Genome-wide prediction of vaccine targets for human herpes simplex viruses using Vaxign reverse vaccinology

Herpes simplex virus (HSV) types 1 and 2 (HSV-1 and HSV-2) are the most common infectious agents of humans. No safe and effective HSV vaccines have been licensed. Reverse vaccinology is an emerging and revolutionary vaccine development strategy that starts with the prediction of vaccine targets by informatics analysis of genome sequences. Vaxign (http://www.violinet.org/vaxign) is the first web-based vaccine design program based on reverse vaccinology. In this study, we used Vaxign to analyze 52 herpesvirus genomes, including 3 HSV-1 genomes, one HSV-2 genome, 8 other human herpesvirus genomes, and 40 non-human herpesvirus genomes. The HSV-1 strain 17 genome that contains 77 proteins was used as the seed genome. These 77 proteins are conserved in two other HSV-1 strains (strain F and strain H129). Two envelope glycoproteins gJ and gG do not have orthologs in HSV-2 or 8 other human herpesviruses. Seven HSV-1 proteins (including gJ and gG) do not have orthologs in all 40 non-human herpesviruses. Nineteen proteins are conserved in all human herpesviruses, including capsid scaffold protein UL26.5 (NP_044628.1). As the only HSV-1 protein predicted to be an adhesin, UL26.5 is a promising vaccine target. The MHC Class I and II epitopes were predicted by the Vaxign Vaxitop prediction program and IEDB prediction programs recently installed and incorporated in Vaxign. Our comparative analysis found that the two programs identified largely the same top epitopes but also some positive results predicted from one program might not be positive from another program. Overall, our Vaxign computational prediction provides many promising candidates for rational HSV vaccine development. The method is generic and can also be used to predict other viral vaccine targets.

[1]  A. Nesburn,et al.  New concepts in herpes simplex virus vaccine development: notes from the battlefield , 2009, Expert review of vaccines.

[2]  Robert T. Chen,et al.  Emerging Vaccine Informatics , 2011, Journal of biomedicine & biotechnology.

[3]  L. J. Perry,et al.  The complete DNA sequence of the long unique region in the genome of herpes simplex virus type 1. , 1988, The Journal of general virology.

[4]  Yongqun He,et al.  Bioinformatics analysis of Brucella vaccines and vaccine targets using VIOLIN , 2010, Immunome research.

[5]  D. Watanabe Medical application of herpes simplex virus. , 2010, Journal of dermatological science.

[6]  J. Venter,et al.  Identification of vaccine candidates against serogroup B meningococcus by whole-genome sequencing. , 2000, Science.

[7]  N. Ariel,et al.  Search for Potential Vaccine Candidate Open Reading Frames in the Bacillus anthracis Virulence Plasmid pXO1: In Silico and In Vitro Screening , 2002, Infection and Immunity.

[8]  B. Matthews Comparison of the predicted and observed secondary structure of T4 phage lysozyme. , 1975, Biochimica et biophysica acta.

[9]  W. Newcomb,et al.  Herpesvirus capsid assembly: insights from structural analysis. , 2011, Current opinion in virology.

[10]  Martin Ester,et al.  PSORTb 3.0: improved protein subcellular localization prediction with refined localization subcategories and predictive capabilities for all prokaryotes , 2010, Bioinform..

[11]  Yongqun He,et al.  Vaxign: The First Web-Based Vaccine Design Program for Reverse Vaccinology and Applications for Vaccine Development , 2010, Journal of biomedicine & biotechnology.

[12]  Y. Yang,et al.  ICP34.5 Protein of Herpes Simplex Virus Facilitates the Initiation of Protein Translation by Bridging Eukaryotic Initiation Factor 2α (eIF2α) and Protein Phosphatase 1* , 2011, The Journal of Biological Chemistry.

[13]  W. Newcomb,et al.  Evidence for Controlled Incorporation of Herpes Simplex Virus Type 1 UL26 Protease into Capsids , 2000, Journal of Virology.

[14]  Theresa M. Wizemann,et al.  Use of a Whole Genome Approach To Identify Vaccine Molecules Affording Protection against Streptococcus pneumoniae Infection , 2001, Infection and Immunity.

[15]  F. Homa,et al.  Amino Acids 143 to 150 of the Herpes Simplex Virus Type 1 Scaffold Protein Are Required for the Formation of Portal-Containing Capsids , 2008, Journal of Virology.

