江苏烟粉虱生物型鉴定与危害程度分析

通过实地调查结合mtDNA COI基因测序方法,分析并鉴定了江苏地区主要作物上烟粉虱的危害程度及烟粉虱的生物型组成。序列检测表明,江苏地区烟粉虱种群生物型为Q型和B型,其中Q型烟粉虱占所测总样本94.40%,Q型烟粉虱在苏南、苏中和苏北的比例分别是97.5%、96.0%和91.67%,表明Q型烟粉虱已成为在江苏省主要生物型烟粉虱。同源性分析发现,江苏的Q型烟粉虱序列与浙江、美国和日本的Q型烟粉虱碱基序列相似性为100%,江苏的B型烟粉虱序列与巴基斯坦、日本和中国北京的B型烟粉虱序列同源性为100%。在江苏地区烟粉虱主要危害茄科的番茄、长茄、甜椒,葫芦科的黄瓜、西葫芦及锦葵科的苘麻、棉花,表现出虫口密度大,植株受害重,而十字花科的小白菜、大白菜、萝卜及豆科的菜豆、豇豆等受害较轻,苋科的苋菜和菊科的生菜受害最轻。     

烟粉虱B型和Q型群体遗传结构的RAPD分析

近20年来,烟粉虱B型传入世界各地并暴发成灾,成为一种重要的农业入侵害虫; 烟粉虱Q型则是近几年引起人们高度重视的一种新的入侵生物型,目前已传入许多国家并造成一定危害。本文利用RAPD分子标记对烟粉虱B型和Q型不同地理种群的遗传结构进行了分析。结果表明：（1）引物H16对烟粉虱B型不同种群扩增的特异带,能有效区分烟粉虱B型和Q型、浙江非B/Q型种群;（2）烟粉虱Q型种群各项遗传多样性指数均比烟粉虱B型的要高;（3）我国烟粉虱Q型来自伊比利亚半岛的可能性比来自中东地区的可能性要大。另外,聚类分析结果提示,RAPD分子标记能有效地区分烟粉虱不同生物型,但可能不适用于生物型之间亲缘关系分析。     

烟粉虱生物型的监测及其遗传结构研究

烟粉虱Bemisia tabaci(Gennadius)是一种重要的农业害虫并包括许多生物型,其中B型和Q型是入侵性较强的2种生物型。文章着重介绍近年来在烟粉虱生物型的监测及其遗传结构方面的研究进展。B型烟粉虱和Q型烟粉虱这2个生物型均已入侵我国,其中多数地区烟粉虱是B型烟粉虱,局部地区有Q型烟粉虱并呈现不断蔓延趋势。微卫星(SSR)分子标记分析结果表明我国B型烟粉虱的入侵来源具有多元化,而云南地区Q型烟粉虱来源比较单一。化学农药的使用能够影响室内种群的遗传结构,降低种群的遗传多样性。基于RAPD、ISSR分子标记的分析结果表明,Q型烟粉虱种群各项遗传多样性指数均比B型烟粉虱的高。今后加强烟粉虱入侵生物型的遗传结构及其种群动态关系等方面的研究,对于揭示烟粉虱的灾变机制及其控制具有重要的意义。     

江苏地区烟粉虱生物型演替研究初报

本文连续5年系统监测了江苏省13个地级市烟粉虱Bemisia tabaci(Gennadius)生物型的发生分布状况,探讨了它们的迁移扩散和演替规律。利用RAPD分子标记和mtDNA COI基因序列进行烟粉虱生物型鉴定,结果表明:江苏地区发生的烟粉虱生物型为B型和Q型。自2005年到2009年,B型烟粉虱在苏南和苏北地区的发生分布频率逐年下降,在苏北地区的发生分布频率由52.58%下降为22.22%,在苏南由56.52%下降为9.37%;而Q型烟粉虱在苏南和苏北的发生分布频率逐年升高,在苏北由47.42%上升至77.78%,在苏南由43.48%上升为90.63%。B型烟粉虱的发生分布范围由全省逐渐向苏北地区缩小,而Q型烟粉虱的发生分布范围逐渐扩大遍及全省;此外,Q型烟粉虱在江苏是由苏中和苏南地区向苏北地区扩散,并逐步取代B型烟粉虱成为江苏地区农作物的主要害虫。     

