Interactions of Neisseria meningitidis with the human immune system

Harding, Rachel Jane

January 2015

Neisseria meningitidis is an obligate human pathogen causing over 1000 cases of meningococcal disease within the U.K., 10 % of which result in long-term disability or fatality. 10-70 % of the population carry N. meningitidis in their nasopharynx, the natural reservoir of this bacterium, as a commensal. The host-pathogen interactions of this species are complex and a greater understanding of the molecular mechanisms involved in pathogenesis and immune evasion is required. Three aspects of N. meningitidis pathogenesis were explored in this study. One mechanism of immune evasion which promotes serum resistance of N. meningitidis is recuitment of complement factor H through domains 6 and 7 (fH₆₇) by factor H binding protein (fHbp). In this study, mouse fH₆₇ was recombinantly expressed and purified. fHbp did not bind mouse fH₆₇ at physiologically relevant protein concentrations. The structure of mouse fH₆₇ was solved, showing differences in domain orientation and surface chemistry compared to the human version of this protein, potentially accounting for the host specificity of this interaction. Type IV pili (T4P) are crucial adhesins of N. meningitidis, the fibre of which is composed of thousands of copies of PilE. A method was developed to recombinantly produce large quantities of this protein from a variety of meningococcal strains and the structure was solved of one PilE protein. Subsequent analysis was performed with the PilE proteins investigating their interaction with the putative pilus receptor CD46 and human epithelia as well as their immunogenicity. A method was also established to produce PilC, the proposed tip-assocoated adhesin of T4P. ZapE has recently been identified as an important protein in pathogen colonisation, functioning as an ATPase linked to Z-ring formation in bacterial cell fission. Both N. meningitidis and E. coli ZapE were recombinantly produced. The domain boundaries were mapped and ATPase activity was confirmed. No interaction was seen with FtsZ but DNA binding and modulation was observed by shift assays, the exact function of which remains to be elucidated in future studies.

572.8

Etudes structurale et fonctionnelle de protéines impliquées dans la virulence chez S. pneumoniae et P. aeruginosa

Izore, 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.

Cristallographie aux rayons x

Système de sécrétion de type III

Pilus

Pilotine

Caractérisation structurale et fonctionnelle des composants du pilus de Streptococcus pneumoniae : vers une meilleure compréhension de la biogenèse des pili.

Manzano, Clothilde

07 September 2009

Streptococcus pneumoniae est un pathogène majeur chez l'homme, responsable d'otites sévères, de pneumonies, de bactériémies et de méningites. C'est une cause majeure de mortalité et de morbidité, essentiellement chez les enfants et les personnes âgées. Il a été récemment découvert que certaines souches virulentes de S. pneumoniae portent à leur surface des pili, considérés comme un important facteur de virulence. Cependant, contrairement aux bactéries à Gram-négatif, peu de choses sont connues sur la structure des pili des bactéries à Gram-positif. Les gènes requis pour la production des pili chez S. pneumoniae sont localisés sur un îlot de pathogénicité et codent pour 3 sortases (SrtC-1, SrtC-2, SrtC-3) et 3 protéines structurales (RrgB, qui forme le corps du pilus, RrgA et RrgC). Celles-ci contiennent un motif LPXTG, motif de reconnaissance des enzymes sortases. Dans ce travail, nous apportons de nouvelles informations structurale, biochimique et microbiologique sur le mécanisme de formation du pilus par (1) une reconstitution du corps de la fibre in vitro après avoir identifié SrtC-1 comme étant la principale pilus-polymérase; (2) une étude de microscopie électronique montrant que les fibres produites in vitro mimaient structuralement les pili ; (3) une étude in vivo confirmant les résultats obtenus in vitro; (4) la résolution de la structure par cristallographie aux rayons X de SrtC-1 et SrtC-3 qui révèle un site actif dont l'accès est contrôlé par un couvercle flexible, contrairement aux sortases non impliquées dans la biogenèse de pili. Ces observations suggèrent que la spécificité de substrat est dictée par une reconnaissance de surface couplée à une ouverture du couvercle. Dans un second temps, nous avons caractérisé la région du site actif de SrtC-1 : la triade catalytique mais aussi les deux résidus du couvercle qui s'ancrent dans le site actif. L'identification de résidus clés dans l'activité sortasique aussi bien que dans la stabilisation structurale a été ainsi mis en évidence.

