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Regulation of clavam metabolite production in Streptomyces clavuligerusKwong, Thomas Unknown Date
No description available.
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Implication des systèmes à deux composants dans les réponses de Streptococcus thermophilus à des changements environnementaux, dont la coculture avec Lactobacillus bulgaricus. / Involvement of two-component systems in Streptococcus thermophilus response to environmental changes such as mixed culture with Lactobacillus bulgaricusThevenard, Benoît 23 September 2011 (has links)
S. thermophilus est une bactérie lactique largement utilisé dans l'industrie laitière et, comme toute bactérie, doit s'adapter à des environnements variés tels que le lait, le yaourt et même le tractus digestif, après que le produit ait été ingéré. Les systèmes à deux composants (TCS) constituent un des mécanismes essentiels qu'utilisent les bactéries pour percevoir et s'adapter à des changements environnementaux. D'un point de vue structural, les TCS sont constitués de deux composants: un « senseur » ou protéine histidine kinase (HK) qui s'auto-phosphoryle en réponse à un stimulus puis transfère son groupement phosphate au « response regulator » (RR), le deuxième composant. Celui-ci se comporte alors le plus souvent comme un régulateur transcriptionnel permettant une réponse physiologique adaptée. Afin de mieux comprendre ces phénomènes de régulation impliqués dans la réponse aux changements environnementaux, nous avons étudié la contribution de chacun des 8 TCS de Streptococcus thermophilus LMD-9 à son adaptation dans le lait. Ainsi, des études transcriptionnelles effectuées sur des cultures en lait montrent que tous les RR sont exprimés, à des niveaux et profils d'expression différents. Nous avons noté en coculture avec Lactobacillus bulgaricus, le partenaire de Streptococcus thermophilus dans le yaourt, une induction de l'expression de 4 RR qui atteint, pour rr02 et rr09, un facteur 6. Nous avons construit par ailleurs des mutants négatifs pour 7 des 8 RR de S. thermophilus et montré l'essentialité de RR05, un orthologue de YycF chez B. subtilis ou de or de WalR chez S. aureus. Pour les 7 autres mutants RR, l'absence d'un seul gène rr n'impacte pas suffisamment la croissance du streptocoque en lait. Enfin, la détermination du régulon du TCS06 par des études post-génomiques a permis de montrer que ce système est impliqué dans la résistance à la bacitracine en modulant entre autres la voie de biosynthèse du polysaccharide à rhamnose (RGP). / The lactic acid bacterium Streptococcus thermophilus is widely used in the dairy industry and, as a food bacterium, has to cope with changing environments such as milk, yogurt as well as the digestive tract, after the product has been ingested. Two-component systems (TCS), typically composed of a sensor kinase (HK) that detects a stimulus and of a response regulator (RR) which acts as a transcriptional regulator, are among the most prevalent means for bacteria to adapt to changing environments via fine-tune gene expression. To get a more comprehensive view of the role of all two-component systems in S. thermophilus physiology, we have investigated the contribution of each S. thermophilus LMD-9 TCS to its fitness and adaptation to milk. Transcriptomic studies (RT-qPCR) and construction of negative mutants of the rr genes were performed for LMD-9 S. thermophilus strain. We have shown that all LMD-9 response regulators were expressed in milk, at different levels and with different profiles of expression during growth. In mixed culture with Lactobacillus bulgaricus, the S. thermophilus partner in yoghurt, the expression of four LMD-9 rr increased; for two of them, rr02 and rr09, the increase reached a factor 6. These results indicate that Lb. bulgaricus induces regulatory changes in S. thermophilus and that S. thermophilus is able to adapt to these changes by probable fine tuning regulations. We constructed negative mutants for 7 out of 8 LMD-9 RRs and we showed that RR05 -an ortholog of B. subtilis YycF or S. aureus WalR- was essential for the optimum growth of S. thermophilus. For the 7 other RR, the absence of a single rr gene was not sufficient to notably impact the growth of LMD-9 in milk. The determination of the TCS06 regulon by post-genomics shows that TCS06 is involved in bacitracin resistance through the modulation of the rhamnose polysaccharide pathway.
