棉蚜体内感染沃尔巴克氏体（Wolbachia）的分子检测

Wolbachia是存在于节肢动物体内的一类呈母系遗传的细胞内共生细菌 ,这类细菌可以通过卵的细胞质传播并参与调控寄主的生殖活动。通过对Wolbachia外膜蛋白质的wsp基因进行特异性扩增 ,证实了寄生于不同植物的棉蚜 (AphisgossypiiGlover)体内均有感染 ,说明Wolbachia可能广泛存在于棉蚜体内 ,扩增出的Wolbachia目的片段为 5 90bp左右。通过对棉蚜体内感染的Wolbachia的wsp基因序列进行分子检测 ,为进一步研究棉蚜的孤雌生殖与Wolbachia的相关关系等奠定基础。     

我国三地区黑腹果蝇中Wolbachia的系统发育关系及其对宿主生殖的影响

【目的】Wolbachia 是广泛存在于节肢动物和丝状线虫体内的一类共生菌, 能够以多种方式对宿主产生影响。精卵细胞质不亲和（CI）是其引起的最普遍的表型, 即感染Wolbachia的雄性宿主与未感染或感染不同品系的雌性宿主交配后, 不能产生后代或后代极少, 而感染同品系Wolbachia的雌雄宿主交配后则能正常产生后代。我们前期研究发现, 湖北武汉、 云南六库和天津3个地区黑腹果蝇Drosophila melanogaster被Wolbachia感染。本研究旨在明确这3个地区黑腹果蝇中Wolbachia的系统发育关系及其对宿主生殖的影响。【方法】利用Clustal X软件对Wolbachia的wsp基因序列进行比对, 利用MEGA软件构建系统发育树。采用多位点序列分型（MLST）的方法对Wolbachia进行分型。通过区内交配和区之间杂交的方式研究不同地区黑腹果蝇体内Wolbachia 的关系及其对果蝇生殖的影响。【结果】湖北武汉、 云南六库和天津3个地区黑腹果蝇中感染的Wolbachia都是属于A大组的Mel亚群。这3个地区果蝇感染的Wolbachia的序列类型（ST）不同, Wolbachia之间存在一定的差异。湖北武汉和天津果蝇中的Wolbachia能引起强烈的CI表型, 而云南六库果蝇中的Wolbachia引起的CI强度相对较弱。武汉果蝇中Wolbachia不能完全挽救天津果蝇中Wolbachia引起的CI表型, 而天津果蝇中Wolbachia也不能完全挽救武汉果蝇中Wolbachia引起的CI表型。【结论】武汉和天津地区黑腹果蝇中的Wolbachia可能距离较远。Wolbachia的长期共生可能对黑腹果蝇的进化产生了一定的影响, 湖北武汉与云南六库的黑腹果蝇中感染的Wolbachia属于不同的序列类型, 这2个地区的黑腹果蝇已发生了一定的分歧, 产生了一定的生殖隔离。     

苹果蠹蛾体内wolbachia wsp基因克隆与序列分析

【目的】对苹果蠹蛾Cydia pomonella L.体内共生菌Wolbachia进行分子生物学鉴定,确定该虫体内Wolbachia的进化位置,为进一步探讨Wolbachia对其生殖作用的调控机制提供理论依据。【方法】应用Wolbachia的wsp基因特异引物,通过PCR扩增法检测了苹果蠹蛾10个地理种群(新疆伊犁、吐鲁番、和田、石河子、奎屯、哈密、库尔勒、阿拉尔、喀什、和甘肃张掖)感染Wolbachia的状况,并对阿拉尔种群体内的Wolbachia的wsp基因进行测序和序列分析。【结果】苹果蠹蛾10个地理种群全部感染了tWolbachia,利用wsp基因的特异性引物从阿拉尔种群体内扩增出了617 bp的Wolbachia的wsp基因片段(GenBank登录号为KC832324),系统发育分析结果表明,苹果蠹蛾体内感染的Wolbachia属于A群Dor亚群,与锤角细蜂亲缘关系较近。【结论】苹果蠹蛾体内普遍感染了Wolbachia,属于A群Dor亚群。     

Wolbachia infection in crustaceans: novel hosts and potential routes for horizontal transmission

Thirty‐five percent of isopods are estimated to be infected by Wolbachia, an intracellular maternally inherited α‐Proteobacterium. Previous studies have indicated that horizontal transfer of Wolbachia strains may occur, although the mechanisms are unclear. The wsp gene was sequenced from 17 Wolbachia strains harboured by crustacean host species and three from their associated predators and parasites. Two major clades of Wolbachia were found in crustacean, with relatives also found in insects, the other restricted to crustaceans. Highly divergent Wolbachia strains were found in a woodlouse‐eating spider and its prey, suggesting no intertaxon bacterial exchange via the predator–prey route. The phylogenetic proximity of Wolbachia from parasitoid flies or phoretic mites to those from isopods suggests that horizontal symbiont transmission may have occurred between those taxa. Two distant Wolbachia strains were detected in two intertidal amphipods; these strains were closely related to different coastal isopod symbionts, suggesting Wolbachia transmission may occur between distantly related crustacean hosts living under the same ecological conditions.     

