Litcius/Paper detail

Evolutionary stability of antigenically escaping viruses

Victor Chardès, Andrea Mazzolini, Thierry Mora, Aleksandra M. Walczak

2023Proceedings of the National Academy of Sciences17 citationsDOIOpen Access PDF

Abstract

Antigenic variation is the main immune escape mechanism for RNA viruses like influenza or SARS-CoV-2. While high mutation rates promote antigenic escape, they also induce large mutational loads and reduced fitness. It remains unclear how this cost-benefit trade-off selects the mutation rate of viruses. Using a traveling wave model for the coevolution of viruses and host immune systems in a finite population, we investigate how immunity affects the evolution of the mutation rate and other nonantigenic traits, such as virulence. We first show that the nature of the wave depends on how cross-reactive immune systems are, reconciling previous approaches. The immune-virus system behaves like a Fisher wave at low cross-reactivities, and like a fitness wave at high cross-reactivities. These regimes predict different outcomes for the evolution of nonantigenic traits. At low cross-reactivities, the evolutionarily stable strategy is to maximize the speed of the wave, implying a higher mutation rate and increased virulence. At large cross-reactivities, where our estimates place H3N2 influenza, the stable strategy is to increase the basic reproductive number, keeping the mutation rate to a minimum and virulence low.

Topics & Concepts

Mutation rateBiologyVirulenceMutationAntigenic variationViral evolutionImmune systemVirusCoevolutionPopulationGeneticsImmune escapeVirologyEvolutionary biologyRNAGeneDemographySociologyEvolution and Genetic DynamicsMathematical and Theoretical Epidemiology and Ecology ModelsCOVID-19 epidemiological studies