Generation of remosomes by the SWI/SNF chromatin remodeler family

International audienceChromatin remodelers are complexes able to both alter histone-DNA interactions and to mobilize nucleosomes. The mechanism of their action and the conformation of remodeled nucleosomes remain a matter of debates. In this work we compared the type and structure of the products of nucleosome remodeling by SWI/SNF and ACF complexes using high-resolution microscopy combined with novel biochemical approaches. We find that SWI/SNF generates a multitude of nucleosome-like metastable particles termed "remosomes". Restriction enzyme accessibility assay, DNase I footprinting and AFM experiments reveal perturbed histone-DNA interactions within these particles. Electron cryo-microscopy shows that remosomes adopt a variety of different structures with variable irregular DNA path, similar to those described upon RSC remodeling. Remosome DNA accessibility to restriction enzymes is also markedly increased. We suggest that the generation of remosomes is a common feature of the SWI/SNF family remodelers. In contrast, the ACF remodeler, belonging to ISWI family, only produces repositioned nucleosomes and no evidence for particles associated with extra DNA, or perturbed DNA paths was found. The remosome generation by the SWI/SNF type of remodelers may represent a novel mechanism involved in processes where nucleosomal DNA accessibility is required, such as DNA repair or transcription regulation

Epigenetic function of the amino-terminal domain of CENP-A during mitosis

Le variant d’histone CENP-A marque épigénétiquement le centromère. La présence de CENP-A au centromère permet le recrutement de protéines centromériques qui constituent la plateforme pour l’assemblage de kinétochores fonctionnels.Dans les cellules humaines, l'extrémité amino-terminale de CENP-A ainsi que la phosphorylation de la sérine 7, ont été signalées comme étant cruciales pour la progression de la mitose. Cependant, aucune phosphorylation de CENP-A dans d'autres espèces de métazoaires n'a été décrite. Ici, nous montrons que le domaine NH2-terminal CENP-A, mais pas sa séquence primaire, est nécessaire pour la mitose dans les fibroblastes embryonnaires de souris (MEFs). Nos données montrent que les défauts mitotiques résultant de la déplétion de CENP-A endogène peuvent être restaurés lorsque les MEFs expriment un mutant GFP-CENP-A dont l'extrémité NH2-terminal de CENP-A a été échangée par la queue phosphorylable de l'histone canonique H3. Inversement, dans ce même mutant, lorsque l’on remplace les deux serines phosphorylables par des résidus alanines, les défauts mitotiques persistent. En outre, le mutant de fusion non- phosphorylable de CENP-A, où les sept serines du domaine NH2-terminal ont été remplacées par des résidus alanines, a été également incapable de restaurer le phénotype mitotique des cellules déplétées en CENP-A endogène.Nous avons également identifié les trois premières sérines de la queue de CENP-A comme sites potentiels de phosphorylation. De plus, nos résultats montrent que l’absence de phosphorylation du domaine amino-terminal conduit à la délocalisation de la protéine centromérique CENP-C. Ces résultats suggèrent que la phosphorylation mitotique de CENP-A est un événement potentiellement fréquent chez les métazoaires et essentiel à la progression mitotique.Dans la seconde partie de ce travail, nous avons voulu lier sans ambiguïté la fonction du domaine NH2-terminal du CENP-A à la mitose. Nous avons conçu une nouvelle méthode, appelée approche Hara-kiri, pour pouvoir éliminer le domaine NH2- terminal seulement pendant la mitose. Ceci afin de répondre à la question ci-dessus dans les cellules humaines. L'élimination du domaine NH2-terminal du CENP-A en utilisant l'approche Hara-kiri en début de mitose a conduit à une augmentation des défauts mitotiques dans les cellules. Prises collectivement, ces données montrent que le domaine NH2-terminal CENP-A est nécessaire pendant la mitose afin d’assurer le bon déroulement de la division cellulaire.The histone variant CENP-A epigenetically marks the centromere. The presence of CENP-A at the centromeres allows the recruitment of centromeric proteins that constitute the platform for functional kinetochores.In human cells, the NH2-terminus of CENP-A and its phosphorylation at serine 7 in mitosis has been reported to be crucial for the progression of mitosis. However, no phosphorylation of CENP-A in other metazoan species has been described. Here, we show that the NH2-terminus of CENP-A, but not its primary sequence, is required for mitosis in mouse embryonic cells (MEFs). Our data show that the mitotic defects resulting from the depletion of the endogenous CENP-A can be rescued when MEFs expressing a GFP- CENP-A mutant where the NH2-terminus of CENP-A was swapped with the phosphorylatable tail of conventional histone H3. Conversely, no rescue was observed when the two phosphorylatable serines in the H3 tail mutant were replaced with alanines. Furthermore, a non-phosphorylatable fusion mutant of CENP-A where all seven serines in the amino-tail were replaced with alanines, was also unable to rescue the mitotic phenotype of CENP-A depleted cells.We also identified that the first three serines of the tail of CENP-A as potential sites for phosphorylation. Additionally, we were able to link the phosphorylation of CENP-A amino-tail to the proper localization of the key centromeric protein CENP-C. These results suggest that mitotic CENP-A phosphorylation is a potentially common event in metazoans essential for mitotic progression.In the second par of this work we wanted to unambiguously tie the NH2-terminus function of CENP-A to mitosis. To achieve this, we wanted to remove the CENP-A amino-tail only during mitosis and we devised a new method called the Hara-kiri approach in order to answer the above question in human cells. The removal of the NH2-terminal domain of CENP-A using the Hara-kiri approach at the onset of mitosis led to increased mitotic defects in cells. Taken collectively these data show that the CENP-A NH2- terminus is required during mitosis to assure proper cell division

