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La protéine Fnr et le système à deux composants ResDE, des régulateurs majeurs de la synthèse des entérotoxines de Bacillus cereus / The Fnr protein and the two component system ResDE, two major regulators of enterotoxin gene expression in Bacillus cereusEsbelin, Julia 02 July 2009 (has links)
Bacillus cereus est un pathogène opportuniste à l'origine de deux types de toxi-infections alimentaires classées en syndrome émétique ou diarrhéique. Le syndrome diarrhéique résulte de la production d'entérotoxines (Hbl, Nhe et CytK) au niveau de l'intestin grêle de l'hôte, caractérisé par une atmosphère anaérobie et un faible potentiel d'oxydo-réduction (POR). La capacité de B. cereus à se développer et à produire des entérotoxines dans ces conditions est sous le contrôle de deux systèmes qui agissent, en partie, indépendamment du régulateur pléiotrope connu, PlcR (Phospholipase C Regulator). Il s'agit du système à deux composants ResDE et de la protéine Fnr (Fumarate Nitrate Reductase). Le but de cette étude a été de caractériser d'un point de vue fonctionnel l'implication du régulateur Fnr et du système ResDE dans la toxinogenèse de B. cereus. Les résultats ont montré que la régulation de la transcription de hbl et nhe était sous le contrôle direct et indirect de Fnr et de ResD. En aérobiose, la fixation de Fnr (forme Apo) sur les régions promotrices des gènes de structure des entérotoxines (pnhe et phbl) et des gènes de régulation (presDE, pfnr et pplcR) dépend des conditions redox. L'affinité de ResD pour pnhe, phbl, presDE, pfnr et pplcR dépend des séquences de ces régions promotrices et son affinité pour les régions promotrices presDE et pfnr dépend de son état de phosphorylation. ResD et ApoFnr sont capables de se fixer simultanément sur les régions promotrices étudiées et sont également capables d'interagir physiquement en l'absence d'ADN. Nous avons proposé un modèle de régulation de la toxinogenèse dans lequel ResDE et Fnr pourraient agir en synergie. Enfin des expériences de double hybride ont permis de mettre en évidence que la protéine PlcR pourrait interagir in vivo avec les régulateurs ResD et Fnr. La régulation de la toxinogenèse impliquerait donc la formation d'un complexe multi-moléculaire / Bacillus cereus is an opportunistic pathogen responsible of two types of food-borne diseases, classified as emetic and diarrhoeal syndromes. The diarrhoeal syndrome results from the production of enterotoxins (Hbl, Nhe and CytK) in the host small intestine, which constitutes a high reducing anoxic environment. The ability of B. cereus to produce enterotoxins and grow well in such environment is controlled by two global regulators that may function independently of the pleiotropic virulence regulator PlcR (Phospholipase C Regulator). These two regulators are the two-component system ResDE and the redox regulator Fnr (Fumarate Nitrate Reductase). The aim of this study was to establish the role of Fnr and ResDE in the virulence regulatory pathway of B. cereus. The results showed that transcriptional regulation of hbl and nhe was directly and indirectly controlled by Fnr and ResD. In aerobiosis, Fnr interaction (apo form) with the promoter regions of the enterotoxin structural genes (pnhe and phbl) and the enterotoxin regulator genes (presDE, pfnr and pplcR) depends on its oligomeric state. DNA binding affinity of ResD for pnhe, phbl, presDE, pfnr and pplcR depends on the promoter sequences and affinity for presDE and pfnr depends on its phosphorylation state. ResD and Fnr were found to physically interact and simultaneously bind their target DNAs. We proposed a model for regulation of enterotoxin genes expression in which ResD and Fnr could act synergically. Finally, yeast two-hybride experiments showed that PlcR could physically interact in vivo with Fnr and ResD. Enterotoxin genes expression of B. cereus could thus be controlled through a mechanism including a ternary complex
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Ideonella dechloratans: Investigation of the chlorite dismutase promoterGoetelen, Thijs January 2015 (has links)
Chlorate and perchlorate pollutions have become a problem in the environment in the last decades. Studies have shown that some bacteria can degrade these substances into unharmful substances such as chloride and molecular oxygen. One of these chlorate degrading bacteria is Ideonella dechloratans that uses chlorate reductase and chlorite dismutase to process chlorate. In the promoter gene sequence of chlorite dismutase there might be regulator sequences such as fumarate and nitrate reductase regulator (FNR) and aerobic respiration control protein (ArcA) that might control the transcription of this enzyme. This promoter sequence was placed in a pBBR1MCS-4-LacZ reporter vector and the possible regulatory sequences were changed through site-directed mutagenesis and tested on activity through beta-galactosidase assays. The changes in the FNR binding sequence gave beta-galactosidase activity that was close to a negative control which might give conclusions that either FNR has an important role or an important part of the promoter was hit. The changes in the ArcA regulator binding sequence did not give such big differences and no certainty can be given if this made important changes to the promoter.
