TTTCGACTCGCCTCGCTCCC 2281 1 Hepal-6 Fmo4 TAAAGTGGAAAGTACGTTAG 16828 Ctrl_1000 Sytl2 CAGCGCTGCGAGGATCTAGT 22812 Hepal-6 Fmo4 TCAAGAGTTCTTCACGGTGA 16829 Ctrl_1000 Apol6 CCTATCTCTGAGAGACAGCG 22813 Hepal-6 Pja2 CTATTGGCTGCGCCCTCAGG 16830 Ctrl 1000 01*631 TCAAGCATAGAGGAAGAAAG 22814 Hepal-6 Pja2 GGAAGCAGAGGTGGTGACGG 16831 Ctrl_1000 Gm5416 ATTTATCTCCACATTATCTG 22815 Hepal-6 Pja2 CCCTTGCGCTGCGAAGGAGG 16832 Ctrl_1000 01fr67 AGGAGGAAAGTTCTCAAGAG 22816 Hepal-6 Cyb5r4 CCTTCCCAAGCCGGGCGACC 16833 Ctrl 1000 01*1243 CTGAAATAATTCTCCTACAA 22817 Hepal-6 Cyb5r4 GCGCATGCTCAGTTACTCTT 16834 CtrlJOOO Pfkfb4 CAACTCTGGTTTGACGGATG 22818 Hepal-6 Cyb5r4 GACGCAATCACGCTCACGAG 16835 Ctrl_1000 AL669898 2 GGAGGCTGAGGCGGAGGTGA 22819 Hepal -6 Dnaafi GTCGTTATGACAACCGCGTC 16836 Ctrl_1000 Tnnc2 CAAAGGACCTTGGCTAAATT 22820 Hepal -6 Dnaaf3 ACTGACCAATTAACGTGAAA 16837 Ctrl_1000 Insl5 GGAGTCGCTGTGGAAATACA 22821 Hepal -6 DnaaO CCAATAGAAGCTCCGGGAGA 16838 Ctr OOO 01*642 AGGGTTTATTCAGTTCTTTC 22822 Hepal-6 Utpl4b GCGGGAGGAAGGATGCACCG 16839 CtrlJOOO Timm29 GAAGTTCCATTCCGTGTATT 22823 Hepal-6 Ut l4b TACCTCCCACGGACGCCGCG 16840 Ctrl_1000 Vmn2r75 GAGGATTCTTAAGCACTCTC 22824 Hepal-6 Ut l4b AGGGCGTCCTCGCGGATTCG 16841 Ctrl_1000 Prm3 CTCACACTCTCTCGCTACCC 22825 Hepal -6 Tmf 1 CGGTAGCGTGAAGCCACATC 16842 CtrlJOOO VgU2 GGGACCAAAGGACTGCGACG 22826 Hepal-6 Ttnfl ACGTACACAACCACCAGATC 16843 CtrlJOOO Tsenl5 GGCTGAAGAATTCTGAATTC 22827 Hepal-6 Tmfl TCGCGTCCCTCAGTTGAGAA 16844 Ctrl_1000 Utp4 GCCGTCCCGGAAGTACTCCG 22828 o Hepal -6 Prx GATGTCACCCAAAGGGTGGG 16845 Ctrl_1000 Olfrl406 CTGTAAAGTCCTTATCTCCC 22829 Hepal -6 Prx ATGGATGTAGTGCACAGAAG 16846 CtrlJOOO Tepsin AATAGGATAGGCGGAGAGTC 22830 Hepal -6 Prx TCTGGGCTCTGGCAAGGGAG 16847 CtrlJOOO Sex GGAGGAGCTGACTGCTATAA 2283 1 Hepal -6 Amacr TTGGTTTAGCTGCTCAACTT 16848 CtrlJOOO Sival AAAGGCCAAGGGCGCTGGCG 22832 Hepal -6 Amacr CATGTTGTGCGAGTCCTCTT 16849 CtrlJOOO Id4 AATCGACCGGAGAGCTGCTC 22833 Hepal -6 Amacr GGTGAGGGTAGCGATTCAGG 16850 Ctrl_1000 Mapkl2 AGCGAGGGTGTAGGCTGGCC 22834 Hepal-6 Tnfrsf26 TTCTTTGGACCGGAAGCAGG 16851 Ctrl_1000 Ciart ACAAGGTCTGTGTACGCAGG 22835 Hepal -6 Tn*sf26 GGCAGCATCTGGACTGCAGC 16852 Ctrl_1000 Spin2d CGCGCITGTCCTGATGCTGC 22836 Hepal -6 Tnfrsf26 AGAGCCGAGAGAGATGCTTG 16853 Ctrl_1000 2210016F16Rik GGACGCGACAAGAAACACGA 22837 Hepal -6 Atg2a CGCAAGCGTAAACTACGATT 16854 CtrlJOOO 01fr235 TGTGTGATCACTTATTTCTT 22838 Hepal -6 Atg2a GAAGGGCGAGGCCCACTGAT 16855 CtrlJOOO 01fr378 CTATAGGTCACTGATAGAAA 22839 Hepal -6 Atg2a ACCAATGGCAGCGAGCGTGG 16856 CtrlJOOO Vmn2r60 CATATCCAATGACGCCCAAT 22840 Hepal -6 Obsll AAGTCACTCAAGCCCAAGCC 16857 Ctrl_1000 Cd209d GTCTAGGAAGTGGGCATTAG 22841 Hepal -6 Obsll ATATTCTCTGATGACACAGC 16858 Ctrl_1000 Ankrd23 AGAGCTGAGCTCAATTCGCT 22842 Hepal -6 Obsll GGCCTCCAGGTCTCCAACTG 16859 Ctrl_1000 Tmco5b ATAGGTCCTTTAGAACAATT 22843 Hepal -6 Dyt GTACTGCTCCCTAAGCTCTA 16860 Ctrl_1000 Trappc5 GGGCAATGCGGTGACCGAGA 22844 Hepal -6 Dyt CTTGCTCCCAGCAGAACTGG 16861 CtrlJOOO Lcelal CATGGATGCTACATCCAGCA 22845 Hepal -6 Dytn ACATGAAACTAATACGGAAA 16862 Ctrl_1000 Cfd TTTCGGTGTGTCAGCCCTTC 22846 Hepal-6 Ttc33 CAGTTAGAGGGCGCTTCGTC 16863 Ctrl_1000 3110001I22Rik CTTCGCTTCCGGAAATAACC 22847 Hepal-6 Ttc33 GGAATGGACTCCCGTGTTTG 16864 Ctrl_1000 Dcxr CCAGACTGACCCAACTATAG 22848 Hepal-6 Ttc33 GGCTTACCGCCTAGTCTGAC 16865 Ctrl_1000 Dynap TATGAAAGGCTTTAGGATGC 22849 Hepal-6 Fcgr3 GTGTAGAAGGGATATCTGTC 16866 CtrlJOOO Gm42416 TGCAACTCATACTTACAGTT 22850 Hepal-6 Fcgr3 CAGCACCTTCTTGTACCCTT 16867 Ctrl_1000 01frl437 GTAAGATCTAAAGAATGAGC 22851 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Fcgr3 ACTCTCTTGCTTAACCGCAC 16868 GCGGAGCGATACTCCTCACC 22852 Hepal-6 Epasl GGACACTGCCGAGGATTGTA 16869 TGAGGTTGAGTGGAGTCTTT 22853 Hepal-6 Epasl CGGACTCCGGAGCTGTACAC 16870 ACCAGGAAGGATTGAGCAAG 22854 Hepal-6 Epasl GCCGGACATTCGAGAGCGGC 16871 TGGTTGGGCGGCAACATTAC 22855 Hepal-6 Egf AAATATTCAGGGTAGAGAAG 16872 TGATTGGTTCATGATATACA 22856 Hepal-6 Egf CTCTCATGGTGTTTGCAAAG 16873 CTTTGTAAGACCGGGCTTTG 22857 Hepal-6 Egf TTCCACCAGAGCAAGCAGGA 16874 CTCGCTGACAAGGACGCGTC 22858 o 4 Hepal-6 Faml70b CAAGACTAAACGTCCCTGCC 16875 GACTTGATCTAGAAAGAATA 22859 Hepal-6 Faml70b AGGCATAAAGACTTAAATGC 16876 AAGGCGTGCGTCACCACGCC 22860 Hepal-6 Faml70b TACTTGAAAGCATGCGTCTG 16877 GAGGCGGTGTCAGCGCTCGC 22861 Hepal-6 Ptp 2 TAGAACCCGCTTCTCGGGAG 16878 GCAACAGGAGGACAACCAGA 22862 Hepal-6 Ptprn2 TGGGCGTGCCTGAACGTGCA 16879 CAAATTCCAGGGACTCCAAG 22863 Hepal-6 Ptp 2 AGAAGGGACCACAGCTTGTG 16880 AACCTGCTAGGGCGCAGGCG 22864 Hepal-6 Pcsk5 AACAGGGAGGCGCTAGGACC 16881 CCACAACACGTAGAACTGTT 22865 Hepal-6 Pcsk5 GGGAGTCATTTATGCGGAGC 16882 CTGTGTGTTTGATTATTTAG 22866 Hepal-6 Pcsk5 CCTGCTGTAAACTCCAGGGT 16883 CCAGATGTTGCCGGTACCCT 22867 Hepal-6 Adgrf4 AGTCTGTGTTGTATCTTCTC 16884 TGACGTAAACTTAGCAGCAG 22868 Hepal-6 Adgrf4 TACACAATCCTCGAAGCTGT 16885 GTCTTGTCAGGTACCAGGAC 22869 Hepal-6 Adgrf4 GCTTGACAGACCCACTGTGG 16886 AGTTTCTGGCAGAAATTCCT 22870 Hepal-6 P ame 5 TGTAGAGAGTGATAAGGGTT 16887 AGCGACGGGCCGGCTAGTTC 22871 Hepal-6 Prame 5 ACACAATGAGTTCCACATTG 16888 AAGCTGATGAGGCCAGGCGT 22872 Hepal-6 P ame 25 TCTTTAAATGCCTGCATCAA 16889 GTTCCTTTCCAGCTGGGCCC 22873 Hepal-6 Zmyndl l TGGACCACCCATTATCACTC 16890 AATTGGTCAAATGGTCGCAG 22874 o to Hepal-6 Zmyndl l CCGTCTCAAATATGCACAAG 16891 TGATGCAAATCTTTCTTCAG 22875 Hepal-6 Zmyndl l ACTGACCCGAGTGGGTAAGA 16892 CATGGGTTCACCATTGCATA 22876 Hepal-6 Vm3 GTACTGGTCAAGTTCTTAAT 16893 AGGTTAATGAAATGACTTCC 22877 Hepal-6 Vnn3 TTAGTATGGACTCAACTGGT 16894 ATTGGAGGAGATAACCATGC 22878 Hepal-6 Vnn3 AGTTCAGAATTGCATGAGCA 16895 ATGGAGATCTCGAGGCATTG 22879 Hepal-6 Lipo3 CACATAATTTGTAGTCTCTC 16896 GTATGCGCGCAGTCCTGAAG 22880 Hepal-6 L p o 3 TCTTCACAACTTTGGAAAGG 16897 TGATTTCTCAGGGTAATTCC 22881 Hepal-6 Lipo3 TAGGCCACTTCAGGTGACAG 16898 GGTGAAATGACCACAGTTTC 22882 Hepal-6 Rnasehl CTGGGATTGGACTAGGCACT 16899 GAAGATTAAGTGTTAGCGAA 22883 Hepal-6 Rnasehl GAAACCGAAGACACAATCCT 16900 CCACGCGCTTTCCTCCTCCC 22884 Hepal-6 Rnasehl TAGACGTCGGTGGAGACGTT 16901 GCTTCCTGACAAGCTTACCG 22885 Hepal-6 Zfp93 ACCGAAGCTTTGCCATTCCG 16902 ATGAGTACCTTCTCTCAGTG 22886 Hepal-6 Zfp93 GTCGTTTCCGCTCCCGGGAG 16903 GAAITTAGCTTGATCCATTA 22887 Hepal-6 Zfp93 CAGAAGAGCGACCTACCAAA 16904 GGTGAACGTTTAATGCGGGT 22888 Hepal-6 Fcgbp GGAGCCCTGAAGATCTGCCA 16905 ACTGTTCGCAGCCAAAGGGC 22889 n Hepal-6 Fcgbp CGGGTCACCTGACGCGCACA 16906 AGCGCGTTCCTGACACTGAA 22890 Hepal-6 Fcgbp ATATAACTTAGCTTGCAATC 16907 GACAAATATGTGAGTTGGAC 22891 n Hepal-6 Faml79a GAGCCCAAGTCCCTGTGTGG 16908 TGTTGATAGAATGTTTGATG 22892 o Hepal-6 Faml79a CAGAGGCCAACCTGTCCTCT 16909 ATGACTCTATGGAGGAACTT 22893 Hepal-6 Faml79a GCATGGCAACCGCTCTCTGA 16910 GGAGGCGAGCATCCACTCAG 22894 Hepal-6 Cep78 TCAGGTCAAGCCCGGTTCTC 16911 GGAGCCGCTGAGCTCGCTCC 22895 b Hepal-6 Cep78 GCTCGCTGTGCGTCAGAGCG 16912 CAAGATTCTTGCTACATTGT 22896 J Hepal-6 Cep78 TCCAACGCGCCATCAGCTGG 16913 CTGGGCCAGTCAGTACTGCG 22897 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Miip TACCAATTCAAATTGAGGAC 16914 Ctrl 1000 Comt GCTGTGATGGGATGATGTCA 22898 Hepal-6 Miip TCCGGATGTAAAGTCTCTAA 16915 CtrLJOOO Rnfl22 GGCAGGAGAAAGGCTCCCAT 22899 Hepal-6 Miip TCTGGTTGGTCAGTAGTACT 16916 Ctrl_1000 Cyp2c54 CAGAACAATCAATTGCACTT 22900 Hepal-6 Golga5 GCCTCCCATCTGAAAGTTAA 16917 Ctrl_1000 Pragl GCAGGCCCGGTGGAGACGCG 22901 Hepal-6 Golga5 CGTGCTCCGCAATGTTGTGG 16918 Ctrl_1000 01fr391-ps ATATCCCTGCTGTCACTGCT 22902 Hepal-6 Golga5 GCAAGACATTAATTGTCTTC 16919 CtrLJOOO Liptl CAGCTCGTCTTTACATATTT 22903 Hepal-6 Zkscan4 AGTAAGTTATCCGGGACCCT 16920 Ctrl_1000 Olfrl290 TTAGGGACTTCTCTGTTAAG 22904 oi 4 Hepal-6 Zkscan4 AGGAGTATATGTTTAAGCAG 16921 Ctrl_1000 Vmn2rl3 TCATTCAATGTCATTCTCCC 22905 Hepal-6 Zkscan4 CCAAATTAACCCATTATTGT 16922 Ctrl lOOO Faml74b GCAGTTAGGATTCCTCCATG 22906 Hepal-6 Nadsynl CTGTGGAGGGCGAAAGGACG 16923 Ctrl_1000 Aldoart2 GTTACTAGAACCTGTTTCTG 22907 Hepal-6 Nadsynl GGCGCAGACCGTGTCTTACC 16924 Ctrl_1000 Gm8660 GTGTTCTATCTAATCATCCA 22908 Hepal-6 Nadsynl GCTGGGCTATGACGGCAGAG 16925 Ctrl 1000 Selenov GAGGAGAGCTTTCGCACCCG 22909 Hepal-6 Rangrf GGAAAGACCCAGGACCGCTG 16926 Ctrl_1000 Gm20172 TTTCCCAATGATGGTTGACT 22910 Hepal-6 Rangrf TCAGTGCTGGATGTGCCATG 16927 Ctrl_1000 Atoh8 AAAGGCGCTCGCTGCTCGGG 2291 1 Hepal-6 Rangrf GAGTGAAGTGTGGCCACGTG 16928 Ctrl_1000 Ankrd33 AATTCACTCAGCTCTGAGCC 22912 Hepal-6 ExosclO GTGGGTCTTGCCTTAACGAT 16929 Ctrl_1000 Chmb4 CCCGAGACTTTCTCACACTC 22913 Hepal-6 ExosclO ATGCGTGTTACGCCCGCCTC 16930 Ctrl 1000 Rnfll3a2 TAGACTAAATTATTTGAGGC 22914 Hepal-6 ExosclO GCTGTATCCTAACAAACCTG 16931 Ctrl_1000 C 74 GGAACTGAAAGCCACAAATC 22915 Hepal-6 Nkx2-6 TGTGCATCCCAGAATCGATT 16932 Ctrl_1000 Glol TATTGTGCACAATGGCATTC 22916 Hepal-6 Nks2-6 GGACCGCGCCTTCCCTTGAC 16933 Ctrl_1000 Sprrla TCTGGGCCAAGTGTGTTTCC 22917 Hepal-6 Nkx2-6 GCGATCTTATCACCCGGTCC 16934 Ctrl 1000 Skidal CAAGTCAGTGTAATTTCTTG 22918 Hepal-6 Adamts3 AGTGGGCCGCTCGCCCGCTC 16935 Ctrl 1000 01fr923 GATGATCTGCAAACCATATA 22919 Hepal-6 Adamts3 GGGCAGAGAGCAGACGCCCG 16936 Ctrl_1000 AC127556.1 AAGTCTGTGACGTGAGAGAA 22920 o Hepal-6 Adamts3 CGTGTGCGGCGGAGGATCCA 16937 Ctrl_1000 Krt34 AATAGCATAATTCTCTTTCC 22921 Hepal-6 Tripl l TCCCACGGTCCTTCGCGCCC 16938 Ctrl_1000 Ikzf3 CAGTGCCTCAGCGACCGTCT 22922 Hepal-6 Tripl l CGTGACTTCCGCGTAACCTG 16939 Ctrl_1000 Tmem42 CCGCGACTAAGGAGAGCCTG 22923 Hepal-6 Tripl l ACTTTAGGTGGAGACCGAAA 16940 Ctrl_1000 Maob CCAGGTCACCCTCCCAGCTG 22924 Hepal-6 Tspan32 AAGGGTTGCTGACAGATAGG 16941 Ctrl 1000 Gal3st4 CCAGCCACCGCCCGGCTCCT 22925 Hepal-6 Tspan32 TTCTATACCAGCTGTTGCTC 16942 Ctrl_1000 Izumo2 GCTACACTCGGAGTGTTCTG 22926 Hepal-6 Tspan GACAGTTTGATATGAGCTCC 16943 Ctrl_1000 Tmem243 CTTGGCAATTGGCGGCTGCG 22927 Hepal-6 Mrpl44 AAACACAAGCGAGACTGATA 16944 Ctrl_1000 Gimap8 TACATCAGTAGAGCCTGAGA 22928 Hepal-6 Mrpl44 TTCTGCCCATTCTGTAAGTA 16945 Ctrl_1000 Trafl CTCCAGCCTGAAGTGCCGCA 22929 Hepal-6 Seipinb3b GCAAAGGGAAGTACAGTGAT 16946 Ctrl lOOO Ergic3 GGAITGGGCAGTGCTCCGAG 22930 Hepal-6 Seipinb3b GATGAGGCAACAGTGGTAAA 16947 Ctrl 1000 Cdl51 TCCTAACTGGTTTGGTGCTA 2293 1 Hepal-6 Serpinb3t> GTATGCAAATTTGTGAGAAA 16948 Ctrl_1000 Dynlrbl GAAGCAAGGACTCAACCCTT 22932 Hepal-6 Serpinalc TCTCTCTGCTCCTAAACCAA 16949 Ctrl_1000 Ackrl GAACACGGTGAGGTCCACAA 22933 Hepal-6 Serpinalc AGTTCATCGATTGGGCACTG 16950 Ctrl_1000 Usp9y AGTGAAATCGCAGCTAGAAA 22934 Hepal-6 S rp lb ACAGTGTTGCATGCAGCTTC 16951 CtrlJOOO 01*846 ACTTTCTGTTTCTATTAGGT 22935 n Hepal-6 Siipblb TTGTCTCAAGTGTCTTGTCT 16952 Ctrl_1000 B tll GTCCTTCGAGCAGAATGCTC 22936 Hepal-6 Sirpblb GACAACATGGCACAAGCTCA 16953 Ctrl_1000 Barxl GCTAGAGGCGCGGCGGCGCG 22937 n Hepal-6 Adam28 GAAACAATAGCTCCTAATAG 16954 Ctrl_1000 01frl78 CAGCTAAGGTAAATTAAACA 22938 Hepal-6 Adam28 GTGGTTCTGCCGCAATGGCA 16955 Ctrl_1000 Ppplrl GACAGCAGGTCTCTCACTGA 22939 Hepal-6 Adam28 ATGAACTATTATAGCTCAAG 16956 Ctrl_1000 01fr212 TTGACCACTAAGTCTCAGGC 22940 Hepal-6 Syde2 GCCAACACGCGGCGTTCCCG 16957 Ctrl_1000 Mettl7a3 GGAAGCAGACCTCAGGTTCT 22941 Hepal-6 Syde2 GCAGCGGCGGGTCGGTAGAG 16958 Ctrl_1000 01*808 GCTAAGATCTGAAATTGGGT 22942 Hepal-6 Syde2 CCCGTCGCGGCTCTAGTTCC 16959 CtrlJOOO AL590629.2 GACGCTCAGCCCACAATAAA 22943 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 4931406P16Rik CCAGCTGGTCAACAGCATTT 16960 Ctrl 1000 Krtap3-1 CAGCCATAAACTGAAACATG 22944 Hepal-6 4931406P16Rik GGTAAATGGATTTGACAGGC 16961 Ctrl_1000 Vmn2r68 ATTACTGTACCTACTACTAA 22945 Hepal-6 4931406P16RiJk AACTTCCAAATCTCCTGTAA 16962 Ctrl_1000 4930567H17Rik AATAGTTTCAGTGTTCTAAC 22946 Hepal-6 Snxl CCATGCAGGGCACAAAGACC 16963 Ctrl_1000 Rflna AAGGAGGCTCAGCTGGCGGC 22947 Hepal-6 S xl CAGCCTTGCGGTTCAGTGCT 16964 Ctrl_1000 Ednra GGGATAGCGCTCTTGCAGTT 22948 Hepal-6 Snxl TAGAGGCTGAGGAGTTCCTC 16965 CtrlJOOO Tas2rl02 ATGTCAATTAAATGCCAAAC 22949 Hepal-6 Rail TCGTGGCCTCGGGTGCCAGG 16966 Ctrl_1000 Gjd2 CCCATCTCCGGCGCAGCGGG 22950 Hepal-6 Rail GGCCTTGTGGCCACGTCCAC 16967 Ctrl_1000 Lman2 AGCGAGCAGCGTCGTCGAAG 22951 Hepal-6 Rail GGGCTTGGCAGAGGGCCTGA 16968 Ctrl 1000 Mrpl36 GAGCITAGAGTGCAGGATTC 22952 Hepal-6 Pttgl CAGACGCGAGAGCTGGGCGG 16969 Ctrl_1000 Tmxl CCGCTCCGCTCATGCGCACA 22953 Hepal-6 Pttgl GTCGGGACGTGTGCTTCACT 16970 CtrlJOOO C330018D20Rik TCCGCCGTGCGCCGCACTTC 22954 Hepal-6 Pttgl CGAGCACGACAAGAGCGCCT 16971 Ctrl 1000 Vatl AAGACTAGCGGTGCAGGTGG 22955 Hepal-6 Ttcl3 TGCTTGAGGCTAACAGGGCG 16972 Ctrl_1000 Ndufaf4 CCTGTGCGGAAGGGTGGGCG 22956 Hepal-6 Ttcl3 GCCTGGACTGGCCTTGGGAG 16973 Ctrl_1000 Gtpbp2 CAGTATCCCTTGATGCCCTG 22957 Hepal-6 Ttcl3 TACAAGTCCCAGTAAGCCCT 16974 Ctrl_1000 Soibsl TTCCAGGCCATGCTAATGAG 22958 Hepal-6 Mfsd61 ACGGACGCCCTGTGGTTTGC 16975 Ctrl_1000 01fr937 GTAATGATCAAAGTGCTCAC 22959 Hepal-6 Mfsd61 TCCATTAGGTGGCGCAGGTG 16976 Ctr OOO Zfp472 CAGTTCTAAGGAGTTGGGTC 22960 Hepal -6 Mfsd61 GGTACAGTCAACAGGTGCGT 16977 Ctrl_1000 Deupl TGGCGITCTTGGTGACCCAC 22961 Hepal-6 Vmnlr206 TGCAACATTAACTGTGTCTA 16978 CtrlJOOO Klhl34 AAGGTTCCTTCATCCAGATT 22962 Hepal-6 Vmnlr206 AACCTCAGTAATTCTAGACA 16979 Ctrl_1000 Mtfpl AGGTGTGCGGCTTCTAGGAA 22963 Hepal-6 Vmnlr206 AGGATACAGGAGACATTACA 16980 CtrlJOOO E2f6 ATCCATCCTCCGGAACACCC 22964 Hepal-6 Klr CACTCGTATTCATTGTCCAA 16981 CtrlJOOO 4930571K23Rik CCATGACACTCAGTACACGT 22965 Hepal-6 Klrcl TTGATAAGGCAACAACTTAA 16982 Ctrl_1000 Mup21 AGCTAAAGGAGACCCATATG 22966 o Hepal-6 Klrcl ACAACAGCAACAACAACTTT 16983 Ctrl_1000 G l AGGAACTGTGCGGGAGCCTC 22967 Hepal -6 Dpcrl ATGTCATGGAGCTAGGTACC 16984 Ctrl_1000 Tmem203 GCGTCATTTCCTGTTGACAG 22968 Hepal -6 Dpcrl GGGTCAGATTTGACGTCACA 16985 CtrlJOOO Rdh5 TTAAGCGGCTCTATGTTTGC 22969 Hepal -6 Dpcrl CAGGGACCCTTCATCTTATA 16986 Ctrl_1000 Cdc42ep2 GCTGGATTCCAAGATTCTAG 22970 Hepal-6 Cryl GAGGTGCCGGTGGTCACGTG 16987 CtrlJOOO Vm l r ACACCAAATGTTAAAGAGAA 22971 Hepal-6 Cryl GCAACCGGTCCCGAAGCACC 16988 Ctrl_1000 Naplll GGCGAGCACAAGACCGCCAC 22972 Hepal-6 Cryl TCACGACCTGAGTTCTCGCG 16989 Ctrl_1000 Olfr294 CAGTATCTAGGTAGTGTCCT 22973 Hepal -6 Cgnll GTCCTCGGTCCGCCGGGTCC 16990 CtrlJOOO Med25 CTGATACGGCCATGITTGTG 22974 Hepal -6 Cgnll CGCCCGGGACTGTCCGCGAG 16991 Ctrl_1000 Olfrl355 TTAAGTAGATGATTACCCTC 22975 Hepal -6 Cgnll GAGGTCTCAGGGCGCAGATG 16992 CtrlJOOO Slc2a8 GAGCCGGTTGCAAAGCTCAA 22976 Hepal-6 Foxd4 AATCGAGTCACGGGATTATT 16993 CtrlJOOO Lmcdl GAGGGATTCCTGCCGCCTAG 22977 Hepal-6 Foxd4 GTGAAGTTTACGAGGAGGGA 16994 Ctrl_1000 aipl AAGAACTCGTCCAAAITCCC 22978 Hepal-6 Foxd4 GAGCCATTTCTCTGGAATGG 16995 CtrlJOOO Ube2n GCCTCGGCGGAGGTAGCGAC 22979 Hepal-6 Serpinb3c GGCAACAGTGGTAAGAGGAG 16996 Ctrl_1000 Nanos2 AGCTCCACCTTTGCTTAGAA 22980 Hepal-6 Serpinb3c ATCATATGACCTGTGGCAAA 16997 Ctrl_1000 Hlfnt GCTGCATCTACCTTTCCACC 22981 Hepal-6 Serpinb3c GAAATACAACTGAAATGATG 16998 Ctrl_1000 Fam57a CGATAGGCGCGGGCAGGAGC 22982 Hepal -6 Dab2 ACTCGGCAGACACGTTGAGG 16999 Ctrl_1000 Olfr535 CAGTTCACCACTTCAAAGTC 22983 Hepal -6 Dab2 TCTGATAACAGGAATAGGAG 17000 CtrlJOOO 1700109H08Rik AAACAGCTATGAGCAAACAA 22984 Hepal 6 Dab2 ATATTTCTAAGGCCTAAGTC 17001 Ctrl_1000 Olfrl 140 GAAGTAAATCACACTTAAAG 22985 Hepal-6 Cd22 GCATGGAAATTCATCAGACA 17002 Ctrl_1000 Slc25a32 GACAGGAAGCCCGCGGAAGG 22986 Hepal-6 Cd22 CGTGGTGGAGAACACAAGTT 17003 Ctrl_1000 Sephs2 GTATATAAATAGAGGCCGCG 22987 Hepal-6 Cd22 ACACCGGAGACACACTCTGT 17004 Ctrl_1000 Cersl TGAGCCATCTTGACCGCAGA 22988 Hepal-6 Akrlcl2 GCATGGCTAACTTTCAGAAA 17005 CtrlJOOO Gadd45b GGCATGCGCTTTCCACCCAT 22989 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Akrlcl2 TATATCAACTTCCTGTCAAA 17006 Ctrl 1000 Faml07a CATGTTCTGTCAGACTGATG 22990 Hepal-6 Ccdc87 GGCAGTGACAACAGCTAGGA 17007 Ctrl_1000 Olfr700 GAGCAAACTTATTTACTAGT 22991 Hepal-6 Ccdc87 CTACCGGTTCGGTGCGGCCT 17008 CtrlJOOO 2310061N02Rik TAATTGCAGTTTAATCACTG 22992 Hepal-6 Ccdc87 AGTAGAGTTGTGTTGGTCTC 17009 Ctrl_1000 Ldah GGATCTCCCGTGTGAGAGTT 22993 Hepal-6 Pramefl2 AAATGCGGCTGGTCTGTGCG 17010 Ctrl_1000 Tmem95 GTAAGACAATGGCATTGTTC 22994 Hepal-6 Pramefl2 TGCTTCTGTTTCTAACCCGA 170 11 Ctrl_1000 01fr25 AGTGGTTGGAGATCTTTGTA 22995 Hepal-6 Pramefl2 TTTGAAITGACCCTTAAGTC 17012 Ctrl_1000 Tob2 ACCTACGACTGGGCTGCGAG 22996 o 4 Hepal-6 H2-M3 TGACATTAAGTACTCAGTGT 17013 Ctrl_1000 Cdl60 TTGATAGAGATCAGCTGCTG 22997 Hepal-6 H2-M3 CTCCAATGCTGGGTTAAACC 17014 Ctrl 1000 GtpbplO CACACAACTTAGACGAATCT 22998 Hepal-6 H2-M3 GGAGAAGCGTCATCAGTATC 17015 Ctrl_1000 Mq>sl8c CAAAGGTTCCGGCGCGAACG 22999 Hepal-6 Myh3 AGAGGAAGAATGAGCCCAGG 17016 Ctrl_1000 01fr912 TCTGTGCTCTAGGAAGCGGC 23000 Hepal-6 Myh3 CATTCTCTTTCCAAATATAG 17017 Ctrl 1000 Olfr460 TCTAGGTTTCACAAGGAACA 23001 Hepal-6 Myh3 TGACACCACAGGCTGAGAAC 17018 Ctrl_1000 Mt2 AGCAAAGGAGCTGAGCGCAA 23002 Hepal-6 Nme8 CTCCCTGTGGTGGAGGCTCG 17019 Ctrl_1000 Spc24 AATTTGCGCGGGTTCGGACT 23003 Hepal-6 Nme8 GAGCAATACAGCAGGAGTCG 17020 Ctrl_1000 Tacstd2 GGGTGGCGCTCCCTATTCCC 23004 Hepal-6 Nme8 CTGCTCACAGCAGGTAGAAC 17021 Ctrl_1000 Saa3 ATGCCTAGATGGCGCAATCT 23005 Hepal-6 Ms4a3 TATATGGAGCCATCAGCATC 17022 Ctrl 1000 f 2 14 ACTTTCTTATGGTGACTAAA 23006 Hepal-6 Ms4a3 GCTAATAACACTCCTATTTG 17023 Ctrl_1000 Nkxl-2 CAGCCTCCACGAGACTATCC 23007 Hepal-6 Ms4a3 CCTTCTTAATGGTATACTTG 17024 Ctrl_1000 Olfrl504 TAGCATGACTACAAACTGCT 23008 Hepal-6 C87977 GGTGAATGGAGACACAATGA 17025 Ctrl_1000 Phldal AGCGACCGCGTGGAGCCTCC 23009 Hepal-6 C87977 TGACTTTAACTGGGAGGGTG 17026 Ctrl 1000 A2mll ATGGAAGATCAATTACCTTT 23010 Hepal-6 C87977 AAAGGGAGGATTCAGCTAAA 17027 Ctrl 1000 Rdhll GCCAGGCGGCCGCCAAATCC 2301 1 Hepal-6 Spagl TCGTCGACAGTGTGCGTGTG 17028 Ctrl_1000 Ddx47 TTCTGAACGCCTCCTGCTGG 23012 o Hepal-6 Spagl TGCCGCACTGTGGTTTCCTG 17029 Ctrl_1000 EmclO TCGTTGACGTCACGGAACGC 23013 Hepal-6 Spagl CACCGCTGTGGTTCACACGG 17030 CtrlJOOO Cryaa AAATGTCTATGCTCAGCTCG 23014 Hepal-6 rr 27 AGGTTTAGGGTCTATGGACT 17031 Ctrl_1000 Gnail AGCTGGGCTCGGCGATCACG 23015 Hepal-6 Lrrc27 GCGCTTACCGCCTCTTATGC 17032 Ctrl_1000 Ppp4c TGGCTCGTGTGCGTCACTTC 23016 Hepal-6 L 27 AGGAGAGTCTGTGCAGATCC 17033 Ctrl lOOO Bscl2 GGAGATTATAATGGGTCCTT 23017 Hepal-6 C7 TGCATCTGGCATCAAGGCAC 17034 Ctrl_1000 Gabarapll AAACAAAGCTTCTGTCCACC 23018 Hepal-6 C7 GGGAAGTATATCTGTTAATT 17035 Ctrl_1000 01fr677 TAATGGAAGCGCTTAATGAG 23019 Hepal-6 C7 TGGTGAAGACTCAGCACAGC 17036 Ctrl_1000 Ak6 GGTCTGAGTGCGTGCGAGCC 23020 Hepal-6 Hif3a GCTTGTTGCTCCCGAGAAGG 17037 Ctrl_1000 Cstf2t GACAACAGGATTCCGTTCCA 23021 Hepal-6 Hif3a CCCGAGCTAGAGACGCCGTC 17038 Ctrl 1000 Olfrl390 TGGAGTATTTCAGAATTATC 23022 Hepal-6 Hif3a GGGACAGGGAGGCCTCCCGG 17039 Ctrl 1000 Gprl32 CTAGCCTGCGTTGTGGTTAG 23023 Hepal-6 Dis312 AGCGAGCGTTCCGAGAGCGA 17040 Ctrl_1000 Bhmt2 GACAGATCCCGGCCTTAGGA 23024 Hepal-6 Dis312 AGGATCCAGATAGCGCGAGA 17041 Ctrl_1000 Gm5901 CCTAATAGGTGATAGAGCCT 23025 Hepal-6 Dis312 GGTACGAGGCTCATCCCGCG 17042 Ctrl_1000 Muml GGGACTTGGAGCGGGCCTCC 23026 Hepal-6 Cyp20al CACAAGGAAACCTCCAGGCC 17043 Ctrl_1000 Pdgfrl TCCGTCACCACTCCACCAGG 23027 n Hepal-6 Cyp20al GCCAGGCCAGGGTGGGACCC 17044 Ctrl_1000 Pigm AGCGGAAGCGTCGCCAATAA 23028 Hepal-6 Cyp20al TTGGTCTGCTGGCGACTCAC 17045 CtrlJOOO Sstr4 CGCTCCGCCTAAGAAGTGCG 23029 n Hepal-6 Zfp286 TGCGTGGAATCCCGCAGTAA 17046 Ctrl_1000 Defbll TGAACACATATTAACAGCAC 23030 o Hepal-6 Zfp286 CTGTGCCGCTGAGCCACTCG 17047 Ctrl_1000 Nsgl AAGGCGGAGGCGCATCCGCG 2303 1 Hepal-6 Zfp286 CCAACCTGCCAAGAAACAGG 17048 CtrlJOOO Mia3 GAGGCTTGCGATTGGGCGAG 23032 Hepal-6 Mlph GCGGACTCCAGTGGCCCTCC 17049 Ctrl_1000 Vmn2rl6 ACAGAATGAGTGGAAAGGAA 23033 b Hepal-6 Mlph CGCCGGTCCTGCCCAACTTG 17050 CtrlJOOO 016987 TTCTGTGATGCAACTTATGT 23034 J Hepal-6 Mlph GGGAGGCGCTGAAGTGGGTA 17051 Ctrl_1000 Arhgef3 CGCCACTTAAGTTGCATGAC 23035 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Klra9 AAAGAGGTACTGAAGTTCAT 17052 Ctrl lOOO Ctps2 GGCGGGAGAATCCAAGCAAG 23036 Hepal-6 Klra9 GAAGACACACTCCTGCAGAG 17053 Ctrl_1000 BC049715 AGTGTGCAATGACATCATAA 23037 Hepal-6 Klra9 TTTGCTTTGTTGACAAGGAG 17054 CtrlJOOO Dedd2 ATTCTGCGCTTGCGCTGTAG 2303 8 Hepal-6 Ecell CACCTACCAGTCTGCGGTAA 17055 Ctrl_1000 Lyrm9 TCCCGCGGATGGCCGGCAGA 23039 Hepal-6 Ecell TCTCAGGAGCGTTATCTCCG 17056 CtrlJOOO Gm590 TCAGAAGTTCGGAGCTTGTC 23040 Hepal-6 Ecell CAGGCTCTTCACCTGCCCAT 17057 Ctrl_1000 Hbb-bhl GGTCCAGGGTGAAGAATAAA 23041 Hepal-6 ScgMbl9 CCTTCTTTAACTGCCCTGTT 17058 Ctrl_1000 01*641 CAGAATTATCAGATACAGTG 23042 Hepal-6 Scgblbl9 GCATGGAGAGGCTCAGACAC 17059 CtrlJOOO Ccr6 ACTCAGGGCAATGTACAGTG 23043 Hepal-6 Scgblbl9 TCCAAGATGTGTACTGGGAG 17060 Ctrl 1000 Acad8 TAGTAGAAGACGCGTCTCAG 23044 Hepal-6 Laccl CCCGCGCCGCTCAGCAGTTC 17061 CtrlJOOO Μφ 157 TACAGTGGAAACTCTGGATG 23045 Hepal-6 Laccl TGGCGGGAACACCCAAACCC 17062 Ctrl_1000 MuplO CATTCCACAAAGCCTGACTG 23046 Hepal-6 Laccl GTCTCCAGGGCGCCACCTCG 17063 Ctrl 1000 Olfr305 CAATGTATAAACACACTATG 23047 Hepal-6 1810065E05Rik GGATGGGAAAGAGGTTATGA 17064 Ctrl_1000 Cdk2apl AAACTTTGAGCCCAGCCGGT 23048 Hepal-6 1810065E05Rik CAGGAAGTGTAGTGCACTTT 17065 Ctrl_1000 Mamldl GGAATGGAGCGAGCAGATTG 23049 Hepal-6 1810065E05Rik CTTACAGCGCCTTAATTGCC 17066 Ctrl_1000 Stac3 TACACAGAGCAGGTCAGTTC 23050 Hepal-6 Trh AGCGGCGCCTGTGAGGTCAG 17067 Ctrl_1000 Purg GAATCGGAGCGGGAGGCCTG 23051 Hepal-6 Trh TCTCGAGCGCATATAAGCCT 17068 Ctrl lOOO Miga2 GTCTCCATATCGCTCCGCAT 23052 Hepal-6 Trh CCGCCCGCTTTCCGGAAACC 17069 Ctrl_1000 Uxt AAGTGCATCTTCCCACACGC 23053 Hepal-6 Tshr TCGGAACAGAAGGCGCTGCG 17070 Ctrl_1000 Ppil6 CACCGAAGGACCTAAGAATC 23054 Hepal-6 Tshr ACGACACAGGGACCGAGGTT 17071 Ctrl_1000 01frl261 TTCAATTAAGATCACTGTGC 23055 Hepal-6 Tshr CTCATCGCTGGAGAGCACGC 17072 Ctrl 1000 Fbxl5 AATCGCACTGTCCCAGGGCG 23056 Hepal-6 Faml24b AGAGGAAATGATCGGCCGAA 17073 Ctrl 1000 Sfrl TTGGCTAGCTTGGCCGGAGC 23057 Hepal-6 Faml24b GGCGTGGGTCTCAGCATTAT 17074 Ctrl_1000 01frl361 AAGAAGGGAAAGGGAAAGAA 23058 o Hepal-6 Faml24b TAGGAAGTCAGAGCCCATTG 17075 Ctrl_1000 Mrps23 ATTCCTATG AAACAGCTCC A 2 Hepal-6 Myocd GCCGGCTGTTAAGACTCCTG 17076 Ctrl_1000 Nsdhl TGCCCAATGAGGCTAGTCTT 23060 Hepal-6 Myocd CCGCCACCACGCCTITATGA 17077 Ctrl_1000 Minosl CATACGTCGTCCCTGGCTTC 23061 Hepal-6 Myocd CTTTGCAGAATAGTGCGCCA 17078 CtrlJOOO Meoxl TTTGGAGTGAAATGTGAGAG 23062 Hepal-6 Serpina3c TGGACAGACTGGATGATTTC 17079 Ctrl 1000 Tmeml73 AATTAAATGA AGGG AAGTCC 23063 Hepal-6 Serpina3c GGAGGGAGGAGACCTTGGTG 17080 Ctrl_1000 Olfrl 102 TCGAGTTAACGTAACTGCAT 23064 Hepal-6 Serpina3c GGCTTGTGTAGAACAGAGGT 17081 Ctrl_1000 Krtapl3-1 ACAACCATTGTTTCCATATG 23065 Hepal-6 Gpatchl ATCTGCAGTCGGACTTGCAT 17082 Ctrl_1000 01frl313 AGTCATGTCCAGAACTTGTT 23066 Hepal-6 Gpatchl TCAGTTTCGCTTCTGTGAAC 17083 Ctrl_1000 01frl378 GTTCCATTGCCAGGTATGAT 23067 Hepal-6 Gpatchl GACTATGATTTGCGAGGAGG 17084 Ctrl 1000 Jmjd8 ACAATGCGCTTGTATGAAGA 23068 Hepal-6 Kanslll GGCGCGCCATGCAAATGAGA 17085 Ctrl 1000 Myadm CCAGGACGCTAGCCTTCTGG 23069 Hepal-6 Kanslll CACTGGGAGCCGGCAGAGTT 17086 Ctrl_1000 Wdr44 CGCGGCCGGCCGGTAAAGCG 23070 Hepal-6 Kanslll TGAAAGCAGCCTGAGCGCGG 17087 Ctrl_1000 Pus3 CTTCACCAAGCGTGCGCCGA 23071 Hepal-6 Rfx7 GGTGTTGTGCCGTCTGCGCC 17088 Ctrl_1000 Ptgs2 GCGGACTCCACGTGACGTAG 23072 Hepal-6 Rfx7 GCCACCCGACCGCTCCCTCG 17089 Ctrl_1000 Olfrl 18 ATACTTTCTGTCTTTACATC 23073 Hepal-6 Rfx7 GGGCGTGGACGCGCGTGTGC 17090 Ctrl_1000 D630039A03Rik TAGGGTGACCTTGTACACAT 23074 Hepal-6 Trmt2b GCTGCGATATGAATTTCTTC 17091 Ctrl_1000 01fr76 TCACACAGACCACAAGGACA 23075 Hepal-6 Trmt2b CTCCTTATCAAATAGGGATC 17092 Ctrl_1000 Mgst3 TAGAGCAAATATATACACTG 23076 Hepal 6 Trmt2b AGTCAAAGTTCAGCAGGAAA 17093 Ctrl_1000 Rps6kll GCCGGGTGCCTGCCAGCCAT 23077 Hepal-6 Zdhhc25 CTGCAAGGATCAGCTTGTCA 17094 Ctrl_1000 1700015GllRik A GGG CATGAGTGGCA CTTT 23078 Hepal-6 Zdhhc25 GGCTGGGAGGAGACACCTAT 17095 Ctrl_1000 Ndufs4 TCTAGGTCCTCAATCGCAAA 23079 Hepal-6 Zdhhc25 TCCACTCTGAACGAACCTGT 17096 Ctrl_1000 Sptssa GAGCACACGAAGTGGCCGCT 23080 Hepal-6 Vnmlrl94 TTGACTTCATGCATGGCACT 17097 Ctrl_1000 Fam84a CTGGGCAGGGCGGAGCACAA 23081 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Vmnlrl94 TATCTGGTCAGGAATCATTA 17098 Ctrl 1000 Tagln CCTTCCTTGTTACCCGGACT 23082 Hepal-6 Vmnlrl94 TTTCTCTGTTCATTCCTATG 17099 CtrlJOOO Gm5148 TCCCGATCAAAGCAGCAGTG 23083 Hepal-6 Serpma9 GGGTGAGATCTGTCGGAGAG 17100 Ctrl_1000 Klhdc7b ACATTAGATTCCGTATTCTT 23084 Hepal-6 Serpina9 AGCCAGCAGGCCTCAGCATC 17101 CtrlJOOO Vmnlr205 AGCCTCTGCAATCCTAGACA 23085 Hepal-6 Serpina9 TTCATAATGAAGCTGTGGGC 17102 Ctrl_1000 Vmn2rll3 TTCTCTGAGGCTGGGCAGAA 23086 Hepal-6 Cep89 GGGTTGTCAAGAGCAACGGG 17103 Ctrl_1000 Hist2h2ab AATTTATAAGATCTATCGGG 23087 Hepal-6 Cep89 CATGCITGTTGTAAAGTCGG 17104 Ctrl_1000 Ctdspl GCGGGCGGGTGGGTGTGTCC 23088 o 4 Hepal-6 Slc9cl AGCCAGTAGGCACATAGCAG 17105 Ctrl_1000 D17H6S53E GCTCAGGGTCTGGTCTTAGG 23089 Hepal-6 Slc9cl AGCCAATCAAATTAGGAGTT 17106 Ctrl 1000 Alg5 CTAGGCCGGCCTCTCCTGCG 23090 Hepal-6 Slc9cl GTTAGGAACCTCTAGCCAGT 17107 Ctrl_1000 Chstl3 TCTGGGCGGGCCCTAAACTA 23091 Hepal-6 MphosphlO TTTGGCGTACTGCTTCCGGC 17108 Ctrl_1000 01*1462 AAGAGAACAGGATCTGGTAT 23092 Hepal-6 MphosphlO AAGTGTTTGCGGCTATAGGC 17109 Ctrl 1000 Gm3383 TCACAACAACGCATCTTGAA 23093 Hepal-6 MphosphlO CCTAAAGTTCCGCCACACAC 17110 Ctrl_1000 01fr572 GTGTTACAATCCGACCTCTC 23094 Hepal-6 Mter ACACTGTGTACAGGCTCCCG 17111 CtrlJOOO Cdkll CAGGGAGAACGCCTGCTCCC 23095 Hepal-6 Mterf ATTGGCTACGCTCGGGATGG 17112 Ctrl_1000 Mpc2 CTGGCCTCACAGAGCGGAAG 23096 Hepal-6 Mterf2 GAATAAGTGAGCCACACTAC 17113 Ctrl_1000 Krtap4-16 GACTCCATGTAAGTGTTAGA 23097 Hepal-6 5430401F13Rik TCAAGGTGACATTGTTTCCC 17114 Ctrl 1000 Edfl AATCCGCACCCGGCTAGTCT 23098 Hepal-6 5430401F13Rik GAACAGGATGTGTTCTTCAA 17115 Ctrl_1000 Kissl TCTCTCTTTGACCTAGGCTC 23099 Hepal-6 5430401F13RiJk TAATTCATCTTGTCTGGCTG 17116 CtrlJOOO Icam4 GCCGGCCGAGGCCCATTCTG 23100 Hepal-6 Lypd8 AGGGTCACTACAGTTGGGCA 17117 Ctrl_1000 Sdccag3 AGACAGGCCTCGGCTCACCT 23101 Hepal-6 Lypd8 CCCAGCTTAGGGCTGTTAGA 17118 CtrlJOOO Pf4 TGCAGAAGCAATGACACTTG 23102 Hepal-6 Lypd8 AAGAGGCCTTATATAGTAGG 17119 CtrlJOOO Antxrl CGCCGCCCTTGGCCACAAGA 23103 Hepal-6 Gcml TAGCATAGTGTACCCTGACC 17120 Ctrl_1000 Gm20765 ATCTTGAGCCATAGTGGCTA 23104 o Hepal-6 Gcml AAATCAAGArGCTTTCAGCC 17121 Ctrl_1000 AL61 1930 1 AGGCAGAAACTGTGCACTCC 23105 Hepal-6 Gcml ACCATAGAATATTCATCACA 17122 Ctrl_1000 Olfrl303 AAGTGTATCTATAGTCCAGT 23106 Hepal-6 Heatrl TGAGGTTCAGGCCCTTAGAG 17123 CtrlJOOO RassflO CAGCGGCTCAGGGCGCTGGG 23107 Hepal-6 Heatrl AACTTAGAGTCACGGAGGCG 17124 Ctrl_1000 Vmn2r86 ATGACATAGGATGAATGGAA 23108 Hepal-6 Heatrl GAACTTCCGGCTTCTCACTA 17125 CtrlJOOO CT571246 5 AGGAGACCCATACGGGAAGA 23109 Hepal-6 9530053AOTRik TCAGGACTCACTATTCCCTC 17126 Ctrl_1000 Minppl CTCCGACGAGCGTGTGACAC 23110 Hepal-6 9530053AOTRik GGCAGATGGTGCCAGCTTCC 17127 Ctrl_1000 [ft2712b TTTGCTGTCAAACCTCCAAG 2311 1 Hepal-6 9530053AOTRik AGTCCCGTTTCTTGTTCCCT 17128 Ctrl_1000 Mgp TCTGGAAGGAATGAGTACTT 23112 Hepal-6 Spire2 CTCGCGGGCAGATGCAGGTG 17129 Ctrl_1000 01*1241 TTAATGCCATAGTGAACTGA 23113 Hepal-6 Spire2 GGAGGGAAGGGAAGACCGGT 17130 CtrlJOOO Chin AAACACCTTATTTATCCTAG 23114 Hepal-6 Spire2 ACAAAGCACACGGGCGGCGC 17131 CtrlJOOO Rubcnl GAGAGAACTTCGGTTTCTAT 23115 Hepal-6 Z pT80 GGAATTCGATCCGTTACTTC 17132 Ctrl_1000 Mettl23 GCTTTGGGTTGGGCGAACAG 23116 Hepal-6 ZfpT80b GGGCGATCCGAGCTTGCTAC 17133 Ctrl_1000 ffistlb2bq TTGGTCCTGTCTATTTGATG 23117 Hepal-6 ZfpT80b TTTCCCAGGGTCCACCGCAC 17134 Ctrl_1000 Tmem254b GGTGGAGCCTTGCACAGGGA 23118 Hepal-6 Kifl3a CAAGCGCCGCTCTAGCCGCT 17135 Ctrl_1000 Clqll TTCCGGCCGGCGCGGAGCCT 23119 n Hepal-6 if l a TCTCGGAGCTCTCGGCGGAG 17136 Ctrl_1000 Tspan3 1 ATTGATTGGCATTGAAGTCC 23120 Hepal-6 Kifl3a CCGAGGCGCGCGGGCCATCC 17137 Ctrl_1000 Catsperz ACCCAGTCCAGTTTCGAGTC 23121 n Hepal-6 Gas213 GTGCGGTAGAAAGTCTCCGG 17138 Ctrl_1000 MedlO CAGTTCAGAAGCTTCCAAGC 23122 Hepal 6 Gas213 AACGACGGGACAAATAGGAG 17139 Ctrl_1000 01frl347 GTTGCCATGATGAATCATCA 23123 Hepal-6 Gas213 GATAGAGACTGGACTGGAAA 17140 CtrlJOOO Pelo ACCCACAACAGACTTGCGCC 23124 Hepal-6 Iba57 TGAAATCTGCCATCTTACCT 17141 CtrlJOOO Hykk GAGGAGCCAATAGGAAGGCG 23125 Hepal-6 Iba57 GCAAGCCCAGATAAACACCA 17142 Ctrl_1000 113 ATATAAGGTGAAGGCTCCTG 23126 Hepal-6 Iba5T CTAAGGAAAGGGTCACCGGG 17143 CtrlJOOO Mril AGTAACGGATGGACGATTTC 23127 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

