We use a mathematical model to study the evolution of influenza A during the epidemic dynamics of a single season. Classifying strains by their distance from the epidemic-originating strain, we show that neutral mutation yields a constant rate of antigenic evolution, even in the presence of epidemic dynamics. We introduce host immunity and viral immune escape to construct a non-neutral model. Our population dynamics can then be framed naturally in the context of population genetics, and we show that departure from neutrality is governed by the covariance between a strain's fitness and its distance from the original epidemic strain. We quantify the amount of antigenic evolution that takes place in excess of what is expected under neutrality ...
The enigmatic observation that the rapidly evolving influenza A (H3N2) virus exhibits, at any given ...
Seasonal influenza viruses create a persistent global disease burden by evolving to escape immunity ...
The evolution of many microbes and pathogens, including circulating viruses such as seasonal influen...
We use a mathematical model to study the evolution of influenza A during the epidemic dynamics of a ...
To escape immune recognition in previously infected hosts, viruses evolve genetically in immunologic...
To escape immune recognition in previously infected hosts, viruses evolve genetically in immunologic...
In this thesis we develop a mathematical cross-scale model for the evolution of influenza within a s...
The recurrence of influenza A epidemics has originally been explained by a "continuous antigenic dri...
The recurrence of influenza A epidemics has originally been explained by a "continuous antigenic dri...
It is commonly believed that influenza epidemics arise through the incremental accumulation of viral...
In this paper we explore the consequences of a heterogeneous immune response in individuals on the e...
The accumulation of cross-immunity in the host population is an important factor driving the antigen...
The recurrence of influenza A epidemics has originally been explained by a ‘‘continuous antigenic dr...
Influenza in humans is characterised by strongly annual dynamics and antigenic evolution leading to ...
International audienceViruses evolve in the background of host immune systems that exert selective p...
The enigmatic observation that the rapidly evolving influenza A (H3N2) virus exhibits, at any given ...
Seasonal influenza viruses create a persistent global disease burden by evolving to escape immunity ...
The evolution of many microbes and pathogens, including circulating viruses such as seasonal influen...
We use a mathematical model to study the evolution of influenza A during the epidemic dynamics of a ...
To escape immune recognition in previously infected hosts, viruses evolve genetically in immunologic...
To escape immune recognition in previously infected hosts, viruses evolve genetically in immunologic...
In this thesis we develop a mathematical cross-scale model for the evolution of influenza within a s...
The recurrence of influenza A epidemics has originally been explained by a "continuous antigenic dri...
The recurrence of influenza A epidemics has originally been explained by a "continuous antigenic dri...
It is commonly believed that influenza epidemics arise through the incremental accumulation of viral...
In this paper we explore the consequences of a heterogeneous immune response in individuals on the e...
The accumulation of cross-immunity in the host population is an important factor driving the antigen...
The recurrence of influenza A epidemics has originally been explained by a ‘‘continuous antigenic dr...
Influenza in humans is characterised by strongly annual dynamics and antigenic evolution leading to ...
International audienceViruses evolve in the background of host immune systems that exert selective p...
The enigmatic observation that the rapidly evolving influenza A (H3N2) virus exhibits, at any given ...
Seasonal influenza viruses create a persistent global disease burden by evolving to escape immunity ...
The evolution of many microbes and pathogens, including circulating viruses such as seasonal influen...