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Production de lipides et étude de la régulation métabolique chez la diatomée Asterionella formosa / Production of neutral lipids in Asterionella formosa and regulation of metabolismMekhalfi, Malika 17 December 2014 (has links)
La diatomée d'eau douce A. formosa peut produire des lipides neutres en plus ou moins grandes quantités en fonction des conditions de culture. Ainsi, nous avons montré par exemple qu'une carence en silice stimule la production de triacylglycérols (TAGs) mais génère une diminution de la biomasse. En revanche, nous avons montré que l'addition de bicarbonate et de phytohormones augmente à la fois la biomasse et la production de TAGs. L'ajout de phytohormones dans les milieux de culture de cette diatomée résulte en une augmentation de l'activité d'enzymes dans les extraits et notamment celles du cycle de Benson-Calvin. Parmi ces enzymes, la GAPDH est une enzyme dont l'activité augmente significativement. Nous avons montré que chez A. formosa, cette enzyme forme un complexe ternaire avec la CP12 et la Férrédoxine NADP Réductase (FNR) et non pas avec la CP12 et la phosphoribulokinase comme chez la plupart des organismes photosynthétiques. La régulation de cette enzyme en est de fait modifiée. La phytohormone, 24-épibrassinolide conduit à une augmentation d'activité de la GAPDH qui résulte de la dissociation du complexe GAPDH-CP12 et la GAPDH n'est plus redox régulée. La GAPDH chez les diatomées est donc régulée par des interactions protéineprotéine. / A. formosa, a freshwater diatom, can produce different amounts of neutral lipids such as triacylglycerols (TAGs) under different growth conditions. We showed that as it is well-known for diatoms, starvation for silica increased the production of TAGs but decreased biomass. However, the addition of bicarbonate or phytohormones into the growth medium increased both biomass and TAGs. Addition of phytohormones increased the activities of enzymes in particular those of the Benson-Calvin cycle. Among the target enzymes of the Benson-Calvin cycle, GAPDH was strongly affected. We purified this enzyme and demonstrated that, in the diatom A. formosa, glyceraldehyde-3-phosphate dehydrogenase (GAPDH) from the Calvin cycle, forms a complex with the small chloroplast protein CP12 and Ferredoxin NADP Reductase (FNR), which is involved in the photochemical phase of photosynthesis. In cells treated with the phytohormone, 24-epibrassinolide, GAPDH was "free", not redox-regulated and not associated anymore with CP12. Therefore GAPDH from this diatom is regulated by protein-protein interaction but the GAPDH/CP12/FNR complex replaces the one formed between GAPDH, CP12 and phosphoribulokinase found in most photoautotrophs.
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Regulation of nitrogen fixation in <i>Klebsiella pneumoniae</i>: The role of Fnr in oxygen signal-transduction / Regulation der Stickstoffixierung in <i>Klebsiella pneumoniae</i>: die Rolle von Fnr in der SauerstoffsignaltransduktionGrabbe, Roman 20 June 2002 (has links)
No description available.
