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Volume 17, Number 5—May 2011
Dispatch

Tick-Borne Encephalitis Virus, Kyrgyzstan

Author affiliations: Author affiliations: State University of New York, Buffalo, New York, USA (B.J. Briggs, D.M. Czechowski, J. Hay); Health Protection Agency, Porton Down, Salisbury, UK (B. Atkinson, R. Hewson); Texas Tech University, Lubbock, Texas, USA (P.A. Larsen, H.N. Meeks, J.P. Carrera, R.M. Duplechin, C.J. Phillips, R.J. Baker); National Academy of Sciences of the Kyrgyz Republic, Bishkek, Kyrgyz Republic (A.T. Junushov); Ministry of Healthcare of the Kyrgyz Republic, Bishkek (O.N. Gavrilova, I. Breininger)

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Abstract

Tick-borne encephalitis virus (TBEV) is an emerging pathogen in Europe and Asia. We investigated TBEV in Kyrgyzstan by collecting small mammals and ticks from diverse localities and analyzing them for evidence of TBEV infection. We found TBEV circulating in Kyrgyzstan much farther south and at higher altitudes than previously reported.

Tick-borne encephalitis virus (TBEV) is a flavivirus in the family Flaviviridae. The TBEV positive-sense RNA genome is translated as a polyprotein and subsequently cleaved into 3 structural and 7 nonstructural (NS) proteins (1). TBEV has 3 subtypes— European, Siberian, and Far-Eastern—each of which has its own ecology, clinical presentation, and geographic distribution (2). The vectors are Ixodes ricinus ticks for the European subtype and I. persulcatus ticks for the other 2 subtypes. TBEV circulates through a complex cycle involving small mammals, ticks, and large mammals (3); it can also be transmitted through consumption of unpasteurized milk and milk products (4).

Our unpublished data and that of others suggest that TBEV circulates in Kazakhstan. However, we have found no reports (in English) since 1978 of TBEV infection in the neighboring Kyrgyz Republic (Kyrgyzstan). Kyrgyzstan has extensive alpine and subalpine habitats (94% of Kyrgyzstan is >1,000 m above sea level) (5); the Tien Shan mountain range dominates and physiographically links Kyrgyzstan to the Himalayas and western People’s Republic of China. We conducted fieldwork in Kyrgyzstan during June–July 2007 and July–August 2009 to establish a baseline of risk for zoonotic diseases, including TBEV.

The Study

Figure 1

Thumbnail of Animal trapping sites in Kyrgyzstan, with topographic characteristics shown. Ala-Archa (star) is the location of tick-borne encephalitis virus and a possible human case of tick-borne encephalitis.

Figure 1. Animal trapping sites in Kyrgyzstan, with topographic characteristics shown. Ala-Archa (star) is the location of tick-borne encephalitis virus and a possible human case of tick-borne encephalitis.

During the 2007 and 2009 study periods, we collected 369 rodents and insectivores and 222 ixodid and 128 argasid ticks from 6 localities in Kyrgyzstan (Figure 1; Table 1) in accordance with animal subject review boards of Texas Tech University and the State University of New York at Buffalo. We analyzed 302 rodents and insectivores for immunoglobulin (Ig) G and IgM to TBEV by using recombinant antigen of domain III from the envelope (E) protein of Kumlinge and Powassan viruses (6). This assay is specific for the tick-borne flavivirus group and lacks cross-reactivity that occurs with other assays (7). We found that serologically positive (IgG and IgM) mammals were clustered at Ala-Archa National Nature Park, ≈40 km south of Bishkek, the capital of Kyrgyzstan, at elevations ranging from 1,891 to 2,472 m. Using mitochondrial DNA analysis, we also found clusters of seropositive Himalayan field mice, Apodemus pallipes.

To further evaluate the prevalence of TBEV, we used reverse transcription–PCR (RT-PCR) to examine viral genomic sequences in tissue samples collected from rodents, insectivores, and ticks. We used 3 separate PCR protocols. Table 2 shows primer sequences. Real-time and conventional RT-PCRs were used; however, conventional RT-PCR was preferred because it allowed sequencing of viral genomes. Thus far, we have examined sequences from the NS5 (8) and E (9) protein coding regions.