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Untersuchungen zur Stimulus-Wahrnehmung und Regulation des Zweikomponenten-Systems KdpD/KdpE aus Escherichia coliLaermann, Vera 11 August 2014 (has links)
Unter K+-limitierenden Wachstumsbedingungen oder, in wesentlich geringerem Ausmaß, unter Salzstress synthetisiert E. coli den KdpFABC-Komplex, ein hoch-affines K+-Transportsystem (Km ~ 2μM). Die Regulation der Expression des kdpFABC-Operons erfolgt durch das Sensorkinase/Antwortregulator-System KdpD/KdpE. Ziel des ersten Teils dieser Arbeit war die Identifizierung des Stimulus, der von der Sensorkinase KdpD wahrgenommen wird. Ausgangspunkt der Untersuchungen war die Beobachtung, dass die K+-Aufnahme über das Kdp-System bei K+-Konzentrationen >5 mM inhibiert wird. Diese wichtige Eigenschaft des Kdp-Systems wurde in der Vergangenheit häufig übersehen, da die Inhibierung des Kdp-Systems bei höheren pH-Werten (pH 7,8) durch eine hohe Rate unspezifischen K+-Transports kompensiert und somit überdeckt wird. Es konnte gezeigt werden, dass einzelne Aspartat-Substitutionen in den periplasmatischen Schleifen der Sensor-Domäne von KdpD ausreichten, um die Inhibierung des Kdp-Systems bei höheren K+-Konzentrationen aufzuheben. Diese KdpD-Derivate zeigten eine, im Vergleich zum KdpD-WT, veränderte Regulation der kdpFABC-Expression bei K+-Konzentrationen >5 mM, die eine adäquate K+-Aufnahme via KdpFABC ermöglichte. Diese Ergebnisse zeigen, dass die Inhibierung der K+-Aufnahme über das Kdp-System bei K+-Konzentrationen >5 mM auf einer Inhibierung der kdpFABC-Expression durch KdpD basiert. Weiterhin konnte gezeigt werde, dass eine Abnahme der extrazellulären K+-Konzentration eine effiziente und sofortige Stimulierung der KdpD/KdpE-Signaltransduktion bewirkt. Aus diesen Ergebnissen wurde geschlussfolgert, dass die extrazelluläre K+-Konzentration als Reiz für die Sensorkinase KdpD dient. Im zweiten Teil dieser Arbeit erfolgte erstmals eine absolute Quantifizierung von KdpD und KdpE, sowie der Untereinheiten des KdpFABC-Komplexes unter induzierenden und nicht-induzierenden Bedingungen mittels hoch-sensitiver und selektiver Massenspektrometrie. Unter nicht-induzierenden Bedingungen liegt die KdpFABC-Synthese in der gleichen Größenordnung wie die KdpD- und KdpE-Synthese vor. Dieser Befund ist eine wichtige Voraussetzung für die postulierte, regulatorische Interaktion zwischen der Sensorkinase KdpD und der K+-Transportuntereinheit KdpB (Kipschull, 2011). Unter induzierenden Bedingungen stieg die KdpFABC-Synthese 100-300-fach, während eine etwa 10-fache Erhöhung der KdpD- und KdpE-Synthese nachgewiesen werden konnte. Diese Beobachtung bestätigt, dass das Zweikomponenten-System KdpD/KdpE unter induzierenden Bedingungen einer Autoregulation unterliegt. Die Autoregulation konnte durch eine räumliche Trennung des kdpFABC- und kdpDE-Operons aufgehoben werden. Die Aufhebung der Autoregulation von KdpD/KdpE hatte jedoch keinen Einfluss auf die Expressionskinetik des kdpFABC-Operons unter induzierenden Bedingungen. Der dritte Teil dieser Arbeit beschreibt die Konstruktion eines E. coli-Stamms, der eine vollständige Deletion des kdpD-Gens trägt. Nach einer zeitlichen Verzögerung konnte in dem daraus resultierenden E. coli-Stamm (LB2240ΔkdpD) unter K+-Limitation eine KdpD-unabhängige Expression des kdpFABC-Operons nachgewiesen werden. Die kdpFABC-Expression befähigte diesen Stamm, in Abwesenheit von KdpD unter K+-Limitation zu wachsen. Es konnte gezeigt werde, dass das K+-limitierte Wachstum von LB2240ΔkdpD eine Phosphorylierung von KdpE voraussetzt, wobei Acetylphosphat nicht als alternativer Phosphodonor diente. Da nur wenige Zellen einer LB2240ΔkdpD-Kultur den beschriebenen Phänotyp zeigten, liegt die Vermutung nahe, dass diese Zellen Träger einer Suppressormutation sind, die eine KdpD-unabhängige Phosphorylierung von KdpE und daraus folgend eine kdpFABC-Expression verursacht.
