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. pneumoniae

Izoré, Thierry

10 October 2011

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.

Cristallographie aux rayons x

Système de sécrétion de type III

Pilus

Pilotine

X-Ray scattering

Type III secretion system

Pilus

Pilotin

570

Le Pilus Conjugatif de Pseudomonas aeruginosa : Caractérisation des éléments de membrane externe / The conjugative pilus of Pseudomonas aeruginosa : Caracterisation of outer membrane components

Spagnolo, Jennifer

26 April 2013

La souche de P. aeruginosa PA14 est un isolat humain hautement virulent. PA14 possède deux îlots de pathogénicité. L'îlot de pathogénicité PAPI-1 de 108 kb est un élément intégratif et conjugatif (ICE), capable de s'auto-transférer à des souches de Pseudomonas par un mécanisme de conjugaison. Le mécanisme de transfert fait intervenir un pilus de Type IVb, encodé dans l'îlot PAPI-1. Mon travail de doctorat a eu pour but de caractériser à un niveau moléculaire le pilus de Type IVb (Pil-PAPI-1). J'ai d'abord, inséré un promoteur constitutif en place du promoteur endogène pour activer l'expression du locus pil2. J'ai démontré que 9 des 10 gènes sont requis pour le transfert d'ADN. J'ai ensuite initié la caractérisation de composants formant la machine de conjugaison. J'ai caractérisé le produit des gènes pilL2 et pilN2. J'ai démontré que PilL2 est une protéine de membrane externe (ME) et exposée dans le périplasme. Cette protéine est essentielle pour la fonctionnalité (transfert d'ADN) de la machinerie de conjugaison. Malgré ses caractéristiques prédites de lipoprotéine, aucune des mutations réalisées n'a pu modifier la localisation de ME de PilL2. J'ai aussi démontré que PilL2 forme un sous complexe de ME avec PilN2, la sécrétine du système. PilN2 forme des multimères stable, et présente les caractéristiques d'une liposécretine, capable d'auto-insertion et d'auto-multimérisation dans la ME. J'ai démontré que le N-ter de PilN2 mature est critique pour la formation d'un pore fonctionnel, mais n'est pas impliqué dans l'interaction avec PilL2. Ces résultats suggèrent que PilL2 et PilN2 forment un nouveau type de sous complexe de ME dans la famille des TFPb. / The P. aeruginosa PA14 strain is a highly virulent human isolate. PA14 possesses two pathogenicity islands. The 108-kb pathogenicity island PAPI-1 is an integrative and conjugative element (ICE), capable of self-transferring to any recipient Pseudomonas strain, by a conjugative mechanism. The transfer mechanism is mediated by a Type IVb pilus, encoded within the PAPI-1 Island. My PhD work aimed to characterize this Type IVb pilus (Pil-PAPI-1) at a molecular level. The pil2 locus is poorly expressed under laboratory condition. I, first, introduced a constitutive promoter to turn on expression of the pil2 locus. I demonstrated that 9 of the 10 genes are required for DNA transfer. Then, I initiated the characterization of components forming the conjugation machinery. I characterized the products of pilL2 and pilN2 genes. I demonstrated that PilL2 is an OM protein and protruding in the periplasm. This protein is essential for the functionality (DNA transfer) of the conjugative TFPb machinery. Despite its predicted lipoprotein-hallmarks, none of the mutations engineered were able to abrogate the OM-localization of PilL2. We also demonstrated that PilL2 forms an OM sub-complex with PilN2, the secretin of the system. We provide evidence that PilN2 forms stable multimers, which presents the features of a liposecretin, capable of self-insertion and self-multimerization in the OM. We demonstrated that while the N-terminus of the mature PilN2 is required for the formation of a functional pore, it is not involved in interaction with PilL2. These results suggest that PilL2 and PilN2 could form new type of OM sub-complex in the TFPb family.

