西北地区枸杞木虱不同地理种群遗传分析

doi:10.11707/j.1001-7488.LYKX20240066

摘要/Abstract

摘要：

目的: 探讨我国西北地区枸杞木虱种群遗传多样性、分化以及种群系统发育关系，为枸杞木虱区域性发生规律和制定防控策略提供分子生物学理论依据。方法: 对2023年6—8月采自西北地区18个不同地理种群的512份枸杞木虱样品的mt DNA COI基因进行了PCR扩增、测序，并利用MEGA7.0、Dna SP 5.0、Arlequin 3.5和Network 10.0等软件分析mt DNA COI基因序列变异、系统发育及遗传分化等情况。结果: 1）测定片段长度为474 bp，序列碱基T、C、A、G含量分别为35.6%、22.2%、26.8%、15.4%，A+T含量（62.4%）明显高于G+C含量（37.6%），表现出明显的碱基偏倚性，核苷酸多样度为0.002 5，核苷酸平均差异数K为1.110。2 ）检出5个单倍型，单倍型多样度为0.512，其中单倍型H2为优势单倍型，共出现344次，占所有检测个体的67.19%。3） 18个枸杞木虱地理种群Taijima’s D及Fu’s Fs值分别为0.876、0.911，均未达到显著水平。4）群体遗传分化指数为0.642 78，基因流为0.21，种群内遗传变异百分率为35.72%，种群间遗传变异百分率为64.28%，种群内变异显著小于种群间变异（P<0.01）。5）由单倍型NJ系统发育树和网络中介图可知，5个单倍型聚为4个聚类簇。6）各种群间的遗传距离在0 ~ 0.007之间。UPGMA聚类图结果表明，德令哈（DLH）和格尔木（GEM）种群、古浪县（GLX）和石河子（SHZ）种群与其他种群相比分化明显。7） Mantel检测结果显示，18个枸杞木虱地理种群间遗传距离与地理距离存在显著中度正相关（r=0.675，P<0.05）。结论: 西北地区18个枸杞木虱地理种群遗传多样性较低，地理种群间和种群内均出现了遗传变异，种群总体变异的主要因素为种群间变异，种群内遗传分化相对较低。

关键词: 枸杞木虱, mt DNA COI, 地理种群, 遗传分化

Abstract:

Objective: This study aims to explore the genetic diversity, genetic differentiation, and phylogenetic relationships of Paratrioza sinica populations in northwest China, so as to provide molecular biological theoretical basis for the regional occurrence patterns of P. sinica and the formulation of prevention and control strategies. Method: In this study, 512 samples of P. sinica were collected from 18 different geographical populations in northwest China from June to August 2023. The mtDNA COI gene was amplified with PCR and sequenced, and the mtDNA COI gene sequence variation, phylogenetic and genetic differentiation were analyzed by using MEGA7.0, Dna SP 5.0, Arlequin 3.5, and Network 10.0 software. Result: 1) The length of the amplified fragment was 474 bp, and the content of the base T, C, A, and G was 35.6%, 22.2%, 26.8%, and 15.4%, respectively. The A+T content (62.4%) was significantly higher than the G+C content (37.6%), showing a significant base bias. The nucleotide diversity was 0.002 5, and the average nucleotide difference number of k was 1.110. 2) There were 5 haplotypes detected, with the haplotype diversity of 0.512. Among them, haplotype H2 was the dominant haplotype, and appeared 344 times, accounting for 67.19% of all detected individuals. 3) The Taijima's D and Fu's Fs values of the 18 P. sinica geographic populations were 0.876 and 0.911, respectively, and both of them did not reach significant levels. 4) The population genetic differentiation index was 0.642 78, and the gene flow was 0.21. The percentage of genetic variation within populations was 35.72%, and the percentage of genetic variation between populations was 64.28%. The variation within populations was significantly smaller than that between populations (P<0.01). 5) The haplotype NJ phylogenetic tree and network mediation diagram showed that the five haplotypes were clearly clustered into 4 clusters. 6) The genetic distance among various populations ranged from 0.000 to 0.007. The UPGMA clustering results indicated that the populations from Delingha (DLH) and Golmud (GEM), as well as those from Gulang County (GLX) and Shihezi (SHZ) were significantly differentiated compared to other populations. 7) The Mantel test showed that there was a significant moderate positive correlation (r=0.675, P<0.05) between genetic distance and geographic distance among the 18 geographical populations of P. sinica. Conclusion: The 18 geographical populations of P. sinica in the northwest region exhibit low genetic diversity, with genetic variation occurring both among and within populations. The main factor contributing to the overall population variation is interpopulation variation, while intrapopulation genetic differentiation is relatively low.

