Spatio-temporal clustering of African swine fever virus (Asfarviridae: Asfivirus) circulating in the Kaliningrad region based on three genome markers.

INTRODUCTION: The rapid spread of African swine fever in the Kaliningrad region makes it necessary to use the methods of molecular epidemiology to determine the dynamics and direction of ASF spread in this region of Russia. The aim of the study was to determine single nucleotide polymorphisms within molecular markers K145R, O174L and MGF 505-5R of ASFVs isolated in Kaliningrad region and to study the circulating of the pathogen in European countries by subgenotyping and spatio-temporal clustering analysis. MATERIALS AND METHODS: Blood samples from living domestic pigs and organs from dead domestic pigs and wild boars, collected in the Kaliningrad region between 2017 and 2022 were used. Virus isolation was carried out in porcine bone-marrow primary cell culture. Amplicons of genome markers were amplified by PCR with electrophoretic detection and subsequent extraction of fragments from agarose gel. Sequencing was performed using the Sanger method. RESULTS: The circulation of two genetic clusters of ASFV isolates on the territory of the Kaliningrad has been established: epidemic (K145R-III, MGF 505-5R-II, O174L-I - 94.3% of the studied isolates) and sporadic (K145R-II, MGF 505-5R-II, O174L-I - 5.7%). CONCLUSION: The broaden molecular genetic surveillance of ASFV isolates based on sequencing of genome markers is necessary in the countries of the Eurasian continent to perform a more detailed analysis of ASF spread between countries and within regions.

[Analysis of the whole-genome sequence of an ASF virus (Asfarviridae: Asfivirus: African swine fever virus) isolated from a wild boar (Sus scrofa) at the border between Russian Federation and Mongolia].

INTRODUCTION: The causative agent of African swine fever (Asfarviridae: Asfivirus: African swine fever virus) (ASF) is a double-stranded DNA virus of 175-215 nm. To date, 24 of its genotypes are known. Clustering of ASF genotype II isolates is carried out by examining a limited number of selected genome markers. Despite the relatively high rate of mutations in the genome of this infectious agent compared to other DNA viruses, the number of known genome molecular markers for genotype II isolates is still insufficient for detailed subclustering. The aims of this work were the comparative analysis of ASFV/Zabaykali/WB-5314/2020 virus isolate and determination of additional molecular markers which can be used for clustering of viral genotype II sequences. MATERIAL AND METHODS: ASF virus isolate ASFV/Zabaykali/WB-5314/2020 was used to extract genomic DNA (gDNA). Sequencing libraries were constructed using the Nextera XT DNA library prepare kit (Illumina, USA) using the methodology of the next generation sequencing (NGS). RESULTS: The genome length was 189,380 bp, and the number of open reading frames (ORFs) was 189. In comparison with the genome of reference isolate Georgia 2007/1, 33 single nucleotide polymorphisms (SNPs) were identified, of which 13 were localized in the intergenic region, 10 resulted to the changes in the amino acid sequences of the encoded proteins, and 10 affected the ORF of ASF virus genes. DISCUSSION: When analyzing intergenic regions, the ASFV/Zabaykali/WB-5314/2020 isolate is grouped separately from a number of isolates from Poland and three isolates from People's Republic of China (PRC), since it does not harbor additional tandem repeat sequence (TRS). At the same time, the construction of a phylogenetic tree based on DP60R gene sequencing relates ASFV/Zabaykali/WB-5314/2020 to isolates from PRC and Poland. Moreover, phylogenetic analysis of full-genome sequences confirmed previous studies on the grouping of viruses of genotype II, and as for the studied isolate, it was grouped with the variants from China. CONCLUSION: A new variable region was identified, the DP60R gene, clustering for which gave a result similar to the analysis of full-length genomes. Probably, further study of the distribution of ASF virus isolates by groups based on the analysis of this gene sequences will reveal its significance for studying the evolution of the virus and its spread.

Genetic characteristics of spring viraemia of carp virus strains Kirov/08 and Orenburg/14.

The paper presents the genetic characteristics of two strains of spring viraemia of carp virus (SVCV), Kirov/08 and Orenburg/14, isolated in the Kirov and Orenburg oblasts of the Russian Federation, respectively. Nucleotide sequence analysis of a 516-bp fragment of the G genes of Kirov/08 and Orenburg/14 showed 9.5% divergence. Phylogenetic analysis demonstrated a close relationship of these strains to SVCV isolates recovered in Russia, Ukraine, and the Republic of Moldova.

[Changes in the genome of African swine fever virus (Asfarviridae: Asfivirus: African swine fever virus) associated with adaptation to reproduction in continuous cell culture].