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The AlgZ/R Two-Component System Is Responsible for Attenuation of Virulence in Pseudomonas aeruginosaWilliams, Danielle A 01 December 2017 (has links) (PDF)
Pseudomonas aeruginosa is an important opportunistic pathogen. Many P. aeruginosa virulence factors are regulated by the AlgZ/R two component system. AlgZ is the sensor histidine kinase which phosphorylates AlgR, the response regulator. AlgR activates transcription of different gene targets based upon its phosphorylation state. The genes that encode AlgZ and AlgR are transcribed in an operon. While regulation of algR expression has been well studied, regulation of algZ expression has not. Using a pilW mutant in concert with algZTF-lacZ transcriptional fusion, we conducted a transposon mutagenesis to identify algZ regulators. We identified an unknown autoregulatory loop. The type IV pilus minor pilins prevent the phosphorylation of AlgR by AlgZ . This inhibition of the AlgZ/R system subsequently down-regulates both the expression of the fimU operon and the algZ/R operon. Because AlgR regulates virulence, it is possible that virulence can also be reduced by targeting activation of the AlgZ/R system.
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Similarities and variations of the enterobacterial chemotaxis paradigm in Sinorhizobium melilotiAgbekudzi, Alfred 21 December 2023 (has links)
Sinorhizobium meliloti is a nitrogen-fixing endosymbiont of the legume Medicago sativa commonly known as alfalfa. It uses flagellar rotation and chemotaxis to seek roots of host plants to inhabit. This symbiosis serves as a great model system for studying biological nitrogen fixation and plant-microbe interactions. Since alfalfa brings enormous economic value to the USA, investments into the knowledge of the chemotaxis process that initiates symbiosis have the ability to mitigate deterioration of the environment and significantly increase food supply. The chemotaxis system in the enteric bacteria Escherichia coli is well studied and has been a great resource to understanding the process in other bacterial systems including our model organism S. meliloti.
This dissertation compares and contrasts the chemotaxis features in E. coli and S. meliloti and investigates their molecular functions. Based on the understanding gained so far, we attempt to offer plausible explanations for the underlying mechanisms of the S. meliloti chemotaxis pathway. Chapter 1 describes why biological nitrogen fixation is important for agriculture and the health of our environment. This chapter also sheds light on the symbiotic relationship between alfalfa and S. meliloti, which culminates in the formation of nitrogen fixing nodules. We expound on the chemotaxis systems in E. coli and other bacteria including S. meliloti and Bacillus subtilis.
In chapter 2, we compare the distribution of C-terminal pentapeptide-bearing receptors and the adaptation proteins that they tether in E. coli and S. meliloti. The stoichiometry data show that the ratio of pentapeptide-bearing chemoreceptors to chemotaxis protein (Che)R and CheB molecules are approximately 500- and 160-fold higher in S. meliloti than in E. coli, respectively. Since not all chemoreceptors in chemotactic bacteria have and utilize the pentapeptide moiety, we investigated the S. meliloti system and observed a strong interaction between CheR, activated CheB and the isolated pentapeptides via in-vitro binding studies. On the contrary, unmodified CheB showed weak binding to the pentapeptide. Through in-vivo studies, we highlighted the physiological necessity of the pentapeptide for chemotaxis. S. meliloti strains with substitutions of the conserved tryptophan residue to alanine in one or all four pentapeptide-bearing Methyl-accepting Chemotaxis Proteins (MCPs) resulted in diminished or loss of chemotaxis to glycine betaine, lysine, and acetate, ligands sensed by pentapeptide-bearing McpX and pentapeptide-lacking McpU and McpV, respectively. The flexible linker connecting the pentapeptide to the MCPs together with the pentapeptide itself were shown to be functional on pentapeptide-lacking chemoreceptors and provided adaptational assistance to other chemoreceptors that lacked a functional pentapeptide. Based on these results, we concluded that S. meliloti employs a pentapeptide-dependent adaptation system with MCPs possessing a consensus pentapeptide motif (N/D)WE(E/N)F). Finally, we postulated that the higher abundance of CheR and CheB in S. meliloti compared to E. coli compensates for the lower number of pentapeptide-bearing chemoreceptors in the chemosensory array.
