Interaction tripartite Aedes albopictus, Wolbachia, arbovirus : mécanismes moléculaires et cellulaires de l’interférence microbienne / Aedes albopictus, Wolbachia, arbovirus tri-partite interaction : molecular and cellular mechanisms of microbial interference

Saucereau, Yoann

09 December 2016

L'émergence et la réémergence d'arboviroses au niveau mondial sont responsables de pathologies pouvant causer le décès des personnes infectées et elles sont transmises par des moustiques vecteurs. En l'absence de prophylaxies efficaces, les moyens de lutte actuels reposent essentiellement sur l'utilisation d'insecticides, mais ces derniers sont nocifs pour les écosystèmes et des résistances apparaissent chez la plupart des vecteurs. Il devient nécessaire de développer des moyens de lutte alternatifs. La découverte du potentiel antiviral de certaines bactéries symbiotiques des moustiques a ouvert de nouvelles voies pour le développement de la lutte biologique. Mon projet de thèse porte sur l'étude des mécanismes déclenchés dans l'interaction tripartite entre le moustique tigre Aedes albopictus, ses deux souches de Wolbachia, wAlbA et wAlbB, et deux arbovirus (Chikungunya et Dengue) dont il est un vecteur avéré. Originaire d'Asie du Sud Est, il est devenu une préoccupation majeure de santé publique, notamment pour son fort pouvoir invasif, ayant colonisé les quatre autres continents, ainsi que pour son statut de vecteur de nombreux arbovirus et certaines filaires. Les résultats de nos travaux ont montré un potentiel antiviral de la bactérie chez les moustiques infectés par Wolbachia en comparaison des moustiques aposymbiotiques. Les analyses du protéome et du transcriptome ont permis d'identifier certains mécanismes cellulaires et moléculaires du moustique spécifiquement modulés par la présence de Wolbachia ou des arbovirus, mais aussi deux partenaires microbiens simultanément. Ces approches ont permis de mettre en évidence le rôle important du métabolisme dans le maintien de l'intégrité cellulaire et du système immunitaire pour contrôler l'infection virale. En outre, nos résultats révèlent un patron de compétition entre bactérie et arbovirus contribuant à la compréhension du phénomène interférence observé chez les moustiques / The emergence and reemergence of arboviruses in the world are responsible for pathologies that can cause the death of infected and they are transmitted by mosquitoes. In absence of effective prophylaxis, current control methods are essentially based on the use of insecticides, but they are harmful to ecosystems and resistances appear in most vectors. It becomes necessary to develop alternative means of control. Discovery of the antiviral potential of some symbiotic bacteria mosquito has opened new avenues for the development of biological control. My PhD project focuses on the study of mechanisms triggered in the tripartite interaction between the Asian tiger mosquito, Aedes albopictus, two strains of Wolbachia, and wAlbA wAlbB and two Arbovirus (Chikungunya and Dengue) of which he is a proven vector. Native to Southeast Asia, it has become a major public health concern, particularly for its highly invasive, have colonized the four other continents, as well as its status vector many arboviruses and some wire. The results of our work has shown antiviral potential of bacteria in mosquitoes infected with Wolbachia in comparison aposymbiotic mosquitoes. The analyzes of the proteome and transcriptome have identified certain cellular and molecular mechanisms of mosquito specifically modulated by the presence of Wolbachia or arboviruses, but also two microbial partners simultaneously. These approaches have helped to highlight the important role of metabolism in maintaining cell integrity and immune system to control the viral infection. In addition, our results reveal a pattern competition between bacteria and arbovirus contributing to understanding the phenomenon interference observed in mosquitoes

Aedes albopictus

Wolbachia

Arbovirus

Interference microbienne

Aedes albopictus

Wolbachia

Arbovirus

Microbial interference

579.17

Bases génétiques et mécanismes cytologiques à l'origine de la diversité de l'incompatibilité cytoplasmique induite par Wolbachia chez le moustique Culex pipiens / Genetic bases and cytological mechanisms underlying cytoplasmic incompatibility diversity induced by Wolbachia in the Culex pipiens mosquito.