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Etude d’un système respiratoire de Porphyromonas gingivalis, pathogène impliqué dans les infections parodontales / Characterisation of an oxygen-dependent respiratory enzyme of the periodontal pathogen Porphyromonas gingivalisLeclerc, Julia 21 December 2015 (has links)
Les parodontites sont des maladies chroniques inflammatoires causées par un biofilm bactérien. Elles sont la première cause de perte des dents dans les pays industrialisés et représentent donc un coût important pour la société. Le biofilm buccal est composé de plus de 500 espèces différentes, parmi lesquelles Porphyromonas gingivalis est reconnue comme une cause majeure du développement des symptômes. Cette bactérie à Gram négatif est considérée comme anaérobie bien qu’elle tolère des concentrations faibles en oxygène, ce qui favorise la colonisation de la cavité orale. Notre objectif était de mettre en évidence les processus biologiques conférant à P. gingivalis sa résistance à l’oxygène et au stress oxydant, mais également ceux impliqués dans la transition métabolique en concentrations variables d’oxygène. Des analyses in silico des génomes de souches de P. gingivalis ont révélé la présence d’un système respiratoire dépendant de l’oxygène, impliquant une cytochrome bd oxydase CydAB. Nous avons construit un mutant de P. gingivalis ATCC 33277 par délétion des gènes cydAB. Nos travaux ont montré que ce mutant était plus sensible que la souche parentale aux espèces réactives de l’oxygène (ROS) dont le peroxyde d’hydrogène et le générateur d’anion superoxyde paraquat. De plus, nous avons démontré que CydAB était impliquée dans le phénotype aérotolérant de P. gingivalis, et que cette enzyme consommait effectivement l’oxygène grâce à une étude par oxygraphie à haute résolution. Les mécanismes de régulations en réponse aux ROS et à l’oxygène sont encore mal connus, notamment en ce qui concerne la régulation positive de l’expression des gènes cydAB en présence d’oxygène. Deux gènes codant des régulateurs de type FNR ont été identifiés dans le génome de P. gingivalis, l’un d’entre eux codant un régulateur de la réponse au stress nitrosant, HcpR. Le second gène PGN_1569 a fait l’objet de notre étude. Par mutation et par analyses transcriptomiques, nous avons démontré que ce régulateur s’autorégulait négativement et activait l’expression de 4 groupes de gènes en anaérobie, n’incluant pas les gènes cydAB. L’expression de ces gènes est par ailleurs contrôlée par d’autres régulateurs redox, OxyR et/ou SigH et/ ou RprY. Cette étude met donc en évidence une connexion entre FNR et les autres régulateurs de la réponse au stress oxydant chez P. gingivalis. Des études complémentaires permettront de caractériser la fonction encore hypothétique des protéines codées par le régulon FNR. Il est intéressant de noter que l’absence de FNR confère à P. gingivalis une plus grande capacité à former un biofilm en anaérobie / Periodontal diseases are chronic inflammatory infections caused by bacteria in oral biofilm they are the first cause of loss of tooth in industrial countries with an important cost for the society. The biofilm comprises more than 500 bacterial species. Amongst them, Porphyromonas gingivalis, a Gram-negative bacterium, is well known as a major causative agent of periodontitis. Although considered as mainly anaerobe, P. gingivalis tolerates low oxygen concentration, therefore enhancing its ability to colonize the oral cavity. Our aim was to decipher the biological processes underpinning the resistance of P. gingivalis to oxygen and reactive oxygen species (ROS) and to characterise the transition from anaerobiosis to hypoxia. In silico studies of P. gingivalis genomes have revealed the presence of a putative oxygen-dependent respiratory system involving a cytochrome bd oxidase CydAB. We constructed a mutant deleted for cydAB genes in the P. gingivalis ATCC 33277 strain. Our study showed that cydAB mutation increased the sensibility of the mutant to reactive oxygen species such as the anion-superoxide generator paraquat and hydrogen peroxide. Moreover we demonstrated that CydAB is involved in the aerotolerance of P. gingivalis, and in oxygen consumption, as demonstrated by high resolution respirometry assay. Many regulations in response to ROS and oxygen are still unexplained in P. gingivalis, including the activation of cydAB expression by oxygen