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ODF 1.0 Headerlines= 9 Model= Gene List COLUMN NAMES:Feature Description COLUMN TYPES:String String Float COLUMN DESCS:Name of the Description of the Gene

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ODF 1.0 HeaderLines= 9 Model= Gene List COLUMN_NAMES:Feature Description COLUMN_TYPES:String String float COLUMN_DESCS:Name of the Description of the gene. Distance from reference gene. MarkerSelectionMethod= Continuous GeneName= Z48481_at_NA_illumina DistanceFunction= Euclidean NumNeighbors= 15191 DataLines= 15191 N Target ID Description Score 1 Z48481_at_NA_illumina MT-MMP protein 0 2 U66059_cds7_at_NA_illumina TCRBV1S1A1N1 gene extracted from 2012.3337 3 HG3319-HT3496_s_at_NA_illumina Split Gene 1 Enhancer, Tup1-Like 2044.1316 4 M34667_at_GI_33598945-A PLCG1 Phospholipase C, gamma 1 2044.6802 5 M87284_at_GI_8051624-A 69/71 KD 2080.5542 6 HG243-HT243_s_at_NA_illumina Lowe Oculocerebrorenal Syndrome 2083.9236 7 U77827_at_GI_4504090-S Orphan G protein-coupled receptor 2084.0466 8 L13434_at_NA_illumina Chromosome 3p21.1 gene sequence 2114.1865 9 X66894_s_at_GI_4557588-S FACC Fanconi anemia complementation 2145.438 10 D88613_at_GI_45269132-S HGCMa 2148.3267 11 X97160_rna1_at_GI_21359903-S TFE3 transcription factor gene extracted 2158.8982 12 X99687_at_NA_illumina Methyl-CpG-binding protein 2, intron 2 2165.1611 13 Y08302_at_GI_4503420-S MAP kinase phosphatase 4 2166.3406 14 M29581_at_GI_33438574-S ZNF8 Zinc finger protein 8 (clone HF.18) 2172.3496 15 U24056_s_at_NA_illumina Inward rectifier K+ channel protein (hirk2) 2179.5518 16 U52830_at_NA_illumina Cri-du-chat region mRNA, clone CSC8 2182.0735 17 X80763_s_at_NA_illumina HTR2C 5-hydroxytryptamine (serotonin) 2184.6533 18 HG960-HT960_at_NA_illumina Guanine Nucleotide Exchange Factor 1 2187.7837 19 X90978_at_NA_illumina An acute myeloid leukaemia protein 2189.3987 20 HG4336-HT4606_at_NA_illumina Bactericidal Bpi'Gene 2189.5771 21 X83973_at_GI_33356178-S TTF-I 2193.3801 22 M20747_s_at_GI_4507010-S SLC2A4 Solute carrier family 2 (facilitated 2193.7532 23 X97249_at_GI_41352696-S Leucine-rich primary response protein 1 2195.7188 24 U86409_at_GI_20302154-A Hyaluronan synthase 3 (HAS3) gene, 2195.8064 25 HG4167-HT4437_at_NA_illumina Nuclear Factor 1, A Type 2196.7754 26 U37251_at_GI_4508008-S ZNF177 KRAB zinc finger protein 2204.1401 27 U34962_at_GI_4758089-S Transcription factor HCSX (hCsx) mRNA 2212.3677 28 U25750_at_NA_illumina Chromosome 17q21 mRNA clone 1046:1- 2213.5823 29 U79252_at_GI_42766427-S Clone 23679 mRNA 2215.5974 30 U66052_at_NA_illumina Clone W2-6 mRNA from chromosome X 2217.1167 31 M85247_at_GI_16445404-S Dopamine D1A receptor gene, complete 2223.9565 32 D56495_at_GI_10835249-S Reg-related sequence derived peptide-1 2224.005 33 M55040_at_GI_7710156-A ACHE Acetylcholinesterase (YT blood 2227.7664 34 U20428_at_GI_21264629-S SNC19 mRNA sequence 2230.5 35 HG3255-HT3432_at_NA_illumina Gamma-Aminobutyric Acid (Gaba) A 2233.5542 36 HG2525-HT2621_at_NA_illumina Helix-Loop-Helix Protein Delta Max, Alt. 2234.9026 37 X90763_at_GI_15431313-S Type I keratin, hHa5 2237.123 38 S81264_s_at_GI_44921604-S Hs-TBX2=T-box gene {T-box region} 2238.7046 39 J02888_at_GI_4505416-S NMOR2 Quinone oxidoreductase (NQO2) 2239.614 40 X55005_rna1_at_NA_illumina C-erbA-1 mRNA for thyroid hormone 2239.799 41 M26683_at_GI_22538812-S SCYA2 Small inducible