Litcius/Paper detail

Asynchrony between virus diversity and antibody selection limits influenza virus evolution

Dylan H. Morris, Velislava Petrova, Fernando W. Rossine, Edyth Parker, Bryan T. Grenfell, Richard A. Neher, Simon A. Levin, Colin A. Russell

2020eLife47 citationsDOIOpen Access PDF

Abstract

Seasonal influenza viruses create a persistent global disease burden by evolving to escape immunity induced by prior infections and vaccinations. New antigenic variants have a substantial selective advantage at the population level, but these variants are rarely selected within-host, even in previously immune individuals. Using a mathematical model, we show that the temporal asynchrony between within-host virus exponential growth and antibody-mediated selection could limit within-host antigenic evolution. If selection for new antigenic variants acts principally at the point of initial virus inoculation, where small virus populations encounter well-matched mucosal antibodies in previously-infected individuals, there can exist protection against reinfection that does not regularly produce observable new antigenic variants within individual infected hosts. Our results provide a theoretical explanation for how virus antigenic evolution can be highly selective at the global level but nearly neutral within-host. They also suggest new avenues for improving influenza control.

Topics & Concepts

BiologyAntigenic driftVirusAntigenic variationVirologyAntigenic shiftViral evolutionOriginal antigenic sinHost (biology)Influenza A virusPopulationAsynchrony (computer programming)Evolutionary biologyAntigenH5N1 genetic structureVaccinationGeneticsGeneDiseaseInfectious disease (medical specialty)GenomeCoronavirus disease 2019 (COVID-19)DemographyPathologyMedicineSociologyComputer scienceAsynchronous communicationComputer networkInfluenza Virus Research StudiesT-cell and B-cell ImmunologyMonoclonal and Polyclonal Antibodies Research