Effects of Vibrio cholerae protease and pigment production on environmental survival and host interaction

Vaitkevicius, Karolis

January 2007

Only two out of more than 200 V. cholerae serogroups, classified on the basis of LPS structure, are associated with epidemic or pandemic cholera. These toxigenic serogroups carry phage-derived pathogenicity islands coding for the main virulence factors for establishment of cholera disease – cholera toxin (CTX) and toxin-coregulated pilus (TCP). The latter also serves as a bacterial surface receptor for the CTXΦ – the filamentous phage which carries the cholera toxin genes into otherwise harmless to human, environmental bacterium V. cholerae. In its natural aquatic habitat V. cholerae is subject to predator grazing, bacteriophage killing, temperature and pH changes, seasonality of plankton blooms and other environmental factors. Therefore understanding V. cholerae pathogenic and virulence potential requires the knowledge of its interaction not only with human host but also members of aquatic environment and environmental factors. V. cholerae is capable of killing the nematode Caenorhabditis elegans. Using a reverse genetics approach, we demonstrated that the quorum sensing regulated protease PrtV is essential for this killing. Other proteases did not seem to contribute to virulence in this model. The data from this study suggest that the PrtV could be important to V. cholerae in its natural niche for its resistance to the grazing predators. The PrtV protease belongs to an M6 family of metallopeptidases which is represented by an Immune Inhibitor A protease from the insect killing bacterium Bacillus thuringiensis. To characterize the protease in more detail, the PrtV was cloned, overexpressed in V. cholerae and purified from the culture supernatant. The enzyme was calcium stabilized and inhibited by metal ion chelators. In tests with in vitro cultured cells of the human intestinal cell line HCT8, the PrtV protein showed a cytotoxic effect leading to cell detachment and death. Using human blood plasma as a source of potential substrates, and by tests with purified candidate substrate proteins, we have identified fibrinogen (all α, β and γ chains), fibronectin and plasminogen to be degraded by the protease. Additionally, PrtV was found to alter the stability of V. cholerae cytolysin implicating its role in modulation of the reactogenicity of V. cholerae secreted factors. Pigmentation has been considered to be important in microbial pathogenesis because it has been associated with virulence in many microorganisms. Using transposon mutagenesis we identified the mutated locus of a pigment producing V. cholerae strain to encode a gene of a tyrosine catabolic pathway. The mutation in a putative homogentisate 1,2-dioxigenase gene lead to accumulation of homogentisic acid, its spontaneous oxidation and formation of a dark pigment. The pigment producing strain was altered in its ability to survive UV exposure and H2O2 stress, and was more efficient in colonizing the suckling mouse intestine compared to the wild type strain. Under the in vitro growth conditions the major virulence factor TcpA and CT expression was found to be somewhat enhanced too.

Bacteria-host interaction

Nematode

Metalloprotease

Medical microbiology

Medicinsk mikrobiologi

Functional analysis of the predicted surface proteome of Gram-positive bacteria from the human gastrointestinal tract. A high-throughput approach to identification of immune modulators / Analyse fonctionnelle du protéome de surface prédit de bactéries à Gram positif du tractus digestif humain. Une approche à haut débit pour l'identification de modulateurs immunitaires

Dobrijevic, Dragana

25 September 2013

Il est maintenant bien établi que le microbiote du tractus digestif humain joue un rôle important dans la santé humaine. Pourtant, nous commençons à peine à comprendre les mécanismes moléculaires par lesquels les bactéries agissent sur les cellules hôtes, des connaissances qui pourraient fournir des nouvelles orientations dans le traitement et la prévention de maladies. Cette dernière décennie a vu un développement rapide des études du microbiote intestinal, et à présent des quantités importantes de données métagénomiques ainsi que des centaines de séquences génomiques de bactéries commensales sont disponibles. Ensemble, ces données fournissent une plateforme pour des approches in silico pour l'identification de molécules bactériennes impliquées dans la communication moléculaire avec l'hôte. Le défi consiste à développer des stratégies efficaces d'exploration de données et de validation, permettant de passer de corrélations et prédictions à des interactions bactérie - hôte fonctionnelles, validées expérimentalement. Le travail présenté dans cette thèse vise à démontrer l'importance d'analyses in silico afin d'élargir nos connaissances sur les interactions bactéries - hôtes. Il montre également comment cette information peut être appliquée dans des études fonctionnelles visant à identifier des molécules effectrices bactériennes fonctionnelles. Les principaux résultats peuvent être divisés en trois parties. La première partie traite de l'élaboration et de la validation d'un système hôte - vecteur pour des études de (méta)génomique fonctionnelle. La deuxième partie décrit une étude fonctionnelle où un certain nombre d'effecteurs candidats ont été identifiés parmi les protéines sécrétées et de surface de bactéries à Gram positif par une approche d'exploration in silico. Il décrit également l'application du nouveau système hôte - vecteur pour l'évaluation du rôle de ces candidats dans l'immuno-modulation. Enfin, dans la troisième partie, nous présentons une étude in silico qui a permis l'identification de fonctions bactériennes sur- ou sous-représentées dans une sélection de bactéries à Gram positif du tractus digestif humain. / It is now well established that the human gastrointestinal tract microbiota plays an intricate role in human health. However, we are only beginning to understand the molecular mechanisms by which bacteria act on the host cells, knowledge that could provide new directions in treating and preventing disease. The last decade has seen a rapid development of the gut microbiota field, and presently abundant metagenome data and hundreds of genome sequences of individual commensal bacteria are available. Together, these data provide a platform for in silico mining approaches to identify bacterial molecules involved in communication with the host. The challenge is to develop efficient mining and validation strategies, in order to move from correlations and predictions to experimentally validated functional bacteria – host relationships. The work presented in this thesis aims to demonstrate the importance of in silico analyses to broaden our knowledge on bacteria - host interactions. It also shows how this information can be applied in functional studies aiming to identify functional bacterial effector molecules. The main results can be divided in three parts. The first part deals with the development and validation of a host - vector system for functional (meta)genomics studies. The second part describes a functional study where a number of candidate effectors were identified among secreted and surface-exposed proteins from Gram-positive bacteria using an in silico mining approach. It also describes the application of the newly developed host - vector system to evaluate the role of these candidates in immune modulation. Finally, in the third part we present an in silico study that identified new bacterial functions over- or under-represented in a selection of Gram-positive human gut bacteria.

Tractus digestif

Interaction bactéries-hôte

Métagénomique fonctionnel

Modulation immunitaire

Gut

Bacteria-host interaction

Functional metagenomics

Immune modulation