Auswahl der wissenschaftlichen Literatur zum Thema „Wolbachia endosymbionts“

Solitary bees are important pollinators of crops, with species in the family Megachilidae (mason bees) being used for orchard pollination. Commercial movement of these bees also moves their microbiota, including bacterial endosymbionts capable of reproductive manipulation. To test for presence of these bacteria, I screened commercially available species of US orchard pollinators and locally captured solitary bees from Kentucky. I also set up mason bee boxes in five apple orchards to examine recruitment of local pollinators. I conducted 454-pyrosequencing to determine bacterial diversity within four species followed by diagnostic PCR of 30 collected species (184 individuals) to determine infection frequency of selected endosymbionts. Consistent with literature, Wolbachia was abundant in these bees. I also found two other endosymbiotic bacteria, Sodalis (previously undetected in Hymenoptera), and Arsenophonus. Diagnostic screening demonstrated that Sodalis was present at moderate frequency in Osmia aglaia, whereas Arsenophonus was present at low frequency in Lasioglossum pilosum. Neither was found in other bees, but three bee species were infected with Sodalis-like endosymbionts. Although recruitment of bees to bee boxes was ineffective, I was able to independently collect native orchard pollinating Andrenidae species. My results demonstrate that other endosymbionts capable of reproductive manipulation, besides Wolbachia, are present in bees.

Most animals contain chronic microbial infections that inflict no harm on their hosts. Recently, the gut microflora of humans and other animals have been characterized. However, little is known about the forces that shape the diversity of these bacterial communities. In this work, comparative genomics was used to investigate the evolutionary dynamics of host-adapted bacterial communities, using Wolbachia infecting arthropods and Lactobacteria infecting bees as the main model systems. Wolbachia are maternally inherited bacteria that cause reproductive disorders in arthropods, such as feminization, male killing and parthenogenesis. These bacteria are difficult to study because they cannot be cultivated outside their hosts. We have developed a novel protocol employing multiple displacement amplification to isolate and sequence their genomes. Taxonomically, Wolbachia is classified into different supergroups. We have sequenced the genomes of Wolbachia strain wHa and wNo that belong to supergroup A and B, respectively, and are present as a double-infection in the fruit-fly Drosophila simulans. Together with previously published genomes, a supergroup comparison of strains belonging to supergroups A and B indicated rampant homologous recombination between strains that belong to the same supergroup but were isolated from different hosts. In contrast, we observed little recombination between strains of different supergroups that infect the same host. Likewise, phylogenetically distinct members of Lactic acid bacteria co-exist in the gut of the honeybee, Apis mellifera, without transfer of genes between phylotypes. Nor did we find any evidence of co-diversification between symbionts and hosts, as inferred from a study of 13 genomes of Lactobacillus kunkeei isolated from diverse bee species and different geographic origins. Although Lactobacillus kunkeii is the most frequently isolated strain from the honey stomach, we hypothesize that the primary niche is the beebread where the bacteria are likely to contribute to the fermentation process. In the human gut, the microbial community has been shown to interact with the immune system, and likewise the microbial communities associated with insects are thought to affect the health of their host. Therefore, a better understanding of the role and evolution of endosymbiotic communities is important for developing strategies to control the health of their hosts.

Wolbachia are maternally transmitted endosymbionts that naturally infect approximately 40% of all insect species and impose a range of phenotypic effects upon their hosts, including feminization, parthenogenesis, cytoplasmic incompatibility (CI) and male-killing. The genetic basis and mechanisms of these phenotypes remain mostly undetermined. Investigating new strains of Wolbachia can provide important insight into the biology of the symbiosis. In Drosophila pandora, two distinct Wolbachia strains co-exist to manipulate host reproduction, which are wPanCI (causing CI) and wPanMK (causing male-killing) respectively. Furthermore, wPanMK seems to rescue CI induced by wPanCI. To understand the molecular basis of CI and male-killing, genome sequencing and comparison projects with wPanCI and wPanMK were undertaken. To investigate the mechanism of CI, both cifA and cifB were compared among wMel, wPanCI and wPanMK; the cifB protein in wPanMK is truncated and has one base pair deletion, which indicating that it may be non-functional in wPanMK. The similar cifA gene in wPanCI and wPanMK and wPanMK’s ability to recue CI provide evidence for a previously toxin (cifB)-antitoxin (cifA) model; however, wPanMK cannot induce CI due to the mutation of cifB provide evidence that CI mechanism need both cifA and cifB. For male-killing mechanism, a spaid gene has been described to affect the male-killing in another endosymbiotic bacterium, Spiroplasma poulsonii. By comparing a spaid-like protein in different Wolbachia strains, a common structure with a protein-protein interaction domain and a cell death domain has been described and a spaid-like gene, wPanMK_288, has been found in wPanMK, which may be the manipulator gene to induce the male-killing. The study explains both two models of CI mechanism and provides a common structure and suggests putative genes for the expression of MK in Wolbachia and Spiroplasma.<br>Thesis (Masters)<br>Master of Science (MSc)<br>School of Environment and Sc<br>Science, Environment, Engineering and Technology<br>Full Text