Key words: Paratrioza sinica, mitochondrial DNA COI, geographical population, genetic differentiation

中图分类号:

S763.18

周兴隆,刘竟星,吕宁,李健荣,杨金娟,于丽,杨俊丽,姬宇翔. 西北地区枸杞木虱不同地理种群遗传分析[J]. 林业科学, 2025, 61(5): 171-179.

Xinglong Zhou,Jingxing Liu,Ning Lü,Jianrong Li,Jinjuan Yang,Li Yu,Junli Yang,Yuxiang Ji. Genetic Analysis of Different Geographical Populations of Paratrioza sinica in Northwest China[J]. Scientia Silvae Sinicae, 2025, 61(5): 171-179.

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参考文献 0

	姜　宁, 夏振远, 谢永辉, 等. 基于线粒体COI基因的云南西花蓟马种群遗传多样性研究. 中国烟草学报, 2023, 29 (4): 66- 75.
	Jiang N, Xia Z Y, Xie Y H, et al. Polulation genetic diversity of Frankliniella occidentalis in Yunnan based on mtDNA COI gene. Acta Tabacaria Sinica, 2023, 29 (4): 66- 75.
	马力文, 刘　静. 2018. 枸杞气象业务服务. 北京: 气象出版社.
	Ma L W, Liu J. 2018. Meteorological business service of wolfberry. Beijing: Meteorological Press. ［in Chinese］
	沈登荣, 宋文菲, 袁盛勇. 等. 基于mtDNA-COⅠ的云南西花蓟马的遗传分析. 植物保护, 2014, 40 (5): 75- 79. doi: 10.3969/j.issn.0529-1542.2014.05.013
	Shen D R, Song W F, Yuan S Y, et al. Genetic analysis of Frankliniella occidentalis based on mt DNA-COI in Yunnan, China. Plant Protection, 2014, 40 (5): 75- 79. doi: 10.3969/j.issn.0529-1542.2014.05.013
	谢艳兰, 张宏瑞, 李正跃. 基于线粒体 COI基因的中国西南地区木领针蓟马地理种群的遗传分化分析. 昆虫学报, 2019, 62 (3): 370- 380.
	Xie Y L, Zhang H R, Li Z Y. Analysis of genetic differentiation among geographic populations of Helionothrips mube (Thysanoptera: Thripidae) in southwestern China based on mitochondrial COI gene. Acta Entomologica Sinica, 2019, 62 (3): 370- 380.
	熊忠平, 吴培福, 徐　磊,等. 2018. 二斑栗实象COI序列多态性分析. 西南林业大学学报(自然科学), 38(1): 110−116.
	Xiong Z P, Wu P F, Xu L, et al. 2018 Analysis of COI Genetic Sequence Polymorphisms of Curculio bimaculatus. Journal of Southwest Forestry University, 38(1): 110−116. ［in Chinese］
	徐　磊, 季莹莹, 黎　红, 等. 基于线粒体COI基因的南海浮游介形类斜突浮萤单倍型与种群遗传结构研究. 生态科学, 2019, 38 (5): 15- 22.
	Xu L, Ji Y Y, Li H, et al. Genetic structure and haplotype pattern of marine planktonic ostracod Proceroecia procera from the South China Sea based on the mitochondrial COI gene. Ecological Science, 2019, 38 (5): 15- 22.
	杨顺义, 周兴隆, 宋丽雯, 等. 基于mt DNA COI基因的甘肃截形叶螨不同地理种群遗传分化分析. 昆虫学报, 2017, 60 (9): 1083- 1092.
	Yang S Y, Zhou X L, Song L W, et al. Analysis of genetic differentiation among different geographic populations of Tetranychus truncatus (Acari: Tetranychidae) in Gansu province, northwestern China based on mt DNA COI gene. Acta Entomologica Sinica, 2017, 60 (9): 1083- 1092.
	张海燕, 陈光辉, 古丽扎尔·阿不都克力木. 等, 2021. 基于mt DNA COI基因的新疆部分地区叶蝉的分子鉴定. 中国农学通报, 37(36): 119−129.
	Zhang H Y, Chen G H, Gulinazha A, et al. 2021. Cicadellidae in some areas of Xinjiang: molecular identification based on mt DNA COI gene. Chinese Agricultural Science Bulletin, 37(36): 119−129. ［in Chinese］
	郑梓豪, 吴珊珊, 魏　勇, 等. 基于线粒体COI基因分析广州市15个白纹伊蚊种群的遗传多样性. 中国人兽共患病学报, 2021, 37 (11): 985- 994. doi: 10.3969/j.issn.1002-2694.2021.00.141
	Zheng Z H, Wu S S, Wei Y, et al. Analysis of the genetic diversity of 15 Aedes albopictus populations in Guangzhou based on the mitochondrial COI gene. Chinese Journal of Zoonoses, 2021, 37 (11): 985- 994. doi: 10.3969/j.issn.1002-2694.2021.00.141
	朱玉溪, 王欣宇, 杨　润, 等. 昆虫共生菌调控宿主温度适应性研究进展. 植物保护学报, 2022, 49 (6): 1565- 1575.
	Zhu Y X, Wang X Y, Yang R, et al. Advances in researches on symbiont-mediated thermal adaption in insects. Journal of Plant Protection, 2022, 49 (6): 1565- 1575.
	Bandelt H J, Forster P, Rohl A. Median-joining networks for inferring intraspecific phylogenies. Molecular Biology and Evolution, 1999, 16 (1): 37- 48. doi: 10.1093/oxfordjournals.molbev.a026036
