DOCSLIB.ORG

Journal of Virology Volume 68 * November 1994 * Number 11

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Journal of Virology Volume 68 * November 1994 * Number 11 JOURNAL OF VIROLOGY VOLUME 68 * NOVEMBER 1994 * NUMBER 11 Thomas E. Shenk, Editor in Chief (1999) Carol Prives, Editor (1996) Princeton University Mary K. Estes, Editor (1998) Columbia University Princeton, N.J. Baylor College of Medicine New York, N.Y John M. Coffin, Editor (1996) Houston, Tex. Vincent R. Racaniello, Editor (1997) Tufts University Medical School Diane E. Griffin, Editor (1999) Columbia University Boston, Mass. The Johns Hopkins University School New York, N. Y Ronald C. Desrosiers, Editor (1998) of Medicine Joseph Sodroski, Editor (1998) Harvard Medical School Baltimore, Md. Dana-Farber Cancer Institute Boston, Mass. Peter M. Howley, Editor (1998) Boston, Mass. Lynn W. Enquist, Editor (1999) Harvard Medical School Inder M. Verma, Editor (1998) Princeton University Boston, Mass. The Salk Institute Princeton, N.J. San Diego, Calif EDITORIAL BOARD Rafi Ahmed (1994) Hidesaburo Hanafusa (1995) Bernard Moss (1995) Heinz Schaller (1995) Carl C. Baker (1994) Ed Harlow (1996) Richard W. Moyer (1995) Sondra Schlesinger (1995) Amiya K. Banerjee (1996) Gary S. Hayward (1996) James Mullins (1996) Robert J. Schneider (1994) Kenneth I. Berns (1994) Ari H. Helenius (1996) Brian R. Murphy (1994) Manfred H. Schubert (1996) Joseph B. Bolen (1994) Virginia S. Hinshaw (1996) Nicholas A. Muzyczka (1996) Bartholomew M. Sefton (1994) Thomas J. Braciale (1994) David D. Ho (1996) Gerald Myers (1995) Bert L. Semler (1995) John Brady (1994) James M. Hogle (1994) Gary J. Nabel (1996) David A. Shafritz (1994) Thomas R. Broker (1995) John J. Holland (1996) Opendra Narayan (1994) Yosef Shaul (1995) Michael J. Buchmeier (1995) Kathryn V. Holmes (1994) Neal Nathanson (1996) Saul J. Silverstein (1994) Robert Callahan (1994) Nancy Hopkins (1995) Jay A. Nelson (1994) Daniel T. Simmons (1995) Barrie J. Carter (1996) Stephen H. Hughes (1994) Joseph R. Nevins (1994) Anna Marie Skalka (1996) Mark Challberg (1995) Eric Hunter (1996) Dennis O'Callaghan (1995) Nahum Sonenberg (1996) Irvin S. Y. Chen (1996) Tony Hunter (1995) Peter Palese (1994) Arne Stenlund (1995) Bruce W. Chesebro (1994) Nancy A. Jenkins (1995) Enzo Paoletti (1994) Mark F. Stinski (1995) Donald M. Coen (1995) Richard A. Katz (1996) Takis S. Papas (1996) Jonathan P. Stoye (1996) Gary H. Cohen (1994) Jack D. Keene (1994) Tristram G. Parslow (1996) James H. Strauss (1996) Charles N. Cole (1995) Thomas J. Kelly (1994) J. Thomas Parsons (1995) Bill Sugden (1996) Peter L. Collins (1994) Elliott Kieff (1996) C. David Pauza (1996) Jesse Summers (1995) Richard C. Condit (1995) Karla Kirkegaard (1996) David J. Pintel (1995) Ron Swanstrom (1996) Neal G. Copeland (1995) Geofrey R. Kitchingman (1995) Abraham Pinter (1994) Peter J. Tattersall (1995) Richard J. Courtney (1995) Daniel F. Klessig (1994) James M. Pipas (1996) John M. Taylor (1996) Clyde S. Crumpacker 11 (1994) David M. Knipe (1994) Lewis I. Pizer (1996) Mary J. Tevethia (1996) Bryan R. Cullen (1996) Hsing-Jien Kung (1996) Nancy Raab-Traub (1996) Satvir S. Tevethia (1994) Thomas Curran (1994) Ching-Juh Lai (1996) Arnold B. Rabson (1996) David A. Thorley-Lawson (1994) Samuel Dales (1994) Michael Lai (1994) R. Frank Ramig (1994) Paula Traktman (1995) Daniel DiMaio (1994) Jonathan Leis (1994) Dan S. Ray (1995) Didier Trono (1996) Walter Doerfler (1995) Jack Lenz (1996) Alan R. Rein (1996) Philip N. Tsichlis (1995) Elvera Ehrenfeld (1995) Norman L. Letvin (1995) Carol S. Reiss (1996) Kenneth L Tyler (1994) Robert N. Eisenman (1994) Maxine Linial (1994) Solon L. Rhode (1995) Luis V. Villarreal (1994) John Elder (1996) David M. Livingston (1994) William S. Robinson (1995) Peter K. Vogt (1996) Michael Emerman (1995) Douglas R. Lowy (1995) Bernard Roizman (1994) Edward K. Wagner (1995) Suzanne U. Emerson (1995) Paul J. Maddon (1996) John K. Rose (1994) Robert G. Webster (1996) Hung Fan (1994) James L. Manley (1995) Craig Rosen (1996) Raymond M. Welsh (1994) Ellen Fanning (1994) Malcolm A. Martin (1995) Naomi Rosenberg (1995) Gail Wertz (1994) Bernard Fleckenstein (1996) William S. Mason (1994) Barry T. Rouse (1996) J. Lindsay Whitton (1995) Jane Flint (1996) Michael B. Mathews (1994) Roland R. Rueckert (1994) Reed B. Wickner (1994) William R. Folk (1994) Alan McLachlan (1996) Norman P. Salzman (1996) John W. Wills (1995) Paul D. Friesen (1994) A. Dusty Miller (1994) Charles E. Samuel (1995) Eckard Wimmer (1994) Denise A. Galloway (1995) Lois K. Miller (1994) Richard Jude Samulski (1995) Flossie Wong-Staal (1996) Don Ganem (1994) Edward S. Mocarski (1996) Peter Sarnow (1996) Moshe Yaniv (1995) Costa P. Georgopoulos (1995) Peter Model (1995) Nava Sarver (1996) Charles Hamish Young (1995) Joseph C. Glorioso (1995) John P. Moore (1996) Dorothea L. Sawicki (1994) Harald zur Hausen (1995) Harry B. Greenberg (1995) Elizabeth Moran (1996) Priscilla A. Schaffer (1996) Barbara H. Iglewski, Chairman, Publications Board Linda M. lhlig, Director, Joumals Judith Nedrow, Production Editor Arthur Gelmis, Assistant Production Editor The Journal of Virology, a publication of the American Society for Microbiology (ASM), 1325 Massachusetts Ave., N.W., Washington, DC 20005-4171, is devoted to the dissemination of fundamental knowledge concerning viruses of bacteria, plants, and animals. Investigators are invited to submit reports of original research in all areas of basic virology, including biochemistry, biophysics, genetics, immunology, morphology, physiology, and pathogenesis and immunity. Instructions to authors are published in the January issue each year; reprints are available from the editors and the Journals Division. The Journal is issued monthly, one volume per year. The nonmember print subscription prices are $380 (U.S.) (Canadians add 7% GST) and $454 (other countries) per year; single copies are $43 (Canadians add 7% GST). The member print subscription prices are $81 (U.S.) (Canadians add 7% GST) and $106 (other countries); single copies are $11 (Canadians add 7% GST). For prices of CD-ROM versions, contact the Subscriptions Unit, ASM. Correspondence relating to subscriptions, defective copies, missing issues, and availability of back issues should be directed to the Subscriptions Unit, ASM; correspondence relating to reprint orders should be directed to the Reprint Order Unit, ASM; and correspondence relating to disposition of submitted manuscripts, proofs, and general editorial matters should be directed to the Journals Department, American Society for Microbiology, 1325 Massachusetts Ave., N.W., Washington, DC 20005-4171. Phone: (202) 737-3600. Claims for missing issues from residents of the United States, Canada, and Mexico must be submitted within 3 months after publication of the issues; residents of all other countries must submit claims within 6 months of publication of the issues. Claims for issues missing because of failure to report an address change or for issues "missing from files" will not be allowed. Second-class postage paid at Washington, DC 20005, and at additional mailing offices. POSTMASTER: Send address changes to Journal of Virology, ASM, 1325 Massachusetts Ave., N.W., Washington, DC 20005-4171. Made in the U.S.A. Printed on acid-free paper. ISSN 0022-538X CODEN: JOVIAM Copyright © 1994, American Society for Microbiology. All Rights Reserved. The code at the top of the first page