TACTTGCTTAACAGTCCAGA 17144 CtrlJOOO Naxd TTGATGGACGCTGACCCTGG 23128 TAGAGAAAGCATATGAGGAG 17145 CtrlJOOO Enthdl AGTCCTTTCCTTCCTCAGGC 23129 ACTTCCTGAGGTGCTCCAGC 17146 CtrlJOOO Get4 GGCGGGACCGAGGTCTTGGG 23130 o GTCACCTGTTTGGGACGCCA 17147 CtrlJOOO Shisa2 CTGCGCGCATGCGTGCCGAG 2 13 1 TGCTTGGCAAGGAACGCCAC 17148 Ctrl_1000 Hist21i3b GCCCAGAAAGCAGGAGTTTC 23132 TCCTGAATCGCCCTCGCAAT 17149 Ctrl_1000 01*1413 TTGAGAACTAAGTAAATCAG 23133 b GACTGAGGTGGAGGCCTGGG 17150 Ctrl_1000 Snrpc CAATCCGCGCTCACTTATTC 23134 4 TTGAACAGGATCGTCCAAGG 17151 Ctrl_1000 Pbdcl AGGTAACAACACGCGTTCGC 23135 AGAGTGCGAGGGCGACCAGG 17152 Ctrl 1000 Ghrl ACATAACATGGAGATGAAGT 23136 ACGTGCCTTCAGCAGTGACA 17153 Ctrl_1000 01fr711 GTAATCTAGGTAGGTCCTTG 23137 GACCCTAGACACCCGCATAG 17154 Ctrl_1000 Detl TATGGTCTCGATCTCTCCTC 23138 CCTCCAGAGAAAGTACTTTC 17155 Ctrl 1000 Ptges31 AGGAGACGCTGCTGCTCCGC 23139 CAGTGACCACATGAACCTTG 17156 Ctrl_1000 Olfr820 GGAGACAAATCAATACATTA 23140 GTTTGCCCGAAGCACTCTGT 17157 CtrlJOOO Gm42742 CATACTAAAGATGGCCACTG 23141 GAAACAGTACTTCCGGCCTC 17158 Ctrl_1000 Vmnlr63 CAATCTGCACAGGACTTTAG 23142 CGCGTTCGAACTGGCGCTTG 17159 Ctrl_1000 Acr CACAGATCAGTTAATCGAGG 23143 GGCGGTTCATTCTCCACCAA 17160 Ctrl lOOO Gml7677 TCAGTATTCAACAAGTGCTC 23144 CCTGTCACCTCTCCTCTAAA 17161 Ctrl_1000 Actrt2 TATACACCAGTGTCCTCTCA 23145 GGAGTATGGGTTAACTAATG 17162 CtrlJOOO Mettl7a2 ATAAACTCTTTCTTTGCCAG 23146 AGATGGACCCGGTGGAGCGC 17163 Ctrl_1000 Olfrl209 TTAATGTGAAACACTTTGTC 23147 GGAGCATGCGTATTAGCCGA 17164 CtrlJOOO Mcts2 GAGGATCAGCGCAAACGTGG 23148 AACCGAACCCAGGGTCGAGG 17165 CtrlJOOO 01frl7 GCTTACATTGTACTCTAAAT 23149 CAGGGCGCGCGTGTGAGTCC 17166 Ctrl_1000 Rsul ATGCTCAGTAAGCTAGCTGA 23150 o c AGACTGCGGGTCCTGCCCTT 17167 CtrlJOOO 01*1338 ATATACAACTTTGAGCTCTC 23151 CATAAGCTGCCTGCCAGTGG 17168 Ctrl_1000 OLfrl339 AGGTCCATTTCTGTITGCAG 23152 TTGTCTCAATTATGCAAAGT 17169 Ctrl_1000 Cdh22 CCCGGCGGCCGCCTGCGGCT 23153 GTTCTCACATTTCACCTTGC 17170 Ctrl_1000 01fr887 GTGGAATGTTGAAGAGGGCT 23154 ATGACTAATCTGTGTCCATG 17171 CtrlJOOO Egr4 GCCGCAGCTATATAAGTGGG 23155 TTTACATCATTTAGCAGGGA 17172 CtrlJOOO 01*665 GGAGGAGAGAGCAATGCAGT 23156 TACTAGGCAATTTGGCATTG 17173 CtrlJOOO Tmemll5 CAGTATTCCTGATGCAGTAA 23157 ACTTGATCTCCCTGTATAAA 17174 Ctrl_1000 Zfp87 GGAGGGTGGAAAGAAAGGAG 23158 TAACTTCTGAAATGTGAATC 17175 Ctrl_1000 Timp2 GCCCTACAGCGCAGCGTGCC 23159 CTGATGCCCACTCAAGCTTC 17176 CtrlJOOO Fisl TTCCTAGGATAATGTGATGC 23160 GGAGCCACGCTTCGGGCATC 17177 CtrlJOOO 0 1* 1 ATAATGTCTTTGCTGTGGGA 23161 AGTTTGAGTAAGGGCAAGAA 17178 CtrlJOOO Pradcl GTCTATAAGGAGGAGTGCGG 23162 GGCCCGCGGAGCCATCTGAT 17179 Ctrl_1000 Krt20 AGGTGACACGGCAGCAGAGG 23163 GATGTGGGACCAGTCCTTGG 17180 Ctrl_1000 Idnk CTCACAAAGACAGCAGTGAA 23164 TCACGCCTTACCTGCAGAGC 17181 Ctrl_1000 Texl3a CTACAGCAAGTAGACAGACA 23165 n ATAAATAGTTCAGCAAACAG 17182 Ctrl_1000 01fr229 TGTGTGTGTGTGTGTGTGTT 23166 TACTAGTGTAACAGAGTCCT 17183 Ctrl_1000 Lrrc42 CCCGAGGCAATGCAATGTAA 23167 n TTTCGGGCAATTTCCCGCTG 17184 Ctrl_1000 Peal5a GGCAGGACTGGGATGGAATA 23168 o CCAGATATGGGCGTGTCCTG 17185 Ctrl_1000 01fr399 TATCAAGTATTGCAATGTCC 23169 TGCAGAGCCCTCGGCGGTCG 17186 Ctrl_1000 Lysmd3 AGCACGCAGGCGCGCCGATG 23170 AGCAGAGTGTGCACCGGGCT 17187 Ctrl_1000 01frl45 1 CCTGTAGAAATGAGAATTAA 23171 GGAGCTGGGCGTCGCCATCC 17188 Ctrl_1000 Lcn4 CCCTCTTGGCCATTTGTCAT 23172 J GGCTGGGCCCTTGCTTCCTC 17189 CtrlJOOO 01*45 GGTCCACTGCTATGTCTTTC 23173 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Champl GAGACAGAAGCCCAGGCCTG 17190 Ctrl 1000 Cd59a GTTAGGAGTAAGAAATCAGA 23174 Hepal-6 Champl GGTTCCCAGCTGGGCTGTGC 17191 CtrlJOOO Nftil GCCCTGCAGAGAGGGCGGTC 23175 Hepal -6 Serpina3j ATTGGCATAAGGCTATTAGG 17192 CtrlJOOO Npy5r GGGACTGTCACGTGTTCCCG 23176 Hepal -6 Serpina3j GCGTTTGTGCCCATCTCTGT 17193 CtrlJOOO C3arl TTAAGAGGTGACTCATGGAA 23177 Hepal -6 Serpina3j TGGTGATAGGAAAGGGTACA 17194 CtrlJOOO Zfp85 GGCAAAGAATTTAAAGCGCA 23178 Hepal-6 Tamil AGTGAGGCAAGTCTCTGAAG 17195 CtrlJOOO Vmnlr229 CACTGGAGTTTCTATATCCA 23179 Hepal-6 Tamil CCTCTTCCGTTTCAAATTTC 17196 Ctrl_1000 Cracr2b GCCAACAATAACGGTTGTTC 23180 Hepal-6 Tamil GGGCCTAACACTGGGCTTGC 17197 Ctrl_1000 Pcdhbl7 ATAGTTTAGTTCATGGGTCT 23181 Hepal -6 Igtp AGACTTCTGACCTCTATACC 17198 Ctr OOO Ndnf TCAAGCTCTGCAGTGACACC 23182 Hepal-6 Igtp GGAGGTAGCAGGGTCAGACA 17199 Ctrl_1000 016914 GCAATTGTCATTTCACTTCA 23183 Hepal-6 Igtp GGGTAACTGGGCCAGATTCC 17200 Ctrl_1000 Nedd8 TCCTGAGCGTTTCGGGAACC 23184 Hepal -6 Gsta2 TCAGGAACTGGCTATATTAG 17201 CtrlJOOO Gml3290 AATTCTCAAGGCGCGATGGA 23185 Hepal-6 Gsta2 TCTATGTGTGTCTATGGGAG 17202 Ctrl_1000 Ldlradl ACACTCATCTCCAGGAACTG 23186 Hepal -6 Gsta2 CAACAATTCTTACCCAGTAT 17203 Ctrl_1000 KbtbdS CAGTTTGTAACGTACCCTGC 23187 Hepal -6 Ttc3 GCTGAGCCGCGCCTGCGCAT 17204 Ctrl_1000 Mom4 GGGCCAAAGATCTGAAAGAG 23188 Hepal -6 Ttc3 TTTAATTTCCGCCCACGCTG 17205 Ctrl_1000 2210011C24Rik GAGCACCGGACCGAGCGCCC 23189 Hepal -6 Ttc3 GCACCGCGACCGCAGCGAGG 17206 CtrlJOOO Snmp35 CAGATTCGCCACGACGTCGT 23190 Hepal-6 Cuxl CGGGCTGTGGAGAGAGAGCG 17207 Ctrl_1000 Brkl CTGAGGAAGAGTGACTGCGC 23191 Hepal-6 Cuxl CGTGAAAGTGACTGCGGAGC 17208 CtrlJOOO Vmn2rl 1 ATACTGCCCAGGCTCAGAAC 23192 Hepal-6 Cuxl CCTACGGCGGCCCGGCCTCG 17209 Ctrl_1000 Gchfr GGACACTGCACGAGCCAATC 23193 Hepal -6 Pzp TTACCCAAATGTTTGAAAGA 17210 CtrlJOOO Ctsg CAAACCTCCTAGGAAGCTTT 23194 Hepal -6 Pzp TGCAGGCTGCCACTAGCTCA 172 11 CtrlJOOO Fsbp CGTAAGTCAGCTTAAGCTGG 23195 Hepal -6 Pzp GTTTACTTTCACTGCCCATC 17212 CtrlJOOO Leng8 TTCGCGAGACGTGTGGTGGG 23196 o so Hepal-6 Th TGGGCACAGAGCGAGGGCGA 17213 Ctrl_1000 016800 AACAGAATGTGCATATAAGT 23197 Hepal -6 Th AAGAGGCCGCCTGCCTGGCA 17214 Ctrl_1000 Itm2a TCGGTTGCACTGCAGAGCTC 23198 Hepal -6 Th CAGGCACAGCAGGCGTGGAG 17215 Ctrl_1000 Mgat4d GTGCCTGGGAGAAAGTGTTG 23199 Hepal -6 Scg2 CAGCACAAATTCCCTTAGAA 17216 Ctrl_1000 016635 CATTAAACACAGCATCATTA 23200 Hepal -6 Ikbkap CCACAGTTGGGCTTTGGCCC 17217 CtrlJOOO 01691 AAGACAAGACGAGGAGCGGT 23201 Hepal -6 Ikbkap CTGAGGGACAGCAGACAGCA 17218 Ctrl_1000 Cdc 14b CCTTCCTACAGGCAGGTACT 23202 Hepal -6 Ikbkap CGCGTCTGGCCACACCCACC 17219 CtrlJOOO 016549 TAGAATAGCAGAAAGCATTC 23203 Hepal -6 Maml3 TGGAGGCCGTGAGACAAGCC 17220 CtrlJOOO Spate 1 TACCCAGAGCCTACTAGACC 23204 Hepal -6 Maml3 AAGGGAGGCGGGAGTCAGGT 17221 CtrlJOOO Pth GTTAAGGATGATGTCACTCC 23205 Hepal -6 Maml3 GAGCTCAGTAAACACGGCAG 17222 CtrlJOOO P s GCAGTGTTCTGCATCCCAGT 23206 Hepal-6 Cd69 TTCAGCCTTTATACTCGATT 17223 CtrlJOOO Slc38a3 AATGTGATTGGCCTTACCCA 23207 Hepal -6 Cd69 GAGCATAAATTAAAGAGAAC 17224 Ctrl_1000 Gml7018 CATCGGTCGGGTAGTTGCCA 23208 Hepal -6 Cd69 CGGTGAAGTGTCTAGGCCGC 17225 Ctrl_1000 Hdac8 TCCATCCCTGTAGTTGGACG 23209 Hepal-6 Gm829 TGACTCAGCTCACAAGGCAG 17226 CtrlJOOO Nkx2-1 TGGACCGAGTCCGCCTTAAT 23210 Hepal -6 Gni829 TGTGGATGGGTCATGACTCA 17227 Ctrl_1000 Nxph4 GCTCCGCGGTGCTCCAATCC 23211 Hepal -6 Gm829 CAAGGAGTTATTTGTAGAGC 17228 Ctrl_1000 Tnfaip6 GGTCAGCATGTATTCTCCAA 23212 Hepal -6 V e CCAAGTTGGAAAGAAACTTC 17229 Ctrl_1000 Nemp2 TGCTCTGAGAACCCTGCGCG 23213 Hepal -6 Vwce AGAATTCAGATTGGATTCTA 17230 Ctrl_1000 Dcpp3 TTGGCAAATACAGAGTGTCC 23214 Hepal 6 Vwce CGAAGCCTTCAGTCATTCTG 17231 CtrlJOOO Smr3a GGCAATAAAGAAACACAAGT 23215 Hepal -6 Btd TGTCACCAACAACAACTCTT 17232 Ctrl_1000 Prl7cl CACCATAACAATTGGGACTA 23216 Hepal -6 Btd CTTACATGATCGCCTCACCA 17233 Ctrl_1000 Rxfp4 GGGTGTTGGTCTAGAGCTTC 23217 Hepal -6 Btd CCCAACGGATTTAAGCAAAG 17234 Ctrl_1000 Vmnlrl32 CGTCCGCACATTTGTCTTCA 23218 Hepal -6 St3gal6 CAATAAGGAGGAGCTTCCCG 17235 Ctrl_1000 Kritl GCACGGACCGGCACGAACGG 23219 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 St3gal6 AAGTGCTGCCCGGTGGCTGC 17236 Ctrl 1000 Tnfaip813 CGGACTCTACCCTCGCGTGC 23220 Hepal-6 St3gal6 AGAGAGCACGGCTACCGCCC 17237 Ctrl_1000 Marveldl AGGCCTGTCATGGGCCAGGG 23221 Hepal-6 Clca3al CCTATCATGGCAAATAGCCA 1723 S Ctrl_1000 Gm2016 ATTGAATTATTCTTGGAGCA 23222 Hepal-6 Clca3al CTTTGTATGATAGGCCTTAT 17239 Ctrl_1000 Mrpl54 TGGAGGTGTTGGAGGCGCCG 23223 Hepal-6 Clca3al TCTTCTGGGAAGAATGTTCA 17240 Ctrl_1000 Tmeml77 TGAGCAGGCGCAAAGCACGC 23224 Hepal-6 Ppplr3g AGAGGTGGCAGTTGCAGGCC 17241 Ctrl_1000 Dgatl GATGCTGCGGAGCAGCTGAC 23225 Hepal-6 Ppplr3g ATGAATGCCTTCAAGTCTGA 17242 Ctrl_1000 Vmn2r28 CAGAITGCTCCTGGCCCTGT 23226 oi 4 Hepal-6 Ppplr3g GCTAGGCGCCAATGGCCACC 17243 Ctrl_1000 1810009J06Rik CCGGTATTCTCTAAAGGTTA 23227 Hepal-6 Gpx5 CTTCAAITCTCTAGGTTTGC 17244 Ctrl 1000 Mapre3 GGCAACCGGGCGGCCAGAAG 23228 Hepal-6 Gp 5 TGAATTCGGAGTGCTCGTGG 17245 Ctrl_1000 Xafl TTGCCCAGCCTGACTCACAG 23229 Hepal-6 Gp 5 TGGTCTTAATAGGTGTGGGC 17246 Ctrl_1000 Slc35 3 TCGCGGATGTGAAGTCAACT 23230 Hepal-6 G TGGGATGAAGCTTTCTGGCG 17247 Ctrl 1000 Gm996 ACTGTGGACCTTCTTTGTAG 2323 1 Hepal-6 Ghr TGGTGCGTGTCGCTCTCAAT 17248 Ctrl_1000 Vmnlr34 TATTCACCTTAAGCACATAG 23232 Hepal-6 Ghr GGAGTACGTCTGCTGGGACC 17249 Ctrl_1000 01fr3 12 AGGTCCATGTTTACTCATTG 23233 Hepal-6 Filipll CGTCACCGCTCAGCCTTATA 17250 Ctd_1000 Leprotll CGGAAGGAAGGACGCCGGCC 23234 Hepal-6 Filipll TATAACTTTCTTTCCTTGTC 17251 Ctrl_1000 P l cl GAGAGTTAGAGGAGAGTAAG 23235 Hepal-6 Filipll TGTGAGGGTCTGGGCTGTCG 17252 Ctrl 1000 01fr231 AGGGACTTCCTGGAATTTCC 23236 Hepal-6 Itpkb TTCTATTGCTTGGCAAACCG 17253 Ctrl_1000 Olfrl 196 TAGCAITGGAAATGTAAATG 23237 Hepal-6 Itpkb GGTTGAGGGAGGAGGCAGAG 17254 Ctrl_1000 a 24 GTCCCTACCGCCGCCATCAG 23238 Hepal-6 Itpkb AAGGAAGTTGTGAGCCTGTC 17255 Ctrl_1000 Crebzf TGGATCGAGGAGAGTGGTAC 23239 Hepal-6 Dars2 GCGTAACTTTGGCGCTCGCC 17256 Ctrl lOOO Vmnlr232 CGATGGTTAGTGAGTCCAAG 23240 Hepal-6 Dars2 TATGCGGGAAAGTTTCGCAC 17257 Ctrl 1000 A TCCCTCCCAAGCAAGCAATC 23241 Hepal-6 Dars2 GAAGAACAACGCGGCGCAAT 17258 Ctrl_1000 Us 2 GCGGCGTGAGCGCCGGGCTC 23242 o Hepal-6 Og l TTCCGCGCGTCGTGACGTCT 17259 Ctrl_1000 Fatal 10b GAACTTGGAGCCAGTTGCTG 23243 Hepal-6 Ogdhl GGAAGCACCTGGCTCTTTGG 17260 Ctrl_1000 01fr447 ACAAGTCAAGAATATTAGGA 23244 Hepal-6 Ogdhl GATCTGGGAGGTCAGCACCT 17261 Ctrl_1000 Tmem79 AGGGCCTGCGCCTTTAATCT 23245 Hepal-6 Pramel5 CTCCTTCCAACACCCTTATA 17262 Ctrl_1000 Fdxacbl CGCATCAACAGCTTGTTACC 23246 Hepal-6 Tas2rl l 9 AAGGAAGCAGAAATCATACA 17263 Ctrl lOOO P2ix6 TATATGGTGGGCAGTCAACA 23247 Hepal-6 Tas2rl l 9 TGATGCCAACCCAAAGACAA 17264 Ctrl_1000 Phospho2 GTGCAGAGCAGTGGGCGAGC 23248 Hepal-6 Tas2rl l 9 CAACTAGACCAAGGTTCCTT 17265 Ctrl_1000 Slc6al8 GATGTCAGTTATCAATTAAC 23249 Hepal-6 Espl TTCTCGCTGATTGGTCACTA 17266 Ctrl_1000 01fr435 TGAAATGTGAGTAAATTGAC 23250 Hepal-6 Espll TAATTGACTGAGGTTGAAGA 17267 Ctrl_1000 01fr982 TGCGCAATAAAGCTGACTGT 23251 Hepal-6 Espll CGCTGTCTGTCACGTGTTCC 17268 Ctrl 1000 01fr348 AATGGGAAGCATTGCAGTTA 23252 Hepal-6 Shank2 CGCCATGGAGGCCAACGCTG 17269 Ctrl 1000 01fr47 TGTCATGTTTCTGAAATCTG 23253 Hepal-6 Shank2 CCCAGTTATCCAAGGAAACC 17270 Ctrl_1000 Tcaml CGAGTITCTGGGCAGATCAG 23254 Hepal-6 Shank2 CTCTGCGCGGGATGACGCCC 17271 Ctrl_1000 Kdm8 CTGCTCTGCAAGGTATGACC 23255 Hepal-6 Smarcall ATTTGAGAGGCGTAACGTTG 17272 Ctrl_1000 Spin2c TCCTCTCCTACTCCACACCG 23256 Hepal-6 Smarcall ATCACCCACAATTTATGACC 17273 Ctrl_1000 Spmt3 TTCACAGGTTGCAGTTAACT 23257 n Hepal-6 Smarcall GAATCGGAAAGCCTGCCCAT 17274 Ctrl_1000 Lias TCCTCACCTCGCAGTAGATG 23258 Hepal-6 Speer3 CATCAATACATGAGAGTTCT 17275 Ctrl_1000 Olfr344 CCTCTTCTGCTGTGAATGAA 23259 n Hepal-6 Speer3 CAACAATCTGAAATAGTGGC 17276 Ctrl_1000 01frl321 GTACTACACAGGATACATGG 23260 Hepal-6 Speer3 ATGGCTATAGCCATACTGGT 17277 Ctrl_1000 Agpatl AGCGTGCAGAACCTGCCTTC 23261 Hepal-6 Nudt7 GCCTATAGGTAGGGCGTGTT 17278 CtrlJOOO Phox2b GGGCTCGGTGCGTAATGGTG 23262 Hepal-6 Nudt7 GCACTTCGGGCGTCTTTGAA 17279 Ctrl_1000 Snul3 ATTAGCGTTCTAGTTAGGAT 23263 Hepal-6 Nudt7 GGCGGAGTTAGGTCCGAAGG 17280 Ctrl_1000 P t 3 AGCCACTGTTCAACGGCTCC 23264 Hepal-6 Cdhl5 GCCAAGGGACTGCACGTGTG 17281 Ctrl_1000 G6pc2 TCATCTGCTTATGACTTTAA 23265 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 1,809 - 23,776)

