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Volume 25, Number 11—November 2019
Research Letter

Tamdy Virus in Ixodid Ticks Infesting Bactrian Camels, Xinjiang, China, 2018

Author affiliations: Shandong First Medical University & Shandong Academy of Medical Sciences, Taian, China (H. Zhou, T. Hu, R. Yu, J. Li, W. Shi); Xinjiang University, Urumqi, China (Z. Ma, A. Mamuti); Chinese Academy of Sciences, Beijing, China (Y. Bi, G.F. Gao); University College Dublin, Dublin, Ireland (M.J. Carr); Hokkaido University, Sapporo, Japan (M.J. Carr); Sun Yat-sen University, Guangzhou, China (M. Shi); The University of Sydney, Sydney, New South Wales, Australia (M. Shi); Research Institute of Experimental and Clinical Medicine, Novosibirsk, Russia (K. Sharshov); Chinese Center for Disease Control and Prevention, Beijing (G.F. Gao)

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Abstract

We isolated Tamdy virus (TAMV; strain XJ01/TAMV/China/2018) from Hyalomma asiaticum ticks infesting Bactrian camels in Xinjiang, China, in 2018. The genome of the strain showed high nucleotide similarity with previously described TAMV strains from Asia. Our study highlights the potential threat of TAMV to public health in China.

Tamdy virus (TAMV) was first isolated from the tick species Hyalomma asiaticum asiaticum collected from sheep in the Tamdinsky district of the Bukhara region, Uzbekistan, in 1971 (1). Subsequently, large-scale surveillance of TAMV from Ixodidae ticks using newborn mice successfully isolated 47 TAMV strains from various tick species from Armenia, Kazakhstan, Kyrgyzstan, Turkmenistan, and Uzbekistan, highlighting both its widespread distribution and its ability to infect mammals (2). Recently, TAMV was identified in Turkey from Hyalomma spp. ticks collected from Meriones tristrami gerbils in the Middle East (3). Sequence comparison and phylogenetic analyses of full-length TAMV genomes from different subspecies of H. asiaticum ticks taxonomically classified it in the genus Nairovirus, family Bunyaviridae (4). TAMV was also detected in 1973 from a febrile patient in Kyrgyzstan (5).

In May 2018, fourteen ticks attached to 2-humped Bactrian camels (Camelus bactrianus) were collected from a camel farm in Xinjiang, China. We extracted total RNA of the ticks using the E.Z.N.A. Total RNA Kit (Omega Bio-tek, https://www.omegabiotek.com). We used a transcriptomics approach to investigate the viruses harbored by the ticks and used the BGI mRNA Library Preparation protocol according to MGIEasy mRNA Library Prep Kit (BGI, https://www.bgi.com) to construct the RNA sequencing libraries for each tick. We conducted paired-end (100-bp) sequencing of each RNA library on the BGISEQ-500RS platform (BGI). We obtained 493,090,699 raw reads and then adaptor and quality trimmed them with the Fastp program (6), resulting in a total of 492,344,756 clean reads. These reads were de novo assembled using Trinity (7) with default settings. We compared the assembled contigs using BLASTn (http://blast.ncbi.nlm.nih.gov/blast.cg) against the nucleotide database downloaded from GenBank, with an E-value cutoff set at 1 × 10−5.

We identified contigs annotated as the large (L), medium (M), and small (S) gene segments of TAMV (family Nairoviridae, genus Orthonairovirus) in 1 tick (pool 10). To confirm the assembled viral contigs, we mapped reads back to the full-length genome of the TAMV strain LEIV-1308Uz (GenBank accession nos. KP792726–8, corresponding to the L, M, and S gene segments) as reference with Bowtie2 (8) and inspected using Geneious version 11.1.5 (Biomatters, Ltd., https://www.geneious.com). After removing repetitive reads, we mapped 34,172 reads to the L gene segment (depth 252 + SD 120), 60,184 reads to the M gene segment (depth: 1186 ± 418), and 8,724 reads to the S gene segment (depth 392 + 138). The virus genome obtained comprised L segment (encoding the RNA-dependent RNA polymerase [RdRp]), 12,215 bp; M segment (encoding the glycoprotein precursor), 4,565 bp; and S segment (encoding the nucleocapsid), 2,005 bp.

