Caractérisation de nouveaux gènes et polymorphismes potentiellement impliqués dans les interactions hôtes-pathogènes / Finding novel gene candidates and polymorphisms involved in host-pathogen interactions

Abou-Khater, Charbel

05 July 2017

La coévolution ainsi que les différentes interactions entre hôte et pathogène contribuent à former la diversité génétique de ces deux organismes. Dans le cadre de cette thèse, nous nous sommes intéressés à l’étude de la variabilité génétique de 1760 gènes immunitaires choisis suivant des critères définis, pour essayer d’expliquer pourquoi il existe une variation individuelle face aux infections. L’objectif principal de ce projet était alors de caractériser et d'analyser de nouveaux gènes et polymorphismes immunitaires pouvant expliquer le contrôle ou la susceptibilité à certaines infections. Deux études pilotes nous ont permis de développer le pipeline de détection de polymorphismes. Pour la première, le polymorphisme des 3 gènes CD28, CTLA4, et ICOS a été caractérisé. Dans la deuxième, nous avons caractérisé le polymorphisme de 10 gènes impliqués dans la réponse immunitaire contre M. tuberculosis. Ces gènes ne sont pas très polymorphes et trois d’entre eux sont très conservés. Ces deux études nous ont aidés à préparer l’analyse à grande échelle avec les mises au point et l’amélioration du pipeline. Nous avons sélectionné 1760 gènes en se basant sur des critères définis. La variabilité génétique a été étudiée dans les populations humaines par une analyse minutieuse in silico de données de séquençage d’exomes générées par différents projets et consortiums pour plus de 700 individus représentant 20 populations à travers le monde. 30 gènes les plus polymorphes ont été ainsi identifiés. Ces gènes pourront être entièrement caractérisés et les données produites pourraient être comparées avec des données de résistance/sensibilité de certaines maladies infectieuses. / Host-pathogen co-evolution and interactions contribute in shaping the genetic diversity of both organisms. The objective of this thesis is to define the genetic basis of variability in disease resistance/susceptibility through the development of large-scale in silico screens to identify novel gene candidates implicated in host-pathogen interactions (such as tuberculosis).A pilot study was conducted on CD28, CTLA4, and ICOS to investigate their polymorphism. As a first step in our study based on data available in the literature, we selected a set of ten genes relevant for the immune response against M. tuberculosis. Seven of these genes were moderately polymorphic, while three of them were highly conserved. This analysis was used to prepare and setup the large scale analysis using the same developed pipeline for polymorphism detection and allele reconstruction. For our in silico, we used sequence data from several projects and consortiums to isolate most polymorphic human genes amongst a list of over 1760 candidates selected based on already established relevance for infections and on evolutionary considerations. A first screen of 64 individuals from eight different populations from several regions of the world was performed and most variable genes were selected for further extensive analyses on a larger panel (715 individuals). 30 most polymorphic genes were thus identified. The extent of polymorphism and the allelic worldwide variants of each of these 30 genes are ready to be fully characterized. The data generated could be compared against infectious disease resistance/susceptibility data to identify potentially relevant gene variation.

Polymorphisme

Gènes candidats

Snp

Interactions hôtes-Pathogènes

Polymorphisms

Gene candidates

Snp

Host-Pathogen interactions

Réseau régulatoire de HDAC3 pour comprendre les mécanismes de différenciation et de pathogenèse de Toxoplasma gondii / Characterization of histone modifications inside nucleosome H4K31ac and H4K31me1 in Apicomplexan parasites

