甜橙和柚中CTV强弱毒株系p20的遗传变异

doi:10.3864/j.issn.0578-1752.2017.07.017

Abstract

Abstract: 【Objective】 In order to clarify the genetic variation of p20 of the severe and mild strains of Citrus tristeza virus (CTV) in sweet orange and pummelo, seven CTV strains were studied. 【Method】The CTV p20 populations were established by RT-PCR, cloning and sequencing, and the phylogenetic tree was constructed with MEGA6. The genetic structure and mutation level of the CTV populations were analyzed by DNAStar. Haplotype diversity, nucleotide diversity and neutral test of the CTV populations were analyzed by DnaSP. 【Result】 Seven CTV p20 populations consisted of 162 sequences with 11 haplotypes were established. One or more haplotypes were found in each population. Sequence analysis showed that the original nucleotide sequence identity of the haplotypes from different populations was 88.2%-100.0%, the corresponding amino acid sequence identity was 92.3%-100.0% and the lowest amino acid sequence identity was found between CT23-1 and CT9-2. There were 50 sequences of haplotypes PeraIAC-4, CT22 and CT9-1, the corresponding nucleotide sequence identity was 100.0%, of which were dominant haplotypes and close to the standard strain T36. PeraIAC possessed the most abundant haplotype diversity (0.800±0.051) and CT22 had the lowest haplotype diversity (0.170±0.102). Compared with haplotype diversity (0.170-0.552) and nucleotide diversity (0.00032-0.05919) of the populations from pummelo, the populations from sweet orange had richer haplotype diversity (0.513-0.800) and nucleotide diversity (0.04208-0.05677). Phylogenetic analysis showed that the population structure of the isolates from sweet orange was complex, and the haplotypes detected in the populations from sweet orange were related to the standard strains T30, T36, VT and T3. CT31-2, which is close to the strain T3, was the most distant to the dominant haplotype in the phylogenetic tree, and the identity of the corresponding nucleotide sequences was 88.3%. The results of neutrality test showed that the populations from sweet orange tended to be balanced or contracted, while the populations from pummelo tended to be expanded except for CT23. The Tajima’s D values, Fu and Li’s D* values and Fu and Li's F* values of the TR-514Y, CT31 and CT23 populations were positive and significantly different, while those of the CT9 population were negative and significantly different. Recombination analysis of each population showed that no recombination occurred in any group. The population variation analysis showed that the percentage of mutant clones was 0-30.8% and the base mutation frequency was 0-7.706×10^-4. The highest percentage of mutant clones (30.8%), the highest mutation frequency (7.706×10^-4), the most base mutations (11) and the most mutation sites (7) happened in p20 populations of CTV severe strains from sweet orange. The percentage of mutated clones and mutation frequency of CTV mild populations from sweet orange were significantly lower than those of CTV severe populations from sweet orange. The percentage of mutated clones and mutation frequency of CTV mild populations from pummelo were slightly lower than those of severe populations from pummelo. The analysis of base mutation types showed that the base mutation types were mainly base substitution, and substitution from A to G was dominant. The sole insertion of A was detected between the 156 and 157 sites of CT3 and no deletion was found in p20 populations. 【Conclusion】 The variations of severe and mild populations of CTV p20 from sweet orange and pummelo were different. CTV p20 populations from sweet orange had more complex population structure and higher variation level than those from pummelo, and the severe populations of CTV p20 had higher variation level than those of mild populations.

Key words: Citrus tristeza virus (CTV), p20, population, genetic variation

WANG YaFei, RUAN Tao, ZHOU Yan, WANG XueFeng, WU GenTu, SUN XianChao, ZHOU ChangYong, QING Ling. Genetic Variation of p20 of the Severe and Mild Strains of CTV in the Sweet Orange and Pummelo[J].Scientia Agricultura Sinica, 2017, 50(7): 1343-1350.

0
/ / Recommend

Add to citation manager EndNote|Reference Manager|ProCite|BibTeX|RefWorks

URL: https://www.chinaagrisci.com/EN/10.3864/j.issn.0578-1752.2017.07.017

https://www.chinaagrisci.com/EN/Y2017/V50/I7/1343

References

[1] Roistacher C, Moreno P. The worldwide threat from destructive isolates of Citrus tristeza virus—a review. rael, 1991, 8: 9.

