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Antivirulent and antibiofilm salicylidene acylhydrazide complexes in solution and at interfacesHakobyan, Shoghik January 2015 (has links)
The growing bacterial resistance against antibiotics creates a limitation for using traditional antibiotics and requests development of new approaches for treatment of bacterial infections. Among the bacterial infections that are most difficult to treat, biofilm-associated infections are one of the most hazardous. Consequently, the prevention of biofilm formation is a very important issue. One of the techniques that are widely investigated nowadays for this purpose is surface modification by polymer brushes that allows generating antifouling antibacterial surfaces. Previously, it was reported that salicylidene acylhydrazides (hydrazones) are good candidates as antivirulence drugs targeting the type three secretion system (T3SS). This secretion system is used by several Gramnegative pathogens, including Pseudomonas aeruginosa, to deliver toxins into a host cell. Furthermore, the chemical structure of these substances allows formation of complexes with metal ions, such as Fe3+ and Ga3+. The antibacterial activity of Ga3+ is well known and attributed to its similarity to the Fe3+ ion. It has also been shown that Ga3+ ions are able to suppress biofilm formation and growth in bacteria. In this thesis the chemistry of antibacterial and antivirulence Ga3+-Hydrazone complexes in solution was studied. First, to get insights in the solution chemistry, the protonation and the stability constants as well as the speciation of the Ga3+-Hydrazone complexes were determined. Additionally, a procedure for anchoring one of the hydrazone substances to antifouling polymer brushes was optimized, and the resulting surfaces were characterized. Results showed that the complexation with Ga3+ ions stabilizes the ligand and increases its solubility. Ga3+ ion binds to the hydrazone molecule forming a strong chelate that should be stable at physiological conditions. The different biological assays, such as Ga3+ uptake, antivirulence and antibiofilm effects, indicated very complex interaction of these complexes with the bacterial cell. Negatively charged and zwitterionic surfaces strongly reduced protein adsorption as well as biofilm formation. Therefore, the antifouling zwitterionic poly-[2-(methacryloyloxy)ethyl]dimethyl-3- sulfopropyl)-ammonium hydroxide (pMEDSAH) brushes were post-modified and successfully functionalized with bioactive substances via a block-copolymerization strategy. However, in order to maintain the availability of the bioactive substance after functionalization, the hydrophobic polyglycidylmethacrylate (pGMA) top block is probably better to functionalize with a lipophilic molecules to reduce diblock copolymer brush rearrangement.
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Structural studies of the inner membrane ring of the bacterial type III secretion systemMcDowell, Melanie A. January 2012 (has links)
Shigella flexneri attacks cells of the intestinal tract, causing over 1 million deaths annually from bacterial dysentery. A type III secretion system (T3SS) initiates the host-pathogen interaction and transports virulence factors directly into host cells via a needle complex (NC) comprising an extracellular needle and membrane-spanning basal body. Rings formed by the single-pass membrane proteins MxiG and MxiJ are arranged concentrically within the inner membrane ring (IMR) of the NC. The Neterminal domain of MxiG (MxiG-N) is the predominant IMR cytoplasmic structure, however it was structurally and functionally uncharacterised. Determination of the solution structure of MxiG-N in this study revealed it to be a forkhead associated (FHA) domain, although subsequent analyses of conserved residues suggested it does not have the canonical role in cell-signalling via phospho-threonine recognition. Subsequent positioning of the structure in the electron microscopy (EM) density for the S. flexneri NC supported models with 24-fold symmetry in the IMR. Both MxiG and MxiJ also have significant periplasmic domains, which were purified to homogeneity in this study, facilitating preliminary characterisation of their structures and intermolecular interactions. In addition, the entire IMR within the context of intact basal bodies was isolated and visualised in vitro by EM. The essential function of MxiG-N could be to localise the putative cytoplasmic ring (Cering) at the base of the T3SS. Although absolutely required for secretion, the Csring component, Spa33, was structurally uncharacterised. The crystal structure of the Cvterminal domain of Spa33 (Spa33-C) was determined in this study, showing an intertwined dimer that aligned with homologous structures and exhibited a novel interaction with the N-terminus of the ATPase regulator, MxiN. Subsequently, Spa33-C was identified as an altemative translation product of spa33 that formed a 2: 1 complex with Spa33 in vitro. This complex oligomerised further, demonstrating for the first time that Spa33 has the propensity to form the ordered, high molecular weight assemblies that would be required for C-ring formation in S. flexneri.
