Project description:A multitude of histone chaperones is required to protect histones from their biosynthesis to DNA deposition. They cooperate through the formation of co-chaperone complexes, but the crosstalk between nucleosome assembly pathways is unclear. Using explorative interactomics approaches, we map the organization of the histone H3-H4 chaperones network and define the interplay between histone chaperones systems. We identify and validate a panel of novel histone (PTM) dependent complexes. We show DAXX acts separately from the rest of the network, recruiting heterochromatin factors and promoting lysine 9 tri-methylated new histone H3.3 prior to deposition onto DNA. With its functionality, DAXX provides a molecular mechanism for de novo heterochromatin assembly.

Project description:Histone octamers are thought to be a rigid part of nucleosomes that shape chromatin and block cellular machinery from accessing DNA. ATP-dependent chromatin remodelers like ISW2 mobilize nucleosomes to provide DNA access. We find evidence for histone octamer distortion preceding DNA being moved into nucleosomes and processive movement of the ATPase motor of ISW2 on nucleosomal DNA. DNA entering nucleosome is uncoupled from the ATPase activity of ISW2 and alterations of the histone octamer structure mediated by ISW2 by deletion of the SANT domain from the C-terminus of the Isw2 catalytic subunit. We also find that restricting histone movement by chemical crosslinking traps remodeling intermediates resembling those seen by loss of the SANT domain, further supporting the importance of changes in histone octamer structure early in ISW2 remodeling. Transient octamer distortions are stabilized by H3-H4 tetramer disulfide crosslinking, thereby linking intrinsic histone octamer flexibility to chromatin remodeling.

Project description:Nucleosomes are the building blocks of chromatin where gene regulation takes place. Chromatin landscapes have been profiled for several species, providing insights into the understanding of fundamental mechanisms of chromatin-mediated transcriptional regulation of gene expression. However, knowledge is missing from several major and deep-branching eukaryotic groups, such as the marine model diatom Phaeodactylum tricornutum. Diatoms are highly diverse and ubiquitous species of phytoplankton that play a key role in global biogeochemical cycles. Dissecting chromatin-mediated regulation of genes in diatoms will help understand the ecological success of these organisms in contemporary oceans. Here, we use high resolution mass spectrometry to identify a full repertoire of post-translational modifications on P. tricornutum histones, including eight novel modifications. We map five histone marks coupled with expression data and show that P. tricornutum displays both unique and broadly conserved chromatin features, reflecting the chimeric nature of its genome. Combinatorial analysis of histone marks and DNA methylation demonstrates the presence of an epigenetic code defining active or repressive chromatin states. We further profile three specific histone marks under conditions of nitrate depletion and show that the histone code is dynamic and targets specific sets of genes. This study is the first genome-wide characterization of the histone code from a Stramenopile and a marine phytoplankton. The work represents an important initial step for understanding the evolutionary history of chromatin and how epigenetic modifications affect gene expression in response to environmental cues in marine environments.

Project description:Methylation of DNA at CpG dinucleotides represents one of the most important epigenetic mechanisms involved in the control of gene expression in vertebrate cells. In this report, we conducted high-throughput nucleosome reconstitution experiments on 572 KB of human DNA and 668 KB of mouse DNA that was unmethylated or methylated in order to investigate the effects of this epigenetic modification on the positioning and stability of nucleosomes. The DNA loci from both species contained the genes that encode the serum albumin family, the MYC protein, and the tumor suppressor p53. The results demonstrated that a small subset of nucleosomes positioned by nucleotide sequence was sensitive to methylation where the modification increased the affinity of these sequences for the histone octamer. The features that distinguished these nucleosomes from the bulk of the methylation-insensitive nucleosomes were an increase in the frequency of CpG dinucleotides and a unique rotational orientation of CpGs such that their minor grooves tended to face toward the histones in the nucleosome rather than away. We propose that these features serve to enhance the affinity of methylated DNA for the histone octamer and that this effect could be involved in gene regulatory mechanisms such as silencing. These methylation-sensitive nucleosomes were preferentially associated with exons as compared to introns while unmethylated CpG islands near transcription start sites became enriched in nucleosomes upon methylation. The results of this study suggest that the effects of DNA methylation on nucleosome stability in vitro can recapitulate what has been observed in the cell and provide a direct link between DNA methylation and the structure and function of chromatin. For the human data, there were 3 unmethylated nucleosome replicates, 2 methylated nucleosome replicates, an unmethylated MNase control, and an unmethylated sonicated control. For the mouse data, there were 2 unmethylated nucleosome replicates, 2 methylated nucleosome replicates, an unmethylated MNase control, a methylated MNase control, and an unmethylated sonicated control.