In chapter 3, we explored the putative phosphatase function of a novel protein, CheT, on phosphorylated S. meliloti response regulators. The kinase CheA phosphorylates both the sink response regulator, CheY1, and the flagellar motor interacting response regulator, CheY2. CheY1 competes with CheY2 for these phosphate groups, but we have discovered another layer of complexity to the story. Sequence comparison of S. meliloti CheT and the E. coli phosphatase CheZ shows little sequence homology. However, both proteins share a DXXXQ phosphatase motif. Phosphorylation assays performed using radiolabeled [γ-32P]-ATP revealed that CheT acts as a phosphatase of CheY1~P and accelerates dephosphorylation of CheY1~P by at least two-fold. Interestingly, we also discovered that CheT interacts with CheR, but this interaction did not affect the enzymatic activity of either protein under the examined conditions. Unexpectedly, a cheT deletion strain and strains carrying mutations in the phosphatase motif exhibit an increased swimming speed, a phenotype that does not conform with the model that the absence of CheT or its activity results in increased CheY2~P levels and reduced swimming speed. We concluded that a revised S. meliloti signal termination pathway should include CheT enhancing dephosphorylation of CheY1~P and sensory adaptation involving the yet unknown function of CheT on CheR.
While the adaptation system in S. meliloti is unexplored, this work provides first insights into fascinating deviations and similarities to the known paradigm. We have also delivered evidence that the S. meliloti signal termination system requires a dedicated phosphatase. The knowledge gained here takes us a step closer to enhance the S. meliloti chemotaxis pathway towards improved symbiosis with alfalfa and to reduce our dependence on environmentally deleterious synthetic fertilizers. / Doctor of Philosophy / Like all living things, bacteria inhabit a constantly changing environment, hence the need to take up and process this information. Bacterial cells have evolved sophisticated biological tools to tackle this challenge of detecting, responding and adapting to environmental signals like nutrients, toxins, temperature changes, light, metabolites, etc. Motile bacteria such as Escherichia coli, a gut resident microbe, and Sinorhizobium meliloti, a soil dwelling bacterium, direct their swimming behavior in response to chemical gradients within the milieu through a process termed chemotaxis. Generally, this vital process enables a bacterium to escape harmful chemicals and gravitate towards beneficial ones. However, S. meliloti specifically employs chemotaxis to locate the roots of its plant host (alfalfa) and to establish a symbiotic relationship through which the bacteria provide essential nitrogen for plant growth in exchange for nourishment. The biological tools employed by S. meliloti for chemotaxis include environmental sensing receptors called Methyl-accepting Chemotaxis Proteins (MCPs) and proteins inside the bacterial cell that transfer information from the sensors to long, helical rotating propeller structures, called flagella. Importantly, the efficiency of this process hinges on a timely termination of information flow and the ability to adapt to prevailing stimuli while maintaining sensitivity to increasing concentration gradients. This work investigates the function of the C-terminal five amino acid motif of MCPs known to be critical for adaptation in E. coli and the phosphatase activity of a novel protein, CheT, in signal termination of S. meliloti chemotaxis system.
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Estudos estruturais e funcionais da proteína repressora PhoU na sinalização de transporte de fostato em Xanthomonas axonopodis pv. citri. / Structural and functional studies of the repressor protein PhoU in phosphate signalling and uptake in Xanthomonas axonopodis pv. citri .Pena, Pâmela de Oliveira 31 January 2018 (has links)
A habilidade de sensoriar o ambiente extracelular e responder às suas mudanças é inerente para a maioria das bactérias. As concentrações de nutrientes direcionam os processos metabólicos relacionados à sobrevivência e proliferação. O fosfato inorgânico (Pi) é um dos nutrientes cuja regulação, sensoriamento e sinalização são bastante conservados em bactéria. Um dos mecanismos de captação do íon fosfato com alta afinidade é o sistema Pst, um transportador do tipo ABC (ATP-Binding Cassette) , localizado na membrana interna das células. Este transportador, juntamente com as proteínas PhoR/PhoB que formam um sistema de dois componentes (Two-Component Regulatory System) , são capazes de sensoriar e monitorar os níveis deste íon nas células. Ambos os sistemas pertencem ao chamado regulon Pho, conjunto de genes envolvidos no transporte, captação e metabolização do fosfato. Estudos tem mostrado que a interação entre os sistema