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Etudes structurale et fonctionnelle de protéines impliquées dans la virulence chez S. pneumoniae et P. aeruginosa / Fonctional and structural analysis of proteins implicated in the pathogenesis of P. aeruginosa and S. pneumoniaeIzoré, Thierry 10 October 2011 (has links)
Cette thèse est composée de deux parties : Le première partie rend compte de l'étude structurale de la protéine RrgA. RrgA est associée au pilus du pathogène Streptococcus pneumoniae et participe aux premières étapes de colonisation chez l'hôte en se liant à plusieurs composés de la Matrice Extra Cellulaire. Nous avons résolu la structure de cette protéine à 1.9 Å par cristallographie aux rayons-X. RrgA possède une structure allongée formée de quatre domaines alignés d'origine eucaryote et procaryote. En effet, trois domaines ayant des similarités structurales avec les IgG et le domaine Cna-B semblent servir de piédestal pour orienter et présenter le domaine fonctionnel de type Intégrine. Nous avons confirmé la formation de deux ponts isopeptidiques stabilisateurs par spectrométrie de masse. De plus, le domaine intégrine possède deux insertions particulières dont la présence pourrait être impliquée dans la reconnaissance des divers substrats par RrgA. La deuxième partie de cette thèse est axée sur l'étude structurale du complexe ATPase et de ExsB, la pilotine présumée du système de sécrétion de type III chez Pseudomonas aeruginosa, bactérie opportuniste et jouant un rôle majeur dans l'infection des patients atteints de mucoviscidose. Pour la première fois, nous avons mis au point un protocole d'expression et de purification sous forme soluble de l'ATPase PscN en complexe avec une protéine partenaire, PscL. Des cristaux de ce complexe ont été obtenus au robot du PSB. Par ailleurs, nous avons confirmé l'expression de la lipoprotéine ExsB chez P. aeruginosa que nous avons localisée au sein de la membrane externe. De plus, nous avons résolu la structure de cette protéine qui présente un nouveau repliement et qui établie les bases structurales pour l'étude des pilotines pour tous les systèmes de sécrétion de type III de la famille Ysc. / This manuscript is made up of two parts The first part describes the structural study of RrgA from Streptococcus pneumoniae. This protein is a pilus-associated adhesin that is able to bind to several components of the Extra Cellular Matrix and thus, participates in the first steps of host colonization. We solved the structure of RrgA to 1.9 Å by X-Ray crystallography. We showed that RrgA folds into an elongated 4-domain structure, and these domains display both eukaryotic and prokaryotic origins. Actually, three out of the four domains are reminiscent of IgG and Cna-B structures and act like stalks to orient and display the large Integrin-like domain. We confirmed the presence of two isopeptide bonds by mass spectrometry and hypothesised that the two inserted arms in the integrin domain could explain the wide variety of substrates RrgA can bind. The second part of this manuscript focuses on the structural studies of the ATPase complex as well as ExsB, the putative pilotin of the type III secretion system from Pseudomonas aeruginosa. This bacterium is a major threat in hospital-acquired infections and the main pathogen found in cystic-fibrosis suffering patients. For the first time we were able to express and purify the ATPase PscN in complex with its partner PscL. Crystallization trials led to a very promising condition that is being refined. Moreover, we confirmed expression of the lipoprotein ExsB in P. aeruginosa that we localised in the outer membrane. To have a better understanding of this protein, we also solved its high-resolution structure that displays a novel fold and our study paves the way for coming studies concerning pilotins.
