[1]杨 帆,李优佳,SHAMEER K S,等.原产地与入侵地椰子织蛾遗传分化特征[J].福建农林大学学报(自然科学版),2021,50(02):178-183.[doi:10.13323/j.cnki.j.fafu(nat.sci.).2021.02.005]
 YANG Fan,LI Youjia,SHAMEER K S,et al.Genetic and divergence characteristics of Opisina arenosella from native and invasive areas[J].,2021,50(02):178-183.[doi:10.13323/j.cnki.j.fafu(nat.sci.).2021.02.005]
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原产地与入侵地椰子织蛾遗传分化特征()
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福建农林大学学报(自然科学版)[ISSN:1671-5470/CN:35-1255/S]

卷:
50卷
期数:
2021年02期
页码:
178-183
栏目:
植物保护
出版日期:
2021-02-15

文章信息/Info

Title:
Genetic and divergence characteristics of Opisina arenosella from native and invasive areas
文章编号:
1671-5470(2021)02-0178-06
作者:
杨 帆12 李优佳1 SHAMEER K S3 阎 伟4 吕宝乾5 蒋方一丁1 章雨璐1 涂 艳1 齐可欣1
1.海南大学林学院,海南 海口 570228; 2.热带特色林木花卉遗传与种质创新教育部重点实验室,海南 海口 570228; 3.Insect Ecology & Ethology Laboratory, Department of Zoology, University of Calicut, Calicut 673635, India; 4.中国热带农业科学院椰子研究所,海南 文昌 571339; 5.中国热带农业科学院环境与植物保护研究所,海南 海口 571101
Author(s):
YANG Fan12 LI Youjia1 SHAMEER K S3 YAN Wei4 LÜ Baoqian5 JIANG Fangyiding1 ZHANG Yulu1 TU Yan1 QI Kexin1
1.College of Forestry, Hainan University, Haikou, Hainan 570228, China; 2.Key Laboratory of Genetic and Germplasm Innovation of Tropical Featured Tree and Ornamental Plants, Ministry of Education, Haikou, Hainan 570228, China; 3.Insect Ecology & Ethology Laboratory, Department of Zoology, University of Calicut, Calicut 673635, India; 4.Coconut Research Institute, Chinese Academy of Tropical Agricultural Sciences, Wenchang, Hainan 571339, China; 5.Environment and Plant Protection Institute, Chinese Academy of Tropical Agricultural Sciences, Haikou, Hainan 571101, China
关键词:
椰子织蛾 线粒体DNA 遗传分化 变异位点
Keywords:
Opisina arenosella mitochondrial DNA genetic divergence variable sites
分类号:
S763.42
DOI:
10.13323/j.cnki.j.fafu(nat.sci.).2021.02.005
文献标志码:
A
摘要:
椰子织蛾来源于印度和斯里兰卡,已成功入侵我国华南地区4个省,对我国棕榈植物及城市园林景观造成严重威胁.利用COⅠ、COⅡ和COⅢ 3个基因片段对原产地(印度)和入侵地(中国、马来西亚、泰国和印度尼西亚)共12个地区的107份椰子织蛾样品的遗传分化特征进行分析,结果表明:原产地与入侵地种群的核苷酸组成存在34个变异位点,38%为嘌呤转换,62%为嘧啶转换; 入侵中国、马来西亚、印度尼西亚和泰国的种群均为同一种基因型.系统发育树表明椰子织蛾存在两个遗传支系,即原产地支系与入侵地支系,遗传距离为1.3%,说明椰子织蛾种群已产生遗传分化.
Abstract:
Opisina arenosella, originating from India and Sri Lanka, has successfully invaded South China and poses tremendous threat to palm plantation and urban landscape in China. In this study, COⅠ, COⅡ and COⅢ gene fragments were used to analyze the genetic and divergence characteristics of O.arenosella samples collected from 12 regions, including the place of origin(India)and 4 invasive regions(China, Malaysia, Thailand and Indonesia). The results showed that there were 34 variation sites between the populations from the native and the invasive sites, including 38% purine conversion and 62% pyrimidine conversion. Phylogenetic trees showed that there were 2 genetic branches of the coconut moth, namely the origin branch and invasive branch, with a genetic distance of 1.3%, suggesting that the genetic divergence had developed.