Bonneau, Manon

22 November 2018

Les Wolbachia sont des alpha-protéobactéries intracellulaires transmises verticalement de la mère aux descendants via les ovocytes. Du fait de ce mode de transmission, des stratégies de manipulation de la reproduction favorisant leur propagation ont été sélectionnées chez ces bactéries. La plus communément utilisée par Wolbachia s’appelle l’incompatibilité cytoplasmique (IC). L’IC a lieu lorsque des mâles infectés copulent avec des femelles non infectées ou infectées par des Wolbachia incompatibles et se traduit par la mort des descendants avant l’éclosion. L’IC est généralement conceptualisée comme un modèle mod/resc ou toxine/antidote dans lequel les Wolbachia présentes chez les mâles introduiraient dans les spermatozoïdes une toxine (fonction mod) qui, après la fécondation, entrainerait la mort des embryons, sauf si les Wolbachia présentes dans l’œuf produisent un antidote (fonction resc). C’est chez l’espèce de moustique Culex pipiens que la plus grande diversité de phénotypes d’IC a été décrite. Cette diversité repose uniquement sur la diversité des souches de Wolbachia hébergées par C. pipiens. Dans cette thèse, nous avons mené la première étude des mécanismes cytologiques responsables de la mort des embryons dans les croisements incompatibles chez C. pipiens. Nous avons montré que des défauts de condensation et de ségrégation de la chromatine paternelle lors de la première division embryonnaire entraînent la mort des embryons dans tous les croisements incompatibles étudiés. Ces défauts cellulaires sont les seuls observés, ce qui indique que la diversité de relations d’IC décrite chez C. pipiens ne repose pas sur une diversité de défauts cellulaires. L’étude, chez plusieurs souches de wPips, de l’opéron cidA/cidB dont l’implication fonctionnelle dans l’IC a récemment été mise en évidence chez la drosophile, nous a permis de montrer que cet opéron est amplifié et polymorphe dans tous les génomes de wPips séquencés. L’exploration des variants de cet opéron dans les génomes de Wolbachia infectant des populations naturelles de C. pipiens, à l’aide de plus de 250 lignées isofemelles, a permis d’associer de manière robuste une variation de cidB avec un changement dans le phénotype mod de certains mâles. En outre, la présence d’un variant ubiquitaire de cidA, supporte le rôle de ce gène dans la fonction resc. Ainsi, chez C. pipiens, l’opéron cidA/cidB grâce à son amplification et sa diversification est impliqué dans la diversité des phénotypes d’IC et fonctionnerait comme un système toxine-mod /antidote-resc : cidB étant impliqué dans la fonction mod et cidA dans la fonction resc. / Wolbachia are intracellular alpha-proteobacteria vertically transmitted from mothers to their offspring through oocytes. As a consequence of this transmission mode, reproductive manipulation strategies that promote bacteria spread in host populations have been selected. The most common manipulation used by Wolbachia is called cytoplasmic incompatibility (CI). CI occurs when infected males mate with uninfected or incompatible Wolbachia-infected females and results in the death of offspring before hatching. CI is generally conceptualized as a mod/resc or toxin/antidote model in which paternal Wolbachia would introduce a toxin (mod function) in sperms which would, after fertilization, induce embryonic death unless an antidote produced by maternal Wolbachia in the egg counteracts its effect (resc function). A to date unique diversity of CI phenotypes has been described in the mosquito species Culex pipiens. This diversity is based solely on the diversity of Wolbachia strains hosted by C. pipiens. In this PhD, we conducted, in C. pipiens, the first study of the cytological mechanism behind embryonic mortality in CI crosses. We showed that paternal chromatin condensation and segregation defects during the first embryonic division were responsible for embryonic death in all CI crosses. These CI defects were the only ones observed indicating that the diversity of CI phenotypes in C. pipiens is not based on a diversity of cellular mechanisms. We then studied the cidA/cidB operon in several wPip strains as the functional involvement of this operon in CI was recently demonstrated in Drosophila. We showed that this operon is amplified and polymorphic in all genomes of sequenced wPip. Investigation of cidA/cidB variants in Wolbachia genomes infecting natural populations of C. pipiens, using more than 250 isofemale lines, enabled us to reveal a robust association between cidB variations and change in mod phenotype. In addition, the presence of an ubiquitous cidA variant supports the role of this gene in the resc function. In C. pipiens, the cidA/cidB operon, through its amplification and diversification, is involved in the CI phenotypes diversity and would operate as a toxin-mod / antidote-resc system: cidB being involved in the mod function and cidA in the resc function.