cytokine A2 2240.934 42 M87434_at_NA_illumina 69/71 KD 2241.4102 43 X90761_at_GI_15431311-S HHKa2 protein 2241.6658 44 U70064_s_at_NA_illumina Lysosomal trafficking regulator (LYST) 2243.0295 45 X97544_at_GI_5454119-S TIM17 preprotein translocase 2245.2588 46 HG1723-HT1729_at_NA_illumina Macrophage Scavenger Receptor, Alt. 2250.1206 47 X07024_at_NA_illumina TRANSCRIPTION INITIATION FACTOR 2251.392 48 U44755_at_GI_4507102-S PSE-binding factor PTF delta subunit 2252.0354 49 U79718_at_GI_38455392-S Endonuclease III homolog mRNA 2252.4956 50 X99141_at_GI_15431322-S Hair keratin, hHb3 2253.395 51 U33839_at_NA_illumina No description available for U33839 2259.4185 52 X97444_f_at_NA_illumina Transmembrane protein Tmp21-IIex 2260.5552 53 L76224_at_GI_6006004-S NMDA receptor mRNA 2260.595 54 D14889_at_GI_34485717-S Small GTP-binding protein, S10 2261.7961 55 HG2028-HT2082_at_NA_illumina Laminin, A Polypeptide 2262.6914 56 U66828_s_at_NA_illumina Carnitine palmitoyltransferase I (CPTI) 2264.8503 57 U64315_s_at_GI_4885216-S XPF Xeroderma pigmentosum, 2265.378 58 X79981_at_GI_14589894-S CDH5 Cadherin 5, VE-cadherin (vascular 2265.4158 59 U96629_rna2_at_GI_41281366-S 2A8.3 gene (hereditary multiple exostoses 2271.6372 60 M94172_s_at_GI_4502522-S N-type calcium channel alpha-1 subunit 2271.8926 61 U87408_at_NA_illumina Clone IMAGE:30008 unknown protein 2274.8567 62 M64108_at_GI_37555875-S Udulin 1 mRNA, 3' end 2275.7515 63 X80915_rna1_at_GI_5123452-S Gdf5 gene 2277.7466 64 X64269_at_NA_illumina TCF6L1 Transcription factor 6-like 1 2282.456 65 U09303_at_GI_31317225-S Placenta LERK-2 (EPLG2) mRNA 2283.129 66 X62573_at_GI_21361190-S FCGR2B Fc fragment of IgG, low affinity 2284.304 67 U39905_at_GI_4506986-S SLC18A1 Solute carrier family 18 2285.06 68 D85245_at_NA_illumina TR3beta 2288.2212 69 U63541_at_NA_illumina mRNA expressed in HC/HCC livers and 2289.9778 70 X69115_at_GI_37551348-S ZNF37A Zinc finger protein 37a (KOX 21) 2290.2673 71 X82206_s_at_GI_13325058-S ALPHA-CENTRACTIN 2290.3542 72 Z31357_at_GI_4502754-S CDO1 Cysteine dioxygenase, type 1 2291.2485 73 M83181_at_GI_4504530-S Serotonin receptor gene 2292.4575 74 J03930_at_GI_13787191-S ALKALINE PHOSPHATASE, INTESTINAL 2294.2888 75 U57623_s_at_GI_10938020-S FATTY ACID-BINDING PROTEIN, HEART 2297.322 76 U09477_at_GI_5032188-S Clone 53BP1 p53-binding protein mRNA, 2297.762 77 U31176_at_GI_4885264-S HERV1 mRNA 2299.174 78 U77846_rna1_s_at_NA_illumina Elastin gene, partial cds and partial 3'UTR 2300.6667 79 M33684_s_at_NA_illumina (clone lambda-16-1) non-receptor tyrosine 2300.7874 80 Z70219_at_GI_7662245-S 5'UTR for unknown protein (clone 2306.0542 81 U71088_at_NA_illumina MAP kinase kinase MEK5c mRNA 2308.3118 82 U59878_at_GI_20127508-S Low-Mr GTP-binding protein (RAB32) 2309.919 83 X02750_at_GI_4506114-S PROC Protein C (inactivator of coagulation 2311.7773 84 M80629_at_GI_14110389-A Cdc2-related protein kinase (CHED) 2314.3303 85 M91592_at_GI_34147656-S ZNF76 Zinc finger protein 76 2314.997 86 HG4606-HT5011_at_NA_illumina Centractin, Alpha 2315.9526 87 U67674_at_GI_4506972-S SLC15A2 Solute carrier family 15 2318.32 88 D86977_at_GI_41406095-S KIAA0224 gene 2318.9692 89 Z48054_at_NA_illumina PXR1 Peroxisome receptor 1 2319.0742 90 U59736_at_NA_illumina Transcription factor (NFATc.b) mRNA 2319.621 91 U69645_at_GI_24307924-S Zinc finger protein mRNA 2322.696 92 HG273-HT273_s_at_NA_illumina Lymphocyte Antigen