High prevalence of Babesia microti 'Munich' type in small mammals from an Ixodes persulcatus/Ixodes trianguliceps sympatric area in the Omsk region, Russia.

Babesia microti is a genetically diverse group of protozoan parasites whose life cycle is associated with both small mammals and Ixodes spp. ticks. In this study, the prevalence of different B. microti genetic groups in ticks and small rodents in an area with Ixodes persulcatus and Ixodes trianguliceps occurring in sympatry was examined. A total of 541 small mammals were captured during eight sampling periods between 2013 and 2015 at a site in the Omsk region of Russia and tested for the presence of B. microti using nested PCR with subsequent sequencing of positive samples. B. microti DNA was found in 31.6 % of examined samples, and prevalence rates ranged from 5.3 to 61.6 % in different sampling periods. The sequenced B. microti samples belonged to two genetic groups: enzootic B. microti 'Munich' type and zoonotic B. microti 'US' type. B. microti 'Munich' type was more common across all sampling periods, with greater than 80 % prevalence in infected animals. Despite the high B. microti 'Munich'-type prevalence in voles, B. microti was not found in any of 394 adult I. persulcatus ticks collected by flagging or in the 84 I. persulcatus or 20 I. trianguliceps ticks taken from voles and molted under laboratory conditions. It was demonstrated that B. microti 'Munich'-type DNA can be detected in the blood of naturally infected voles for at least 20 weeks after capture. Thus, the high prevalence of B. microti 'Munich' type in small mammals may be explained by the prolonged persistence of B. microti in the blood of wild voles.

Detection and genetic characterization of a putative novel Borrelia genospecies in Ixodes apronophorus / Ixodes persulcatus / Ixodes trianguliceps sympatric areas in Western Siberia.

Four genospecies from the Borrelia burgdorferi sensu lato complex were detected in Ixodes persulcatus and Ixodes pavlovskyi ticks from Siberia and genetically characterized. The presence of Borrelia spp. in Ixodes apronophorus and Ixodes trianguliceps ticks found in Asia has never been studied. In this study, genetic diversity of B. burgdorferi s.l. was investigated in three I. persulcatus / I. trianguliceps / I. apronophorus sympatric habitats in Western Siberia. Three groups of samples were examined: (i) ticks that were taken from rodents and molted in a laboratory; (ii) non-molted ticks collected from rodents; (iii) specimens from small mammals. Expectedly, Borrelia afzelii and Borrelia bavariensis were detected in I. persulcatus and in small mammals from the studied locations. Borrelia bavariensis was first found in molted I. apronophorus and I. trianguliceps. Identical genovariants of B. bavariensis were found in I. apronophorus, I. trianguliceps, and I. persulcatus. In addition, a new Borrelia genovariant was discovered in non-molted and molted I. apronophorus and non-molted I. persulcatus and I. trianguliceps, as well as in small mammals. This new genovariant was genetically characterized using MLST and single locus sequence analysis, which indicated that the new Borrelia genovariant significantly differs from all known Borrelia species. We propose the name "Candidatus Borrelia sibirica" for this putative new species.

Novel Genetic Lineages of Rickettsia helvetica Associated with Ixodes apronophorus and Ixodes trianguliceps Ticks.

Ixodes apronophorus is an insufficiently studied nidicolous tick species. For the first time, the prevalence and genetic diversity of Rickettsia spp. in Ixodes apronophorus, Ixodes persulcatus, and Ixodes trianguliceps ticks from their sympatric habitats in Western Siberia were investigated. Rickettsia helvetica was first identified in I. apronophorus with a prevalence exceeding 60%. "Candidatus Rickettsia tarasevichiae" dominated in I. persulcatus, whereas I. trianguliceps were infected with "Candidatus Rickettsia uralica", R. helvetica, and "Ca. R. tarasevichiae". For larvae collected from small mammals, a strong association was observed between tick species and rickettsiae species/sequence variants, indicating that co-feeding transmission in studied habitats is absent or its impact is insignificant. Phylogenetic analysis of all available R. helvetica sequences demonstrated the presence of four distinct genetic lineages. Most sequences from I. apronophorus belong to the unique lineage III, and single sequences cluster into the lineage I alongside sequences from European I. ricinus and Siberian I. persulcatus. Rickettsia helvetica sequences from I. trianguliceps, along with sequences from I. persulcatus from northwestern Russia, form lineage II. Other known R. helvetica sequences from I. persulcatus from the Far East group into the lineage IV. The obtained results demonstrated the high genetic variability of R. helvetica.

"Candidatus Rickettsia uralica" and "Candidatus Rickettsia thierseensis" are genetic variants of one species.