Hepal-6 Cdhl5 CTACACTCTTGTGGCTGTCC 17282 Ctrl 1000 Hoxc6 CACATACTTAGTCTCAACTA 23266 Hepal-6 Cdhl5 GCTAGGGCTGAGTGACTGCA 17283 CtrlJOOO 01*550 GACAITCATTCATGTGATCA 23267 Hepal-6 Trmtl3 AAACAAACATTTCTGTGTGC 17284 Ctrl_1000 0 r3 2 GACTTGCATCAGAGGTTTCT 23268 o Hepal-6 Trmtl3 TTACATTTCTCTGATGTGCA 17285 Ctrl_1000 Zfp688 AACGAACGCGGCAGCCTTAC 23269 Hepal-6 Trmtl3 AAGACAGGCAAACAACAGCC 17286 Ctrl_1000 Cleclb CGTGAACTTTGTCATTTGAC 23270 Hepal -6 Cenpq AGACGCGCGCCCGCAATGTC 17287 Ctrl_1000 Pgkl GTCGTGCAGGACGTGACAAA 23271 Hepal -6 Cenpq GGATTGGATTGGCTAATCCG 17288 Ctrl_1000 Gm4894 CTTCCAGCACGTACATTAAG 23272 o 4 Hepal -6 Cenpq AAGACATACGCTCCGCAGGC 17289 Ctrl_1000 Izumo4 GGGCGGGACATGTCTAAGCG 23273 Hepal-6 Sipal AGAGAACTTCAGGCTGTCCG 17290 Ctrl 1000 Agtr2 TTTGAATGAGCTGTTATGAT 23274 Hepal-6 Sipal TCACTGACTGGGCTAGGACC 17291 Ctrl_1000 Ceptl TGGGCCTGTTCTGCACTTTG 23275 Hepal-6 Sipal GACTACCCGGGAGCTGTCTA 17292 Ctrl_1000 Slamf7 ACGCCAAGCGATGTGAAGCC 23276 Hepal -6 My i8 AGGGAATCTTTGACAGCGCC 17293 Ctrl 1000 Isg TATGAGCTGTGGGTGTGAAG 23277 Hepal -6 My AACTTATGAGAAGGCCCACC 17294 Ctrl_1000 Nat8f4 TTCACCTGTAGCATTTAGCC 23278 Hepal -6 Myh8 GTCGCTACAAACTTCGCCGA 17295 Ctrl_1000 Tcf l GCGGGCGCGAAGTCGGACCC 23279 Hepal -6 Adgrf2 TACTGGGAGAGGCACGGAGC 17296 Ctrl_1000 Ufdl TCTCTTCCAAACAACTTGAT 23280 Hepal -6 Adgrf2 GAGAGAGTGTCAGAGTCACT 17297 Ctrl_1000 Tmem239 CACTTATGTCCTTTACTTAA 23281 Hepal -6 Adgrf2 TGGCGGTGGCATGAGAATTG 17298 Ctrl 1000 Fbxw9 AACACCTGCCAGATATTGCT 23282 Hepal -6 Ankrdl 1 GGCGGATACGGCGAGCCAAT 17299 Ctrl_1000 Tex37 GGGATAGGGCAACTGACATG 23283 Hepal -6 Ankrdl 1 GCGGGAGGCTCTCATGCGGC 17300 Ctrl_1000 Ccdcl82 ACACTATCACTTGAAGTCGT 23284 Hepal -6 Ankrdl 1 TGCCTGITACGGAAGCCGTC 17301 Ctrl_1000 Intsl3 TCGCGAGGCTTGTCGCTCAG 23285 Hepal -6 Senp6 TGGCCITGTCTGGCCGGCCT 17302 Ctrl lOOO Procal GCCAGAAGTGTCTGTACCAG 23286 Hepal -6 Senp6 GGGCTGTCGTCCTGCCGGCC 17303 Ctrl 1000 Hsdl7bl2 AGGAGACATAGTACGCTTAC 23287 Hepal -6 Senp6 GTTCGGCCGAGCCCGGAGGG 17304 Ctrl_1000 Sral AGTTGTCCTTTAATGAACGG 23288 Hepal-6 H2-M10 4 CCTAGAAATCTCCCACACCC 17305 Ctrl_1000 Delb33 CTAGTCAGCAGGGTCATAGT 23289 Hepal-6 H2-M10 4 GCTGTACAACTGGTGCCAAG 17306 Ctrl_1000 Irf9 CAAGGGCGGAGCTGAAGAAA 23290 Hepal-6 H2-M10 4 CTGATGTGGCTAATGCTGAT 17307 Ctrl_1000 Ppmlb AGAAGCACAGAAGATACTAG 23291 Hepal -6 Itgbll TCTTGTCTTTCTTCAAGTAC 17308 Ctrl_1000 01fr816 GCTTGTCTAAATAAAGTGTG 23292 Hepal -6 Itgbll GGCAGTGGATCCGCTTTGGG 17309 Ctrl lOOO Crip2 GGGCGCCGCGGTCCTGTCTG 23293 Hepal -6 Itgbll GAAACAGTTGTACAAGCAGA 17310 CtrlJOOO jd4 GACGCAATGGCACGCTCCAC 23294 Hepal-6 Hspal2a GCGGTTTCAGAGCTTGTGGG 17311 Ctrl_1000 Naa40 CTGCCTTCGCTGAGGCGCGC 23295 Hepal-6 Hspal2a TCCAGGGCCTTGGCTCCGTG 17312 Ctrl_1000 Pcdhb5 CCTGCTTTAAGTTGTATAAT 23296 Hepal-6 Hspal2a GGTGCGCTAATGACAGCACG 17313 Ctrl_1000 Pexl6 TGAACAGTTCATACTAGAGA 23297 Hepal-6 4930579F01Rik AGGCTGGAGAAGATGTTCAG 17314 Ctrl 1000 01frl388 TCATGGTTTGCACTGGTCAA 23298 Hepal-6 4930579F01Rik AGCCAGCTCTTGATGGAAAG 17 1 Ctrl 1000 Aasdlippt CAACCCTGAACTAAAGGTGG 23299 Hepal-6 4930579F01Rtk GTTGCTTAGTTACCATTGTA 17316 Ctrl_1000 2610318N02Rik TAGGCGCAAGCCAATGAGGC 23300 Hepal-6 Elk3 GCTTAGGGACCTCCCTTTCG 17317 Ctrl_1000 Hilsl AGTCTGCTGAGGCCAATCGT 23301 Hepal-6 Elk3 TCCTAAGTTTGGCATCACCC 17 1 Ctrl_1000 Igflrl TAATATAATCTGTTCGACAC 23302 Hepal-6 EI 3 CATTAGCAGGGCACGAACCC 17319 Ctrl_1000 Higdlc TGGCTATCTGGTATTGGTCG 23303 n Hepal-6 Tsscl AGCGGGAATGGACGTCCATC 17320 Ctrl_1000 Cxcr5 AAGGTTTGTGCTGGTGCCTA 23304 Hepal-6 Tsscl TTATTCTGCGCATGCTCATT 17321 Ctrl_1000 Nudt8 GGACCTAAGTGGGAGCCGGA 23305 n Hepal-6 Tsscl GTCATCAATACGCTCCTCCC 17322 Ctrl_1000 01*74 GCACACTTTACTTATCCTAC 23306 o Hepal 6 Nlrpla GGCATCTGCAGAGACTTAAC 17323 CtrlJOOO Napepld AGGCTCACCCGCAGGCGCTC 23307 Hepal-6 Nlrpla CACCCTGACTCCTCCAGCCC 17324 Ctrl_1000 Gm8298 GGTAGAAGACATATCTGTCT 23308 Hepal-6 Nlrpla GATGTACTTCCTCTGAACAC 17325 CtrlJOOO ffitm6 TTCAAGGAAGTTCATATGGG 23309 b Hepal-6 Synel AAGGGTTCCTGAGACAGCCA 17326 Ctrl_1000 Drc3 AGCTCGTTGACTGTGCTGAT 23310 Hepal-6 Synel GATTACCCTTCTTACCCTCG 17327 Ctrl_1000 Drd4 AACTCTAGGAAATTGGCAGA 2 11 J Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Synel GAGCCGTAACCTGCTCTTGC 17328 Ctrl 1000 01fr667 TATAAATCAAAGGTAAGCAG 2 1 Hepal-6 Cdhl GATTCGAACGACCGTGGAAT 17329 Ctrl_1000 Xpnpep3 CGAGCAGTTGACTGGTTTCC 23313 Hepal-6 Cdhl GCTGGGAAGTCTTCTAAGGC 17330 Ctrl_1000 T 7s 3 AAGGAAAGAAGAAGAGAGAA 23314 o Hepal-6 Cdhl CCTGTCTGTAGTTGGTGGCA 17 1 Ctrl_1000 H2allj TTGGTTATTTGGAGAGCCTT 23315 Hepal-6 Ankl CAGAGTCTGTTTGTGCCTCG 17332 Ctrl_1000 Rhox3c AAGGAAGGGCACAAACCTCG 23316 Hepal-6 Ankl CTCCTCAGCTTCATTCACTG 17333 Ctrl_1000 Hba-x TAGGGCTTGGTGGGACTGTA 23317 Hepal-6 Ankl AACTCITCCATCACATCCAG 17334 CtrlJOOO Fkbpll TGCCATTACCAACTGTAAAG 23318 o 4 Hepal-6 Rsad2 CACAGTGATCAAATGCTTGG 17335 Ctrl_1000 Smox GCTGTGCCGCGGGCAACTCC 23319 Hepal-6 Rsad2 CTGTTTAACTGAGTCAAGGG 17336 Ctrl 1000 Endodl ATTTATTTAGCAGGGTCTTA 23320 Hepal-6 Rsad2 CAGAGCCAAGACTGAACCTT 17337 Ctrl_1000 Chstl4 CCCTCCCTGATACAGGCGCG 23321 Hepal-6 Myol5 CTGGTGATTATAGAGAAATA 17338 Ctrl_1000 Poml21112 TTGTAGAGATTATAACGCTC 23322 Hepal-6 Myol5 AAGGGAGAGAGCTCTAAGGC 17339 Ctrl 1000 Msmp CCCTCCTCCTGGCTGTGTGG 23323 Hepal-6 Myol5 CAGCCTGGAAAGCAAGTAGT 17340 Ctrl_1000 3110082J24Rik GGAAGCGAGTGTGCCAACGC 23324 Hepal-6 Uhrflbpll AGGGCAGCGGAGGACCTAGT 17341 Ctrl_1000 Zfplll ACCTAGCTCTGGTGCTCTIT 23325 Hepal-6 Uhrflbpll TAGGCAGGGCTGAAGATTCC 17342 Ctrl_1000 Nmnat2 TTGCGTCTAGAGCGGCTCCT 23326 Hepal-6 Uhrflbpll TGAAAGCCCAAGTACCAACT 17343 Ctrl_1000 MrpMl GGTGGTCGGGCTCTAGCCTA 23327 Hepal-6 Btn2a2 GACTTAAGGCAGGCCAATCC 17344 Ctrl 1000 Plppr3 TCCCTGGGCGCCTGAGCAAA 23328 Hepal-6 Btn2a2 GCTAGACATAGGAATACTAT 17345 Ctrl_1000 KrtSl GCAATTGGACTTTATGGGCT 23329 Hepal-6 Bt 2a2 GAAGAAAGGAGCGCATGAAA 17346 Ctrl_1000 Etfbkmt GTCTGACCTGAGGAGTCGCC 23330 Hepal-6 Esyt2 GGTCGGCTGTCTCTGAACAG 17347 Ctrl_1000 Hsdl7bl TAGTTACAAACAGCACCCTT 23331 Hepal-6 Esyt2 TGCGCCCGACTCTTCCTCAC 17348 Ctrl 1000 Olfr209 ACCAAGACTCAGTAAGAATG 23332 Hepal-6 Esyt2 GCTTGCTCGGGCTGAGTGCG 17349 Ctrl 1000 01fr434 TTTAACTGACACCCAACTTT 23333 Hepal-6 Parg AGTATCGCACTTCCGCTTTA 17350 Ctrl_1000 Snmp27 CATCTGTTTGCTGGAGCCGC 23334 to Hepal-6 Parg CACGGCCGAGCATACGTCCC 17351 Ctrl_1000 Adora3 CAGCTGACAGTTTCAGCTAC 23335 Hepal-6 Parg GCGAGACGGCTGCTTTCCGG 17352 Ctrl_1000 01frl48 TCAGTCTCTTGGCCTGTTCA 23336 Hepal-6 Fgd2 GGTCAGATGCCAAGAGGGCC 17353 Ctrl_1000 01*225 TTGTTTAATGCTTGCCTGTC 23337 Hepal-6 Fgd2 GGAGCCTGTGAAGTACTGCC 17354 Ctrl_1000 Amigo2 TGCGGTCCCACCCGGCCGAG 23338 Hepal-6 Fgd2 GGCCTCTCTTCCAAGCTACT 17355 Ctrl 1000 RslcanlS ACAAGATCCTGGCATAGTGG 23339 Hepal-6 Fvl GACGCAGTAGCCGAGTTCTA 17356 Ctrl_1000 Ldhd CTCCACCCAGGGCAGCTATT 23340 Hepal-6 Fvl AATTTGGATCCGAGGCTTGT 17357 Ctrl_1000 Qrichl GCGCTCCTTCCCACAACGAG 23341 Hepal-6 Fvl CTAATGGCAGTGGATAGGTG 17358 Ctrl_1000 Echdcl CGCGCTGTGGCGTGATTGGG 23342 Hepal-6 Nkapl AGGGCTCTTGCGCAGGCTCT 17359 Ctrl_1000 01*963 TTTATGGATGAATCAGCTCC 23343 Hepal-6 Nkapl GCGCTGTGTGCGGGTTGTGC 17360 Ctrl 1000 Ttim8 GAGAAGCCCGGGAGGTGCTC 23344 Hepal-6 Nkapl CAGCGCCACGGTTCGGACTA 17361 Ctrl 1000 Rab5b AGATCACCCGCCTACCGTGG 23345 Hepal-6 Adgrfl AACGGGAAGTCTTTGGTCTC 17362 Ctrl_1000 Ldhb CCTCTAACTTTAGAGAGCGG 23346 Hepal-6 Adgrfl TTTCAGCAGAGGCAGCAACC 17363 Ctrl_1000 01*112 CCATTATGAAGACAAAGTGT 23347 Hepal-6 Adgrfl GTTGGCTTTCCCTCTGCAGG 17364 Ctrl_1000 Rsphl ATAGTGTCCTAGCAACTGGA 23348 Hepal-6 Slcl5a3 TTCTGCTTCTTAAGAAACCC 17365 Ctrl_1000 Gml0267 GGTTGTAAATTAAGTCATGA 23349 n Hepal-6 Slcl5a3 AGCCTGCAGACGGGCTAAGA 17366 Ctrl_1000 1700010D01Rik TCACAAAGCACCTTGCTGCC 23350 Hepal-6 Slcl5a3 CTGTGGCTGCCTACGTCACC 17367 Ctrl_1000 Ucp3 CTGATCACTTGACAAGAGGC 23 1 n Hepal-6 Sta GGGCCAGGAAGCCCTGAACA 17368 Ctrl_1000 1700012B09Rik GGTCTGTAGCTAAGGAATTA 23352 o Hepal-6 Stabl CCCAGGCAGGTGGCTAATGG 17369 Ctrl_1000 Krtcap3 TGGCACCGCCGCTTCGGTTG 23353 Hepal-6 Stabl GGCCCAGGTCGTCCATGTGG 17370 Ctrl_1000 Zfp536 GGGCGCGTCACGGCTACGCC 23354 Hepal-6 Tdidl2 GTAGTTCACCGCCCAGCCTG 17371 Ctrl_1000 01fr916 GGATAATCCACACTCCATGC 23355 b Hepal-6 T d l 2 GCATGCAGTCACTCCATGGG 17372 Ctrl_1000 Map7d3 AAAGCTATTAACTTTGTCTG 23356 Hepal-6 Tdidl2 CGCACCAACGGCCTGGATAA 17373 Ctrl_1000 Spata46 CATGATTCCATTAGCCAGTT 23357 J Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Ore 3 TCGTAGGTCGATCGCCTGTC 17374 Ctrl lOOO Sec 1415 CAAGGCGCCTCCTGGTGATT 23358 Hepal-6 Ore 3 AGAGGCGACTTCCGGCGCGG 17375 Ctrl_1000 Aqp8 TTCTGGGCCACCTCCCATTC 23359 Hepal-6 Ore 3 AGTCCAGAGCGGCGAGCCAG 17376 Ctrl_1000 B 1 GTGTGTTCGCCATGGCCACC 23360 Hepal-6 Allc GGGCATAGGAAATAGAGCCG 17377 Ctrl_1000 01fr645 AGGITATGAACCTCCAGCTA 23361 Hepal-6 Allc GAAGAGGCCTGCTTCAGCCA 17378 Ctrl_1000 Olfrl 105 TCCTTTATAGGAGATCTGTA 23362 Hepal-6 Allc GCCAGCAATGTTAGAATTTA 17379 Ctrl_1000 Olfrl 27 9 GTTTCAATTCACTTGATGTG 23363 Hepal-6 Manba CTCCAGCTCGATCCTGTAAG 17380 Ctrl_1000 BC049352 CTTATTGAGTTAGGTTGCTG 23364 Hepal-6 Manba GAAGCGCTCAGCTGACCTGG 17381 Ctrl_1000 Vmn2r65 GATACTTGGGCTTTGGCCTA 23365 Hepal-6 Manba CTCACAGGTCGCAGAGACCC 17382 Ctrl 1000 Coxl4 GGGCCGCTCCAGGCGGTAGG 23366 Hepal-6 Smcr8 GGTGTTGGAGGAACGTGCAC 17383 Ctrl_1000 01fr291 TATATTCCCATTCTATCCTT 23367 Hepal-6 Smcr8 AGTTAACGGGACTTGTCCTC 17384 Ctrl_1000 Vmn2r79 TTCTCAAGCACCTATCTTGA 23368 Hepal-6 Smcr8 GATTGGCAGGGCCTCTTAAA 17385 Ctrl 1000 Tbxl GCGCTTCCGTCACAGCGGTA 23369 Hepal-6 Lrig3 GAAGGCGGGCGCGCGCCCAT 17386 Ctrl_1000 Avpil CGAAGGCTCCGCGTTCGATT 23370 Hepal-6 Lrig3 AGACTGCTGGCTGCAGACGC 17387 Ctrl_1000 Gm6902 TTTCATGGTTTGACAACACC 23371 Hepal-6 Lrig3 GGCGCGATGTCCCGGCGCGG 17388 Ctrl_1000 Timm9 GGTAACGAATCTGCGTCTAA 23372 Hepal-6 Bace2 GGCCTCCCGGGCACGTTCCG 17389 Ctrl_1000 Ppwdl GGGCCTTTGCCAGTCAGAGC 23373 Hepal-6 Bace2 CTCGTCATATCCGTTAGCCG 17390 Ctrl lOOO Esp24 GTCATCCGGGATTAAAGGTG 23374 Hepal-6 Bace2 CTCCTCCGTGGCCAAGGTCA 17391 Ctrl_1000 Slc35f6 CCGGAGCTGCCACCGGTCTT 23375 Hepal-6 Chst4 AGAGAGAACGGTGCTGAGCC 17392 Ctrl_1000 Gml6405 ACCAGACACCATCACTTCTA 23376 Hepal-6 Chst4 GAGCCTGTCTTGCAAGGCGG 17393 Ctrl_1000 Kmt5c ATCCAGCGAACTACAGCCAA 23377 Hepal-6 Chst4 AGAGGGCAAGCAGAAGGGTT 17394 Ctrl lOOO Elf l CCTTGGGCTGAGAGGCCGGG 23378 Hepal-6 Ccdc93 GGAACCACTGCGCCTGCGCA 17395 Ctrl 1000 Krtapl4 ACACTATTACCTGAATTCCA 23379 Hepal-6 Ccdc93 AGTTCAGCACCTCCTCTGAG 17396 Ctrl_1000 Deft>2 GCATTTCCAGTGCTGTTGAT 23380 Hepal-6 Ccdc93 GGACAGCCAGCACTGCTGGG 17397 Ctrl_1000 Vamp2 GGCAGGCGACACGTCGCAAG 23381 Hepal-6 Nlrp4e AGTGTITGCTGCACAAGTTT 17398 Ctrl_1000 1 il GGAGACGAAGTGAGGAACCA 23382 Hepal-6 Nlrp4e TCAGCATTTATGTAACAAGC 17399 Ctrl_1000 H2alla GATGTAACAAAGCCCTCTCA 23383 Hepal-6 Nlrp4e GTCTTGCCTGCAAGATGTGC 17400 Ctrl_1000 Naglu AATACCAAGCTCCGGGCCCG 23384 Hepal-6 Prdm2 GAGGGCGACACAGTCCGCCG 17401 Ctrl 1000 P ol GGGACCTTAATTCTAGCCAA 23385 Hepal-6 Prdm2 CCAGAGCGTTATTACCTCGA 17402 Ctrl_1000 01frl357 CTTAACAGGGAACCTGGGAA 23386 Hepal-6 Prdm2 CCGTCGTGTTGAGCTCCTCG 17403 Ctrl_1000 Snxl2 TGGTGCTTCTCAAACTACTG 23387 Hepal-6 Slc30a7 GAAAGTCCGAGCTGAAAGCT 17404 Ctrl_1000 Suox GAGGACTGTCAACTGTCGCC 23388 Hepal-6 Slc30a7 CTTTCGTGAGTTCAGGAGAT 17405 Ctrl_1000 Olfrl ATGAGTTACTGGACTCCTCT 23389 Hepal-6 Slc30a7 GATCTATCTCTAGCTGAGCT 17406 Ctrl 1000 Slpr4 TGGGTGGTACTTGATGTGTT 23390 Hepal-6 Tango6 TGTGTATGCGCATGAGTTGC 17407 Ctrl 1000 Nudtl3 GTAATCTCTCTGAGACTGCT 23391 Hepal-6 Tango6 TTGCAGGCTGGTGTCTGATA 17408 Ctrl_1000 Olfrl 179 ATTCAATGGCATTAGCTGAA 23392 Hepal-6 Tango6 GGATGCTGGGAATTGAACTG 17409 Ctrl_1000 Gipcl CCGTGTGCACTCGCGACCAA 23393 Hepal-6 Zfp940 CTGGCAAGGTGAGGACTAGC 17410 Ctrl_1000 Dnajb3 GCTCAGTGACGCTTAAAGAC 23394 Hepal-6 Zfp940 TAAGAGTCGCATGGACTCCT 17411 Ctrl_1000 P g l TGTGGCAGGGATAAAGCAAA 23395 Hepal-6 Zfp940 ACGCGGTAGCCAACCTAGAC 17412 Ctrl_1000 Rad51b GGGTTAGCCCAGCTGTATTT 23396 Hepal-6 Histlhld AGATCCTTTCTCTGGCAACG 17413 Ctrl_1000 Olfrl 201 TGGCATGTGAATTCCTCTCT 23397 Hepal-6 Histlhld AATATGGGCACGAAATAATT 17414 Ctrl_1000 2010003KllRik GGGAGATCACCTGTAGACAA 23398 Hepal-6 Histlhld TTATATAGAGAGAAGCTGCG 17415 Ctrl_1000 Aldh3bl CCACAACATCTATCTCATAG 23399 Hepal-6 1700019N19Rik GATTAGCGGCTAAGTTTACT 17416 Ctrl_1000 17000471 17Rik2 CTTCGTCGCTTCCGCGGGCC 23400 Hepal-6 1700019N19Rik GGGCAGATGCTGGATTCATA 17417 Ctrl_1000 Gm8765 CACATCTCACACTGCACTCA 23401 Hepal-6 1700019N19Rik GACATTGGAACAAGAACTAC 17418 Ctrl_1000 Rn 34 AGGGACGCTCAGTGGGTCTC 23402 Hepal-6 Slc22a30 ACAATTCCCATGGTCAAATA 17419 CtrlJOOO Olfrl307 TTTCCATAAATAACAAGGGA 23403 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Serpinala AGTCCATCGAGTGGGCACTG 17420 Ctrl 1000 I117d TGCAGTCGAGAGGCCGACTT 23404 Hepal-6 Serpinala TCTCTCTGCGCCTAAACCAA 17421 Ctrl_1000 Gfral TGGAAGACTGTTACATTCAG 23405 Hepal-6 Serpinala TTGTTGTGTTTATGAGGGAT 17422 Ctrl_1000 Li 8b CCGCTGACTAAGTTCGCGCG 23406 Hepal-6 Ptgrl AGCTTCTGCCCACACACAGC 17423 Ctrl_1000 Msrl ATTTCAGCATCTAGCCCACA 23407 Hepal-6 Ptgrl CAGGGAAGGGACATTGGGAG 17424 Ctrl_1000 Tstd3 GTGGCAGTACCTCTTTCTGC 23408 Hepal-6 Ptgrl GCCCAGGACTTGACTTATAC 17425 Ctrl_1000 Fibcdl GAGGGTCCGAGACGAAGACG 23409 Hepal-6 Calm4 CTTTGCTCCAATCACAGAAA 17426 Ctrl_1000 Dazap2 AAGTGACTCCGAACAGGAAG 23410 Hepal-6 Calm4 TTAATGGATGAGAAGATCTG 17427 Ctrl_1000 Btgl-psl AATGATCTCACAATAGGAGG 2341 1 Hepal-6 Calm4 CATGATGCTCCTCCCAGGGA 17428 Ctrl 1000 Vm l GAGAGTGTATTCATCTTAAG 23412 Hepal-6 Cysltr2 TTAGCGGCAGGGCAATTCTA 17429 Ctrl_1000 Tmem86b AACAATGCAAAGTTCCACAG 23413 Hepal-6 Cysltr2 TCAGCTTTGTGGCACTGTCA 17430 Ctrl_1000 01*1348 TGAGATGATTAACTTGCTCA 23414 Hepal-6 Cysltr2 GAGAAGTCACTTGGGTCAGC 17431 Ctrl 1000 Pbld2 AAACCCGGGTGACGGGTCTG 23415 Hepal-6 Azi2 ACAGGTCCCATGAGCCTCTG 17432 Ctrl_1000 Camiil2 GCTGAGTCGCGGTTGAAGCA 23416 Hepal-6 Azi2 GTACGTACTACCAGTCCCAG 17433 Ctrl_1000 Olfr904 TTGATTTATATGCTCACGTG 23417 Hepal-6 Azi2 CGGCACCCTATATAGTCTTC 17434 Ctrl_1000 Krtap31-1 TGCAAATGATTCAGAGCACT 23418 Hepal-6 Clec3b GAGCCATAGCTACACTGCTG 17435 Ctrl_1000 Ra 39 ACGCAGCTGCTCTGCAAGTT 23419 Hepal-6 Clec3b ATGCTGACTTTCTCGGAGCC 17436 CtrlJOOO Coa4 GGCTGAAGGCGGGCTCTACA 23420 Hepal-6 Clec3b GATTGAACAATGACAGCTTT 17437 Ctrl_1000 Coa7 TCAGTTACGTGAGCCAGCCC 23421 Hepal-6 Sstr3 GGGTGCCGGACACGGGATGG 17438 CtrlJOOO Tmem207 TCACAGGTACTAGGAGCTCA 23422 Hepal-6 Sst GTCTTCGGATGGCACCCAGT 17439 Ctrl_1000 Ube2d2b GGGAGGGTGACAGTTGGTCA 23423 Hepal-6 Sst TGACAGAAATGTGAGATAGC 17440 Ctrl 1000 01*1496 GAATCATCTTAGCAGTGCAG 23424 Hepal-6 Asxl3 GTAGGTACTGTGCTCTGCCA 17441 Ctrl 1000 Themis TGATGAAACAGAGTGGCCTG 23425 Hepal-6 Asxl3 ATGCTCGCACAGTGTCCTCA 17442 Ctrl_1000 Olfr502 TACAGGAAAGGATTTATAAG 23426 Hepal-6 Asxl3 GCACACGTGCAGAGAACATA 17443 Ctrl_1000 Tmeml70b AGCGCTCCTCGATGTCTCCC 23427 Hepal-6 At lOb TTGAGTAGGTGTAGCCTTGT 17444 Ctrl_1000 Prox2 GGGTCAGCCAACCAGCTCGG 23428 Hepal-6 AtplOb CCCTCTATACCAGGTTGTGA 17445 Ctrl_1000 Slc2 4 GTCTCAAAGGGATCAACCAA 23429 Hepal-6 AtplOb AGGTATGTCAGTGTGGATGT 17446 Ctrl_1000 Btnlal TAAAGAGCTGTACCGAATAT 23430 Hepal-6 Ch g TCCCAGGATATGTACAATGC 17447 Ctrl 1000 Betll GTTGGAITTAGCAGCGCCAG 2343 1 Hepal-6 Ch g CTGGCAGGGTTGGCTGGGAG 17448 Ctrl_1000 P l 2 GAGGATGCTAATAATCCTTA 23432 Hepal-6 Chmg CAGTGGTCAGACAGCTGGTG 17449 Ctrl_1000 Cdc34 GTGGCACGCAAGCGCTTTCG 23433 Hepal-6 Mt l CCCGCAGGTACTTTCAGCGC 17450 CtrlJOOO 2 10002L09Rik AACTCATGATGAACAGACAT 23434 Hepal-6 Mtol GGCGGGAGATTCTATCTTGG 17451 Ctrl_1000 2310034C09Rik GAGTTGCACAITTGTAAACC 23435 Hepal-6 Mtol GTGGACTTGTCTTTATCGCC 17452 Ctrl 1000 Fgll GAGGCAGGCAAAGTTGACTC 23436 Hepal-6 Lnpep GGCAACAACACCTTCGTTCC 17453 Ctrl 1000 Atxnll TAGGCGGCGCTCCCAGGCCA 23437 Hepal-6 Lnpep ATGCCCAGCAAAGGCCTCCG 17454 Ctrl_1000 Gnl3 GGGTGCCGGAGAGACGGCCG 23438 Hepal-6 Lnpep CTTAGCGTCCACGCCTCAGT 17455 Ctrl_1000 Sap25 AAACGCTGGCGCAGGCGTCG 23439 Hepal-6 Exoc8 CGTGCGCGGACGAGCCAGCA 17456 Ctrl_1000 Olfr690 GAAGCCTTGCCTACCATAGG 23440 Hepal-6 Exoc8 GAGCGGCTCGACTCTGGCAC 17457 CtrlJOOO Gm3264 TTCTAGCAGACCCTGCAGAT 23441 Hepal-6 Exoc8 CAACACCCAAACGCCTGCGC 17458 Ctrl_1000 S GGCGCTCTGGTGCGACCAAC 23442 Hepal-6 Gm572 GTAATTAATGTCACCCTAGG 17459 Ctrl_1000 E030018B13Rik GGTTAGATICTGTGTCTTCT 23443 Hepal-6 Gm572 TCTTGGCAACCAAGGGAAGG 17460 Ctrl_1000 Msl2 CGCTGCCGTTCTCGCCATGC 23444 Hepal-6 Gm572 CACTCCCAGCTCAGAAGTAA 17461 Ctrl_1000 Vmn2r58 TCCACTGTCAATGAGAGTTT 23445 Hepal-6 Prdml4 AAAGCCTGCACAGCCTTCGG 17462 CtrlJOOO 01*873 TATCACTCGACACTGTATTT 23446 Hepal-6 Prdml4 GGTTAAGTGGGTGATCTCTG 17463 CtrlJOOO Foxp3 TATAGTCCTTTGCTAAACTG 23447 Hepal-6 Prdml4 GAGGGTGCAGATCCGGCCTC 17464 Ctrl_1000 Ccrl2 ACACGGTCAGGTGGACTGTG 23448 Hepal-6 Spaca6 TCAAATGATGGTCAAGCATC 17465 Ctrl_1000 Delb37 TCTTGTAATGGTCAACTTTG 23449 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Spaca6 ACCTGAAATCCCTAAATTTG 17466 Ctrl 1000 01fr733 CTAATGCTGAGACAAAGGTG 23450 Hepal-6 Spaca6 CCAGCTAGAGGAAGGTTGCC 17467 Ctrl_1000 HnmpaO CGCTTGTGACGCACCGCGCG 23451 Hepal-6 Dcbld2 GGCGTGATGATTGGACGGCA 17468 CtrlJOOO Mpp2 TTGGTCCTGCTCAGAGTTGG 23452 o Hepal-6 Dcbld2 GGGCGGTGGAGCTTTAGGAG 17469 CtrlJOOO Ldhal6b TACTTCAAGGGTTCTGGGTT 23453 Hepal-6 Dcbld2 CTCGTAGACCGACCGTCTCT 17470 CtrlJOOO Clqb GCAGGATGGGAGGAACAGAG 23454 Hepal-6 Usp43 ATTCCCAGCTCCAGCCGCGG 17471 CtrlJOOO Tas2rl43 GAGGGAGGATCTGTTCAGAC 23455 Hepal-6 Usp43 CCACGCGGGAATCCGGCCCT 17472 Ctrl_1000 Andc2 CTGGTTCTGCTGAGAGAATT 23456 4 Hepal-6 Usp43 CTCCCTCTGAGCCCGCCTAG 17473 Ctrl_1000 Wfdcll CAGATCTACCTCAGATCTTA 23457 Hepal-6 Ppdpf GGAGTCTAATAGGGAAGGGC 17474 Ctr OOO Smco3 GCTGGGTCCCACTGCCCATC 23458 Hepal-6 Ppdpf GTGGATTCTTGCTCCGCTCG 17475 Ctrl_1000 Saxo2 TAGGGACGCCGGCGACCAGA 23459 Hepal-6 Ppdpf TGCTACITCTGGTCTATCAG 17476 CtrlJOOO Tcf24 CAGGAGCAGCTCAGCACCTG 23460 Hepal-6 Npvf GGAATGTGCTTAATTCATTC 17477 CtrlJOOO Dnajcl5 CAGGGTCAGTTTATCGGAGA 23461 Hepal-6 Npvf CTTGCAGACTCATAGACACC 17478 Ctrl_1000 Aadacl2 ACAGAATGAAGAAACACTGC 23462 Hepal-6 Npvf ATTAGGTTAATATGTTCAGC 17479 Ctrl_1000 Esp23 TGGGTCAACAGTCTACTATT 23463 Hepal-6 Hecwl TGCTAAGTGTTGGAAGGATA 17480 Ctrl_1000 Smugl CGTCCTGGCGCGGAGGGCAC 23464 Hepal-6 Hecwl CTGGTTCCAGATAAGCCTCG 17481 CtrlJOOO Rbm4b GATTGGCTAGCCCGGGCTGG 23465 Hepal-6 Hecwl GGGTGCGTGAGGCTGCAGGG 17482 CtrlJOOO Zfand2a GCTGGCCTTCGATGACATTT 23466 Hepal-6 Zfp692 GGTGGTCTCGCGGTTCAGAA 17483 Ctrl_1000 Gprl8 TTGAGATGTAGTACCGATAG 23467 Hepal-6 Zfp692 TAGGCAGAGATGCTAATAGA 17484 Ctrl_1000 Kbtbd2 GGCGCGTGCGCGTAGCAGAG 23468 Hepal-6 Zfp692 TGCAGCTCGCGTTTGCTTGG 17485 Ctrl_1000 R l 7 CAATGGCGCCATCTCTTGGC 23469 Hepal-6 Rabgapll GTCCACAGGCTCGCTTGACT 17486 CtrlJOOO Asb8 TGGCCAAGGGCCTTGTGTGA 23470 Hepal-6 Rabgapll GCCCTGGAGCACACTAGAGA 17487 CtrlJOOO Mrps2 AAGGATGCGGGCGCAGCGAG 23471 Hepal-6 Rabgapll AACTCITCCTGCTCCGCTCC 17488 Ctrl_1000 Zdblic4 CAATCGGCTCGCAGAACCAG 23472 Hepal -6 MrpslO CGCGAACAATGCTGTGACCC 17489 Ctrl_1000 Sh3pxd2b TCGCCAGGCCCGGGCGCGGG 23473 Hepal-6 MrpslO TTTCTAATAACTTCCTCCAA 17490 Ctrl_1000 01fr544 TTAACTCACCCTGGCAACTG 23474 Hepal-6 MrpslO CCCGTCITGCCAATTTATGT 17491 Ctrl_1000 Cplx2 AAAGGAGATAAGGAAGAGAG 23475 Hepal-6 Tmem2 AGGACGCCCGCCAACACCGT 17492 Ctrl_1000 ί2 13 TGTTTCTTGCAAATCTTCAT 23476 Hepal-6 Tmem2 TGACCCGCCTCCCTAGCTCG 17493 CtrlJOOO Eril ATGGTGCTGCGCCGGTTGCC 23477 Hepal-6 Tmem2 AAGGAGCCGCTGGGAAACCC 17494 Ctrl_1000 Atp5sl TCCGCACGCGCGCCTITAAA 23478 Hepal-6 2210407C18Rik TTCCTGAACTTCTGGTTGGT 17495 Ctrl_1000 AC182748.1 TCGGCCAAGCTCCTCCCAGT 23479 Hepal-6 2210407C18Rik TAGCCCAGAGGACCAATGCC 17496 Ctrl_1000 Krtapl9-3 TGTTAGCAAACAGATTAATG 23480 Hepal-6 2210407C18Rik TTTACAGTGTCTTAATTGCC 17497 Ctrl_1000 Ybey TCAGATTCTTGCGATCTCCA 23481 Hepal-6 Zfp287 AGAGGAGGAAACCTCAGTTG 17498 CtrlJOOO 01fr948 GCTTGCTTCTGCACCACAGT 23482 Hepal-6 Zfp287 AATTAACAATTGGTGTGGGA 17499 CtrlJOOO 5031410I06Rik GAAACTGAGCTGCCCTTTCC 23483 Hepal-6 Zfp287 CCTACACTTCAGTCTTATAG 17500 Ctrl_1000 OHrl277 GTGAITGAACCTTCTAACTT 23484 Hepal-6 Zfp68 GCCATCTACTGTCACTCAAG 17501 Ctrl_1000 Lipt2 CGTGCGTGGGCCACGCCTTC 23485 Hepal-6 Zfp68 GAGCTCCTACAGCTGTGCGT 17502 Ctrl_1000 Neu2 GAACCGAAAGGCACCTGCCT 23486 Hepal-6 Zfp68 CTCAACTCAGTGCCTCCGAT 17503 Ctrl_1000 4933416C03Rik TCGCGGCAGTCCTGGGCCTC 23487 n Hepal-6 Man2al ACTCCTGGAGAGCAAGGCAA 17504 Ctrl_1000 TrmtlOb ATCTGTCTGTTAGTTGACGA 23488 Hepal-6 Man2al CCACAAACTTGCTTTCCTGC 17505 Ctrl_1000 Slc22al7 CTGACGAACAGTCTGGACCC 23489 n Hepal-6 Man2al CAAGGCCGGCCGTCCCTGCA 17506 Ctrl_1000 Mettl24 ACGGACCGGGCTGACAACTG 23490 o Hepal-6 Mco 3 AGGCTCAGAAGCCTGAACAA 17507 Ctrl_1000 Papolg ATTGACAATCCCACAGACCA 23491 Hepal-6 Mcoln3 AGCAAACACTTCCACTCAGC 17508 Ctrl_1000 Wdr34 TGGTTACAGCATCGTCTTTA 23492 Hepal-6 Mcoln3 GTAGCAAACACCGCGGGCCT 17509 Ctrl_1000 Usp27x GCTCGGGCGGCCACTGGGCG 23493 Hepal-6 Enam TTTGCCATCACAAGAGTTAG 17510 Ctrl_1000 Nrl GGCAGGTTTAAACATCTCCT 23494 J Hepal-6 Enam ATGTGTTATTATAGAACCTG 17511 CtrlJOOO Rpl27a CGACTAGGGAGGAGCTACCG 23495 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal -6 Enam ATCAAGCCTCCTGACAAGGA 17512 Ctrl 1000 Defb23 GGACTAGTGTTCTTGAGCTC 23496 Hepal -6 Triobp CGGGAGGACCAATGGGAGCG 17513 CtrlJOOO Bbipl ATGCCCAGGCTCGCTCAAGG 23497 Hepal -6 Triobp CTGTTGGCTCTCTCTAGCTA 17514 CtrlJOOO 01*1252 CAGAATGGAAGTCTAGGTTT 23498 Hepal -6 Triobp AGCTGTCCATTGGTCCGCCC 17515 CtrlJOOO Uts2 AAATITACTGGCTTGTTGAC 23499 Hepal -6 Adam7 GTACTAATTAAGGACAACAG 17516 CtrlJOOO Lrit2 TGAGTAGCAAATCCTATTAT 23500 Hepal -6 Adam7 ACAGTTTCACAACTTGTGCA 17517 CtrlJOOO 01*1393 CGGGTACTTGTTCAGGTCAA 23501 Hepal -6 Adam7 TAGGCTGGGCATCCTTGCAG 17518 CtrlJOOO 01*768 TGTCAGCATGAGGGATCATT 23502 Hepal -6 Ligl GCGTGACTAGGGAGAAAGCC 17519 CtrlJOOO 01*1535 GCAGTCTACCTGTGGGAAGC 23503 Hepal -6 Ligl AGCGTGAGGCAGCCTAGAAA 17520 CtrlJOOO Derl3 GGGACGGCCAGGTGTATCCG 23504 Hepal -6 Ligl TTGCGGCACGCGCTACTCGC 17521 CtrlJOOO Seclla TTCTCGGCCGGAGAAGGCTA 23505 Hepal -6 Mettll3 GCGCGGACGAACCACTGAGC 17522 CtrlJOOO Samt4 GTAGATTATGAACAATGAAC 23506 Hepal -6 Mettll3 TAGGTTCTGAGTGTAGCTGC 17523 CtrlJOOO Bsp GTGTGAGCAGATGGAGTAGG 23507 Hepal -6 Mettll3 GCACAGGGCCCGGTTCGGTT 17524 CtrlJOOO 01*591 AGAGGAGGAAGTCAATACAC 23508 Hepal -6 Trpm5 CCCAGTTATTCACAACCGCC 17525 CtrlJOOO Camk TGACGATGAGCGCCCGACTG 23509 Hepal -6 Trpm5 ACTGTCAAGAGCTGTCATGA 17526 CtrlJOOO 01*1110 CCAGAATCTGATAACCATCA 23510 Hepal -6 Trpm5 AAGGAGCTGGATAGATCAAC 17527 CtrlJOOO Stxl9 TCACGCGGCTCCTTGGTAAC 23511 Hepal -6 Pcolce TATATGTCCAAGACCTAGAG 17528 CtrlJOOO 01frl219 ATTGCAATAGACTCAATCAA 23512 Hepal -6 Pcolce GATGTGTTCCCAGCATTCTC 17529 Ctrl_1000 Uox GCGAGGCATTTGGCTTTGAA 23513 Hepal -6 Pcolce CAGTGCTTGAGTCCCTTCAG 17530 Ctrl_1000 Slc39a8 AGACAGAGAGGTAAGCGCCC 23514 Hepal -6 Dactl GATCAGCTCCTGTCAGGCGC 17531 CtrlJOOO Pnp TCCAATAACGCAGCGGAGAA 23515 Hepal -6 Dactl GGCGGGCGGGCGAGCAGGCG 17532 CtrlJOOO Mom5 TGCTCTAGGGCCGCTGGAGG 23516 Hepal -6 Dactl CGGCCACGCTACGTCACTCC 17533 CtrlJOOO 01fr883 AAGCTAAGAAACAGAATAGA 23517 Hepal -6 Cdc42bpg GGGTGGCACCGTGATCAGAG 17534 Ctrl_1000 Gml6286 GCGCGTCGAGCTCGCCTTCT 23518 Hepal -6 Cdc42bpg GCCGACCCTCGTCCAGGAAG 17535 Ctrl_1000 Ptcd2 ACGCGTCTAGTCGCCGAGCC 23519 Hepal -6 Cdc42bpg GTCTAGGTGGCGCTGGGACT 17536 CtrlJOOO Cracr2a GCTCACGGAAGAAGAGCAGC 23520 Hepal -6 Crygf GTTGGCAGGAACAGCACAAA 17537 Ctrl_1000 Fahdl CCAAGGCTGCTAGGGCAGCT 23521 Hepal -6 Crygf AAAGTGCCCTGTCCCACTGC 17538 Ctrl_1000 If l GAAATTCCTCTGAGGCAGAA 23522 Hepal -6 Crygf GACACTCCAGAGCTTTCGAA 17539 CtrlJOOO 01fr3 CAGCTGGGTACACCTACTGC 23523 Hepal -6 Myo5c CTGTTAGCTCACTGATTCTT 17540 Ctrl_1000 Pdcd2 AAACAGTGACAGTTCGATGG 23524 Hepal -6 Myo5c CCGGCAGCCCGCGTTGCCAT 17541 Ctrl_1000 Olfrl043 CTTCTGAGTGATCTTGATTC 23525 Hepal -6 Myo5c GTGAGGGTTAGCAGCGGGAT 17542 Ctrl_1000 Zc2hclc CCCTCCAACCCAATCTGCCC 23526 Hepal -6 Sbsn GGCAGGGCAGAACCCTACTG 17543 Ctrl_1000 Tmem213 AACAGCAAGTGCAGGTCTAA 23527 Hepal -6 Sbs GGGTGTTTCCCAGAGATATT 17544 CtrlJOOO Taarl AGACTGAGTTAGTTGCTGAC 23528 Hepal -6 Sbsn GGGATTGAGCAATTAAGAGG 17545 CtrlJOOO Ctage5 ACGTCCGCGCTCGACCTTAA 23529 Hepal -6 Taf61 TCTTAAAGCAACAGCTCCTT 17546 CtrlJOOO Decr2 CTCCCATTCTCAGTCCCAGC 23530 Hepal -6 Taf61 CTCAGTAGACGGCCACCGAT 17547 Ctrl_1000 Vmnlr82 TTATTAGGCTAATCAGATCT 2353 1 Hepal -6 Taf61 GTGCAGAAGCTGCCCATGAT 17548 Ctrl_1000 Vmnlr89 GTCAGGTTTGTTAAGTCTAG 23532 Hepal -6 ED30030I06Rik CGGAACTGGCGTGAAAGCAC 17549 Ctrl_1000 Nrarp AGCACTAGTCTGGTCTGGCC 23533 Hepal -6 E030030I06Rik GCATTGGGTTACAGGGTCCT 17550 Ctrl_1000 Fam25c AAGGCTTGTGCACAGTACTG 23534 Hepal -6 ED30030I06Rik GCCCTCCCTGACTCGTCGCG 17551 Ctrl_1000 01frl489 CTAACTTAAATGTTCACACA 23535 Hepal -6 Calm5 CTGTTGAAGAGCTGAGCTAT 17552 Ctrl_1000 Arbgaplla CCAGGAGCTGCCTGTCTAAA 23536 Hepal TnfrsfS CTCTCTTAGGCTTCACAGGC 17553 Ctrl_1000 Tmem221 TGGTACCAGCACTCGAGCCC 23537 Hepal -6 TnfrsfH CACAGGTGGTAAGAGGGTGG 17554 Ctrl_1000 Ma CGAAGAAGCGTGAGCAACAG 23538 Hepal -6 TnfrsfS TAGCCACAGCGCACGCACGC 17555 Ctrl_1000 Prodh GATGGAGCTACTTTCTGTGC 23539 Hepal -6 Ppil4 AGCTGCCGGGCCGAACGAGC 17556 CtrlJOOO R p3 GGTGTTACTATTGTGTAAGT 23540 Hepal -6 Ppil4 ACGGCTTCTGGCGTCAGCCG 17557 Ctrl_1000 Krtap6-2 TATGGGTTGTCAACAGTGAC 23541 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 1,809 - 23,776)