Figure

Thumbnail of Identification of the Tamdy virus (TAMV) strain XJ01/TAMV/China/2018 from Hyalomma asiaticum ticks infesting Bactrian camels in Xinjiang, China, 2018, by cell culture and phylogenetic analysis. A) Light micrographs of cytopathic effects caused by TAMV infection at 11 days postinfection. Left, normal Vero cells as control; right, infected Vero cells with apparent cytopathic effects (black arrows). Original magnification ×100. B) Phylogenetic analysis of the RNA-dependent RNA polymera

Figure. Identification of the Tamdy virus (TAMV) strain XJ01/TAMV/China/2018 from Hyalomma asiaticum ticks infesting Bactrian camels in Xinjiang, China, 2018, by cell culture and phylogenetic analysis. A) Light micrographs of cytopathic effects...

We then cultured the grinding fluid supernatant corresponding to pool 10 in Vero cells in Dulbecco Modified Eagle medium. We observed apparent cytopathic effects, such as higher cell refractive index, cell shrinkage, size reduction, rounding, and shedding, in infected Vero cells at 11 days postinfection (Figure, panel A). The virus strain was named XJ01/TAMV/China/2018 (hereafter XJ01). After 2 passages, we performed further transcriptome sequencing of the first- and second-generation virus suspension from cell cultures. We assembled the complete genome sequences of XJ01 again, as described, and found that the TAMV genomes from cell cultures were identical to those from the original sample.

To confirm the genome sequence of XJ01, we designed 14 paired primers for Sanger sequencing (Appendix Table). The consensus gene sequences of Sanger sequencing of the amplified products were consistent with those from transcriptome sequencing and were deposited in GenBank (accession nos. MK757580–2). Sequence comparison revealed that XJ01 was highly similar to 3 previously described TAMV strains from Asia; sequence identities were 94.8%–94.9% for the L segment, 93.5%–94.7% for the M segment, and 95.4%–96.8% for the S segment.

Phylogenetic analysis of representative strains of the family Nairoviridae using RAxML (9) revealed that the 4 TAMV strains clustered with high bootstrap support and fell within the Orthonairovirus genus in the RdRp tree (Figure, panel B). In addition, they were closely related to several other orthonairoviruses from ticks, including Burana virus, Tacheng tick virus 1, and Pacific coast tick nairovirus in all the RdRp, glycoprotein precursor, and nucleocapsid trees and formed a small cluster in the Orthonairovirus genus (Figure, panel B; Appendix Figures 1, 2).

We also obtained the cytochrome c oxidase gene sequence of the tick and deposited it in GenBank (accession no. MK757583). A BLASTn search (https://blast.ncbi.nlm.nih.gov/Blast.cgi) revealed that the top hit was from H. asiaticum (GenBank accession no. KX882103.1) with sequence identity of 99%; this species is a widely distributed tick in China, especially in northwestern China (10).

In summary, we identified a TAMV strain from Ixodid ticks collected in Xinjiang, China, that poses a threat to public health in Xinjiang and even globally. Because of the ability of TAMV to infect mammals including humans, the lack of effective antiviral drugs and prophylactic vaccines, and the widespread distribution of its major host in China, extensive TAMV surveillance is urgently needed.

Dr. Zhou obtained her PhD in microbiology at Shandong University and now is a lecturer at Shandong First Medical University. Her research interests include viromics and novel virus discovery.

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Acknowledgment

This study was supported by the National Science and Technology Major Project (2018ZX10101004-002), the National Key Science and Technology Projects of China (2017ZX10104001-006), the Academic Promotion Plan of Shandong First Medical University & Shandong Academy of Medical Sciences, and the Strategic Priority Research Program of the Chinese Academy of Sciences (XDB29010102). W.S. was supported by the Taishan Scholars program of Shandong Province (ts201511056).

