[GENETIC CHARACTERISTICS OF INFLUENZA A/H3N2 AND B VIRUSES THAT HAD CIRCULATED IN RUSSIA IN 2013 - 2015].

AIM: Establish genetic characteristics, carry out phylogenetic analysis and determination of molecular markers of resistance to etiotropic preparations against influenza A/H3N2 and B viruses that had circulated in Russia in 2013 - 2015. MATERIALS AND METHODS: 80 biological samples containing influenza A/H3N2 virus RNA and 31 samples containing influenza B virus RNA were studied. Sequencing of PCR fragments was carried out inABI-3 100 PRIZMTM GeneticAnalyzer (AppliedBiosystems, USA) and using MiSeq (Illumina, USA). Data treatment and analysis was carried out using CLC v.3.6.5., DNASTAR and BioNumerics v.6.5. programs. RESULTS: In 2013 -2014 A/Texas/50/2012-like-clade 3C.3 influenza A/H3N2 viruses dominated, 10% belonged to subclade 3C.2a and 10% - to 3C.3b. Most of the viruses (8 1%) of 2014 - 2015 were of 3C.2a clade, the portion of viruses belonging to 3C.3b and 3C.3a was 9 and 10%. Yamagata-like viruses predominated among the studied influenza B viruses, only 1 virus of 2014 - 2015 belonged to Victoria lineage, 1 reassortant of Yamagata and Victoria lineages was detected. Rimantadine- resistance mutationS3 lN(M2 protein) was detected in all the influenza A/H3N2 viruses. Mutations determining resistance to oseltamivir (NA gene) were not detected in influenza A/H3N2 and B viruses. CONCLUSION: Increase of influenza morbidity in 2014 - 2015 was determined by the emergence of influenza A/H3N2 and B viruses, antigenically distinct from those that had circulated previously and those included into the vaccine, thus resulting in the WHO decision to change A/ H3N2 and B components of the 2015 - 2016 vaccine: Simultaneous circulation of 2 lineages of influenza B virus and emergence of their reassortants gives evidence on the necessity of use of quadrivalent vaccines, containing both lineages.

Proteomic characterization of Mycoplasma gallisepticum nanoforming.

The goal of this work was to create a model for the long persistence of Mycoplasma gallisepticum in depleted medium and under low growth temperature followed by proteomic study of the model. Nanoforms and revertants for M. gallisepticum were obtained. Proteomic maps were produced for different stages of the formation of nanoforms and revertants. It is shown that proteins responsible for essential cellular processes of glycolysis, translation elongation, and DnaK chaperone involved in the stabilization of newly synthesized proteins are crucial for the reversion of M. gallisepticum to a vegetative form. Based on the current data, it is assumed that changes in the metabolism of M. gallisepticum during nanoforming are not post-mortal, thus M. gallisepticum does not transform to uncultivable form, but remains in a reversible dormant state during prolonged unfavorable conditions.