Pseudomonas aeruginosa

ICE

Pilus de Type IVb

Sécrétine

Lipoprotéine

Pseudomonas aeruginosa

ICE

Type IVb Pilus

Secretin

Lipoprotein

579

Régulation du transfert de l' îlot de pathogénicité PAPI-1 chez Pseudomonas aeruginosa PA14 / Regulation of the transfer of the PAPI-1 pathogenicity island in Pseudomonas aeruginosa PA14

Roux, Nicolas

20 February 2015

Les infections à Pseudomonas aeruginosa sont un problème de santé publique important et peu de solutions thérapeutiques sont disponibles face à des souches isolées multi-résistantes. Le séquençage de souches de P. aeruginosa a montré qu'en plus du génome cœur, il existe de nombreux gènes accessoires. La souche PA14 est un isolat clinique hautement virulent, de part la présence de deux îlots de pathogénicité, PAPI-1 et PAPI-2, contribuant de manière individuelle et synergique à la virulence. L'îlot PAPI-1, de 108 kb, est un élément intégratif et conjugatif (ICE), capable de s'auto-transférer à des souches de Pseudomonas par un mécanisme de conjugaison. Le mécanisme de transfert fait intervenir un pilus de type IVb encodé dans l'îlot PAPI-1.Mon travail de thèse a eu pour objectif d'identifier les régulateurs de ce locus pilPAPI-1. Ce travail a montré que ce locus est faiblement exprimé mais qu'il peut être induit par l'ajout d'acide caprique. Par une approche de mutagénèse aléatoire, j'ai démontré qu'il existe au moins deux gènes de fonctions inconnues présents dans PAPI-1 nécessaires à l'activation du locus et au transfert de l'îlot : RL103, qui coderait pour un régulateur transcriptionnel de type Ribbon-Helix-Helix (RHH) et RL102, qui coderait pour une protéine de partitionnement chromosomique. Par une approche transcriptomique, j'ai démontré que ces deux régulateurs sont aussi impliqués dans l'activation de l'expression de plus de 35% des gènes de PAPI-1. Dans leur ensemble, ces résultats ont mis en évidence que RL103 et RL102 sont deux activateurs du transfert de PAPI-1 et ont montré le premier exemple de régulateur de type RHH impliqué dans le transfert d'un ICE. / P. aeruginosa infections have become a serious threat to public health and are very difficult to treat due to the increasingly emergence of strains resistant to all known antibiotics. Sequencing of P. aeruginosa strains showed, that in addition to a conserved core genome, there are variable accessory genes. The PA14 strain is a highly virulent clinical and this is mainly due to two pathogenicity islands, PAPI-1 and PAPI-2, that contribute individually and synergistically to the virulence. The 108 kb PAPI-1 pathogenicity island is an integrative and conjugative element (ICE), capable of self-transferring to any recipient Pseudomonas strain by a conjugative mechanism. The transfer mechanism is mediated by a type IVb pilus, encoded within the PAPI-1 island. My PhD work was aimed to identifying the regulators of this pilPAPI-1 locus. This work showed that this locus is weakly expressed but may be induced by the addition of capric acid. Using a random mutagenesis approach, i have shown that there are at least two genes of unknown function (present in PAPI-1) necessary for activation of the locus pilPAPI-1 and the transfer of the island : RL103, which would encode a Ribbon Helix Helix-like transcriptional regulator and RL102, which would encode a partitioning chromosome protein. Using a transcriptomic approach with microarrays, I demonstrated that these two regulators are also involved in the activation of the expression of more than 35% of PAPI-1 genes. Taken together, these results show that Cpr and RL102 are two activators of the PAPI-1 transfer of PA14 and show the first example of a Ribbon-Helix-Helix transcriptional regulator involved in the transfer of an ICE.

Pseudomonas aeruginosa

Pilus

Transfert

Régulation

Pathogénicité

Virulence

Conjugaison

Pseudomonas aeruginosa

Pilus

Transfer

Regulation

Pathogenicity

Virulence

Conjugation

579

Étude des interactions entre streptococcus suis sérotype 2 et des cellules endothéliales porcines

Vanier, Ghyslaine

January 2008

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal.