of an article in this journal indicates the copyright owner's consent that copies of the article may be made for personal use or for personal use of specific clients. This consent is given on the condition, however, that the copier pay the stated per-copy fee through the Copyright Clearance Center, 222 Rosewood Drive, Danvers, MA 01923, for copying beyond that permitted by Sections 107 and 108 of the U.S. Copyright Law. This consent does not extend to other kinds of copying, such as copying for general distribution, for advertising or promotional purposes, for creating new collective works, or for resale. The Division of National Cancer Institute Cancer Announces to the Scientific Community the Availability of the Following Etiology Resources/Services for Cancer Related Research As Noted Below: E:Insilikilotom --iolgliol., * Cell Culture Identification Service. Using * Viruses: Avian, Feline, Murine, and Primate * Human sera from donors with various Isozyme Analysis, Immunofluorescence and Viruses Produced in vivo and in vitro. malignancies (including nasopharyngeal Karyotypic Analysis (Chromosome Banding). Contact: Kathleen Whitaker, Ph.D. carcinoma), non-malignant disorders, Contact: Dr. Joseph Kaplan BCB Repository and from normal individuals. Children's Hospital of Michigan Quality Biotech, Inc. Contact: Program Director, Research 3901 Beaubien Boulevard 1667 Davis Street Resources, Biological Detroit, Ml 48201 Camden, NJ 08104 Carcinogenesis Branch, (313) 745-5570 (609) 966-8000 DCE, NCI, NIH (609) 342-8078 FAX Executive Plaza North, Room 540 Citing Contract #NO1-CP-33063 Bethesda, MD 20892 Cost: Reasonable; inquire with specific Citing Contract #NO1-CP-15665 (301) 496-1951 requests. Cost: Reasonable; inquire with specific (301) 496-2025 FAX requests. Cost: Shipping and handling charges only. * Goat Antisera Against: Avian, Bovine, Feline, * Monoclonal Antibodies are available with * The Division of Cancer Etiology's Registry of Murine, and Primate Intact Viruses and Viral specificities for synthetic peptides representing Experimental Cancers announces the availabili- Proteins; Antibodies to Immunoglobulins for a the amino acid sequences of the left end, right ty of 16 different study sets containing histologic number of species. Preimmune
Load more

Recommended publications
  • 2019 Annual Report
    BECKMAN CENTER 279 Campus Drive West Stanford, CA 94305 650.723.8423 Stanford University | Beckman Center 2019 Annual Report Annual 2019 | Beckman Center University Stanford beckman.stanford.edu 2019 ANNUAL REPORT ARNOLD AND MABEL BECKMAN CENTER FOR MOLECULAR AND GENETIC MEDICINE 30 Years of Innovation, Discovery, and Leadership in the Life Sciences CREDITS: Cover Design: Neil Murphy, Ghostdog Design Graphic Design: Jack Lem, AlphaGraphics Mountain View Photography: Justin Lewis Beckman Center Director Photo: Christine Baker, Lotus Pod Designs MESSAGE FROM THE DIRECTOR Dear Friends and Trustees, It has been 30 years since the Beckman Center for Molecular and Genetic Medicine at Stanford University School of Medicine opened its doors in 1989. The number of translational scientific discoveries and technological innovations derived from the center’s research labs over the course of the past three decades has been remarkable. Equally remarkable have been the number of scientific awards and honors, including Nobel prizes, received by Beckman faculty and the number of young scientists mentored by Beckman faculty who have gone on to prominent positions in academia, bio-technology and related fields. This year we include several featured articles on these accomplishments. In the field of translational medicine, these discoveries range from the causes of skin, bladder and other cancers, to the identification of human stem cells, from the design of new antifungals and antibiotics to the molecular underpinnings of autism, and from opioids for pain