Hepal-6 Ppil4 CACGTCGTGACGTAAGACGT 17558 Ctrl 1000 GGAGGAGCAGACAAGGCCAA 23542 Hepal-6 Pemt CACAATGCAGCTTGCACCCT 17559 CtrlJOOO AGTATAACCCTTCCTACCTC 23543 Hepal-6 Pe t TACAAGTCCCAGAGCAGTTT 17560 Ctrl_1000 ACACTACACTTAGCTTCCGG 23544 Hepal-6 Pemt ATATAAGGACTTTCGAAGAA 17561 Ctrl_1000 GTGGAAGGTGGCCTGCTGTG 23545 Hepal-6 C6 TATTGCAACAACTCTCAATG 17562 CtrlJOOO GGCCAGCTCGCCGGAGCGCT 23546 Hepal-6 C6 TTAGGTCACCGTTAGGGTTT 17563 CtrlJOOO AAGGCGGGTGACCAATCGCG 23547 Hepal-6 C6 ACTGCTATACTTAGAATTTC 17564 Ctrl_1000 GCAGGCGCTCGGAAGGCAGC 23548 Hepal-6 Iraklbpl GTTTCCAACGTGTGTGATCC 17565 Ctrl_1000 GCTGAAACTATAAATACATC 23549 Hepal-6 Iraklbpl AGAACGACTGGTCACGTGGA 17566 Ctrl 1000 CGGAGCGGGCCAGGCTAGGC 23550 Hepal-6 Iraklbpl GCACTTGCGGGTAAGACCAC 17567 Ctrl_1000 ATGTTAGTTACAATAGCTTC 23551 Hepal-6 Mcmdc2 ATAGGTGAGACTGGTTGCCC 17568 Ctrl_1000 GCTGGGCGTGGAGGCGCGAG 23552 Hepal-6 Mcmdc2 TAGTGCTGTTTGCTCCCGCA 17569 Ctrl 1000 GGCGGAGGCGGAGTGGGCGG 23553 Hepal-6 Mcmdc2 TGACAGAAGGGCTGCGGTCC 17570 Ctrl_1000 AACGTCTTGTATATTTGAGA 23554 Hepal-6 Zfp790 CTACTCGAGCCATGCGCCTC 17571 CtrlJOOO ACCAGGTCTCATAGATTCAC 23555 Hepal-6 Zfp790 TGGGTCGAGGAGCCTGATCT 17572 CtrlJOOO GTGAACTAACTTCTAGAACA 23556 Hepal-6 Zfp790 TCTATGAAGTCTTTCACCGC 17573 CtrlJOOO TACTAAGTGGACACGAGAGT 23557 Hepal-6 Klhdc4 CCGTCTCGGGCCGCGTGAGT 17574 CtrlJOOO CATATGCACACGAAGTGTGG 23558 Hepal-6 Klhdc4 CTAAACGAGACGCGAGCATG 17575 Ctrl_1000 CTTACGGGTTTGTGTCGTTC 23559 Hepal-6 Klhdc4 TTGCTGGTGTGCCAGCGGAG 17576 CtrlJOOO ATTGGCCGAAAGGCAACCCG 23560 Hepal-6 Ap4 GCGATCGGAAATCAACTACT 17577 Ctrl_1000 AGATTCTGACGTCACATTGA 23561 Hepal-6 Ap4bl TCAAAGCTCGCGCGGCGGCG 17578 CtrlJOOO CGTCGGGCCGGAAGCAAAGC 23562 Hepal-6 Ap4bl TGGGCCCGAGCTCCAGCGCG 17579 CtrlJOOO CTGCTCCGTGATCGCGTTTC 23563 Hepal-6 Zpl GCCAAATCTTTATATGCATC 17580 Ctrl_1000 GCTACAATATAAACGAAGAC 23564 Hepal-6 Zpl GGGCAAAGGAGATCCACCTG 17581 CtrlJOOO GTTTCCAGAACAATCCAACC 23565 Hepal-6 Zpl GGCAGGAAGTGGTAGCCTCT 17582 CtrlJOOO GCGCCCGCCCGGGAAGAAGC 23566 Hepal-6 Dokl ACTAAAGCCTTTATCTTTAG 17583 Ctrl_1000 ATCAGGAAGCATCCGCATCC 23567 Hepal-6 Dokl CGAGCCATCAGGAAGAACTC 17584 Ctrl_1000 TATCCCGTGCAGTCTGCCTC 23568 Hepal-6 Dokl TGCACACAGTGGCACCACTC 17585 CtrlJOOO TGGCCTGCTGTCCCGGACCT 23569 Hepal-6 Fam83g TCGGAATCCTGGGAATAAGC 17586 Ctrl_1000 GACTCATCGTCTTGTCTAGC 23570 Hepal-6 Fam83g GAGGTTAGCCAGAGCCGTCC 17587 Ctrl_1000 GGACTCCAGTCATGTATTCC 23571 Hepal-6 Fam83g CCCAGTCCGGAGTAAGAGCC 17588 CtrlJOOO ACCCAAGATGCACTCACAGA 23572 Hepal-6 R f l 9a AACCGCGGCTGGTCGACGTG 17589 Ctrl_1000 GAGCACAGCGCAGTTACTTC 23573 Hepal-6 Rnfl9a GCAGTGCGAGGCGAACGTGC 17590 CtrlJOOO CGCACGCGCACACACGTTGG 23574 Hepal-6 Rnfl9a TCTGGGACGCGGTGGTTCCT 17591 CtrlJOOO ATAGGCTATAATGTACATTC 23575 Hepal-6 P3 2 GCTGTCGCGCAGCGGGATCA 17592 Ctrl_1000 GGTGATTGGTGAACTGCGGA 23576 Hepal-6 P3 2 GCGCTGCCGGCGGTCACCTG 17593 CtrlJOOO TGTTATGCGATAGCAGGGTG 23577 Hepal-6 P3 2 TGGAGGCGTCCCTTTAAGAG 17594 Ctrl_1000 GAACTGGTAGCTAACTCTGC 23578 Hepal-6 Ckap4 GCCTCCCTTCCCGGGAGGCG 17595 Ctrl_1000 TTGTGCTTTCTGAGGGAGGC 23579 Hepal-6 Ckap4 ACGAGGAAGGAGGCCGGCCG 17596 Ctrl_1000 TGGGATTAGTGTGGAGCTGC 23580 Hepal-6 Ckap4 GGGACTGCGCGGGCGGCACG 17597 Ctrl_1000 CTTGTCACTTTCAGCTTGCA 23581 Hepal-6 Tfb2m AGTTCCAGCACGGACACACC 17598 CtrlJOOO TCGCACTTAGTCATCTTCAG 23582 Hepal 6 Tfb2m AGTCCACGCACAGGAGCCTG 17599 Ctrl_1000 GGCAGCACAACCTCTCCGAG 23583 Hepal-6 Tfb2m GAGCATAGAGTGCGAGACCG 17600 Ctrl_1000 GTGTACCCTCCAAATTGCCC 23584 Hepal-6 Vnmlr209 AGTAAACAGGAGAAATTTCA 17601 Ctrl_1000 GATACGCCATTCTCCTTTCC 23585 Hepal-6 Zf x3 GGTGCGGTCAGTGCCTCGCG 17602 Ctrl_1000 CTATCAGAAGCCTGCTTTAC 23586 Hepal-6 Zf x3 AAAGGCCGGCCTGGAAGAAA 17603 CtrlJOOO GCGTTGTCAAGCTACACCGT 23587 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Zfhx3 CGGCTITGTTCCTGCCGGGC 17604 CtrlJOOO 2 10009E07Rik ATGTGGGACCCGCTGGCCGG 23588 Hepal-6 Slc27a5 CTCCATCTCCTGTTAGGTAT 17605 CtrlJOOO 01*1380 AGACAACTGAATGCTATTTA 23589 Hepal-6 Slc27a5 GTTACTTAGTTCTTACTGGC 17606 CtrlJOOO 01*545 TGAGTCTCCAATATTTCTAG 23590 Hepal-6 Slc27a5 ATGGCTGGTGGTGTCCAAGG 17607 CtrlJOOO Tssk2 GACTTCATTCGCTGGTCACT 23591 Hepal-6 Kmt2b CACCACGGGAGCAGGAGTCC 17608 Ctrl_1000 m211 TTAAGATGTTTCCAAAGCCA 23592 Hepal-6 Kmt2b GGGCAGCCCGTGCGCAGGGC 17609 Ctrl_1000 01fr827 GTTCTCTTAAGGGAGCAGCA 23593 Hepal-6 Kmt2b GACAACAACCAGCGCCGCTG 17610 Ctrl_1000 Crem CATTGATGGCAGTGATAGGC 23594 Hepal-6 Poll AAACAGCCCGAGCGTGGCAG 176 11 CtrlJOOO 01*653 TACTTGAATGGACATTTAGT 23595 Hepal-6 Poli GAATGAGAAAGATCTGGTTG 17612 Ctrl 1000 Rtp2 AAGAGGAAGCTGGCTCTTGT 23596 Hepal-6 Poli AGGCTAGGCCGTGGTTTCCT 17613 Ctrl_1000 Sh2d7 ATCATAGATGCTCGTGAGGA 23597 Hepal-6 BC016579 TCAGGAAAGGTAGATGCAAG 17614 Ctrl_1000 Igsfll AACTCAAGGCTGGCGCGGCC 23598 Hepal-6 BC016579 CAAGGTCAGCTAACCAAAGC 17615 Ctrl 1000 Zfp54 CAACGGCTGTTTCCGGTGAG 23599 Hepal-6 BC016579 GGCGCCAGATAGGCCTGCGG 17616 Ctrl_1000 Gpr82 AAGCATACAAATTGCTGTGG 23600 Hepal-6 BC030500 CTGTGCGTTTGTTCTGCAGA 17617 Ctrl_1000 Psorslc2 CCTAAGAGGCTTTATAGCAG 23601 Hepal-6 Ced 122 ACCGGCCGGCCGGTGACTTT 17618 Ctrl_1000 Fmid8 CTTGCGTGATCTAAGTAAGC 23602 Hepal-6 Cede 122 CAAACCCGGGCGCACGCCCG 17619 Ctrl_1000 Lamtorl CGACGAGTTGTGTGGTCACA 23603 Hepal-6 Cede 122 GGGCTCGGCCTTGCGTCTCC 17620 Ctrl 1000 Exosc4 CCGGTAGCCTAGTCGCTTTC 23604 Hepal-6 Ald l TAACTCACCGTTCTCAATGT 17621 Ctrl_1000 Gml0413 GGAAGGATAGGTTGCCAAAG 23605 Hepal-6 Ald l CTGGGAGTCTTTCCATTCGC 17622 Ctrl_1000 Ill lra2 TGTGTCCCAGAAAGGGTGGC 23606 Hepal-6 Aldh5al GCCCTGGAGAAGAACGTGCG 17623 CtrlJOOO Clec4b 1 CACTTTCCTCTAATGATTTA 23607 Hepal-6 Fmo6 TAGGGTGCTGCCTGAAGTGG 17624 CtrlJOOO D as l ACGTGCTATCAGCCTGCCCA 23608 Hepal-6 Fmo6 TCTCTAAGAAATGACCAAGT 17625 CtrlJOOO Rprml TGGGCGACGCGAGTGGGTTG 23609 Hepal-6 Tyk2 TTAGTCGTGATTTGTTGGCG 17626 Ctrl_1000 01*218 CTGGATGTGCTCTTTACAAA 23610 Hepal-6 Tyk2 GTTCTCGTACAATGACCAAT 17627 Ctrl_1000 01*101 AAAGTAAATTTATGGCCAGA 2361 1 Hepal-6 Tyk2 CGTTCCGAATGTTGATGGTG 17628 CtrlJOOO Dtd2 TAGGCGCCTCCCACTGCTCG 23612 Hepal-6 Cd2ap TCAGCCCGCACCCGCTCCCT 17629 Ctrl_1000 01*170 GCTCTCTATGAGGCACTTGA 23613 Hepal-6 Cd2ap CAGCTGGCTGAGGCACTTGG 17630 Ctrl_1000 Cyp2c37 CTAGACTTTGCTACAATACT 23614 Hepal-6 Cd2ap GTGCGCCCTGTGCTCAGGCG 17631 CtrlJOOO Cyr61 CATTATAAAGGGCGGGCTCC 23615 Hepal-6 Urocl GCCTGAGTGTTACTTGCCAG 17632 Ctrl_1000 Slc9a3rl TTCACCCTGGCGCAAGAGCC 23616 Hepal-6 Urocl GGGTCATACCCAAGTTAGAT 17633 Ctrl_1000 Ace3 ACATTCTATGGAAGACCCTT 23617 Hepal-6 Urocl AAGTGACTGACTGGGTAGTC 17634 Ctrl_1000 Mrgprxl GGGCAGCCCATGCGATTTCT 23618 Hepal-6 Cog8 CGCAAAGATCACGGAGAATT 17635 Ctrl_1000 Vmnlr47 ATGCAGCCACCACAGGATAC 23619 Hepal-6 Cog8 GCTAGAGAGACACGCGTTCG 17636 CtrlJOOO 01frl232 CCAATAGAGAGCGTATGATT 23620 Hepal-6 Cog8 TCTATGGITTCTCATCTAGC 17637 CtrlJOOO Commd5 CCGTGGCTCTCTGTGGTCCC 23621 Hepal-6 Mab2113 TCAGGACTGGTATAAGACCT 17638 Ctrl_1000 Reg3a AGTGAATGCTTATTTAAGTC 23622 Hepal-6 Mab2113 AGAGAGTGGAAGGGCTGGAT 17639 Ctrl_1000 Olfrl055 ACTACTCAGGAAATTTATTC 23623 Hepal-6 Mab2113 TGGGAGGATATGCAAATTTG 17640 Ctrl_1000 Myoz3 CCCAAGATTAACACTTCAGT 23624 Hepal-6 Serpine3 CTCCAGGAATTTGGACGGAG 17641 Ctrl_1000 Tapbp TATTTATTGGTCACTTCACT 23625 Hepal-6 Serp ne TGGACGTTCTGCAGGGAGCC 17642 Ctrl_1000 Psmal GCCTGCGAAAGCTGAGAACG 23626 Hepal-6 Serpme3 GCAATTACCAGCTTCCTCCC 17643 CtrlJOOO 01*1333 TATATGATAGCCCTGAAAGA 23627 Hepal-6 Vcaml CACACACACACACACACTGT 17644 CtrlJOOO Pips 113 GACAACCAGTGCGCGCTAAC 23628 Hepal 6 Rabl2 CCGCAGGTTGGAGAGGCATA 17645 CtrlJOOO Cuta CCCGCCCTCTTAAGTGGGCG 23629 Hepal-6 Rabl2 AGCATCCGCTCTGTCATCCC 17646 CtrlJOOO 01*458 AGCAGTTGGGACTGCTGGCC 23630 Hepal-6 Rabl2 ATACTGCAGCAACCTGTTGC 17647 CtrlJOOO 01*215 TTCTCACAGTGCACACAATG 2363 1 Hepal-6 Cmbl GGTCCGCAAGGACCGCGAGA 17648 CtrlJOOO 01*1223 GTGTAGCTAGGGAGTGAATT 23632 Hepal-6 Cmbl GGGAGGAGTCTCAGTCTGCA 17649 CtrlJOOO Abcf3 ACGGGAAACTGGAACCGCGC 23633 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

