Strawberry Mottle Virus Isolated in Fujian: Complete Genome Sequence and Molecular Variation

doi:10.11924/j.issn.1000-6850.casb2021-0359

Abstract

Abstract:

To analyze the molecular variation and genetic diversity of strawberry mottle virus (SMoV), high-throughput sequencing (HTS), RT-PCR combined with 3ʹ and 5ʹ RACE were used to obtain the complete genome sequence of SMoV Fujian isolate. The results showed that RNA1 and RNA2 of SMoV consisted of 7034 nt and 6354 nt, and both contained one large ORF, encoding polyprotein P1 and P2, respectively. The homology of SMoV Fujian isolate and other fifteen SMoV isolates was analyzed. The nucleotide and amino acid homology of RNA1 was 79.2%-96.8% and 89.0%-99.5%, respectively. The nucleotide and amino acid homology of RNA2 was 77.9%-97.8% and 89.9%-98.9%, respectively. Among the encoding proteins of SMoV Fujian isolate, only the viral genome-linked protein was the most conserved, the nucleotide and amino acid sequences of other proteins were variable compared to other 15 SMoV isolates. The Fujian isolate and some other Chinese isolates are in a big branch, and most closely related to Chinese isolate DGHY3. The genomic structure of Fujian isolate is consistent with other SMoV isolates. Nucleotide sequence and amino acid sequence of Fujian isolate have obvious molecular variation. Fujian isolate and the other Chinese isolates have abundant diversity, and there is geographical relativity in evolution.

Key words: strawberry mottle virus, high-throughput sequencing, complete genome sequence, molecular variation, phylogenetic tree analysis

CLC Number:

S432.4+1

CHEN Dao, WANG Xin, JIANG Shan, ZHANG Jie, WU Zujian, DING Xinlun. Strawberry Mottle Virus Isolated in Fujian: Complete Genome Sequence and Molecular Variation[J]. Chinese Agricultural Science Bulletin, 2022, 38(6): 94-101.

