Contribution de l’épigénétique dans les Dauermodifikations et l’évolution adaptative chez le parasite humain Schistosoma mansoni et le corail tropical Pocillopora damicornis

The origin of phenotypic variability has been much debated since the establishment of Lamarck’s and Darwins theories of evolution. It is commonly accepted in the contemporary vision of adaptive evolution that the only source of heritable phenotypic variability is genetic. Here, phenotypes are the product of the genotypes under the influence of the environment. Random DNA mutations generate novel phenotypes, which are then subjected to natural selection. Traditionally, it is considered that acquired characters are not heritable and have no impact on evolution. Yet almost a century ago, a German biologist named Victor Jollos revealed that some phenotypes could be produced in particular environmental conditions and could persist for a few generations in the absence of the original stimulus, before disappearing gradually. He named this phenomenon Dauermodifikations, literally “long term changes”. His conclusions were going against evolutionary conceptions of his time, and were considered experimental artefacts. However, we are now aware that, in addition to the genetic code, there is also another heritable, and yet flexible, mechanism responding to environmental fluctuations: the epigenetic code. In this thesis, I attempted to characterize the role of epigenetic mechanisms, and more specifically modifications of the chromatin structure, in two organisms with Dauermodifikations: the tropical coral Pocillopora damicornis and the human parasite Schistosoma mansoni. The two main objectives of this study were (I) to determine how the environment influences the chromatin structure (in a targeted or random fashion) and (II) to what extent these changes are heritable (through mitosis or meiosis).My results provide a better knowledge of the epigenome of the two organisms we studied. We have described the chromatin structure of S. mansoni through the distribution of six histones modifications, in two developmental stages. Furthermore, we have shown three types of changes in chromatin structure of S. mansoni: (I) targeted in response to environmental changes, (II) genotype associated, and (III) random. Only types II and III are inherited to the next developmental stages of the parasite. Our work on P. damicornis delivers evidence for an unusual chromatin structure in this organism and to provide the first description of a coral methylomeL’origine de la variabilité phénotypique est un sujet très débattu depuis les théories de Lamarck et Darwin. Dans la vision contemporaine de l’évolution adaptative, il est communément admis que la seule source héritable de variabilité phénotypique soit d’origine génétique. Le phénotype est alors le produit du génotype sous l’influence de l’environnement. La mutation aléatoire des séquences d’ADN permet de générer de nouveaux variants phénotypiques qui sont alors soumis à la sélection naturelle. Traditionnellement, il est considéré que les caractères acquis par un individu durant sa vie, en réponse à l’environnement, ne sont pas héritables et ne jouent aucun rôle évolutif. Pourtant, il y a presque un siècle, un biologiste allemand du nom de Victor Jollos a mis en évidence que certains phénotypes peuvent être induits par des conditions environnementales particulières et persister durant quelques générations en l’absence du stimulus initial avant de disparaître progressivement. Il nomma ce phénomène Dauermodifikations, littéralement « modifications de longue durée ». Ses conclusions allaient à contre-courant des conceptions évolutives de son temps, et ont été considérées comme des artéfacts expérimentaux. Toutefois, nous sommes maintenant conscient qu’outre le code génétique, il existe également un autre mécanisme permettant une réponse héritable et pourtant flexible en réponse aux fluctuations environnementales : le code épigénétique. Au cours de cette thèse, j’ai essayé de mieux caractériser le rôle des mécanismes épigénétiques, plus précisément ceux impliques dans la structure chromatinienne, chez deux organismes présentant des Dauermodifikations : le corail tropical Pocillopora damicornis et le parasite humain Schistosoma mansoni. Les deux objectifs principaux de cette étude sont de déterminer (I) de quelle manière l’environnement influence la structure chromatinienne (ciblée ou aléatoire) et (II) dans quelle mesure ces changements sont-ils héritables (mitotiquement ou méïotiquement).Nos résultats ont permis de mieux caractériser les épigénomes des deux organismes étudiés. Nous avons décrit la structure chromatinienne de S. mansoni au travers de la distribution de six modifications d’histones, sur deux stades développementaux. Par ailleurs, nous avons montré chez S. mansoni trois types de changements de la structure chromatinienne : (I) ciblés en réponse à l’environnement, (II) associés au génotype et (III) aléatoires. Seuls les types II et III sont héritables d’un stade développemental du parasite à un autre. Nos travaux sur P. damicornis ont permis de remarquer une structure chromatinienne inhabituelle et d’offrir une première description d’un méthylome de corail

Exposure to hycanthone alters chromatin structure around specific gene functions and specific repeats in Schistosoma mansoni.