The spotted fever group is the largest group in the Rickettsia genus, and new candidate species of this group are found throughout the world. "Candidatus Rickettsia thierseensis" was observed in a single Ixodes ricinus in Austria in 2020. However, sequences of five genes (total length: 5305 bp) of the "Candidatus R. thierseensis" were nearly identical to those available for "Candidatus Rickettsia uralica" identified in Ixodes trianguliceps and small mammals in Russia in 2015. To confirm the identity of these species, appropriate fragments of seven genetic loci from four isolates of "Candidatus R. uralica" were sequenced and compared with the "Candidatus R. thierseensis" sequences. Additionally, the groEL gene fragment was first sequenced for "Candidatus R. uralica". In this analysis, "Candidatus R. uralica" and "Candidatus R. thierseensis" demonstrated 100% identity in the 23S-5S IGS region (354 bp) and in fragments of the 16S rRNA (991 bp), gltA (1119 bp), and htrA (463 bp) genes, differing by only one substitution in each of the ompA (3696 bp), ompB (4871 bp), and sca4 (2971 bp) gene fragments. Thus, "Candidatus R. uralica" and "Candidatus R. thierseensis" are likely the same species based on comparative sequence analysis.

Omsk haemorrhagic fever.

Omsk haemorrhagic fever is an acute viral disease prevalent in some regions of western Siberia in Russia. The symptoms of this disease include fever, headache, nausea, severe muscle pain, cough, and moderately severe haemorrhagic manifestations. A third of patients develop pneumonia, nephrosis, meningitis, or a combination of these complications. The only treatments available are for control of symptoms. No specific vaccine has been developed, although the vaccine against tick-borne encephalitis might provide a degree of protection against Omsk haemorrhagic fever virus. The virus is transmitted mainly by Dermacentor reticulatus ticks, but people are mainly infected after contact with infected muskrats (Ondatra zibethicus). Muskrats are very sensitive to Omsk haemorrhagic fever virus. The introduction of this species to Siberia in the 1930s probably led to viral emergence in this area, which had previously seemed free from the disease. Omsk haemorrhagic fever is, therefore, an example of a human disease that emerged owing to human-mediated disturbance of an ecological niche. We review the biological properties of the virus, and the epidemiological and clinical characteristics of Omsk haemorrhagic fever.

Long-term persistence of Anaplasma phagocytophilum and Ehrlichia muris in wild rodents.

Wild animals are reservoir hosts for a number of tick-transmitted agents, and long-term persistence of the agents is a key factor for their effective transmission from animal hosts to ticks. To study the persistence of Anaplasmataceae in rodents, 59 adult Myodes spp. voles (M. rutilus, M. rufocanus, and M. glareolus) were captured in Omsk Province, Asian Russia, freed from all ectoparasites, and kept in individual cages. Their blood samples were regularly analyzed for the presence of DNA of Anaplasma phagocytophilum, Ehrlichia muris, and "Candidatus Neoehrlichia mikurensis". Anaplasma phagocytophilum, E. muris, and mixed infections were found in 29 (49 %), 17 (29 %), and 14 (24 %) voles, respectively. DNA of "Candidatus N. mikurensis" was not identified. Long-term persistence of A. phagocytophilum and E. muris in naturally infected Myodes spp. was shown for the first time. Thus, 12 animals with A. phagocytophilum were found infected for more than three months and four of them carried the bacterium throughout 22-55 weeks of observation. Four voles were infected with E. muris for 26-40 weeks. Fragments of groESL operon were sequenced for genotyping A. phagocytophilum and E. muris. In voles with A. phagocytophilum, the determined sequences belonged to two phylogenetic clusters. Most sequences were identical or closely related to those found in small mammals and Ixodes trianguliceps ticks from Western Siberia and European countries; one sequence was previously identified in rodents and Ixodes persulcatus and Ixodes pavlovskyi ticks from Asian Russia. Sequences of groESL fragments from E. muris were close to those determined previously in small mammals and I. persulcatus ticks from Siberia. In addition, a new groESL sequence of E. muris was identified in one vole and the sequence substantially differed from all known corresponding E. muris sequences (≥ 14 mismatches).

Genetic variability of Anaplasmataceae circulating in small mammals and ticks in an Ixodes persulcatus/Ixodes trianguliceps sympatric area in Russian Siberia.

