基于线粒体COII-LrRNA基因对肾形肾状线虫种内群体的遗传多样性分析

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摘要肾形肾状线虫(Rotylenchulus reniformis)是一种植物半内寄生线虫，分布于世界的热带和亚热带地区，是许多蔬菜和热带果树重要的病原线虫。为明确该线虫种内群体的遗传变异，本研究采用序列分析法，对采自浙江(ZJ)、福建(FJ)和重庆(CQ)3个地区的肾形肾状线虫的线粒体COII-LrRNA基因序列进行比较。结果表明，肾形肾状线虫线粒体COII-LrRNA 基因片段序列为557~563 bp，AT含量为85.5%，明显高于GC含量。序列分析所得3个群体总的变异位点数、单倍型数、单倍型多样性指数(haplotype diversity, Hd)和核苷酸多样性指数(nucleotide diversity, π)分别为176、40、0.946和0.157 4。分子方差分析(analysis of molecular variance, AMOVA)结果显示，这3个肾形肾状线虫群体间遗传分化系数为0.058 15，遗传分化程度中等，没有明显的地理隔离。遗传变异结果显示，94.18%的变异来自群体内个体间，只有5.82%的变异发生在群体间。结果说明，我国肾形肾状线虫种群内COII-LrRNA基因序列变异较明显，具有丰富的遗传多样性，且对环境变化的适应能力较强。研究结果丰富了我国肾形肾状线虫的系统发育信息，为肾形肾状线虫危害植物的内在遗传因素的研究提供了资料。

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	邓艳凤
	田忠玲
	郑经武

关键词 ：肾形肾状线虫, 线粒体DNA(mtDNA), COII-LrRNA基因, 遗传多样性

Abstract：Rotylenchulus reniformis is a semi-endoparasitic nematode, which widely distributes in tropical and subtropical area of the world, and is pathogenic nematodes of many vegetables and tropical fruit trees. Our research was focus on identification and phylogenetic relationship among different geographical populations of reniform nematode. To characterize the genetic diversity of intra-species populations of Rotylenchulus reniformis, sequence variations of COII- LrRNA mitochondrial DNA (mtDNA) between individuals and 3 intra-species populations of reniform nematode from Zhejiang (ZJ), Fujian (FJ) and Chongqing (CQ) were analyzed based on DNA sequence analysis technology. The result showed that the length of COII-LrRNA gene region ranged from 557 to 563 bp using primer 1108 and C2F3-R. The average content of A, T, C and G were 32.6%, 52.9%, 4.5% and 10.0%, respectively. The content of A+T was 85.5%, and it was much higher than that of G+C content. Obvious genetic diversity was found from the amplified region. All 389 conserved sites, 176 variation sites, 51 parsimony-informative sites and 125 singleton sites were identified. There were 40 haplotypes among the 64 sequences, which suggested a high level of heteroplasmy in R. reniformis, and 17 haplotypes were found in ZJ population, 13 haplotypes in CQ population and 12 haplotypes in FJ population. The number haplotype diversity (Hd), and nucleotide diversity (π) of 3 population were 0.946 and 0.157 4, respectively. The analysis of molecular variance (AMOVA) showed that the Fst (F-statistics) of coefficient of genetic differentiation was 0.058 15 (P＜0.01), which placed these isolates into a moderate range of genetic differentiation and no obvious geographic isolation. The variation within populations was 94.18% and only 5.82% of the variation occurred among the 3 intra-species populations. In general, the variation among COII-LrRNA gene sequence of reniform nematodes in China was obvious, which indicated that reniform nematodes in China had abundant genetic diversity, and a strong ability to adapt to environmental change. This study enriches the phylogenetic information of R. reniformis, and provides the basic evidence for the inherent genetic factors of damage from reniform nematode.

Key words： Rotylenchulus reniformis mitochondrial DNA(mtDNA) COII-LrRNA gene Genetic diversity

收稿日期: 2015-11-11 出版日期: 2016-02-24

基金资助:国家自然科学基金;国家重点基础研究发展计划973计划项目

通讯作者: 郑经武 E-mail: jwzheng@zju.edu.cn

引用本文:

邓艳凤田忠玲郑经武. 基于线粒体COII-LrRNA基因对肾形肾状线虫种内群体的遗传多样性分析[J]. , 2016, 24(4): 593-599.