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Régulation de l'adaptation de la bactérie Pseudomonas aeruginosa à son hôte : implication des métabolites du tryptophane / Regulation of the adaptation of Pseudomonas aeruginosa to his host : involvement of tryptophan metabolites.Chaker, Hichem 07 March 2012 (has links)
P. aeruginosa est un pathogène opportuniste capable d'infecter un large spectre d'hôtes. Elle possède un vaste arsenal de facteurs de virulence. Le système de sécrétion de type III (SSTT) est un facteur de virulence majeur dont la régulation est complexe pour permettre une adaptation la plus précise possible de la bactérie au cours de l'infection. Nous nous sommes intéressés à déterminer le rôle potentiel de nouveaux acteurs de l'adaptation de P.aeruginosa au cours de l'infection. La porine OprF qui représente la protéine la plus abondante de la membrane externe de P. aeruginosa lui permettrait d'évaluer l'état d'activation du système immunitaire de son hôte afin d'adapter sa virulence. Chez P. aeruginosa, le tryptophane est le précurseur des kynurenines qui sont également produites par l'hôte à partir du tryptophane et qui, dans ce dernier contexte, sont des immunomodulateurs. Peu ou pas d'études ont été réalisées pour mettre en œuvre un éventuel rôle d'immunomodulation ou dans la virulence des kynurénines bactériennes. Dans un premier temps, nous nous sommes intéressés à un signal anciennement découvert au laboratoire et qui réprime l'expression du SSTT à haute densité bactérienne. Nous avons montré que ce signal exerce une régulation post-transcriptionnelle en plus d'une inhibition de la transcription des gènes du SSTT. Le métabolisme du tryptophane et de l'anthranilate semble être au cœur de ce processus de régulation. En inactivant des voies du catabolisme du tryptophane, nous avons montré que la production de ce signal dépend partiellement de la voie des kynurénines mais ne dépend pas ni des voies classiques du quorum sensing ni de l'opéron phnAB, impliqué dans la synthèse de l'anthranilate. Cependant, la voie des phénazines pourrait être impliquée dans la production de ce signal. Par CLHP couplée à la spectrométrie de masse, nous avons pu séparer des espèces moléculaires réprimant le SSTT et qui sont contenues dans ce signal, mais l'identification précise nécessite plus d'investigations. Dans un second temps, nous nous sommes intéressés aux kynurénines produites par la bactérie. Nous avons confirmé que P. aeruginosa produit des kynurénines et le gène kynA est le gène clé de la voie de synthèse de ces métabolites. En utilisant des fusions transcriptionnnelles, nous avons montré que le tryptophane et la kynurénine régulent positivement la production des kynurénines en agissant sur l'expression des gènes clés. D'autres parts, nous avons remarqué que la bactérie module l'activité de la voie métabolique des kynurénines issue du tryptophane en fonction de son état de croissance. Nous avons montré qu'au cours du dialogue interrègne bactérie/hôte, la voie des kynurénines de P. aeruginosa est stimulée par certains composants du système immunitaire. Grâce à un modèle d'infection pulmonaire aiguë, nous avons prouvé que les kynurénines produites par la bactérie sont importantes pour sa virulence. Selon notre hypothèse les kynurénines pourraient avoir une action sur la réponse immune, mais cela reste à déterminer. Dans un troisième temps, nous nous somme focalisés sur la porine OprF. Nous avons montré que la mutation ∆oprF est à l'origine d'une altération de la production mais vraisemblablement pas de la sécrétion des exotoxines du SSTT. Un ligand connu d'OprF, l'interféron gamma, module la voie des kynurénines. OprF pourrait donc avoir un rôle central dans les différents aspects de la régulation de la virulence. Nous avons donc produit des anticorps monoclonaux anti-OprF. Ces derniers se sont révélés capables de reconnaître spécifiquement la protéine OprF. Afin de vérifier l'efficacité de ces anticorps, des expériences de neutralisation de la bactérie in vitro puis in vivo seront réalisées. Mots clés : Pseudomonas aeruginosa, Système de Sécrétion de Type III, régulation, catabolisme du tryptophane, kynurénines, OprF. / P. aeruginosa is an opportunistic pathogen capable of infecting a wide host range. It possesses a large arsenal of virulence factors. The type III secretion system (TTSS) is a major virulence factor whose regulation is complex to allow the most accurate adaptation of the bacteria during infection. We were interested to determine the potential role of new actors in the adaptation of P. aeruginosa during infection. OprF represents the most abundant protein of the outer membrane of P. aeruginosa. This protein allows bacteria to assess the activation status of the host's immune system to adapt its virulence. In P. aeruginosa, tryptophan is the precursor of kynurenines that are also produced by the host from tryptophan and in the latter context, are immunomodulators. Little or no studies have been done to determine a possible role of bacterial kynurenines in immune modulation or virulence. Initially, we were interested in a signal previously discovered in the laboratory and which suppresses the