pathogénicité bactérienne

pneumocoque

pilus

PilZ Domain-Containing Proteins Regulate Motility in Acinetobacter baumannii

Smith, Gabriel

01 August 2024

Acinetobacter baumannii is an increasingly multidrug-resistant pathogen contributing to hospital-acquired infections, necessitating a greater understanding of how it interacts with its surroundings. Many bacteria utilize different methods of bacterial motility to move about and interact with these surroundings. A bacterial second messenger, cyclic diguanosine monophosphate (c-di-GMP), can regulate various motility factors that are potentially advantageous for survival in and adaptation to their environment. Concentrations of c-di-GMP are regulated by specific synthesizing and degrading enzymes. Controlled levels of c-di-GMP allow interaction between the c-di-GMP and its binding effectors that induce changes in bacterial phenotypes such as biofilm formation and motility. A search of the A. baumannii genome identified two proteins that contain the c-di-GMP-binding PilZ domain. The PilZ protein for which this PilZ domain was named was initially discovered in Pseudomonas aeruginosa where it has been demonstrated to be a part of the type IV pilus machinery. Type IV pili play roles in twitching motility, adhering to surfaces, DNA uptake, protein secretion, and predation. One of the PilZ-containing proteins from A. baumannii resembled this original PilZ protein (PilZ), while the second PilZ-containing protein contained a hydrolase domain with unknown substrate specificity (HydP). I investigated whether these PilZ-containing proteins play a role in motility of A. baumannii by testing two strains: AB5075 that displays twitching motility, and ATCC17978 that displays an uncharacterized form of surface-associated motility. Results suggest PilZ plays a role in twitching motility, while its effect on surface-associated motility phenotypes3 is possibly due to polar effects from mutation. Results also suggest HydP plays a role in surface-associated motility, although its mechanism is not understood. Testing of both proteins’ PilZ domains indicates they may not bind c-di-GMP, implying they may be playing roles in motility regulation through other mechanisms outside of binding c-di-GMP. These findings give us greater insight into the regulatory mechanisms used by A. baumannii to move about its environment.

C-di-GMP

Acinetobacter buamannii

PilZ

Pilus

Motility

Bacterial Infections and Mycoses

Bacteriology

Microbial Physiology

Pathogenic Microbiology

Estudo estrutural e funcional das proteínas PilZ e YaeQ do fitopatógeno Xanthomonas axonopodis pv citri / Structural and functional studies of PilZ and YaeQ from Xanthomonas axonopodis pv citri proteins