Symbiose

Évolution

Génomique

Cytologie

Wolbachia

Culex pipiens

Symbiosis

Evolution

Genomics

Cytology

Wolbachia

Culex pipiens

Interaction entre la bactérie endosymbiotique Wolbachia et les moustiques du complexe Culex pipiens : Des génomes bactériens à la structuration des populations d’hôtes / Interaction between the endosymbiotic bacteria Wolbachia and mosquitoes of the Culex pipiens complex : from bacterial genomes to host population’s structuring

Dumas, Emilie

11 December 2013

Wolbachia est une bactérie endosymbiotique, intracellulaire et exclusivement transmise maternellement qui infecterait au moins 106 espèces d'insectes. Wolbachia manipule fréquemment la reproduction de ses hôte à son avantage, notamment en induisant une forme de stérilité conditionnelle appelée incompatibilité cytoplasmique (IC). Chez les moustiques du complexe Culex pipiens, une grande diversité de souches de Wolbachia et de types d'IC a été précédemment identifiée, mais plusieurs aspects de la biologie de cette association restaient peu connus. Les travaux présentés dans cette thèse ont notamment permis de caractériser (i) l'impact de Wolbachia sur la structuration génétique des populations hôtes et (ii) la diversité des souches de Wolbachia et, plus précisément d'appréhender le mécanisme de l'IC. Par un suivi de populations naturelles, nous avons mis en évidence que Wolbachia induisait une forte structuration de la diversité mitochondriale, mais aussi qu'elle participait à des événements répétés d'introgression cytoplasmique entre les différents membres du complexe Cx. pipiens. Nous avons également mené une étude de génomique comparative basée sur le séquençage de quatre génomes complets de Wolbachia très proches phylogénétiquement. Pour cela, nous avons mis en place une série d'analyses approfondies utilisant un large panel d'outils bioinformatiques couplés à des vérifications moléculaires. Nous avons montré qu'il existait peu de polymorphisme entre les groupes de Wolbachia infectant Cx. pipiens. De plus, ces études nous ont permis de mettre en évidence des gènes candidats qui pourraient être directement impliqués dans le mécanisme de l'IC. / Wolbachia is an intracellular bacterial symbiont, exclusively maternally inherited, infecting at least 106 species of insects. Wolbachia commonly manipulates insect reproduction to its own advantage, as well illustrated by a phenomenon of conditional sterility called cytoplasmic incompatibility (CI). In mosquitoes of Culex pipiens complex, a great diversity of Wolbachia strains and of CI types was previously identified, but several aspects of the biology of this symbiotic association remained unknown. The aim of the studies presented in this thesis is to characterize (i) the impact of Wolbachia on the host genetic structure and (ii) the Wolbachia strains diversity in order to attempt an identification of CI molecular basis. By a survey of natural populations, we highlighted that Wolbachia deeply impacts the population structure of mitochondrial diversity, but is also associated with repeated events of cytoplasmic introgression between members of complex Cx. pipiens. We also conducted a study of comparative genomics based on the sequencing of four complete genomes of very closely related Wolbachia strains. For that purpose, we performed a series of analyses using a wide panel of bioinformatic tools coupled with molecular validations. We showed a low polymorphism between two groups of Wolbachia infecting Cx. pipiens. These studies also allowed us to highlight promising candidate genes which could be directly involved in the CI mechanism.

