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Ahead of Print - Molecular Characterization of African Swine Fever Virus, China, 2018 - Volume 24, Number 11—November 2018 - Emerging Infectious Diseases journal - CDC

Ahead of Print - Molecular Characterization of African Swine Fever Virus, China, 2018 - Volume 24, Number 11—November 2018 - Emerging Infectious Diseases journal - CDC



CDC - Centers for Disease Control and Prevention - CDC 24/7: Saving Lives. Protecting People.â„¢

Volume 24, Number 11—November 2018

Research Letter

Molecular Characterization of African Swine Fever Virus, China, 2018

Shengqiang Ge1, Jinming Li1, Xiaoxu Fan1, Fuxiao Liu1, Lin Li1, Qinghua Wang, Weijie Ren, Jingyue Bao, Chunju Liu, Hua Wang, Yutian Liu, Yongqiang Zhang, Tiangang Xu, Xiaodong WuComments to Author , and Zhiliang WangComments to Author 
Author affiliations: China Animal Health and Epidemiology Center, Qingdao, China

Abstract

On August 3, 2018, an outbreak of African swine fever in pigs was reported in China. We subjected a virus from an African swine fever–positive pig sample to phylogenetic analysis. This analysis showed that the causative strain belonged to the p72 genotype II and CD2v serogroup 8.
African swine fever (ASF) is a disease that is reportable to the World Health Organisation for Animal Health. This disease causes high fever, hemorrhages, ataxia, and severe depression in domestic pigs and has mortality rates approaching 100%. Its causative agent is African swine fever virus (ASFV; family Asfarviridae, genus Asfivirus), a large, enveloped, double-stranded DNA virus (1). ASF was first described in Kenya in 1921, and was introduced into the Republic of Georgia in 2007, after which it spread into other countries in eastern Europe, including Russia (2007), Ukraine (2012), Belarus (2013), Lithuania (2014), Estonia (2014), Poland (2014), Latvia (2014), Romania (2017), the Czech Republic (2017), and Hungary (2018).
During July 1–August 1, 2018, a total of 47 of 383 pigs died on a farm in the Shenbei District of Shenyang, Liaoning Province, China. Postmortem analysis performed by local veterinarians showed an ASF-typical lesion in pig spleens that were extremely swollen and severely necrotic. Other pathologic changes included hemorrhages in tonsils and lungs, marbled lesions in mandibular and mesenteric lymph nodes, and diffuse hemorrhages in a large part of gastric serosa.
We collected samples from 2 dead pigs and 6 live pigs on this farm and sent these samples to our Biosafety Level 3 laboratory for confirmation of ASFV infection. We performed a real-time PCR for ASFV as recommended by the World Health Organisation for Animal Health protocol. Results confirmed ASFV infections in China (2).
After confirmation of ASFV infection by our laboratory, we used nucleic acid extracts from an ASFV-infected sample for conventional PCR amplification with 3 pairs of primers. We amplified 3 gene fragments: a partial gene fragment of the B646L gene encoding the p72 capsid protein (3), a fragment of the EP402R gene encoding the CD2v protein (4), and a tandem repeat sequence (TRS) located between the I73R and I329L genes (5).
Thumbnail of Phylogenetic analysis of a causative virus strain (China 2018/1) of an African swine fever outbreak, China, 2018. A) p72 genotype; B) CD2v serogroup. The neighbor-joining method and Kimura 2-parameter model were used for construction of phylogenetic trees in MEGA 5.0 software (https://www.megasoftware.net/). Numbers along branches indicate bootstrap values >70% (1,000 replicates). Black circles indicate causative virus isolate from this study. Roman numerals to the right in panel
Figure. Phylogenetic analysis of a causative virus strain (China 2018/1) of an African swine fever outbreak, China, 2018. A) p72 genotype; B) CD2v serogroup. The neighbor-joining method and Kimura 2-parameter model were...
We subjected 3 amplified products to nucleotide sequencing and deposited the resulting sequences in GenBank (accession nos. MH722357, MH735142, and MH735144). We used the p72 fragment sequence for phylogenetic analysis of the genotype, and the CD2v fragment sequence for phylogenetic analysis of the serogroup (6). We constructed 2 phylogenetic trees by using MEGA 5.0 software (https://www.megasoftware.net/). These trees showed that the causative strain (China 2018/1) in this study belonged to p72 genotype II (Figure, panel A) and to CD2v serogroup 8 (Figure, panel B).
Genotype identification of ASFV often depends on partial p72 gene characterization (3). During ASF outbreaks, this genotyping approach can be used to identify possible origins of viruses and differentiate them from closely related strains (7). In this study, we classified China 2018/1 as genotype II (Figure, panel A), the sequences we obtained had extremely high homology with those of other genotype II strains, therefore suggesting the origin of China 2018/1 from a homogenotypic strain.
In addition to conventional genetic typing, serologic typing is another method for classifying ASFVs on the basis of hemadsorption inhibition (HAI). Eight ASFV serogroups have been identified (6). Moreover, HAI typing places ASFV into discrete serogroups not necessarily resolved by the p72-based genetic typing. For example, serogroup 1, 2, and 4 strains can be simultaneously classified as having the P72 genotype I (7). In this study, we found that China 2018/1 belonged to serogroup 8 as determined by phylogenetic analysis, suggesting the same HAI characteristics as those for other strains in the homoserogroup (Figure, panel B).
We compared Georgia 2007/1, which is representative of genotype II, with China 2018/1. China 2018/1 had a 10-bp additional fragment (5′-GGAATATATA-3′) that was inserted into the TRS between the I73R and I329L genes and was identical to those of the Bel13/Grodno, Ukr12/Zapo, Lt14/1490, Lt14/1482, Pol14/Sz, and Pol14/Krus strains (5).
ASF causes devastating socioeconomic consequences in the global pig industry, especially for countries with large-scale pig production and pork consumption. After the confirmation of ASF outbreak in China in August 2018, we characterized the causative strain, China 2018/1, by phylogenetic comparison with previous strains. We classified this new strain as having the p72 genotype II and 100% p72 sequence identity with several strains from eastern Europe and Africa, such as Bel13/Grodno, Voronezh 2016, Mal 2011/01, and ZIM/2015/01.
On the basis of serologic typing, we found that China 2018/1 belonged to the CD2v serogroup 8. In addition, this strain had a 10-bp additional fragment (5′-GGAATATATA-3′) in its TRS when compared with several others in the homogenotype.
Because ASFV is a large DNA virus with a stable genome, it is hardly unexpected that the sequence of China 2018/1 had extremely high homology with sequences in genotype II over a wide geographic area. However, it remains to be elucidated from where China 2018/1 was introduced into China.
Dr. Ge is a virologist at the National Research Center for Exotic Animal Diseases, Animal Health and Epidemiology Center, Qingdao, China. His primary research interest is prevention and control of exotic animal diseases.
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Acknowledgments