云南Q型烟粉虱种群的鉴定

利用mtDNACOⅠ基因片段作标记,对采自云南昆明一品红上的烟粉虱Bemisiatabaci(Gennadius)种群生物型进行了鉴定。结果表明,该种群COⅠ基因片段(501bp)与摩洛哥Q型、西班牙Q型烟粉虱的相应碱基序列具有极高的同源性,与2种Q型烟粉虱的COⅠ基因仅分别相差3个和4个碱基,同源性分别达到994%和992%。序列分析表明我国云南昆明一品红上存在Q生物型烟粉虱     

烟粉虱B型与Q型种群遗传多样性的AFLP分析

烟粉虱Bemisia tabaci(Gennadius)是由多种生物型或物种组成的复合种。Q型烟粉虱在我国部分地区正在取代B型烟粉虱成为优势生物型。烟粉虱Q型与B型遗传多样性比较研究为解析这2种生物型入侵的遗传学基础具有重要的意义。本文利用AFLP技术研究了Q型(包括Q1型、Q2型)、B型烟粉虱种群的遗传多样性。结果表明:Q型烟粉虱遗传多样性高于B型烟粉虱;Q1型烟粉虱各项遗传多样性指数均接近于Q2型。最后探讨了AFLP与SSR分子标记的各自特点。     

基于微卫星标记对中国Q型烟粉虱早期入侵种群与B型烟粉虱种群的遗传结构分析（英文）

2003年首次在云南昆明发现Q型烟粉虱Bemisia tabaci (Gennadius)传入中国。随后几年时间内, 它在许多省份逐年取代了B型烟粉虱种群。2008年后,Q型烟粉虱基本上成为了中国多数省份农区的优势生物型。为了进一步揭示Q型烟粉虱在中国快速扩散以及取代B型烟粉虱的遗传学基础, 本研究利用11个微卫星位点分析并比较了2003年中国云南昆明Q型烟粉虱入侵种群及其他地点的11个B型入侵种群, 西班牙2个Q型土著种群, 以色列1个Q型入侵种群, 以色列1个B型土著种群, 以及西班牙、 美国与澳大利亚的5个B型入侵种群的遗传结构。结果表明, 中国Q型烟粉虱早期种群（云南昆明种群）可能来自于西部地中海地区。中国B型烟粉虱种群遗传多样性高于西班牙、 澳大利亚、 美国B型种群, 中国B型可能存在多次传入或某个混合种群的再次传入。相对于原产地种群, 中国Q型烟粉虱早期入侵种群与B型烟粉虱种群遗传多样性并没有明显降低, 表明Q型与B型烟粉虱种群可能经历了较小的瓶颈效应或奠基者效应。中国Q型烟粉虱早期入侵种群遗传多样性高于B型烟粉虱种群, Q型烟粉虱这种较高的遗传多样性可能为其较强的生态适应性提供了遗传基础, 有利于Q型烟粉虱在新的环境下快速扩散并取代B型烟粉虱。     

不同生物型烟粉虱体内Wolbachia共生菌的检测及其系统树分析

Wolbachia是广泛分布于节肢动物体内一类共生细菌,它能够通过多种机制调控宿主的生殖方式。近年来的研究表明,Wolbachia与许多外来生物的成功入侵相关。本文利用长PCR的方法特异扩增了不同生物型烟粉虱（共24个种群）体内Wolbachia的wsp基因,结果发现B型和Q型烟粉虱入侵种群体内均未检测到Wolbachia,而在非B/Q型的浙江种群和肯尼亚种群体内检测到了Wolbachia。对该wsp基因进行测序并和已知序列进行同源性分析发现,浙江烟粉虱种群的Wolbachia属于B组Con/Rug亚种群,而肯尼亚种群属于B组Btab1亚种群。Wolbachia的存在与否可能与烟粉虱的成功入侵有一定的关系。图2表2参23     