    [Show full text]
  • Journal of Virology Volume 68 * April 1994 * Number 4
    JOURNAL OF VIROLOGY VOLUME 68 * APRIL 1994 * NUMBER 4 Arnold J. Levine, Editor in Chief (1994) Vincent R. Racaniello, Editor (1997) Princeton University Columbia University Princeton, N.J. Peter M. Howley, Editor (1998) New York, N.Y Harvard Medical School John M. Coffin, Editor (1996) Boston, Mass. Thomas E. Shenk, Editor (1994) Tufts University Medical School Princeton University Boston, Mass. Michael B. A. Oldstone, Editor (1994) Princeton, N.J. Scripps Clinic & Research Foundation Ronald C. Desrosiers, Editor (1998) La Jolla, Calif. Joseph Sodroski, Editor (1998) Harvard Medical School Dana-Farber Cancer Institute Boston, Mass. Carol Prives, Editor (1996) Boston, Mass. Columbia University Mary K. Estes, Editor (1998) New N.Y Inder M. Verma, Editor (1998) Baylor College of Medicine York, The Salk Institute Houston, Tex. San Diego, Calif. EDITORIAL BOARD Rafi Ahmed (1994) Harry B. Greenberg (1995) Elizabeth Moran (1996) Priscilla A. Schaffer (1996) Carl C. Baker (1994) Hidesaburo Hanafusa (1995) Bernard Moss (1995) Heinz Schaller (1995) Amiya K. Banerjee (1996) Ed Harlow (1996) Richard W. Moyer (1995) Sondra Schlesinger (1995) Kenneth L. Berns (1994) Gary S. Hayward (1996) James Mullins (1996) Robert J. Schneider (1994) Joseph B. Bolen (1994) Ari H. Helenius (1996) Brian R Murphy (1994) Manfred H. Schubert (1996) Thomas J.'Braciale (1994) Virginia S. Hinshaw (1996) Nicholas A. Muzyczka (1996) Bartholomew M. Sefton (1994) John Brady (1994) David D. Ho (1996) Gerald Myers (1995) Bert L. Semler (1995) Thomas R. Broker (1995) James M. Hogle (1994) Gary J. Nabel (1996) David A. Shafritz (1994) Michael J. Buchmeier (1995) John J. Holland (1996) Opendra Narayan (1994) Yosef Shaul (1995) Robert Callahan (1994) Kathryn V.
    [Show full text]
  • Poliovirus Mutant That Does Not Selectively Inhibit Host Cell Protein Synthesis
    MOLECULAR AND CELLULAR BIOLOGY. November 1985. p. 2913-2923 Vol. 5. No. 11 0270-7306/85/112913-11$02.00/0 Copyright © 1985. American Society for Microbiology Poliovirus Mutant That Does Not Selectively Inhibit Host Cell Protein Synthesis HARRIS D. BERNSTEIN,1 NAHUM SONENBERG.~ AND DAVID BALTIMOREh Whitehead Institute for Biomedical Research, Cambridge, Massachusetts 02142, and Department of Biology, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, 1 and Department of Biochemistry, McGill Unirersity, Montreal, Quebec, Canada H3G I Y6~ Received 20 May 1985/Accepted 1 August 1985 A poliovirus type I (Mahoney strain) mutant was obtained by inserting three base pairs into an infectious eDNA clone. The extra amino acid encoded by the insertion was in the amino-terminal (protein 8) portion of the P2 segment of the polyprotein. The mutant virus makes small plaques on HeLa and monkey kidney (CV-1) cells at all temperatures. It lost the ability to mediate the selective inhibition of host cell translation which ordinarily occurs in the first few hours after infection. As an apparent consequence, the mutant synthesizes far less protein than does wild-type virus. In mutant-infected CV-1 cells enough protein was produced to permit a normal course of RNA replication, but the yield of progeny virus was very low. In mutant-infected He La cells there was a premature cessation of both cellular and viral protein synthesis followed by a premature halt of viral RNA synthesis. This nonspecific translational inhibition was distinguishable from wild-type-mediated inhibition and did not appear to be part of an interferon or heat shock response.