expression of TTSS at high bacterial density. We have shown that this signal exerts a post-transcriptional regulation in addition to inhibition of TTSS genes transcription. The metabolism of tryptophan and anthranilate appears to be at the heart of this regulatory process. By inactivating pathways of tryptophan catabolism, we showed that production of this signal depends partly on the kynurenines pathway but does not depend neither classical ways of quorum sensing or phnAB operon involved in the synthesis of anthranilate. However, the phenazines pathway could be involved in the production of this signal. By HPLC coupled with mass spectrometry, we were able to separate molecular species suppressing the TTSS and which are contained in this signal, but accurate identification requires further investigation. In a second time, we were interested to kynurenines produced by the bacterium. We confirmed that P. aeruginosa produces kynurenines and KynA is the key gene in the synthesis of these metabolites. We showed that tryptophan and kynurenine upregulate the production of kynurenines by acting on the expression of key genes. Other shares, we found that the bacterium modulates the activity of the kynurenines pathway depending on its state of growth. We showed that during the dialogue bacteria / host, the pathway of kynurenines in P. aeruginosa is stimulated by certain immune system components. With an acute lung infection model, we proved that kynurenines produced by the bacterium are important to its virulence. We hypothesized that the kynurenines could have an effect on the immune response, but this remains to be determined. In a third time, we focused on the protein OprF. We showed that mutation ΔoprF is causing an alteration in production but probably not the secretion of TTSS exotoxins. One known ligand of OprF is the gamma interferon. It modulates the pathway of kynurenines. OprF could therefore have a central role in various aspects of the regulation of virulence. So, we produced monoclonal anti-OprF which recognizes specifically the protein OprF. To verify the effectiveness of these antibodies, neutralization experiments of the bacteria in vitro and in vivo will be realized.
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Caracterização estrutural da proteína hipotética XACb0033 da bactéria Xanthomonas axonopodis pv. citri / Structural characterization of an hypothetical protein XACb0033 from Xanthomonas axonopodis pv. citri (bacterium)Borin, Paula Fernanda Lacarini 16 August 2018 (has links)
Orientador: Ljubica Tasic / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-16T13:55:17Z (GMT). No. of bitstreams: 1
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Previous issue date: 2010 / Resumo: A Xanthomonas axonopodis pv. citri (Xac) é uma bactéria Gram-negativa que parasita plantas cítricas e é responsável pela doença conhecida como cancro cítrico, que apresenta grande importância econômica em todo mundo. Acredita-se que a infecção da célula hospedeira ocorre com atuação dos sistemas de secreção, onde fatores macromoleculares de virulência, normalmente proteínas ou complexos de ácidos nucléicos com proteínas, são excretados para o citosol da célula no caso dos sistemas do tipo III e IV, onde irão interferir no processo celular do hospedeiro. O alvo do estudo é a proteína hipotética XACb0033, codificada pelo locus virB do plasmídio pXac64. Ela foi identificada como possível chaperona secretória do sistema de secreção tipo IV, por apresentar diversas características destas proteínas, como baixo peso molecular, pI ácido e propensão a formação de dímeros, entre outras. A XACb0033 foi clonada no vetor de expressão pET23a(+) e expressa na bactéria Escherichia coli utilizando técnicas de biologia molecular de clonagem e expressão. Os resultados da expressão foram satisfatórios, obtendo-se a proteína em quantidade suficiente para sua purificação seguida pela caracterização estrutural. A XACb0033 foi analisada por Espectrometria de Massas (MALDI-Tof MS), Dicroísmo Circular (CD), fluorescência de emissão estática e dinâmica, Ressonância Magnética Nuclear de Hidrogênio-1 (RMN de H) e Espalhamento de raios-X a baixo ângulo (SAXS). Todos os dados indicam que a XACb0033 apresenta estrutura enovelada, não interage com os nucleotídeos (ATP e ADP) e tende em agir em forma dimerica seguindo o modelo de uma chaperona secretória, e, por fim, a estrutura do seu envelope molecular foi obtida. / Abstract: Xanthomonas axonopodis pv. citri (Xac) is a Gram-negative bacterium that parasites citric plants all over the world and is responsible for causing the citrus canker with significant economic importance. It is believed that infection of the host cell occurs with activity of Xac¿s secretion systems, where macromolecular virulence factors, usually proteins or nucleic acid complexes with proteins, are excreted into the cytosol of the host cells as in the case of type III and IV systems, where they will interfere with the key cell processes. The aim of our study was structural characterization of the XACb0033, Xac¿s hypothetical protein, encoded by the locus virB of pXac64 plasmid. This protein was identified as a possible type IV secretion