	Chen Y T, Zhang Y K, Du W X, et al. 2016. Geography has a greater effect than Wolbachia infection on population genetic structure in the spider mite, Tetranychus pueraricola. Bulletin of Entomological Research , 106(5): 685.
	Excoffier L, Lischer H E. Arlequin suite ver 3.5: a new series of programs to perform population genetics analyses under Linux and Windows. Molecular Ecology Resources, 2010, 10 (3): 564- 567. doi: 10.1111/j.1755-0998.2010.02847.x
	Frankham R, Ballou J D, Briscoe D A. 2002. Introduction to conservation genetics . Cambridge: Cambridge University Press: 5-30.
	Grant W A S, Bowen B W. Shallow population histories in deep evolutionary lineages of marine fishes: insights from sardines and anchovies and lessons for conservation. Journal of Heredity, 1998, 89 (5): 415- 426. doi: 10.1093/jhered/89.5.415
	Hague M T, Caldwell C N, Cooper B S. Pervasive effects of Wolbachia on host temperature preference. mBio, 2020, 11 (5): e01768- 20.
	Ju J F, Bing X L, Zhao D S, et al. Wolbachia supplement biotin and riboflavin to enhance reproduction in planthoppers. The ISME Journal, 2020, 14 (3): 676- 687. doi: 10.1038/s41396-019-0559-9
	Knight A, Mindell D P. Substitution Bias. Weighting of DNA sequence evolution and the phylogenetic position of Fea's Viper. Systems Biology, 1993, 42 (1): 18- 31. doi: 10.1093/sysbio/42.1.18
	Lan H, Shi L. The origin and genetic differentiation of nativebreeds of pigs in southwest China: an approach from mitochondrial DNA polymorphism. Biochemical Genetics, 1993, 31 (1/2): 51- 60.
	Lohman D J, Peccie D, Pierce N E, et al. 2008. Phylogeography and genetic diversity of a widespread old world butterfly, Lampides boeticus (Lepidoptera: Lycaenidae). BMCE Volutionary Biology, (8): 301.
	Marullo R, Mercati F, Vono G. DNA barcoding: A reliable method for the identification of thrips species (Thysanoptera, Thripidae) collected on sticky traps in onion fields. Insects, 2020, 11 (8): 489. doi: 10.3390/insects11080489
	Miller N, Birley A J, Overall A D J, et al. 2003. Population genetic structure of the lettuce root aphid, Pemphigus bursar (L. ), in relation to geographic distance, gene flow andlushost plant usage. Heredity, 91(3): 217−223.
	Nneji L M, Adeola A C, Ayoola A O, et al. DNA barcoding and species delimitation of butterflies (Lepidoptera) from Nigeria. Molecular Biology Reports, 2020, 47 (12): 9441- 9457. doi: 10.1007/s11033-020-05984-5
	Rogers A R, Harpending H. Population growth makes waves in the distribution of pairwise genetic differences. Mol Biol Evol, 1992, 9 (3): 552- 569.
	Rozas J, Ferrer-Mata A, Sanchez-Delbarrio J C, et al. DnaSP 6: DNA sequence polymorphism analysis of large data sets. Molecular Biology and Evolution, 2017, 34 (12): 3299- 3302. doi: 10.1093/molbev/msx248
	Simon C, Frati F, Beckenbach A, et al. Evolution, Weighting, and phylogenetic utility of mitochondrial gene sequences and a compilation of conserved polymerase chain reaction primers. Annals of the Entomological Society of America, 1994, 87 (6): 651- 701. doi: 10.1093/aesa/87.6.651
	Skibinski D O, Gallagher C, Beynon C M. Mitochondrial DNAinheritance. Nature, 1994, 368 (6474): 817- 818.
	Symondson W O C, Lidddll J E. 1996. The ecology of agricultural pests: biochemical approaches. London: Chapmanand Hall, Melbourne. 231−263.
	Vrijenhoek R C, 1994. Genetic diversity and fitness in small populations. Conserv Genet, 68: 37−53.
	Zhang Y K, Ding X L, Zhang K J, et al. Wolbachia play an important role in affecting mt DNA variation of Tetranychus truncatus (Trombidiformes: Tetranychidae). Environmental Entomology, 2013, 42 (6): 1240- 1245.