exposure. Two genes encoding FNR-like regulators were identified in the genome of P. gingivalis. One of them encodes the HcpR regulator which controls part of the nitrosative stress response. The second gene PGN_1569 was the focus of our study. By mutation and transcriptome analysis, we demonstrated that this FNR-like regulator repressed its own transcription and activated the expression of 4 gene clusters in anaerobiosis, but not including cydAB genes. The expression of these 4 gene clusters is also controlled by other redox regulators, OxyR and/or SigH and/or RprY. Therefore, this study pointed out the interplay between FNR and known oxidative stress response regulators of P. gingivalis. Further work will study the functions of the hypothetical proteins encoded by the FNR regulon. Interestingly, the fnr mutant displayed higher ability than the wild-type strain to form biofilm in anaerobiosis.
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La protéine Fnr et le système à deux composants ResDE, des régulateurs majeurs de la synthèse des entérotoxines de Bacillus cereusEsbelin, Julia 02 July 2009 (has links) (PDF)
Bacillus cereus est un pathogène opportuniste à l'origine de deux types de toxi-infections alimentaires classées en syndrome émétique ou diarrhéique. Le syndrome diarrhéique résulte de la production d'entérotoxines (Hbl, Nhe et CytK) au niveau de l'intestin grêle de l'hôte, caractérisé par une atmosphère anaérobie et un faible potentiel d'oxydo-réduction (POR). La capacité de B. cereus à se développer et à produire des entérotoxines dans ces conditions est sous le contrôle de deux systèmes qui agissent, en partie, indépendamment du régulateur pléiotrope connu, PlcR (Phospholipase C Regulator). Il s'agit du système à deux composants ResDE et de la protéine Fnr (Fumarate Nitrate Reductase). Le but de cette étude a été de caractériser d'un point de vue fonctionnel l'implication du régulateur Fnr et du système ResDE dans la toxinogenèse de B. cereus. Les résultats ont montré que la régulation de la transcription de hbl et nhe était sous le contrôle direct et indirect de Fnr et de ResD. En aérobiose, la fixation de Fnr (forme Apo) sur les régions promotrices des gènes de structure des entérotoxines (pnhe et phbl) et des gènes de régulation (presDE, pfnr et pplcR) dépend des conditions redox. L'affinité de ResD pour pnhe, phbl, presDE, pfnr et pplcR dépend des séquences de ces régions promotrices et son affinité pour les régions promotrices presDE et pfnr dépend de son état de phosphorylation. ResD et ApoFnr sont capables de se fixer simultanément sur les régions promotrices étudiées et sont également capables d'interagir physiquement en l'absence d'ADN. Nous avons proposé un modèle de régulation de la toxinogenèse dans lequel ResDE et Fnr pourraient agir en synergie. Enfin des expériences de double hybride ont permis de mettre en évidence que la protéine PlcR pourrait interagir in vivo avec les régulateurs ResD et Fnr. La régulation de la toxinogenèse impliquerait donc la formation d'un complexe multi-moléculaire
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Observing flow using fast neutron radiography and positron emission particle trackingDaniels, Graham Clinton 12 July 2021 (has links)
Dynamic flow of material has been studied using fast neutron radiography (FNR) and positron emission particle tracking (PEPT). A new fast neutron imaging system was commissioned at The South African Nuclear Energy Corporation, Pretoria, as part of this study, although FNR measurements were ultimately performed at PhysikalischTechnische Bundesanstalt (PTB), Braunschweig. The PEPT studies were undertaken at the PEPT Cape Town facility located at iThemba LABS, Cape Town. The steady state motion of media, within a laboratory-scale tumbling mill, was studied for a range of speed and media mixes, using both FNR and PEPT. Several operational parameters were derived from the data, which could be related to potential improvements to the milling efficiency. The blending of FNR and PEPT data for the study of steady state flow, was explored for the first time. In addition, the flow of water through porous media was studied using FNR, which enabled the determination of the hydraulic conductivity, and hence intrinsic permeability, of the media within the column. The potential of using FNR, without or without PEPT, for the study of material in motion is discussed.