参考文献/References:

[1] 丁晖,雷军成,乐志芳,等.中国生物入侵的现状与趋势[J].生态与农村环境学报,2011,27(3):35-41.
[2] 齐国君,吕利华.近年来中国热带地区外来有害昆虫的种类特征及入侵分析[J].环境昆虫学报,2018,40(4):749-757.
[3] LU B, TANG Z, BELLIS G, et al. Life table analysis under constant temperature for Opisina arenosella(Lepidoptera: Xyloryctidae), an invasive moth of palm plants[J]. Austral Entomology, 2016,55(3):334-339.
[4] 吕宝乾,严珍,金启安,等.警惕椰子织蛾Opisina arenosella Walker(鳞翅目:织蛾科)传入中国[J].生物安全学报,2013,22(1):17-22.
[5] MURALIMOHAN K, SRINIVASA Y. Occurrence of protandry in an aseasonal multivoltine moth: implications for body-size evolution[J]. Current Science, 2008,94:513-518.
[6] 阎伟,吕宝乾,李洪,等.椰子织蛾传入中国及其海南省的风险性分析[J].生物安全学报,2013,22(3):163-168.
[7] 阎伟,刘丽,李朝绪,等.入侵害虫椰子织蛾对海南椰子造成的经济损失评估[J].中国南方果树,2015,44(4):156-159.
[8] 王谨,林玉英,金涛.厦门棕榈科植物害虫调查[J].热带农业科学,2015,35(4):66-70.
[9] 国家林业局.国家林业局公告2014年第6号[EB/OL].(2014-03-10)[2020-03-20].http: //www.forestry.gov. cn /main /72 /content663834.html.
[10] 李娟,常国彬,曲涛,等.我国林业有害生物危害性评价[J].中国森林病虫,2019,38(4):11-17,21.
[11] 万宣伍,刘映红,罗林明,等.基于分子生物学方法的外来入侵物种入侵历史重构[J].生态学报,2015,35(4):1296-1309.
[12] 李志红,NOPPARAT B,胡俊韬,等.实蝇科害虫入侵来源与入侵机制研究进展[J].植物检疫,2013,27(3):1-12.
[13] HEBERT P, CYWINSKA A, BALL S, et al. Biological identifications through DNA barcodes[J]. Proceedings of the Royal Society of London Series B: Biological Sciences, 2003,270:313-321.
[14] HAJIBABAEI M, SINGER G, HEBERT P, et al. DNA barcoding: how it complements taxonomy, molecular phylogenetics and population genetics[J]. Trends in Genetics, 2007,23(4):167-172.
[15] 李优佳,杨帆,吕宝乾,等.入侵性食叶害虫椰子织蛾的单倍型多样性分析[J].华南农业大学学报,2020,41(4):76-81.
[16] MENG R, HE Y, AO S, et al. Complete mitochondrial genome of the coconut black-headed caterpillar Opisina arenosella(Lepidoptera: Gelechioidea: Xyloryctidae)[J]. Mitochondrial DNA Part B, 2019,4(1):1237-1238.
[17] HALL T. A user-friendly biological sequence alignment editor and analysis program for Windows TM[J]. Nucleic Acid Symposium Series, 1999,41:95-98.
[18] TAMURA K, STECHER G, PETERSON D, et al. MEGA 6: molecular evolutionary genetics analysis version 6.0[J]. Molecular Biology and Evolution, 2013,30(12):2725-2729.
[19] KALYAANAMOORTHY S, MINH B Q, WONG T K F, et al. ModelFinder: fast model selection for accurate phylogenetic estimates[J]. Nat Methods, 2017,14(6):587-589.
[20] RONQUIST F, TESLENKO M, VAN DER MARK P, et al. MrBayes 3.2: efficient Bayesian phylogenetic inference and model choice across a large model space[J]. Systematic Biology, 2012,61(3):539-542.
[21] 魏兆军,赵巧玲,张志芳,等.蓖麻蚕线粒体基因组细胞色素氧化酶亚基Ⅲ的序列及其分子进化分析[J].昆虫学报,2002,45(2):193-197.
