Project description:Replication of the eukaryotic genome occurs in the context of chromatin, a nucleoprotein packaging state consisting of repeating nucleosomes. Chromatin is commonly thought to carry epigenetic information from one generation to the next, although it is unclear how such information survives the disruptions of nucleosomal architecture that occur during genomic replication. Here, we sought to directly measure a key aspect of chromatin structure dynamics during replication – how rapidly nucleosome positions are established on the newly-replicated daughter genomes. By isolating newly-synthesized DNA marked with the nucleotide analogue EdU, we characterize nucleosome positions on both daughter genomes of budding yeast during a time course of chromatin maturation. We find that nucleosomes rapidly adopt their mid log positions at highly-transcribed genes, and that this process was impaired upon treatment with the transcription inhibitor thiolutin, consistent with a role for transcription in positioning nucleosomes in vivo. Additionally, experiments in the Hir1Δ background reveal a role for HIR in nucleosome spacing. Using strand-specific EdU libraries, we characterize nucleosome positions on the leading and lagging strand daughter genomes, uncovering differences in chromatin maturation dynamics between the two daughter genomes at hundreds of genes. Our data define the maturation dynamics of newly-replicated chromatin, and support a role for transcription in sculpting the chromatin template. We have mapped changes in nucleosome positions on newly replicated DNA in a timecourse after genome replication. We have used Micrococcal Nuclease footprinting of cross linked chromatin to determine nucleosome positions and EdU (ethylene deoxy uridine) to mark nascent DNA strands. EdU incorporated into nascent DNA strands was biotinylated with Click chemistry and nascent DNA strand fragments were subsequently isolated using Streptavidin coated magnetic beads.

Project description:In the nucleus of the eukaryote cell, the genetic material is organized in the form of chromatin where DNA associates with nucleosomes, formed by an octamer of histone proteins, to provide the correct environment to regulate gene expression, maintain cellular identity and avoid disease. Despite the important role of chromatin organization in cellular function, in each cell division chromatin is totally disorganized. Nucleosomes are evicted ahead of the replication fork and will have to be recycled together with newly synthetized histones to maintain nucleosome density in the two daughter strands. This produce changes in chromatin accessibility and a dilution in epigenetic information. To date, it is not clear how these chromatin and epigenetic changes can affect gene expression. Here, we have used the cutting-edge technology ChOR-seq (Chromatin Occupancy after Replication and sequencing) and ChrRNA-seq (Chromatin-associated RNA-seq) to investigate the distribution and abundance of the RNA Polymerase II (RNAPII) in newly replicated chromatin and nascent RNA levels in human cells.

Project description:In the nucleus of the eukaryote cell, the genetic material is organized in the form of chromatin where DNA associates with nucleosomes, formed by an octamer of histone proteins, to provide the correct environment to regulate gene expression, maintain cellular identity and avoid disease. Despite the important role of chromatin organization in cellular function, in each cell division chromatin is totally disorganized. Nucleosomes are evicted ahead of the replication fork and will have to be recycled together with newly synthetized histones to maintain nucleosome density in the two daughter strands. This produce changes in chromatin accessibility and a dilution in epigenetic information. To date, it is not clear how these chromatin and epigenetic changes can affect gene expression. Here, we have used the cutting-edge technology ChOR-seq (Chromatin Occupancy after Replication and sequencing) and ChrRNA-seq (Chromatin-associated RNA-seq) to investigate the distribution and abundance of the RNA Polymerase II (RNAPII) in newly replicated chromatin and nascent RNA levels in human cells.

Project description:In the nucleus of the eukaryote cell, the genetic material is organized in the form of chromatin where DNA associates with nucleosomes, formed by an octamer of histone proteins, to provide the correct environment to regulate gene expression, maintain cellular identity and avoid disease. Despite the important role of chromatin organization in cellular function, in each cell division chromatin is totally disorganized. Nucleosomes are evicted ahead of the replication fork and will have to be recycled together with newly synthetized histones to maintain nucleosome density in the two daughter strands. This produce changes in chromatin accessibility and a dilution in epigenetic information. To date, it is not clear how these chromatin and epigenetic changes can affect gene expression. Here, we have used the cutting-edge technology ChOR-seq (Chromatin Occupancy after Replication and sequencing) and ChrRNA-seq (Chromatin-associated RNA-seq) to investigate the distribution and abundance of the RNA Polymerase II (RNAPII) in newly replicated chromatin and nascent RNA levels in human cells.

Project description:In the nucleus of the eukaryote cell, the genetic material is organized in the form of chromatin where DNA associates with nucleosomes, formed by an octamer of histone proteins, to provide the correct environment to regulate gene expression, maintain cellular identity and avoid disease. Despite the important role of chromatin organization in cellular function, in each cell division chromatin is totally disorganized. Nucleosomes are evicted ahead of the replication fork and will have to be recycled together with newly synthetized histones to maintain nucleosome density in the two daughter strands. This produce changes in chromatin accessibility and a dilution in epigenetic information. To date, it is not clear how these chromatin and epigenetic changes can affect gene expression. Here, we have used the cutting-edge technology ChOR-seq (Chromatin Occupancy after Replication and sequencing) and ChrRNA-seq (Chromatin-associated RNA-seq) to investigate the distribution and abundance of the RNA Polymerase II (RNAPII) in newly replicated chromatin and nascent RNA levels in human cells.