Adhésion

Adhesion

Cellules endothéliales

Endothelial cells

Cytotoxicité

Cytotoxicity

Induction de cytokines

Induction of cytokines

Invasion

Invasion

Méningite

Meningitis

Pilus

Pilus

Sortase

Sortase

Streptococcus suis

Streptococcus suis

Suilysine

Suilysin

Estudo funcional e estrutural dos reguladores da biossíntese do Pilus Tipo IV de Xanthomonas citri subsp. citri / Functional and structural studies of the regulators of Type IV Pilus biogenesis in Xanthomonas citri subsp. citri

Cornejo, Edgar Enrique Llontop

13 June 2019

O pilus tipo IV (T4P) são finos e flexíveis filamentos encontrados na superfície de uma ampla gama de bactérias Gram-negativas, Gram-positivas e archaea. O T4P desempenha um rol crucial no estilo de vida bacteriano ao estar envolvido em uma variedade de funções incluindo motilidade, aderência, formação de biofilme, patogenicidade, transformação natural e na infecção por fagos. Várias das proteínas requeridas para a biossíntese e regulação do T4P se estendem através do periplasma conectado a membrana interna e externa. O T4P são estruturas dinâmicas que sofrem ciclos de extensão e retração energizados por duas ATPases associadas com a membrana interna bacteriana. Durante a extensão, PilB, a ATPase de biossíntese do T4P, estimula a polimerização do pilus a partir de monômeros de pilinas localizados na membrana interna, através de um mecanismo ainda desconhecido. Duas proteínas, FimX e PilZ estão envolvidas na regulação da biossíntese do T4P via interações com PilB e nocautes de esses genes acabam com a biogênese e função do T4P. Neste trabalho, nós determinamos a estrutura cristalográfica do complexo binário formado pelo domínio N-terminal de PilB (PilBNt, resíduos 12-163) e a PilZ com uma resolução de 1.7 Å. As interações entre PilB e PilZ envolve uma superfície hidrofóbica formada por aminoácidos altamente conservados na família não canônica de domínios PilZ. Mutações ou deleções de alguns destes resíduos em PilZ enfraquecem a interação PilB-PilZ e afeta a função do T4P. Nós também observamos que esta interação induz mudanças conformacionais no domínio PilBNt, revelando a possibilidade de um rearranjo estrutural funcionalmente relevante da região Nterminal de PilB permitindo a sua interação com PilM, conectando a ATPase PilB como a maquinaria do T4P. Nós mostramos que PilB, PilZ e FimX podem formar um complexo ternário estável com uma massa molar aparente de ~600 kDa, sugerindo uma estequiometria de 6PilB:6PilZ:2FimX. Também observamos que FimX incrementa a atividade ATPase do complexo PilB-PilZ. O c-di-GMP e o ATPγS (um análogo não hidrolisável do ATP) induz mudanças conformacionais em FimX e no complexo PilB-PilZ, respectivamente, e estabiliza o complexo ternário PilB-PilZ-FimX. Além disso, PilB, PilZ e FimX localizam em um dos polos da célula (polo líder) em células de X. citri e a localização polar dirige a orientação da motilidade twitching. Finalmente, o T4P é necessário para a exitosa infecção de X. citri pelo fago ΦXacm4-11. Nossos resultados sugerem que asinterações entre PilB-PilZ-FimX estariam envolvidas na regulação da função de PilB, onde sinais especificas sentidas pelos domínios de FimX seriam transmitidas por PilZ até PilB. / Bacterial type IV pili (T4P) are thin and flexible filaments found on the surface of a wide range of Gram-negative bacteria and play a crucial role in their lifestyles due to their involvement in a variety of functions including motility, adherence, biofilm formation, pathogenicity, natural transformation and phage infection. Several proteins required for the biogenesis and regulation of T4P span the periplasm connecting both the inner and outer membranes. T4P are dynamic structures that undergo cycles of extension and retraction powered by two hexameric ATPases associated with the bacterial inner membrane. During extensions, the T4P assembly ATPase PilB stimulates the polymerization of pilin monomers from the inner membrane, though the precise mechanism is unknown. Two proteins, FimX and PilZ are involved in the regulation of T4P biogenesis via interactions with the PilB and knockouts of these proteins abolish T4P biogenesis. Here, we determined the crystal structure of the binary complex made up of the PilB N-terminal domain (PilBNt, residues 12- 163) bound to PilZ at 1.7Å resolution. PilZ interactions with PilB involve a hydrophobic surface made up of amino acids conserved in a non-canonical family of PilZ domains. Mutations or deletion of some these amino acids in PilZ weaken the PilZ-PilB interaction and affect T4P function. This interaction induces significant conformational changes in the PilBNt domain, suggesting that structural rearrangements of the PilB N-terminal domains could be important for its interaction with PilM, connecting the ATPase PilB with T4P machinery. We show also that full-length PilB, PilZ and FimX can form a stable ternary complex with apparent molecular weight of ~600 kDa, suggestive of a 6PilB:6PilZ:2FimX stoichiometry and that FimX increases the ATPase activity of the PilB PilZ complex. C-diGMP and ATPγS (non-hydrolysable analog of ATP) induce conformational changes in FimX and in PilB-PilZ, respectively, and stabilize the ternary PilB-PilZ-FimX complex. In addition, we show that PilB, PilZ and FimX localize at one cell pole (leading pole) that drives the movement in X. citri. Finally, the T4P is necessary for successful infection of X. citri cells by phage ΦXacm4-11. Our results suggest how FimXPilZPilB interactions could be involved in the regulation of PilB function, where specific environmental signals sensed by FimX domains could be transmitted via PilZ to PilB.