system chaperona because it presents many features of these proteins, such as low molecular weight, acidic pI, and propensity to form dimers, among others. The XACb0033 was cloned at expression vector pET23a (+) and expressed in Escherichia coli using molecular biology techniques for cloning and expression. The expression results were satisfactory, obtaining sufficient protein for its purification followed by structural characterization. The XACb0033 was analyzed by Mass Spectrometry (MALDI-Tof MS), Circular Dichroism (CD), static and dynamic Fluorescence, Nuclear Magnetic Resonance (H NMR) and by Small Angle X-ray Scattering (SAXS). All collected data indicated that XACb0033 has folded structure, does not interact with nucleotides (ATP and ADP) and tends to act in dimeric form, following a model of a secretory chaperona, and, at last but not at least, its molecular envelope structure has been obtained. / Mestrado / Quimica Organica / Mestre em Química
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O papel da flagelina e do sistema de secreção de Escherichia coli enteroinvasora na resposta imune inata dos macrófagos / The role of flagellin and secretion system of enteroinvasive Escherichia coli in the immune response innate macrophagesLucas Gonçalves Ferreira 11 December 2012 (has links)
Escherichia coli enteroinvasora (EIEC) é um dos agentes etiológicos da disenteria bacilar. Seu processo fisiopatológico é desencadeado pela expressão de fatores de virulência, que proporcionam sua invasão e sobrevivência nas células do hospedeiro, ativando o sistema imune inato e adaptativo da mucosa intestinal. Trabalhos recentes têm salientado a importância do sistema de secreção e da flagelina bacteriana como agonista de receptores da imuninade inata dos macrófagos, em especial alguns dos receptores do tipo NLR. Uma vez que esta espécie de E. coli também é capaz de expressar flagelina e fazer a montagem completa do flagelo e do sistema de secreção do tipo III, a nossa proposta foi avaliar o papel da flagelina e do sistema de secreção de EIEC na resposta imune dos macrófagos murinos. Para isso, utilizamos três cepas de EIEC: a cepa selvagem; a cepa mutante no gene responsável pela síntese da flagelina; e a cepa sem o plasmídio de virulência plnv, deficiente no sistema de secreção, para a infecção de macrófagos peritoniais de camundongos C57BI/6, caspase-1-/-, IPAF-/- e ASC-/-. Neste estudo foi possível observar que o escape bacteriano e a morte dos macrófagos infectados por EIEC, assim como a ativação da caspase-1 e posterior secreção de IL-1β é independente da flagelina bacteriana, mas dependente do sistema de secreção, além disso, a ativação da caspase-1 de macrófagos infectados por EIEC é dependente do receptor IPAF e parcialmente da proteína adaptadora ASC. Assim, no nosso modelo, a ativação da caspase-1 dos macrófagos infectados por EIEC parece estar envolvida com o processamento e secreção de IL-1β e, possivelmente na secreção de IL-18, mas não na morte celular. No modelo de infecção in vivo, o sistema de secreção bacteriano foi importante para a sobrevivência bacteriana no hospedeiro, assim como para a indução de uma resposta inflamatória no local da infecção. Ainda, a caspase-1 parece ter um papel importante para o controle da infecção in vivo por EIEC, podendo assim contribuir para uma resposta imune protetora do hospedeiro. / Enteroinvasive Escherichia coli (EIEC) is one of the etiologic agents responsible for bacillary dysentery. The pathophysiological process induced by this bacteria is triggered by the expression of virulence factors that provide the invasion and survival in host cells, resulting in activation of innate and adaptive immune system present on intestinal mucosa. Recent studies have emphasized the importance of the secretion system and bacterial flagellin as agonist of innate immune receptors present in macrophage, especially NLR (Nod like receptors). Then, our proposal was evaluate the role of flagellin (f1iC) and secretion system of EIEC in the induction of immune response of murine macrophages using the EIEC strains wild type (WT), mutant flagellin gene (f1iC), and a strain deficient in secretion system (DSS) for infection of peritoneal macrophages of C57Bl/6, caspase-1-/-, IPAF-/- and ASC-/-- mice. In this study we observed that the bacterial escape and death of infected macrophages with EIEC, the caspase-1 activation and subsequent IL-1β secretion is independent of bacterial flagellin, but dependent of secretion system, moreover, the caspase-1 activation in infected macrophages is IPAF-dependent and partially dependent of the adapter protein ASC. Thus, in our model, the caspase-1 activation in EIEC infected macrophages seems to be involved with the processing and secretion of IL-1β and possibly with the secretion of IL-18, but not involved with cell death. In the infection model in vivo, bacterial secretion system was important for bacterial survival in the host, as well as for the inflammatory response induction at the infection site. In addition, caspase-1 seems to have an important role to the control of in vivo infection by EIEC and can contribute to a protective immune response of the host.
