Project description:Goal of this project was the identification of chromatin interacting proteins whose binding is differentially regulated by di-methylation of lysine 20 on histone H4 (H4K20me2). To achieve this unodified and H4K20me2-modified histone H4 were generated by native chemical ligation and assembled into recombinant di-nucleosomes. The di-nucleosomes were immobilized on streptavidin-coated beads via the biotinylated di-nucleosomal DNA and used for nucleosome affinity purifications to identify proteins regulated by H4K20me2 from SILAC-labelled HeLaS3 nuclear extracts (Arg10 and Lys8). SILAC affinity purifications were carried out in "forward" (heavy extract on modified nucleosome and light extract on unmodified nucleosome) and "reverse" (light extract on modified nucleosome and heavy extract on unmodified nucleosome) label-swap experiments and protein abundances were quantified by MaxQuant.

Project description:Here we investigated the stability of nucleosomal modifications during pull-down affinity purification with HeLa nuclear extracts. Unmodified di-nucleosomes and di-nucleosomes decorated with H3K4me3K9acK14acK18acK23acK27ac, H4K5acK8acK12acK16acK20me2 and incorporating histone variant H2A.Z were incubated with HeLa nuclear extract or buffer alone for 4 hours at 4 degrees Celsius. The relative abundances of nucleosomal modifications were quantified using LC-MS.

Project description:Characteristic features of chromatin states are not limited to particular epigenetic modifications but include other regulatory cues, such as linker DNA length, typically ranging from around 35-55 bp in most eu- and heterochromatin domains (Valouev et al, 2011; Voong et al., 2016, Cell) to over 200 bp in nucleosome-depleted regions (NDRs) found at active enhancers and promoters (Schones et al, 2008; Hansen He et al, 2010). To investigate whether and how the nucleosome linker DNA affects chromatin recognition by nuclear proteins we performed a set of affinity purifications using di-nucleosomes incorporating different DNA linkers. Here, we investigated the effect of a 200 bp di-nucleosome linker DNA represented by scrambled DNA or SV40 promoter DNA sequence on the nuclear protein binding to di-nucleosome decorated with promoter-associated modifications, including H3K4me3K9acK14acK18acK23acK27ac, H4K5acK8acK12acK16acK20me2 and histone variant H2A.Z Below is a description (modifications and linker) of di-nucleosomes used in pull-downs with HeLa nuclear extracts followed by label-free MS: 1. H3K4me3-5ac,H4K20me2-4ac, H2AZ, 50bp linker 2. H3K4me3-5ac,H4K20me2-4ac, H2AZ, 200bp scrambled DNA linker 3. H3K4me3-5ac,H4K20me2-4ac, H2AZ, 200bp SV40 promoter DNA linker 4. Unmod. H3&H4, 50bp linker 5. Unmod. H3&H4, 200bp scrambled DNA linker 6. Unmod. H3&H4, 200bp SV40 promoter DNA linker

Project description:Characteristic features of chromatin states are not limited to particular epigenetic modifications but include other regulatory cues, such as linker DNA length, typically ranging from around 35-55 bp in most eu- and heterochromatin domains (Valouev et al, 2011; Voong et al., 2016, Cell) to over 200 bp in nucleosome-depleted regions (NDRs) found at active enhancers and promoters (Schones et al, 2008; Hansen He et al, 2010). To investigate whether and how nucleosome linker DNA affects chromatin recognition by nuclear proteins we performed an additional set of affinity purifications using di-nucleosomes incorporating different DNA linkers. Here, we investigated the effect of a 200 bp di-nucleosome linker DNA represented by scrambled DNA or SV40 enhancer DNA sequence on the nuclear protein binding to di-nucleosome decorated with enhancer-associated modifications, including H3K4me1 and H3K27ac.

Project description:Characteristic features of chromatin states are not limited to particular epigenetic modifications but include other regulatory cues, such as linker DNA length, typically ranging from between 35-55 bp (Valouev et al, 2011; Voong et al., 2016, Cell) to over 200 bp in nucleosome-depleted regions (NDRs) found at active enhancers and promoters (Schones et al, 2008; Hansen He et al, 2010). To investigate whether and how the nucleosome linker DNA affects chromatin recognition by nuclear proteins we performed a set of affinity purifications using di-nucleosomes incorporating different DNA linkers. This dataset contains experiments aimed to probe how the linker DNA length affects protein binding to di-nucleosomes decorated with H3K9me3 or H3K27me3. The following di-nucleosomes were used in affinity pull-down purifications with HeLa nuclear extract followed by label-free MS: 1. unmod. H3, 35 bp linker 2. unmod. H3, 40 bp linker 3. unmod. H3, 45 bp linker 4. unmod. H3, 50 bp linker 5. unmod. H3, 55 bp linker 6. H3K9me3, 35 bp linker 7. H3K9me3, 40 bp linker 8. H3K9me3, 45 bp linker 9. H3K9me3 50 bp linker 10. H3K9me3, 55 bp linker 11. H3K27me3, 35 bp linker 12. H3K27me3, 40 bp linker 13. H3K27me3, 45 bp linker 14. H3K27me3, 50 bp linker 15. H3K27me3, 55 bp linker