[16]  A. Cunningham,et al.  Development of prophylactic vaccines for genital and neonatal herpes , 2003, Expert review of vaccines.

[17]  Second-site mutations encoding residues 34 and 78 of the major capsid protein (VP5) of herpes simplex virus type 1 are important for overcoming a blocked maturation cleavage site of the capsid scaffold proteins. , 2000, Virology.

[18]  Fang Chen,et al.  VIOLIN: vaccine investigation and online information network , 2007, Nucleic Acids Res..

[19]  D. Conrad,et al.  Identification and Immunological Characterization of Three Potential Vaccinogens against Cryptosporidium Species , 2011, Clinical and Vaccine Immunology.

[20]  David L. Wheeler,et al.  GenBank , 2015, Nucleic Acids Res..

[21]  R. Rappuoli Reverse vaccinology : Genomics , 2000 .

[22]  Rino Rappuoli,et al.  Reverse vaccinology. , 2000, Current opinion in microbiology.

[23]  Yongqun He,et al.  Bioinformatics analysis of bacterial protective antigens in manually curated Protegen database , 2012 .

[24]  Tatiana Tatusova,et al.  NCBI Reference Sequence (RefSeq): a curated non-redundant sequence database of genomes, transcripts and proteins , 2004, Nucleic Acids Res..

[25]  A. Ventura,et al.  HSV : herpes simplex virus Reactivation : HSV DNA in sensory ganglia neurons directs synthesis of mRNA molecules that encode proteins required for HSV DNA replication and assembly of daughter virions , 2013 .

[26]  D. McGeoch,et al.  The Genome Sequence of Herpes Simplex Virus Type 2 , 1998, Journal of Virology.

[27]  Bjoern Peters,et al.  VO: Vaccine Ontology , 2009 .

[28]  L. Doering,et al.  Glycoproteins E and I facilitate neuron-to-neuron spread of herpes simplex virus , 1995, Journal of virology.

[29]  J. Burgos,et al.  ICP47 mediates viral neuroinvasiveness by induction of TAP protein following intravenous inoculation of herpes simplex virus type 1 in mice , 2006, Journal of NeuroVirology.

[30]  Yongqun He,et al.  Vaxjo: A Web-Based Vaccine Adjuvant Database and Its Application for Analysis of Vaccine Adjuvants and Their Uses in Vaccine Development , 2012, Journal of biomedicine & biotechnology.

[31]  Z. Meshkat,et al.  Evaluation of antibodies against glycoprotein D (gD) and glycoprotein G (gG) in HSV-1 infected individuals' serum samples. , 2012, European review for medical and pharmacological sciences.

[32]  J. Rajčáni,et al.  Developments in herpes simplex virus vaccines: Old problems and new challenges , 2008, Folia Microbiologica.

[33]  D. Koelle Vaccines for herpes simplex virus infections. , 2006, Current opinion in investigational drugs.

[34]  Dragomir R. Radev,et al.  Mining of vaccine-associated IFN-γ gene interaction networks using the Vaccine Ontology , 2011, J. Biomed. Semant..

[35]  Yongqun He,et al.  Protegen: a web-based protective antigen database and analysis system , 2010, Nucleic Acids Res..

[36]  John Sidney,et al.  A Systematic Assessment of MHC Class II Peptide Binding Predictions and Evaluation of a Consensus Approach , 2008, PLoS Comput. Biol..

[37]  T. Daikoku,et al.  Identification and Characterization of the UL56 Gene Product of Herpes Simplex Virus Type 2 , 2002, Journal of Virology.

[38]  Y. He,et al.  Vaxign: a web-based vaccine target design program for reverse vaccinology , 2009 .

[39]  J. Betts Transcriptomics and Proteomics: Tools for the Identification of Novel Drug Targets and Vaccine Candidates for Tuberculosis , 2002, IUBMB life.

[40]  Tatiana A. Tatusova,et al.  NCBI Reference Sequence (RefSeq): a curated non-redundant sequence database of genomes, transcripts and proteins , 2004, Nucleic Acids Res..

[41]  Yongqun He,et al.  Ontology-based Brucella vaccine literature indexing and systematic analysis of gene-vaccine association network , 2011, BMC Immunology.