Guzzo, Cristiane Rodrigues

25 February 2010

O trabalho aqui desenvolvido teve como objeto o estudo estrutural e funcional de várias proteínas do fitopatógeno Xanthomonas axonopodis pv citri (Xac), dentre as quais se destacam as proteínas hipotéticas conservadas YaeQ e SufE, as proteínas RpfC, RpfF e RpfG envolvidas em quorum sensing e proteínas PilZ, FimX e PilB envolvidas na biogênese do pilus tipo IV. Para o desenvolvimento deste trabalho foram utilizadas diferentes técnicas incluindo: clonagem, expressão, purificação, desnaturação térmica, cristalografia, difração de raios-X, RMN, ensaios de 2-híbrido, produção de nocautes, mutação sítio dirigida, Western- e Far- Western, entre outras. Dentre os resultados mais importantes obtidos temos a determinação estrutural das proteínas YaeQ e PilZ pela técnica MAD. Em ambos os casos, as estruturas representaram topologias inéditas. Com base nos dados estruturais, mostramos que YaeQ pertence à família PD-(D/E)XK presente em endonucleases dependentes de magnésio, e a partir de ensaios funcionais obtivemos evidências que sugerem que YaeQ está envolvida em alguma via de reparo de DNA em Xac. A estrutura tridimensional de PilZ revelou uma inesperada variedade estrutural dentro da família PilZ e mostrou de forma clara porque ortólogos não interagem com o segundo mensageiro bacteriano, c-diGMP. A cadeia principal de PilZ foi assinalada por RMN e a estrutura secundária de PilZ em solução é consistente com aquela determinada por cristalografia. Duas proteínas que interagem com PilZ foram identificadas: PilB e FimX. Como PilZ, ambos exercem papéis na biogênese do pilus tipo IV (T4P). Mostramos que PilZ interage especificamente com o domínio EAL de FimX e que resíduos conservados na região do C-terminal de PilZ estão envolvidos na interação com PilB, mas não com FimX. Ensaios de mutação sítio dirigida mostraram que a Y22 de PilZ pode estar envolvida na regulação da interação de PilZ com FimX e com PilB. Apesar de PilZ não interagir com c-diGMP seu parceiro, FimX, interage. PilZ consegue interagir com PilB ao mesmo tempo em que interage com FimX, formando um complexo ternário que é independente da interação de FimX com c-diGMP. Com base em todos estes resultados propusemos possíveis mecanismos de ação de PilZ e FimX no controle da biogênese do T4P. Além dos resultados acima descritos, determinamos a estrutura de SufE e mostramos que esta aumenta a atividade cisteína dessulfarase de seu parceiro, SufS, em torno de 10 vezes, como ocorre com SufE-SufS de E.coli. Clonamos, expressamos, purificamos e fizemos ensaios de cristalização de algumas proteínas envolvidas no controle de quorum sensing em Xac. Tivemos êxito na cristalização do domínio HPT (histidina fosfotransferase) da proteína chave deste sistema, RpfC / The aim of the project was to perform structural and functional studies of different Xanthomonas axonopodis pv citri (Xac) proteins including the hypothetical proteins YaeQ and SufE; RpfC, RpfF and RpfG involved in the quorum sensing and PilZ, FimX and PilB that play roles in type IV pilus (T4P) biogenesis. Several experimental techniques were employed including cloning, expression and purification of recombinant proteins, thermal denaturation, protein crystallography, X-ray diffraction, NMR, two-hybrid assays, Western- and Far-Western Blotting assays, site direct mutagenesis, and the production of Xac knockouts strains. The most important results include the determination of the three-dimensional crystal structures of PilZ and YaeQ using the MAD technique. In both cases, the structures reveled new protein topologies. The comparison of the YaeQ structure with others deposited in public databases revealed that YaeQ proteins represent a new variation within the PD-(D/E)XK magnesium dependent endonucleases superfamily. Functional assays suggest that YaeQ may be envolved in DNA repair in Xac. The PilZ three-dimensional structure revealed an unexpected structural variation within the PilZ domain superfamily and showed why PilZ orthologs are not able to bind the important bacterial second messenger, c-diGMP. We assigned the PilZ main chain by NMR and used this information to demonstrate that the PilZ secondary structure in solution is consistent with the PilZ crystal structure. We identified two proteins that interact with PilZ: PilB and FimX. As with PilZ, both PilB and FimX are involved in T4P biogenesis. PilZ binds specifically to the EAL domain of FimX and the conserved residues located in the PilZ unstructured C-terminal region contribute to binding with PilB but not with FimX. Site direct mutagenesis studies showed that PilZ residue Y22 is necessary for its capability to interact with both PilB and FimX. Although PilZ does not bind c-diGMP, her partner, FimX, does. We present evidence that PilZ can bind simultaneously to FimX and PilB, forming a ternary complex that is independent of c-diGMP. These results allow us to propose possible mechanisms by which PilZ and FimX control T4P biogenesis. Other results obtained during this period include the resolution of the crystal structure of the SufE protein from Xac using the molecular replacement technique. We show that SufE induces a 10-fold increase in the cysteine desulfurase activity of SufS, similar to that observed for the SufE-SufS complex from E. coli. Several proteins involved in quorum sensing and c-di-GMP signaling were cloned, expressed and submitted to crystallization trials. Crystals of the HPT (histidine phophotransferase) domain) of the RpfC sensor histidine kinase were obtained

Difração de raios-X

Pilus tipo IV)

PilZ

PilZ

Quorum sensing

Quorum sensing

SufE

SufE

Type IV pilus

X-ray diffraction

YaeQ

YaeQ

Estudo estrutural e funcional das proteínas PilZ e YaeQ do fitopatógeno Xanthomonas axonopodis pv citri / Structural and functional studies of PilZ and YaeQ from Xanthomonas axonopodis pv citri proteins