Figures/Tables 5

References 26

[1]	ALEXANDER V K, INDRANIL D, MARC F, et al. ICTV virus taxonomy profile: Secoviridae[J]. Journal of general virology, 2017, 98:529-531. doi: 10.1099/jgv.0.000779 URL
[2]	FRAZIER N W, SYLVESTER E S. Half-lives of transmissibility of two aphid-borne viruses[J]. Virology, 1960, 12(2):233-244. doi: 10.1016/0042-6822(60)90197-5 URL
[3]	韦石泉, 吴元华. 中国草莓斑驳病毒研究鉴定[J]. 植物病理学报, 1994, 24(4):293-298.
[4]	FREEMAN J A, MELLOR F C. Influence of latent viruses on vigor, yield and quality of British Sovereign strawberries[J]. Canadian journal of plant science, 1962, 42:602-610. doi: 10.4141/cjps62-103 URL
[5]	MARTIN L, CONVERSE R. Influence of recent and chronic virus infections on strawberry growth and yield[J]. Phytopathology, 1977, 67:573-575.
[6]	MARTIN R R, TZANETAKIS I E. Characterization and recent advances in detection of strawberry viruses[J]. Plant disease, 2006, 90:384-396. doi: 10.1094/PD-90-0384 URL
[7]	王国平, 刘福昌, 国际翔. 中国草莓主栽区病毒种类的鉴定[J]. 植物病理学报, 1991, 21(1):9-14.
[8]	却志群. 草莓斑驳病毒的RT-PCR技术检测[J]. 北方园艺, 2012, 7:132-134.
[9]	朱海生, 花秀凤, 陈敏氡, 等. 四种草莓病毒SMoV、SVBV、SCV、SMYEV多重RT-PCR检测[J]. 核农学报, 2013, 11:1630-1635.
[10]	褚明昕, 魏然, 席昕, 等. 北京地区不同草莓品种5种主要病毒的检测[A].见:中国植物病理学会2017年学术年会论文集[C]. 北京: 中国农业出版社, 2017.
[11]	陈道, 丁新伦, 张洁, 等. 福建省六种草莓病毒的分子检测[J]. 植物保护学报, 2018, 45(6):1433-1434.
[12]	杨波, 赵宝龙, 郝小军, 等. 新疆地区四种草莓病毒病原的检测[J]. 新疆农业科学, 2018, 55(9):1689-1697. doi: 10.6048/j.issn.1001-4330.2018.09.015
[13]	韩晓玉, 陈思宇, 李刚, 等. 河南省草莓病毒病病原的鉴定及5种草莓病毒多重PCR体系的建立[J]. 植物保护学报, 2020, 47(1):219-220.
[14]	THOMPSON J R, LEONE G, LINDNER J L, et al. Characterization and complete nucleotide sequence of strawberry mottle virus: a tentative member of a new family of bipartite plant picorna-like viruses[J]. Journal of general virology, 2002, 83:229-239. doi: 10.1099/0022-1317-83-1-229 URL
[15]	BHAGWAT B, DICKISON V, DING X, et al. Genome sequence analysis of five Canadian isolates of strawberry mottle virus reveals extensive intra-species diversity and a longer RNA2 with increased coding capacity compared to a previously characterized European isolate[J]. Archive of virology, 2016, 161:1657-1663. doi: 10.1007/s00705-016-2799-6 URL
[16]	WANG W Q, IDEI S, FUKUDA R, et al. First report of the complete genome sequences of strawberry mottle virus isolated in Japan[J]. Journal of General plant pathology, 2021.doi: 10.1007/s10327-021-00981-3.
[17]	MANN K S, WALKER M, SANFACON H. Identification of cleavage sites recognized by the 3C-like cysteine protease within the two polyproteins of strawberry mottle virus[J]. Frontiers in microbiology, 2017.doi: 10.3389/fmicb.2017.00745.
[18]	MANN K S, CHISHOLM J, SANFAÇON H. Strawberry mottle virus (family secoviridae, order picornavirales) encodes a novel glutamic protease to process the rna2 polyprotein at two cleavage sites[J]. Journal of virology, 2019.doi: 10.1128/JVI.01679-18.
[19]	THOMPSON J R, JELKMANN W. The detection and variation of Strawberry mottle virus[J]. Plant disease, 2003, 87(4):385-390. doi: 10.1094/PDIS.2003.87.4.385 URL
[20]	杨洪一, 李丽丽, 代红艳, 等. 草莓斑驳病毒分子变异及PCR 检测技术研究[J]. 中国农业科学, 2008, 41(7):1983-1988.
[21]	CIEŚLIŃSKA M. Genetic diversity of seven strawberry mottle virus isolates in Poland[J]. The plant pathology journal, 2019, 35(4):389-392. doi: 10.5423/PPJ.NT.12.2018.0306 URL
[22]	MARTIN M. Cutadapt removes adapter sequences from high-throughput sequencing reads[J]. EMBnet.journal, 2011, 17(1):10.
[23]	LANGMEAD B, SALZBERG S L. Fast gapped-read alignment with Bowtie 2[J]. Nature methods, 2012, 9(4):357-359. doi: 10.1038/nmeth.1923 URL
[24]	ZERBINO D R, BIRNEY E. Velvet: algorithms for de novo short read assembly using de Bruijn graphs[J]. Genome research, 2008, 18:821-829. doi: 10.1101/gr.074492.107 URL
[25]	杨洪一, 杜国栋, 代红艳, 等. 利用内标为基础的RT-PCR技术检测草莓斑驳病毒[J]. 植物病理学报, 2005, 2:116-122.
[26]	李丽丽, 杨洪一. 草莓斑驳病毒的分子杂交检测[J]. 湖南农业大学学报:自然科学版, 2014, 40(3):273-276.