GTGGCAGTGTCCTGCATTCC 17650 Ctrl 1000 KrtaplO-4 CAACAAGCACACAAGATGTC 23634 GCCTCCAAGATCACAAGTTA 17651 CtrlJOOO Bcl2114 GGGTTCTGCATTGGAATGCT 23635 AGAGAGGCACAAGCATTCTA 17652 Ctrl_1000 l l ATTTGCTTCAATCCAGTTTA 23636 o GATTAGCTGCTGTGAGCCCT 17653 Ctrl_1000 Dyncli2 AGCGGAAACGCTTCGGGCCC 23637 TGCGGGTCTGGTTGACGTGG 17654 Ctrl_1000 Brox GGCGGCCGAGCGTGTCTCTG 23638 TGCGCACCTCGGACCCTCTG 17655 Ctrl_1000 Spint5 AATTTAATTTCCTCAGGGCC 23639 CGCACCGCGACCGCAGCGAG 17656 Ctrl_1000 Olfr70 GGAGGTTCAGTGTGTTAAGG 23640 o 4 GAATATGGTTGGATAGCAGC 17657 Ctrl_1000 01fr666 TTAACAATTTCTCATTTGGG 23641 GCTTGAGGTTTGGATCTACG 17658 Ctrl 1000 Tomm20 GCGTCTCAGCCGCGCAGACT 23642 AGGCGCTTCCACGCTCCTAT 17659 Ctrl_1000 Snmp25 CGACGAGATAGCTTAGCCAA 23643 CTAGACGATATTAAGTGCTT 17660 Ctrl_1000 Gpankl GACAAACTACCAATCCCAAG 23644 TCAGCAGGTTCCCTCGCCTC 17661 Ctrl 1000 Clecl4a GTTCCTACTTCTTTCTAAGC 23645 AAAGTAGCGGACCGGAAGGG 17662 Ctrl_1000 Tceal9 GTAGATGGGAGCGGAGGGCG 23646 GCACGGGTGCCAGTGTGGAG 17663 Ctrl_1000 Hbqlb TGCATCGTTCCAGGATGCCT 23647 ATGACCCTGACTGAAGCGCA 17664 Ctrl_1000 01frl8 TCATGGTAACCCAATCTCAC 23648 TCGrTTGCGTTTAGTGGGAA 17665 Ctrl_1000 Lipe AGCCGCGCTTGGTAGCCGTT 23649 GGCGCGTTCAGCTAGGCCCG 17666 Ctrl 1000 Olfr205 TGTGAAAGAGGACTATGATC 23650 GCAGCGTCCTGTGAGGCGAG 17667 Ctrl_1000 Trexl GCGGGCCCTGTTCAGGAGGC 23651 AGTCGTGGCCGCTCCCTTCG 17668 Ctrl_1000 01*1461 CATTGTAGTAACAACTTGTT 23652 GAGATATCCCTCCGCAGAGC 17669 CtrlJOOO Naa38 GACGAGGAGACTAGAATAGA 23653 GACAGTCGATTTGCTGACAG 17670 CtrlJOOO Ccl28 TGCCCAGAAACAGCTTAAGT 23654 CCTGGCTCGGACGAGGGTAC 17671 CtrlJOOO Scn2b TAATATGGCCGACTTGTATG 23655 TGGTTCCAACTGTCAGTTGC 17672 Ctrl_1000 Uqcrll GAAGTAGATGTCAATGTCTT 23656 GAGCTCACGGAACTCCTTGG 17673 Ctrl_1000 1117a GGATGGAATCTTTACTCAAA 23657 CCAAACAGACACTGTTCCTG 17674 Ctrl_1000 Pdcd21 GCGCAGATAACACTCTCTGT 23658 CTGTCTAGGAAGGGAAGTCC 17675 Ctrl_1000 Ppy AGAAAGGCTGACAGGAGGCG 23659 GGCCAAATTTGTGCTATGCC 17676 CtrlJOOO Bex3 AGGATGGTGCAGACCCTCCC 23660 ACACTCTGTTTCTTCTAGCT 17677 CtrlJOOO Gkn2 ATAAAGGCCGGACGCTGCAC 23661 ACTGTCAACAGTTGGAGAAA 17678 Ctrl_1000 Vmnlrl79 TAGTTCATGCATTGTTCTCC 23662 ATAGAAATGCTGATATCTCT 17679 Ctrl_1000 Nobox TGACCAGTATCTGGTACCCT 23663 GTGGGAGGATCTTACAGATA 17680 Ctrl_1000 Astel TTAAACAACCACGCCCTCCG 23664 GCAGAGAAGGGCAAGCTACC 17681 CtrlJOOO Tmem53 CAGAAAGACCCTCAGTCGAC 23665 CAAGAGGTCTGGAACTCAAG 17682 CtrlJOOO 01fr298 TGATGTACAGAAATTCTCTG 23666 AGCTGTGAACTGCAAACTGC 17683 CtrlJOOO Slcl0a4 GTTGGTCTTCTCCGCCCTCC 23667 GCATGCTGGGTAGAGGTGAA 17684 Ctrl_1000 OHrl427 GTAATTGTAGCATGTTCTIT 23668 GCTGGGAGTGATGAGTTTGT 17685 Ctrl_1000 Texl3cl GTTCAGTTATAGAGTACAGT 23669 GCGTCCTGTGCTGGAGACTC 17686 CtrlJOOO 01*467 TTGGTCTGGGAAGGATTTGG 23670 GGGAACAGGGAACCCGCGAG 17687 Ctrl_1000 Ddt GGCTCCAAATTACTGGTCCC 23671 n TCACTCCCAGTGGAACACTG 17688 Ctrl_1000 Gtf2e2 TGGCGTTGGCGACACAGCCC 23672 GTGACGGCTAGGGCCGGCTA 17689 Ctrl_1000 Zic4 ATACCCTCTGTCAACGTCCC 23673 n CTCCCACACTACACATCCTC 17690 Ctrl_1000 Lyar AAGTIGCCGATGAGCTGCCG 23674 o GGAATCAGCAATCTACCACT 17691 CtrlJOOO 2210013021Rik AGAAAGGTTAAAGTGGGCTG 23675 CTTAATATCTAACGCTTAAG 17692 Ctrl_1000 01fr898 GAGTTCTTGCTAACTGGGTT 23676 GTTCCCAGGTGACCCATCCC 17693 Ctrl_1000 Ccl9 TTCATTCACTCCTTTAGCTC 23677 b AGGTATATAAGAGCATGAAA 17694 Ctrl_1000 Slurp2 AAGGCTTGTGAAATTGTACC 23678 J AGTGAGTAAAGCATTACTTT 17695 Ctrl_1000 01frl272 TGTGTTAGACATCAGATAAT 23679 Table 5 : “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