We thank our colleagues for assistance in collecting and transporting clinical samples.
This study was supported by the National Project for Prevention and Control of Transboundary Animal Diseases (grant no. 2017YFD0501800), the National Key Research and Development Program for the 13th Five-Year Plan, and the Ministry of Science and Technology, China.
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References

  1. Alonso  CBorca  MDixon  LRevilla  YRodriguez  FEscribano  JMIctv Report ConsortiumICTV virus taxonomy profile: Asfarviridae. J Gen Virol2018;99:6134DOIPubMed
  2. Wang  QRen  WBao  JGe  SLi  JLi  Let al. The first outbreak of African swine fever was confirmed in China [in Chinese]Journal of China Animal Health Inspection. 2018;35:19.
  3. Bastos  ADPenrith  MLCrucière  CEdrich  JLHutchings  GRoger  Fet al. Genotyping field strains of African swine fever virus by partial p72 gene characterisation. Arch Virol2003;148:693706DOIPubMed
  4. Sanna  GDei Giudici  SBacciu  DAngioi  PPGiammarioli  MDe Mia  GMet al. Improved strategy for molecular characterization of African swine fever viruses from Sardinia, based on analysis of p30, CD2V and I73R/I329L variable regions. Transbound Emerg Dis2017;64:12806DOIPubMed
  5. Gallardo  CFernández-Pinero  JPelayo  VGazaev  IMarkowska-Daniel  IPridotkas  Get al. Genetic variation among African swine fever genotype II viruses, eastern and central Europe.Emerg Infect Dis2014;20:15447DOIPubMed
  6. Malogolovkin  ABurmakina  GTulman  ERDelhon  GDiel  DGSalnikov  Net al. African swine fever virus CD2v and C-type lectin gene loci mediate serological specificity. J Gen Virol2015;96:86673DOIPubMed
  7. Malogolovkin  ABurmakina  GTitov  ISereda  AGogin  ABaryshnikova  Eet al. Comparative analysis of African swine fever virus genotypes and serogroups. Emerg Infect Dis2015;21:3125DOIPubMed
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Suggested citation for this article: Ge S, Li J, Fan X, Liu F, Li L, Wang Q, et al. Molecular characterization of African swine fever virus, China, 2018. Emerg Infect Dis. 2018 Nov [date cited]. https://doi.org/10.3201/eid2411.181274
DOI: 10.3201/eid2411.181274


1These authors contributed equally to this article.

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