Wolbachia

Culex pipens

Incompatibilité Cytoplasmique

Génome

Introgression cytoplasmique

Wolbachia

Culex pipens

Cytoplasmic Incompatibility

Genomic

Cytoplasmic Introgression

L’individu en développement / The developmental individual

Prévot, Karine

25 November 2016

La définition de l’individu biologique pose problème tant à la philosophie qu’à la biologie. Enparticulier, comment prendre en compte une hiérarchie d’entités diverses, depuis la cellulejusqu’aux communautés ou associations ? De nombreuses analyses s’efforcent de considérerdes degrés d’individualité divers, mais soit elles laissent de côté certains composants del’individualité, les composants abiotiques par exemple, soit elles persistent à considérerl’organisme comme l’individualité typique. Afin de dépasser ces différents biais, noussoutenons qu’une approche pertinente est celle de la biologie du développement. En effet, ledéveloppement, en tant qu’il est l’étude des mécanismes et processus par lesquels l’individu seforme, apparaît comme un outil privilégié pour examiner les facteurs causaux qui rendent raisonde l’individualité biologique, et les hiérarchiser. À travers le concept d’individu endéveloppement, nous nous attachons à définir le développement d’une part et à élaborer uneanalyse critique des études qui ont été menées à son sujet d’autre part. En redéfinissant ledéveloppement à l’aune des interactions – avec les facteurs environnementaux et diversesentités – qui le composent, nous soutenons que la microbiologie est une voie privilégiée à partirde laquelle une refonte du concept d’individu est possible. Nous appliquons enfin lesconséquences de nos analyses à un cas d’étude précis, celui des symbioses aux bactériesWolbachia, et soulignons la nécessité de faire des communautés le niveau d’individualitétypique ainsi que de repenser les modèles du développement individuel / Defining the biological individual raises questions both for philosophers and biologists. Inparticular, how is it possible to take into account a hierarchy of entities, from the cells to the communities and associations? Many analyses try to consider degrees of individuality, but some of them leave some components out – like abiotic components for instance – whereas otherskeep defining the organism as the typical individual. We think that these views imply biases inthe definition of the individual, that can be solved by the study of the developmental biology.Indeed, development is defined as the study of all the processes involved in the individual’sconstitution. As such, development represents a relevant tool from which the analysis and theselecting of the necessary causes and factors of the individual’s formation can be done. Usingthe concept of “developmental individual”, we first define what development is, and thenformulate a critical analysis of the different conceptions of development. We offer a definitionof the developmental individual based on the different interactions that compose it, and definethe field of microbiology as a relevant way to redesign the concept of the individual. We finallyapply those analyses to a case-study: Wolbachia symbiosis, and show that both the individualand the models used in developmental biology have to be considered from the level of thecommunities.

Individu

Développement

Interactions

Symbioses

Microbiologie

Wolbachia

Individual

Development

Symbiosis

Interactions

Microbiology

Wolbachia

Aspectos da relação simbiótica entre as bactérias Wolbachia (Alphaproteobacteria, Rickettsiales) e os isópodos terrestres (Crustacea, Oniscidea)