中国部分地区烟粉虱生物型种类及系统发育关系分析

烟粉虱是一种危害严重的世界性害虫,是一个快速进化的复合种.本文利用mtCOI分子标记方法,对2010和2011年采自我国9个省(市)的33个烟粉虱种群进行了生物型鉴定和系统发育分析.结果表明： 我国目前存在着B型、Q型、ZHJ-1型、ZHJ-3型、An型以及Nauru型等6种生物型,且不同生物型的分布是不均匀的.遗传距离及系统发育树的分析结果显示,海南省的An型和台湾省的An型聚为一支,为同一来源;中国B型与来自法国和乌干达的B型的亲缘关系较近,同源性达到99%以上;中国的Q型与来自摩洛哥和法国的Q型聚为一个分支,而来自以色列和土耳其的Q型烟粉虱单独聚为一支,说明中国的Q型烟粉虱与来自地中海西部的Q型烟粉虱亲缘关系更近,可以推断中国的Q型烟粉虱的起源地为地中海西部地区.
     

微卫星位点BEM06与BEM23鉴别烟粉虱B型与Q型的有效性

烟粉虱Bemisia tabaci (Gennadius) B型与Q型是烟粉虱复合种中入侵性较强、分布较广的2种生物型, 当前在许多地区混合发生。这2种生物型的快速鉴别对其种群动态调查及入侵生态学研究具有重要价值。为了验证微卫星位点BEM06与BEM23鉴别B型与Q型烟粉虱的有效性, 本研究分析了这2个微卫星位点的等位基因在国内外17个B型、4个Q型、3个非B/Q型烟粉虱种群的分布特点。结果表明: 这2个微卫星位点的联合使用可鉴别B型与Q型烟粉虱, 但是无法有效地将B型、Q型与一些非B/Q型烟粉虱某些个体区分开来。结果提示: 利用微卫星位点BEM06与BEM23鉴别B型与Q型烟粉虱具有一定的局限性, 尤其是田间烟粉虱存在其他生物型时需要慎重使用这种鉴别方法。     

A phylogeographical analysis of the bemisia tabaci species complex based on mitochondrial DNA markers

Mitochondrial 16S ( approximately 550 bp) and cytochrome oxidase I (COI) ( approximately 700 bp) sequences were utilized as markers to reconstruct a phylogeography for representative populations or biotypes of Bemisia tabaci. 16S sequences exhibited less divergence than COI sequences. Of the 429 characters examined for COI sequences, 185 sites were invariant, 244 were variable and 108 were informative. COI sequence identities yielded distances ranging from less than 1% to greater than 17%. Whitefly 16S sequences of 456 characters were analysed which consisted of 298 invariant sites, 158 variable sites and 53 informative sites. Phylogenetic analyses conducted by maximum parsimony, maximum-likelihood and neighbour-joining methods yielded almost identical phylogenetic reconstructions of trees that separated whiteflies based on geographical origin. The 16S and COI sequence data indicate that the B-biotype originated in the Old World (Europe, Asia and Africa) and is most closely related to B-like variants from Israel and Yemen, with the next closest relative being a biotype from Sudan. These data confirm the biochemical, genetic and behavioural polymorphisms described previously for B. tabaci. The consideration of all global variants of B. tabaci as a highly cryptic group of sibling species is argued.     