Pst e o sistema doiscomponentes PhoR/PhoB é mediada pela proteína PhoU, um regulador negativo cujo gene encontra-se no mesmo operon do transportador. Apesar de muito estudados em Escherichia coli , poucas informações existem sobre as características destes sistemas em Xanthomonas citri subsp. citri , bactéria responsável pelo cancro cítrico e de grande importância econômica para o país. Estudos realizados pelo nosso grupo mostraram que X. citri conserva a maioria dos genes descritos como pertencentes ao regulon Pho, incluindo o sistema Pst, as proteínas PhoR/PhoB e PhoU. Este trabalho, portanto, tem como objetivos, a caracterização funcional e estrutural da proteína PhoU de X. citri e a análise da possível interação de PhoU com a proteína PhoR, a histidina quinase do sistema dois componentes. Para tal, as proteínas foram expressas em linhagens de E. coli Tuner e purificadas por cromatografia de afinidade a metal, seguida de exclusão molecular. Visando a caracterização biofísica e estrutural da proteína PhoU, foram realizados ensaios de dicroísmo circular, cristalização, análises de bioinformática e modelagem molecular. Os resultados de bioinformática mostraram que PhoU conserva características estruturais e funcionais quando comparada com ortólogos. Após sua purificação, a proteína foi produzida na sua forma enovelada e mostrou interação com ligantes, conforme descrito na literatura para ortólogos. A expressão da proteína PhoR também foi obtida e ensaios de pull-down foram realizados para a caracterização da interação entre PhoU-PhoR. Adicionalmente, foram realizados estudos de expressão das proteínas em diferentes condições de cultivo, utilizando-se anticorpos policlonais anti-PhoU e anti-PhoR. Os resultados apresentados neste projeto são de grande importância uma vez que se obteve a padronização dos processos de produção de ambas as proteínas e ensaios biofísicos e estruturais para a futura caracterização do complexo, o que será de grande relevância para a compreensão do papel destes sistemas na fisiologia da bactéria. / The ability to sensor the extracellular environment and respond to its changes is inherent to most bacteria. Nutrient concentrations direct metabolic processes related to survival and proliferation. Inorganic phosphate (Pi) is one of the nutrients whose regulation, sensing and signalling are quite preserved in bacteria. One of the mechanisms for phosphate ion uptake with high affinity is the Pst system, composed by an ABC transporter (ATP-Binding Cassette), located on the inner membrane of the cells. This transporter, along with the PhoR/PhoB proteins, which form a Two Component Regulatory System, are capable of sensing and monitoring the levels of phosphate in cells. Both systems belong to the called regulon Pho, set of genes involved in phosphate transport, uptake and metabolism. Studies have shown that the interaction between the Pst system and the two component PhoR/PhoB system is mediated by the PhoU protein, a negative regulator, whose gene is located in the same operon of Pst system. Although much studied in Escherichia coli , there are few information about of these systems in Xanthomonas citri subsp. citri , the major causative of citric canker. Studies conducted by our group showed that X. citri conserves most of the genes described as belonging to regulon Pho, including the Pst system, the proteins PhoR/PhoB and PhoU. This work, therefore, aimed at performing functional and structural characterization of the X. citri PhoU protein and analyzing the possible interaction of PhoU with the PhoR protein, the histidine kinase of the Two Component System. For this, the proteins were expressed in E. coli Tuner strains and purified by metal affinity chromatography, followed by size exclusion chromatography. Aiming at the biophysical and structural characterization of the PhoU protein, we performed circular dichroism, crystallization, bioinformatics and molecular modeling. The results of bioinformatics showed that PhoU retains structural and functional characteristics when compared with orthologs. After purification, the protein was produced in its folded form and showed interaction with ligands, as described in the literature for orthologs. Expression of the PhoR protein was also obtained and Pull Down assays were performed for the characterization of the interaction between PhoUPhoR. In addition, protein expression studies were carried out under different culture conditions using polyclonal anti-PhoU and anti-PhoR antibodies. The results presented in this project are of great importance, once the standardization of the production processes of both proteins has been obtained, as well as biophysical and structural information. These information will be important for future characterization of the complex, which will be of great relevance for the understanding of the role of these systems in the physiology of bacteria.