International audienceSchistosoma mansoni is a parasitic plathyhelminth responsible for intestinal schistosomiasis (or bilharzia), a disease affecting 67 million people worldwide and causing an important economic burden. The schistosomicides hycanthone, and its later proxy oxamniquine, were widely used for treatments in endemic areas during the twentieth century. Recently, the mechanism of action, as well as the genetic origin of a stably and Mendelian inherited resistance for both drugs was elucidated in two strains. However, several observations suggested early on that alternative mechanisms might exist, by which resistance could be induced for these two drugs in sensitive lines of schistosomes. This induced resistance appeared rapidly, within the first generation, but was metastable (not stably inherited). Epigenetic inheritance could explain such a phenomenon and we therefore re-analyzed the historical data with our current knowledge of epigenetics. In addition, we performed new experiments such as ChIP-seq on hycanthone treated worms. We found distinct chromatin structure changes between sensitive worms and induced resistant worms from the same strain. No specific pathway was discovered, but genes in which chromatin structure modifications were observed are mostly associated with transport and catabolism, which makes sense in the context of the elimination of the drug. Specific differences were observed in the repetitive compartment of the genome. We finally describe what types of experiments are needed to understand the complexity of heritability that can be based on genetic and/or epigenetic mechanisms for drug resistance in schistosome

Methylome evolution in plants

Despite major progress in dissecting the molecular pathways that control DNA methylation patterns in plants, little is known about the mechanisms that shape plant methylomes over evolutionary time. Drawing on recent intra- and interspecific epigenomic studies, we show that methylome evolution over long timescales is largely a byproduct of genomic changes. By contrast, methylome evolution over short timescales appears to be driven mainly by spontaneous epimutational events. We argue that novel methods based on analyses of the methylation site frequency spectrum (mSFS) of natural populations can provide deeper insights into the evolutionary forces that act at each timescale

Erratum to:Methylome Evolution in plants

Erratum After publication of this article [1] we noticed that the centromere of Chromosome 3 was missing from Fig. 4a, and that the Fig. 4e y-axis should read ‘CG meth. Div. W-Acc.’. The y-axis of the barplot in Fig. 5a should read ‘Number of cytosines’. The corrected Figs. 4 and 5 are shown below

Histone methylation changes are required for life cycle progression in the human parasite Schistosoma mansoni

Epigenetic mechanisms and chromatin structure play an important role in development. Their impact is therefore expected to be strong in parasites with complex life cycles and multiple, strikingly different, developmental stages, i.e. developmental plasticity. Some studies have already described how the chromatin structure, through histone modifications, varies from a developmental stage to another in a few unicellular parasites. However, this, to our knowledge, has never been done before in multicellular metazoan parasites. We used chromatin immunoprecipitation followed by massively parallel sequencing (ChIPSeq) to characterize the profile of two histone post-translational modifications (trimethylation on lysine 4 of histone H3, H3K4me3, and trimethylation on lysine 27 of histone H3 H3K27me3) over five developmental stages (miracidium, primary sporocyst, cercaria, schistosomulum, adult) of the human blood fluke Schistosoma mansoni. While H3K4me3 profiles remain relatively constant, H3K27 trimethylation and bivalent methylation show strong variation. Inhibitors (A366 and GSK343) of H3K27 histone methyltransferase activity in S. mansoni efficiently blocked miracidium to sporocyst transition indicating that H3K27 trimethylation is required for life cycle progression. As S. mansoni is a multicellular parasite that significantly affects both the health and economy of endemic areas, a better understanding of fluke developmental processes within the definitive host will likely highlight novel disease control strategies. Towards this goal, we also studied H4K20me1 in female cercariae and adults. In particular, we found that bivalent trimethylation of H3K4 and H3K27 at the transcription start site of genes is a landmark of the cercarial stage. In cercariae, H3K27me3 presence and strong enrichment in H4K20me1 over long regions (10?100 kb) is associated with development related genes. Here, we provide a broad overview of the chromatin structure of a metazoan parasite throughout its most important lifecycle stages. The five developmental stages studied here present distinct chromatin structures, indicating that histone methylation plays an important role during development. Hence, components of the histone methylation (and demethylation) machinery may provide suitable Schistosomiasis control targets.publishersversionPeer reviewe

The Epigenome of Schistosoma mansoni Provides Insight about How Cercariae Poise Transcription until Infection

