Abstract Background RNA viruses evolve extremely quickly, allowing them to rapidly adapt to new environmental conditions. Viral pathogens, such as influenza virus, exploit this capacity for evolutionary change to persist within the human population despite substantial immune pressure. Understanding the process of adaptation in these viral systems is essential to our efforts to combat infectious disease. Results Through analysis of simulated populations and sequence data from influenza A (H3N2) and measles virus, we show how phylogenetic and population genetic techniques can be used to assess the strength and temporal pattern of adapt...
Most studies on seasonal influenza A/H3N2 virus adaptation have focused on the main antigenic gene, ...
Host-pathogen interactions, especially those involving RNA viruses and bacteria, are often character...
To escape immune recognition in previously infected hosts, viruses evolve genetically in immunologic...
Abstract Background RNA viruses evolve extremely quic...
Quantifying adaptive evolution at the genomic scale is an essential yet challenging aspect of evolut...
The within-host evolution of influenza is a vital component of its epidemiology. A question of parti...
Quantifying adaptive evolution at the genomic scale is an essential yet challenging aspect of evolut...
Quantifying adaptive evolution at the genomic scale is an essential yet challenging aspect of evolut...
ABSTRACT The seasonal influenza A virus undergoes rapid evolution to escape human immune response. A...
The seasonal influenza A virus undergoes rapid evolution to escape human immune response. Adaptive c...
Abstract Background Since its emergence in 1968, infl...
We present a method to infer the role of selection acting during the within-host evolution of the in...
Rapidly evolving pathogens like influenza viruses can persist by changing their antigenic properties...
<div><p>The within-host evolution of influenza is a vital component of its epidemiology. A question ...
Strains of the influenza virus form coherent global populations, yet exist at the level of single in...
Most studies on seasonal influenza A/H3N2 virus adaptation have focused on the main antigenic gene, ...
Host-pathogen interactions, especially those involving RNA viruses and bacteria, are often character...
To escape immune recognition in previously infected hosts, viruses evolve genetically in immunologic...
Abstract Background RNA viruses evolve extremely quic...
Quantifying adaptive evolution at the genomic scale is an essential yet challenging aspect of evolut...
The within-host evolution of influenza is a vital component of its epidemiology. A question of parti...
Quantifying adaptive evolution at the genomic scale is an essential yet challenging aspect of evolut...
Quantifying adaptive evolution at the genomic scale is an essential yet challenging aspect of evolut...
ABSTRACT The seasonal influenza A virus undergoes rapid evolution to escape human immune response. A...
The seasonal influenza A virus undergoes rapid evolution to escape human immune response. Adaptive c...
Abstract Background Since its emergence in 1968, infl...
We present a method to infer the role of selection acting during the within-host evolution of the in...
Rapidly evolving pathogens like influenza viruses can persist by changing their antigenic properties...
<div><p>The within-host evolution of influenza is a vital component of its epidemiology. A question ...
Strains of the influenza virus form coherent global populations, yet exist at the level of single in...
Most studies on seasonal influenza A/H3N2 virus adaptation have focused on the main antigenic gene, ...
Host-pathogen interactions, especially those involving RNA viruses and bacteria, are often character...
To escape immune recognition in previously infected hosts, viruses evolve genetically in immunologic...