Etude des fonctions du domaine amino-terminal de CENP-A pendant la mitose

The histone variant CENP-A epigenetically marks the centromere. The presence of CENP-A at the centromeres allows the recruitment of centromeric proteins that constitute the platform for functional kinetochores.In human cells, the NH2-terminus of CENP-A and its phosphorylation at serine 7 in mitosis has been reported to be crucial for the progression of mitosis. However, no phosphorylation of CENP-A in other metazoan species has been described. Here, we show that the NH2-terminus of CENP-A, but not its primary sequence, is required for mitosis in mouse embryonic cells (MEFs). Our data show that the mitotic defects resulting from the depletion of the endogenous CENP-A can be rescued when MEFs expressing a GFP- CENP-A mutant where the NH2-terminus of CENP-A was swapped with the phosphorylatable tail of conventional histone H3. Conversely, no rescue was observed when the two phosphorylatable serines in the H3 tail mutant were replaced with alanines. Furthermore, a non-phosphorylatable fusion mutant of CENP-A where all seven serines in the amino-tail were replaced with alanines, was also unable to rescue the mitotic phenotype of CENP-A depleted cells.We also identified that the first three serines of the tail of CENP-A as potential sites for phosphorylation. Additionally, we were able to link the phosphorylation of CENP-A amino-tail to the proper localization of the key centromeric protein CENP-C. These results suggest that mitotic CENP-A phosphorylation is a potentially common event in metazoans essential for mitotic progression.In the second par of this work we wanted to unambiguously tie the NH2-terminus function of CENP-A to mitosis. To achieve this, we wanted to remove the CENP-A amino-tail only during mitosis and we devised a new method called the Hara-kiri approach in order to answer the above question in human cells. The removal of the NH2-terminal domain of CENP-A using the Hara-kiri approach at the onset of mitosis led to increased mitotic defects in cells. Taken collectively these data show that the CENP-A NH2- terminus is required during mitosis to assure proper cell division.Le variant d’histone CENP-A marque épigénétiquement le centromère. La présence de CENP-A au centromère permet le recrutement de protéines centromériques qui constituent la plateforme pour l’assemblage de kinétochores fonctionnels.Dans les cellules humaines, l'extrémité amino-terminale de CENP-A ainsi que la phosphorylation de la sérine 7, ont été signalées comme étant cruciales pour la progression de la mitose. Cependant, aucune phosphorylation de CENP-A dans d'autres espèces de métazoaires n'a été décrite. Ici, nous montrons que le domaine NH2-terminal CENP-A, mais pas sa séquence primaire, est nécessaire pour la mitose dans les fibroblastes embryonnaires de souris (MEFs). Nos données montrent que les défauts mitotiques résultant de la déplétion de CENP-A endogène peuvent être restaurés lorsque les MEFs expriment un mutant GFP-CENP-A dont l'extrémité NH2-terminal de CENP-A a été échangée par la queue phosphorylable de l'histone canonique H3. Inversement, dans ce même mutant, lorsque l’on remplace les deux serines phosphorylables par des résidus alanines, les défauts mitotiques persistent. En outre, le mutant de fusion non- phosphorylable de CENP-A, où les sept serines du domaine NH2-terminal ont été remplacées par des résidus alanines, a été également incapable de restaurer le phénotype mitotique des cellules déplétées en CENP-A endogène.Nous avons également identifié les trois premières sérines de la queue de CENP-A comme sites potentiels de phosphorylation. De plus, nos résultats montrent que l’absence de phosphorylation du domaine amino-terminal conduit à la délocalisation de la protéine centromérique CENP-C. Ces résultats suggèrent que la phosphorylation mitotique de CENP-A est un événement potentiellement fréquent chez les métazoaires et essentiel à la progression mitotique.Dans la seconde partie de ce travail, nous avons voulu lier sans ambiguïté la fonction du domaine NH2-terminal du CENP-A à la mitose. Nous avons conçu une nouvelle méthode, appelée approche Hara-kiri, pour pouvoir éliminer le domaine NH2- terminal seulement pendant la mitose. Ceci afin de répondre à la question ci-dessus dans les cellules humaines. L'élimination du domaine NH2-terminal du CENP-A en utilisant l'approche Hara-kiri en début de mitose a conduit à une augmentation des défauts mitotiques dans les cellules. Prises collectivement, ces données montrent que le domaine NH2-terminal CENP-A est nécessaire pendant la mitose afin d’assurer le bon déroulement de la division cellulaire

