Interruption de la communication bactérienne dans la rhizosphère par la dégradation enzymatique des signaux quorum sensing

L identification, chez divers organismes, d enzymes de dégradation des N-acyl homosérineslactones (NAHLs) impliquées dans la signalisation QS pose la question de leurs rôles dans lesinteractions bactéries-eucaryotes. Dans une première partie, une synthèse bibliographique analyse lesconnaissances acquises sur ces enzymes dégradant les NAHLs. Dans une seconde partie, la croissancedes bactéries dégradant les signaux NAHLs a été stimulée par l application de g-caprolactone (GCL)dans la rhizosphère de plants de pommes de terre à des fins de phytoprotection. L effet de cetraitement sur la diversité des communautés bactériennes rhizosphériques a été évalué en combinantdifférentes approches d écologie microbienne moléculaire comme la DGGE, le pyroséquençaged amplicons rrs, et la métagénomique fonctionnelle. Cette dernière approche appliquée à une banquede 30 000 clones environ a conduit à l identification d un gène qsdB codant la dégradation des signauxNAHL. Ce travail révèle ainsi l existence d une nouvelle classe d enzymes de dégradation des NAHLsappartenant à la famille des enzymes possédant une signature amidase (AS) dont des membres sontpar ailleurs impliqués dans la dégradation de composés xénobiotiques. Dans une troisième partie, unsystème expérimental a été développé afin de mesurer le transfert conjugatif du plasmide de virulenceTi (tumor inducing) chez des dérivés du pathogène Agrobacterium tumefaciens, appelés tricheurs ,incapables de produire des signaux NAHLs mais utilisateurs de ceux produits par les autres bactéries.Ce modèle a permis de montrer l effet modérateur de lactonases dégradant les NAHLs exprimées chezdes agrobactéries produisant les NAHLs, chez des bactéries réceptrices du plasmide Ti, ou des planteshôtes des agrobactéries sur le transfert conjugatif initié par les tricheurs. L ensemble de ce travailrévèle à la fois une nouvelle famille d enzymes impliquées dans la dégradation des NAHLs, ainsiqu un nouveau rôle de ces enzymes dans la modulation des flux de gènes entre bactériesphytopathogènes en interaction avec une plante hôte.Identification of bacterial and eukaryotic enzymes that degrade N-acyl homoserine lactones(NAHLs) involved in QS signaling raises the question of their roles in bacteria-eucaryotesinteractions. In a first part of this study, a bibliographic report analyzes the current data on thoseNAHL-degrading enzymes. In a second part, the growth of NAHL-degrading bacteria was stimulatedby g-caprolactone (GCL) amendment in potato rhizosphere to protect this plant against the soft-rotpathogen Pectobacterium. The effect of the GCL treatment on rhizospheric bacterial communities wasevaluated by a combination of different molecular microbial ecology techniques such as DGGE,pyrosequencing and functional metagenomic. This last approach was applied to generate ametagenomic library of ca. 30,000 clones and lead to the identification of the qsdB gene that encodesNAHL degradation, This work revealed the occurrence of a novel class of NAHL-degrading enzymesthat belong to the amidase signature (AS) family, some members of which being involved inxenobiotic compound degradation. In a third part, an experimental system was developed to measurethe conjugative transfer of Ti plasmid in various strains of the pathogen Agrobacterium tumefaciens,including cheaters , i.e. bacteria unable to produce NAHL signals but capable to use signals producedby other bacteria. Using this model; variations of the plasmid transfer of cheaters were measured whenNAHL-degrading lactonases were expressed in agrobacteria that produce NAHL signals, in recipientbacteria of Ti plasmid, or in agrobacterial host plant. Taken together, thesis experiments revealed anovel class of enzymes involved in NAHL-degradation and a new role for thoses enzymes in themodulation of gene transfer between pathogenic bacteria interacting with host plants.PARIS11-SCD-Bib. électronique (914719901) / SudocSudocFranceF

Quorum-quenching limits quorum-sensing exploitation by signal-negative invaders

Some bacteria produce and perceive quorum-sensing (QS) signals that coordinate several behaviours, including the costly processes that are exoenzyme production and plasmid transfer. In the case of plasmid transfer, the emergence of QS signal-altered invaders and their policing are poorly documented. In Agrobacterium tumefaciens, the virulence Ti-plasmid encodes both synthesis and sensing of QS-signals, which promote its transfer from a donor to a recipient cell. Here, we reported that QS-altered A. tumefaciens mutants arose during experimental evolution. All showed improved growth compared to their ancestor. Genome sequencing revealed that, though some had lost the Ti-plasmid, most were defective for QS-signal synthesis and Ti-plasmid conjugation (traR mutations) and one exhibited a QS-signal exploitation behaviour, using signal produced by other cells to enhance its own Ti-plasmid transfer. We explored mechanisms that can limit this QS-hijacking. We showed that the A. tumefaciens capacity to inactivate QS-signals by expressing QS-degrading enzyme could attenuate dissemination of the QS signal-negative Ti-plasmids. This work shows that enzymatic QSdisruption whether encoded by the QS-producing Ti-plasmid itself, by a companion plasmid in the same donor cells, or by one in the recipient cells, in all cases can serve as a mechanism for controlling QS exploitation by QS signal-negative mutants

Proline antagonizes GABA-induced quenching of quorum-sensing in Agrobacterium tumefaciens

Plants accumulate free L-proline (Pro) in response to abiotic stresses (drought and salinity) and presence of bacterial pathogens, including the tumor-inducing bacterium Agrobacterium tumefaciens. However, the function of Pro accumulation in host-pathogen interaction is still unclear. Here, we demonstrated that Pro antagonizes plant GABA-defense in the A. tumefaciens C58-induced tumor by interfering with the import of GABA and consequently the GABA-induced degradation of the bacterial quorum-sensing signal, 3-oxo-octanoylhomoserine lactone. We identified a bacterial receptor Atu2422, which is implicated in the uptake of GABA and Pro, suggesting that Pro acts as a natural antagonist of GABA-signaling. The Atu2422 amino acid sequence contains a Venus flytrap domain that is required for trapping GABA in human GABAB receptors. A constructed atu2422 mutant was more virulent than the wild type bacterium; moreover, transgenic plants with a low level of Pro exhibited less severe tumor symptoms than did their wild-type parents, revealing a crucial role for Venus flytrap GABA-receptor and relative abundance of GABA and Pro in host-pathogen interaction