Project description:Acetylation of lysine residues in the tail domain of histone H3 at active regulatory elements are well characterised, but the less studied acetylations of histone globular domain lysines also hold regulatory potential based on their potential impact on nucleosome dynamics and stability. Here we have mapped the genome-wide distribution of acetylated H3 lysine 115 (H3K115ac), a residue on the lateral surface of the nucleosomes, in mouse embryonic stem cells. We find that H3K115ac is associated with highly active promoters, especially those associated with CpG islands, and with enhancers. H3K115ac is dynamic, changing in line with gene activation during differentiation and correlated with changes in local chromatin accessibilityas assyed by ATAC-seq. Distinct from other commony studied histone acetylation marks, H3K115ac is enriched on non-canonical “fragile” nucleosomes precisely at the transcription start sites of active gene promoters and within the binding sites of pluripotency transcription factors. Surprisingly we also detect H3K115ac-marked fragile nucleosomes at sites most strongly occupied by CTCF, within the CTCF footprint and oriented relative to the CTCF motif. This unique enrichment and genomic distribution of modified fragile nucleosomes suggests a previously unappreciated role for H3K115ac in gene regulation and chromatin structure. We propose that H3K115ac is a very precise marker for identifying regulatory elements in mammalian genomes.

Project description:Acetylation of lysine residues in the tail domain of histone H3 at active regulatory elements are well characterised, but the less studied acetylations of histone globular domain lysines also hold regulatory potential based on their potential impact on nucleosome dynamics and stability. Here we have mapped the genome-wide distribution of acetylated H3 lysine 115 (H3K115ac), a residue on the lateral surface of the nucleosomes, in mouse embryonic stem cells. We find that H3K115ac is associated with highly active promoters, especially those associated with CpG islands, and with enhancers. H3K115ac is dynamic, changing in line with gene activation during differentiation and correlated with changes in local chromatin accessibilityas assyed by ATAC-seq. Distinct from other commony studied histone acetylation marks, H3K115ac is enriched on non-canonical “fragile” nucleosomes precisely at the transcription start sites of active gene promoters and within the binding sites of pluripotency transcription factors. Surprisingly we also detect H3K115ac-marked fragile nucleosomes at sites most strongly occupied by CTCF, within the CTCF footprint and oriented relative to the CTCF motif. This unique enrichment and genomic distribution of modified fragile nucleosomes suggests a previously unappreciated role for H3K115ac in gene regulation and chromatin structure. We propose that H3K115ac is a very precise marker for identifying regulatory elements in mammalian genomes.

Project description:Acetylation of lysine residues in the tail domain of histone H3 at active regulatory elements are well characterised, but the less studied acetylations of histone globular domain lysines also hold regulatory potential based on their potential impact on nucleosome dynamics and stability. Here we have mapped the genome-wide distribution of acetylated H3 lysine 115 (H3K115ac), a residue on the lateral surface of the nucleosomes, in mouse embryonic stem cells. We find that H3K115ac is associated with highly active promoters, especially those associated with CpG islands, and with enhancers. H3K115ac is dynamic, changing in line with gene activation during differentiation and correlated with changes in local chromatin accessibilityas assyed by ATAC-seq. Distinct from other commony studied histone acetylation marks, H3K115ac is enriched on non-canonical “fragile” nucleosomes precisely at the transcription start sites of active gene promoters and within the binding sites of pluripotency transcription factors. Surprisingly we also detect H3K115ac-marked fragile nucleosomes at sites most strongly occupied by CTCF, within the CTCF footprint and oriented relative to the CTCF motif. This unique enrichment and genomic distribution of modified fragile nucleosomes suggests a previously unappreciated role for H3K115ac in gene regulation and chromatin structure. We propose that H3K115ac is a very precise marker for identifying regulatory elements in mammalian genomes.

Project description:H3K115 marks fragile nucleosomes at regulatory sites

Project description:H3K115 marks fragile nucleosomes at regulatory sites [ATAC-seq]

Project description:H3K115 marks fragile nucleosomes at regulatory sites [ChIP-seq]

Project description:H3K115 marks fragile nucleosomes at regulatory sites (Sucrose Gradient fractions rep1)

Project description:H3K115 marks fragile nucleosomes at regulatory sites (Sucrose Gradient fractions rep2)

Project description:Insulators are DNA elements, which prevent inappropriate interactions between the neighboring regions of the genome. They can be functionally classified as either enhancer blockers or domain barriers. CTCF (CCCTC binding factor) is the only known major insulator binding protein in the vertebrates and has been shown to bind many enhancer-blocking elements. However, it is not clear whether it plays a role in chromatin domain barriers between active and repressive domains. Here, we used ChIP-Seq to map the genome-wide binding sites of CTCF in three cell types and identified significant binding of CTCF to the boundaries of repressive chromatin domains marked by H3K27me3. Although we find an extensive overlapping of CTCF binding sites across the three cell types, its association with the domain boundaries is cell type-specific. We further show that the nucleosomes flanking CTCF binding sites are well positioned and associated with histone H2AK5 acetylation (H2AK5ac). Interestingly, we found a complementary pattern between the repressive H3K27me3 and the active H2AK5ac regions, which are separated by CTCF. Our findings indicate that CTCF may play important roles in the barrier activity of insulators and provide a resource for further investigation of the CTCF function in organizing chromatin in the human genome. Examination of the role of CTCF in chromatin domain barrier function In addition to the ChIP-seq analysis, two replicates of HeLa expression data were studied.

Project description:ChIPseq data for 31 CLL samples (12 controls, 19 tumor) of the CancerEpiSys-PRECiSe project; containing histone H3, histone modifications and transcription factor binding sites (CTCF, EBF1).