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Etudes électrochimiques de chaînes de transfert d'électrons photosynthétiques ou Vers une photoproduction biomimétique d'hydrogène.Fourmond, Vincent 03 April 2007 (has links) (PDF)
Pour assurer l'avenir énergétique de l'humanité, il est vital de se tourner vers d'autres ressources que les combustibles fossiles. La photosynthèse est un système efficace élaboré sur des centaines de millions d'années pour convertir l'énergie lumineuse en énergie chimique. <br />Certaines algues sont capables de produire de l'hydrogène à partir d'eau en utilisant des chaînes photosynthétiques pour alimenter des enzymes, les hydrogénases, qui catalysent la formation d'hydrogène gazeux. Cette thèse s'inscrit dans un projet d'étudier et de comprendre ces systèmes pour être en mesure d'imiter leurs fonctions avec des systèmes artificiels. <br />Au cours de cette thèse, des chaînes de transferts d'électrons impliquant des protéines photosynthétiques (photosystème I) et leurs partenaires ont été étudiées ex-vivo dans des cellules électrochimiques par voltamétrie cyclique. L'activité catalytique des photosystèmes sous éclairement permet d'obtenir un transfert linéaire d'électrons depuis l'électrode jusqu'à un accepteur final. <br />Une méthode fondée sur les mesures de courants photocatalytiques a été mise au point et utilisée pour explorer les interactions de différents partenaires de la chaîne photosynthétique. Il a été montré qu'il est possible de choisir la réaction de la chaîne à étudier par cette méthode en adaptant les concentrations des différents partenaires. Cette méthode a été appliquée avec succès à l'étude des partenaires directs du photosystème I et à l'élucidation de certains aspects du fonctionnement de la ferrédoxine:NADPH oxydoréductase. Ces résultats s'annoncent prometteurs pour l'étude des hydrogénases par la même technique.
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Análise epidemiológica de cepas APEC e análise do regulador FNR na modulação da virulência de ExPECBarbieri, Nicolle Lima January 2014 (has links)
Escherichia coli é um bacilo Gram-negativo, anaeróbico facultativo e de distribuição cosmopolita. E. coli coloniza o intestino de humanos e outros animais endotérmicos logo após o nascimento, estabelecendo-se como um importante membro da microbiota intestinal. Algumas cepas de E. coli podem adquirir fatores de virulência, assumindo assim, uma natureza patogênica, como é o caso das E. coli patogênicas extraintestinais (ExPEC). As cepas ExPEC apresentam a capacidade de colonizar e se disseminar em diversos nichos no hospedeiro, e são divididas em UPEC (E. coli uropatogênica), NMEC (E. coli causadora de meningite neonatal) e APEC (E. coli patogênica para aves). UPEC, NMEC e APEC compartilham fatores associados à virulência. Para serem aptas a causar doença, cepas ExPEC devem apresentar pelo menos um fator associado à adesão, um fator para captação de ferro (sideróforo) e um fator de resistência ao soro, podendo, também, apresentar genes que codificam toxinas e invasinas. Embora sejam conhecidos muitos fatores de virulência associados à patogenicidade de cepas ExPEC, a regulação da expressão de tais fatores ainda não foi elucidada. Fumarato-nitrato-redutase (FNR) é uma proteína que atua como regulador global, agindo como um sensor da presença de oxigênio em bactérias gramnegativas. Já foi demonstrado que FNR está relacionada à regulação da virulência de bactérias patogênicas como Shigella flexneri e Salmonella enterica serovar Typhimurium. Este trabalho teve como objetivo a análise epidemiológica e caracterização de cepas APEC, bem como a investigação do controle da expressão de fatores associados à virulência de ExPEC pelo regulador global FNR. Os resultados da análise epidemiológica das cepas APEC mostram o perfil de resistência aos agentes antimicrobianos, a prevalência dos fatores de virulência e dos grupos filogenéticos (de acordo com a classificação EcoR) e a relação filogenética dos isolados, fornecendo