Zimmermann, Bianca Laís

January 2010

Wolbachia é uma alfaproteobactéria que apresenta simbiose com uma variedade de artrópodos e nematoides, estando entre os mais abundantes gêneros de bactérias intracelulares já descobertos. Na região Neotropical, os estudos sobre tais bactérias e seus hospedeiros, em especial isópodos terrestres, ainda são incipientes. O presente trabalho teve como objetivos: investigar as espécies de isópodos terrestres neotropicais infectados por Wolbachia; analisar a prevalência de infecção, variação genética e relações filogenéticas das linhagens presentes nessas espécies; investigar a simbiose de Wolbachia em nematoides parasitos de tatuzinhos-de-jardim e inferir sobre as possíveis rotas de transmissão horizontal da bactéria entre os isópodos terrestres e os invertebrados que possuam associações ecológicas com os mesmos. A detecção da bactéria foi realizada através de PCRs diagnósticas, utilizando-se o gene 16S rDNA. A infecção pelo simbionte foi registrada pela primeira vez em Atlantoscia floridana e Burmoniscus meeusei. As linhagens de Wolbachia que infectam as espécies nativas de isópodos terrestres, ao contrário das introduzidas, são muito diversas e não se agrupam dentro do Oniclado. Já as sequências presentes em B. meeusei não são relacionadas a nenhuma outra linhagem presente em crustáceos, e nem mesmo fazem parte de qualquer supergrupo conhecido de Wolbachia. Pela primeira vez foi evidenciada a presença da bactéria em um nematoide da família Mermithidae, Agamermis sp., endoparasito do tatu-bola Armadillidium vulgare. Uma vez que as sequências do parasito e do hospedeiro são idênticas, é possível que um evento de transmissão horizontal tenha ocorrido entre ambos. Por fim, a presença de Wolbachia foi examinada em espécies que possuiam relações ecológicas com os isópodos terrestres (predadores, parasitos, foréticos e animais que vivem sob as mesmas condições ecológicas). Entre as espécies associadas, a infecção foi registrada apenas no nematoide parasito e nos ácaros foréticos. Enquanto as linhagens do isópodo hospedeiro e do nematoide se mostraram muito similares, àquelas dos ácaros foréticos não apresentaram relação filogenética com as de seus forontes Balloniscus glaber. Interessantemente, as sequências presentes nos ácaros são proximamente relacionadas com aquelas de B. meeusei, embora mais estudos sejam necessários para esclarecer tal achado. / Wolbachia is a genus of alfaproteobacteria whose members live in symbiosis with a variety of arthropods and nematodes. It is among the richest genera of intracellular bacteria discovered to date. In the Neotropical region, studies on these bacteria and their hosts, especially terrestrial isopods, are still in the initial stages. The objectives of the present study were: to investigate the species of Neotropical terrestrial isopods infected by Wolbachia; to analyze the prevalence of infection, genetic variation, and phylogenetic relationships of the lineages present in these isopod species; to investigate the symbiosis of Wolbachia in parasitic nematodes of pillbugs; and to provide information to support inferences about the possible routes of horizontal transmission of the bacteria between the terrestrial isopods and the invertebrates that are ecologically associated with them. The bacteria were detected by means of diagnostic PCR’s, using the 16S rDNA gene. Infection by this symbiont was recorded for the first time in Atlantoscia floridana and Burmoniscus meeusei. The lineages of Wolbachia that infect the native species of terrestrial isopods, in contrast to the introduced species, are very diverse and do not group within the Oniclade. The sequences present in B. meeusei are not related to any other lineage present in crustaceans, nor to any other known supergroup of Wolbachia. This study is the first to demonstrate the presence of these bacteria in a nematode of the family Mermithidae, Agamermis sp., an endoparasite of Armadillidium vulgare. Since the sequences from the parasite and the host are identical, it is possible that a horizontal transmission event occurred between the two. Finally, the presence of Wolbachia was examined in species that are ecologically associated with terrestrial isopods (predators, parasites, phoretic species, and animals that live under the same ecological conditions). Among the associated species, the infection was recorded only in the parasitic nematode and in the phoretic mites. Whereas the lineages of the isopod host and of the nematode proved to be very similar, those of the phoretic mites showed no phylogenetic relationship with those of their phoront Balloniscus glaber. Interestingly, the sequences present in the mites are closely related to those of B. meeusei, although further studies are necessary to clarify this finding.

Wolbachia

Oniscidea

Symbiosis

Wolbachia

Neotropical terrestrial isopods

Horizontal transmission

16S rDNA

Aspectos da relação simbiótica entre as bactérias Wolbachia (Alphaproteobacteria, Rickettsiales) e os isópodos terrestres (Crustacea, Oniscidea)