引物名称	引物序列	退火温度/℃
RNA1-1	F:AGTTCATCGCTCTCACTGAGGTG;R:GTGAAAGGACACATGCGCGTGCC	57
RNA1-2	F:ACATTGCGACGAACTTCCGAAG;R:ATTCGAGTTCATCGCTCTCAC	52
RNA1-3	F:GGCACGCGCATGTGTCCTTTCAC;R:GAACCTGTGCAAGCCTTTGCCAT	57
RNA1-4	F:CAGGTCTTGGATTTGAATGATTC;R:GACAATGGCAGTTCTACTGGC	52
RNA1-5	F:GCCAGTAGAACTGCCATTGTC;R:ATAAACCGGCCTTATCATAAGC	51
RNA1-6	F:GCTTATGATAAGGCCGGTTTAT;R:GCTGAAGTGGGTCACTACTCCAC	52
race1-3	GATTACGCCAAGCTTACACTGGTCTCGGGATGTTGACCGC	63
race1-5	GATTACGCCAAGCTTTGCCACCCTGTTCAACACATTGTG	57
RNA2-1	F:TGGATTGTCCTTCGTCACTG;R:ACAGGCTAACACCATCGACACTAG	52
RNA2-2	F:CTAGTGTCGATGGTGTTAGCCTGT;R:ATATCAGCATCCTTCTGACCACA	53
RNA2-3	F:TGTGGTCAGAAGGATGCTGATAT;R:ACAGGACCCTTGGAATGGTCAT	53
RNA2-4	F:ATGACCATTCCAAGGGTCCTGT;R:TCGGTTCACGTCCTAGTCTCAC	55
race2-3	GATTACGCCAAGCTTTGGCAGTCTTCCATCCTGGTGCCCT	63
race2-5	GATTACGCCAAGCTTGTGTCAAAGGAATGGGTGATATTGAG	58

引物名称	引物序列	退火温度/℃
RNA1-1	F:AGTTCATCGCTCTCACTGAGGTG;R:GTGAAAGGACACATGCGCGTGCC	57
RNA1-2	F:ACATTGCGACGAACTTCCGAAG;R:ATTCGAGTTCATCGCTCTCAC	52
RNA1-3	F:GGCACGCGCATGTGTCCTTTCAC;R:GAACCTGTGCAAGCCTTTGCCAT	57
RNA1-4	F:CAGGTCTTGGATTTGAATGATTC;R:GACAATGGCAGTTCTACTGGC	52
RNA1-5	F:GCCAGTAGAACTGCCATTGTC;R:ATAAACCGGCCTTATCATAAGC	51
RNA1-6	F:GCTTATGATAAGGCCGGTTTAT;R:GCTGAAGTGGGTCACTACTCCAC	52
race1-3	GATTACGCCAAGCTTACACTGGTCTCGGGATGTTGACCGC	63
race1-5	GATTACGCCAAGCTTTGCCACCCTGTTCAACACATTGTG	57
RNA2-1	F:TGGATTGTCCTTCGTCACTG;R:ACAGGCTAACACCATCGACACTAG	52
RNA2-2	F:CTAGTGTCGATGGTGTTAGCCTGT;R:ATATCAGCATCCTTCTGACCACA	53
RNA2-3	F:TGTGGTCAGAAGGATGCTGATAT;R:ACAGGACCCTTGGAATGGTCAT	53
RNA2-4	F:ATGACCATTCCAAGGGTCCTGT;R:TCGGTTCACGTCCTAGTCTCAC	55
race2-3	GATTACGCCAAGCTTTGGCAGTCTTCCATCCTGGTGCCCT	63
race2-5	GATTACGCCAAGCTTGTGTCAAAGGAATGGGTGATATTGAG	58

分离物名称	样品来源	登录号
FuJian	中国福建China	MW383501 / MW383502
DGHY3	中国China	MT070747 / MT070752
DGHY21	中国China	MT070748 / MT070753
BJMX7	中国China	MT070751 / MT070756
SDHY1	中国China	MT070749 / MT070754
SDHY5	中国China	MT070750 / MT070755
NSper17	加拿大Canada	KU200458 / KU200459
NSper3	加拿大Canada	KU200456 / KU200457
NSper51	加拿大Canada	KU200460 / KU200461
NB926	加拿大Canada	KU200453 / KU200454
Ontario	加拿大Canada	KU177218 / KU177219
Simcoe	加拿大Canada	MH746440 / MH746441
1134	荷兰Netherlands,NL	AJ311875 / AJ311876
SMoV_RNA1_A	捷克The Czech Republic,CZ	MH013322 / MH013325
SMoV_RNA1_B	捷克The Czech Republic	MH013323 / MH013326
SMoV_RNA1_C	捷克The Czech Republic	MH013324 / MH013327
DGHY17	中国China	MT085786
DGHY10	中国China	MT085782
DGHY25B	中国China	MT085791
DGHY11A	中国China	MT085783
DGHY20B	中国China	MT085788
DGHY20A	中国China	MT085787
DGHY26	中国China	MT085792
DGHY11B	中国China	MT085784
DGHY24	中国China	MT085789
DGHY25A	中国China	MT085790
DGHY16	中国China	MT085785
DGHY9	中国China	MT085781
IRNS69	伊朗 Iran	KT864988
IRNS20	伊朗Iran	KT864987
CN1	中国China	AY937262
SDHY32B	中国China	MT085795
SDHY31	中国China	MT085793
SDHY33	中国China	MT085796
SDHY32A	中国China	MT085794
1278	荷兰Netherlands	AJ496145
1509/4	波兰Poland,PL	AJ496147
167	波兰Poland	AJ496148
197/3A	捷克The Czech Republic	AJ496149
3CH	智利Chile	AJ496151
ST	德国Germany,GER	AJ496154
HD	德国Germany	AJ496153
9032.001M	美国United States,USA	AJ496152

