BACKGROUND: The high variability of influenza strains and the emergence of new variants of viruses lead to the need for constant updating of the composition of influenza vaccines. One of the options for solving this problem is the development of vaccines with enhanced cross-protection against a wide range of influenza strains. Genetically engineered preparations based on live influenza vaccine can be used for targeted stimulation of the cellular immune response. It has been experimentally established that CTL epitopes inserted into the NS gene of the live influenza vaccine strain cause the activation of lymphocytes and the formation of a pool of resident memory T-cells in the lungs of model animals. It is optimal to use experimentally confirmed immunogenic regions for insertion.
 AIM: The aim of this study was to rescue a panel of experimental cold-adapted live attenuated influenza vaccine strains with a modified NS gene using A/Leningrad/134/17/57 backbone and recent influenza strains of H1N1, H3N2 and H7N9 subtypes, and evaluate their properties in vitro.
 MATERIALS AND METHODS: A cassette encoding immunogenic, conserved among a wide range of influenza strains T-cell epitopes of the influenza virus PB1 protein restricted by common HLA-allotypes was inserted into the gene encoding the NS1 protein. The modified NS gene was cloned into the pCIPolISapIT influenza virus reverse genetics vector. Chimeric influenza viruses were rescued by transfection of Vero cells by electroporation using a standard 8-plasmid system. The growth characteristics of viruses were assessed in developing chicken embryos.
 Results: Three strains were successfully obtained based on the live influenza vaccine master donor virus A/Leningrad/ 134/17/57 with a modified NS gene and influenza viruses of the H1N1, H3N2, H7N9 subtypes. Thus, modification of NS gene by insertion of immunogenic PB1 epitopes did not affect the viability and replicative activity of the rescued chimeric live influenza vaccine strains, regardless of the composition of the surface proteins. The strains replicated well at an optimal temperature, had temperature-sensitive phenotype and were able to grow at low temperature.
 CONCLUSIONS: The strains will be further studied as candidates for influenza prophylaxis as an experimental universal influenza vaccine.
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