Project description:Chemical modification of histone proteins by methylation plays a central role in chromatin regulation by recruiting epigenetic ‘readers’ via specialized binding domains. Depending on the degree of methylation, the exact modified amino acid, and the associated reader proteins histone methylations are involved in the regulation of all DNA-based processes, such as transcription, DNA replication, and DNA repair. We have previously established a method that allows the unbiased identification of nuclear proteins which binding to nucleosomes is regulated by the presence of specific histone modifications (1,2). The method is based on an in-vitro reconstitution of semi-synthetic nucleosomes bearing a predefined set of histone modifications which are subsequently used as baits for affinity purification pull-down experiments with nuclear extracts followed by identification and quantification of nucleosome-interacting proteins using LC-MS/MS. Here we provide a representative set of label-free MS results for nucleosome pull-down affinity purification experiments performed using unmodified as well as H3K4me3- and H3K9me3-modified di-nucleosomes and nuclear extract obtained from HeLa S3 cells. 1. Bartke T, Vermeulen M, Xhemalce B, Robson SC, Mann M, Kouzarides T (2010) Nucleosome-interacting proteins regulated by DNA and histone methylation. Cell 143:470-484 2. Makowski MM, Gräwe C, Foster BM, Nguyen NV, Bartke T, Vermeulen M (2018) Global profiling of protein-DNA and protein-nucleosome binding affinities using quantitative mass spectrometry. Nat Commun 9:1653

Project description:Chromatin remodelers are ATP-dependent enzymes that reorganize nucleosomes within all eukaryotic genomes. The Chd1 remodeler specializes in shifting nucleosomes into evenly spaced arrays, a defining characteristic of chromatin in gene bodies that blocks spurious transcription initiation. Linked to some forms of autism and commonly mutated in prostate cancer, Chd1 is essential for maintaining pluripotency in stem cells. Here we report a complex of yeast Chd1 bound to a nucleosome in a nucleotide-free state, determined by cryo-electron microscopy (cryo-EM) to 2.6 Å resolution. The structure shows a bulge of the DNA tracking strand where the ATPase motor engages the nucleosome, consistent with an initial stage in DNA translocation. Unlike other remodeler-nucleosome complexes, nucleosomal DNA compensates for the remodeler-induced bulge with a bulge of the complementary DNA strand one helical turn downstream from the ATPase motor. Unexpectedly, the structure also reveals an N-terminal binding motif, called ChEx, which binds on the exit-side acidic patch of the nucleosome. The ChEx motif can displace a LANA-based peptide from the acidic patch, which suggests a means by which Chd1 remodelers may block competing chromatin remodelers from acting on the opposite side of the nucleosome.

Project description:Jurkat T-leukemic cells at 0, 15, 45, and 240 minutes post MPH treatment. Chromatin structure depends highly on the position and density of nucleosomes in the genome. The distribution of these nucleosomes likely plays a critical role in all processes for which DNA is the template, including: gene expression, DNA replication, recombination and repair. It has been proposed for more than half a century that although all the cells in a human body contain, essentially, the same genetic material, nucleosomes give access to different areas of the genome effectively giving access to cell-type specific areas of the genome. We hypothesized that alterations in nucleosome distribution might play a role in the MPH stimulated immune response. We measured chromatin structural changes in a human T-cell line (Jurkat T-leukemic) at high temporal resolution after MPH treatment. We mapped the nucleosome distribution at 4 different time points (0, 15, 45, 240 minutes). Nucleosomal DNA sequences were harvested via chromatin cross-linkage, MNase digestion and DNA extraction. Results were gathered by measuring differences in nucleosome distribution between the basal and the treated states at the different time points. We identified changes in nucleosome distribution. Interestingly, these changes in nucleosome distribution were transient, returning to their basal positions. Finally, these changes in nucleosome distribution exhibited different kinetics at different genes. We propose that the changes in nucleosomal distribution help potentiate differences in gene activity. The results allow us to understand the direct affects of MPH on chromatin structure and help reveal certain mechanistic processes by which it performs. Jurkat T-leukemic cells at 0, 15, 45, and 240 minutes post MPH treatment.

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:Nucleosome structure and positioning play pivotal roles in gene regulation, DNA repair and other essential processes in eukaryotic cells. Nucleosomal DNA is thought to be uniformly inaccessible to DNA binding and processing factors, such as MNase. Here, we show, however, that nucleosome accessibility and sensitivity to MNase varies. Digestion of Drosophila chromatin with two distinct concentrations of MNase revealed two types of nucleosomes: sensitive and resistant. MNase-resistant nucleosome arrays are less accessible to low concentrations of MNase, whereas MNase-sensitive arrays are degraded by high concentrations. MNase-resistant nucleosomes assemble on sequences depleted of A/T and enriched in G/C containing dinucleotides. In contrast, MNase-sensitive nucleosomes form on A/T rich sequences represented by transcription start and termination sites, enhancers and DNase hypersensitive sites. Lowering of cell growth temperature to ~10°C stabilizes MNase-sensitive nucleosomes suggesting that variations in sensitivity to MNase are related to either thermal fluctuations in chromatin fiber or the activity of enzymatic machinery. In the vicinity of active genes and DNase hypersensitive sites nucleosomes are organized into synchronous, periodic arrays. These patterns are likely to be caused by “phasing” nucleosomes off a potential barrier formed by DNA-bound factors and we provide an extensive biophysical framework to explain this effect. Mnase-seq, Mnase-ChIP-seq of Drosophila melanogaster embryo and S2 cells chromatin