Predicting the Evolutionary Variability of the Influenza A Virus

Overview

Journal Acta Naturae

Specialty Biology

Date 2017 Nov 7

PMID 29104775

Citations 2

Authors

T A Timofeeva

M N Asatryan

A D Altstein

B S Narodisky

A L Gintsburg

N V kaverin

Affiliations

Soon will be listed here.

Abstract

The influenza A virus remains one of the most common and dangerous human health concerns due to its rapid evolutionary dynamics. Since the evolutionary changes of influenza A viruses can be traced in real time, the last decade has seen a surge in research on influenza A viruses due to an increase in experimental data (selection of escape mutants followed by examination of their phenotypic characteristics and generation of viruses with desired mutations using reverse genetics). Moreover, the advances in our understanding are also attributable to the development of new computational methods based on a phylogenetic analysis of influenza virus strains and mathematical (integro-differential equations, statistical methods, probability-theory-based methods) and simulation modeling. Continuously evolving highly pathogenic influenza A viruses are a serious health concern which necessitates a coupling of theoretical and experimental approaches to predict the evolutionary trends of the influenza A virus, with a focus on the H5 subtype.

Citing Articles

The Effect of I155T, K156Q, K156E and N186K Mutations in Hemagglutinin on the Virulence and Reproduction of Influenza A/H5N1 Viruses.

Timofeeva T, Sadykova G, Lomakina N, Gambaryan A, Rudneva I, Timofeeva E Mol Biol. 2021; 54(6):861-869.

PMID: 33424035 PMC: 7783499. DOI: 10.1134/S0026893320060126.

Influenza passaging annotations: what they tell us and why we should listen.

DuPai C, McWhite C, Smith C, Garten R, Maurer-Stroh S, Wilke C Virus Evol. 2019; 5(1):vez016.

PMID: 31275610 PMC: 6599686. DOI: 10.1093/ve/vez016.

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