INTRODUCTION: African swine fever virus (ASFV) is a large, double-stranded DNA virus in the Asfarviridae family. It is the causative agent of African swine fever (ASF). Only the genome of BA71V strain, adapted to Vero cell culture, was fully analyzed.The aim of this study was analyzing the complete genome sequence of two strains of adapted to the growth in CV-1 cell culture (CC) ASFV obtained after 30 and 50 passages, in comparison to the parental virus. MATERIAL AND METHODS: ASFV isolate Odintsovo 02/14 (parental), ASFV adapted variants ASFV/ARRIAH/CV-1/30 and ASFV/ARRIAH/CV-1/50 were all used to extract genomic DNA (gDNA). Sequencing library was constructed using the «Nextera XT DNA library preparation kit¼ («Illumina¼, USA). RESULTS: Genomes of ASFV/ARRIAH/CV-1/30 and ASFV/ARRIAH/CV-1/50 consisted of 186 529 bp and 186 525 bp, respectively. Total 78 single nucleotide polymorphisms (SNPs) were identified between the parental Odintsovo 02/14 and the two high passaged strains, as well as a 2947 bp large-size deletion in the 3' variable region of adapted viruses was detected. DISCUSSION: ASFV as a DNA-containing virus may not have a very high level of mutation, but this is the second study showing that adaptation to growth in continuous CC leads to large deletions in the genome of the virus. CONCLUSION: Mutations in the protein-coding regions of the genome can be synonymous and non-synonymous, i.e. leading to amino acid substitution. Additional research is needed to understand the influence of the mutations described in the adaptation process on the reproduction of the virus and its virulence.

Genetic analysis of genotype G57 H9N2 avian influenza virus isolate A/chicken/Tajikistan/2379/2018 recovered in Central Asia.

This paper presents genetic data on the full genome analysis of A/chicken/Tajikistan/2379/2018 H9N2 influenza virus isolated in September 2018 from chicken pathological material received from poultry farms of the Republic of Tajikistan and subtyped as H9N2 by serological and molecular methods. According to the results of hemagglutinin gene sequencing, the amino acid sequence of the cleavage site was RSSR/GLF, which is typical for low-virulent avian influenza virus. Phylogenetic analysis of the nucleotide sequence of a hemagglutinin gene fragment (nt 1-1539 of the open reading frame) showed that the A/chicken/Tajikistan/2379/2018 H9N2 isolate belongs to the Y280 genetic group of low-virulent A/H9 influenza virus, which is widespread in Southeast Asia. The complete nucleotide sequence of the viral genome was determined. Comparative analysis of all genomic segments revealed that the A/chicken/Tajikistan/2379/2018 H9N2 virus is closely related to an A/H9 influenza virus isolated in the Far East of the Russian Federation in 2018. Genetic similarity (97.1-99% identity in four out of eight viral genes) was found to isolates of an H7N9 subtype virus recovered in the Inner Mongolia and Hebei regions of China in 2017. According to the analysis of the predicted amino acid sequence of the studied isolate, the positions of some molecular markers indicate possible adaptation of the virus to mammals. Further genetic analysis showed that this virus belongs to genotype G57.

Avian hepatitis E virus identified in Russian chicken flocks exhibits high genetic divergence based on the ORF2 capsid gene.

A total of 79 liver samples from clinically sick and asymptomatic chickens were tested for avian hepatitis E virus (aHEV). Samples were received from 19 farms, five of which tested positive with primers targeting the ORF2 capsid gene. The phylogenetic analysis of a 242-base-pair fragment demonstrated that the Russian aHEV isolates share between 78.2 and 96.2% over the fragment sequenced, whereas the nucleotide sequence identities between the Russian isolates and the other representatives from GeneBank varied from 76.3 to 96.2%. The homology between the studied hepatitis E viruses and swine hepatitis E virus varied between 46.9 to 48.1%. The most divergent isolate aHEV16050 showed homology of 82.6% as compared with the strains in the dendrogram. The three positive hepatitis E virus samples (aHEV16279, aHEV16050 and aHEV18196) did not cluster with the European genotype 3 as expected due to the close location of Russia to Europe, nor did they with the other two genotypes, separating to a distinct branch. The aHEV16211 grouped together with European and Chinese isolates, and the aHEV18198 with Canadian ones.

Genetic diversity of Mycoplasma gallisepticum field isolates using partial sequencing of the pvpA gene fragment in Russia.

The genetic diversity of the pvpA gene of Mycoplasma gallisepticum (MG) samples originating from commercial chickens was investigated. In the present study, we evaluated the genetic variability of 26 field samples of MG detected in commercial chickens and turkeys from 18 regions of Russia and compared them to the reference strains of MG available in GenBank. Genetic variability was evaluated by partial nucleotide sequencing of the pvpA gene, which encodes a putative cytadhesin protein. Comparisons with MG strains and isolates from the United States, Australia, China, and Iran using sequence analysis of PCR products showed that Russian MG field samples clustered more closely to each other than to the international reference MG strains. The MG pvpA sequences were found to be highly variable with a discrimination index of 0.975 for Russian field samples. No apparent cluster was found using the criteria of year or location of detection. DNA sequence polymorphism and size variation in the pvpA gene were shown among the Russian MG field samples and could be used for MG typing. These findings might help better understand the relationship among MG isolates from Russia and other countries.