[2] Davino S, Rubio L, Davino M. Molecular analysis suggests that recent Citrus tristeza virus outbreaks in Italy were originated by at least two independent introductions. European Journal of Plant Pathology, 2005, 111(3): 289-293.

[3] Read D A, Pietersen G. Genotypic diversity of Citrus tristeza virus within red grapefruit, in a field trial site in South Africa. European Journal of Plant Pathology, 2015, 142(3): 531-545.

[4] Ghosh A, Das A, Pun K B, Kumar R, Meena R, Baranwal V K. Present status of Citrus tristeza virus infecting Citrus spp. in Darjeeling hills and its detection in different plant parts. Phytoparasitica, 2014, 42(3): 381-386.

[5] Zhou Y, Zhou C Y, Song Z, Liu K H, Yang F Y. Characterization of Citrus tristeza virus isolates by indicators and molecular biology methods. Agricultural Sciences in China, 2007, 6(5): 573-579.

[6] Bar-joseph M, Marcus R, Lee R F. The continuous challenge of Citrus tristeza virus control. Annual Review of Phytopathology, 1989, 27(1): 291-316.

[7] Brlansky R H, Howd D S, Broadbent P, Damsteegt V D. Histology of sweet orange stem pitting caused by an Australian isolate of Citrus tristeza virus. Plant Disease, 2002, 86(10): 1169-1174.

[8] Karasev A, Boyko V, Gowda S, Nikolaeva O, Hilf M, Koonin E, Niblett C, Cline K, Gumpf D, Lee R. Complete sequence of the Citrus tristeza virus RNA genome. Virology, 1995, 208(2): 511-520.

[9] Lu R, Folimonov A, Shintaku M, Li W X, Falk B W, Dawson W O, Ding S W. Three distinct suppressors of RNA silencing encoded by a 20-kb viral RNA genome. Proceedings of the National Academy of Sciences of the United States of America, 2004, 101(44): 15742-15747.

[10] Chapman E J, Prokhnevsky A I, Gopinath K, Dolja V V, Carrington J C. Viral RNA silencing suppressors inhibit the microRNA pathway at an intermediate step. Genes & Development, 2004, 18(10): 1179-1186.

[11] Mallory A C, Reinhart B J, Bartel D, Vance V B, Bowman L H. A viral suppressor of RNA silencing differentially regulates the accumulation of short interfering RNAs and micro-RNAs in tobacco. Proceedings of the National Academy of Sciences of the United States of America, 2002, 99(23): 15228-15233.

[12] Pantaleo V, Szittya G, Burgyán J. Molecular bases of viral RNA targeting by viral small interfering RNA-programmed RISC. Journal of Virology, 2007, 81(8): 3797-3806.

[13] 周彦, 周常勇, 赵学源, 蒋元晖, 王雪峰. 6种柑橘类植物对柑橘衰退病毒分离株TR-L514变异的影响. 植物病理学报, 2007, 37(2): 131-137.

Zhou Y, Zhou C Y, Zhao X Y, Jiang Y H, Wang X F. Influence of six citrus cultivars on the composition of Citrus tristeza virus isolate TR-L514. Acta Phytopathologica Sinica, 2007, 37(2): 131-137. (in Chinese)

[14] Zhou Y, Li Z A, Wang X F, Liu K H, Li T S, Zhou C Y. Variations of pathogenicity and composition of two Citrus tristeza virus isolates induced by host passage. Journal of Plant Pathology, 2013, 95(2): 265-273.

[15] 宋震, 周常勇, 周彦, 王雪峰, 唐科志. 柑橘衰退病毒柚类分离株的分子鉴定. 病毒学报, 2006, 22(4): 314-319.

Song Z, Zhou C Y, Zhou Y, Wang X F, Tang K Z. Molecular identification of Citrus tristeza virus isolates from pummelos. Chinese Journal of Virology, 2006, 22(4): 314-319. (in Chinese)

[16] 王志刚, 周常勇, 周彦. 寄主凤凰柚对柑橘衰退病病毒甜橙分离株构成的影响. 园艺学报, 2007, 34(5): 1098-1102.

Wang Z G, Zhou C Y, Zhou Y. Influence of Fenghuang pummelo on the composition of Citrus tristeza virus isolates collected from sweet orange. Acta Horticulturae Sinica, 2007, 34(5): 1098-1102. (in Chinese)

[17] Ayllón M A, Rubio L, Sentandreu V, Moya A, Guerri J, Moreno P. Variations in two gene sequences of Citrus tristeza virus after host passage. Virus Genes, 2006, 32(2): 119-128.