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Type VI secretion system effectorsLe, Thi Thu Hang 22 February 2017 (has links)
Mon travail a porté sur la caractérisation des effecteurs toxiques et protéines d’immunité du T6SS Sci-1 d’Escherichia coli Entero-agrégatif, éléments de la lutte inter-bactérienne. Nous avons identifié en outre Tle1, un effecteur de toxine codé par ce groupe et montré que Tle1 possède des activités de phospholipase A1 et A2 requises pour détruire la cellule proie dans la compétition interbactérienne. L'auto-protection de la cellule attaquante est assurée par une lipoprotéine de membrane externe, Tli1, qui lie Tle1 dans un rapport stoechiométrique 1: 1 avec une affinité nanomolaire et inhibe son activité phospholipase. Il a été prédit que la protéine 435 provenant à partir d'un groupe de gènes T6SS1 de l'agent pathogène AIEC LF82 est une phospholipase de la famille d'effecteurs Tle3 avec une activité PLA1. Sa toxicité peut être neutralisée par la protéine d'immunité cognate 434 qui est un Tli3 putatif, en formant le complexe de protéine Tle3 - Tli3. Les deux protéines séparées et leur complexe ont ensuite été appelées protéines complexes Tle3AIEC, Tli3AIEC et Tle3AIEC - Tli3AIEC, respectivement. Afin d'étudier plus en détail le mécanisme de Tle3-AIEC et de Tli3-AIEC, nous avons réalisé l'expression, la purification, la caractérisation, la cristallisation des deux protéines et des études cristallographiques de rayons X préliminaires du complexe Tle3-AIEC/Tli3-AIEC afin de comprendre comment la protéine Tle3-AIEC reconnaît et se lie à son effecteur apparenté Tli3-AIEC et inhibe son activité. Les données préliminaires de diffraction des rayons X ont été recueillies à partir de cristaux Tle3AIEC-SeMet/Tli3AIEC à une résolution de 3,8 Å. / Here, we analyzed the Entero-aggregative Escherichia coli Sci-1 T6SS toxin effectors. We identified Tle1, a toxin effector encoded by this cluster and show that Tle1 possesses phospholipase A1 and A2 activities required for the inter-bacterial competition. Self-protection of the attacker cell is secured by an outer membrane lipoprotein, Tli1, which binds Tle1 in a 1:1 stoichiometric ratio with nanomolar affinity, and inhibits its phospholipase activity.The protein 435 from the pathogen AIEC LF82 has been predicted to be a phospholipase of the Tle3 effector family with PLA1 activity from a T6SS1 gene cluster. Its toxicity can be neutralized by the cognate immunity protein 434 that is a putative Tli3, by forming Tle3 - Tli3 protein complex. The two separated proteins and their complex were then called Tle3AIEC, Tli3AIEC and Tle3AIEC - Tli3AIEC complex proteins, respectively. In order to further investigate the related mechanism of Tle3AIEC and Tli3AIEC, we performed expression, purification, characterization, crystallization of the two proteins and preliminary X-ray crystallographic studies of the Tle3AIEC - Tli3AIEC complex in order to understand how Tle3AIEC protein recognizes and binds to its cognate Tli3AIEC effector and inhibits its activity. X-ray diffraction data were collected from selenomethionine-derivatize Tle3AIEC SeMet - Tli3AIEC crystals to a resolution of 3.8 Å.