Occurrence of Wolbachia in central European weevils: correlations with host systematics,ecology, and biology

We studied the occurrence of Wolbachia in relation to the systematics, ecology, and biology of 40 weevil species from central Europe. Identification of Wolbachia supergroups and phylogeny was performed on the basis of 16S rDNA, ftsZ, wsp, and hcpA sequences. Sixteen species (40%) were infected by Wolbachia. Six of these possess only supergroup A (15% of all studied species, 37.5% of the infected species), and four harbored only supergroup B (10 and 25%, respectively). Six species were infected by both supergroups A and B or their genomes harbored parts of these two supergroups (15 and 37.5%, respectively). No differences between Wolbachia supergroup frequencies were detected. There was almost no correlation between Wolbachia phylogeny and host systematics and phylogeny at the level of subfamily and tribe, because the representatives of both supergroups were detected in all the studied multi‐species tribes. Wolbachia strains were probably inherited from a common ancestor only in the case of the genus Strophosoma, where two of three analyzed species possessed bacteria which are genetically very close in all the studied genes. There was also only limited congruence between phylogenies obtained from the four studied genes. These results suggest horizontal transmission of Wolbachia strains between species and recombination events between different strains. A significant correlation was detected between infected and uninfected species in relation to mobility (flying species were 2× more frequently infected than non‐flying species), foraging (polyphagous species were 2.5× less frequently infected than mono‐ or oligophagous species), and reproductive mode (parthenogenetic weevils were infected nearly 2× as often as bisexuals). No differences were detected between mesophilous and xerothermophilous species, nor between those inhabiting open areas vs. arboreal species. However, these results might have been influenced by common ancestry among the studied weevils. Because weevils include many plant pests of economic importance, it is possible to use these data in developing alternative, biology‐based strategies for controlling them.     

First evidence of Wolbachia infection in populations of grasshopper Podisma sapporensis (Orthoptera: Acrididae)

The brachypterous grasshopper Podisma sapporensis (Orthoptera: Acrididae) is distributed throughout the Sakhalin, Kunashir and Hokkaido Islands. Karyotypes of this species consist of two major chromosomal races with different sex chromosome systems, XO/XX and XY/XX. Molecular phylogeographic analysis of the chromosome races and subraces confirms the genetic divergence of the races and subraces in P. sapporensis. Here we first report that P. sapporensis is infected with Wolbachia consisting of three variants on wsp locus, while gatB locus was monomorphic. Furthermore, observation of cell tissue of P. sapporensis using electron microscopy confirmed the infection of Wolbachia that was inferred from polymerase chain reaction and revealed the distribution of the bacteria in the head, thorax and abdomen of P. sapporensis embryos. Our finding may shed new light on Wolbachia as a possible agent causing hybrid dysfunction resulting from experimental crosses between chromosome races or subraces of P. sapporensis.     

我国蚊虫体内感染的Wolbachia的wsp基因序列测定与分析

测定了我国尖音库蚊复合组和白纹伊蚊蚊虫体内感染的Wolbachia株的wsp基因序列。核苷酸和氨基酸的同源性及系统关系分析表明,我国尖音库蚊复合组和白纹伊蚊中Wolbachia株的wsp基因序列与Pip组其它株的核苷酸及氨基酸同源性分别为98%～100%和97%～100%, 属B大组Wolbachia中的Pip组。     

湖南三地区麦氏安瘿蜂体内Wolbachia 的感染及其wsp基因序列分析

为检测麦氏安瘿蜂Andricus mairei Kieffer有无Wolbachia感染, 本研究对其岳阳、 长沙和邵阳3种群雌、 雄成虫体内Wolbachia的wsp基因进行了PCR检测, 进而对获得的基因片段进行了序列分析。结果显示, 麦氏安瘿蜂岳阳、 长沙及邵阳种群雌、 雄成虫均有Wolbachia感染, 除邵阳种群雌成虫的感染率为80%之外, 其他均为100%。3个种群Wolbachia的wsp基因序列长度皆为561 bp, 且序列完全一致。麦氏安瘿蜂Wolbachia的wsp基因序列与已知瘿蜂族(Cynipini) Neuroterus macropterus、 Biorhiza pallida及Andricus solitarius （strain 1）以及Synergini族Synergus crassicornis感染的Wolbachia的一致性达95%。除Synergini族Ceroptres cerri感染的Wolbachia属于B群（B group）之外, 瘿蜂感染的Wolbachia均属于A群（A group）。在NJ系统树中, 麦氏安瘿蜂与瘿蜂族Neuroterus macropterus、 Biorhiza pallida和Andricus solitarius （strain 1）及Synergini族Synergus crassicornis感染的Wolbachia聚合在同一分支。此外, 麦氏安瘿蜂岳阳、 长沙和邵阳种群均获得了雌、 雄成虫, 其雌性率分别为15.3%, 12.1%和19.8%, 表现出明显的雄性比偏高。结果提示与瘿蜂族的其他已报道的种类一样, Wolbachia与麦氏安瘿蜂的共生并不诱导其营产雌孤雌生殖。     