[18] 易龙. 柑橘衰退病毒的进化与起源初步分析[D]. 重庆: 西南大学, 2007.

Yi L. Preliminary analysis of the evolution and orign of Citrus trsiteza virus[D]. Chongqing: Southwest University, 2007. (in Chinese)

[19] 任芳, 青玲, 熊艳, 谭万忠. 中国番茄黄化曲叶病毒卫星DNAβ在心叶烟中的遗传结构及种群变异. 植物保护学报, 2010, 37(1): 31-36.

Ren F, Qing L, Xiong Y, Tan W Z. Genetic structure and population variation of satellite DNAβ associated with Tomato yellow leaf curl China virus in Nicotiana glutinosa. Acta Phytophylacica Sinica, 2010, 37(1): 31-36. (in Chinese)

[20] Cheng C Z, Yang J W, Yan H B, Bei X J, Zhang Y Y, Lu Z M, Zhong G Y. Expressing p20 hairpin RNA of Citrus tristeza virus confers Citrus aurantium with tolerance/resistance against stem pitting and seedling yellow CTV strains. Journal of Integrative Agriculture, 2015, 14(9): 1767-1777.

[21] Zablocki O, Pietersen G. Characterization of a novel Citrus tristeza virus genotype within three cross-protecting source GFMS12 sub-isolates in South Africa by means of Illumina sequencing. Archives of Virology, 2014, 159(8): 2133-2139.

[22] Schneider W L, Roossinck M J. Evolutionarily related Sindbis-like plant viruses maintain different levels of population diversity in a common host. Journal of Virology, 2000, 74(7): 3130-3134.

[23] Schneider W L, Roossinck M J. Genetic diversity in RNA virus quasispecies is controlled by host-virus interactions. Journal of Virology, 2001, 75(14): 6566-6571.

[24] Sentandreu V, Castro J A, Ayllón M A, Rubio L, Guerri J, Gonzalez-Candelas F, Moreno P, Moya A. Evolutionary analysis of genetic variation observed in Citrus tristeza virus (CTV) after host passage. Archives of Virology, 2006, 151(5): 875-894.

[25] Ge L, Zhang J, Zhou X, Li H. Genetic structure and population variability of Tomato yellow leaf curl China virus. Journal of Virology, 2007, 81(11): 5902-5907.