    [Show full text]
  • Microbiology and Immunology (MI) Courses” Section of This Assistants for Two Courses
    National Science Foundation. Program for Graduate Study—The Ph.D. degree requires course MICROBIOLOGY AND work and independent research demonstrating an individual’s creative, scholastic, and intellectual abilities. On entering the department, students meet an advisory faculty member; together they IMMUNOLOGY design a timetable for completion of the degree requirements. Typically, this consists of first identifying gaps in the student’s Emeriti: (Professors) Edward S. Mocarski, Sidney Raffel, Leon T. undergraduate education and determining courses that should be Rosenberg taken. Then, a tentative plan is made for two to four lab rotations Chair: Karla Kirkegaard (one rotation per quarter). During the first year of graduate study in Associate Chair: Hugh O. McDevitt the department, each student also takes six or seven upper-level Professors: Ann Arvin, Helen Blau, John C. Boothroyd, Yueh-Hsiu (200-series) courses. Three of these courses are requirements of the Chien, Mark M. Davis, Stanley Falkow, Stephen J. Galli, Harry department: MI 215, Principles of Biological Techniques; MI 209, B. Greenberg, Karla Kirkegaard, A. C. Matin, Hugh O. Advanced Pathogenesis of Bacteria, Viruses, and Eukaryotic McDevitt, Peter Parham, Phillip Pizzo, Charles Prober, David Parasites, Part I; and MI 210, Advanced Pathogenesis of Bacteria, Relman, Peter Sarnow, Gary K. Schoolnik, Lucy S. Tompkins Viruses, and Eukaryotic Parasites, Part II. Three courses are part of Associate Professors: Christopher Contag, Garry Nolan, David the core curriculum that is required of many graduate students in Schneider, Julie Theriot Stanford Biosciences: BIO 203 /DBIO 203 /GENE 203, Advanced Assistant Professors: Manuel Amieva, Matthew Bogyo, Chang- Genetics; BIO 230, Molecular and Cellular Immunology; and MCP Zheng Chen, Denise Monack, Upinder Singh, Justin Sonnenburg, 221/BIO 214, Cell Biology of Physiological Processes.
    [Show full text]
  • Lecture Slides
    (J. American Chemical Association, 78, 3458-3459) The Secondary Structure of Complementary RNA E. Peter Geiduschek, John W. Moohr, and Smauel B. Weiss, Proceedings of The National Academy of Sciences, 48, 1078-1086, 1962. R.H. DOI RH, and S. SPIEGELMAN Homology test between the nucleic acid of an RNA virus and the DNA in the host cell. Science 1962 Dec 14 1270-2. MONTAGNIER L, SANDERS FK. REPLICATIVE FORM OF ENCEPHALOMYOCARDITIS VIRUS RIBONUCLEIC ACID. Nature. 1963 Aug 17;199:664-7. (Science 143, 1034-1036, March 6, 1964) WARNER RC, SAMUELS HH, ABBOTT MT, KRAKOW JS. (1963) Ribonucleic acid polymerase of Azotobacter vinelandii, II. Formation of DNA- RNA hybrids with single-stranded DNA as primer. Proc Natl Acad Sci U S A. 49:533-8. Double Stranded RNA as a Specific Biological Effector December 8, 2006 Karolinska Institute, Stockholm, Sweden Viral interference (Interferon) effects in animals M. Hoskins (1935) A protective action of neurotropic against viscerotropic yellow fever virus in Macacus rhesus. American Journal of Tropical Medicine, 15, 675-680 G. Findlay and F. MacCallum (1937) An interference phenomenon in relation to yellow fever and other viruses. J. Path. Bact. 44, 405-424. A. Isaacs and J. Lindenmann (1957) Virus Interference. I. The Interferon Proc. Royal Soc. B 147, 268-273. Proceedings of the National Academy of Sciences, USA, Volume 58, Pages 782-789. 1967 Promoter Make transgenic worms geneX Antisense Transcripts Interference (Development 113:503 [1991]) geneX Promoter Make transgeneic worms geneX SENSE Transcripts Also Interference! (Development 113:503 [1991]) In Vitro Promoter Make RNA in vitro geneX Antisense RNA Inject worm gonad Interference! (Guo and Kemphues, 1995) In Vitro geneX Promoter Make RNA in vitro geneX SENSE RNA Inject worm gonad Also Interference! (Guo and Kemphues, 1995) Craig Mello's RNAi Workshop: 1997 C.