Wolbachia (Alphaproteobacteria) is an inherited endosymbiont of arthropods and filarial nematodes and was reported to be widespread across insect taxa. While Wolbachia’s effects on host biology are not understood from most of these hosts, known Wolbachia-induced phenotypes cover a spectrum from obligate beneficial mutualism to reproductive manipulations and pathogenicity. Interestingly, data on Wolbachia within the most species-rich order of arthropods, the Coleoptera (beetles), are scarce. Therefore, we screened 128 species from seven beetle families (Buprestidae, Hydraenidae, Dytiscidae, Hydrophilidae, Gyrinidae, Haliplidae, and Noteridae) for the presence of Wolbachia. Our data show that, contrary to previous estimations, Wolbachia frequencies in beetles (31% overall) are comparable to the ones in other insects. In addition, we used Wolbachia MLST data and host phylogeny to explore the evolutionary history of Wolbachia strains from Hydraenidae, an aquatic lineage of beetles. Our data suggest that Wolbachia from Hydraenidae might be largely host genus specific and that Wolbachia strain phylogeny is not independent to that of its hosts. As this contrasts with most terrestrial Wolbachia–arthropod systems, one potential conclusion is that aquatic lifestyle of hosts may result in Wolbachia distribution patterns distinct from those of terrestrial hosts. Our data thus provide both insights into Wolbachia distribution among beetles in general and a first glimpse of Wolbachia distribution patterns among aquatic host lineages.

Reciprocal and homologous crosses were carried out using pairs or groups of twenty males and females for three biotypes of the whitefly Bemisia tabaci complex. Crosses were undertaken for the A biotype-Arizona (AzA), the B biotype-Africa (AzB), and the monophagous, Jatropha (Jat) biotype-Puerto Rico. The maternal haplotype pedigree of parents and selected offspring (F₁, F₂) was determined using the mitochondria cytochome oxidase I sequence. All reciprocal crosses yielded viable female offspring, indicating reproductively compatibility, except for AzB♀ x AzA♂, or AzB♀ x Jat♂ crosses, which yielded females unidirectionally. As an unidirectional pattern was reminiscent of cytoplasmic-mediated incompatibility (CI), the possibility was investigated that the phenotype might be caused by CI-bacteria, instead of a germ line barrier. Using the 16S rRNA sequence three prospective CI-bacterial species were identified in whitefly colonies. A Cardinium spp. (Bacteroidetes) was present in the A biotype (isolates AzA, CulA, RivA, SalA), whereas the B biotype (isolates AzB, FlB1, FlB2) was infected with Rickettsia bellii (Proteobacteria), and a Wolbachia spp. (Proteobacteria) was associated with the Jat biotype. The unidirectional incompatible phenotypes were consistent with CI-bacterial infection of AzA (Cardinium) and Jat (Wolbachia), but no such association was apparent for B biotype-Rickettsia infections. The bidirectional compatibility for Jat x AzA suggested a CI-bacteria-mediated reciprocal rescue. However, that Wolbachia-infected Jat♀ and Cardinium-infected AzA♂ crosses yielded fewer females, compared to AzA-Cardinium♀ and Jat- Wolbachia♂ crosses, suggested that Cardinium could better counter Wolbachia-induced female mortality than Wolbachia. This suggested the possibility that these phylogenetically divergent bacteria might utilize similar CI-mechanisms. In this study, the suspect CI-bacteria were strongly associated with complete or partial obstruction of gene flow in certain crosses, and with sex bias in the AzA x Jat crosses. This is the first evidence that female offspring can be produced between phylogeographically divergent, and polyphagous and monophagous B. tabaci, for which gene flow barriers are widely reported, suggesting that hybridization is utilized as a means of diversification in B. tabaci. The inability to rid colonies of CI-bacteria has necessitated introgression experiments to investigate direct CI-causality over CI-association.