采样地点 Sampling site	种群代码 Population code	纬度 Latitude	经度 Longitude	海拔 Altitude/m	寄主植物 Host plants	样本数量 Sample size	采样时间 Sampling time
惠农区Huinong District	HNQ	106°41'12''	39°5'29''	1192	枸杞Lycium barbarum	24	2023?07?08
西夏区Xixia District	XXQ	106°13'15''	38°6'48''	1108	枸杞Lycium barbarum	22	2023?07?08
利通区Litong District	LTQ	106°12'12''	37°47'43''	1125	枸杞Lycium barbarum	22	2023?07?05
红寺堡区Hongsipu District	HSP	105°56'43''	37°26'23''	1223	枸杞Lycium barbarum	40	2023?07?05
沙坡头区Shapotou District	SPT	105°12'15''	36°56'7''	1204	枸杞Lycium barbarum	29	2023?07?31
中宁县Zhongning County	ZNX	105°39'50''	37°29'40''	1132	枸杞Lycium barbarum	40	2023?07?07
玉门市Yumen City	YMS	96°59'34''	40°20'32''	1335	枸杞Lycium barbarum	33	2023?07?15
金塔县Jinta County	JinT	98°44'42''	40°11'2''	1329	枸杞Lycium barbarum	33	2023?07?18
嘉峪关市Jiayuguan City	JYG	98°22'50''	39°50'38''	1678	枸杞Lycium barbarum	22	2023?08?17
酒泉市Jiuquan City	JQS	98°30'24''	39°46'46''	1527	枸杞Lycium barbarum	17	2023?07?17
古浪县Gulang County	GLX	103°37'3''	37°32'58''	2049	枸杞Lycium barbarum	28	2023?08?04
兰州市Lanzhou City	LZS	103°37'3''	36°5′24″	1517	枸杞Lycium barbarum	22	2023?07?03
景泰县Jingtai County	JTX	104°6'28''	37°17'7''	1702	枸杞Lycium barbarum	40	2023?08?04
靖远县Jingyuan County	JYX	105°4'29''	36°57'23''	1384	枸杞Lycium barbarum	40	2023?07?31
阿克塞县Akesai County	AKS	94°17'53''	39°39'24''	3131	枸杞Lycium barbarum	24	2023?08?15
石河子市Shihezi City	SHZ	85°28'25''	44°53'54''	446	枸杞Lycium barbarum	28	2023?08?22
格尔木市Geermu City	GEM	94°30′47″	36°0′38″	2658	枸杞Lycium barbarum	24	2023?07?15
德令哈市Delingha City	DLH	96°24′36″	36°25′12″	2815	枸杞Lycium barbarum	24	2023?06?18