    [Show full text]
  • Surrender, Avoidance and Subversion by Microorganisms
    REVIEWS CELLULAR AUTOPHAGY: SURRENDER, AVOIDANCE AND SUBVERSION BY MICROORGANISMS Karla Kirkegaard, Matthew P.Taylor and William T. Jackson Intracellular bacteria and viruses must survive the vigorous antimicrobial responses of their hosts to replicate successfully. The cellular process of autophagy — in which compartments bound by double membranes engulf portions of the cytosol and then mature to degrade their cytoplasmic contents — is likely to be one such host-cell response. Several lines of evidence show that both bacteria and viruses are vulnerable to autophagic destruction and that successful pathogens have evolved strategies to avoid autophagy, or to actively subvert its components, to promote their own replication. The molecular mechanisms of the avoidance and subversion of autophagy by microorganisms will be the subject of much future research, not only to study their roles in the replication of these microorganisms, but also because they will provide — as bacteria and viruses so often have — unique tools to study the cellular process itself. 6,7 4 DAUER Cellular autophagy involves the sequestration of thaliana and C. elegans ,wild-type autophagy genes An arrested stage in regions of the cytosol within double-membrane-bound are required to prevent premature senescence. Caenorhabditis elegans compartments that then mature and degrade their cyto- One attractive hypothesis is that the degradation of development that can be formed plasmic contents. It is a highly regulated process, the cytosolic structures by autophagy might have
    [Show full text]
  • Current Topics in Microbiology and Immunology Volume
    BookID 160045_ChapID FM_Proof# 1 - 17/4/2009 Current Topics in Microbiology and Immunology Volume 335 Series Editors R. John Collier Department of Microbiology and Molecular Genetics, Harvard Medical School, 200 Longwood Avenue, Boston, MA 02115, USA Richard W. Compans Emory University School of Medicine, Department of Microbiology and Immunology, 3001 Rollins Research Center, Atlanta, GA 30322, USA Max D. Cooper Department of Pathology and Laboratory Medicine, Georgia Research Alliance, Emory University, 1462 Clifton Road, Atlanta, GA 30322, USA Yuri Y. Gleba ICON Genetics AG, Biozentrum Halle, Weinbergweg 22, Halle 6120, Germany Tasuku Honjo Department of Medical Chemistry, Kyoto University, Faculty of Medicine, Yoshida, Sakyo-ku, Kyoto 606-8501, Japan Hilary Koprowski Thomas Jefferson University, Department of Cancer Biology, Biotechnology Foundation Laboratories, 1020 Locust Street, Suite M85 JAH, Philadelphia, PA 19107-6799, USA Bernard Malissen Centre d’Immunologie de Marseille-Luminy, Parc Scientifique de Luminy, Case 906, Marseille Cedex 9 13288, France Fritz Melchers Biozentrum, Department of Cell Biology, University of Basel, Klingelbergstr. 50–70, 4056 Basel Switzerland Michael B.A. Oldstone Department of Neuropharmacology, Division of Virology, The Scripps Research Institute, 10550 N. Torrey Pines, La Jolla, CA 92037, USA Sjur Olsnes Department of Biochemistry, Institute for Cancer Research, The Norwegian Radium Hospital, Montebello 0310 Oslo, Norway Herbert W. “Skip” Virgin Washington University School of Medicine, Pathology and Immunology, University Box 8118, 660 South Euclid Avenue, Saint Louis, Missouri 63110, USA Peter K. Vogt The Scripps Research Institute, Dept. of Molecular & Exp. Medicine, Division of Oncovirology, 10550 N. Torrey Pines. BCC-239, La Jolla, CA 92037, USA BookID 160045_ChapID FM_Proof# 1 - 17/4/2009 BookID 160045_ChapID FM_Proof# 1 - 17/4/2009 ii Current Topics in Microbiology and Immunology Previously published volumes Further volumes can be found at springer.com Vol.
    [Show full text]
  • Julie K. Pfeiffer, Ph.D. 1/2019
    Julie K. Pfeiffer, Ph.D. 1/2019 University of Texas Southwestern Medical Center Phone: (214) 648-8775 Department of Microbiology 6000 Harry Hines Blvd, NL4.140B Dallas, TX 75390-9048 email: [email protected] CURRENT POSITION Professor 9/2017- University of Texas Southwestern Medical Center, Department of Microbiology, Dallas, Texas Associate Professor 9/2012-8/2017 University of Texas Southwestern Medical Center, Department of Microbiology, Dallas, Texas Assistant Professor 2/2006-8/2012 University of Texas Southwestern Medical Center, Department of Microbiology, Dallas, Texas2 EDUCATION and TRAINING Post-Doctoral Research Fellow 9/2001-12/2005 PI: Professor Karla Kirkegaard, Ph.D. Stanford University, Department of Microbiology, Stanford, California Graduate Research Assistant 9/1996-8/2001 Ph.D., 6/14/2001, Microbiology and Immunology, University of Michigan, Ann Arbor, Michigan PI: Associate Professor Alice Telesnitsky, Ph.D. Thesis: Factors that affect template switching during M-MuLV reverse transcription Undergraduate Studies 9/1992-5/1996 B.A., Microbiology, cum laude, Miami University, Oxford, Ohio RESEARCH SUPPORT Ongoing Research Support Burroughs Wellcome- Investigators in the Pathogenesis of Infectious Diseases 7/2012-6/2021 Title: How gut microbes enhance enteric virus infectivity Role: PI NIH R01, NIAID R01AI074668 2/2008-2/2023 Title: Enteric virus-microbiota interactions Role: PI Howard Hughes Medical Institute 55108554 11/2016-10/2021 Faculty Scholars Program Title: Enteric virus-microbiota interactions Role: PI NIH T32, NIAID 5T32 AI007520-17 (Norgard) 9/1/2014-8/31/2019 Molecular Microbiology Training Grant This training grant supports a multi-disciplinary Molecular Microbiology Training Program. The program supports 5 pre-doctoral and 2 post-doctoral trainees annually.