Cristiane Rodrigues Guzzo

25 February 2010

O trabalho aqui desenvolvido teve como objeto o estudo estrutural e funcional de várias proteínas do fitopatógeno Xanthomonas axonopodis pv citri (Xac), dentre as quais se destacam as proteínas hipotéticas conservadas YaeQ e SufE, as proteínas RpfC, RpfF e RpfG envolvidas em quorum sensing e proteínas PilZ, FimX e PilB envolvidas na biogênese do pilus tipo IV. Para o desenvolvimento deste trabalho foram utilizadas diferentes técnicas incluindo: clonagem, expressão, purificação, desnaturação térmica, cristalografia, difração de raios-X, RMN, ensaios de 2-híbrido, produção de nocautes, mutação sítio dirigida, Western- e Far- Western, entre outras. Dentre os resultados mais importantes obtidos temos a determinação estrutural das proteínas YaeQ e PilZ pela técnica MAD. Em ambos os casos, as estruturas representaram topologias inéditas. Com base nos dados estruturais, mostramos que YaeQ pertence à família PD-(D/E)XK presente em endonucleases dependentes de magnésio, e a partir de ensaios funcionais obtivemos evidências que sugerem que YaeQ está envolvida em alguma via de reparo de DNA em Xac. A estrutura tridimensional de PilZ revelou uma inesperada variedade estrutural dentro da família PilZ e mostrou de forma clara porque ortólogos não interagem com o segundo mensageiro bacteriano, c-diGMP. A cadeia principal de PilZ foi assinalada por RMN e a estrutura secundária de PilZ em solução é consistente com aquela determinada por cristalografia. Duas proteínas que interagem com PilZ foram identificadas: PilB e FimX. Como PilZ, ambos exercem papéis na biogênese do pilus tipo IV (T4P). Mostramos que PilZ interage especificamente com o domínio EAL de FimX e que resíduos conservados na região do C-terminal de PilZ estão envolvidos na interação com PilB, mas não com FimX. Ensaios de mutação sítio dirigida mostraram que a Y22 de PilZ pode estar envolvida na regulação da interação de PilZ com FimX e com PilB. Apesar de PilZ não interagir com c-diGMP seu parceiro, FimX, interage. PilZ consegue interagir com PilB ao mesmo tempo em que interage com FimX, formando um complexo ternário que é independente da interação de FimX com c-diGMP. Com base em todos estes resultados propusemos possíveis mecanismos de ação de PilZ e FimX no controle da biogênese do T4P. Além dos resultados acima descritos, determinamos a estrutura de SufE e mostramos que esta aumenta a atividade cisteína dessulfarase de seu parceiro, SufS, em torno de 10 vezes, como ocorre com SufE-SufS de E.coli. Clonamos, expressamos, purificamos e fizemos ensaios de cristalização de algumas proteínas envolvidas no controle de quorum sensing em Xac. Tivemos êxito na cristalização do domínio HPT (histidina fosfotransferase) da proteína chave deste sistema, RpfC / The aim of the project was to perform structural and functional studies of different Xanthomonas axonopodis pv citri (Xac) proteins including the hypothetical proteins YaeQ and SufE; RpfC, RpfF and RpfG involved in the quorum sensing and PilZ, FimX and PilB that play roles in type IV pilus (T4P) biogenesis. Several experimental techniques were employed including cloning, expression and purification of recombinant proteins, thermal denaturation, protein crystallography, X-ray diffraction, NMR, two-hybrid assays, Western- and Far-Western Blotting assays, site direct mutagenesis, and the production of Xac knockouts strains. The most important results include the determination of the three-dimensional crystal structures of PilZ and YaeQ using the MAD technique. In both cases, the structures reveled new protein topologies. The comparison of the YaeQ structure with others deposited in public databases revealed that YaeQ proteins represent a new variation within the PD-(D/E)XK magnesium dependent endonucleases superfamily. Functional assays suggest that YaeQ may be envolved in DNA repair in Xac. The PilZ three-dimensional structure revealed an unexpected structural variation within the PilZ domain superfamily and showed why PilZ orthologs are not able to bind the important bacterial second messenger, c-diGMP. We assigned the PilZ main chain by NMR and used this information to demonstrate that the PilZ secondary structure in solution is consistent with the PilZ crystal structure. We identified two proteins that interact with PilZ: PilB and FimX. As with PilZ, both PilB and FimX are involved in T4P biogenesis. PilZ binds specifically to the EAL domain of FimX and the conserved residues located in the PilZ unstructured C-terminal region contribute to binding with PilB but not with FimX. Site direct mutagenesis studies showed that PilZ residue Y22 is necessary for its capability to interact with both PilB and FimX. Although PilZ does not bind c-diGMP, her partner, FimX, does. We present evidence that PilZ can bind simultaneously to FimX and PilB, forming a ternary complex that is independent of c-diGMP. These results allow us to propose possible mechanisms by which PilZ and FimX control T4P biogenesis. Other results obtained during this period include the resolution of the crystal structure of the SufE protein from Xac using the molecular replacement technique. We show that SufE induces a 10-fold increase in the cysteine desulfurase activity of SufS, similar to that observed for the SufE-SufS complex from E. coli. Several proteins involved in quorum sensing and c-di-GMP signaling were cloned, expressed and submitted to crystallization trials. Crystals of the HPT (histidine phophotransferase) domain) of the RpfC sensor histidine kinase were obtained