Figure 2

Thumbnail of Maximum-likelihood phylogenetic tree of relationship between various tick-borne encephalitis virus (TBEV) strains isolated from rodents, insectivores, and ticks, Kyrgyzstan, 2007 and 2009. Tree is based on partial sequencing of the envelope protein (from Cys3 to Gly286). Strain names are followed by GenBank accession numbers. The strain from Ala-Archa (KY09_HM641235) is most closely related to strains from Novosibirsk (TBEV 1467 and Z6). This strain was isolated from an Ixodes persu

Figure 2. Maximum-likelihood phylogenetic tree of relationship between various tick-borne encephalitis virus (TBEV) strains isolated from rodents, insectivores, and ticks, Kyrgyzstan, 2007 and 2009. Tree is based on partial sequencing of the envelope...

On the basis of data obtained in 2007, we focused collections in 2009 at 2 sites at Ala-Archa, 5 km apart and differing in elevation by 100 m. We found TBEV-positive ticks and IgG- and IgM-positive A. pallipes mice at collection sites. Sequence analyses of TBEV NS5 and E genes from A. pallipes mice and I. persulcatus ticks suggested that the TBEV circulating in Kyrgyzstan is of the Siberian subtype. Phylogenetic analyses of the E protein, amplified from a pool of I. persulcatus ticks collected at Ala-Archa, showed that the TBEV strain from Kyrgyzstan shares a clade with 2 strains (TBEV 1467 and Z6) isolated in the Novosibirsk region of Russia (Figure 2). This sequence is homologous with that of 5 other TBEV-positive tick pools and liver samples from A. pallipes mice from the same collection site.

While we were conducting fieldwork in 2009, a possible case of encephalitis occurred in a human. The 21-year-old man had removed an engorged tick (I. persulcatus) from himself after visiting Ala-Archa in June 2009. After ≈22 days, he sought care at the National Center for Infection in Bishkek for signs and symptoms consistent with viral encephalitis; he died 15 days later. We obtained 2 samples of the patient’s serum (in accordance with approved human Institutional Review Board protocols from the State University of New York at Buffalo) at 22 and 37 days postexposure. The TBEV IgG titer for the 22-day sample was 200, within reference range, but the titer at 37 days was 2,000. This rising titer strongly indicates infection with TBEV.

Conclusions

Identification of the Ala-Archa National Nature Park as a focus of TBEV transmission is noteworthy because of its proximity to the capital. This TBEV focus is unlikely to be transient because we found evidence of TBEV in small mammals and ticks in 2007 and in 2009. We also found serologic evidence of human infection in 2009. Our findings are relevant to public health because Ala-Archa is frequently visited by hikers and climbers from many parts of the world. In 2008, nearly 45,000 persons visited Ala-Archa.

A TBEV focus at 2,100 m on the north slope of the Tien Shan mountains is relevant for several reasons. One of these is the fact that the east–west Tien Shan mountain range marks the approximate southernmost distribution of I. persulcatus ticks, the vectors of the Siberian and Far-Eastern strains of TBEV (10). Likewise, the north slope of this mountain range marks the northernmost distribution of the likely reservoir species in Kyrgyzstan, A. pallipes mice. Our analysis of cytochrome b DNA sequences from these mice in Kyrgyzstan supports the hypothesis that they are recent, Late Pleistocene or Holocene epoch (<15,000 years), arrivals in the region. Haplotype divergence across all collecting localities is <1%. A tentative explanation for the TBEV focus on the northern slope at Ala-Archa is that this slope is the approximate geographic point of overlap for the distribution of I. persulcatus ticks and a suitable reservoir species, A. pallipes mice. Although A. pallipes mice have not previously been identified as a TBEV reservoir, other Apodemus spp. mice in Europe and Siberia are TBEV reservoirs. Laboratory studies have shown that, in contrast with other rodents, mice of the genus Apodemus are capable of vertical transmission (11) and nonviremic transmission of TBEV through ixodid ticks (12).

Finding TBEV-infected ticks active at these altitudes is probably not the result of climate change. Rather, we propose altitude compensation at southern latitudes as an explanation. By altitude compensation, we mean that the closer one gets to the equator, the higher the altitude that is needed for ideal transmission ecology. We suggest that TBEV transmission in Kyrgyzstan is a delicate interaction between tick larvae, tick nymphs, and reservoir rodents, analogous to the situation seen with I. ricinus ticks in central Europe (13).

Our findings provide testable hypotheses about the ecologic and physiographic factors that determine the distribution of TBEV in Kyrgyzstan. Additional understanding of these factors will aid public health responses to the zoonosis caused by this virus (14).

Mr Briggs is an MD/PhD student at the State University of New York at Buffalo, School of Medicine and Biomedical Sciences. His research interests include the effects of zoonotic viruses in central Asia.

