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Integrated Bioinformatics Data and Analysis Tools for Herpesviridae Viruses

Integrated Bioinformatics Data and Analysis Tools for Herpesviridae Viruses in the Virus Pathogen Resource ( ViPR ) Yun Zhang 1 , Brett Pickett 1 , Eva Sadat 2 , , R. Burke Squires 2 , Jyothi Noronha 2 , Sanjeev Kumar 3 , Sam Zaremba 3 ,

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Integrated Bioinformatics Data and Analysis Tools for Herpesviridae Viruses

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  1. Integrated Bioinformatics Data and Analysis Tools for Herpesviridae Viruses in the Virus Pathogen Resource (ViPR) Yun Zhang1, Brett Pickett1, Eva Sadat2, , R. Burke Squires2, Jyothi Noronha2, SanjeevKumar3, Sam Zaremba3, Zhiping Gu3, LiweiZhou3, Chris Larsen4, Wei Jen3, Edward B. Klem3, Richard H. Scheuermann1 1J. Craig Venter Institute, San Diego, CA; 2Department of Pathology, Univ. of Texas Southwestern Medical Center, Dallas, TX; 3Northrop Grumman Health Solutions, Rockville MD; 4Vecna Technologies, Greenbelt MD. Introduction GBrowse for Genome Viewing Host-virus Interaction Data • The Virus Pathogen Database and Analysis Resource (ViPR, www.viprbrc.org), sponsored by the National Institute of Allergy and Infectious Diseases serves as a single publicly-accessible repository of integrated datasets and analysis tools for 14 different virus families including Herpesviridae to support wet-bench virology researchers focusing on the development of diagnostics, prophylactics, vaccines, and treatments for these pathogens1. • ViPR Supports 14 Virus Families • ArenaviridaeFlaviviridaePoxviridae • BunyaviridaeHepeviridaeReoviridae • CaliciviridaeHerpesviridaeRhabdoviridae • CoronaviridaeParamyxoviridaeTogaviridae • FiloviridaePicornaviridae • ViPRIntegrates Data from Many Sources • GenBank sequence records, gene annotations, and strain metadata • Protein Databank (PDB) 3D protein structures • Immune epitopes from the Immune Epitope Database (IEDB) • Clinical data • Host Factor Data generated from the NIAID Systems Biology projects and the ViPR-funded Driving Biological Projects • UniProtKB protein annotations • Gene Ontology (GO) classifications • Additional data derived from computational algorithms • ViPR Provides Analysis and Visualization Tools • Multiple Sequence Alignment • Phylogenetic Tree Construction • Sequence Polymorphism Analysis • Metadata-driven Comparative Genomics Statistical Analysis • Genome Annotator • Gbrowse Genome Viewer • Sequence Format Conversion • BLAST Sequence Similarity Search • 3D Protein Structure Visualization and Movie Generation • Sequence Feature Variant Type (SFVT) Analysis • ViPR enables you to store and share data and results through the ViPR Workbench ViPR is currently funding Driving Biological Projects to produce whole genome sequences for Human Herpesvirus1 oral or neurotropic isolates. Lists of host genes that are differentially-expressed during infection of human neuronal cells will also be deposited. • Provides both bird’s eye and detailed views of genomes and genome annotations. • Available for Reference Sequences of Pox- and Herpes viruses. Figure 2: A screenshot of the GBrowse window.The “Overview” panel displays the entire genome; the “Region” panel displays a portion of the genome surrounding a specified region; the “Details” panel displays several tracks of genomic features. Figure 5: Host Factor Data in ViPR. A host factor experiment result summary showing differentially expressed genes in human cells infected with SARS. 3D Protein Structure Viewer Viral Protein Ortholog Groups ViPR groups viral proteins into clusters based on predicted orthology within a virus taxon to facilitate gene/protein search, gene function inference, and virus evolution research. Figure 3: A screenshot of the Ortholog Group search result page. Each ortholog group name is linked to all viral proteins in the same ortholog cluster for the selected taxon. Figure 6: 3D Protein Structure Viewer5in ViPR. A display of a 3D protein structure for the Thymidine Kinase protein from Herpes Simplex Type 1 virus. Ligands, epitopes and active sites are highlighted (PDB ID: 1E2I). Multiple Sequence Alignment, Phylogenetic Tree and Metadata-driven Comparative Analysis Tool Summary A D • ViPR combines the strength of a relational database with a suite of integrated bioinformatics tools to support everything from basic sequence and structural analyses to genotype-phenotype studies and host-virus interaction studies. The uniqueness of ViPR lies in: • integrating data from various sources • capturing unique data on the host response to virus infection • combining the available tools to quickly perform complex analytical workflows • facilitating rapid hypothesis generation using bioinformatics methods for subsequent experimental testing • allowing data sharing and storage with collaborators B C Acknowledgements We would like to thank the primary data providers for the data that was used throughout this study. We also recognize the scientific and technical personnel responsible for supporting and developing ViPR, which has been wholly supported with federal funds from the NIH/NIAID (N01AI2008038 to R.H.S.). Figure 4: Comparative Genomic Analytical tools in ViPR A multiple sequence alignment of Human Herpesvirus 1 (HHV-1) (A) whole genome sequences2 and (B) VP16 nucleotide sequences3. (C) A phylogenetic tree visualized with the Archaeopteryx4 tool shows the relationship between HHV-1 VP16 proteins, red represents human while pink indicates unknown host. (D) The Metadata-driven Comparative Analysis Tool for Sequences uses statistics to identify individual positions that correlate with a specified metadata attribute. References 1 Pickett, B.E., et al. (2012) ViPR: an open bioinformaticsdatabaseandanalysisresource for virologyresearch. Nucl. Acids Res. 40(D1): D593-D598 2Darling, A.C.E., et al. (2004) Mauve: MultipleAlignmentofConservedGenomicSequenceWithRearrangements. Genome Res., 14: 1394-1403 3Edgar, R.C. (2004) MUSCLE: multiplesequencealignmentwith high accuracyand high throughput.NucleicAcids Res. 32(5):1792-1797. 4Zmasek, C.M. andEddy, S.R. (2001) ATV: display andmanipulationofannotated phylogenetic trees. Bioinformatics, 17, 383-384. 5Hanson, R. (2010) Jmol - a paradigm shift in crystallographic visualization. Journal of Applied Crystallography, 43, 1250-1260. Figure 1: A screenshot of the ViPRhomepage The ViPR homepage is the portal used to access the various types of data and advanced functionality for any supported virus family.

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