The complex pattern of epigenomic variation between natural yeast strains at single-nucleosome resolution

International audienceBackground: Epigenomic studies on humans and model species have revealed substantial inter‑individual variation in histone modification profiles. However, the pattern of this variation has not been precisely characterized, particularly regarding which genomic features are enriched for variability and whether distinct histone marks co‑vary synergistically. Yeast allows us to investigate intra‑species variation at high resolution while avoiding other sources of variation, such as cell type or subtype. Results: We profiled histone marks H3K4me3, H3K9ac, H3K14ac, H4K12ac and H3K4me1 in three unrelated wild strains of Saccharomyces cerevisiae at single‑nucleosome resolution and analyzed inter‑strain differences statistically. All five marks varied significantly at specific loci, but to different extents. The number of nucleosomes varying for a given mark between two strains ranged from 20 to several thousands; +1 nucleosomes were significantly less subject to variation. Genes with highly evolvable or responsive expression showed higher variability; however, the variation pattern could not be explained by known transcriptional differences between the strains. Synergistic variation of distinct marks was not systematic, with surprising differences between functionally related H3K9ac and H3K14ac. Interestingly, H3K14ac differences that persisted through transient hyperacetylation were supported by H3K4me3 differences, suggesting stabilization via cross talk. Conclusions: Quantitative variation of histone marks among S. cerevisiae strains is abundant and complex. Its relation to functional characteristics is modular and seems modest, with partial association with gene expression divergences, differences between functionally related marks and partial co‑variation between marks that may confer stability. Thus, the specific context of studies, such as which precise marks, individuals and genomic loci are investigated, is primor‑ dial in population epigenomics studies. The complexity found in this pilot survey in yeast suggests that high complexity can be anticipated among higher eukaryotes, including humans

Mapping and analysis of natural epigenomic variations in the yeast Saccharomyces cerevisiae

L'épigénome est défini par l’ensemble de l’information chromatinienne autre que celle fournie par la séquence ADN. Au sein d'une même espèce et pour un type cellulaire donné, chaque individu présente des caractéristiques particulières de l'épigénome. Les épi-polymorphismes, définis comme étant les différences inter-individus de marques chromatiniennes, sont encore partiellement caractérisés et peuvent être liés aux phénotypes de chacun. La première partie de mon travail a été d'identifier et d'interpréter chez S.cerevisiae l'impact des épi-polymorphismes de modification des queues d'histones. Pour y parvenir, j'ai cartographié les épigénomes de cinq modifications différentes (3 acétylations et 2 méthylations) chez trois souches de levures issues de différents isolats naturels. Par une méthode de ChIP-seq et le développement d'un outil informatique, j'ai comparé les épigénomes de ces souches à l'échelle de nucléosomes individuels. L'étude des propriétés génomiques des épi-polymorphismes m'a alors permis de découvrir certaines caractéristiques encore inconnues et décrites dans ce manuscrit.Par ailleurs, j'ai voulu aborder le lien entre épi-polymorphismes et réponse transcriptionnelle à l'environnement. Pour cela, j'ai construit un jeu de souches mutantes dérivées de souches naturelles, où certains épi-polymorphismes ne peuvent plus être maintenus. J'ai analysé par RNA-seq les transcriptomes de certaines de ces souches avant et après un changement environnemental. Malheureusement, l'analyse des résultats a révélé que la qualité des données ne permettent pas d'établir le lien recherché mais les outils mis en place sont désormais disponibles.J'ai enfin étudié la dynamique d'évolution d'un épigénome en présence ou en l'absence de pression de sélection. Pour cela, j'ai suivi une modification d'histone (l'acétylation de la lysine 14 de l'histone H3) chez la levure pendant 1.000 générations dans deux conditions d'évolution expérimentale différentes : l'une sélective, l'autre neutre. J'ai mis en évidence des différences remarquables et inattendues entre ces deux régimes évolutifs. Des études mécanistiques détaillées restent à faire pour caractériser la nature et les propriétés de ces différences.Epigenome is defined as the entire chromatin information other than the DNA sequence. Within a given species and for a given cell type, each indivual has specific epigenomic characteristics. Epigenomic differences between individuals (refered to as 'epi-polymorphisms') remain poorly characterized, although cases were reported where they could be linked to phenotypic differences. In my thesis, I used the model organism S. cerevisiae to identify histone modification epi-polymorphisms and study their biological impact. I profiled the epigenome of five different histone modifications (3 acetylations and 2 methylations) in three natural yeast strains. By ChIP-seq methods and software developments, I compared these strains at single-nucleosome resolution and discovered novel characteristics of these epi-polymorphisms which are described in this manuscript.Furthermore, I constructed a research framework to investigate the link between epi-polimorphisms and response to environmental cues. For this, I built a set of mutant strains derived from natural strains but where some epi-polymorphisms can no longer be maintained. I analyzed by RNA-seq the transcriptomes of some of these mutant strains before and after an environmental shift. Unfortunately, the quality of this initial data produced was not sufficient to link epi-polymorphisms to differntial responses, but the strain resources remain available for further investigations. Finally, I studied the evolutionary dynamics of epi-polymorphisms in the presence or absence of selection pressure. To do so, I followed the evolution of H3K14ac for 1.000 generations under two conditions of yeast experimental evolution ( selective or neutral). Marked differences were observed between the two regimes, revealing unexpected consequences of the presence of selection. Further mechanistic studies will be needed to elucidate the full properties of these differences