Hla-G3 2323.342 93 M92303_at_GI_40804469-I DIHYDROPRYRIDINE-SENSITIVE L- 2324.86 94 Y07829_xpt4_at_GI_16445349-A Exon A2 from H.sapiens gene encoding 2326.6436 95 M62783_at_GI_4557780-S NAGA N-acetylgalactosaminidase, alpha- 2326.8486 96 J00212_f_at_GI_4504594-S IFNA21 Interferon, alpha 21 2327.248 97 U16127_at_GI_28605144-S GRIK5 Glutamate receptor, ionotropic, 2327.8196 98 D85527_at_NA_illumina LIM domain, partial cds 2328.4573 99 U78793_at_NA_illumina Folate receptor alpha (hFR) mRNA, partial 2329.1672 100 L22454_at_GI_28882054-S Nuclear respiratory factor-1 (NRF-1) 2329.5732 101 L20815_at_GI_26787969-S S protein mRNA 2331.4756 102 D78129_at_GI_6806899-S Squalene epoxidase, partial cds 2334.2769 103 X51435_s_at_GI_4504388-S HIVEP1 Human immunodeficiency virus 2334.5452 104 Z80783_at_NA_illumina H2B/l gene 2334.9807 105 X14675_at_NA_illumina Bcr-abl mRNA 5' fragment (clone 3c) 2335.5066 106 Z67743_at_GI_39725672-S Chloride channel protein (CLCN7) mRNA, 2341.6646 107 L04282_at_GI_11415035-S CACCC box-binding protein mRNA 2344.4785 108 K01383_at_GI_28866959-S Metallothionein-I-A gene, complete coding 2344.4805 109 U21858_at_GI_38570151-A HISTONE H3.3 2344.7405 110 D63877_at_GI_20127649-S KIAA0241 gene, partial cds 2345.987 111 X72632_s_at_NA_illumina Rev-ErbAalpha protein (hRev gene) 2348.1958 112 HG3920-HT4521_s_at_NA_illumina Homeotic Protein A1, Class I, Alt. Splice 1 2349.397 113 X76104_at_GI_4826683-S DAP-kinase mRNA 2353.2764 114 M55422_at_GI_7705388-S Krueppel-related zinc finger protein (H-plk) 2355.8335 115 Z15114_at_GI_31377808-S PRKCG Protein kinase C, gamma 2357.7598 116 J04809_rna1_at_GI_4502010-S Cytosolic adenylate kinase (AK1) gene 2360.8472 117 M63175_at_GI_21071002-A AMFR Autocrine motility factor receptor 2363.4553 118 X66417_at_GI_4885160-S KAPPA CASEIN PRECURSOR 2363.6582 119 AF002700_at_GI_22091444-S RET ligand 2 (RETL2) mRNA 2364.3035 120 X86012_at_NA_illumina DNA sequence from intron 22 of the factor 2364.8708 121 U49837_at_GI_4502892-S LIM protein MLP mRNA 2364.8904 122 HG2639-HT2735_s_at_NA_illumina Single-Stranded Dna-Binding Protein Mssp- 2366.615 123 L14754_at_GI_4504622-S IGHMBP2 DNA-binding protein (SMBP2) 2367.4336 124 U09410_at_NA_illumina ZNF131 Zinc finger protein 131 (clone pHZ- 2369.5703 125 HG908-HT908_at_NA_illumina Mg61 Protein (Gb:L08239) 2371.678 126 HG2480-HT2576_at_NA_illumina Fmlp-Related Receptor I 2371.705 127 Z49105_at_NA_illumina HD21 mRNA 2373.3062 128 X65867_at_GI_4557268-S ADENYLOSUCCINATE LYASE 2374.4438 129 Z69915_at_NA_illumina mRNA (clone ICRFp507L1876) 2374.7668 130 Y00414_s_at_GI_40786545-S TH Tyrosine hydroxylase 2374.906 131 L42563_at_GI_10280617-S ATP1AL1 ATP-driven ion pump 2375.7573 132 U67369_at_GI_4885266-S Growth factor independence-1 (Gfi-1) 2375.964 133 Z69720_at_GI_4505232-S MPG N-methylpurine-DNA glycosylase 2376.5789 134 D84307_at_GI_4505650-S Phosphoethanolamine cytidylyltransferase 2378.9658 135 X01715_at_GI_7382453-S Gene fragment for the acetylcholine 2379.3076 136 M21812_at_NA_illumina MYL2 Myosin, light polypeptide 2, 2379.696
