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Structural studies of the inner-membrane platform of the bacterial type II secretion systemZhang, Hui January 2018 (has links)
The type II secretion system (T2SS) is widespread in Gram-negative bacteria that cause disease in animals and plants. In human and animal pathogens toxins are secreted (e.g. cholera toxin) and in plant pathogens lytic enzymes that breakdown the plant cell wall are exported in to the extracellular milieu (e.g. pectate lyase). Structurally the T2SS comprises at least 11 core proteins that form three major subassemblies spanning the inner-membrane, periplasmic space and outer-membrane: (i) the inner-membrane platform and associated cytoplasmic ATPase (E); (ii) the pseudopilus, which consists of five pseudopilins, G to K; and (iii) a large, pore-forming outer-membrane complex secretin D. The inner-membrane platform comprises three single transmembrane helix proteins, and one three transmembrane helix protein, OutF. The evidence from cryo-electron microscopy on the related type IVa pilus machine (T4PS) places the protein corresponding to OutF at the centre of this platform. This platform is responsible for assembling the pilus and for communicating between the periplasm and the cytoplasmic ATPase. To date, no high-resolution structure of a full-length OutF/PilC family protein is available. A low-resolution electron microscopy reconstruction of isolated PilG (PilC ortholog from Neisseria meningitides T4PS) showed a tetrameric two lobed structure. Here I report the results of studying the structure of the inner-membrane protein OutF from Dickeya dadantii and the complete inner-membrane platform comprising 9 proteins: OutEFGHIJKLM. This work involved cloning the corresponding operon, purifying the proteins, and using crystallography and electron microscopy. Key results reported here are the crystal structure of the first cytoplasmic domain of Dickeya dadantii, OutF65-172 and a preliminary three-dimensional model of the Dickeya dadantii inner-membrane platform. This model, and higher-resolution models to come, will provide valuable information about the oligomeric state, and arrangement of the inner-membrane proteins. These studies will help us to understand how the type II secretion system works.
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A Tale of Two Pathways: Secretin Assembly in Vibrio cholerae2014 September 1900 (has links)
The Type 2 Secretion System (T2SS) is responsible for the transport of toxins and enzymes across the outer membrane of many Gram-negative bacteria. A crucial component of the T2SS is a large pore, composed of a multimer of EpsD, named the secretin. This pore inserts in the outer membrane with the assistance of a pilotin (EpsS) or assembly factors (EpsAB), both of which are present within the genome of Vibrio cholerae. The goal of this study was to determine whether or not both assembly mechanisms operate on the same secretin assembly in V. cholerae.
Protease deficient mutants generated from an insertion transposon library in V. cholerae epsAB were analyzed. The transposon was found to disrupt the operon encoding VC1702 and epsS.
Mutant strains of V. cholerae were constructed or obtained that are deficient in epsA, epsB, epsC, and epsS. Double mutants were constructed that were deficient in epsA and epsS or epsB and epsS. These mutants were tested for assembly of the secretin and secretion of lipase, protease, and cholera toxin. The epsA and epsB mutants have slightly reduced levels of secretion and secretin assembly, while the levels in the pilotin mutant are drastically reduced. The double mutants had little to no assembly, and secretion was reduced to the levels of the control mutant epsC.
In an attempt to restore function epsAB was over-expressed in all strains. It successfully complemented the epsA and epsB mutants, and restored levels of secretion to epsS levels in the double mutant, epsAS.
In a similar manner to epsAB complementation, epsS was over-expressed. It was found to require the preceding gene VC1702 to complement. The operon, encoding both epsS and VC1702, could complement both epsA and epsS mutations and over-expression increased secretin assembly and secretion to levels greater than wild-type levels.
Lastly, a phylogenomic analysis demonstrates that the EpsAB protein complex is found in most orders of the gamma proteobacteria and is ancestral. The pilotins appear to be a late acquisition as they are only found in the family Enterobacteriales.
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Structural studies of type IX and type II secretion systems / Etudes structurales des systèmes de sécrétion de type IX et de type IITrinh, Thi Trang Nhung 21 March 2019 (has links)
Les protéines synthétisées et sécrétées par les bactéries jouent des rôles importants pour leur survie. Les bactéries à Gram négatif ont développé des voies de sécrétion en tant qu'armes principales pour transporter des facteurs de virulence dans l'environnement extracellulaire ou dans des cellules hôte. L'un de ces systèmes, le T9SS a été principalement étudié chez l'agent pathogène oral Porphyromonas gingivalis et chez la bactérie mobile Flavobacterium johnsoniae. Un autre complexe, le T2SS est le principal déterminant de la virulence de la bactérie Pseudomonas aeruginosa, un agent pathogène de la fibrose kystique. Dans le cadre de ma thèse, j'ai résolu la structure atomique de plusieurs composants centraux du T9SS et du T2SS. Concernant le projet T9SS, j'ai essayé de cristalliser le domaine cytoplasmique de GldL de F. johnsoniae. La co-cristallisation de GldL avec des Nbs a été réalisée sans succès. Néanmoins, les structures cristallines de deux nanobody contre GldL ont été résolues par remplacement moléculaire. De plus, j'ai également travaillé sur la protéine PG1058 de P. gingivalis. J'ai résolu sa structure par diffraction anomale à la longueur d’onde du selenium. Concernant le projet T2SS, je me suis concentré sur la partie N-terminale de XcpQ, une sous-unité de la sécrétine. J'ai résolu la structure cristalline de XcpQN012 seul et en complexe avec le nanobody vhh04 à une résolution de 2,98 Å et de 2,9 Å, respectivement. Enfin, j'ai participé à la détermination structurale de TssK, un composant de plaque de base du système de T6SS et déterminer la structure cristalline d'un nanobody contre le domaine périplasmique de PorM. / Proteins synthesized and secreted by bacteria serve many important roles in their survival. In particular, Gram-negative bacteria have evolved secretion pathways as the main weapons for transporting virulence factors into target cells or into the extracellular environment. One of these systems, the type IX secretion system (T9SS) or the Por secretion system, has been studied mainly in the oral pathogen Porphyromonas gingivalis and the gliding bacterium Flavobacterium johnsoniae. Another complex, the type II secretion system (T2SS) is the main determinant of the virulence of Pseudomonas aeruginosa, a cystic fibrosis pathogen. In my PhD thesis, I solved the atomic structure of several core components of both T9SS and T2SS.For the T9SS project, I tried to crystallize the cytoplasmic domain of GldL from F. johnsoniae. The co-crystallization of GldL with Nbs was unsuccessfull. The crystal structures of two nanobodies against GldL were solved by molecular replacement. I also worked on the PG1058 protein of P. gingivalis. I obtained crystals of the selenomethionine-derivatized PG1058 OmpA_C-like domain that diffracted up to 1.55 Å, and solved its structure by single-wavelength anomalous diffraction. For the T2SS project, I focused on the N-terminal part of XcpQ, a subunit of the secretin. I solved the crystal structure of XcpQN012 alone and in complex with nanobody vhh04 at a resolution of 2.98 Å and 2.9 Å, respectively. In addition, I also took part in the structural determination of the base plate component TssK of the T6SS and determined the crystal structure of one nanobody (vhh19) against the periplasmic domain of PorM.
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