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L-Lysine Decarboxylase and Cadaverine Gamma-Glutamylation Pathways in Pseudomonas Aeruginosa PAO1Chou, Han Ting 14 December 2011 (has links)
In comparison to other Pseudomonas, P. aeruginosa grows poorly in L-lysine as a sole source of nutrient while fast growth mutants can be obtained. The proposed catabolic pathway involves lysine decarboxylation to cadaverine and its subsequent degradation through g-glutamylation pathway to d-aminovalerate and glutarate. The lysine decarboxylase A (ldcA) gene, previously identified as a member of the ArgR regulon of L-arginine metabolism, was found essential for L-lysine catabolism. The ldcA gene encodes a decarboxylase which takes L-lysine but not L-arginine as substrate. Contrarily, the ldcA expression was inducible by L-arginine but not by L-lysine. This peculiar arginine control on lysine utilization was also noted from uptake experiments. The lack of lysine-responsive control on lysine catabolism and its tight connection to arginine regulatory network provided an explanation of lysine as poor nutrient for P. aeruginosa. Catabolism of cadaverine, a product from lysine decarboxylation, was investigated and compared to that of putrescine, another diamine of similar biochemical properties that is derived from arginine and ornithine. While the g-glutamylation pathway was first reported in E. coli for putrescine utilization, an expanded version of this pathway was found in P. aeruginosa with redundant enzymes for polyamine degradation. The PauR protein was identified as a transcriptional repressor of genes for the catabolism of putrescine and cadaverine, as well as their corresponding downstream metabolites, g-aminobutyrate (GABA) and d-aminovalerate (AMV). PauR shows distinct dimer configuration after glutaraldehyde crosslinkage, and possible conformational changes could be triggered by the presence of putrescine and cadaverine, but not GABA. A newly identified ABC transport system, encoded by the agtABCD operon, was found important for the uptake of GABA and AMV; and expression of which is controlled by the AgtSR two-component system. The CbrAB two-component system was proposed to regulate the catabolite repression control protein Crc through a small RNA CrcZ. A consensus CbrB recognition sequence was proposed based on the conserved palindromic nucleotide sequence in the upstream activating sequence of the crcZ promoter. Genetic studies indicated utilization of arginine, lysine and diamines (but not histidine, GABA and AMV) might be under CbrAB regulation through the CbrAB/CrcZ/Crc system in P. aeruginosa.
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La régulation de la virulence de l’agent de la coqueluche Bordetella pertussis : signalisation par le senseur-kinase BvgS / Virulence regulation of the whooping cough agent, Bordetella pertussis : signaling by the BvgS sensor-kinaseLesne, Elodie 29 September 2016 (has links)
Bordetella pertussis est l’agent responsable de la coqueluche. Pour coloniser le tractus respiratoire humain, cette bactérie à Gram négatif, aérobie stricte, produit de nombreux facteurs de virulence dont l’expression est sous la dépendance du système à deux composants BvgAS. BvgS est un senseur-kinase dimérique. Chaque monomère est constitué de trois domaines putatifs de perception - deux domaines Venus flytrap périplasmiques et un domaine PAS cytoplasmique -, suivis du domaine enzymatique et deux autres domaines, de phospho-transfert et receveur, impliqués dans la cascade de phosphorylation. L’expression du régulon de virulence est activée suite à la phosphorylation par BvgS du régulateur de réponse BvgA. BvgS est en mode kinase à l’état basal, et la perception de basses températures ou de signaux chimiques comme les ions sulfate ou nicotinate cause son passage en mode phosphatase. L’étude présentée dans ce manuscrit vise à caractériser le senseur-kinase BvgS en analysant les domaines putatifs de perception ainsi que la transduction de signal qui s’effectue au sein de la molécule. L’étude de la portion périplasmique a permis de mettre en évidence, à l’état basal, un gradient de dynamique décroissant. En se fixant au domaine VFT2 proximal à la membrane, le nicotinate induirait une diminution de la dynamique du second lobe du VFT1, causée par la formation d’un bloc compact entre le domaine VFT2 et le deuxième lobe du domaine VFT1. Cette rigidification exercerait une tension sur les hélices α qui précèdent les segments transmembranaires, provoquant une transition de la portion cytoplasmique vers l’état phosphatase. La perception de modulateurs par le domaine VFT2 - ou possiblement la fixation d’un ligand dans la cavité du VFT1- modifierait cette dynamique et causerait le changement d’activité de BvgS. Ainsi, nous proposons un modèle dans lequel le VFT1 est considéré comme le moteur du système, lui impulsant une dynamique qui serait relayée ou atténuée par le domaine VFT2. Une recherche de ligands antagonistes pour le domaine VFT1 a été entreprise, selon l’idée que la fixation d’un ligand réduirait la dynamique de ce