ATAGAGTTTGGTTACTTGAA 17696 Ctrl 1000 Snipl CAGCTTTGCACTTCCGCTTC 23680 GGAGCTAGAGAAAGAACCCA 17697 CtrlJOOO G az CGCGAGCGCAGTCCGTTGCC 23681 ACGCGAACGCTATGGACACG 1769S CtrlJOOO Ssr4 TTTCGTCATGGCGCTGAAGG 23682 ATATTGAAGCACAAGGCCCG 17699 CtrlJOOO Mppl CCTTCCTTGTGCTTAGCGAT 23683 CTCAAACACAGTTCTAATCC 17700 Ctd_1000 Hmgcsl GGGAACAAAGTCCGAGGACC 23684 TTTGTATTACCGGCTATTGG 17701 Ctrl_1000 Cdk5r2 AGGATTGGCTGCGTGAGGCG 23685 TTTGTTCTGAGAGGGAGAGA 17702 Ctrl_1000 Gm5617 GGGTGCGCAGTAGGGTCGGT 23686 CCGACCGGAAGTGCAGCTGC 17703 Ctrl_1000 2610528AllRik TAGTGCTGAATGTCTAGCCC 23687 GAGTCGGTACCGACGGAGGG 17704 Ctrl 1000 Arsg GCGCGGGCCCACGTGGATCG 23688 TCCCTCCTACTCACGGCGCG 17705 Ctrl_1000 Rpsa AATAACCCACAGCCAGCCAA 23689 TGATGGCCACGTGGCCTCGC 17706 Ctrl_1000 Gjd3 GGATAGTCCATCCTCAGCTA 23690 GCACGAAGCACGGCCGGTTC 17707 CtrlJOOO Sec24c GTATGTGGTGTATCCCGTCA 23691 TTCATAGACTTCCAGTAACC 17708 Ctrl_1000 H2af| TCTGCTTCCGCGAGCTGATT 23692 TTCTTCTGTGCTCACTGCAC 17709 Ctrl_1000 Vmn2rl02 TCACATTGATTCTGGTACTT 23693 ATGACTAATTGGACCAGTTC 17710 Ctrl_1000 4921501E09Rik AGGACAAGGCAAACAAGACT 23694 TTTCCGTCCCAACAGGCTGC 17711 Ctrl_1000 Ly6i CAATAAACATGTTGGCCTAA 23695 GATAATTTCAGAACCACAAA 17712 Ctrl lOOO Mcpt2 GATGCAGGAGTCTCAGAATC 23696 GATACCTCCCTCAGCGTCGT 17713 Ctrl_1000 Μφ 140 GCGCATTTATTAGAAGAGCG 23697 AAGTGTCCGTGGGCCGCGCG 17714 CtrlJOOO H1209 GAGATGCACTCTGCCGGGAG 23698 CGAAGCAGCAGCCGGCAGAT 17715 Ctrl_1000 Afp TTGCCAATAATTAACAGAGC 23699 TGCTGGCCGCGGCGGTCGGA 17716 Ctrl 1000 Olfr290 ACAGATTAGACTGATAAAGC 23700 CAGGCGCCCTGGGAGCGCCC 17717 Ctrl 1000 Erp29 AGCGGCTGCGCATGCGTCGT 23701 GGGAGTGCGCTTGCGCACAG 17718 Ctrl_1000 0 1 523 TTCCCGGGACCTTCTAGATA 23702 o GTAGGACTGAATATAGTTTC 17719 Ctrl_1000 Mrpl58 GCTTCCGGTGCTCACTCTIC 23703 AGTACGGAGCGATGCTACTC 17720 Ctrl_1000 01frll34 ACATTGTGATTTCATACAGT 23704 CAGAACAAGTTCCCGACCGC 17721 CtrlJOOO Smad9 CGTGGCGCGGCCAGGGCGCT 23705 TGATGTCGAAATCCGAGTGA 17722 Ctrl_1000 Krtap9-1 ATGCTGCAAGCAATTAATTG 23706 CTGGTGGCTGGAGGGTGCAG 17723 CtrlJOOO Tas2rl23 TAAAGCAGAGTTCATCTCTT 23707 ATCAAGTGCTGGTGAGTTTG 17724 Ctrl_1000 Olfr720 TGAAGAGTAATCTGACAATC 23708 CAGCCAGCTGGCTGTGACAC 17725 Ctrl_1000 Slc25a54 GTGTCTCAGGCAGTTGGGTG 23709 TAGGAGCCATTTAATAGAAG 17726 Ctrl_1000 Zfp770 AGATCGTGAGAGGATGTTTC 23710 CATTTCTTCAAAGTTTAACC 17727 Ctrl_1000 01fr585 TTAGGATGTGAGCACAGTAA 23711 CATCTGCAGTGGTGTTGTCC 17728 CtrlJOOO Inafml TGATGGAGGGAACTGGGTCT 23712 AACGTGAATTTGTCTTGACC 17729 CtrlJOOO Tmem301) ATCGGCCTCACCTGCGTGGG 23713 ATCTCTTTAAGAGGCGGACC 17730 Ctrl_1000 Dnal4 CATAGTCGTCTTAAGCCTGC 23714 AATAAGCGTTAGGGATAGAC 17731 CtrlJOOO Pyml GTGTAAGACGCTCACAGTCA 23715 TGAGTGTAAGGCTCCATCTG 17732 Ctrl_1000 Rerl ACAGGCGCATTGACGTCCTC 23716 TTCAGACGTGATCAAGCGCC 17733 Ctrl_1000 Vt GATAACACGCTTAGCTTAGC 23717 TTTCTCGGTGCAATGTCTTC 17734 Ctrl_1000 1110004E09Rik ACGGCGCACGCTCGCGGAAG 23718 ATTATCCACTGTGTACAGAG 17735 Ctrl_1000 01frl080 AACTTTAAGGAGTCTCCCTG 23719 GTATAGATACATATAAGTCC 17736 Ctrl_1000 Vmnlr46 ATATGAGCTAGAGCTGTGTT 23720 TGTGGCTCAAGTTATATAAG 17737 Ctrl_1000 Adam4 GCATTGTGTGCTCAGGGATC 23721 TTCTTAGGGTTCACTTTGGT 17738 Ctrl_1000 Tmeml96 TCTCATTGCTATGACCTCAT 23722 AGGGATGCGTTCATTGGACA 17739 Ctrl_1000 Dnajb2 TCCCAGCTGGGTCAGGTTGG 23723 TGGGCTTATGGAAGGTAGCT 17740 Ctrl_1000 493 1406 C07Rik GTTGTTCACTGTGGCCGCTC 23724 GAAGAGCTAATGTCCTCAAG 17741 CtrlJOOO Ltc4s CCAGTGTGCTACTCAGACGC 23725 Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal-6 Fasl CAAGTCTTCGAAGTTCCAAT 17742 Ctrl 1000 Ofdl GAGGCGGCCGGTTCTCATCT 23726 Hepal-6 Fasl CGTCTCTGTGCTAACTGAGA 17743 CtrlJOOO Vmnlrl63 GACAATATAACAGAGACCCG 23727 Hepal-6 Linsl GAGGCGGGCTAATAGAGGCT 17744 CtrlJOOO 01*599 TCAGCATCAGCGGTGAGTAG 23728 o Hepal-6 Linsl ACGAAGGGAGAGCGACCAAT 17745 CtrlJOOO Tsr2 GATGGCGTTTCCCACTGTTC 23729 b Hepal-6 Linsl TCTAACTGTCGCGAATCCGC 17746 CtrlJOOO Hist4h4 TTTCAATCAGGTCCGCTCCC 23730 Hepal-6 Gm438 CAATTAGAGACAGATAAACC 17747 Ctrl_1000 Zfp622 TCTTGGCAGCTGGCTTAAGA 2373 1 b Hepal-6 Gm4 AGGATTGTGTCAGAGGGTGG 17748 Ctrl_1000 Syp ATTCGGGAGGCTAGAGACTC 23732 o 4 Hepal-6 Gm438 AGTGTGAAGTTCTGAGAGAC 17749 Ctrl_1000 Cnn2 GCAAATGTCCTTATAAGGCG 23733 Hepal-6 Itih3 TCCAAGCAGGGTCAAGGACC 17750 CtrlJOOO Nr2c2ap GAACCAGAAACCTCAGTGTG 23734 Hepal-6 Itih3 ACTCCTGATAGTCTGAAGTC 17751 Ctrl_1000 Ano9 AGCAATCAGAGGAGTAGGCG 23735 Hepal-6 Itih3 ACACTGTTATTGTATCCACG 17752 Ctrl_1000 01*493 TCTTCATCACAGCCTTGATC 23736 Hepal-6 Sultial ACCCTAGCGTTGCAGGGCCC 17753 Ctrl 1000 01*884 TACTACATTCTTTGAGAGTT 23737 Hepal-6 Sultial CGCTTATTGCTTGCCTATGG 17754 CtrlJOOO Trib2 CAGCGGCGCCGCTGATTGAT 23738 Hepal-6 Atg4b CGGCGCGTGTGGTTCCTAAC 17755 CtrlJOOO Eif4g2 CGCTACCAATCCGCGCAGGG 23739 Hepal-6 Atg4b CGTGTCGCGCAGTAGTCCGT 17756 Ctrl_1000 Glra4 GGTGAGAGCAGGTATCCTGT 23740 Hepal-6 Atg4b GGCGTCGCCATCTCGCCGTA 17757 Ctrl_1000 Lyll GCTCCGGAAGGAGACAATTC 23741 Hepal-6 Netl TTTAGGAGCTCCAGTGACAA 17758 CtrlJOOO Faml67b GGGCCACGTGATGCCCATCC 23742 Hepal-6 Netl GGAGGCCGAGTGAACGCCAG 17759 Ctrl_1000 Xlr4b GGCATATGCGCCGGAAGGCA 23743 Hepal-6 Netl ATCGGGAGTCACGTGGGTCC 17760 CtrlJOOO Cops6 ACACTACAGAACTCATGGCC 23744 Hepal-6 Gbel AACTGTGCTGGCTGGCCACC 17761 Ctrl_1000 Gml5800 CCTGCTTCCCATGCTATCTG 23745 Hepal-6 Gb l GACTGGTGAGACCCGCCTCC 17762 CtrlJOOO Ltb4rl CAAAGAGTCTTCCTCTCTTT 23746 Hepal-6 Gbel GGTGACCACCGGGCAGGAAG 17763 CtrlJOOO Clccl AACCACCAGTTCAGTTCAGA 23747 Hepal-6 Psmd8 CTTGTCAGGTGTCACTACAT 17764 Ctrl_1000 Vmnli228 ATAGCITCAGTGTCACATGA 23748 Hepal-6 Psmd8 GGGTACCGCCTCTACGTCAA 17765 CtrlJOOO 01*123 1 GATGTTCACACTATACCAAC 23749 Hepal-6 Psmd8 ACAGGTGGGCGGGACATTGT 17766 CtrlJOOO Gm9 GGAGCTGCAGATTGGACTAA 23750 Hepal-6 3830417A13Rik GGATGTTGATGCGGAAGTTT 17767 Ctrl_1000 Shoc2 TTCCTAGTAGGGTCATGGCC 23751 Hepal-6 3830417A13Rik CGCTGAGTCATCCAAGTCCC 17768 Ctrl_1000 Ndufs8 CATAGTGCCCTTTCCTTCTT 23752 Hepal-6 3830417A13Rik GAGGGTCTCACATAAAGTCG 17769 CtrlJOOO AC170751.4 CGCGITCCGGCACCGGCCAG 23753 Hepal-6 Riokl TGACTCAGGCTAAGGATTCC 17770 Ctrl_1000 Gm3985 TTATGCCGCTCAGAATAACT 23754 Hepal-6 Riokl GGAAGGTGTTCTCCCTCCCG 17771 Ctrl_1000 Zfp4 GGATGGTAACACAAAGTAGA 23755 Hepal-6 Riokl GCGCCCTGCGACGCACCAGT 17772 Ctrl_1000 Klkl3 ATGGTGITTAGGGAATAAGT 23756 Hepal-6 Kcnkl8 CAGCCGGAACCCATCATGTT 17773 Ctrl_1000 Lmodl AAACTGCTCTGTACTAAATT 23757 Hepal-6 cn l 8 GGAGGATCAATAACAATTTG 17774 CtrlJOOO 4931428F04Rik TGAAACCATTTACTGCTTGC 23758 Hepal-6 Kcnkl8 GCTCATCCAAACAACTGGGA 17775 CtrlJOOO T*2 TGGTTCCCGTCACAGGTTGG 23759 Hepal-6 Plekhhl GGAAAGTCCCACCTGGTTAC 17776 Ctrl_1000 Npc2 GCGGAGCTTGCGGAGTAAGA 23760 Hepal-6 P c hl I CCCAGACAGCGTGGGATCCC 17777 CtrlJOOO Galnt6 ATGAGTGGCAGACCCAAGGG 23761 Hepal-6 Plekhkl CAGGTGGCTAGACACTCGCT 17778 Ctrl_1000 AtglOl TGCCACGTAACTTTAGTACT 23762 Hepal-6 Ncapg TTTCAAACAACTATCGCGGG 17779 Ctrl_1000 Dlfr648 GACAGCAATGAGCTTACATC 23763 n Hepal-6 Ncapg GAGTCAGCTCCGGGACCCTC 17780 Ctrl_1000 Klk9 GCCTCCTAGCTCAGCAGAAT 23764 Hepal-6 Ncapg TGGCCTGCCGCTCTCCCAAT 17781 Ctrl_1000 Ubqlnl AAGAACGGGAGACGCGAAGT 23765 n Hepal-6 Zscan4d GATGAAGCAGAGCCAAGGCA 17782 CtrlJOOO Emc6 GTTGGGCTTTCCGGAGTCCC 23766 o Hepal-6 Zscan4d AACCGACTAACGGAAGCCAG 17783 Ctrl_1000 Pinlrtl AGTAAGGGAATTCGTTATAA 23767 Hepal-6 Cyp39al AGCTTTGATTTGAACTGGGC 17784 Ctrl_1000 Spx AGAITGACAAGCTACCCTCG 23768 Hepal-6 Cyp39al AGTAAACTAGCTGTTTGCAG 17785 CtrlJOOO 01*1084 TTTCTGCCTCTGCTGATGAC 23769 Hepal-6 Cyp39al GGCGGGAACACATCCTGAGG 17786 CtrlJOOO 01*1419 CTGTGACTTTGGAGAAATAT 23770 Hepal-6 Chd3 GGTGGTGGTGGTAGCGGTGG 17787 CtrlJOOO Tomm7 CGACGGATTACGGCCTCTGT 23771 J Table 5: “Personalized” sgRNA libraries (SEQ ID NOs: 11,809 - 23,776)