Histone H3.3 regulates mitotic progression in mouse embryonic fibroblasts

H3.3 is a histone variant, which marks transcription start sites as well as telomeres and heterochromatic sites on the genome. H3.3 presence is thought to positively correlate with transcriptional status of its target genes. Using a conditional genetic strategy against H3.3B combined with short hairpin RNAs against H3.3A, we essentially depleted all H3.3 gene expression in mouse embryonic fibroblasts. Following nearly complete loss of H3.3 in cells, our transcriptomic analyses show very little impact on global gene expression as well as on histone variant H2A.Z localization. Instead, fibroblasts display slower cell growth and an increase in cell death coincident with large-scale chromosome misalignment in mitosis and large polylobed or micronuclei in interphase cells. Thus we conclude that H3.3 may additionally have an important under-explored role in chromosome segregation, nuclear structure and maintenance of genome integrity.The accepted manuscript in pdf format is listed with the files at the bottom of this page. The presentation of the authors' names and (or) special characters in the title of the manuscript may differ slightly between what is listed on this page and what is listed in the pdf file of the accepted manuscript; that in the pdf file of the accepted manuscript is what was submitted by the author

H2A.Z is dispensable for both basal and activated transcription in post-mitotic mouse muscles

International audienceWhile the histone variant H2A.Z is known to be required for mitosis, it is also enriched in nucleosomes surrounding the transcription start site of active promoters, implicating H2A.Z in transcription. However, evidence obtained so far mainly rely on correlational data generated in actively dividing cells. We have exploited a paradigm in which transcription is uncoupled from the cell cycle by developing an in vivo system to inactivate H2A.Z in terminally differentiated post-mitotic muscle cells. ChIP-seq, RNA-seq and ATAC-seq experiments performed on H2A.Z KO post-mitotic muscle cells show that this histone variant is neither required to maintain nor to activate transcription. Altogether, this study provides in vivo evidence that in the absence of mitosis H2A.Z is dispensable for transcription and that the enrichment of H2A.Z on active promoters is a marker but not an active driver of transcription

H1–nucleosome interactions and their functional implications

International audienc