Zimmermann, Bianca Laís

January 2010

Wolbachia é uma alfaproteobactéria que apresenta simbiose com uma variedade de artrópodos e nematoides, estando entre os mais abundantes gêneros de bactérias intracelulares já descobertos. Na região Neotropical, os estudos sobre tais bactérias e seus hospedeiros, em especial isópodos terrestres, ainda são incipientes. O presente trabalho teve como objetivos: investigar as espécies de isópodos terrestres neotropicais infectados por Wolbachia; analisar a prevalência de infecção, variação genética e relações filogenéticas das linhagens presentes nessas espécies; investigar a simbiose de Wolbachia em nematoides parasitos de tatuzinhos-de-jardim e inferir sobre as possíveis rotas de transmissão horizontal da bactéria entre os isópodos terrestres e os invertebrados que possuam associações ecológicas com os mesmos. A detecção da bactéria foi realizada através de PCRs diagnósticas, utilizando-se o gene 16S rDNA. A infecção pelo simbionte foi registrada pela primeira vez em Atlantoscia floridana e Burmoniscus meeusei. As linhagens de Wolbachia que infectam as espécies nativas de isópodos terrestres, ao contrário das introduzidas, são muito diversas e não se agrupam dentro do Oniclado. Já as sequências presentes em B. meeusei não são relacionadas a nenhuma outra linhagem presente em crustáceos, e nem mesmo fazem parte de qualquer supergrupo conhecido de Wolbachia. Pela primeira vez foi evidenciada a presença da bactéria em um nematoide da família Mermithidae, Agamermis sp., endoparasito do tatu-bola Armadillidium vulgare. Uma vez que as sequências do parasito e do hospedeiro são idênticas, é possível que um evento de transmissão horizontal tenha ocorrido entre ambos. Por fim, a presença de Wolbachia foi examinada em espécies que possuiam relações ecológicas com os isópodos terrestres (predadores, parasitos, foréticos e animais que vivem sob as mesmas condições ecológicas). Entre as espécies associadas, a infecção foi registrada apenas no nematoide parasito e nos ácaros foréticos. Enquanto as linhagens do isópodo hospedeiro e do nematoide se mostraram muito similares, àquelas dos ácaros foréticos não apresentaram relação filogenética com as de seus forontes Balloniscus glaber. Interessantemente, as sequências presentes nos ácaros são proximamente relacionadas com aquelas de B. meeusei, embora mais estudos sejam necessários para esclarecer tal achado. / Wolbachia is a genus of alfaproteobacteria whose members live in symbiosis with a variety of arthropods and nematodes. It is among the richest genera of intracellular bacteria discovered to date. In the Neotropical region, studies on these bacteria and their hosts, especially terrestrial isopods, are still in the initial stages. The objectives of the present study were: to investigate the species of Neotropical terrestrial isopods infected by Wolbachia; to analyze the prevalence of infection, genetic variation, and phylogenetic relationships of the lineages present in these isopod species; to investigate the symbiosis of Wolbachia in parasitic nematodes of pillbugs; and to provide information to support inferences about the possible routes of horizontal transmission of the bacteria between the terrestrial isopods and the invertebrates that are ecologically associated with them. The bacteria were detected by means of diagnostic PCR’s, using the 16S rDNA gene. Infection by this symbiont was recorded for the first time in Atlantoscia floridana and Burmoniscus meeusei. The lineages of Wolbachia that infect the native species of terrestrial isopods, in contrast to the introduced species, are very diverse and do not group within the Oniclade. The sequences present in B. meeusei are not related to any other lineage present in crustaceans, nor to any other known supergroup of Wolbachia. This study is the first to demonstrate the presence of these bacteria in a nematode of the family Mermithidae, Agamermis sp., an endoparasite of Armadillidium vulgare. Since the sequences from the parasite and the host are identical, it is possible that a horizontal transmission event occurred between the two. Finally, the presence of Wolbachia was examined in species that are ecologically associated with terrestrial isopods (predators, parasites, phoretic species, and animals that live under the same ecological conditions). Among the associated species, the infection was recorded only in the parasitic nematode and in the phoretic mites. Whereas the lineages of the isopod host and of the nematode proved to be very similar, those of the phoretic mites showed no phylogenetic relationship with those of their phoront Balloniscus glaber. Interestingly, the sequences present in the mites are closely related to those of B. meeusei, although further studies are necessary to clarify this finding.

Wolbachia

Oniscidea

Symbiosis

Wolbachia

Neotropical terrestrial isopods

Horizontal transmission

16S rDNA

Aspectos da relação simbiótica entre as bactérias Wolbachia (Alphaproteobacteria, Rickettsiales) e os isópodos terrestres (Crustacea, Oniscidea)