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    Genes in Eyecare geneseyedoc 3 W.M. Lyle and T.D. Williams 15 Mar 04 This information has been gathered from several sources; however, the principal source is V. A. McKusick’s Mendelian Inheritance in Man on CD-ROM. Baltimore, Johns Hopkins University Press, 1998. Other sources include McKusick’s, Mendelian Inheritance in Man. Catalogs of Human Genes and Genetic Disorders. Baltimore. Johns Hopkins University Press 1998 (12th edition). http://www.ncbi.nlm.nih.gov/Omim See also S.P.Daiger, L.S. Sullivan, and B.J.F. Rossiter Ret Net http://www.sph.uth.tmc.edu/Retnet disease.htm/. Also E.I. Traboulsi’s, Genetic Diseases of the Eye, New York, Oxford University Press, 1998. And Genetics in Primary Eyecare and Clinical Medicine by M.R. Seashore and R.S.Wappner, Appleton and Lange 1996. M. Ridley’s book Genome published in 2000 by Perennial provides additional information. Ridley estimates that we have 60,000 to 80,000 genes. See also R.M. Henig’s book The Monk in the Garden: The Lost and Found Genius of Gregor Mendel, published by Houghton Mifflin in 2001 which tells about the Father of Genetics. The 3rd edition of F. H. Roy’s book Ocular Syndromes and Systemic Diseases published by Lippincott Williams & Wilkins in 2002 facilitates differential diagnosis. Additional information is provided in D. Pavan-Langston’s Manual of Ocular Diagnosis and Therapy (5th edition) published by Lippincott Williams & Wilkins in 2002. M.A. Foote wrote Basic Human Genetics for Medical Writers in the AMWA Journal 2002;17:7-17. A compilation such as this might suggest that one gene = one disease.
  • A Comprehensive Analysis of the Expression of Crystallins in Mouse Retina Jinghua Xi Washington University School of Medicine in St

    A Comprehensive Analysis of the Expression of Crystallins in Mouse Retina Jinghua Xi Washington University School of Medicine in St

    Washington University School of Medicine Digital Commons@Becker Open Access Publications 2003 A comprehensive analysis of the expression of crystallins in mouse retina Jinghua Xi Washington University School of Medicine in St. Louis Rafal Farjo University of Michigan - Ann Arbor Shigeo Yoshida University of Michigan - Ann Arbor Timothy S. Kern Case Western Reserve University Anand Swaroop University of Michigan - Ann Arbor See next page for additional authors Follow this and additional works at: https://digitalcommons.wustl.edu/open_access_pubs Recommended Citation Xi, Jinghua; Farjo, Rafal; Yoshida, Shigeo; Kern, Timothy S.; Swaroop, Anand; and Andley, Usha P., ,"A comprehensive analysis of the expression of crystallins in mouse retina." Molecular Vision.9,. 410-419. (2003). https://digitalcommons.wustl.edu/open_access_pubs/1801 This Open Access Publication is brought to you for free and open access by Digital Commons@Becker. It has been accepted for inclusion in Open Access Publications by an authorized administrator of Digital Commons@Becker. For more information, please contact [email protected]. Authors Jinghua Xi, Rafal Farjo, Shigeo Yoshida, Timothy S. Kern, Anand Swaroop, and Usha P. Andley This open access publication is available at Digital Commons@Becker: https://digitalcommons.wustl.edu/open_access_pubs/1801 Molecular Vision 2003; 9:410-9 <http://www.molvis.org/molvis/v9/a53> © 2003 Molecular Vision Received 28 May 2003 | Accepted 19 August 2003 | Published 28 August 2003 A comprehensive analysis of the expression of crystallins in mouse retina Jinghua Xi,1 Rafal Farjo,3 Shigeo Yoshida,3 Timothy S. Kern,5 Anand Swaroop,3,4 Usha P. Andley1,2 Departments of 1Ophthalmology and Visual Sciences and 2Biochemistry and Molecular Biophysics, Washington University School of Medicine, St.