um panorama da caracterização de E. coli patogênicas aviárias de lesões severas de celulite e de infecção sistêmica oriundas da região sul do Brasil. Em relação ao FNR, este estudo mostrou a influência deste regulador sobre importantes fatores associados à virulência, estando envolvido no controle de várias etapas do estabelecimento da infecção por cepas ExPEC. A deleção de fnr na cepa UPEC CFT 073 reduziu a motilidade, a expressão das fimbrias tipo I e tipo P, reduziu a expressão da hemolisina e controlou a expressão da ilha de patogenicidade do α- cetoglutarato. Além disso, a deleção de fnr fez tornou as bactérias incapazes de invadir células dos rins e da bexiga e de causar doença in vivo em camundongos de 6 semanas. FNR também foi capaz de controlar as etapas da infecção por NMEC 56. Uma vez deletado, as bactérias perderam a capacidade de causar bacteremia, de crescer no fluido cerebrospinal e de causar doença in vivo em ratos de 5 dias de idade. A deleção de fnr em APEC O1 resultou na diminuição da expressão da proteína OmpT plasmidial, da fímbria do tipo I e do auto-transportador AatA. A principal contribuição deste trabalho foi demonstrar que FNR atua na regulação da expressão de importantes fatores associados à virulência de cepas ExPEC (UPEC, NMEC e APEC), sendo importante para o estabelecimento da infecção por essas cepas. Neste trabalho, verificamos que, além da função já conhecida de regular os genes envolvidos na manutenção de um meio anaeróbico, FNR também atua no controle de genes associados à virulência de cepas ExPEC, refletindo na capacidade de causar doença que tais cepas apresentam. / Escherichia coli is a Gram-negative bacillus, facultative anaerobic and has cosmopolitan distribution. E. coli colonizes the intestine of humans and other endothermic animals immediately after birth, establishing as an important member of the intestinal microbiota. Some strains of E. coli can acquire virulence factors thereby assuming a pathogenic nature, as in the case of extraintestinal pathogenic E. coli (ExPEC). ExPEC strains have the ability to colonize and spread out in different niches of the host, and are divided into UPEC (uropathogenic E. coli), NMEC (newborn meningitis E. coli) and APEC (avian pathogenic E. coli). UPEC, NMEC and APEC share virulence factors. To be able to cause disease, ExPEC strains must produce virulence factors required for adherence, for iron uptake (siderophore) and for resistance to serum and may also contain genes encoding toxins and invasins. Although many virulence factors associated with the pathogenicity of ExPEC strains are known, the regulation of the expression of these factors has not yet been fully elucidated. Fumarate nitrate reductase (FNR) is a global regulatory protein, acting as a sensor of oxygen in Gram- negative bacteria. It has been shown that FNR relates virulence of pathogenic bacteria such as Shigella flexneri and Salmonella enterica serovar Typhimurium. The aim of this study was to do an epidemiological analysis and characterization of APEC strains as well as the investigation of regulation of ExPEC’s virulence factors by the global FNR regulator. The results of epidemiological analysis of APEC strains showed the profile of antimicrobial resistance , the prevalence of virulence factors and phylogenetic groups (according to the EcoR group) and the phylogenetic relationship of the isolates, providing an overview of the characterization of avian pathogenic E. coli causing severe cellulitis lesions and systemic infection originating from southern Brazil. In relation to FNR, this study showed the influence of this important regulator of virulence factors that is involved in controlling various stages of establishment of infection by ExPEC strains. Deletion of fnr in UPEC strain CFT 073 reduced motility and expression of type I and type P fimbriae, reduced the expression of hemolysin and control the expression of the pathogenicity island of α -ketoglutarate. Furthermore, fnr mutant strains were unable to invade