Scientia Agricultura Sinica ›› 2021, Vol. 54 ›› Issue (5): 1063-1072.doi: 10.3864/j.issn.0578-1752.2021.05.017

• ANIMAL SCIENCE·VETERINARY SCIENCE·RESOURCE INSECT • Previous Articles     Next Articles

Molecular Epidemiological Investigation of Porcine Group A Rotavirus in Sichuan from 2017 to 2019

Qun ZHOU1(),XiaoFei CHEN2(),RuiCi KAN1,Yu LI1,Hui CAO1,YanLing PENG3,Bin ZHANG1,4()   

  1. 1College of Life Science and Technology, Southwest University for Nationalities, Chengdu 610041
    2College of Veterinary Medicine, South China Agricultural University, Guangzhou 510642
    3Animal Husbandry Bureau of Xichang City, Xichang 615000, Sichuan
    4Key Laboratory of Qinghai-Tibetan Plateau Animal Genetic Resource Reservation and Utilization of Ministry of Education/Sichuan Province, Chengdu 610041
  • Received:2020-04-13 Accepted:2020-07-29 Online:2021-03-01 Published:2021-03-09
  • Contact: Bin ZHANG E-mail:2297248747@qq.com;chenxf-1@163.com;binovy@sina.com

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Abstract:

【Objective】The aim of this study was to investigate the prevalence and molecular characterization of porcine group A rotavirus (RVA) in large-scale pig farms in Sichuan, to provid a theoretical basis for the development for porcine RVA vaccine. 【Method】 From 2017 to 2019, the 303 samples were collected from 40 pig farms in 14 regions of Sichuan province. Prevalence of RVA was detected by real-time RT-PCR method, and RVA positive samples were typed by RT-PCR. At the same time, the whole genomes of RVA VP4 and VP7 gene were amplified from some positive samples. The genotypes of the corresponding strains were determined by RotaC2.0 classification tool. Sequence homology was analyzed by MegAlign. Phylogenetic tree was constructed by Neighbor-Joining method through MEGA 7.0. SimPlot and RDP4 softwares were applied for recombination analysis. 【Result】 Of the 303 samples examined, 32.34% (98/303, 95%CI=27.1%-37.9%) were positive for RVA. Among the 39 G types, G9 (41%) was the dominant genotype, while G4, G5, G26, and G3 were detected in 23%, 28.2%, 5.1% and 2.7%, respectively. The P[13] genotype (40.7%) was dominant among the 59 P types, followed by P[6], P[23] and P[1] in 30.5%, 23.7% and 5.1%, respectively. Furthermore, the 30 strains successfully identified the G/P combination genotype, and the dominant combination genotype was G9P[23] (23.3%), the other combinations were G4P[6] (16.7%), G9P[13] (13.3%), G5P[23] (10%), G5P[13] (10%), G9P[6] (6.7%), G26P[13] (6.7%), G4P[13] (6.7%), G4P[23] (3.3%) and G3P[13] (3.3%). Notably, the G5P[23], G4P[13], G9P[6], G26P[13] and G4P[23] were first identified in China. In addition, the recombination analysis showed that four strains had recombination on VP7 or VP4 genes. 【Conclusion】 The results demonstrated that the prevalence of RVA in diarrhea piglet feces was high and the genotypes were complex in Sichuan. The dominant genotype of RVAs was G9P[23]. The results of this study enriched the epidemiological data of RVA and provided an important reference for the prevention and control of porcine RVA in Sichuan province.

Key words: porcine group A rotavirus, molecular epidemiology, genomic research, recombination

Table 1

RVA infection rate and genotype distribution in some farms in Sichuan Province"

地区
Region		 猪场个数
Farm		 样本数
Number of samples		 RVA阳性数
Positive number		 G型
G genotype		 P 型
P genotype		 G/P组合型
G/P combination genotype
眉山Meishan 6 62 14 G3,G4,G9 P[1],P[13],P[23] G3P[13],G4P[23],G9P[23],G9P[13]
绵阳Mianyang 5 34 24 G5,G9 P[23] G9P[23],G5P[23]
泸州Luzhou 5 13 3 G9 P[1],P[13] G9P[13]
西昌Xichang 5 25 8 P[1],P[13]
成都Chengdu 4 49 9 G9 P[13],P[23] G9P[13],G9P[23]
雅安Yaan 4 13 3 G9 P[13] G9P[13]
内江Neijiang 3 18 2 G9 P[6] G9P[6]
宜宾Yibin 2 7 5 G5 P[13],P[23] G5P[23],G5P[13]
乐山Leshan 1 4 2 G4 P[13] G4P[13]
遂宁Suining 1 18 4 G9,G26 P[13],P[23] G9P[23],G26P[13]
南充Nanchong 1 3 3 G9 P[13] G9P[13]
资阳Ziyang 1 18 2 G4 P[6] G4P[6]
广元Guangyuan 1 36 19 G4,G5 P[6],P[13] G4P[6],G5P[13]
攀枝花Panzhihua 1 3 0
共计Total 40 303 98

Fig. 1

Phylogenetic tree based on RVA VP7 sequences (790 bp) constructed using the neighbor-joining (NJ) method ●:本研究中的毒株 Strains in this study。下同 The same as below ▲:右侧G9、G4和G5进化树的缩略图 Thumbnails of the right G9, G4 and G5 phylogenetic trees"