Eight Wolbachia variants were identified in the wasp community. Identical Wolbachia variants were identified in inquiline and parasitoid wasp species suggesting that horizontal transmission of Wolbachia occurs in this community

Orientador: Odair Correa Bueno<br>Banca: Ana Eugênia C. Campos Farinha<br>Banca: Denise Selivon Scheepmaker<br>Resumo: O gênero Solenopsis tem distribuição cosmopolita, mas espécies do grupo S. saevissima, são nativas da América do Sul e inclui as conhecidas formigas lava-pés. Elas foram introduzidas de forma acidental em diversas regiões biogeográficas do mundo. No Brasil possuem ampla distribuição, mas têm preferência por áreas de atividade humana. São formigas altamente agressivas e são responsáveis por acidentes que podem levar a choques anafiláticos e à morte. As formigas apresentam associações de diferentes tipos com outros organismos, inclusive com bactérias endossimbiontes como a Wolbachia, bactéria intracelular que também infecta as formigas do gênero Solenopsis. No presente trabalho, procurou-se caracterizar as populações de lava-pés (Solenopsis spp.) de ampla área do território brasileiro, analisando o parentesco dessas populações e inferindo sobre sua filogenia. Além disso, foi investigada a presença, frequência e distribuição do endossimbionte Wolbachia em populações de Solenopsis spp. no Brasil. A caracterização das lava-pés foi baseada na análise do gene citocromo oxidase I e em estudos filogenéticos. Observou-se desde completa coerência geográfica, até polifilia para as espécies S. invicta e S. saevissima, o que demonstra claramente a diversidade desse gênero de formigas no Brasil. Existe a possibilidade de ocorrer populações isoladas reprodutivamente, tendo como decorrência processos evolutivos de especiação. Além disso, clados com espécies divergentes agrupadas podem trazer evidências de espécies erroneamente identificadas morfologicamente, presente em bancos de dados. O levantamento da ocorrência de Wolbachia foi baseado no gene wsp do endossimbionte e análises filogenéticas foram realizadas para inferir a história evolutiva dessas bactérias nas populações de lava-pés do país. Foi encontrada uma grande... (Resumo completo, clicar acesso eletrônico abaixo)<br>Abstract: The genus Solenopsis has a cosmopolitan distribution, but species of S. saevissima group are native from South America and include the known fire ant. They were accidentally introduced in several countries of the world. In Brazil they have wide distribution with preference for areas of human activity. Ants are highly aggressive and responsible for accidents that can lead to anaphylactic shock and death. The ants have different associations with other organisms, including bacteria endosymbionts such as Wolbachia, intracellular bacteria that also infect the ants of the Solenopsis genus. In this study, we sought to characterize the populations of fire ants (Solenopsis spp.) in a wide area of Brazil, analyzing the relationship of these populations and inferring their phylogeny. Furthermore, we investigated the presence, frequency and distribution of the endosymbiont Wolbachia in those populations of Solenopsis spp. in Brazil. The characterization of fire ants was based on analysis of the cytochrome oxidase I gene and on phylogenetic studies. It was observed that there were complete geographical coherence and polyphyly for the species S. invicta and S.saevissima, which clearly demonstrate the diversity of this genus of ants in Brazil. There is the possibility to occur reproductively isolated populations, leading to evolutionary processes of speciation. Furthermore, clustered clades with divergent species can bring evidences of species wrong morphologically identified, presents in databases. The survey of the occurrence of Wolbachia was based on the wsp gene of the endosymbiont and the phylogenetic analyses were performed to infer the evolutionary history of these bacteria in the populations of fire ants. There was a great diversity of Wolbachia in the genus Solenopsis, with 51% of the analyzed colonies presenting infection and the highest incidence was found in populations from... (Complete abstract click electronic access below)<br>Mestre