[22] ZAHIRI R, LAFONTAINE J, SCHMIDT B, et al. A transcontinental challenge — A test of DNA barcode performance for 1 541 species of Canadian Noctuoidea(Lepidoptera)[J]. PLoS ONE, 2014,9(3):e92797.
[23] WEBB J, JACOBUS L, FUNK D, et al. A DNA barcode library for North American Ephemeroptera: progress and prospects[J]. PLoS ONE, 2012,7(5):e38063.
[24] PENTINSAARI M, HEBERT P, MUTANEN M, et al. Barcoding beetles: a regional survey of 1872 species reveals high identification success and unusually deep interspecific divergences[J]. PLoS ONE, 2014,9(9):e108651.
[25] YANG F, KAWABATA E, TUFAIL M, et al. r/K-like trade-off and voltinism discreteness: the implication to allochronic speciation in the fall webworm, Hyphantria cunea complex(Arctiidae)[J]. Ecology and Evolution, 2017,7:10592-10603.
[26] PASHLEY D, MARTIN J. Reproductive incompatibility between host strains of the fall armyworm(Lepidoptera: Noctuidae)[J]. Annals of the Entomological Society of America, 1987,80(6):731-713.
[27] PASHLEY D. Host-associated genetic differentiation in fall armyworm(Lepidoptera: Noctuidae): a sibling species complex?[J]. Annals of the Entomological Society of America, 1986,79(6):898-904.
[28] DLUGOSCH K, PARKER I. Founding events in species invasions: genetic variation, adaptive evolution, and the role of multiple introductions[J]. Molecular Ecology, 2008,17:431-449.
[29] BRODERS H, MAHONEY S, MONTEVECCHI W, et al. Population genetic structure and the effect of founder events on the genetic variability of moose, Alces alces, in Canada[J]. Molecular Ecology, 1999,8(8):1309-1315.
[30] KONECˇNY A, ESTOUP A, DUPLANTIER J, et al. Invasion genetics of the introduced black rat(Rattus rattus)in Senegal, West Africa[J]. Molecular Ecology, 2013,22(2):286-300.
[31] MANJUNATH T. Coconut black-headed caterpillar on banana and coconut[J]. FAO Plant Prot Bull, 1985,33(2):71-72.
[32] SHAMEER K, NASSER M, MOHAN C, et al. Direct and indirect influences of intercrops on the coconut defoliator Opisina arenosella[J]. Journal of Pest Science, 2018,91(1):259-275.
[33] 李洪,刘丽,阎伟.新入侵害虫椰子织蛾的发生及防治[J].中国森林病虫,2015,34(4):10-13.
[34] 曹金亮.危险性有害生物椰子织蛾入侵福建的风险性分析[J].安徽农业科学,2014,42(25):8578-8580,8583.

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备注/Memo

备注/Memo:
收稿日期:2020-05-10 修回日期:2020-07-03
基金项目:海南省自然科学基金(318QN195); 海南大学科研启动基金项目[KYQD(ZR)1821]; 农业农村部农业国际交流与合作项目(BARTP-08-LBQ); 中国热带农业科学院基本业务费(1630042017011).
作者简介:杨帆(1988-),女,讲师.研究方向:林业有害生物综合管理.Email:fanf_yang@hainanu.edu.cn.通信作者吕宝乾(1977-),男,研究员.研究方向:入侵生物防治.Email:lvbaoqian@hotmail.com.
更新日期/Last Update: 2021-02-15