Hepal -6 Chd3 CCCTCCTCAGACGCCGGCCC 17788 Ctrl 1000 Spint4 GGGCCAGGGTTCAGCATTAC 23772 Hepal -6 Chd3 CGCCGCCGAGGAGGAGGAGG 17789 Ctrl_1000 Ppil3 TGGAAAGAGTTGGGCAGAAG 23773 Hepal -6 Gml3088 TCTTTGATCATGACCCATAC 17790 Ctrl_1000 Rirfl 15 ACGCGGAAGGGTCAGAGCAC 23774 Hepal -6 Gml3088 AGTTATCTATCTACACTGCA 17791 Ctrl_1000 Ptdss2 CTGTACAAGCCGGCTGGCAC 23775 Hepal -6 Gml3088 TTACTGACATACTCTCCAAA 17792 Ctrl_1000 01fr414 CCTATAGATGTTCAACAATT 23776 CLAIMS

What is claimed is:

1. A method of vaccinating against cancer in a subject, the method comprising contacting a cell with a composition comprising a CRISPR activation (CRISPRa) system, wherein the CRISPRa system increases expression of at least one endogenous gene resulting in a modified cell, and administering a therapeutically effective amount of a composition comprising the modified cell to the subject, thereby vaccinating against cancer in the subject.

2. A method of treating cancer in a subject in need thereof, the method comprising contacting a cell with a composition comprising a CRISPRa system, wherein the CRISPRa system increases expression of at least one endogenous gene resulting in a modified cell, and administering a therapeutically effective amount of a composition comprising the modified cell to the subject, thereby treating the cancer in the subject.

3. The method of any one of claims 1-2, wherein the CRISPRa system comprises an sgRNA library.

4. The method of claim 3, wherein the sgRNA library comprises at least one sgRNA that targets at least one endogenous gene in the cell.

5. The method of any one of claims 1-2, wherein the CRISPRa system comprises a nucleic acid encoding dCas9-VP64, and a nucleic acid encoding MS2-p65-HSFl and a genome-scale lentiviral SAM CRISPRa sgRNA library.

6. The method of any one of claims 1-2, wherein the CRISPRa system comprises a nucleic acid encoding dCas9-VP64, a nucleic acid encoding MS2-p65-HSFl, and a nucleic acid encoding a genome-scale lentiviral SAM CRISPRa sgRNA library. 7. The method of any one of claims 1-2, wherein the cell is from a cancer cell line.

8. The method of any one of claims 1-2, wherein the cell is from the subject

9. The method of claim 8, wherein the cell from the subject is a cancer cell.

10. The method of any one of claims 1-2, wherein the subject is a mammal.

11. The method of any one of claims 1-2, wherein the subject is a human.

12. The method of any one of claims 1-2, wherein administering the therapeutically effective amount of the composition comprises a one dose, a two dose, a three dose, a four dose, or a multi-dose treatment.

13. The method of any one of claims 1-2, further comprising contacting the cell with a substance that induces senescence in the cell prior to administering to the subject.

14. The method of claim 13, wherein the substance that induces senescence in the cell is mitomycin.

15. The method of claim 2, wherein the cancer is selected from the group consisting of breast cancer, lung cancer, pancreatic cancer, melanoma, glioma, hepatoma, colon cancer, pancreatic cancer and brain cancer.

16. The method of claim 2, further comprising administering an additional treatment.

17. The method of claim 16, wherein the additional treatment is selected from the group consisting of chemotherapy, radiation, surgery, an immune checkpoint inhibitor, and an immune checkpoint blockade (ICB) antibody.

18. The method of claim 17, wherein the immune checkpoint inhibitor blocks CTLA- 4 or PD1. 19. The method of claim 18, wherein the immune checkpoint inhibitor is a monoclonal antibody selected from the group consisting of anti-CTLA4 and anti- PD1

20. The method of any one of claims 1-19, wherein the CRISPRa system is in an AAV vector, a lentiviral vector, or an adenoviral vector

21. The method of claim 20, wherein the AAV vector is AAV2, AAV8, AAV9, AAV-DJ, or other AAV serotypes.

22. A method of vaccinating against cancer in a subject in need thereof, the method comprising administering to the subject a therapeutically effective amount of a composition comprising a vector comprising a CRISPRa system, wherein the CRISPRa system increases expression of at least one endogenous gene in the subject, thereby vaccinating against cancer in the subject.