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References

  1. Lvov  DK, Sidorova  GA, Gromashevsky  VL, Kurbanov  M, Skvoztsova  LM, Gofman  YP, et al. Virus “Tamdy”—a new arbovirus, isolated in the Uzbee S.S.R. and Turkmen S.S.R. from ticks Hyalomma asiaticum asiaticum Schulee et Schlottke, 1929, and Hyalomma plumbeum plumbeum Panzer, 1796. Arch Virol. 1976;51:1521. DOIPubMedGoogle Scholar
  2. L’vov  DK, Sidorova  GA, Gromashevskiĭ  VL, Skvortsova  TM, Aristova  VA. [Isolation of Tamdy virus (Bunyaviridae) pathogenic for man from natural sources in Central Asia, Kazakhstan and Transcaucasia] [in Russian]. Vopr Virusol. 1984;29:48790.PubMedGoogle Scholar
  3. Brinkmann  A, Dinçer  E, Polat  C, Hekimoğlu  O, Hacıoğlu  S, Földes  K, et al. A metagenomic survey identifies Tamdy orthonairovirus as well as divergent phlebo-, rhabdo-, chu- and flavi-like viruses in Anatolia, Turkey. Ticks Tick Borne Dis. 2018;9:117383. DOIPubMedGoogle Scholar
  4. L’vov  DK, Al’khovskiĭ  SV, Shchelkanov  MI, Shchetinin  AM, Aristova  VA, Gitel’man  AK, et al. [Taxonomy of previously unclassified Tamdy virus (TAMV) (Bunyaviridae, Nairovirus) isolated from the Hyalomma asiaticum asiaticum Schülce et Schlottke, 1929 (Ixodidae, Hyalomminae) in the Middle East and transcaucasia] [in Russian]. Vopr Virusol. 2014;59:1522.PubMedGoogle Scholar
  5. Karas  FR, Vargina  SG, Steblyanko  SN, Kolpakov  VN, Seropolko  AA. Ecology of Tamdy virus in Kyrgystan. Proceedings of X Symposium. Ecology of viruses. Baku (Azerbaijan): Ministry of Health of Azerbaijan Republic of USSR; 1976. p. 87–88.
  6. Chen  S, Zhou  Y, Chen  Y, Gu  J. fastp: an ultra-fast all-in-one FASTQ preprocessor. Bioinformatics. 2018;34:i88490. DOIPubMedGoogle Scholar
  7. Grabherr  MG, Haas  BJ, Yassour  M, Levin  JZ, Thompson  DA, Amit  I, et al. Full-length transcriptome assembly from RNA-Seq data without a reference genome. Nat Biotechnol. 2011;29:64452. DOIPubMedGoogle Scholar
  8. Langmead  B, Salzberg  SL. Fast gapped-read alignment with Bowtie 2. Nat Methods. 2012;9:3579. DOIPubMedGoogle Scholar
  9. Stamatakis  A, Ludwig  T, Meier  H. RAxML-III: a fast program for maximum likelihood-based inference of large phylogenetic trees. Bioinformatics. 2005;21:45663. DOIPubMedGoogle Scholar
  10. Sheng  J, Jiang  M, Yang  M, Bo  X, Zhao  S, Zhang  Y, et al. Tick distribution in border regions of Northwestern China. Ticks Tick Borne Dis. 2019;10:6659. DOIPubMedGoogle Scholar

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Cite This Article

DOI: 10.3201/eid2511.190512

Original Publication Date: October 03, 2019

1These authors contributed equally to this article.

Table of Contents – Volume 25, Number 11—November 2019

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Weifeng Shi, Shandong First Medical University & Shandong Academy of Medical Sciences, Key Laboratory of Etiology and Epidemiology of Emerging Infectious Diseases in Universities of Shandong, Yingshengdonglu 2, Taian 271000, Shandong, China; ,

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Page created: October 15, 2019
Page updated: October 15, 2019
Page reviewed: October 15, 2019
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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