Analysis of genetic diversity among different geographical populations and determination of biotypes of Bemisia tabaci in China

Abstract:  Analysis of the genetic diversity among 27 different geographical populations of Bemisia tabaci and determination of biotypes of B. tabaci in China based on amplified fragment-length polymorphism (AFLP) and the mitochondrial cytochrome oxidase I (mtDNA COI) gene sequences were conducted. In AFLP assay, the use of five primer combinations selected from 64 primer combinations allowed the identification of 229 polymorphic bands (97.03%) from 60 to 500 bp, suggesting abundant genetic diversity among different geographical populations of B. tabaci. To further identify biotypes of B. tabaci in China, the mtDNA COI gene sequences of nine representative populations from China, Israel and Spain were obtained. Molecular phylogenetic tree based on AFLP and mtDNA COI gene analyses revealed the presence, in China, of at least four different genetic groups of B. tabaci. B biotype, Q biotype and two non-B/Q biotype. B biotype was distributed nationwide. Q biotype was present only in the local region of China including the YunNan province and BeiJing city. This was also the first report about the invasion of Q biotype into China. Of the other two non-B/Q biotype groups, one was found in ShanDong and HeBei provinces, and another in ZheJiang province. The non-B/Q biotype ZheJiang population showed very high similarity with another Asian population India-IW ( AF110704 ) in mtDNA COI sequences and was possibly a Chinese indigenous population. The close monitoring of the Q biotype in locales of China where commercial plants were exported or imported, is now essential to avoid the further accidental distribution of the Q biotype.     

Prevalence of Wolbachia supergroups A and B in Bemisia tabaci (Hemiptera: Aleyrodidae) and some of its natural enemies

Wolbachia, a bacterial symbiont, is maternally transmitted in arthropods and nematodes. We report a systematic survey of Wolbachia taxonomy in the sweetpotato whitefly, Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae), and in some of its natural enemies. For the first time, Wolbachia infections in B. tabaci are correlated with various whitefly genetic groups, host plants, and natural enemies as well as with geographical regions. Polymerase chain reaction using 16S rDNA and fisZ genes revealed two Wolbachia supergroups, A and B, exist as single or double infections in B. tabaci as well as in some of its aphelinid parasitoids and predatory beetles. Approximately 89% of B. tabaci sampled were infected by Wolbachia, among which 34% were infected by A, 51% were infected by B, and 5% were infected by both A and B supergroups. These infection frequencies differed among B. tabaci genetic groups and locations. The invasive B. tabaci genetic group from the Middle East Asia Minor 1 (also referred as B biotype) and Mediterranean (also referred as Q biotype) was more likely to harbor A than B, whereas native genetic groups in AsiaI and AsiaII were more likely to harbor B than A. Although 60% of aphelinid parasitoids and 72% of coccinellid beetles also were infected by Wolbachia, they were more likely to host B than A. Furthermore, for the first time we report Wolbachia in B biotype from specimens collected outside of China. Construction of a phylogenetic tree clearly indicated that the Wolbachia sequences from different genetic groups of B. tabaci were not only similar to each other but also to sequences from beetles and parasitoids, which may provide evidence of coevolution and horizontal transmission of Wolbachia populations.     

Global relationships of Bemisia tabaci (Hemiptera: Aleyrodidae) revealed using Bayesian analysis of mitochondrial COI DNA sequences

Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae) is a species complex that is one of the most devastating agricultural pests worldwide and affects a broad range of food, fiber and ornamental crops. Unfortunately, using parsimony and neighbor joining methods, global phylogenetic relationships of the major races/biotypes of B. tabaci remain unresolved. Aside from the limitations of these methods, phylogenetic analyses have been limited to only small subsets of the global collection of B. tabaci, and thus limited taxon sampling has confounded the analyses. To improve our understanding of global B. tabaci phylogenetic relationships, a Bayesian phylogenetic technique was utilized to elucidate the relationships among all COI DNA sequence data available in GenBank for B. tabaci worldwide (366 specimens). As a result, the first well-resolved phylogeny for the B. tabaci species complex was produced showing 12 major well-resolved (0.70 posterior probability or above) genetic groups: B. tabaci (Mediterranean/Asia Minor/Africa), B. tabaci (Mediterranean), B. tabaci (Indian Ocean), B. tabaci (sub-Saharan Africa silverleafing), B. tabaci (Asia I), B. tabaci (Australia), B. tabaci (China), B. tabaci (Asia II), B. tabaci (Italy), B. tabaci (New World), B. tabaci (sub-Saharan Africa non-silverleafing) and B. tabaci (Uganda sweet potato). Further analysis of this phylogeny shows a close relationship of the New World B. tabaci with Asian biotypes, and characteristics of the major sub-Saharan Africa non-silverleafing clade strongly supports an African origin of B. tabaci due to its position at the base of the global phylogeny, and the diversity of well-resolved sub-clades within this group. Bayesian re-analyses of B. tabaci ITS, COI, and a combined dataset from a previous study resulted in seven major well-resolved races with high posterior probabilities, also showing the utility of the Bayesian method. Relationships of the 12 major B. tabaci genetic groups are discussed herein.     