A total of 705 rodents from Myodes, Microtus, and Apodemus genera, 396 adult questing Ixodes persulcatus, and 115 Ixodes larvae and nymphs taken from rodents (and then molted under laboratory conditions to nymphs and adults) were collected in 2013-2018 in Omsk province, Russian Siberia, and examined for the presence of Anaplasmataceae. DNA of Anaplasma phagocytophilum was detected in 29.5 % rodents, 3.8 % questing I. persulcatus, two molted adult I. persulcatus, and one molted adult Ixodes trianguliceps. Ehrlichia muris DNA was found in specimens from 12.1 % rodents, 3.0 % questing I. persulcatus, 14 % molted adult I. persulcatus, and one molted adult I. trianguliceps. Neoehrlichia mikurensis DNA was found in 0.6 % blood samples. It was suggested that in the studied area A. phagocytophilum and E. muris are mainly transmitted to small rodents by I. trianguliceps and I. persulcatus, respectively. Based on groEL gene sequence analysis, three phylogenetic clusters of A. phagocytophilum (clusters 4, 5, 6, according to Jaarsma et al., 2019) were identified. Most of genotyped A. phagocytophilum isolates obtained from rodents (87.6 %) and a single isolate found in a molted adult I. trianguliceps belonged to cluster 5. Cluster 6 contained 11.8 % genotyped specimens from rodents, and one questing and two molted adult I. persulcatus, while cluster 4 included specimens from 93 % genotyped questing I. persulcatus and one vole. The finding of A. phagocytophilum from clusters 5 and 6 in voles from the same sampling area indicated that clusters 5 and 6 segregate according to the tick-carriers, but not the geography. Most of the genotyped specimens of E. muris and N. mikurensis corresponded to typical genotypes detected in Asian Russia previously. In addition, new genetic variants of E. muris and N. mikurensis, which significantly differed from other known isolates and formed separate branches on phylogenetic trees, were identified in several voles.

Genetic and morphological characterization of Ixodes apronophorus from Western Siberia, Russia.

Genetic variability of I. apronophorus from Western Siberia, Russia was examined using the nuclear internal transcribed spacer 2 (ITS2) and mitochondrial 16S rRNA and cytochrome c oxidase subunit 1 (cox1) genes and compared to those of Ixodes persulcatus and Ixodes trianguliceps from the same site. The I. apronophorus sequences demonstrated the highest nucleotide and haplotype diversity for both mitochondrial genes, whereas I. persulcatus was more variable in the nuclear ITS2. Phylogenetic analysis of the molecular sequence data showed that I. apronophorus differed from other Ixodes species, including Romanian I. apronophorus. The level of identity between 16S rRNA gene sequences of Siberian and Romanian I. apronophorus was only 91%; these sequences did not form a monophyletic group, indicating that I. apronophorus from Siberia and Romania could be different tick species. The analysis of morphological features of the Siberian I. apronophorus confirmed their consistency with those for the previously described I. apronophorus species. Based on the 16S rRNA and ITS2 sequences, Siberian I. apronophorus clustered together with Ixodes kazakstani and Ixodes scapularis, which are the recognized members of the Ixodes ricinus-I. persulcatus species complex within the subgenus Ixodes, and can be assigned to this complex.

Occurrence and genetic variability of Kemerovo virus in Ixodes ticks from different regions of Western Siberia, Russia and Kazakhstan.

Kemerovo virus (KEMV), a member of the Reoviridae family, Orbivirus genus, is transmitted by Ixodes ticks and can cause aseptic meningitis and meningoencephalitis. Recently, this virus was observed in certain provinces of European part of Russia, Ural, and Western and Eastern Siberia. However, the occurrence and genetic diversity of KEMV in Western Siberia remain poorly studied. Therefore, the aim of this work was to investigate the prevalence and genetic variability of KEMV in Ixodes ticks from Western Siberia. A total of 1958 Ixodes persulcatus, I. pavlovskyi ticks and their hybrids from Novosibirsk and Omsk provinces, Altai Republic (Russia) and East Kazakhstan province (Kazakhstan) were analyzed for the presence of KEMV and tick-borne encephalitis virus (TBEV) RNA. It was observed that the KEMV distribution area in Western Siberia was wider than originally thought and included Northern and Northeastern Altai in addition to the Omsk and Novosibirsk provinces. For the first time, this virus was found in Kazakhstan. The occurrence of KEMV was statistically lower than TBEV in most locations in Western Siberia. KEMV was found both in I. persulcatus and I. pavlovskyi ticks and in their hybrids. Notably, KEMV variants observed in the 2010s were genetically different from those isolated in the 1960s, which indicated the ongoing process of evolution of the Kemerovo virus group. Moreover, the possibility of reassortment for KEMV was demonstrated for the first time.

Genetic variability of Rickettsia spp. in Ixodes persulcatus/Ixodes trianguliceps sympatric areas from Western Siberia, Russia: Identification of a new Candidatus Rickettsia species.