dernier. Au sein du dimère, des connecteurs prédits pour former des enroulements d’hélices α (‘coiled coil’) relient entre eux les domaines VFT et PAS, et les domaines PAS et kinase de BvgS. La transduction d’information entre les domaines périplasmiques et le site enzymatique de BvgS a été analysée par mutagénèse dirigée et ‘cysteine scanning’. Des contacts proches sont observés entre les hélices constituant le segment transmembranaire, qui ne semblent pas être modifiés après perception de modulateur. Nous suggérons donc un modèle de piston symétrique pour la transmission d’information au travers de la membrane. Le coiled coil putatif précédant le domaine PAS présente une certaine dynamique rotationnelle à l’état basal. La perception de modulateurs semble induire l’écartement de ces hélices, ce qui pourrait permettre un changement de l’interface des domaines PAS. L’étude de la topologie du domaine PAS confirme une modification de cette interface entre les modes kinase et phosphatase de BvgS. Enfin, le coiled coil reliant les domaines PAS et kinase est sujet à une forte dynamique rotationnelle à l’état basal, en accord avec un modèle de régulation de l’activité kinase proposé dans d’autres systèmes. Suite à la perception de modulateur, une rigidification marquée de ce coiled coil est observée, permettant le passage en mode phosphatase. L’existence de deux états dynamiques différents de ce coiled coil a également été mise en évidence en absence du domaine PAS.Ces études ont permis d’avancer dans la compréhension de BvgS et de proposer un modèle de la signalisation au sein de ce senseur-kinase, qui pourrait s’appliquer aux autres membres de la famille de BvgS. / Bordetella pertussis is the agent of an acute and highly contagious respiratory disease, whooping cough. In order to colonize the human respiratory tract, this strictly aerobic Gram negative bacterium produces many virulence factors, the expression of which is regulated by the BvgAS two-component system. BvgS is a sensor-kinase composed of three putative domains of perception –two periplasmic Venus flytrap domains and a cytoplasmic PAS domain -, followed by the enzymatic domain and two other domains called phosphotransfert and receiver involved in the phophorelay. The expression of the virulence regulon is activated after the phosphorylation by BvgS of the response regulator BvgA. BvgS is in a kinase mode at the basal state, and the perception of low temperatures or chemical signals like sulfate ions or nicotinate causes a shift to the phosphatase state. The study presented in this manuscript has focused on the characterization of the BvgS sensor-kinase. We have analyzed its putative domains of perception and the mechanisms of signal transduction.Investigations into the dynamics of the periplasmic moiety has provided evidence for a decreasing gradient of dynamics from N to C-terminus at the basal state. Nicotinate binding to the membrane-proximal VFT2 domains decreases the dynamics of the second lobe of VFT1. Tighter interactions between the latter and the VFT2 domain cause a tension on the α helices that precede the transmembrane segments, triggering the transition to the phosphatase state of the enzymatic portion. Perception of modulator by the VFT2 domains –or possibly binding of a ligand in the VFT1 cavity- thus appears to modify periplasmic dynamics, which shifts BvgS activity. We propose that the VFT1 domains are the motor for BvgS activity, and their dynamics are relayed or attenuated by the VFT2 domains. A search for antagonistic VFT1 ligands has been undertaken, along the idea that ligand binding may reduce their dynamics.The VFT and PAS domains, and the PAS and kinase domains are joined to each other by long α helices predicted to form coiled coils. We performed directed mutagenesis and cysteine scanning analyses to decipher signal transduction between the periplasmic domains and the enzymatic moiety of BvgS. The close contacts between the helices of the transmembrane segment are not modified after perception of the modulator, suggesting that signal transduction across the membrane is mediated by symmetrical piston motions. The putative coiled coil before the PAS domain shows rotational dynamics at the basal state. Modulator perception causes the helices to splay, and this motion may modify the PAS domains interface. Our topology analyses of the PAS domain confirm that changes occur at this interface between the kinase and phosphatase states of BvgS. Finally, the coiled coil between the PAS and kinase domains presents a strong rotational dynamics at the basal state, which is consistent with the model of regulation of kinase activity proposed for other sensor-kinases. After perception of a modulator, this coiled coil becomes more rigid, allowing the shift to the phosphatase state. The occurrence of two states of dynamics for this coiled coil has also been demonstrated in the absence of the PAS domain.These studies have advanced our understanding of BvgS and allow us to propose a model of signaling by this sensor-kinase, which may apply more broadly to other family members.