  • Related Macular Degeneration and Cutis Laxa

    Related Macular Degeneration and Cutis Laxa

    UvA-DARE (Digital Academic Repository) Genetic studies of age-related macular degeneration Baas, D.C. Publication date 2012 Document Version Final published version Link to publication Citation for published version (APA): Baas, D. C. (2012). Genetic studies of age-related macular degeneration. General rights It is not permitted to download or to forward/distribute the text or part of it without the consent of the author(s) and/or copyright holder(s), other than for strictly personal, individual use, unless the work is under an open content license (like Creative Commons). Disclaimer/Complaints regulations If you believe that digital publication of certain material infringes any of your rights or (privacy) interests, please let the Library know, stating your reasons. In case of a legitimate complaint, the Library will make the material inaccessible and/or remove it from the website. Please Ask the Library: https://uba.uva.nl/en/contact, or a letter to: Library of the University of Amsterdam, Secretariat, Singel 425, 1012 WP Amsterdam, The Netherlands. You will be contacted as soon as possible. UvA-DARE is a service provided by the library of the University of Amsterdam (https://dare.uva.nl) Download date:05 Oct 2021 G������ S������ �� A��-������� M������ D����������� D����������� M������ G������ S������ �� A��-������� | 2012 D�������� C. B��� G������ S������ �� A��-������� M������ D����������� D�������� C. B��� cover.indd 1 31-10-12 08:36 Genetic Studies of Age-related Macular Degeneration Dominique C. Baas Chapter 0.indd 1 23-10-12 19:24 The research described in this thesis was conducted at the Netherlands Institute for Neuroscience (NIN), an institute of the Royal Netherlands Academy of Arts and Sciences, Department of Clinical and Molecular Ophthalmogenetics, Amsterdam, The Netherlands.
  • Differential Stromal Reprogramming in Benign and Malignant Naturally Occurring Canine Mammary Tumours Identifies Disease-Promoting Stromal Components

    Differential Stromal Reprogramming in Benign and Malignant Naturally Occurring Canine Mammary Tumours Identifies Disease-Promoting Stromal Components

    bioRxiv preprint doi: https://doi.org/10.1101/783621; this version posted September 26, 2019. The copyright holder for this preprint (which was not certified by peer review) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. It is made available under aCC-BY-NC-ND 4.0 International license. Differential stromal reprogramming in benign and malignant naturally occurring canine mammary tumours identifies disease-promoting stromal components Parisa Amini 1,a, Sina Nassiri 2,a, Alexandra Malbon 3,4 and Enni Markkanen 1,* 1 Institute of Veterinary Pharmacology and Toxicology, Vetsuisse Faculty, University of Zürich, Zürich, Switzerland 2 Bioinformatics Core Facility, SIB Swiss Institute of Bioinformatics, Lausanne, Switzerland 3 Institute of Veterinary Pathology, Vetsuisse Faculty, University of Zürich, Zürich, Switzerland 4 current address: The Royal (Dick) School of Veterinary Studies and The Roslin Institute Easter Bush Campus, Midlothian, EH25 9RG a these authors contributed equally to the manuscript * Correspondence: [email protected]; ORCID: 0000-0001-7780-8233 Keywords Laser-capture microdissection, canine mammary carcinoma, canine mammary adenoma, breast cancer, tumour stroma, tumour microenvironment Summary statement: RNasequencing-based analysis of stromal reprogramming between benign and malignant naturally occurring canine mammary tumours identifies potential molecular drivers in cancer-associated stroma that support tumour growth and malignancy. Abstract The importance of cancer-associated stroma (CaS) for initiation and progression of cancer is well accepted. However, as stromal changes in benign forms of naturally occurring tumours are poorly understood, it remains unclear how CaS from benign and malignant tumours compare. Spontaneous canine mammary tumours are viewed as excellent models of human mammary carcinomas (mCa).