种群代码 Population code	AKS	DLH	GEM	GLX	HNQ	HSP	JinT	JQS	JTX	JYG	JYX	LTQ	LZS	SHZ	SPT	XXQ	YMS	ZNX
AKS		0.000	0.000	0.000	inf	0.000	0.000	0.000	inf	0.303	0.478	0.000	0.000	0.000	1.012	inf	inf	0.478
DLH	0.000		0.000	0.000	inf	0.000	0.000	0.000	inf	0.272	0.423	0.000	0.000	0.000	0.954	inf	inf	0.423
GEM	0.000	0.000		0.000	inf	0.000	0.000	0.000	inf	0.198	0.295	0.000	0.000	0.000	0.824	inf	inf	0.295
GLX	0.000	0.000	0.000		inf	0.000	0.000	0.000	inf	0.237	0.363	0.000	0.000	0.000	0.892	inf	inf	0.363
HNQ	1.000	1.000	1.000	1.000		inf	inf	inf	inf	1.165	1.056	inf	inf	inf	0.200	inf	inf	1.056
HSP	0.000	0.000	0.000	0.000	1.000		0.000	0.000	inf	0.198	0.295	0.000	0.000	0.000	0.824	inf	inf	0.295
JinT	0.000	0.000	0.000	0.000	1.000	0.000		0.000	inf	0.198	0.295	0.000	0.000	0.000	0.824	inf	inf	0.295
JQS	0.000	0.000	0.000	0.000	1.000	0.000	0.000		inf	0.303	0.478	0.000	0.000	0.000	1.012	inf	inf	0.478
JTX	1.000	1.000	1.000	1.000	1.000	1.000	1.000	1.000		0.341	0.929	inf	inf	inf	1.141	inf	inf	0.929
JYG	0.262	0.238	0.179	0.211	0.688	0.179	0.179	0.262	0.289		0.108	0.272	0.303	0.237	0.490	0.649	0.649	0.108
JYX	0.380	0.345	0.256	0.304	0.652	0.256	0.256	0.380	0.605	0.103		0.423	0.478	0.363	0.248	0.651	0.651	0.000
LTQ	0.000	0.000	0.000	0.000	1.000	0.000	0.000	0.000	1.000	0.238	0.345		0.000	0.000	0.954	inf	inf	0.423
LZS	0.000	0.000	0.000	0.000	1.000	0.000	0.000	0.000	1.000	0.262	0.380	0.000		0.000	1.012	inf	inf	0.478
SHZ	0.000	0.000	0.000	0.000	1.000	0.000	0.000	0.000	1.000	0.211	0.304	0.000	0.000		0.892	inf	inf	0.363
SPT	0.636	0.615	0.561	0.590	0.181	0.561	0.561	0.636	0.681	0.388	0.220	0.615	0.636	0.590		0.710	0.710	0.248
XXQ	1.000	1.000	1.000	1.000	1.000	1.000	1.000	1.000	1.000	0.478	0.478	1.000	1.000	1.000	0.508		0.000	0.651
YMS	1.000	1.000	1.000	1.000	1.000	1.000	1.000	1.000	1.000	0.478	0.478	1.000	1.000	1.000	0.508	0.000		0.651
ZNX	0.380	0.345	0.256	0.304	0.652	0.256	0.256	0.380	0.605	0.103	-0.043	0.345	0.380	0.304	0.220	0.478	0.478

