Molecular characterization of bovine leukemia virus reveals existence of genotype 4 in Chinese dairy cattle

Bovine leukemia virus (BLV) causes enzootic bovine leucosis and is widely spread worldwide, except several European countries, Australia and New Zealand. Although BLV is highly prevalent in China, information about the genetic diversity and evolutionary dynamics of BLV among Chinese dairy herds is still lacking. To determine the genetic variability of BLV, 219 cows from four cities of Ningxia province of China were screened for BLV infection by fluorescence resonance energy transfer (FRET)-PCR and sequencing, 16 selected positive samples were subjected to molecular characterization. Phylogenetic analysis using the neighbor-joining (NJ) method on complete sequences of envelope (env) gene of BLV obtained from China and those available in GenBank (representing BLV genotypes 1–10) revealed that those Chinese strains belonged to genotypes 4 and 6. Totally, 23 mutations were identified and 16 of them were determined to be unique mutations among Chinese strains. Alignment of the deduced amino acid sequences demonstrated six mutations in glycoprotein 51 (gp51) and three mutations in glycoprotein 30 (gp30) located in the identified neutralizing domain (ND), CD8⁺ T cell epitope, E-epitope, B-epitope, gp51N12 and cytoplasmic domain of transmembrane protein. This study reported for the first time the BLV genotype 4 in China, and further studies are warranted to compare its immunogenicity and pathogenicity with other BLV genotypes.

Bovine leukemia virus (BLV) is the causative agent of enzootic bovine leucosis (EBL), and approximately 30% of infected cattle develop persistent lymphocytosis (PL) while a small percentage of infected cattle die from malignant lymphoma. In recent years, a variety of methods have been applied for BLV genotyping [1,2,3]. Due to the biological functions, most of studies have primarily focused on the env gene. To date, at least 11 genotypes of BLV have been described based on the genetic polymorphism of the env gene [4, 5]. Previous studies demonstrated that BLV was widely spread among dairy herds in China, and genotypes 6, 10 and 11 existed in Chinese dairy or yak herds [6, 7].

From November 2018 to January 2019, bovine whole blood samples (n = 219) from four cities (Shizuishan, Yinchuan, Wuzhong and Zhongwei) of Ningxia province were submitted to Yangzhou University College of Veterinary Medicine for BLV identification. All samples were freshly collected in ethylenediaminetetraacetic acid (EDTA) blood collection tubes by Center for Animal Disease Control and Prevention of Ningxia province, and delivered on ice with next-day delivery. DNA was extracted from whole blood samples using commercial kit as previously described [8]. The FRET-qPCR targeting BLV pol gene (forward primer = 5′-CCTCAATTCCCTTTAAACTAGAACG-3′; reverse primer = 5′-ATGGGCTTTGTAAGAGCATTTGTA-3′; anchor probe = 5′-GACGGGCCAGGCAATAATCCAGT-(6-FAM)-3′; reporter probe = 5′-(LCRed640)-TTCCCGGTACGGAAACCAAATGG-phosphate-3′) was performed following the protocol previous described [9].In total, forty samples were identified to be positive from 219 whole blood samples. Copy numbers of BLV in positive cows ranged from 20 copies/ ml of whole blood to 362,936 copies/ ml of whole blood (mean 19,134 copies/ ml of whole blood and median 35 copies/ ml of whole blood) (Table 1), and those above 130 copies/ ml (n = 16) were further identified for genotyping based on the diversity of env gene.

Partial sequence of BLV env gene were amplified with an in-house regular PCR [6]. Amplicons were gel purified with the QIAquick Gel Extraction Kit and sequenced with both forward and reverse primers at the GenScript Biotech Corp. (Nanjing, China). Sequence data (PCR products based on the forward and reverse primers) obtained in this study were assembled with DNASTAR Lasergen 15.2 (DNASTAR Inc., Madison, WI) and aligned using CLUSTAL W in MEGA 7.0 (MEGA, Pennsylvania State University, University Park) along with those of BLV strains found on GenBank from around the world. A neighbor-joining (NJ) phylogenetic tree was constructed using the Tamura-Nei model [3, 10] and the robustness of clusters was assessed by bootstrapping 1,000 replicates. Maximum-likelihood (ML) phylogenetic analysis was performed to confirm the results (Additional file 1 Figure S1).

Those sequences obtained in this study that were not identical to each other were submitted to GenBank with the GenBank accession numbers: MK820044 and MK840875-MK840880. A neighbor-joining phylogenetic tree based on the env gene complete sequences (1,548 bp) of the Chinese strains and 37 reference strains representing BLV genotypes 1 to 10 from 14 countries demonstrated that three Chinese strains (MK820044, MK840877 and MK840879) belonged to genotype 4 and the remaining four (MK840875, MK840876, MK840878 and MK840880) belonged to genotype 6 (Fig. 1).

