Project description:Probing the rice genome for novel histone coding genes revealed a genera specific, histone H4 variant with several variations in N-terminal tail sequence motifs, expressing in a tissue-specific manner. Genetic perturbation of the H4 variant in rice led to defects in growth and fertility. Probing the chromatin binding sites of the H4 variant with a custom antibody revealed its binding at specific genes and its knockout led to mis-expression of stress-associated genes. Stress-challenged plants showed loss of the H4 variant and re-distribution of other H4 linked histone marks. In vitro reconstituted rice nucleosomes with H4 variant histones displayed atypical properties in terms of stability, intra-nucleosome binding and structure, when compared to the canonical nucleosomes.

Project description:Probing the rice genome for novel histone coding genes revealed a genera specific, histone H4 variant with several variations in N-terminal tail sequence motifs, expressing in a tissue-specific manner. Genetic perturbation of the H4 variant in rice led to defects in growth and fertility. Probing the chromatin binding sites of the H4 variant with a custom antibody revealed its binding at specific genes and its knockout led to mis-expression of stress-associated genes. Stress-challenged plants showed loss of the H4 variant and re-distribution of other H4 linked histone marks. In vitro reconstituted rice nucleosomes with H4 variant histones displayed atypical properties in terms of stability, intra-nucleosome binding and structure, when compared to the canonical nucleosomes.

Project description:Probing the rice genome for novel histone coding genes revealed a genera specific, histone H4 variant with several variations in N-terminal tail sequence motifs, expressing in a tissue-specific manner. Genetic perturbation of the H4 variant in rice led to defects in growth and fertility. Probing the chromatin binding sites of the H4 variant with a custom antibody revealed its binding at specific genes and its knockout led to mis-expression of stress-associated genes. Stress-challenged plants showed loss of the H4 variant and re-distribution of other H4 linked histone marks. In vitro reconstituted rice nucleosomes with H4 variant histones displayed atypical properties in terms of stability, intra-nucleosome binding and structure, when compared to the canonical nucleosomes.

Project description:An Oryza-specific histone H4 variant predisposes H4 lysine 5 acetylation to modulate salt stress responses

Project description:Chromatin immunoprecipitation of genomic loci in Trypanosoma brucei where histone variant H4.V is deposited. A previously generated cell line (Siegel et al., 2009) in which both endogenous H4.V alleles are knockout out and ectopic overexpression of a Ty1-tagged version of H4.V can be induced was used. During the ChIP experiment, the DNA was digested with MNase to obtain mononucleosomes. Nucleosomes containing H4.V were pulled down by using a BB2 anti-Ty1 antibody. Cross links are reversed and mononucleosomal DNA is purified and prepared for Illumina sequencing.

Project description:Nucleosomes that contain the histone variant H2A.Z are enriched around transcriptional start sites in many organisms. A single octameric nucleosome can contain two H2A.Z histones (homotypic) or one H2A.Z and one canonical H2A (heterotype). We generated high-resolution maps of homotypic and heterotypic Drosophila H2A.Z (H2Av) nucleosomes. Although homotypic and heterotypic H2Av nucleosomes map throughout most of the genome, homotypic nucleosomes are enriched and heterotypic nucleosomes are depleted downstream of active promoters and intron/exon boundaries. The distribution of homotypic H2A.Z nucleosomes resembles that of salt-soluble nucleosomes and shows evidence of displacement during transcriptional elongation. Homotypic nucleosomes are also depleted downstream of paused polymerases, where salt-soluble nucleosomes are conspicuously depleted. Our results suggest a model whereby H2A.Z enrichment patterns result from different structural interactions within the core of heterotypic and homotypic nucleosomes following disruption during transcriptional elongation. We analyzed two replicates for input, heterotypic and homotypic purifications. We sequenced one library for each of the single H2Av pulldown and 80mM salt soluble samples.

Project description:Here we examined whether histones H3 and H4 produced using native chemical ligation reaction affect protein binding to di-nucleosomes. To test this we performed a set of affinity purification pull-downs using di-nucleosomes containing the following histones H3 and H4: 1. ligated unmodified histone H3 and recombinant wild type histone H4 (unmod. H3), 2. recombinant wild type histone H3 and ligated unmodified histone H4 (unmod. H4) 3. ligated unmodified histones H3 and H4 (unmod. H3&H4). 4. recombinant wild type histones H3 and H4 (WT) Each pull-down was performed in three replicates. Co-purified proteins were quantified using label-free MS. Note that ligated histones H3 and H4 contain T32C or I29C single amino acid substitutions, respectively, that are introduced by the native chemical ligation procedure. In addition, ligated histone H4 is N-terminally acetylated to mimic its naturally blocked N-terminus.

Project description:Here we examined whether histones H3 and H4 produced using native chemical ligation reaction affect protein binding to di-nucleosomes. To test this we performed a set of affinity purification pull-downs using di-nucleosomes containing the following histones H3 and H4: 1. unmodified ligated histone H3 and recombinant wild type histone H4 (unmod. H3), 2. recombinant wild type histone H3 and ligated unmodified histone H4 (unmod. H4) 3. ligated unmodified histones H3 and H4 (unmod. H3&H4). 4. recombinant wild type histones H3 and H4 (WT) Each pull-down was performed in three replicates. Co-purified proteins were quantified using label-free MS. Note that ligated histones H3 and H4 contain T32C or I29C single amino acid substitutions, respectively, that are introduced by the native chemical ligation procedure. In addition, ligated histone H4 is N-terminally acetylated to mimic its naturally blocked N-terminus.

Project description:Nucleosomes that contain the histone variant H2A.Z are enriched around transcriptional start sites in many organisms. A single octameric nucleosome can contain two H2A.Z histones (homotypic) or one H2A.Z and one canonical H2A (heterotype). We generated high-resolution maps of homotypic and heterotypic Drosophila H2A.Z (H2Av) nucleosomes. Although homotypic and heterotypic H2Av nucleosomes map throughout most of the genome, homotypic nucleosomes are enriched and heterotypic nucleosomes are depleted downstream of active promoters and intron/exon boundaries. The distribution of homotypic H2A.Z nucleosomes resembles that of salt-soluble nucleosomes and shows evidence of displacement during transcriptional elongation. Homotypic nucleosomes are also depleted downstream of paused polymerases, where salt-soluble nucleosomes are conspicuously depleted. Our results suggest a model whereby H2A.Z enrichment patterns result from different structural interactions within the core of heterotypic and homotypic nucleosomes following disruption during transcriptional elongation.

Project description:Signal intensity data for rpd3 delete, H3delta(1-28), H3(K4,9,14,18,23,27Q), H4delta(2-26), H4(K5,8,12,16Q), rpd3 delete H3delta(1-28), and rpd3 delete H4(K5,8,12,16Q) yeast grown in rich (YPD) media Keywords = histones Keywords = chromatin Keywords = rpd3 Keywords = HDAC Keywords = histone deacetylase Keywords = yeast Keywords: other