Related Articles 15

[1]	LIU ZhenShan, TU HongXia, ZHOU JingTing, MA Yan, CHAI JiuFeng, WANG ZhiYi, YANG PengFei, YANG XiaoQin, Kumail Abbas, WANG Hao, WANG Yan, WANG XiaoRong. Genetic Analysis of Fruits Characters in Reciprocal Cross Progenies of Chinese Cherry [J]. Scientia Agricultura Sinica, 2023, 56(2): 345-356.
[2]	GUO Yan, ZHANG ShuHang, LI Ying, ZHANG XinFang, WANG GuangPeng. Diversity Analysis of 36 Leaf Phenotypic Traits of Chinese Chestnut [J]. Scientia Agricultura Sinica, 2022, 55(5): 991-1009.
[3]	ZHANG TianPeng,YAN TieZhu,JIN PingZhong,LEI QiuLiang,LIAN HuiShu,LI Ying,LI XiaoHong,OU HuiPing,ZHOU JiaoGen,DU XinZhong,WU ShuXia,LIU HongBin. Net Anthropogenic Nitrogen Inputs and Its Influencing Factors in Three Typical Watersheds of China [J]. Scientia Agricultura Sinica, 2022, 55(23): 4678-4687.
[4]	HUANG XunHe,WENG ZhuoXian,LI WeiNa,WANG Qing,HE DanLin,LUO Wei,ZHANG XiQuan,DU BingWang. Genetic Diversity of Indigenous Yellow-Feathered Chickens in Southern China Inferred from Mitochondrial DNA D-Loop Region [J]. Scientia Agricultura Sinica, 2022, 55(22): 4526-4538.
[5]	NIE XingHua, ZHENG RuiJie, ZHAO YongLian, CAO QingQin, QIN Ling, XING Yu. Genetic Diversity Evaluation of Castanea in China Based on Fluorescently Labeled SSR [J]. Scientia Agricultura Sinica, 2021, 54(8): 1739-1750.
[6]	NIE JunJun,DAI JianLong,DU MingWei,ZHANG YanJun,TIAN XiaoLi,LI ZhaoHu,DONG HeZhong. New Development of Modern Cotton Farming Theory and Technology in China - Concentrated Maturation Cultivation of Cotton [J]. Scientia Agricultura Sinica, 2021, 54(20): 4286-4298.
[7]	LIU YouChun,LIU WeiSheng,WANG XingDong,SUN Bin,LIU XiuLi,YANG YanMin,WEI Xin,YANG YuChun,ZHANG Duo,LIU Cheng,LI TianZhong. Identification of F₁ Hybrids in Blueberry (Vaccinium corymbosum L.) Based on Specific-Locus Amplified Fragment Sequencing (SLAF-seq) [J]. Scientia Agricultura Sinica, 2021, 54(2): 370-378.
[8]	ZHANG MaoNing,HUANG BingYan,MIAO LiJuan,XU Jing,SHI Lei,ZHANG ZhongXin,SUN ZiQi,LIU Hua,QI FeiYan,DONG WenZhao,ZHENG Zheng,ZHANG XinYou. Genetic Analysis of Peanut Kernel Traits in a Nested-crossing Population by Major Gene Plus Polygenes Mixed Model [J]. Scientia Agricultura Sinica, 2021, 54(13): 2916-2930.
[9]	ZHANG LinLin,ZHI Hui,TANG Sha,ZHANG RenLiang,ZHANG Wei,JIA GuanQing,DIAO XianMin. Characterizations of Transcriptional and Haplotypic Variations of SiTOC1 in Foxtail Millet [J]. Scientia Agricultura Sinica, 2021, 54(11): 2273-2286.
[10]	LiYuan PAN,JianBo HE,JinMing ZHAO,WuBin WANG,GuangNan XING,DeYue YU,XiaoYan ZHANG,ChunYan LI,ShouYi CHEN,JunYi GAI. Detection Power of RTM-GWAS Applied to 100-Seed Weight QTL Identification in a Recombinant Inbred Lines Population of Soybean [J]. Scientia Agricultura Sinica, 2020, 53(9): 1730-1742.
[11]	ShuGuang LI,YongCe CAO,JianBo HE,WuBin WANG,GuangNan XING,JiaYin YANG,TuanJie ZHAO,JunYi GAI. Genetic Dissection of Protein Content in a Nested Association Mapping Population of Soybean [J]. Scientia Agricultura Sinica, 2020, 53(9): 1743-1755.
[12]	ZHANG Jian,YANG Jing,WANG Hao,LI DongXiu,YANG GuiLi,HUANG CuiHong,ZHOU DanHua,GUO Tao,CHEN ZhiQiang,WANG Hui. QTL Mapping for Grain Size Related Traits Based on a High-Density Map in Rice [J]. Scientia Agricultura Sinica, 2020, 53(2): 225-238.
[13]	LIU YouChun,LIU WeiSheng,WANG XingDong,YANG YanMin,WEI Xin,SUN Bin,ZHANG Duo,YANG YuChun,LIU Cheng,LI TianZhong. Screening and Inheritance of Fruit Storage-Related Traits Based on Reciprocal Cross of Southern×Northern High Bush Blueberry (Vaccinium Linn) [J]. Scientia Agricultura Sinica, 2020, 53(19): 4045-4056.
[14]	HUANG MiaoMiao,CHEN WanQuan,CAO ShiQin,SUN ZhenYu,JIA QiuZhen,GAO Li,LIU Bo,LIU TaiGuo. Surveillance and Genetic Diversity Analysis of Puccinia striiformis f. sp. tritici in Gansu and Qinghai Provinces [J]. Scientia Agricultura Sinica, 2020, 53(18): 3693-3706.
[15]	ZHAO XuSheng,QI YongZhi,ZHEN WenChao. Composition and Distribution Characteristics of Pathogens Causing Wheat Sharp Eyespot in Wheat and Maize Double Cropping System [J]. Scientia Agricultura Sinica, 2020, 53(16): 3269-3279.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

Genetic Variation of p20 of the Severe and Mild Strains of CTV in the Sweet Orange and Pummelo

RichHTML

PDF

Abstract

Cite this article

share this article

References

Related Articles 15

Metrics

Comments

Recommended 0