Neighbor-joining phylogenetic tree based on BLV env gene complete sequences (1548 bp) from China and around the world. Strains identified in our study in China are identified with filled circles (●) for genotype 4 (in red) and open circles (○) for genotype 6 (in green). Genotypes shown on the right are according to Yang et al. [6]. The numbers at the branches show bootstrap support (1000 replicates). The bar at the bottom of the figure denotes distance

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For those three Chinese strains clustered into BLV genotype 4, the mean distance of the env nucleotides and the deduced amino acid (AA) were 0.003 ± 0.001 and 0.008 ± 0.004 between these strains, respectively (Table 2). Compared with the BLV strains obtained from GenBank representing BLV genotypes 1 to 10, the Chinese strains had between 0.014 ± 0.002 and 0.038 ± 0.005 nucleotide distance. Similarly, the Chinese strains had between 0.012 ± 0.003 and 0.037 ± 0.008 deduced AA distance compared with these reference strains (Table 2). The distance of nucleotide and deduced AA indicated that these three Chinese BLV strains were mostly similar to genotype 4 but distinct from genotype 5.

For the remaining four strains clustered into BLV genotype 6, the mean distance of the env nucleotides and the deduced AA were 0.004 ± 0.001 and 0.002 ± 0.002, respectively (Table 2). Compared with the BLV strains obtained from GenBank, the Chinese strains had nucleotide distance between 0.020 ± 0.003 and 0.046 ± 0.005. Similarly, the Chinese strains had between 0.008 ± 0.003 and 0.037 ± 0.008 deduced AA distance compared with those reference strains (Table 2). The distance of nucleotide and deduced AA indicated that the three Chinese BLV strains were mostly similar to genotype 6 but distinct from genotype 5.

Although 10 genotypes of BLV have been discovered around the world, there is little information on genetic diversity of BLV among Chinese dairy herds [11], until BLV genotype 6 was firstly identified in Yancheng, Shanghai, Yangzhou, Bengbu and Tianjin in 2019 [6]. The present study revealed the existence of BLV genotype 4 in China for the first time. When compared with the reference sequences representing all 10 BLV genotypes deposited in GenBank, we found that our Chinese isolates had a total of 23 mutations in complete env gene. Among them, fourteen were synonymous mutations (T216C, C294T, C390A, C411T, A450G, T456C, C546T, T603C, G621A, G756A, G972C, T1194C, G1296A and C1362A) and the remaining nine were nonsynonymous mutations (G178A, C445G, G461A, G566A, T599G, T685C, C998A, C1003A and T1378G). Interestingly, the Chinese strains of BLV genotype 4 and genotype 6 have 12 and 11 mutations, respectively on the env gene that was not shared between the two groups (Fig. 2). The distance between BLV genotype 4 and 6 was 0.036 ± 0.005 (nucleotide) and 0.020 ± 0.005 (AA). When compared with the 10 reference sequences and all Chinese sequences available in the GenBank database, 16 of the mutations (G178A, T216C, C390A, C445G, G461A, T599G, T603C, T685C, G756A, G972C, C998A, C1003A, T1194C, G1296A, C1362A and T1378G) were identified as unique mutations (Additional file 2 Figure S2-A and S2-B).

Alignment of full-length of BLV env gene nucleotide sequences (1548 bp) between sequences obtained in this study together with 10 reference sequences obtained in the GenBank database. Strains identified in this study are in red (cluster into genotype 4) and green (cluster into genotype 6). Numbers above the sequences are nucleotide number indicated by the env gene of AB934282. The countries of the strains are marked with abbreviations in parentheses to the right of the GenBank accession numbers. Dots indicate nucleotides identical to the reference sequences. The mark above the square frames indicate mutations for our isolates of BLV genotype 4 (▼) and genotype 6 (▽). The BLV reference strains from GenBank have accession numbers AF933703 (G1), AF257515 (G2), EF065647 (G3), JN695878 (G4), EF065635 (G5), LC080656 (G6), KF801457 (G7), JQ675759 (G8), LC080659 (G9), and LC154066 (G10). The seven Chinese strains from this study have the accession numbers MK820044 and MK840875-MK840880. JPN = Japan; CHN = China; BRA = Brazil; ARG = Argentina; USA = United States of America; RUS = Russia; CRC = Costa Rica; PAR = Paraguay; MDA = Moldova; BOL = Bolivia; MYA = Myanmar

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Among all the nonsynonymous mutations, seven of them (G178A, G461A, T599G, T685C, C998A, C1003A and T1378G) were observed in single isolate and the remaining two (C445G and G566A) were existed in three or four isolates. Alignment of deduced amino acid sequences demonstrated that six mutations (D60N, L149 V, G154E, R189N, L200R and Y229H) were in glycoprotein 51 (gp51) and three mutations (T333 N, L335 M and L460 V) were in glycoprotein 30 (gp30), distributing respectively in the neutralizing domain 2, CD8⁺ T cell epitope, E-epitope, B-epitope, gp51N12 and cytoplasmic domain of the transmembrane protein [12,13,14] (Fig. 3).

