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RESEARCH PRODUCT
Genetic characterization of influenza viruses from influenza-related hospital admissions in the St. Petersburg and Valencia sites of the Global Influenza Hospital Surveillance Network during the 2013/14 influenza season
Andrés MoyaKarina SalvatierraMaria PisarevaArtem FadeevAngels Natividad-sanchoOlga AfanasievaGrudinin MpJoan Puig-barberàJavier Díez-domingoAndrey KomissarovF. Xavier López-labradorF. Xavier López-labradorAnna SomininaN. I. Konovalovasubject
0301 basic medicineHemagglutinin glycoproteinsMalevirusesHemagglutinin Glycoproteins Influenza Virusmedicine.disease_causeGlobal HealthRussia0302 clinical medicineGenomic sequencingInfluenza A Virus H1N1 SubtypeInfluenza A virusH3N2 subtype030212 general & internal medicineCladeChildPhylogenyAged 80 and overPhylogenetic treevirus diseasesMiddle AgedInfectious DiseasesInfluenza A virusChild PreschoolEpidemiological MonitoringRNA ViralFemaleSeasonsAdultAdolescentHemagglutinin (influenza)Genome ViralBiologyH5N1 genetic structure03 medical and health sciencesYoung AdultVirologyInfluenza preventionGenetic variationInfluenza HumanmedicineHumansAgedGenetic diversityInfluenza A Virus H3N2 SubtypeGenetic VariationInfantSequence Analysis DNAVirology030104 developmental biologyH1N1 subtypeSpainbiology.proteinInfluenza virusdescription
Abstract Background Continuous surveillance for genetic changes in circulating influenza viruses is needed to guide influenza prevention and control. Objectives To compare intra-seasonal influenza genetic diversity of hemagglutinin in influenza A strains isolated from influenza hospital admissions collected at two distinct sites during the same season. Study design Comparative phylogenetic analysis of full-length hemagglutinin genes from 77 isolated influenza A viruses from the St. Petersburg, Russian Federation and Valencia, Spain sites of the Global Influenza Hospital Surveillance Network (GIHSN) during the 2013/14 season. Results We found significant variability in A(H3N2) and A(H1N1)pdm09 viruses between the two sites, with nucleotide variation at antigenic positions much lower for A(H1N1)pdm09 than for A(H3N2) viruses. For A(H1N1)pdm09, antigenic sites differed by three to four amino acids from the vaccine strain, two of them common to all tested isolates. For A(H3N2) viruses, antigenic sites differed by six to nine amino acids from the vaccine strain, four of them common to all tested isolates. A fifth amino acid substitution in the antigenic sites of A(H3N2) defined a new clade, 3C.2. For both influenza A subtypes, pairwise amino acid distances between circulating viruses and vaccine strains were significantly higher at antigenic than at non-antigenic sites. Whereas A(H1N1)pdm09 viruses clustered with clade 6B and 94% of A(H3N2) with clade 3C.3, at both study sites A(H3N2) clade 3C.2 viruses emerged towards the end of the season, showing greater pairwise amino acid distances from the vaccine strain compared to the predominant clade 3C.3. Conclusions Influenza A antigenic variants differed between St. Petersburg and Valencia, and A(H3N2) clade 3C.2 viruses were characterized by more amino acid differences from the vaccine strain, especially at the antigenic sites.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2016-11-01 | Journal of Clinical Virology |