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Produkce a sekrece faktorů virulence Bordetella pertussis / Production and secretion of virulence factors in Bordetella pertussisDržmíšek, Jakub January 2015 (has links)
Bordetella pertussis is a strictly human pathogen and causative agent of infectious respiratory disease called whooping cough. In order to establish successful infection and colonization of the host, B. pertussis uses a broad spectrum of virulence factors such as adhesins (filamentous hemagglutinin, pertactin, and fimbriae) and toxins (adenylate cyclase and pertussis toxins). In addition, the type 3 secretion system (T3SS) was also found in the genus Bordetella. In connection to our previous characterisation of B. pertussis strain lacking the gene encoding RNA chaperone Hfq (Δhfq), which proved that Hfq is required for T3SS functionality, the recombinant T3SS proteins BopB, BopD, BopC and BopN were purified to homogeneity. Next, the specific antibodies were obtained using purified recombinant proteins in order to study the production of the T3SS components in B. pertussis. Using refined anti- BopC antibodies it was for the first time shown that laboratory-adapted B. pertussis strain secretes BopC protein into medium. The recombinant translocators BopB and BopD were also used to examine their pore-forming activity using planar black lipid membranes. Based on the characterisation of hfq deletion mutant, having impaired production of membrane proteins when compared to the wild type, mass spectrometry...
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Étude de IglG, une protéine à domaine PAAR-like du système de sécrétion de type VI de Francisella tularensis / Study of the IglG, a PAAR-like protein of Francisella tularensisRigard, Mélanie 13 April 2016 (has links)
Francisella tularensis est une bactérie responsable de la tularémie. Sa virulence est liée à sa capacité à se multiplier dans le cytoplasme des macrophages. F. novicida, proche de F. tularensis, est utilisée comme modèle d’étude. L'îlot de pathogénicité de Francisella (FPI), un locus crucial pour la virulence de Francisella coderait pour un système de sécrétion de type VI (SST6). Ce SST6 est très distinct des autres SST6 décrits et son fonctionnement est très mal connu. En particulier, la protéine VgrG de Francisella est très différente des protéines VgrG des types VI canoniques. Les protéines VgrG canoniques interagissent avec des protéines à motifs PAAR. Celles-ci sont situées à la pointe des SST6 et fixent un atome de zinc grâce à une cystéine et 3 histidines pour stabiliser la protéine lors de la traversée de la membrane de la cellule cible. Les effecteurs du SST6 peuvent être sécrétés via une interaction avec des extensions N-terminale ou C-terminale de VgrG ou des protéines PAAR (rôle cargo de ces extensions). Par une approche bioinformatique, nous avons identifié une protéine (FTN_1314 : IglG) impliquée dans la virulence de F. novicida. Mon projet de thèse porte sur la caractérisation moléculaire de cette protéine dans la virulence de F. novicida. IglG contient, en C-terminal, un domaine de fonction inconnue (DUF 4280) retrouvé chez plus de 250 espèces bactériennes. L’analyse tridimentionnelle de ce domaine suggère que cette protéine adopte un repliement proche de celui des protéines à motif PAAR et contient 4 cystéines. Nous avons montré que la mutation ponctuelle d’une cystéine d’IglG abolit la virulence de F. novicida, et ceci pour les 4 cystéines indépendamment. De plus, elles sont capables de lier un atome de fer et sont nécessaires pour la sécrétion d’IglG et d’IglC (homologue de Hcp). IglG possède en plus de ce domaine PAAR-like, une extension N-terminale qui pourrait interagir avec des effecteurs de la bactérie (rôle de domaine cargo) ou agir directement en tant qu'effecteur dans la cellule hôte. Nous avons distingué 4 régions dans le domaine N-terminal et nous avons montré que la délétion de la plus petite région abolit la virulence de F. novicida. Ce domaine N-terminal est spécifique de IglG, il n’est pas retrouvé dans d’autres protéines à domaine PAAR. Il n’est pas requis pour la sécrétion de IglG, mais il est requis pour l’interaction avec IglF, une autre protéine du FPI, qui pourrait jouer un rôle d’effecteur du SST6. Ce projet permet une meilleure compréhension du SST6 de F. novicida et des mécanismes de réplication de cette bactérie dans la cellule hôte / The virulence of Francisella tularensis, the etiological agent of tularemia, relies on an atypical type VI secretion system (T6SS) encoded by a genomic island termed the Francisella Pathogenicity Island (FPI). While the importance of the FPI in F. tularensis virulence is clearly established, the precise role of most of the FPI-encoded proteins remains to be deciphered. In