分离物名称	样品来源	登录号
FuJian	中国福建China	MW383501 / MW383502
DGHY3	中国China	MT070747 / MT070752
DGHY21	中国China	MT070748 / MT070753
BJMX7	中国China	MT070751 / MT070756
SDHY1	中国China	MT070749 / MT070754
SDHY5	中国China	MT070750 / MT070755
NSper17	加拿大Canada	KU200458 / KU200459
NSper3	加拿大Canada	KU200456 / KU200457
NSper51	加拿大Canada	KU200460 / KU200461
NB926	加拿大Canada	KU200453 / KU200454
Ontario	加拿大Canada	KU177218 / KU177219
Simcoe	加拿大Canada	MH746440 / MH746441
1134	荷兰Netherlands,NL	AJ311875 / AJ311876
SMoV_RNA1_A	捷克The Czech Republic,CZ	MH013322 / MH013325
SMoV_RNA1_B	捷克The Czech Republic	MH013323 / MH013326
SMoV_RNA1_C	捷克The Czech Republic	MH013324 / MH013327
DGHY17	中国China	MT085786
DGHY10	中国China	MT085782
DGHY25B	中国China	MT085791
DGHY11A	中国China	MT085783
DGHY20B	中国China	MT085788
DGHY20A	中国China	MT085787
DGHY26	中国China	MT085792
DGHY11B	中国China	MT085784
DGHY24	中国China	MT085789
DGHY25A	中国China	MT085790
DGHY16	中国China	MT085785
DGHY9	中国China	MT085781
IRNS69	伊朗 Iran	KT864988
IRNS20	伊朗Iran	KT864987
CN1	中国China	AY937262
SDHY32B	中国China	MT085795
SDHY31	中国China	MT085793
SDHY33	中国China	MT085796
SDHY32A	中国China	MT085794
1278	荷兰Netherlands	AJ496145
1509/4	波兰Poland,PL	AJ496147
167	波兰Poland	AJ496148
197/3A	捷克The Czech Republic	AJ496149
3CH	智利Chile	AJ496151
ST	德国Germany,GER	AJ496154
HD	德国Germany	AJ496153
9032.001M	美国United States,USA	AJ496152

基因组	全长和基因	蛋白大小/aa	核苷酸同源性/%	氨基酸同源性/%
RNA1	全长		79.2 ~ 96.8
	多聚蛋白	1914 ~ 1915		89.0 ~ 99.5
	多肽X1	146	85.8 ~ 99.1	87.7 ~ 99.3
	多肽X2	202	76.9 ~ 98.5	90.6 ~ 100
	NBP	616	76.9 ~ 98.2	91.4 ~ 99.7
	Vpg	26	73.1 ~ 100	100
	3CL-Pro	231 ~ 232	73.2 ~ 98.7	82.3 ~ 100
	RdRp	694	74.7 ~ 96.2	88.0 ~ 99.7
RNA2	全长		77.9 ~ 97.8
	多聚蛋白P2	1691		89.9 ~ 98.9
	MP	452	79.8 ~ 98.7	91.4 ~ 99.1
	CP	649	77.1 ~ 98.6	92.1 ~ 99.5
	Pro2-Glu	343	76.4 ~ 98.4	86.6 ~ 98.5
	多肽	247	76.1 ~ 96.5	85.8 ~ 99.2