Symbiont diversity and non-random hybridization among indigenous (Ms) and invasive (B) biotypes of Bemisia tabaci

The whitefly Bemisia tabaci (Hemiptera: Aleyrodidae) is a worldwide pest and a vector of numerous plant viruses. B. tabaci is composed of dozens of morphologically indistinguishable biotypes and its taxonomic status is still controversial. This phloem-feeder harbours the primary symbiont Portiera aleyrodidarum and potentially six secondary symbionts: Cardinium, Arsenophonus, Hamiltonella, Rickettsia, Wolbachia and Fritschea. In the southwest Indian Ocean, La Réunion hosts two biotypes of this species: B (invasive) and Ms (indigenous). A multiplex PCR was developed to study the symbiont community of B. tabaci on La Réunion. Symbiont community prevalence and composition, host mitochondrial and nuclear genetic diversity, as well as host plant and localization, were described on field populations of La Réunion for B and Ms B. tabaci biotypes and their hybrids. A clear association between symbiotypes and biotypes was shown. Cardinium, Arsenophonus and Rickettsia were found in the Ms biotype (73.6%, 64.2% and 3.3%, respectively). Hamiltonella (exclusively) and Rickettsia were found in the B biotype (78% and 91.2%, respectively). Hybrids harboured all symbiotypes found in Ms and B populations, but with a higher prevalence of Ms symbiotypes than expected under random hybridization. An unexpected majority was Cardinium mono-infected (65.6%), and a striking minority (9%) harboured Cardinium/Arsenophonus. In the hybrids only, genetic diversity was linked to symbiotype. Among the hybrids, significant links were found between symbiotypes and: (i) mitochondrial COI sequences, i.e. maternal origin; and (ii) alleles of nuclear microsatellite loci, specific to either Ms or B parental biotype. Taken together, our results suggest that Cardinium and/or Arsenophonus may manipulate the reproduction of indigenous (Ms) with invasive (B) biotypes of Bemisia tabaci.     

内共生菌Cardinium对烟粉虱MED隐种耐药性的影响

【目的】次生内共生菌感染可影响烟粉虱Bemisia tabaci对杀虫剂的敏感性。本研究旨在揭示内共生菌Cardinium感染对烟粉虱B. tabaci MED隐种耐药性的影响。【方法】室内测定海南陵水与山东寿光烟粉虱MED隐种种群内遗传背景一致的Cardinium感染与未感染品系对不同浓度新烟碱类杀虫剂噻虫嗪和吡虫啉的耐药性。【结果】各浓度噻虫嗪和吡虫啉处理后,烟粉虱陵水种群感染Cardinium品系死亡率比未感染品系显著降低;100, 150, 175和200 mg/L噻虫嗪以及175和200 mg/L吡虫啉处理后,烟粉虱寿光种群感染Cardinium品系死亡率比未感染品系显著上升。相对于未感染品系,烟粉虱陵水种群感染Cardinium品系对噻虫嗪、吡虫啉的抗性倍数(RR)分别是1.355和1.847,烟粉虱寿光种群感染Cardinium品系的RR分别是0.790和0.847。【结论】内共生菌Cardinium感染能影响烟粉虱MED隐种对噻虫嗪和吡虫啉的耐药性,且这种影响在不同种群间存在差异。研究结果对于揭示烟粉虱MED隐种的种群适应性及扩张机制具有重要参考价值。