c-di-GMP

cdi-GMP

FimX

FimX

Motilidade twitching

PilB

PilB

Pilus Tipo IV

PilZ

PilZ

Twitching motility

Type IV Pilus

Xanthomonas citri

Xanthomonas citri

Transformation und Pilusbiogenese: zwei voneinander unabhängige Systeme in Acinetobacter sp. BD413 / Transformation and pilus biogenesis: two independent systems in Acinetobacter sp. BD413

Gohl, Olivia

01 November 2002

No description available.

500 Naturwissenschaften allgemein

Mathematics and Computer Science

Acinetobacter

BD413

Transformation

Gleiten

Pili

Pilus;

Acinetobacter

BD413

transformation

gliding

pili

pilus

42.30 Mikrobiologie

WU 000 Mikrobiologie

Characterizing the Roles of PilF and PilQ in Pseudomonas aeruginosa Type IV Pilus Biogenesis

Koo, Jason

12 December 2013

Type IV pili (T4P) are bacterial biomolecular machines that mediate interactions with the environment. Bacterial pathogens such as Pseudomonas aeruginosa require T4P for virulence. Significant progress has been made in recent years towards our understanding of how the proteins in the T4P system interact and function. While over 50 different proteins are involved in T4P biogenesis, the two outer membrane components, PilF and PilQ, are the focus of the work presented in this thesis. PilF was found to be required for assembly of PilQ into secretins, the outer membrane channels through which T4P fibers exit the cell. The functions of PilF are consistent with a family of lipoproteins called pilotins, to which the roles of secretin assembly and/or localization are attributed. Structure determination by X-ray crystallography revealed that PilF is composed of six tetratricopeptide (TPR) protein-protein interaction motifs. Functional mapping of PilF indicated that a hydrophobic groove on the first TPR is involved in secretin assembly. Secretin localization correlated directly with that of PilF. The effects of pilF mutations and the structural data led to the hypothesis that PilF and PilQ interact directly. We propose that PilF and PilQ interact at the inner membrane and are co-transported to the outer membrane by the Lol lipoprotein sorting system. PilQ multimerizes into secretins upon outer membrane insertion and aligns with inner membrane T4P proteins to form a complete molecular machine. PilQ mutagenesis mapping showed that: the N-terminal “system specific” domain is important but not essential for secretin function; the central “multimerization” domain is critical for secretin assembly and function; and the C-terminal tail implicated in secretin-pilotin interactions is dispensable for PilQ function. Purified PilQ enabled copurification of PilF from cell lysates, providing the first evidence for their interaction. These data provide a framework for future exploration of T4P assembly in P. aeruginosa.

