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The coevolution of gene mobility and sociality in bacteriaDimitriu, Tatiana 09 April 2014 (has links) (PDF)
Bacteria are social organisms which participate in multiple cooperative and group behaviours. They moreover have peculiar genetic systems, as they often bear mobile genetic elements like plasmids, molecular symbionts that are the cause of widespread horizontal gene transfer and play a large role in bacterial evolution. Both cooperation and horizontal transfer have consequences for human health: cooperative behaviours are very often involved in the virulence of pathogens, and horizontal gene transfer leads to the spread of antibiotic resistance. The evolution of plasmid transfer has mainly been analyzed in terms of infectious benefits for selfish mobile elements. However, chromosomal genes can also modulate horizontal transfer. A huge diversity in transfer rates is observed among bacterial isolates, suggesting a complex co-evolution between plasmids and hosts. Moreover, plasmids are enriched in genes involved in social behaviours, and so could play a key role in bacterial cooperative behaviours. We study here the coevolution of gene mobility and sociality in bacteria. To investigate the selective pressures acting on plasmid transfer and public good production, we use both mathematical modelling and a synthetic system that we constructed where we can independently control public good cooperation and plasmid conjugation in Escherichia coli. We first show experimentally that horizontal transfer allows the specific maintenance of public good alleles in a structured population by increasing relatedness at the gene-level. We further demonstrate experimentally and theoretically that this in turn allows for second-order selection of transfer ability: when cooperation is needed, alleles promoting donor and recipient abilities for public good traits can be selected both on the plasmid and on the chromosome in structured populations. Moreover, donor ability for private good traits can also be selected on the chromosome, provided that transfer happens towards kin. The interactions between transfer and cooperation can finally lead to an association between transfer and public good production alleles, explaining the high frequency of genes related to cooperation that are located on plasmids. Globally, these results provide insight into the mechanisms maintaining cooperation in bacteria, and may suggest ways to target cooperative virulence.
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The coevolution of gene mobility and sociality in bacteria / Coévolution entre mobilité des gènes et comportements sociaux chez les bactériesDimitriu, Tatiana 09 April 2014 (has links)
Les bactéries sont des organismes extrêmement sociaux, qui présentent de multiples comportements de coopération. De plus, les génomes bactériens sont caractérisés par la présence de nombreux éléments génétiques mobiles, tels que les plasmides. Ces éléments mobiles sont la cause de transferts génétiques horizontaux, et jouent un rôle important dans l'évolution bactérienne. La coopération et le transfert horizontal ont tous deux des conséquences importantes sur la santé humaine: des comportements coopératifs sont souvent à l'origine de propriétés de virulence chez les bactéries pathogènes, et le transfert horizontal entraîne la dissémination de gènes de résistance aux antibiotiques. L'évolution du transfert horizontal a jusqu'ici été analysée essentiellement en termes de bénéfices infectieux apportés à des éléments génétiques égoïstes. Cependant, le taux de transfert des plasmides est extrêmement variable et partiellement contrôlé par les gènes des bactéries hôtes, suggérant une co-évolution complexe entre hôtes et plasmides. De plus, les plasmides sont particulièrement riches en gènes liés à des comportements coopératifs, et semblent donc jouer un rôle-clé dans les phénomènes de socialité bactérienne. Ce travail porte sur la coévolution entre mobilité génétique et socialité chez les bactéries. Nous analysons ici les pressions de sélection agissant sur le transfert de plasmides et la production de biens publics, à l'aide de modèles mathématiques et d'un système synthétique que nous avons construit chez Escherichia coli, dans lequel nous pouvons contrôler indépendamment la coopération et la conjugaison. Dans un premier temps, nous montrons expérimentalement que le transfert horizontal favorise le maintien de la coopération dans une population structurée, en augmentant la sélection de parentèle agissant au niveau des gènes transférés. Dans un second temps, nous montrons expérimentalement et théoriquement que l'échange génétique lui-même peut être sélectionné: les bactéries transférant des plasmides codant pour des biens publics sont favorisées dans une population structurée. Le transfert de gènes codant pour des biens privés peut également être sélectionné, à condition que ce transfert s'effectue entre bactéries apparentées. Finalement, ces interactions entre transfert horizontal et coopération peuvent mener à une association entre allèles de coopération et de transfert, expliquant la fréquence élevée de gènes sociaux situés sur des plasmides.Ces résultats permettent de mieux comprendre le maintien de comportements coopératifs chez les bactéries, et suggèrent des moyens de cibler certains cas de virulence bactérienne. / Bacteria are social organisms which participate in multiple cooperative and group behaviours. They moreover have peculiar genetic systems, as they often bear mobile genetic elements like plasmids, molecular symbionts that are the cause of widespread horizontal gene transfer and play a large role in bacterial evolution. Both cooperation and horizontal transfer have consequences for human health: cooperative behaviours are very often involved in the virulence of pathogens, and horizontal gene transfer leads to the spread of antibiotic resistance. The evolution of plasmid transfer has mainly been analyzed in terms of infectious benefits for selfish mobile elements. However, chromosomal genes can also modulate horizontal transfer. A huge diversity in transfer rates is observed among bacterial isolates, suggesting a complex co-evolution between plasmids and hosts. Moreover, plasmids are enriched in genes involved in social behaviours, and so could play a key role in bacterial cooperative behaviours. We study here the coevolution of gene mobility and sociality in bacteria. To investigate the selective pressures acting on plasmid transfer and public good production, we use both mathematical modelling and a synthetic system that we constructed where we can independently control public good cooperation and plasmid conjugation in Escherichia coli. We first show experimentally that horizontal transfer allows the specific maintenance of public good alleles in a structured population by increasing relatedness at the gene-level. We further demonstrate experimentally and theoretically that this in turn allows for second-order selection of transfer ability: when cooperation is needed, alleles promoting donor and recipient abilities for public good traits can be selected both on the plasmid and on the chromosome in structured populations. Moreover, donor ability for private good traits can also be selected on the chromosome, provided that transfer happens towards kin. The interactions between transfer and cooperation can finally lead to an association between transfer and public good production alleles, explaining the high frequency of genes related to cooperation that are located on plasmids. Globally, these results provide insight into the mechanisms maintaining cooperation in bacteria, and may suggest ways to target cooperative virulence.
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