    [Show full text]
  • Translational Enhancement of the Poliovirus 5' Noncoding Region
    Proc. Nadl. Acad. Sci. USA Vol. 89, pp. 10272-10276, November 1992 Biochemistry Translational enhancement of the poliovirus 5' noncoding region mediated by virus-encoded polypeptide 2A (tanslational regualon/dlistronlc mRNA/17 RNA ply e res cell me/firefly uferase gene) SIMON J. HAMBIDGE* AND PETER SARNOW*t Departments of *Microbiology and Immunology, and tBiochemistry, Biophysics and Genetics, University of Colorado Health Sciences Center, Denver, CO 80262 Communicated by Maxine F. Singer, July 6, 1992 ABSTRACT Genetic and biochemical studies have re- cleavage (7). As a result, eIF-4F is rendered nonfunctional, vealed that the 5' noncodlng region of pollovirus mites and capped host cell mRNAs cannot be translated by a tranation of the viral mRNA by an unusual m nim cap-dependent scanning mechanism (8), while the uncapped involving entry of ribosomes in internal sequences of mRNA viral mRNA can be translated by a cap-independent mech- molecules. We have found that mRNAs bearing the S' non- anism of internal ribosome binding (9). This mechanism coding region ofpoliovirus were transted at an enhced rate involves the binding ofribosomes to RNA sequences, termed in poliovirus-infected cells at a time when trans- the internal ribosome entry site (IRES) (10) or the ribosome lation of cellular mRNAs was not yet inhibited. This btnla- landing pad (9), present in the 5' NCR of the viral RNA. tional enhancement of the polioviral 5' noncodn region was Here, we provide evidence that mRNAs containing the 5' medated by the expression of virus-encoded polypeptde 2A. NCR of poliovirus are translated at an enhanced rate com- This indites that 2A Is a multifunctional protein Involved pared to mRNAs lacking the viral 5' NCR in cells at very directly or indirectly in the activation of viral mRNA trasla- early times after infection with poliovirus.
    [Show full text]
  • Homeotic Gene Antennapedia Mrna Contains 5'-Noncoding Sequences That Confer Translational Initiation by Internal Ribosome Binding
    Downloaded from genesdev.cshlp.org on October 9, 2021 - Published by Cold Spring Harbor Laboratory Press Homeotic gene Antennapedia mRNA contains 5'-noncoding sequences that confer translational initiation by internal ribosome binding Soo-Kyung OH, 1 Matthew P. Scott, 2 and Peter Sarnow 1'3 ~Department of Biochemistry, Biophysics and Genetics, 3Department of Microbiology and Immunology, University of Colorado Health Sciences Center, Denver, Colorado 80262 USA; 2Departments of Developmental Biology and Genetics, Stanford University School of Medicine, Stanford, California 94305-5427 USA The Antennapedia (Antp) homeotic gene of Drosophila melanogaster has two promoters, P1 and P2. The resulting Antp mRNAs contain 1512-nucleotide (P1) and 1727-nucleotide (P2) 5'-noncoding regions, composed of exons A, B, D, and E (PI) or exons C, D, and E (P2), respectively. Multiple AUG codons are present in exons A, B, and C. We have found that 252-nucleotide exon D, common to mRNAs from both transcription units and devoid of AUG codons, can mediate initiation of translation by internal ribosome binding in cultured cells. Many mRNAs in Drosophila contain long 5'-noncoding regions with apparently unused AUG codons, suggesting that internal ribosome binding may be a common mechanism of translational initiation, and possibly its regulation, in Drosoptu'la. [Key Words: Internal ribosome binding; homeotic gene; Antennapedia mRNA; dicistronic mRNA; RNA transfection] Received May 18, 1992; revised version accepted July 7, 1992. The homeotic genes required for segments in Drosophila similarly, exon C contains 15 upstream AUG codons. All melanogaster to have different developmental fates are of these upstream AUG codons are followed by very expressed in some segment primordia but not in others.