变异来源 Source of variation	自由度 df	平方和 Sum of squares	方差组分 Variance components	变异百分率 Percentage of variation	Fst
种群间变异 Among populations	17	181.557	0.371 32 Va	64.28	0.642 78
种群内变异 Within populations	494	101.943	0.206 36 Vb	35.72
总变异 Total	511	283.500	0.577 68	100%

[1]	李鑫玉,王敏求,袁美灵,SaneyoshiUeno,武星彤,蔡梦颖,YoshihikoTsumura,文亚峰. 东亚孑遗植物柳杉属的遗传分化及其种群进化历史[J]. 林业科学, 2022, 58(6): 66-78.
[2]	张元臣,卢绍辉,龚东风,马兴莉. 基于COⅠ基因的我国悬铃木方翅网蝽(半翅目: 网蝽科)种群遗传多样性和遗传结构分析[J]. 林业科学, 2021, 57(8): 102-111.
[3]	马松梅, 王春成, 孙芳芳, 魏博, 聂迎彬. 濒危植物新疆野扁桃的遗传多样性[J]. 林业科学, 2019, 55(9): 71-80.
[4]	张守科, 方林鑫, 刘亚宁, 王毅, 张威, 舒金平, 张亚波, 汪阳东, 王浩杰. 茶籽象ATP合成酶基因在不同海拔选择压力下的遗传分化及结构变异[J]. 林业科学, 2019, 55(6): 65-73.
[5]	李伟,其其格,黄旭,岳阳,尹靖琨,王瑞俭. 蓝莓栽培品种的DNA条形码[J]. 林业科学, 2019, 55(12): 151-161.
[6]	王雁红, 俞琦, 杨佳, 赵鹏, 李忠虎, 赵桂仿. 基于核微卫星的短柄枹栎居群遗传多样性和遗传结构[J]. 林业科学, 2015, 51(12): 121-131.
[7]	杨钤, 谢映平, 樊金华, 邵生富, 吴俊, 王彦士, 赵常胜, 张英伟. 日本松干蚧3个地理种群的遗传分化[J]. 林业科学, 2013, 49(12): 88-96.
[8]	夏明瑞;周国娜;高宝嘉;. 不同林分类型油松毛虫CO Ⅰ 基因变异分析[J]. 林业科学, 2012, 48(9): 171-175.
[9]	李楠;柳新红;李因刚;李海波;盛炜彤;惠刚盈;郑勇奇. 白花树天然群体的遗传多样性[J]. 林业科学, 2012, 48(11): 49-56.
[10]	唐琴;曾秀丽;廖明安;潘光堂;扎西;龚君华;次仁卓嘎. 大花黄牡丹遗传多样性的SRAP分析[J]. 林业科学, 2012, 48(1): 70-76.
[11]	高宝嘉;杜娟;高素红;刘军侠. 美国白蛾种群的遗传多样性与遗传分化[J]. 林业科学, 2010, 46(8): 120-124.
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[13]	张蕊　周志春　金国庆　骆文坚. 南方红豆杉种源遗传多样性和遗传分化[J]. 林业科学, 2009, 12(1): 50-56.
[14]	黄久香黄妃本许涵李意德庄雪影. 海南岛青梅AFLP标记的遗传多样性*[J]. 林业科学, 2008, 44(5): 46-52.
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