Pleiotropic effects of hemagglutinin amino acid substitutions of influenza A(H1N1)pdm09 virus escape mutants.

In the present study we assessed pleiotropic characteristics of the antibody-selected mutations. We investigated pH optimum of fusion, temperatures of HA heat inactivation, in vivo and in vitro replication kinetics, and connectivity with panel of sera of survivors patients in different epidemic seasons of the previously obtained influenza H1 escape mutants. Our results showed that N133D (H3 numbering) mutation significantly lowered the pH of fusion optimum.

Predicting the Evolutionary Variability of the Influenza A Virus.

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.

Pleiotropic effects of amino acid substitutions in H5 hemagglutinin of influenza A escape mutants.

We believe that the monitoring of pleiotropic effects of the hemagglutinin (HA) mutations found in H5 escape mutants is essential for accurate prediction of mutants with pandemic potential. In the present study, we assessed multiple characteristics of antibody-selected HA mutations. We examined the pH optimum of fusion, HA heat inactivation, affinity to sialyl receptors, and in vitro and in vivo replication kinetics of various influenza H5 escape mutants.

[Effect of amino acid substitutions in small subunit of avian H5N2 influenza virus hemagglutinin on selection of the mutants resistant to neutralizing monoclonal antibodies].

Changes associated with the resistance to physical and chemical factors in the hemagglutinin (HA) of influenza A viruses may play an important role in the selection of different influenza variants during circulation in nature. Here, we studied the escape mutants of influenza virus A/mallard/Pennsylvania/10218/84 (H5N2) that were selected by the monoclonal antibody. The escape mutant m4F11(4) carried a single amino acid substitution in large subunit (HA1) of the HA, S145P1, and two ones, m4G10(10) and m4G10(6), had additional amino acid changes in the small subunit (HA2), namely: L124F2 and L124F2 + N79D2, respectively.

Location and architecture of an antibody-binding site of influenza A virus nucleoprotein.

Amino acid positions recognized by monoclonal antibodies (MAbs) in the influenza A virus nucleoprotein (NP) have been reported. As these residues were scattered in the three-dimensional (3D) structure of NP, no patterns of the architecture of antibody-binding sites could be inferred. Here, we used site-specific mutagenesis and ELISA to screen the amino acids surrounding position 470 recognized by the MAb 3/1 as a linear epitope.