链接本文:

http://journal05.magtech.org.cn/Jwk_ny/CN/ 或 http://journal05.magtech.org.cn/Jwk_ny/CN/Y2016/V24/I4/593

[1] Starr J L. Cook R. Bridge J. Plant resistance to parasitic nematodes[J]. Wallingford: CAB International, 2002, 153-174.
[2] Starr J L. Koenning S R. Kirkpatrick T L, et al. The future of nematode management in cotton[J]. Journal of Nematology, 2007, 39: 283-294.
[3] Blasingame D. 2005 cotton disease loss estimate committee report[G]. 2006 Beltwide Cotton Conferences. San Antonio: National Cotton Council of America, 2006: 155-157.
[4] Koenning S R, Kirkpatrick T L, Starr J L, et al., Plant-parasitic nematodes attacking cotton in the United States. Plant Disease, 2004, 88: 100–13.
[5] Starr J L, Page S L J. Nematode parasites of Pineapple[M]. Luc,M, Sikora, R A, Bridge, J (Eds.) Plant Parasitic Nematodesin Subtropical and Tropical Agriculture, Wallingford: CAB International. 1990:. 519–538.
[6] 张绍升, 章淑玲. 寄生甘薯的肾形线虫种类鉴定[J]. 植物病理学报, 2005, 35: 560-562.
[7] Subbotin S, Sturhan D, Chizhov V N, et al., Phylogenetic analysis of Tylenchida Thorne, 1949 as inferred from D2 and D3 expansion fragments of the 28S rRNA gene sequences [J]. Nematology, 2006, 8: 455– 474.
[8] Gutiérrez-Gutiérrez C, Castillo P, Cantalapiedra-Navarrete C. Genetic structure of Xiphinema pachtaicum and X.indexpopulations based on mitochondrial DNA variation[J]. Phytopathology, 2011, 101: 1168- 1175.
[9] Humphreys-Pereira D A, Elling A A. Intraspecific variability and genetic structure in Meloidogyne chitwoodi from the USA [J]. Nematology, 2013. 15 : 315.
[10] Hu M. Chilton N B, Gasser R B. The mitochondrial genomics of parasitic nematodes of socio-economic importance: recent progress, and implications for population genetics and systematic [J]. Advances in Parasitology, 2004, 56: 133–212.
[11] Anderson T J C, Blouin M S, Beech R N. Population biology of parasitic nematodes: applications of genetic markers [J]. Advances in Parasitology, 1998, 41: 219–283.
[12] Gasser R B, Newton S E. Genomic and genetic research on bursate nematodes: significance, implications and prospects [J]. International Journal for Parasitology, 2000, 30: 509–534
[13] Veer M V D, Kanobana K, Ploeger H W, et al., Cytochrome oxidase c subunit 1 polymorphisms show significant differences in distribution between a laboratory maintained population and a field isolate of Cooperia oncophora [J]. Veterinary Parasitology, 2003, 116: 231–238.
[14] Tamura K, Dudley J, Nei M., et al, MEGA4: molecular evolutionary genetics analysis (MEGA) software version 4.0[J]. Molecular Biology and Evolution, 2007, 24:1596-1599.
[15] Rozas J. DNA sequence polymorphism analysis using Dnasp [J]. Methods in Molecular Biology, 2009, 537: 337-350.
[16] Excoffier L, Laval G, Schneider S. Arlequin ver 3.0: an integrated software package for population genetics data analysis [J]. Evolutionary Bioinformatics Online, 2005, 1:47–50.
[17] 袁媛, 高玮玮, 吴琪等. 黄、渤海地区青蛤(Cyclina sinensis)种群的 ITS 序列遗传变异与遗传结构分析[J]. 海洋与湖沼, 2008, 39: 665-670.
[18] Boore J L. Animal mitochondrial genomes [J]. Nucleic Acids Research, 1999, 27: 1767-1768.
[19] 贾万忠, 闫鸿斌, 倪兴维等. 线虫线粒体基因组全序列分析研究进展[J]. 中国农业科学, 2011, 44(6): 1255-1265.
[20] Grant W S. Bowen B W. Shallow population histories in deep evolutionary lineages of marine fishes: insights from sardines and Anchovie and lessons for conservation[J]. The American Genetic Association, 1998, 89: 415-426.
[21] Danny A, Humphreys-Pereira and Elling A. Intraspecific variability and genetic structure in Meloidogyne chitwoodi from the USA[J]. Nematology, 2013, 15: 315-327.