Smc5/6 Antagonism by HBx Is an Evolutionarily Conserved Function of Hepatitis B Virus Infection in Mammals

Chronic infection with hepatitis B virus (HBV) is a major cause of liver disease and cancer in humans. HBVs (family Hepadnaviridae) have been associated with mammals for millions of years. Recently, the Smc5/6 complex, known for its essential housekeeping functions in genome maintenance, was identified as an antiviral restriction factor of human HBV. The virus has, however, evolved to counteract this defense mechanism by degrading the complex via its regulatory HBx protein. Whether the antiviral activity of the Smc5/6 complex against hepadnaviruses is an important and evolutionarily conserved function is unknown. In this study, we used an evolutionary and functional approach to address this question. We first performed phylogenetic and positive selection analyses of the Smc5/6 complex subunits and found that they have been conserved in primates and mammals. Yet, Smc6 showed marks of adaptive evolution, potentially reminiscent of a virus-host "arms race." We then functionally tested the HBx proteins from six divergent hepadnaviruses naturally infecting primates, rodents, and bats. We demonstrate that despite little sequence homology, these HBx proteins efficiently degraded mammalian Smc5/6 complexes, independently of the host species and of the sites under positive selection. Importantly, all HBx proteins also rescued the replication of an HBx-deficient HBV in primary human hepatocytes. These findings point to an evolutionarily conserved requirement for Smc5/6 inactivation by HBx, showing that Smc5/6 antiviral activity has been an important defense mechanism against hepadnaviruses in mammals. It will be interesting to investigate whether Smc5/6 may further be a restriction factor of other, yet-unidentified viruses that may have driven some of its adaptation.IMPORTANCE Infection with hepatitis B virus (HBV) led to 887,000 human deaths in 2015. HBV has been coevolving with mammals for millions of years. Recently, the Smc5/6 complex, which has essential housekeeping functions, was identified as a restriction factor of human HBV antagonized by the regulatory HBx protein. Here we address whether the antiviral activity of Smc5/6 is an important evolutionarily conserved function. We found that all six subunits of Smc5/6 have been conserved in primates, with only Smc6 showing signatures of an "evolutionary arms race." Using evolution-guided functional analyses that included infections of primary human hepatocytes, we demonstrated that HBx proteins from very divergent mammalian HBVs could all efficiently antagonize Smc5/6, independently of the host species and sites under positive selection. These findings show that Smc5/6 antiviral activity against HBV is an important function in mammals. They also raise the intriguing possibility that Smc5/6 may restrict other, yet-unidentified viruses

Additional file 27: of The complex pattern of epigenomic variation between natural yeast strains at single-nucleosome resolution

Similar co-variation of histone marks at isolated vs. regional SNEPs. H3K4me3 SNEPs were termed ‘isolated’ when both flanking nucleosomes did not contain an H3K4me3 SNEP. All others were termed ‘regional’. The same definition was applied to SNEPs of other marks. On each set of nucleosomes (those corresponding to regional and those corresponding to isolated SNEPs for mark (1)), co-variation was quantified as in Fig. 8C, by computing the fraction of BY–RM isolated or regional SNEPs of mark (1) that showed synergistic and significant BY–RM differences in mark (2)