Table 2

RVA VP7 gene homology analysis"

毒株
Strain		 同源性最高的毒株
Strain with highest homology		 国家及宿主
Country and host		 年份
Year		 同源性
Homology
SCMS-71 SCQL-5-2(MG066590) 中国/猪源China/pig 2018 99.9%
SCLS-18,SCLS-20 MOZ/21205(KP222851) 莫桑比克/人源Mozambique/human 2011 96.9%,97.4%
SCZY-165,SCZY-166 ZT-11D-T101(KM247280) 中国/人源China/human 2011 98.9%,98.3%
SCMS-69 GUB71(AB573647) 日本/猪源Japan/pig 2006 95.6%
SCGY-193,SCGY-198,SCGY-199,SCGY-201 R1954(KF726066) 中国/人源China/human 2013 95.1%
6株G5型(SCJY),SCGY-192
6 strains of G5 (SCJY)		 HLJqqhe-1(JX498960) 中国/猪源China/pig 2011 97.6%-98.1%
SCYB-Y1,SCYB-Y2 LL3354(EF159575) 中国/人源China/human 2000 93.9%,94.2%
SCYB-C2,SCYB-C3 103-P-001-1-0126(MK227837) 中国/猪源China/pig 2014 93.7%
4株G9型(SCJY)
4 strains of G9 (SCJY)		 LLP48(KJ126835) 中国/猪源China/pig 2008 97.4%-97.6%
SCRS-142,SCSN-96 HBHP(KX831114) 中国/猪源China/pig 2016 98.3%
SCDY-219 GXqz-2(JX498942) 中国/猪源China/pig 2011 97.5%
SCLZ-FB,SCYA-C7 ISO31(DQ117937) 印度/人源India/human 2008 96.2%,96.5%
SCMY-28,SCMS-153,SCDY-211,
SCDY-210,SCDY-209		 CQ(KX831100) 中国/猪源China/pig 2016 95.9%-97.1%
SCSN-93,SCSN-94 07N1760(LC208008) 尼泊尔/猪源Nepal/pig 2007 96.1%
SCLJ-C18,SCLJ-C20 TA-1-2(KT820779) 中国/猪源China/pig 2014 85.1%

Fig. 2

Phylogenetic tree based on RVA VP4 sequences (800 bp) constructed using the neighbor-joining (NJ) method ▲:Thumbnails of the right P[6], P[13] and P[23] phylogenetic trees"

Table 3

RVA VP4 gene homology analysis"

毒株
Strain		 同源性最高的毒株
Strain with highest homology		 国家及宿主
Country and host		 年份
Year		 同源性
Homology
SCMS-152,SCLZ-35,SCXC-83 A5-10(LC133517) 泰国/牛源Thailand/cow 1988 93.4%
15株P[6]型(SCGY)15 strains of P[6] (SCGY) GUB88(AB573872) 日本/猪源Japan/pig 2006 92.6%-98.6%
SCLJ-C18,SCLJ-C20,SCZY-165 R1207(LC389888) 斯里兰卡/人源Sri Lanka/human 2009 95.7%-98.6%
SCXC-89,SCXC-85,SCXC-84,SCRS-142,SCGY-192 CMP178(DQ536362) 泰国/猪源Thailand/pig 2008 94.5%-96.8%
SCYB-Y1,SCQL-54,SCQL-55,SCMS-71,SCDY-91 SCMY(MH320795) 中国/猪源China/pig 2018 79.1%-98.8%
SCLZ-FB FGP36(AB573878) 日本/猪源Japan/pig 2009 95.1%
SCSN-93,SCSN-94 LNCY(MF462324) 中国/猪源China/pig 2016 98.3%
SCYA-C7,SCRS-131,SCLS-18,SCLS-20,
SCYA-H2,SCYA-H3,SCXC-90,SCYB-Y2		 SWU-1C(MK410284) 中国/猪源China/pig 2018 92.5%-97.7%
SCDY-210,SCSN-140,SCMS-151 SCLS-R3(MK597985) 中国/人源China/human 2018 92.6%-97.0%
SCYB-C2,SCYB-C3 14175-24(KX363359) 越南/猪源Viet Nam/pig 2012 95.3%
SCSN-96 SC11(MH624176) 中国/猪源China/pig 2017 97.4%
SCMS-153,SCMS-68,SCMS-69,SCDY-211,
7株P[23]型(SCJY)7 strains of P[23] (SCJY)		 HLJ/15/1(KU886316) 中国/猪源China/pig 2015 92.1-96.4%

Fig. 3

Similarity analysis of recombinant sequence of RVA/Pig/CHN/SCLJ/C20/2019 strain and RVA/Pig/CHN/SCYB/Y1/2019 strain The vertical axis indicates the similarity (%) of nucleotide sequences between the query strain and other reference strains, the horizontal axis indicates the nucleotide positions. The recombinant region A, B and C of VP7 gene of RVA/Pig/CHN/SCLJ/C20/2019 strain was analyzed by Simplot software, the phylogenetic tree based on recombination region A, B and C. The recombinant region D and E of VP4 gene of RVA/Pig/CHN/SCYB/Y1/2019 strain was analyzed by Simplot software, the phylogenetic tree based on recombination region D and E"

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