Sequence-Based Prediction for Vaccine Strain Selection and Identification of Antigenic Variability in Foot-and-Mouth Disease Virus

Identifying when past exposure to an infectious disease will protect against newly emerging strains is central to understanding the spread and the severity of epidemics, but the prediction of viral cross-protection remains an important unsolved problem. For foot-and-mouth disease virus (FMDV) research in particular, improved methods for predicting this cross-protection are critical for predicting the severity of outbreaks within endemic settings where multiple serotypes and subtypes commonly co-circulate, as well as for deciding whether appropriate vaccine(s) exist and how much they could mitigate the effects of any outbreak. To identify antigenic relationships and their predictors, we used linear mixed effects models to account for variation in pairwise cross-neutralization titres using only viral sequences and structural data. We identified those substitutions in surface-exposed structural proteins that are correlates of loss of cross-reactivity. These allowed prediction of both the best vaccine match for any single virus and the breadth of coverage of new vaccine candidates from their capsid sequences as effectively as or better than serology. Sub-sequences chosen by the model-building process all contained sites that are known epitopes on other serotypes. Furthermore, for the SAT1 serotype, for which epitopes have never previously been identified, we provide strong evidence – by controlling for phylogenetic structure – for the presence of three epitopes across a panel of viruses and quantify the relative significance of some individual residues in determining cross-neutralization. Identifying and quantifying the importance of sites that predict viral strain cross-reactivity not just for single viruses but across entire serotypes can help in the design of vaccines with better targeting and broader coverage. These techniques can be generalized to any infectious agents where cross-reactivity assays have been carried out. As the parameterization uses pre-existing datasets, this approach quickly and cheaply increases both our understanding of antigenic relationships and our power to control disease.

[1]  S. Reid,et al.  Interferon-gamma production in vitro from whole blood of foot-and-mouth disease virus (FMDV) vaccinated and infected cattle after incubation with inactivated FMDV. , 2006, Vaccine.

[2]  E. Beck,et al.  Subtyping of European foot-and-mouth disease virus strains by nucleotide sequence determination , 1987, Journal of virology.

[3]  B. Clarke,et al.  Host cell selection of antigenic variants of foot-and-mouth disease virus. , 1989, The Journal of general virology.

[4]  Alexei J Drummond,et al.  Choosing appropriate substitution models for the phylogenetic analysis of protein-coding sequences. , 2006, Molecular biology and evolution.

[5]  S. Holm A Simple Sequentially Rejective Multiple Test Procedure , 1979 .

[6]  J. Booth,et al.  Microneutralization tests for serological typing and subtyping of foot-and-mouth disease virus strains , 1978, Journal of Hygiene.

[7]  D. Stuart,et al.  The structure and antigenicity of a type C foot-and-mouth disease virus. , 1994, Structure.

[8]  L. Nel,et al.  Characterization of the Structural-Protein-Coding Region of SAT 2 Type Foot-and-Mouth Disease Virus , 2004, Virus genes.

[9]  N. Mattion,et al.  Reintroduction of foot-and-mouth disease in Argentina: characterisation of the isolates and development of tools for the control and eradication of the disease. , 2004, Vaccine.

[10]  R. Kitching,et al.  Antigenic analysis of serotype O foot-and-mouth disease virus isolates from the Middle East, 1981 to 1988. , 1990, Vaccine.

[11]  Yu-Chieh Liao,et al.  Identifying potential immunodominant positions and predicting antigenic variants of influenza A/H3N2 viruses. , 2007, Vaccine.

[12]  M. Rweyemamu Antigenic variation in foot-and-mouth disease: studies based on the virus neutralization reaction. , 1984, Journal of biological standardization.

[13]  S. Cleaveland,et al.  Molecular epidemiology of foot-and-mouth disease virus. , 2003, Virus research.

[14]  W. Vosloo,et al.  Genetic relationships between southern African SAT-2 isolates of foot-and-mouth-disease virus , 1992, Epidemiology and Infection.

[15]  K. De Clercq,et al.  Some guidelines for determining foot-and-mouth disease vaccine strain matching by serology. , 2009, Vaccine.

[16]  S. Barteling,et al.  Antigenic sites on foot-and-mouth disease virus type A10 , 1988, Journal of virology.

[17]  W. Vosloo,et al.  Persistent infection of African buffalo (Syncerus caffer) with SAT-type foot-and-mouth disease viruses: rate of fixation of mutations, antigenic change and interspecies transmission. , 1996, The Journal of general virology.

[18]  Katherine Spindler,et al.  Rapid evolution of RNA genomes. , 1982, Science.

[19]  J. Felsenstein Phylogenies and the Comparative Method , 1985, The American Naturalist.