Sindikubwabo, Fabien

12 October 2017

Apicomplexan parasites are leading causes of human and livestock diseases such as toxoplasmosis and malaria caused by Toxoplasma gondii and Plasmodium falciparum respectively. These organisms are varied in their morphologies and astoundingly complex on their life cycles that include infections of more than one host organism, differentiation through several morphologically distinct forms, and both sexual and asexual replication. What we and others have initially proposed was that the control of gene expression and cellular differentiation are particularly interesting in these organisms, as the apparent lack of large families of recognizable transcription factors typically found in other eukaryotic organisms suggests that they may be unusually reliant on epigenetic mechanisms. The initial hypothesis had to be re-assessed in light of the discovery in Apicomplexa of an expanded family of plant-like transcription factors (TFs) harbouring APETALA2 (AP2)-like domains. Yet, a growing body of evidence tends to favor epigenetic as one of the main contributor to parasite developmental programs and adjustments to fluctuant environment. One way to examine dynamic changes in post-translations modifications (PTMs) patterns is to alter the histone code writing. We therefore took advantage of HDAC inhibitors and showed that specific inhibition of TgHDAC3 by the cyclopeptide FR235222 disrupts the genome wide steady-state level of histone H4 acetylation inducing derepression of stage-specific genes. Yet, many questions about TgHDAC3 modus operandi remain unanswered. During my thesis, I uncovered the TgHDAC3-regulated proteome-wide acetylome typified by the presence of non-histone proteins including AP2 TFs and novel PTMs, e.g. the acetylation at Lys31 within the globular domain of histone H4. H4K31ac promotes a relaxed chromatin state at the promoter of active genes through nucleosome disassembly in both parasites. We identified TgGCN5B and TgHDAC3 as two antagonist enzymes regulating H4K31 acetylation in T. gondii. In contrast, H4K31monomethylation is enriched throughout the gene body of T. gondii active genes and contributes to transcription, whereas it is enriched at transcriptionally inactive pericentromeric heterochromatin regions in P. falciparum, a region that is lacking H3K9me3 and heterochromatin protein 1 in this parasite. We also showed that treating T. gondii cystogenic strains with a low dose of FR235222 induces the levels of proteins known to be expressed exclusively in cat (sporozoite and merozoite) or in murine chronic stage (bradyzoite). Lastly, we determined the specific interactome of TgHDAC3 and found as partners a MORC protein (CR230), several AP2 TFs, and ELM2 domain-containing scaffolding proteins. Collectively, these data established TgHDAC3 family as a central regulator of gene expression and stage conversion in T. gondii and, likely, other Apicomplexa. / Apicomplexan genome architecture is typified by a binary chromatin structure, with a major fraction of the bulk genome packaged as transcriptionally permissive euchromatin while few loci are embedded in silenced heterochromatin. There is evidence that histone modifications occurring at the lateral surface of the nucleosome play a substantial role in shaping chromatin structure, yet our understanding of the exact mechanism of action is poor. Here, we address how versatile modifications at Lys31 within the globular domain of histone H4 contribute to genome organization and expression in Apicomplexa. H4K31 acetylation was found at the promoter of active genes. The residue lies where the DNA wraps around the histone and its acetylation may enhance nucleosome disassembly, thereby favoring a more relaxed, open chromatin state. This residue tends also to be monomethylated and depending of the parasite examined different patterns were found. H4K31me1 was enriched in the core body of Toxoplasma active genes, yet its occupancy was inversely correlated with transcripts levels likely because the mark by reducing histone turnover impedes RNA polymerase progression across transcribed units. In contrast to the methylation of H3, it is the first time that a methylated residue of H4 has been clearly associated with transcriptional regulation. In Plasmodium, H4K31me1 was exclusively enriched at transcriptionally inactive genomic regions and peculiarly at pericentromeric heterochromatin, likely to replace the missing H3K9me3 that commonly decorated pericentric nucleosomes in other species.

Interactions Hôtes-Pathogènes

Epigénétiques

Régulation des gènes

Effecteurs des parasites

Host-Pathogen interactions

Epigenetics

Gene regulation

Parasite-­effectors

570

610

Diversification et adaptation génomique des virus entomopathogènes / Genomic diversification and adaptation of entomopathogenic viruses

Thézé, Julien

31 May 2013

À différentes échelles de temps, le but de ma thèse a été de comprendre l'évolution des virus entomopathogènes à travers l’étude de la diversification et de l’adaptation génomique de grands virus à ADN d’insectes. Dans un premier temps, j’ai pu estimer les âges de diversifications des baculovirus et des nudivirus, et proposer un scénario de coévolution à long terme entre ces virus et leurs hôtes insectes. Puis, me plaçant sur une échelle de temps moindre, j’ai montré que les hôtes insectes sont le facteur principal de la diversification des baculovirus, et de façon surprenante, j’ai également observé que l'environnement biotique de ces virus, c’est-à-dire les plantes hôtes des insectes, joue un rôle central dans leur évolution. Dans un second temps, des mutations ponctuelles ont pu être reliées à l’adaptation locale de populations différentiées du baculovirus SeMNPV. Enfin, l’étude de l'adaptation génomique convergente entre les entomopoxvirus et les baculovirus a mis en évidence que les transferts horizontaux de gènes sont une source importante de variabilité pour les grands virus à ADN, pour l'adaptation aux mêmes niches écologiques. Les gènes et les mécanismes identifiés dans ce travail de thèse apportent des éléments nouveaux pour comprendre comment les génomes sont façonnés par l’écologie. / At different timescales, the purpose of my PhD was to understand insect virus evolution through the study of the genomic diversification and adaptation of insect large DNA viruses. Firstly, I was able to estimate the ages of baculovirus and nudivirus diversifications, and to propose a long-term coevolutionary scenario between these viruses and their insect hosts. Then, on a narrower timescale, I showed that insect hosts are the major factor in baculovirus diversification, and surprisingly, I also observed that the virus biotic environment, i.e. insect host plants, plays a central role in their evolution. Secondly, punctual mutations have been linked to the local adaptation of differentiated populations of the baculovirus SeMNPV. Finally, the study of convergent genomic adaptation between entomopoxviruses and baculoviruses highlighted that horizontal gene transfers are an important source of variability for large DNA viruses, for the adaption to the same ecological niches. Genes and mechanisms identified in this PhD work provide new insights to understand how genomes are shaped by ecology.

Évolution

Phylogénétique

Adaptation

Génomes

Virus

Insectes

Interactions hôtes-pathogènes

Mutations

Transferts de gènes horizontaux

Evolution

Phylogenetics

Adaptation

Genomes

Virus

Insect

Host-pathogen interactions

Mutations

Horizontal gene transfers