The incidence and diversity of Wolbachia in gallwasps (Hymenoptera; Cynipidae) on oak

Wolbachia bacteria infect approximately 20% of all insect species, and cause a range of alterations to host reproduction, including imposition of thelytoky. The incidence and phenotypic impact of Wolbachia remains to be established in many insect taxa, and considerable research effort is currently focused on its association with particular reproductive modes and the relative importance of the various pathways via which infection occurs. Gallwasps represent an attractive system for addressing these issues for two reasons. First, they show a diversity of reproductive modes (including arrhenotoky, thelytoky and cyclical parthenogenesis) in which the impact of Wolbachia infection can be examined. Second, they occupy two intimately linked trophic niches (gall-inducers and inquilines) between which there is potential for the horizontal exchange of Wolbachia infection. In the arrhenotokous gallwasp lineages screened to date (the herb-galling 'Aylacini' and the rose-galling Diplolepidini), Wolbachia infection always induces thelytoky. The impact of Wolbachia in other arrhenotokous clades, and in the cyclically parthenogenetic clades remains unknown. Here we use polymerase chain reaction (PCR) screening and sequence data for two Wolbachia genes (wsp and ftsZ) to examine the prevalence and incidence of Wolbachia infection in 64 species (a total of 609 individuals) in two further tribes: the arrhenotokous inquilines (tribe Synergini), and the cyclically parthenogenetic oak gallwasps (tribe Cynipini). We ask: (i) whether Wolbachia infection has any apparent impact on host reproduction in the two tribes and (ii) whether there is any correlation between Wolbachia infection and the apparent lack of an arrhenotokous generation in many oak gallwasp life cycles. We show: (i) that Wolbachia infection is rare in the Cynipini. Infected species show no deviation from cyclical parthenogenesis, and infection is no more common in species known only from a thelytokous generation; (ii) that there is a higher incidence of infection within the arrhenotokous inquilines, and generally in gallwasp tribes without cyclical parthenogensis; (iii) all Wolbachia-positive inquiline species are known to possess males, implying either that Wolbachia infection does not result in loss of sex in this tribe or, more probably, that (as for some rose gallwasps) Wolbachia infection leads to loss of sex in specific populations; and (iv) although we find some inquilines and gall inducers to be infected with Wolbachia having the same wsp sequence, these hosts are not members of the same gall communities, arguing against frequent horizontal transmission between these two trophic groups. We suggest that exchange may be mediated by the generalist parasitoids common in oak galls.     

Prevailing triple infection with Wolbachia in Callosobruchus chinensis (Coleoptera: Bruchidae)

Prevailing triple infection with three distinct Wolbachia strains was identified in Japanese populations of the adzuki bean beetle, Callosobruchus chinensis. When a polymerase chain reaction (PCR) assay was conducted using universal primers for ftsZ and wsp, Wolbachia was detected in all the individuals examined, 288 males and 334 females from nine Japanese populations. PCR-restriction fragment length polymorphism (RFLP) analysis of cloned wsp gene fragments from single insects revealed that three types of wsp sequences coexist in the insects. Molecular phylogenetic analysis of the wsp sequences unequivocally demonstrated that C. chinensis harbours three phylogenetically distinct Wolbachia, tentatively designated as wBruCon, wBruOri and wBruAus, respectively. Diagnostic PCR analysis using specific primers demonstrated that, of 175 males and 235 females from nine local populations, infection frequencies with wBruCon, wBruOri and wBruAus were 100%, 96.3% and 97.0%, respectively. As for the infection status of individuals, triple infection (93.7%) dominated over double infection (6.1%) and single infection (0.2%). The amounts of wBruCon, wBruOri and wBruAus in field-collected adult insects were analysed by using a quantitative PCR technique in terms of wsp gene copies per individual insect. Irrespective of original populations, wBruCon and wBruOri (107 -108 wsp copies/insect) were consistently greater in amount than wBruAus (106 -107 wsp copies/insect), suggesting that the population sizes of the three Wolbachia strains are controlled, although the mechanism is unknown. Mating experiments suggested that the three Wolbachia cause cytoplasmic incompatibility at different levels of intensity.