Difração de raios-X

Pilus tipo IV)

PilZ

Quorum sensing

SufE

YaeQ

PilZ

Quorum sensing

SufE

Type IV pilus

X-ray diffraction

YaeQ

Study of the natural transformation pilus in streptococcus pneumoniae / Etude du pilus de transformation chez streptococcus pneumoniae

Laurenceau, Raphael

18 September 2014

La transformation naturelle est la capacité de certaines bactéries à incorporer et à recombiner activement de l’ADN extra-cellulaire. Ce procédé majeur augmente la plasticité et l’adaptabilité des bactéries à Gram positif et négatif en réalisant des échanges génétiques intra- et inter-espèces. S. pneumoniae est un pathogène majeur de l’Homme. Cette bactérie est responsable d’infections sévères telles que des pneumonies, des méningites et des septicémies. Dans cette espèce, la transformation naturelle est corrélée au phénomène de changement de capsule et à la baisse d’efficacité des vaccins. La plupart des bactéries à Gram positif naturellement transformables possèdent un opéron comG, semblable aux opérons codant pour la famille des pili de type IV, extrêmement répandus chez les bactéries à Gram négatif. Il a été proposé que l’opéron comG est responsable de la formation d’un petit filament, nommé pseudo- pilus. Cependant, un tel filament n’a jamais été observé. Par des techniques de mutagenèse, de caractérisation biochimique, de microscopie optique et électronique, nous sommes parvenus à identifier des filaments de plusieurs micromètres de long à la surface de bactéries S. pneumoniae compétentes. Nous avons confirmé l’appartenance de ces filaments à la famille des pili de type IV. Par conséquent, nous avons infirmé l’hypothèse de la formation d’un pseudo-pilus par l’opérons comG chez S. pneumoniae. De plus, nous avons montré que les pili se lient à l’ADN et qu’ils sont requis pour la capture de l’ADN extra-cellulaire. Ces résultats apportent des informations cruciales concernant les premières étapes de capture de l’ADN durant la transformation naturelle. Nous proposons un nouveau modèle dans lequel le pilus agirait comme un « piège à ADN », capturant l’ADN à la surface des bactéries compétentes pour le guider jusqu’au pore d’entrée dans la cellule. / Natural transformation is the ability of bacteria to actively take up and recombine extracellular DNA. This crucial process increases genome plasticity and adaptability of Gram-negative and Gram-positive bacteria through intra- and inter-species genetic exchange. S. pneumoniae is a major human pathogen responsible for severe diseases such as pneumonia, meningitis and septicemia. In this species, transformation has been linked to capsular serotype switching and reduced vaccine efficiency. Most transformable Gram-positive bacteria carry a comG operon that resembles operons encoding a widespread family of pili in Gram-negative bacteria, the type IV pili. It has been commonly proposed that the comG operon is responsible for the formation of a short pseudo-pilus filament. However, such an appendage had never been visualized in any bacterium. By mutagenesis, biochemical characterization, optical and electron microscopy techniques we were able to identify long, micrometer-sized appendages protruding from the surface of competent S. pneumoniae. We confirmed the Type IV pili nature of these appendages, we showed that they bind DNA, and are absolutely required for DNA uptake. We consequently overthrew the pseudopilus hypothesis at least in S. pneumoniae, and provided crucial information concerning the initial step of DNA uptake. We propose a revised model in which the transformation pilus acts as a “DNA trap” capturing DNA at the surface of competent cells, guiding it to the translocation channel.

Transformation naturelle

Streptococcus pneumoniae

Pilus de type IV

Transfert horizontal de gène

Compétence

Liaison à l'ADN

Natural transformation

Streptococcus pneumoniae

579

Noninvasive immunization strategies to target dendritic cells and protect against experimental otitis media due to nontypeable <i>Haemophilus influenzae</i>

Novotny, Laura Anne

21 March 2011

No description available.

Immunology

Microbiology

otitis media

nontypeable Haemophilus influenzae

vaccine

biofilm

chinchilla

dendritic cell

LB1

OMP P5

PilA

Type IV pilus

Investigating AmrZ-mediated activation of <i>Pseudomonas aeruginosa</i> twitching motility and alginate production

Xu, Binjie

January 2015

No description available.

Biology

Biomedical Research

Microbiology

Molecular Biology

Pseudomonas aeruginosa

bacterial pathogen

pathogenesis

cystic fibrosis

AmrZ

twitching motility

type IV pilus

alginate

protein oligomerization

gene regulation

transcription

transcription regulation

transcriptome profiling

C-terminal domain