Background: Chromatin structure can control gene expression and can define specific transcription states. For example, bivalent methylation of histone H3K4 and H3K27 is linked to poised transcription in vertebrate embryonic stem cells (ESC). It allows them to rapidly engage specific developmental pathways. We reasoned that non-vertebrate metazoans that encounter a similar developmental constraint (i.e. to quickly start development into a new phenotype) might use a similar system. Schistosomes are parasitic platyhelminthes that are characterized by passage through two hosts: a mollusk as intermediate host and humans or rodents as definitive host. During its development, the parasite undergoes drastic changes, most notable immediately after infection of the definitive host, i.e. during the transition from the free-swimming cercariae into adult worms. Methodology/Principal Findings: We used Chromatin Immunoprecipitation followed by massive parallel sequencing (ChIP-Seq) to analyze genome-wide chromatin structure of S. mansoni on the level of histone modifications (H3K4me3, H3K27me3, H3K9me3, and H3K9ac) in cercariae, schistosomula and adults (available at http://genome.univ-perp.fr). We saw striking differences in chromatin structure between the developmental stages, but most importantly we found that cercariae possess a specific combination of marks at the transcription start sites (TSS) that has similarities to a structure found in ESC. We demonstrate that in cercariae no transcription occurs, and we provide evidences that cercariae do not possess large numbers of canonical stem cells. Conclusions/Significance: We describe here a broad view on the epigenome of a metazoan parasite. Most notably, we find bivalent histone H3 methylation in cercariae. Methylation of H3K27 is removed during transformation into schistosomula (and stays absent in adults) and transcription is activated. In addition, shifts of H3K9 methylation and acetylation occur towards upstream and downstream of the transcriptional start site (TSS). We conclude that specific H3 modifications are a phylogenetically older and probably more general mechanism, i.e. not restricted to stem cells, to poise transcription. Since adult couples must form to cause the disease symptoms, changes in histone modifications appear to be crucial for pathogenesis and represent therefore a therapeutic target. Author Summary: The blood fluke Schistosoma mansoni causes intestinal bilharzia. The parasite has a complex life cycle in which a freshwater snail serves as intermediate host from which the human infecting larvae hatch. These larvae will actively seek skin contact, penetrate through the epithelium and start developing straight away into adult worms. Development from larvae into adults needs thorough adjustment of gene expression through repositioning or modification of proteins that are associated with DNA (the chromatin). We decided to compare the chromatin of human infective larvae (cercariae), the first developmental stage after infection of the vertebrate host (schistosomula) and adults of S. mansoni. We found that cercariae possess chromatin structures (modifications of histone H3) around the beginning of genes that are very different from schistosomula and adults. We conclude that this structure serves to keep gene transcription in a poised state, i.e. transcription is initiated and can start immediately when the blocking histone modification is removed. A similar type of histone modification was found in embryonic stem cells of vertebrates and our data indicate that it is either a more ancient and/or more general means to poise transcription than previously assumed. Since many parasites possess infective stages that develop rapidly within the host, this particular chromatin structure could be a therapeutic target for a new class of antiparasitic drugs

Contribution of epigenetics in Dauermodifikations and adaptive evolution in the human parasite Schistosoma mansoni and the tropical coral Pocillopora damicornis