Alignment of full-length of BLV env gene amino acid sequences (515 AA) between Chinese and reference strains. Chinese strains identified in this study are in red (cluster into genotype 4) and green (cluster into genotype 6). Numbers above the sequences are AA residue number indicated by the env gene of AB934282. The countries of the strains are marked with abbreviations in parentheses to the right of the GenBank accession numbers. Dots indicate amino acid identical to the reference sequence. Labeled lines and ▼ indicate the position of identified glycoproteins, conformational epitope (G), linear epitopes (A, B, D and E), CD4⁺ and CD8⁺ T cell epitopes, gp51N5, gp51N11 and gp51N12, peptides, neutralization domains (ND1 and ND2) and cytoplasmic domain of transmembrane protein. The BLV reference strains from GenBank have accession numbers AF933703 (G1), AF257515 (G2), EF065647 (G3), JN695878 (G4), EF065635 (G5), LC080656 (G6), KF801457 (G7), JQ675759 (G8), LC080659 (G9), and LC154066 (G10). The seven Chinese strains from this study have the accession numbers MK820044 and MK840875-MK840880. JPN = Japan; CHN = China; BRA = Brazil; ARG = Argentina; USA = United States of America; RUS = Russia; CRC = Costa Rica; PAR = Paraguay; MDA = Moldova; BOL = Bolivia; MYA = Myanmar

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This study investigated the prevalence and genetic variability of BLV and identified the BLV genotype 4 in China for the first time. Together with our previous study [6] and studies conducted by Wang and Yu in 2018 and 2019 [5, 7], BLV genotypes 1, 4, 6 and 10 were present in dairy cattle or yaks in China. BLV genotype 4 is the second most common genotype prevalent worldwide and was identified in Mongolia in 2016 [2]. The cow trade between China and Mongolia might contributed to the spread of BLV between the two countries. This study will help us to better understand the genetic diversity of BLV in China. However, further studies are needed to define the immunogenicity and pathogenicity between different genotypes of BLV.

The sequences of full-length envelope gene generated in this study have been deposited in GenBank under the accession numbers MK820044 and MK840875-MK840880.

AA:

amino acid

ARG:

Argentina

BLV:

Bovine leukemia virus

BOL:

Bolivia

BRA:

Brazil

CHN:

China

CRC:

Costa Rica

EBL:

Enzootic bovine leucosis

EDTA:

Ethylenediaminetetraacetic acid

Env:

envelope

FRET:

Fluorescence resonance energy transfer

gp30:

glycoprotein 30

gp51:

glycoprotein 51

JPN:

Japan

MDA:

Moldova

ML:

Maximum likelihood

MYA:

Myanmar

ND:

Neutralizing domain

NJ:

Neighbor-joining

PAR:

Paraguay

PL:

Persistent lymphocytosis

RUS:

Russia

USA:

United States of America

We thank Jun Ma and Haining Zhou (Center for Animal Disease Control and Prevention of Ningxia province) for dairy whole blood sample collection.

This study was supported by China Postdoctoral Science Foundation (2019 M650126), Basic Research Program of Jiangsu Province and the Priority Academic Program Development of Jiangsu Higher Education Institutions (PAPD).

1. Yi Yang and Lina Chen contributed equally to this work.

Authors and Affiliations

1. Jiangsu Co-innovation Center for Prevention and Control of Important Animal Infectious Diseases and Zoonoses; College of Veterinary Medicine, Yangzhou University, Yangzhou, 225009, Jiangsu, China

   Yi Yang, Lina Chen, Maoli Dong, Wenjiang Huang, Xiaoli Hao, Yalan Peng, Zaicheng Gong, Aijian Qin & Shaobin Shang

2. International Corporation Laboratory of Agriculture and Agricultural Products Safety, Yangzhou University, Yangzhou, 225009, Jiangsu, China

   Yi Yang, Aijian Qin, Shaobin Shang & Zhangping Yang

3. Victor Pharmaceutical Company of Limited Liability, Zhenjiang, 212132, Jiangsu, China

   Wenjiang Huang

4. College of Animal Science and Technology, Yangzhou University, Yangzhou, 225009, Jiangsu, China

   Zhangping Yang

Contributions

SS, ZY, YY, WH and AQ conceived and designed the study. LC, MD, XH, YP and ZG performed the experiments. YY analyzed the epidemiological data. YY and SS wrote the manuscript. All authors read and approved the final version of the manuscript.

Corresponding authors

Correspondence to Shaobin Shang or Zhangping Yang.

Ethics approval and consent to participate

Protocols for the collection of samples in this study were reviewed and approved by the Institutional Animal Care and Use Committee of Yangzhou University College of Veterinary Medicine.

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

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