[20]  Peter Dalgaard,et al.  R Development Core Team (2010): R: A language and environment for statistical computing , 2010 .

[21]  D. Rowlands,et al.  Neutralizing epitopes of type O foot-and-mouth disease virus. I. Identification and characterization of three functionally independent, conformational sites. , 1989, The Journal of general virology.

[22]  M. Suchard,et al.  Bayesian selection of continuous-time Markov chain evolutionary models. , 2001, Molecular biology and evolution.

[23]  A. Lapedes,et al.  Mapping the Antigenic and Genetic Evolution of Influenza Virus , 2004, Science.

[24]  A. Rambaut,et al.  BEAST: Bayesian evolutionary analysis by sampling trees , 2007, BMC Evolutionary Biology.

[25]  F. Yates,et al.  Statistical methods for research workers. 5th edition , 1935 .

[26]  J. Valarcher,et al.  Selection of foot and mouth disease vaccine strains--a review. , 2005, Revue scientifique et technique.

[27]  Hilla Peretz,et al.  The , 1966 .

[28]  J. Saiz,et al.  Identification of neutralizing antigenic sites on VP1 and VP2 of type A5 foot-and-mouth disease virus, defined by neutralization-resistant variants , 1991, Journal of virology.

[29]  E. C. Anderson,et al.  Genetic heterogeneity of SAT-1 type foot-and-mouth disease viruses in southern Africa , 2001, Archives of Virology.

[30]  E. C. Anderson,et al.  Molecular Epidemiology of SAT3-Type Foot-and-Mouth Disease , 2003, Virus Genes.

[31]  M. Salimans,et al.  Rapid and simple method for purification of nucleic acids , 1990, Journal of clinical microbiology.

[32]  M. Kendall Statistical Methods for Research Workers , 1937, Nature.

[33]  Ron A M Fouchier,et al.  Antigenic and Genetic Characteristics of Swine-Origin 2009 A(H1N1) Influenza Viruses Circulating in Humans , 2009, Science.

[34]  V. Vakharia,et al.  Analysis of neutralizing antigenic sites on the surface of type A12 foot-and-mouth disease virus , 1989, Journal of virology.

[35]  D. Haydon,et al.  The implications of virus diversity within the SAT 2 serotype for control of foot-and-mouth disease in sub-Saharan Africa. , 2003, The Journal of general virology.

[36]  Chao A. Hsiung,et al.  Bioinformatics models for predicting antigenic variants of influenza A/H3N2 virus , 2008, Bioinform..

[37]  M. G. Mateu,et al.  Antibody recognition of picornaviruses and escape from neutralization: a structural view. , 1995, Virus research.

[38]  M. Rweyemamu,et al.  Food and mouth disease virus strain differentiation: analysis of the serological data. , 1984, Journal of biological standardization.

[39]  A. Bastos Detection and characterization of foot-and-mouth disease virus in sub-Saharan Africa. , 1998, The Onderstepoort journal of veterinary research.

[40]  P. Barnett,et al.  The suitability of the 'emergency' foot-and-mouth disease antigens held by the International Vaccine Bank within a global context. , 2001, Vaccine.

[41]  Min-Shi Lee,et al.  Predicting Antigenic Variants of Influenza A/H3N2 Viruses , 2004, Emerging infectious diseases.

[42]  G. Belsham,et al.  Sequence analysis of monoclonal antibody resistant mutants of type O foot and mouth disease virus: evidence for the involvement of the three surface exposed capsid proteins in four antigenic sites. , 1990, Virology.

[43]  Sergei L. Kosakovsky Pond,et al.  An Evolutionary-Network Model Reveals Stratified Interactions in the V3 Loop of the HIV-1 Envelope , 2007, PLoS Comput. Biol..

[44]  J. Crowther,et al.  Characterization of monoclonal antibodies against a type SAT 2 foot-and-mouth disease virus , 1993, Epidemiology and Infection.

[45]  R. Meloen,et al.  Evidence for more than one important, neutralizing site on foot-and-mouth disease virus , 2005, Archives of Virology.

[46]  W. Vosloo,et al.  Genome variation in the SAT types of foot-and-mouth disease viruses prevalent in buffalo (Syncerus caffer) in the Kruger National Park and other regions of southern Africa, 1986–93 , 1995, Epidemiology and Infection.

[47]  Frank Yates,et al.  The Analysis of Multiple Classifications with Unequal Numbers in the Different Classes , 1934 .

[48]  J. Crowther,et al.  Identification of a fifth neutralizable site on type O foot-and-mouth disease virus following characterization of single and quintuple monoclonal antibody escape mutants. , 1993, The Journal of general virology.