Project description:Histone deacetylase 1 (HDAC1) complexes regulate both histone acetylation and crotonylation in vivo

Project description:Mass spectrometry (MS) has become the technique of choice for large-scale analysis of histone post-translational modifications (hPTMs) and their combinatorial patterns, especially in untargeted settings where novel discovery-driven hypotheses are being generated. However, MS-based histone analysis requires a distinct sample preparation, acquisition and data analysis workflow when compared to traditional MS-based approaches. To this end, sequential window acquisition of all theoretical fragment ion spectra (SWATH) has great potential, as it allows for untargeted accurate identification and quantification of hPTMs. Here, we present a complete SWATH workflow specifically adapted for the untargeted study of histones (hSWATH). We assess its validity on a technical dataset of a time-lapse deacetylation of a commercial histone extract using HDAC1, which contains a ground truth, i.e. acetylated substrate peptides reduce in intensity. We successfully apply this workflow in a biological setting and subsequently investigate the differential response to HDAC inhibition in different breast cancer cell lines. 

Project description:Nucleosome consists of a histone octamer wrapped by 145 bps of DNA and serves as a fundamental unit of chromatin. The overlapping di-nucleosome (OLDN) is found as another chromatin unit, in which 250 bps of DNA continuously wraps around the intimately associated histone octamer-hexamer complex. In the present study, our genome-wide analysis found a higher nucleosome stacking structure, overlapping tri-nucleosome (OLTN), in which about 350 bps of DNA wrap around the histone octamer-hexamer-hexamer complex. We quantified the length of DNA associated with the 20-mer histone core, and also we found that the OLTN localizes downstream of the transcription start sites as well as the OLDN does. The results suggest that nucleosome stacking structures may be formed for gene regulation.

Project description:BAF and PBAF are mammalian SWI/SNF family chromatin remodeling complexes that possess multiple histone/DNA-binding subunits and create nucleosome-depleted/free regions for transcription activation. Despite previous structural studies and recent advance of SWI/SNF family complexes, it remains incompletely understood how PBAF-nucleosome complex is organized. Here we determined structure of 13-subunit human PBAF in complex with acetylated nucleosome in ADP-BeF3-bound state. Four PBAF-specific subunits work together with nine BAF/PBAF-shared subunits to generate PBAF-specific modular organization, distinct from that of BAF at various regions. PBAF-nucleosome structure reveals six histone-binding domains and four DNA-binding domains/modules, the majority of which directly bind histone/DNA. This multivalent nucleosome-binding pattern, not observed in previous studies, suggests that PBAF may integrate comprehensive chromatin information to target genomic loci for function. Our study reveals molecular organization of subunits and histone/DNA-binding domains/modules in PBAF-nucleosome complex and provides structural insights into PBAF-mediated nucleosome association complimentary to the recently reported PBAF-nucleosome structure.

Project description:Using acetylated histone H3 ChIP-seq, we reveal that the histone H3 acetylation level is gradually increased on the neural gene loci while decreased on the neural-inhibitory gene loci during mouse ESC neural differentiation. By overlapping with the targets of HDAC1 ChIP-seq, we identify Nodal as a target gene repressed by histone deacetylation. Thus, our study reveals an intrinsic mechanism that epigenetic histone deacetylation ensures neural fate commitment by restricting Nodal signaling. Examination of HDAC1 in differentiated day 2 cells and acetylated histone H3 in day 2, day 4 and day 6 cells.

Project description:Epigenetic states defined by chromatin can be maintained through mitotic cell division. However, it remains unknown how histone-based information is transmitted. Here we combine nascent chromatin capture (NCC) and triple-SILAC labelling to track histone modifications and histone variants during DNA replication and across the cell cycle. We show that post-translational modifications (PTMs) are transmitted with parental histones to newly replicated DNA. Di- and tri-methylation marks are diluted two-fold upon DNA replication, as a consequence of new histone deposition. Importantly, within one cell cycle all PTMs are restored. In general, new histones are modified to mirror the parental histones. However, H3K9me3 and H3K27me3 are propagated by continuous modification of parental and new histones, because the establishment of these marks extends over several cell generations. Together, our results reveal how histone marks propagate and demonstrate that chromatin states oscillate within the cell cycle.