Zimmermann, Bianca Laís

January 2010

Wolbachia é uma alfaproteobactéria que apresenta simbiose com uma variedade de artrópodos e nematoides, estando entre os mais abundantes gêneros de bactérias intracelulares já descobertos. Na região Neotropical, os estudos sobre tais bactérias e seus hospedeiros, em especial isópodos terrestres, ainda são incipientes. O presente trabalho teve como objetivos: investigar as espécies de isópodos terrestres neotropicais infectados por Wolbachia; analisar a prevalência de infecção, variação genética e relações filogenéticas das linhagens presentes nessas espécies; investigar a simbiose de Wolbachia em nematoides parasitos de tatuzinhos-de-jardim e inferir sobre as possíveis rotas de transmissão horizontal da bactéria entre os isópodos terrestres e os invertebrados que possuam associações ecológicas com os mesmos. A detecção da bactéria foi realizada através de PCRs diagnósticas, utilizando-se o gene 16S rDNA. A infecção pelo simbionte foi registrada pela primeira vez em Atlantoscia floridana e Burmoniscus meeusei. As linhagens de Wolbachia que infectam as espécies nativas de isópodos terrestres, ao contrário das introduzidas, são muito diversas e não se agrupam dentro do Oniclado. Já as sequências presentes em B. meeusei não são relacionadas a nenhuma outra linhagem presente em crustáceos, e nem mesmo fazem parte de qualquer supergrupo conhecido de Wolbachia. Pela primeira vez foi evidenciada a presença da bactéria em um nematoide da família Mermithidae, Agamermis sp., endoparasito do tatu-bola Armadillidium vulgare. Uma vez que as sequências do parasito e do hospedeiro são idênticas, é possível que um evento de transmissão horizontal tenha ocorrido entre ambos. Por fim, a presença de Wolbachia foi examinada em espécies que possuiam relações ecológicas com os isópodos terrestres (predadores, parasitos, foréticos e animais que vivem sob as mesmas condições ecológicas). Entre as espécies associadas, a infecção foi registrada apenas no nematoide parasito e nos ácaros foréticos. Enquanto as linhagens do isópodo hospedeiro e do nematoide se mostraram muito similares, àquelas dos ácaros foréticos não apresentaram relação filogenética com as de seus forontes Balloniscus glaber. Interessantemente, as sequências presentes nos ácaros são proximamente relacionadas com aquelas de B. meeusei, embora mais estudos sejam necessários para esclarecer tal achado. / Wolbachia is a genus of alfaproteobacteria whose members live in symbiosis with a variety of arthropods and nematodes. It is among the richest genera of intracellular bacteria discovered to date. In the Neotropical region, studies on these bacteria and their hosts, especially terrestrial isopods, are still in the initial stages. The objectives of the present study were: to investigate the species of Neotropical terrestrial isopods infected by Wolbachia; to analyze the prevalence of infection, genetic variation, and phylogenetic relationships of the lineages present in these isopod species; to investigate the symbiosis of Wolbachia in parasitic nematodes of pillbugs; and to provide information to support inferences about the possible routes of horizontal transmission of the bacteria between the terrestrial isopods and the invertebrates that are ecologically associated with them. The bacteria were detected by means of diagnostic PCR’s, using the 16S rDNA gene. Infection by this symbiont was recorded for the first time in Atlantoscia floridana and Burmoniscus meeusei. The lineages of Wolbachia that infect the native species of terrestrial isopods, in contrast to the introduced species, are very diverse and do not group within the Oniclade. The sequences present in B. meeusei are not related to any other lineage present in crustaceans, nor to any other known supergroup of Wolbachia. This study is the first to demonstrate the presence of these bacteria in a nematode of the family Mermithidae, Agamermis sp., an endoparasite of Armadillidium vulgare. Since the sequences from the parasite and the host are identical, it is possible that a horizontal transmission event occurred between the two. Finally, the presence of Wolbachia was examined in species that are ecologically associated with terrestrial isopods (predators, parasites, phoretic species, and animals that live under the same ecological conditions). Among the associated species, the infection was recorded only in the parasitic nematode and in the phoretic mites. Whereas the lineages of the isopod host and of the nematode proved to be very similar, those of the phoretic mites showed no phylogenetic relationship with those of their phoront Balloniscus glaber. Interestingly, the sequences present in the mites are closely related to those of B. meeusei, although further studies are necessary to clarify this finding.

Wolbachia

Oniscidea

Symbiosis

Wolbachia

Neotropical terrestrial isopods

Horizontal transmission

16S rDNA

Generation and characterization of Wolbachia transinfections and development of female-specific RIDL technology in Aedes albopictus

Blagrove, Marcus S. C.