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PA 7, souche atypique de Pseudomonas aeruginosa : Etude transcriptomique et caractérisation d'un troisième système de sécrétion de type II fonctionnel, Txc / PA7, an atypical strain of Pseudomonas aeruginosa : Transcriptomic study and characterization of a third functionnal type II secretion system, TxcCadoret, Frederic 07 July 2014 (has links)
Pseudomonas aeruginosa est une bactérie pathogène opportuniste qui est caractérisée par son ubiquité et sa grande capacité adaptative. Cette faculté lui est notamment permise par de nombreux systèmes de perception et de régulation, la sécrétion d'un large arsenal d'exoprotéines, une capacité à alterner entre deux modes de vie, une haute résistance naturelle aux antibiotiques ainsi qu'un génome riche soumis à une importante plasticité génomique. Cette dernière, associée aux pressions de sélection exercées par la grande diversité d'environnements rencontrés par P. aeruginosa, a permis l'émergence de nombreuses souches aux caractéristiques génotypiques et phénotypiques qui leur sont propres. Durant ma thèse, nous avons réalisé une analyse transcriptomique globale comparative entre les souches connues PA14, PAO1 et un nouvel isolat clinique atypique multirésistant aux antibiotiques, la souche PA7. Cette étude nous a permis de suggérer que cette souche, dépourvue des armes principales de la cytotoxicité, tendait naturellement vers un mode de développement associé à la formation de biofilm. Nous avons également caractérisé l'îlot génomique RGP69, unique à la souche PA7 qui code un troisième système de sécrétion de type II, Txc, qui sécrète dans le milieu extracellulaire une protéine d'affinité à la chitine, CbpE, sous le contrôle régulationnel d'un nouveau système de régulation à deux composants, Tts. Cet îlot génomique serait directement impliqué dans la physiologie particulière de la souche PA7. / Pseudomonas aeruginosa is an opportunistic bacterial pathogen, characterized by its ubiquity and its high adaptative property. This faculty is particularly due to many systems of perception and regulation, the secretion of a wide arsenal of exoproteins, an ability to switch between two life styles, a high natural resistance to antibiotics and a rich genome submitted to an important genomic plasticity. The latter, combined with the selection pressure exerted by the wide variety of environments encountered by P. aeruginosa, has allowed the emergence of many strains with their own genotypic and phenotypic characteristics.During my thesis, we performed an overall comparative transcriptomic analysis between the known strains PA14 and PAO1, and a new atypical clinical isolate multiresistant to antibiotics, the PA7 strain. This study allowed us to determine that this strain, lacking the main weapons of cytotoxicity, naturally tended to a life-style associated with biofilm formation. We also characterized the RGP69 genomic island, unique in the PA7 strain, which encodes a third type II secretion system, Txc, that secretes in the extracellular medium a chitin-binding protein, CbpE, under the regulatory control of a component system, Tts. This genomic island could be directly involved in the particular physiology of the PA7 strain.
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Characterization of Two Novel Gene Regulatory Systems in the Zoonotic Bacterium <i>Bartonella henselae</i>Tu, Nhan 19 November 2015 (has links)
The genus Bartonella contains Gram-negative arthropod-borne bacteria that are found in many small animal reservoirs and are capable of causing human disease. Bacteria utilize a general stress response system to combat stresses from their surrounding environments. In α-proteobacteria, the general stress response system uses an alternate σ factor as the main regulator and incorporates it with a two-component system into a unique system. Our study identifies the general stress response system in the α-proteobacterium, Bartonella henselae, where the gene synteny is conserved and both the PhyR and alternate σ factor have similar sequence and domain structures with other α-proteobacteria. Furthermore, we showed that the general stress response genes are up-regulated under conditions that mimic the cat flea vector. We also showed that both RpoE and PhyR positively regulate this system and that RpoE also affects transcription of genes encoding heme-binding proteins and the BadA adhesin. Finally, we also identified a histidine kinase, annotated as BH13820 that can potentially phosphorylate PhyR. In addition, analysis of the transcriptome from the Houston-1 strain of B. henselae by RNA-Seq reveals a family of small RNAs (termed Brt1-Brt9 for Bartonella Regulatory Transcripts 1-9) that may rapidly adapt gene expression patterns to the diverse hosts of this bacterium. This family of RNAs consists of nine novel, highly expressed intergenic transcripts, ranging from 193-205 nucleotides with a high degree of homology (70-100%) and stable predicted secondary structures that are unique to the genus Bartonella. Northern blot analysis indicates that transcription of these sRNAs was highest under conditions mimicking those of the cat flea vector (low temperature, high hemin). The predicted promoters for Brt1-Brt9 have been cloned upstream of a β-galactosidase reporter gene in pNS2 to identify conditions altering transcription. Immediately downstream of each of the nine putative sRNAs is a helix-turn-helix DNA binding protein (termed Trp1-9 for Transcriptional Regulatory Protein 1-9) that is poorly transcribed as determined by RNA-Seq. This gene organization is suggestive of a potential cis-acting RNA mechanism or riboswitch with the RNA secondary structure controlling transcription of the cognate downstream trp.
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