cells of kidney and bladder, and to colonize the urinary tract of 6 weeks-old mice. FNR was also able to control the stages of infection of NMEC 56. The fnr mutant lost its ability to cause bacteremia, grow in cerebrospinal fluid, cause disease in 5 days old rats. Deletion of fnr in APEC O1 resulted in decreased expression of genes corresponding to the plasmid encoded OmpT protein, type I fimbriae and autotransporter AatA. The main contribution of this work was to demonstrate that FNR regulates expression of important virulence factors of ExPEC strains (UPEC, NMEC and APEC), which is important for the establishment of infection by these strains. In this work, we found that, besides the already known function in regulating genes involved in maintaining an anaerobic environment, FNR also acts in the control of virulenceassociated genes of ExPEC strains, reflecting the ability of these strains to cause disease.
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Análise epidemiológica de cepas APEC e análise do regulador FNR na modulação da virulência de ExPECBarbieri, Nicolle Lima January 2014 (has links)
Escherichia coli é um bacilo Gram-negativo, anaeróbico facultativo e de distribuição cosmopolita. E. coli coloniza o intestino de humanos e outros animais endotérmicos logo após o nascimento, estabelecendo-se como um importante membro da microbiota intestinal. Algumas cepas de E. coli podem adquirir fatores de virulência, assumindo assim, uma natureza patogênica, como é o caso das E. coli patogênicas extraintestinais (ExPEC). As cepas ExPEC apresentam a capacidade de colonizar e se disseminar em diversos nichos no hospedeiro, e são divididas em UPEC (E. coli uropatogênica), NMEC (E. coli causadora de meningite neonatal) e APEC (E. coli patogênica para aves). UPEC, NMEC e APEC compartilham fatores associados à virulência. Para serem aptas a causar doença, cepas ExPEC devem apresentar pelo menos um fator associado à adesão, um fator para captação de ferro (sideróforo) e um fator de resistência ao soro, podendo, também, apresentar genes que codificam toxinas e invasinas. Embora sejam conhecidos muitos fatores de virulência associados à patogenicidade de cepas ExPEC, a regulação da expressão de tais fatores ainda não foi elucidada. Fumarato-nitrato-redutase (FNR) é uma proteína que atua como regulador global, agindo como um sensor da presença de oxigênio em bactérias gramnegativas. Já foi demonstrado que FNR está relacionada à regulação da virulência de bactérias patogênicas como Shigella flexneri e Salmonella enterica serovar Typhimurium. Este trabalho teve como objetivo a análise epidemiológica e caracterização de cepas APEC, bem como a investigação do controle da expressão de fatores associados à virulência de ExPEC pelo regulador global FNR. Os resultados da análise epidemiológica das cepas APEC mostram o perfil de resistência aos agentes antimicrobianos, a prevalência dos fatores de virulência e dos grupos filogenéticos (de acordo com a classificação EcoR) e a relação filogenética dos isolados, fornecendo um panorama da caracterização de E. coli patogênicas aviárias de lesões severas de celulite e de infecção sistêmica oriundas da região sul do Brasil. Em relação ao FNR, este estudo mostrou a influência deste regulador sobre importantes fatores associados à virulência, estando envolvido no controle de várias etapas do estabelecimento da infecção por cepas ExPEC. A deleção de fnr na cepa UPEC CFT 073 reduziu a motilidade, a expressão das fimbrias tipo I e tipo P, reduziu a expressão da hemolisina e controlou a expressão da ilha de patogenicidade do α- cetoglutarato. Além disso, a deleção de fnr fez tornou as bactérias incapazes de invadir células dos rins e da bexiga e de causar doença in vivo em camundongos de 6 semanas. FNR também foi capaz de controlar as etapas da infecção por NMEC 56. Uma vez deletado, as bactérias perderam a capacidade de causar bacteremia, de crescer no fluido cerebrospinal e de causar doença in vivo em ratos de 5 dias de idade. A deleção