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Acknowledgment

We greatly appreciate financial support from the UK Global Threat Reduction Program and the US Civilian Research and Development Foundation. We are also grateful to Michael Holbrook for providing plasmids containing TBEV antigens.

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References

  1. Lindenbach  BD, Thiel  H-J, Rice  CM. Flaviviridae: the viruses and their replication. In: Knipe DM, Howley PM, editors. Fields’ virology. 5th ed. Philadelphia: Wolters Kluwer Health/Lippincott Williams & Wilkins; 2007. p. 1101–52.
  2. Randolph  SE. Tick-borne encephalitis virus, ticks and humans: short-term and long-term dynamics. Curr Opin Infect Dis. 2008;21:4627. DOIPubMedGoogle Scholar
  3. Lindquist  L, Vapalahti  O. Tick-borne encephalitis. Lancet. 2008;371:186171. DOIPubMedGoogle Scholar
  4. Holzmann  H, Aberle  SW, Stiasny  K, Werner  P, Mischak  A, Zainer  B, Tick-borne encephalitis from eating goat cheese in a mountain region of Austria. Emerg Infect Dis. 2009;15:16713.PubMedGoogle Scholar
  5. Kyrgyzstan  CIA. The world factbook; 2009 [cited 2009 Dec 27]. https://www.cia.gov/library/publications/the-world-factbook/geos/kg.html
  6. Holbrook  MR, Shope  RE, Barrett  AD. Use of recombinant E protein domain III-based enzyme-linked immunosorbent assays for differentiation of tick-borne encephalitis serocomplex flaviviruses from mosquito-borne flaviviruses. J Clin Microbiol. 2004;42:410110. DOIPubMedGoogle Scholar
  7. Niedrig  M, Vaisviliene  D, Teichmann  A, Klockmann  U, Biel  SS. Comparison of six different commercial IgG-ELISA kits for the detection of TBEV-antibodies. J Clin Virol. 2001;20:17982. DOIPubMedGoogle Scholar
  8. Puchhammer-Stöckl  E, Kunz  C, Mandl  CW, Heinz  FX. Identification of tick-borne encephalitis virus ribonucleic acid in tick suspensions and in clinical specimens by a reverse transcription–nested polymerase chain reaction assay. Clin Diagn Virol. 1995;4:3216. DOIPubMedGoogle Scholar
  9. Ternovoi  VA, Kurzhukov  GP, Sokolov  YV, Ivanov  GY, Ivanisenko  VA, Loktev  AV, Tick-borne encephalitis with hemorrhagic syndrome, Novosibirsk region, Russia, 1999. Emerg Infect Dis. 2003;9:7436.PubMedGoogle Scholar
  10. Ecker  M, Allison  SL, Meixner  T, Heinz  FX. Sequence analysis and genetic classification of tick-borne encephalitis viruses from Europe and Asia. J Gen Virol. 1999;80:17985.PubMedGoogle Scholar
  11. Bakhvalova  VN, Potapova  OF, Panov  VV, Morozova  OV. Vertical transmission of tick-borne encephalitis virus between generations of adapted reservoir small rodents. Virus Res. 2009;140:1728. DOIPubMedGoogle Scholar
  12. Labuda  M, Nuttall  PA, Kozuch  O, Eleckova  E, Williams  T, Zuffova  E, Non-viraemic transmission of tick-borne encephalitis virus: a mechanism for arbovirus survival in nature. Experientia. 1993;49:8025. DOIPubMedGoogle Scholar
  13. Randolph  SE, Green  RM, Peacey  MF, Rogers  DJ. Seasonal synchrony: the key to tick-borne encephalitis foci identified by satellite data. Parasitology. 2000;121:1523. DOIPubMedGoogle Scholar
  14. Phillips  CJ. Harrington AM., Yates TL, Simpson GL, Baker RJ. Global disease surveillance, emergent disease preparedness, and national security. Lubbock (TX): Museum of Texas Tech University; 2009.

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Figures
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Cite This Article

DOI: 10.3201/eid1705.101183

Table of Contents – Volume 17, Number 5—May 2011

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Benjamin J. Briggs, 606 BRB, State University of New York, South Campus, 3435 Main St, Buffalo, NY 14214, USA

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Page created: August 08, 2011
Page updated: August 08, 2011
Page reviewed: August 08, 2011
The conclusions, findings, and opinions expressed by authors contributing to this journal do not necessarily reflect the official position of the U.S. Department of Health and Human Services, the Public Health Service, the Centers for Disease Control and Prevention, or the authors' affiliated institutions. Use of trade names is for identification only and does not imply endorsement by any of the groups named above.
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