Rickettsia spp. are the causative agents of a number of diseases in humans. These bacteria are transmitted by arthropods, including ixodid ticks. DNA of several Rickettsia spp. was identified in Ixodes persulcatus ticks, however, the association of Ixodes trianguliceps ticks with Rickettsia spp. is unknown. In our study, blood samples of small mammals (n=108), unfed adult I. persulcatus ticks (n=136), and I. persulcatus (n=12) and I. trianguliceps (n=34) ticks feeding on voles were collected in two I. persulcatus/I. trianguliceps sympatric areas in Western Siberia. Using nested PCR, ticks and blood samples were studied for the presence of Rickettsia spp. Three distinct Rickettsia species were found in ticks, but no Rickettsia species were found in the blood of examined voles. Candidatus Rickettsia tarasevichiae DNA was detected in 89.7% of unfed I. persulcatus, 91.7% of engorged I. persulcatus and 14.7% of I. trianguliceps ticks. Rickettsia helvetica DNA was detected in 5.9% of I. trianguliceps ticks. In addition, a new Rickettsia genetic variant was found in 32.4% of I. trianguliceps ticks. Sequence analysis of the 16S rRNA, gltA, ompA, оmpB and sca4 genes was performed and, in accordance with genetic criteria, a new Rickettsia genetic variant was classified as a new Candidatus Rickettsia species. We propose to name this species Candidatus Rickettsia uralica, according to the territory where this species was initially identified. Candidatus Rickettsia uralica was found to belong to the spotted fever group. The data obtained in this study leads us to propose that Candidatus Rickettsia uralica is associated with I. trianguliceps ticks.

Genetic similarity of Puumala viruses found in Finland and western Siberia and of the mitochondrial DNA of their rodent hosts suggests a common evolutionary origin.

A total of 678 small mammals representing eight species were trapped in western Siberia in 1999-2000 and assayed for the presence of hantaviruses. Eighteen animals, all Clethrionomys species, were antigen positive by enzyme-linked immunosorbent assay (ELISA). Small and medium genome segments were recovered by RT-PCR from six samples from Clethrionomys glareolus and three from Clethrionomys rufocanus. Sequence comparison and phylogenetic analysis revealed that these hantaviruses were Puumala virus and were similar to hantavirus strains from Finland. To confirm these data, partial nucleotide sequences of the rodent hosts' cytochrome b genes were obtained, as well as several sequences from genes from rodents trapped at different localities of European Russia and western Siberia. The cytochrome b sequences of Siberian bank voles were similar to sequences of C. glareolus, trapped in Finland. These data suggest that the Puumala hantaviruses, as well as their rodent hosts, share a common evolutionary history. We propose that these rodents and viruses may be descendents of a population of bank voles that expanded northward from southern refugia during one of the interglacial periods.

Genetic variability of Anaplasma phagocytophilum in ticks and voles from Ixodes persulcatus/Ixodes trianguliceps sympatric areas from Western Siberia, Russia.

Anaplasma phagocytophilum is a causative agent of granulocytic anaplasmosis in different mammals. The presence of A. phagocytophilum was assayed in Ixodes persulcatus, Ixodes trianguliceps ticks and Myodes spp. voles from two I. persulcatus/I. trianguliceps sympatric areas in the Omsk region (Western Siberia, Russia). In total, A. phagocytophilum was found in 42/108 (38.9%) of vole blood samples, 13/34 (38.2%) of I. trianguliceps ticks removed from voles, 1/12 (8.3%) of I. persulcatus removed from voles, and 18/279 (7.2%) of questing I. persulcatus. GroESL operon sequence analysis of positive samples revealed three distinct A. phagocytophilum genetic groups previously identified in ticks and mammals in Russia. Genetic group 1 was found in 6/36 (16.7%) of sequenced positive blood samples; this group was previously revealed in I. persulcatus and Myodes spp. voles in different regions of Russia. Genetic group 2 was found in 30/36 (83.3%) of sequenced positive blood samples and all positive I. trianguliceps; this group was previously revealed only in Myodes spp. voles and common shrews (Sorex araneus) in I. persulcatus/I. trianguliceps sympatric areas in the Northern Ural. Genetic group 3 was found in all positive questing I. persulcatus and one blood sample; this group was previously revealed in I. persulcatus and Siberian chipmunks (Tamias sibiricus). We suppose that I. trianguliceps is the most probable vector for A. phagocytophilum of group 2. Analysis of the msp4 gene, intergenic region DOV1, and some other genetic loci has shown that isolates from different genetic groups significantly differ in all studied loci and that A. phagocytophilum of group 2 is closely related to A. phagocytophilum isolates revealed in voles and I. trianguliceps in Europe. A. phagocytophilum of groups 1 and 2 are the most similar to each other, while A. phagocytophilum of group 3 clusters with European A. phagocytophilum isolates from I. ricinus and various mammalian species.