L’origine de la variabilité phénotypique est un sujet très débattu depuis les théories de Lamarck et Darwin. Dans la vision contemporaine de l’évolution adaptative, il est communément admis que la seule source héritable de variabilité phénotypique soit d’origine génétique. Le phénotype est alors le produit du génotype sous l’influence de l’environnement. La mutation aléatoire des séquences d’ADN permet de générer de nouveaux variants phénotypiques qui sont alors soumis à la sélection naturelle. Traditionnellement, il est considéré que les caractères acquis par un individu durant sa vie, en réponse à l’environnement, ne sont pas héritables et ne jouent aucun rôle évolutif. Pourtant, il y a presque un siècle, un biologiste allemand du nom de Victor Jollos a mis en évidence que certains phénotypes peuvent être induits par des conditions environnementales particulières et persister durant quelques générations en l’absence du stimulus initial avant de disparaître progressivement. Il nomma ce phénomène Dauermodifikations, littéralement « modifications de longue durée ». Ses conclusions allaient à contre-courant des conceptions évolutives de son temps, et ont été considérées comme des artéfacts expérimentaux. Toutefois, nous sommes maintenant conscient qu’outre le code génétique, il existe également un autre mécanisme permettant une réponse héritable et pourtant flexible en réponse aux fluctuations environnementales : le code épigénétique. Au cours de cette thèse, j’ai essayé de mieux caractériser le rôle des mécanismes épigénétiques, plus précisément ceux impliques dans la structure chromatinienne, chez deux organismes présentant des Dauermodifikations : le corail tropical Pocillopora damicornis et le parasite humain Schistosoma mansoni. Les deux objectifs principaux de cette étude sont de déterminer (I) de quelle manière l’environnement influence la structure chromatinienne (ciblée ou aléatoire) et (II) dans quelle mesure ces changements sont-ils héritables (mitotiquement ou méïotiquement).Nos résultats ont permis de mieux caractériser les épigénomes des deux organismes étudiés. Nous avons décrit la structure chromatinienne de S. mansoni au travers de la distribution de six modifications d’histones, sur deux stades développementaux. Par ailleurs, nous avons montré chez S. mansoni trois types de changements de la structure chromatinienne : (I) ciblés en réponse à l’environnement, (II) associés au génotype et (III) aléatoires. Seuls les types II et III sont héritables d’un stade développemental du parasite à un autre. Nos travaux sur P. damicornis ont permis de remarquer une structure chromatinienne inhabituelle et d’offrir une première description d’un méthylome de corail.The origin of phenotypic variability has been much debated since the establishment of Lamarck’s and Darwins theories of evolution. It is commonly accepted in the contemporary vision of adaptive evolution that the only source of heritable phenotypic variability is genetic. Here, phenotypes are the product of the genotypes under the influence of the environment. Random DNA mutations generate novel phenotypes, which are then subjected to natural selection. Traditionally, it is considered that acquired characters are not heritable and have no impact on evolution. Yet almost a century ago, a German biologist named Victor Jollos revealed that some phenotypes could be produced in particular environmental conditions and could persist for a few generations in the absence of the original stimulus, before disappearing gradually. He named this phenomenon Dauermodifikations, literally “long term changes”. His conclusions were going against evolutionary conceptions of his time, and were considered experimental artefacts. However, we are now aware that, in addition to the genetic code, there is also another heritable, and yet flexible, mechanism responding to environmental fluctuations: the epigenetic code. In this thesis, I attempted to characterize the role of epigenetic mechanisms, and more specifically modifications of the chromatin structure, in two organisms with Dauermodifikations: the tropical coral Pocillopora damicornis and the human parasite Schistosoma mansoni. The two main objectives of this study were (I) to determine how the environment influences the chromatin structure (in a targeted or random fashion) and (II) to what extent these changes are heritable (through mitosis or meiosis).My results provide a better knowledge of the epigenome of the two organisms we studied. We have described the chromatin structure of S. mansoni through the distribution of six histones modifications, in two developmental stages. Furthermore, we have shown three types of changes in chromatin structure of S. mansoni: (I) targeted in response to environmental changes, (II) genotype associated, and (III) random. Only types II and III are inherited to the next developmental stages of the parasite. Our work on P. damicornis delivers evidence for an unusual chromatin structure in this organism and to provide the first description of a coral methylom

DNA methylation dynamics during stress response in woodland strawberry ( Fragaria vesca )

Summary Environmental stresses can result in a wide range of physiological and molecular responses in plants. These responses can also impact epigenetic information in genomes, especially at the level of DNA methylation (5-methylcytosine). DNA methylation is the hallmark heritable epigenetic modification and plays a key role in silencing transposable elements (TEs). Although DNA methylation is an essential epigenetic mechanism, fundamental aspects of its contribution to stress responses and adaptation remain obscure. We investigated epigenome dynamics of wild strawberry (Fragaria vesca) in response to variable ecologically relevant environmental conditions at the DNA methylation level. F. vesca methylome responded with great plasticity to ecologically relevant abiotic and hormonal stresses. Thermal stress resulted in substantial genome-wide loss of DNA methylation. Notably, all tested stress conditions resulted in marked hot spots of differential DNA methylation near centromeric or pericentromeric regions, particularly in the non-symmetrical DNA methylation context. Additionally, we identified differentially methylated regions (DMRs) within promoter regions of transcription factor (TF) superfamilies involved in plant stress-response and assessed the effects of these changes on gene expression. These findings improve our understanding on stress-response at the epigenome level by highlighting the correlation between DNA methylation, TEs and gene expression regulation in plants subjected to a broad range of environmental stresses

The Complete Genome of the “Flavescence Dorée” Phytoplasma Reveals Characteristics of Low Genome Plasticity

Members of the genus ‘Candidatus Phytoplasma’ are obligate intracellular bacteria restricted to phloem sieve elements and are able to colonize several tissues and the hemolymph in their insect vectors. The current unfeasibility of axenic culture and the low complexity of genomic sequences are obstacles in assembling complete chromosomes. Here, a method combining pathogen DNA enrichment from infected insects and dual deep-sequencing technologies was used to obtain the complete genome of a phytoplasma causing Grapevine Flavescence dorée. The de novo assembly generated a circular chromosome of 654,223 bp containing 506 protein-coding genes. Quality assessment of the draft showed a high degree of completeness. Comparative analysis with other phytoplasmas revealed the absence of potential mobile units and a reduced amount of putative phage-derived segments, suggesting a low genome plasticity. Phylogenetic analyses identified Candidatus Phytoplasma ziziphi as the closest fully sequenced relative. The “Flavescence dorée” phytoplasma strain CH genome also encoded for several putative effector proteins potentially playing a role in pathogen virulence. The availability of this genome provides the basis for the study of the pathogenicity mechanisms and evolution of the Flavescence dorée phytoplasma