January 2014

Aedes albopictus is an important vector of dengue and chikungunya viruses, and, over recent decades, has resisted traditional control strategies allowing it to spread from its native Southeast Asia throughout the world. In this thesis, two alternative control methods are assessed and developed: transinfection with the inherited bacteria Wolbachia, for population replacement with a refractory strain; and a genetic equivalent to the sterile insect technique, RIDL (Release of Insects carrying a Dominant Lethal), for population suppression. Wolbachia is a genus comprising maternally inherited intracellular α-proteobacteria which primarily infect arthropods. Certain strains of Wolbachia both have the ability to manipulate host reproduction through cytoplasmic incompatibility (CI) which allows Wolbachia to invade host populations by conferring a reproductive advantage on infected females, and have been shown to confer broad-spectrum pathogen resistance on their hosts. Here, a transinfection of wMel in Aedes albopictus (Uju.wMel) was generated which shows complete bidirectional CI with the natural Wolbachia infection of Ae. albopictus, in the absence of any major fitness costs and (as shown by collaborators) completely abolishes dengue and chikungunya virus transmission. It was also shown that the pathogen inhibition in Uju.wMel occurs in the absence of immune stimulation. Evidence supporting cholesterol sequestration by wMel as a mechanism for the pathogen inhibition observed in Uju.wMel was found. Previous attempts to produce a conditionally inviable genetic sexing Ae. albopictus RIDL line have resulted in a sub-optimal strain in which the construct was not sufficiently specific or repressible, resulting in a high proportion of off-target inviable mosquitoes. Here, the mating competitiveness of RIDL males was shown to be not significantly different from wild-type, confirming the potential utility of the system. Multiple truncations of the promoter were made in an attempt to reduce the off-target expression.

614.4

Population ecology and genetics of the marsh fritillary butterfly Euphydryas aurinia

Smee, Melanie Rose

January 2011

The past two decades have witnessed an unprecedented decline in Lepidopteran species, with more than a third of the UK’s butterflies now either considered threatened, or already lost from the country. The vulnerable marsh fritillary, Euphydryas aurinia, after a long term loss in the UK of 73% in abundance, has become an almost iconic species as the target of many well-funded conservation projects across the UK. Despite extensive ecological studies, populations of E. aurinia are shown in Chapter 2 to still be declining in south-west UK even after recommended management strategies have been implemented. This necessitates the need for prompt research beyond that of management requirements and butterfly habitat preferences. In Chapter 3, microsatellite markers (EST-SSRs) were developed for E. aurinia and using these markers in Chapter 4, it is shown that E. aurinia populations in southern UK and Catalonia, Spain, are severely genetically differentiated at all geographical scales, and genetically depauperate, causing huge concerns for the conservation of this enigmatic and ecologically important species. Dispersal is fundamental to metapopulation existence and survival. Phosphoglucose isomerase (PGI – an enzyme in the glycolysis pathway) is a well-endorsed candidate gene for dispersal, extensively studied in the Glanville fritillary (Melitaea cinxia) and Orange Sulphur (Colias eurytheme). In Chapter 5, an analysis across 27 sites in the UK discovered six non-synonymous SNPs (single nucleotide polymorphisms) within PGI. A single charge-changing SNP of interest showed no evidence of balancing selection, contrary to findings in M. cinxia, instead appearing to be neutral when analysed alongside microsatellite markers developed in Chapter 3. No link was found between genotype and flight, morphology or population trend. These findings challenge the emerging perspective that PGI could be used as an adaptive molecular marker for arthropods. Wolbachia are endosymbiotic bacteria capable of dramatically altering the reproductive system of their host. In Chapter 6, a PCR-based diagnostic in conjunction with MLST (multi-locus sequence typing) identified 100% prevalence of a single strain of Wolbachia across all sampled E. aurinia populations in the UK. Total prevalence suggests that Wolbachia probably has little phenotypic impact on its host, but the potential impacts of this endosymbiont on uninfected populations should be considered during any management plans for the conservation of E. aurinia. Current management plans will need to incorporate all areas of research, from basic ecological requirements to molecular adaptation and unseen manipulators of host biology, to be able to fully and effectively conserve declining fragmented species.

591.7

Genome Evolution and Niche Differentiation of Bacterial Endosymbionts

Ellegaard, Kirsten Maren

January 2014

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.

niche

habitat

endosymbiont

gut microbiome

honey bee

Wolbachia

comparative

genomics