de fnr em APEC O1 resultou na diminuição da expressão da proteína OmpT plasmidial, da fímbria do tipo I e do auto-transportador AatA. A principal contribuição deste trabalho foi demonstrar que FNR atua na regulação da expressão de importantes fatores associados à virulência de cepas ExPEC (UPEC, NMEC e APEC), sendo importante para o estabelecimento da infecção por essas cepas. Neste trabalho, verificamos que, além da função já conhecida de regular os genes envolvidos na manutenção de um meio anaeróbico, FNR também atua no controle de genes associados à virulência de cepas ExPEC, refletindo na capacidade de causar doença que tais cepas apresentam. / Escherichia coli is a Gram-negative bacillus, facultative anaerobic and has cosmopolitan distribution. E. coli colonizes the intestine of humans and other endothermic animals immediately after birth, establishing as an important member of the intestinal microbiota. Some strains of E. coli can acquire virulence factors thereby assuming a pathogenic nature, as in the case of extraintestinal pathogenic E. coli (ExPEC). ExPEC strains have the ability to colonize and spread out in different niches of the host, and are divided into UPEC (uropathogenic E. coli), NMEC (newborn meningitis E. coli) and APEC (avian pathogenic E. coli). UPEC, NMEC and APEC share virulence factors. To be able to cause disease, ExPEC strains must produce virulence factors required for adherence, for iron uptake (siderophore) and for resistance to serum and may also contain genes encoding toxins and invasins. Although many virulence factors associated with the pathogenicity of ExPEC strains are known, the regulation of the expression of these factors has not yet been fully elucidated. Fumarate nitrate reductase (FNR) is a global regulatory protein, acting as a sensor of oxygen in Gram- negative bacteria. It has been shown that FNR relates virulence of pathogenic bacteria such as Shigella flexneri and Salmonella enterica serovar Typhimurium. The aim of this study was to do an epidemiological analysis and characterization of APEC strains as well as the investigation of regulation of ExPEC’s virulence factors by the global FNR regulator. The results of epidemiological analysis of APEC strains showed the profile of antimicrobial resistance , the prevalence of virulence factors and phylogenetic groups (according to the EcoR group) and the phylogenetic relationship of the isolates, providing an overview of the characterization of avian pathogenic E. coli causing severe cellulitis lesions and systemic infection originating from southern Brazil. In relation to FNR, this study showed the influence of this important regulator of virulence factors that is involved in controlling various stages of establishment of infection by ExPEC strains. Deletion of fnr in UPEC strain CFT 073 reduced motility and expression of type I and type P fimbriae, reduced the expression of hemolysin and control the expression of the pathogenicity island of α -ketoglutarate. Furthermore, fnr mutant strains were unable to invade cells of kidney and bladder, and to colonize the urinary tract of 6 weeks-old mice. FNR was also able to control the stages of infection of NMEC 56. The fnr mutant lost its ability to cause bacteremia, grow in cerebrospinal fluid, cause disease in 5 days old rats. Deletion of fnr in APEC O1 resulted in decreased expression of genes corresponding to the plasmid encoded OmpT protein, type I fimbriae and autotransporter AatA. The main contribution of this work was to demonstrate that FNR regulates expression of important virulence factors of ExPEC strains (UPEC, NMEC and APEC), which is important for the establishment of infection by these strains. In this work, we found that, besides the already known function in regulating genes involved in maintaining an anaerobic environment, FNR also acts in the control of virulenceassociated genes of ExPEC strains, reflecting the ability of these strains to cause disease.
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