Pseudomonas aeruginosa

PilF

PilQ

protein-protein interactions

pilotin

secretin

bacterial virulence

pilus biogenesis

X-ray crystallography

lipoprotein

type IV pilus

PilF-PilQ interactions

0306

0410

0307

0487

Étude des interactions entre streptococcus suis sérotype 2 et des cellules endothéliales porcines

Vanier, Ghyslaine

January 2008

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal

Adhésion

Adhesion

Cellules endothéliales

Endothelial cells

Cytotoxicité

Cytotoxicity

Induction de cytokines

Induction of cytokines

Invasion

Invasion

Méningite

Meningitis

Pilus

Pilus

Sortase

Sortase

Streptococcus suis

Streptococcus suis

Suilysine

Suilysin

Characterizing the Roles of PilF and PilQ in Pseudomonas aeruginosa Type IV Pilus Biogenesis

Koo, Jason

12 December 2013

Type IV pili (T4P) are bacterial biomolecular machines that mediate interactions with the environment. Bacterial pathogens such as Pseudomonas aeruginosa require T4P for virulence. Significant progress has been made in recent years towards our understanding of how the proteins in the T4P system interact and function. While over 50 different proteins are involved in T4P biogenesis, the two outer membrane components, PilF and PilQ, are the focus of the work presented in this thesis. PilF was found to be required for assembly of PilQ into secretins, the outer membrane channels through which T4P fibers exit the cell. The functions of PilF are consistent with a family of lipoproteins called pilotins, to which the roles of secretin assembly and/or localization are attributed. Structure determination by X-ray crystallography revealed that PilF is composed of six tetratricopeptide (TPR) protein-protein interaction motifs. Functional mapping of PilF indicated that a hydrophobic groove on the first TPR is involved in secretin assembly. Secretin localization correlated directly with that of PilF. The effects of pilF mutations and the structural data led to the hypothesis that PilF and PilQ interact directly. We propose that PilF and PilQ interact at the inner membrane and are co-transported to the outer membrane by the Lol lipoprotein sorting system. PilQ multimerizes into secretins upon outer membrane insertion and aligns with inner membrane T4P proteins to form a complete molecular machine. PilQ mutagenesis mapping showed that: the N-terminal “system specific” domain is important but not essential for secretin function; the central “multimerization” domain is critical for secretin assembly and function; and the C-terminal tail implicated in secretin-pilotin interactions is dispensable for PilQ function. Purified PilQ enabled copurification of PilF from cell lysates, providing the first evidence for their interaction. These data provide a framework for future exploration of T4P assembly in P. aeruginosa.

Pseudomonas aeruginosa

PilF

PilQ

protein-protein interactions

pilotin

secretin

bacterial virulence

pilus biogenesis

X-ray crystallography

lipoprotein

type IV pilus

PilF-PilQ interactions

0306

0410

0307

0487

Mécanismes moléculaires de la biogenèse du pilus chez Streptococcus pneumoniae

El Mortaji, Lamya

10 December 2010

Streptococcus pneumoniae est un pathogène majeur chez l'homme, responsable d'otites, de pneumonies, de septicémies et de méningites. Récemment des structures de type pilus ont été identifiées à la surface de S. pneumoniae et jouent un rôle important dans les étapes initiales de colonisation des tissus hôtes. Six gènes sont impliqués dans la formation de cette structure. Trois d'entre eux codent pour les protéines structurales ou pilines (RrgA, RrgB et RrgC) et trois autres gènes codent pour les enzymes, appelées sortases, qui catalysent l'association covalente des pilines (SrtC-1, SrtC-2 et SrtC-3). Des modèles de formation du pilus ont été proposés suite à des études de délétion génétique, mais aucune donnée biochimique permettant d'expliquer précisément la formation du pilus au niveau biomoléculaire n'est encore disponible. L'étude individuelle des protéines impliquées dans la formation du pilus a permis la mise en évidence de ponts intramoléculaires Lys-Asn stabilisateurs présents dans chacune des pilines. De plus, la résolution cristallographique de RrgA et RrgB permet de mieux comprendre les propriétés adhésives de cette structure mais également son mécanisme d'assemblage. Comme le rôle de chacune des sortases reste imprécis, nous avons développé un système de co-expression permettant de tester toutes les combinaisons de pilines et de sortases. Celui-ci nous a permis d'identifier les spécificités de chacune des sortases, de générer des complexes covalents piline/piline mais également piline/sortase et ainsi d'obtenir des éléments clés dans la compréhension de la biogenèse de cette structure.

S. pneumoniae

pilus

pilines

sortases

ponts intramoléculaires