Project description:In the nucleus of the eukaryote cell, the genetic material is organized in the form of chromatin where DNA associates with nucleosomes, formed by an octamer of histone proteins, to provide the correct environment to regulate gene expression, maintain cellular identity and avoid disease. Despite the important role of chromatin organization in cellular function, in each cell division chromatin is totally disorganized. Nucleosomes are evicted ahead of the replication fork and will have to be recycled together with newly synthetized histones to maintain nucleosome density in the two daughter strands. This produce changes in chromatin accessibility and a dilution in epigenetic information. To date, it is not clear how these chromatin and epigenetic changes can affect gene expression. Here, we have used the cutting-edge technology ChOR-seq (Chromatin Occupancy after Replication and sequencing) and ChrRNA-seq (Chromatin-associated RNA-seq) to investigate the distribution and abundance of the RNA Polymerase II (RNAPII) in newly replicated chromatin and nascent RNA levels in human cells.

Project description:The higher-order structure of newly replicated (i.e. ‘nascent’) chromatin fibers remains poorly-resolved, limiting our understanding of how epigenomes are maintained across cell divisions. To address this, we present Replication-Aware Single-molecule Accessibility Mapping (RASAM), a long-read sequencing method that nondestructively measures genome-wide replication-status and protein-DNA interactions simultaneously on intact chromatin templates. We report that individual human and mouse nascent chromatin fibers are ‘hyperaccessible’ compared to steady-state chromatin. This hyperaccessibility occurs at two, coupled length-scales: first, individual nucleosome core particles on nascent DNA exist as a mixture of partially-unwrapped nucleosomes and other subnucleosomal species; second, newly-replicated chromatin fibers are significantly enriched for irregularly-spaced nucleosomes on individual DNA molecules. Focusing on specific cis-regulatory elements (e.g. transcription factor binding sites; active transcription start sites [TSSs]), we discover unique modes by which nascent chromatin hyperaccessibility is resolved at the single-molecule level: at CCCTC-binding factor (CTCF) binding sites, CTCF and nascent nucleosomes compete for motifs on nascent chromatin fibers, resulting in quantitatively-reduced CTCF occupancy and motif accessibility post-replication; at active TSSs, high levels of steady-state chromatin accessibility are preserved, implying that nucleosome free regions (NFRs) are rapidly re-established behind the fork. Our study introduces a new paradigm for studying higher-order chromatin fiber organization behind the replication fork. More broadly, we uncover a unique organization of newly replicated chromatin that must be reset by active processes, providing a substrate for epigenetic reprogramming.

Project description:Replication of the eukaryotic genome occurs in the context of chromatin, a nucleoprotein packaging state consisting of repeating nucleosomes. Chromatin is commonly thought to carry epigenetic information from one generation to the next, although it is unclear how such information survives the disruptions of nucleosomal architecture that occur during genomic replication. Here, we sought to directly measure a key aspect of chromatin structure dynamics during replication â?? how rapidly nucleosome positions are established on the newly-replicated daughter genomes. By isolating newly-synthesized DNA marked with the nucleotide analogue EdU, we characterize nucleosome positions on both daughter genomes of budding yeast during a time course of chromatin maturation. We find that nucleosomes rapidly adopt their mid log positions at highly-transcribed genes, and that this process was impaired upon treatment with the transcription inhibitor thiolutin, consistent with a role for transcription in positioning nucleosomes in vivo. Additionally, experiments in the Hir1-delta background reveal a role for HIR in nucleosome spacing. Using strand-specific EdU libraries, we characterize nucleosome positions on the leading and lagging strand daughter genomes, uncovering differences in chromatin maturation dynamics between the two daughter genomes at hundreds of genes. Our data define the maturation dynamics of newly-replicated chromatin, and support a role for transcription in sculpting the chromatin template. Gene expression array.

Project description:Dynamic disruption and reassembly of promoter-proximal nucleosomes is a conserved hallmark of transcriptionally active chromatin. Histone H3-K56 acetylation (H3K56Ac) enhances these turnover events and promotes nucleosome assembly during S phase. Here we sequence nascent transcripts to investigate the impact of H3K56Ac on transcription throughout the yeast cell cycle. Strikingly, we find that H3K56Ac is a genome-wide activator of transcription. H3K56Ac has a major impact on transcription initiation, but it also appears to promote elongation and/or termination. In contrast, H3K56Ac represses promiscuous transcription that occurs immediately following replication fork passage, in this case by promoting efficient nucleosome assembly. We also detect a stepwise increase in transcription as cells transit S phase and enter G2, but this response to increased gene dosage does not require H3K56Ac. Thus, a single histone mark can exert both positive and negative impacts on transcription that are coupled to different cell cycle events.

Project description:H3K56 acetylation regulates chromatin maturation following DNA replication