this study, using highly virulent F. tularensis strains and the closely related species F. novicida, IglG was characterized as a protein featuring a unique a-helical N-terminal extension and a domain of unknown function (DUF4280), present in more than 250 bacterial species. Three dimensional modeling of IglG and of the DUF4280 consensus protein sequence suggest that these proteins adopt a PAAR-like fold, indicating they could cap the T6SS in a similar way as the recently described PAAR proteins. The newly identified PAARlike motif is characterized by four conserved cysteine residues, also present in IglG, which may bind a metal atom. We demonstrate that IglG binds iron and that each individual cysteine is required for T6SS-dependent secretion of IglG and of the Hcp homologue, IglC and for the F. novicida intracellular life cycle. In contrast, the Francisella-specific N-terminal a-helical extension is not required for IglG secretion, but is critical for F. novicida virulence and for the interaction of IglG with another FPIencoded protein, IglF. Altogether, our data suggest that IglG is a PAAR-like protein acting as a bimodal protein that connects the tip of the Francisella T6SS with a putative T6SS effector, IglF
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Biogenesis and membrane anchoring of the Type VI secretion contractile tailZoued, Abdelrahim 07 December 2015 (has links)
Récemment, le système de sécrétion de type VI (SST6) a été identifié comme un nouvel acteur clé dans la compétition inter-bactérienne parmi le large arsenal dont dispose les bactéries. L’une des particularités du SST6 est de cibler à la fois des cellules eucaryotes et procaryotes. Le T6SS est un complexe protéique formé par l’assemblage de deux ‘sous-complexes’. Le premier sert à l’ancrage de la machinerie au sein de l’enveloppe bactérienne et le second agit comme une arbalète moléculaire. Le mécanisme d’action du SST6 est très similaire à celui d’autres machineries contractiles telles que celui des bactériophages : la contraction d’un fourreau propulse une flèche, composée d’un tube avec une aiguille à son extrémité, directement dans la cellule cible afin de délivrer les différentes toxines. Mon projet de thèse consiste à comprendre quelles sont la structure et la biogénèse des deux différents complexes et de comprendre comment ils sont assemblés. Nous utilisons comme modèle la bactérie pathogène à Gram négatif Escherichia coli entéroagrégative. J’ai pu démontrer que le complexe membranaire est assemblé en premier, avec l’adressage de la lipoprotéine de membrane externe TssJ, puis le recrutement séquentiel de TssM et TssL, deux protéines de membrane interne. Le complexe membranaire recrute ensuite une plateforme d’assemblage, appelée ‘baseplate’. Nous avons identifié et caractérisé les composants de cette ‘baseplate’ qui sert de plateforme d’assemblage pour le recrutement du reste de la machinerie (fourreau et flèche). Enfin, nous avons identifié et déterminé le rôle de la protéine TssA, une protéine qui coordonne la polymérisation du fourreau et de la flèche. / Among the broad weaponry of bacteria, the recently identified type VI secretion system (T6SS) emerges as one of the key player in bacterial competition. T6SS is a versatile machinery that targets both eukaryotic and prokaryotic cells. This molecular weapon assembles two evolutionarily different sub-assemblies. One complex anchors the machinery to the cell envelope while the second acts as a molecular crossbow. The mechanism of action of the T6SS is similar to other known contractile machineries such as bacteriophages: the contraction of a sheath propels an arrow, constituted of a tail tube capped by a cell-puncturing device, directly into the prey cell to deliver effector toxins. My Ph.D project was to provide mechanistic details on the structure and biogenesis of the two T6SS sub-complexes and to understand how they are connected, using entero-aggregative Escherichia coli as model bacterium. I have demonstrated that the membrane complex is assembled first and starts with the positioning of the outer membrane TssJ lipoprotein and proceeds inward, from the outer to the inner membrane, through the sequential recruitment of the TssM and TssL subunits. After assembly, the membrane complex recruits an assembly platform called the baseplate. We identified and characterized the components of this baseplate, which serves as assembly platform for the tail. We further demonstrated that the functional and physical interaction between the T6SS membrane complex and the baseplate is mediated by multiple contacts. Finally, we identified and deciphered the role of TssA, a protein that coordinates the polymerizations of the tail tube and sheath.
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