2 . A method of treating cancer in a subject in need thereof, the method comprising administering to the subject a therapeutically effective amount of a composition comprising a vector comprising a CRISPRa system, wherein the CRISPRa system increases expression of at least one endogenous gene in the subject, thereby treating the cancer in the subject.

24. The method of any one of claims 22-23, wherein the CRISPRa system is in an AAV vector, a lentiviral vector, or an adenoviral vector

25. The method of claim 24, wherein the AAV vector is AAV2, AAV8, AAV9, AAV-DJ, or other AAV serotypes.

26. The method of any one of claims 22-23, wherein the CRISPRa system comprises an sgRNA library.

27. The method of claim 26, wherein the sgRNA library comprises a plurality of sgRNAs that target a plurality of endogenous genes in the cell. 28. The method of any one of claims 22-23, wherein the CRISPRa system comprises a nucleic acid encoding dCas9-VP64, a nucleic acid encoding MS2-p65-HSFl, and a genome-scale lentiviral SAM CRISPRa sgRNA library.

29. The method of any one of claims 22-23, wherein the CRISPRa system comprises a nucleic acid encoding dCas9-VP64, a nucleic acid encoding MS2-p65-HSFl, and a nucleic acid encoding a genome-scale lentiviral SAM CRISPRa sgRNA library.

30. The method of claim 22, wherein the subject is a mammal.

31. The method of claim 22, wherein the subject is a human.

32. The method of any one of claims 22-23, wherein administering the therapeutically effective amount of the composition comprises a one dose, a two dose, a three dose, a four dose, or a multi-dose treatment.

33. The method of any one of claims 22-23, further comprising contacting the cell with a substance that induces senescence in the cell prior to administering to the subject.

34. The method of claim 33, wherein the substance that induces senescence in the cell is mitomycin.

35. The method of claim 23, wherein the cancer is selected from the group consisting of breast cancer, lung cancer, pancreatic cancer, melanoma, glioma, hepatoma, colon cancer, pancreatic cancer and brain cancer.

36. The method of any one of claims 22-23, further comprising administering an additional treatment. 37. The method of claim 36, wherein the additional treatment is selected from the group consisting of chemotherapy, radiation, surgery, an immune checkpoint inhibitor, an immune checkpoint blockade (ICB) antibody.

38. The method of claim 37, wherein the immune checkpoint inhibitor blocks CTLA- 4 or PD1 or other immune checkpoint targets.

39. The method of claim 37, wherein the immune checkpoint inhibitor is a monoclonal antibody selected from the group consisting of anti-CTLA4 and anti- PD1

40. The method of claim 23, further comprising wherein administering the composition alters the tumor microenvironment.

4 1. The method of claim 23, further comprising wherein administering the composition augments host immune responses against established tumors.

42. The method of claim 23, wherein the composition is administered intratumorally.

43 . A method of vaccinating against cancer in a subject in need thereof, the method comprising obtaining a cancer cell from the subject and determining at least one mutated endogenous gene, designing a CRISPRa system comprising an sgRNA library specific for the at least one mutated endogenous gene, administering a therapeutically effective amount of a composition comprising the CRISPRa system to the subject, thereby vaccinating against cancer in the subject.

44. A method of vaccinating against cancer in a subject in need thereof, the method comprising obtaining a cancer cell from the subject and determining at least one mutated endogenous gene, designing a CRISPRa system comprising an sgRNA library specific for the at least one mutated endogenous gene, contacting a cell with a composition comprising the CRISPRa system, wherein the CRISPRa system increases expression of the at least one mutated endogenous gene resulting in a modified cell, administering a therapeutically effective amount of a composition comprising the modified cell to the subject, thereby vaccinating against cancer in the subject.

45. A method of treating cancer in a subject in need thereof, the method comprising obtaining a cancer cell from the subject and determining at least one mutated endogenous gene, designing a CRISPRa system comprising an sgRNA library specific for the at least one mutated endogenous gene, administering a therapeutically effective amount of a composition comprising the CRISPRa system to the subject, thereby treating the cancer in the subject.

46. A method of treating cancer in a subject in need thereof, the method comprising obtaining a cancer cell from the subject and determining at least one mutated endogenous gene, designing a CRISPRa system comprising an sgRNA library specific for the at least one mutated endogenous gene, contacting a cell with a composition comprising the CRISPRa system, wherein the CRISPRa system increases expression of the at least one mutated endogenous gene resulting in a modified cell, administering a therapeutically effective amount of a composition comprising the modified cell to the subject, thereby treating the cancer in the subject.

47. The method of any one of claims 43-46, wherein the cell comprises a plurality of mutated endogenous genes, and the activation system comprises an sgRNA library specific for the plurality of mutated endogenous genes, and increases expression of the plurality of mutated endogenous genes. 48. The method of any one of claims 43-46, wherein determining the subject-specific mutated endogenous gene or genes comprises whole-exome sequencing of the cancer cell, whole-exome sequencing of a non-cancer cell from the subject, comparing the sequencing data from the cancer cell to the non-cancer cell and determining at least one mutation, thereby determining the subject-specific mutated endogenous gene or genes.

49. The method of claim 48, wherein the mutation is selected from the group consisting of a single nucleotide polymorphism (SNP), an insertion, a deletion, a frameshift, and a rearrangement.

50. The method of any one of claims 43-46, wherein the composition comprises a vector.

51. The method of any one of claims 43-46, wherein the CRISPRa system is in an AAV vector, a lentiviral vector, or an adenoviral vector

52. The method of claim 51, wherein the AAV vector is AAV2, AAV8, AAV9, AAV-DJ, or other AAV serotypes.

53. The method of any one of claims 43-46, wherein the endogenous genes contain detected somatic mutations.

54. The method of of any one of claims 43-46, wherein the sgRNAs are customized.

55. The method of any one of claims 43-46, wherein the CRISPRa system comprises a nucleic acid encoding dCas9-VP64, and a nucleic acid encoding MS2-p65- HSFland a genome-scale lentiviral CRISPRa sgRNA library.

56. The method of any one of claims 43-46, wherein the CRISPRa system comprises a nucleic acid encoding dCas9-VP64, a nucleic acid encoding MS2-p65-HSFl, and a nucleic acid encoding a genome-scale lentiviral CRISPRa sgRNA library. 57. The method of any one of claims 43-46, wherein the subject is a mammal.

58. The method of any one of claims 43-46, wherein the subject is a human.

59. The method of any one of claims 43-46, wherein administering the therapeutically effective amount of the composition comprises a one dose, a two dose, a three dose, a four dose, or a multi-dose treatment.

60. The method of any one of claims 43-46, further comprising contacting the cell with a substance that induces senescence in the cell prior to administering to the subject.

6 1. The method of claim 60, wherein the substance that induces senescence in the cell is mitomycin.

62. The method of any one of claims 43-46, wherein the cancer is selected from the group consisting of breast cancer, lung cancer, pancreatic cancer, melanoma, glioma, hepatoma, colon cancer, pancreatic cancer and brain cancer.

63. The method of any one of claims 43-46, further comprising administering an additional treatment.

64. The method of claim 63, wherein the additional treatment is selected from the group consisting of chemotherapy, radiation, surgery, an immune checkpoint inhibitor, an immune checkpoint blockade (ICB) antibody, and an immunotherapy.

65. The method of claim 64, wherein the immune checkpoint inhibitor blocks CTLA- 4 or PD1 or other immune checkpoint targets.

66. The method of claim 65, wherein the immune checkpoint inhibitor is a monoclonal antibody selected from the group consisting of anti-CTLA4, anti- PD1, and other immune checkpoint targets. 67. The method of any one of claims 43-46, further comprising wherein administering the composition alters the tumor microenvironment

68. The method of any one of claims 43-46, further comprising wherein administering the composition augments host immune responses against established tumors.

69. A method of generating an anti-tumor response in a subject, the method comprising contacting a cell with a composition comprising a CRISPRa system, wherein the CRISPRa system increases expression of a plurality of endogenous genes resulting in a modified cell, and administering a therapeutically effective amount of a composition comprising the modified cell to the subject, thereby generating an anti-tumor response.

70. A composition comprising a cancer vaccine, comprising a modified cell comprising a CRISPRa system capable of increasing expression of a plurality of endogenous genes.

71. A composition comprising an AAV vector comprising a CRISPRa system capable of increasing expression of a plurality of endogenous genes.

72. The composition of any one of claims 70-71, wherein the CRISPRa system comprises an sgRNA library, wherein the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 1-37.

7 . A vector comprising two sgRNA cassettes in a CRISPRa system, wherein the first sgRNA cassette is used for activation of antigen presentation machinery, and the second sgRNA cassette is used for activation of patient-specific mutated endogenous genes, either in single gene or pooled format.

74. The vector of claim 73, wherein the vector comprises the nucleic acid of SEQ ID NO: 38. 75. A method of treating cancer in a subject in need thereof, the method comprising administering to the subject a therapeutically effective amount of a composition comprising a vector comprising a CRISPRa system, wherein the CRISPRa system increases expression of at least one antigen presentation gene in the subject, thereby treating the cancer in the subject.

76. The method of claim 75, wherein the CRISPRa system is in an AAV vector, a lentiviral vector, or an adenoviral vector.

77. The method of claim 76, wherein the AAV vector is AAV2, AAV8, AAV9, AAV-DJ, or other AAV serotypes.

78. The method of any one of claims 75-77, wherein the CRISPRa system comprises an sgRNA library.

79. The method of claim 78, wherein the sgRNA library comprises a plurality of sgRNAs that target a plurality of antigen presentation genes in the cell.

80. The method of claim 79, wherein at least one of the sgRNAs comprises a nucleotide sequence selected from the group consisting of SEQ ID NOs: 23,886- 24,104.

81. The method of claim 79, wherein the plurality of sgRNAs comprise the nucleotide sequences consisting of SEQ ID NOs: 23,886-24,104.

82. The method of any one of claims 75-81, wherein the cancer is selected from the group consisting of breast cancer, lung cancer, pancreatic cancer, melanoma, glioma, hepatoma, colon cancer, pancreatic cancer and brain cancer.

83. The method of any one of claims 75-82, further comprising administering an additional treatment.

84. The method of claim 83, wherein the additional treatment is selected from the group consisting of chemotherapy, radiation, surgery, an immune checkpoint inhibitor, an immune checkpoint blockade (ICB) antibody, and an immunotherapy.

85. The method of claim 84, wherein the immune checkpoint inhibitor blocks CTLA- 4 or PD1 or other immune checkpoint targets.

86. The method of claim 85, wherein the immune checkpoint inhibitor is a monoclonal antibody selected from the group consisting of anti-CTLA4 and anti- PD1

87. The method of any one of claims 75-86, further comprising wherein administering the composition alters the tumor microenvironment.

88. The method of any one of claims 75-87, further comprising wherein administering the composition augments host immune responses against established tumors.

89. A composition comprising an sgRNA library, wherein the sgRNA library comprises a plurality of sgRNAs that target a plurality genes in the cell.

90. The composition of claim 89, wherein the plurality of sgRNAs comprise at least one sgRNA selected from the group consisting of SEQ ID NOs: 23,886-24,104.

91. The composition of claim 89, wherein the plurality of sgRNAs comprise the

nucleotide sequences consisting of SEQ D NOs: 23,886-24,104.

92. The composition of claim 89, wherein the plurality of sgRNAs comprise at least one sgRNA selected from the group consisting of SEQ ID NOs: 51-259.

93. The composition of claim 89, wherein the plurality of sgRNAs comprise the

nucleotide sequences consisting of SEQ D NOs: 51-259.

94. The composition of claim 89, wherein the plurality of sgRNAs comprise at least

one sgRNA selected from the group consisting of SEQ ED NOs: 260-348. 95. The composition of claim 89, wherein the plurality of sgRNAs comprise the

nucleotide sequences consisting of SEQ ED NOs: 260-348.

96. The composition of claim 89, wherein the plurality of sgRNAs comprise at least

one sgRNA selected from the group consisting of SEQ ED NOs: 349-4,187.

97. The composition of claim 89, wherein the plurality of sgRNAs comprise the

nucleotide sequences consisting of SEQ ED NOs: 349-4,187.

98. The composition of claim 89, wherein the plurality of sgRNAs comprise at least

one sgRNA selected from the group consisting of SEQ ED NOs: 4,188-7,980.

99. The composition of claim 89, wherein the plurality of sgRNAs comprise the

nucleotide sequences consisting of SEQ ED NOs: 4,188-7,980.

100. The composition of claim 89, wherein the plurality of sgRNAs comprise at least

one sgRNA selected from the group consisting of SEQ ED NOs: 7,981-1 1,808.

101 . The composition of claim 89, wherein the plurality of sgRNAs comprise the

nucleotide sequences consisting of SEQ D NOs: 7,981-1 1,808.

102. The composition of claim 89, wherein the plurality of sgRNAs comprise at least

one sgRNA selected from the group consisting of SEQ D NOs: 11,809-23,776.

103. The composition of claim 89, wherein the plurality of sgRNAs comprise the

nucleotide sequences consisting of SEQ D NOs: 11,809-23,776.

104. The composition of claim 89, wherein the plurality of sgRNAs comprise at least

one sgRNA selected from the group consisting of SEQ ED NOs: 23,779-23,885.

105. The composition of claim 89, wherein the plurality of sgRNAs comprise the

nucleotide sequences consisting of SEQ ED NOs: 23,779-23,885. 106. The composition of any one of claims 89-105, futher comprising wherein the sgRNA library is cloned and packaged into an AAV vector.

107. A vector comprising the nucleic acid sequence of SEQ ID NO: 24,105.

108. A vector comprising the nucleic acid sequence of SEQ ID NO: 24,106.

109. A method treating cancer in a subject in need thereof, the method comprising contacting a cell with a first AAV vector comprising a CRISPRa system, and a second AAV vector comprising dCas9, wherein the CRISPRa system increases expression of at least one endogenous gene resulting in a modified cell, and administering a therapeutically effective amount of a composition comprising the modified cell to the subject, thereby treating the cancer in the subject.

110. The method of claim 109, wherein the CRISPRa system comprises an sgRNA library comprising a plurality of sgRNAs.

111. The method of claim 109, wherein the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 1-37.

112. The method of claim 109, wherein the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 51-259.

113. The method of claim 109, wherein the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 260-348.

114. The method of claim 109, wherein the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 349-4,187.

115. The method of claim 109, wherein the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 4,188-7,980. 116. The method of claim 109, wherein the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs 7,981-1 1,808.

117. The method of claim 109, wherein the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 11,809-23,776.

118. The method of claim 109, wherein the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs. 23,779-23,885.

119. The method of claim 109, wherein the sgRNA library comprises at least one sequence selected from the group consisting of SEQ ID NOs: 23,886-24,104.

120. The method of claim 109, wherein the sgRNA library comprises the nucleotide sequences consisting of SEQ ID NOs: 23,886-24,104.

121 . The method of claim 109, wherein the first AAV vector comprises the nucleic acid sequence of SEQ ID NO: 38 or SEQ ID NO: 49.

122. The method of claim 96, wherein the second AAV vector comprises the nucleic acid sequence of SEQ ID NO 24,105 or SEQ ID NO 24,106.

Form PCT/ISA/210 (second sheet) (January 2015) Form PCT/ISA/210 (continuation of first sheet (1)) (January 201 5) Form PCT/1SA/210 (continuation of first sheet (2)) (January 201 5) Form PCT/ISA/210 (extra sheet) (January 2015) INTERNATIONAL SEARCH REPORT International application No.

PCT/US201 9/027956

generating an anti-tumor response; a composition comprising a cancer vaccine, comprising a modified cell comprising a CRISPRa system capable of increasing expression of a plurality of endogenous genes; a composition comprising an AAV vector comprising a CRISPRa system capable of increasing expression of a plurality of endogenous genes; a vector comprising two sgRNA cassettes in a CRISPRa system, wherein the first sgRNA cassette is used for activation of antigen presentation machinery, and the second sgRNA cassette is used for activation of patient-specific mutated endogenous genes, either in single gene or pooled format; a method of treating cancer in a subject in need thereof, the method comprising administering to the subject a therapeutically effective amount of a composition comprising a vector comprising a CRISPRa system, wherein the CRISPRa system increases expression of at least one antigen presentation gene in the subject, thereby treating the cancer in the subject; a composition comprising an sgRNA library, wherein the sgRNA library comprises a plurality of sgRNAs that target a plurality genes in the cell; a vector comprising the nucleic acid; a method treating cancer in a subject in need thereof, the method comprising contacting a cell with a first AAV vector comprising a CRISPRa system, and a second AAV vector comprising dCas9, wherein the CRISPRa system increases expression of at least one endogenous gene resulting in a modified cell, and administering a therapeutically effective amount of a composition comprising the modified cell to the subject, thereby treating the cancer in the subject; these shared technical features do not represent a contribution over the prior art.

Specifically, WO 2017/004153 A 1 to The Broad Institute et al. discloses a method of vaccinating against cancer in a subject (therapeutic methods are also provided to treat a patient in need thereof who would benefit from an increased immune response, Abstract; improved vaccines and novel immune-based therapies for various cancers, Para. [0006]), the method comprising contacting a cell with a composition comprising a CRISPR activation (CRISPRa) system (the components of a CRISPR system sufficient to form a CRISPR complex, including the guide sequence to be tested, may be provided to a host cell, Para. [00246]; applying CRISPRa, Para. [00837]), wherein the CRISPRa system increases expression of at least one endogenous gene resulting in a modified cell (an isolated immune cell modified to comprise an altered expression or activity of POU2A, Para. [0018]; upregulating expression or activity in at least one gene of an opposing gene signature, Para. [0027]; POU2AF1 ... such that an intended biological or physiological activity is increased, Para. [00134]), and administering a therapeutically effective amount of a composition comprising the modified cell to the subject (an isolated immune cell modified to comprise an altered expression or activity of POU2A, Para. [0018]; The administration of the cells or , population of cells according to the present invention may be carried out in any convenient manner, Para. [00173]), thereby vaccinating against cancer in the subject (therapeutic methods are also provided to treat a patient in need thereof who would benefit from an increased immune response, Abstract; improved vaccines and novel immune-based therapies for various cancers, Para. [0006]); a method of treating cancer in a subject in need thereof (therapeutic methods are also provided to treat a patient in need thereof who would benefit from an increased immune response, Abstract; improved vaccines and novel immune-based therapies for various cancers, Para. [0006]), the method comprising contacting a cell with a composition comprising a CRISPRa system (the components of a CRISPR system sufficient to form a CRISPR complex, including the guide sequence to be tested, may be provided to a host cell, Para. [00246]; applying CRISPRa, Para. [00837]), wherein the CRISPRa system increases expression of at least one endogenous gene resulting in a modified cell (an isolated immune cell modified to comprise an altered expression or activity of POU2A, Para. [0018]; upregulating expression or activity in at least one gene of an opposing gene signature, Para. [0027]; POU2AF1 ... such that an intended biological or physiological activity is increased, Para. [00134]), and administering a therapeutically effective amount of a composition comprising the modified cell to the subject (an isolated immune cell modified to comprise an altered expression or activity of POU2A, Para. [0018]; The administration of the cells or population of cells according to the present invention may be carried out in any convenient manner, Para. [00173]), thereby treating the cancer in the subject (therapeutic methods are also provided to treat a patient in need thereof who would - benefit from an increased immune response, Abstract; improved vaccines and novel immune-based therapies for various cancers, Para. [0006]); a method of vaccinating against cancer in a subject in need thereof (therapeutic methods are also provided to treat a patient in need thereof who would benefit from an increased immune response, Abstract; improved vaccines and novel immune-based therapies for various cancers, Para. [0006]), the method comprising administering to the subject a therapeutically effective amount of a composition comprising a vector comprising a CRISPRa system (may be provided to a host cell having the corresponding target , sequence, such as by transfection with vectors encoding the components of the CRISPR sequence, Para. [00246]; the components of a CRISPR system sufficient to form a CRISPR complex, including the guide sequence to be tested, may be provided to a host cell, Para. [00246]; applying CRISPRa, Para. [00837]), wherein the CRISPRa system increases expression of at least one endogenous gene in the subject (an isolated immune cell modified to comprise an altered expression or activity of POU2A, Para. [0018]; upregulating expression or activity in at least one gene of an opposing gene signature, Para. [0027]; POU2AF1 ... such that an intended biological or physiological activity is increased, Para. [00134]), thereby vaccinating against cancer in the subject (therapeutic methods are also provided to treat a patient in need thereof who would benefit from an increased immune response, Abstract; improved vaccines and novel immune-based therapies for various cancers, Para. [0006]); a method of vaccinating against cancer in a subject in need thereof (therapeutic methods are also provided to treat a patient in need thereof who would benefit from an increased immune response, Abstract; improved vaccines and novel immune-based therapies for various cancers, Para. [0006]), the method comprising obtaining a cancer cell from the subject and determining at least one mutated endogenous gene (preferably a CD8+ T cell, may have been isolated from a tumor of a subject, Para. [00164]; a normal point mutation in a diploid cell, Para. [00479]), designing a CRISPRa system comprising an sgRNA library specific for the at least one mutated endogenous gene (perturbations target expressed genes as defined by RNA-seq using a focused sgRNA library. Libraries may be focused on expressed genes in specific networks or pathways. In other preferred embodiments, regulatory drivers are perturbed, Para. [00841]), administering a therapeutically effective amount of a composition comprising the CRISPRa system to the subject (an isolated immune cell modified to comprise an altered expression or activity of POU2A, Para. [0018]; upregulating expression or activity in at least one gene of an opposing gene signature, Para. [0027]; POU2AF1 ... such that an intended biological or physiological activity is increased, Para. [00134]), thereby vaccinating against cancer in the subject thereof (therapeutic methods are also provided to treat a patient in need thereof who would benefit from an increased immune response, Abstract; improved vaccines and novel immune-based therapies for various cancers, Para. [0006]); a method of vaccinating against cancer in a subject in need thereof (therapeutic methods are also provided to treat a patient in need thereof who would benefit from an increased immune response, Abstract; improved vaccines and novel immune-based therapies for various cancers, Para. [0006]), the method comprising obtaining a cancer cell from the subject and determining at least one mutated endogenous gene , (preferably a CD8+ T cell, may have been isolated from a tumor of a subject, Para. [00164]; a normal point mutation in a diploid cell, Para. [00479]), designing a CRISPRa system comprising an sgRNA library specific for the at least one mutated endogenous gene gene (perturbations target expressed genes as defined by RNA-seq using a focused sgRNA library. Libraries may be focused on expressed genes in specific networks or pathways. In other preferred embodiments, regulatory drivers are perturbed, Para. [00841]), contacting a cell with a composition comprising the CRISPRa system, wherein the CRISPRa system increases expression of the at least one mutated endogenous gene resulting in a modified cell (an isolated immune cell modified to comprise an altered expression or activity of POU2A, Para. [0018]; upregulating expression or activity in at least one gene of an opposing gene signature, Para. [0027]; POU2AF1 ... such that

Form PCT/ISA/210 (extra sheet) (January 2015) Form PCT/ISA/210 (extra sheet) (January 201 5) Form PCT/ISA/210 (extra sheet) (January 2015)