    [Show full text]
  • Covalent Bonds Between Protein Anddna FORMATION of PHOSPHOTYROSINE LINKAGE BETWEEN CERTAIN DNA TOPOISOMERASES and DNA*
    THEJOURNAL OF BIOLOGICALCHEMISTRY Vol. 255. No 12, Issue of June 25. pp. 5560-5565. 1980 Printed Ln U.S.A. Covalent Bonds between Protein andDNA FORMATION OF PHOSPHOTYROSINE LINKAGE BETWEEN CERTAIN DNA TOPOISOMERASES AND DNA* (Received for publication, November 27, 1979, and in revised form, March 7, 1980) Yuk-Ching Tse, Karla Kirkegaard, andJames C. Wang From the Department of Biochemistry and Molecular Biology, Haruard Uniuersity, Cambridge, Massachusetts 02138 The cleavageof a DNA phosphodiester bondby Esch- catalytic function. There are, however, a number of other erichia coli DNA topoisomerase I and the simultaneous protein. DNA covalent complexes for which the protein com- covalent linkage of the enzyme to the 5’-phosphoryl ponents themselves havebeen purified in catalytically active group of the DNA at the cleavage site have been re- form, and, therefore, their covalent linking to DNA can be ported previously (Depew, R. E., Liu, L. F., and Wang, studied in some detail. These proteins aregenerally found to J. C. (1978) J. Biol. Chem 253, 511-518; Liu, L. F., and catalyze the breaking and rejoining of DNA backbone bonds. Wang, J. C. (1979) J. Biol. Chem 254,11082-11088). In some cases, the breaking of a DNA internucleotidebond With either E. coli or Micmcoccus luteus DNA topo- is followed in concert by the rejoining of the bond; thus the isomerase I, formation of the covalent complex with overall reaction usually manifests itself by the conversion of 32P-labeled single-stranded DNA, followed by nucleo- one DNA topological isomer (topoisomer) to another. ,The lytic treatment of the complex, yields a 32P-labeled term DNA topoisomerases has been proposed for these en- protein.
    [Show full text]
  • And Vpg-Pupu in Poliovirus-Infected Cells (RNA Replication/Picornavirus) NIGEL M
    Proc. Natl. Acad. Sci. USA Vol. 80, pp. 7452-7455, December 1983 Biochemistry Genome-linked protein VPg of poliovirus is present as free VPg and VPg-pUpU in poliovirus-infected cells (RNA replication/picornavirus) NIGEL M. CRAWFORD AND DAVID BALTIMORE Whitehead Institute for Biomedical Research, Cambridge, MA 02139; and Center for Cancer Research and Department of Biology, Massachusetts Institute of Technology, Cambridge, MA 02139 Contributed by David Baltimore, September 15, 1983 ABSTRACT VPg is a virus-encoded protein covalently at- line). 32P-Labeled virion RNA was isolated as described (12) from tached to the 5' end of poliovirus virion RNA. We have used an- virions collected by centrifugation during preparation of the tibody prepared against chemically synthesized VPg to detect two cell lysates. Synthetic VPg and coupled VPg-bovine serum al- forms of VPg in infected cells. Both forms were specifically im- bumin were gifts from Margaret Baron (7). 125I-Labeled VPg munoprecipitated from lysates of infected cells labeled with [3H]- was leucine. One appears to be unmodified VPg because it had the prepared by iodinating synthetic VPg on tyrosine with Nam25I same electrophoretic mobility as synthetic VPg. The other had a and Iodo-Beads (Pierce) as recommended by the manufacturer. larger apparent molecular weight than VPg and could be labeled Anti-VPg serum and nonimmune serum from rabbits were in vivo with 32p,. Its structure is VPg-pUpU, the UMP dinucleotide prepared as described (7). Serum was passed through a column being attached to VPg via a phosphodiester bond to tyrosine, the containing DEAE-Affi-Gel Blue overlaid with CM-Affi-Gel Blue third amino acid from the NH2 terminus of VPg.
    [Show full text]