Project description:Functional centromeres are essential for proper cell division. Centromeres are established largely by epigenetic processes resulting in incorporation of the histone H3 variant CENP-A. Here, we demonstrate the direct involvement of H2B monoubiquitination, mediated by RNF20 in humans or Brl1 in Schizosaccharomyces pombe, in centromeric chromatin maintenance. Monoubiquinated H2B (H2Bub1) is needed for this maintenance, promoting noncoding transcription, centromere integrity and accurate chromosomal segregation. A transient pulse of centromeric H2Bub1 leads to RNA polymerase IIM-bM-^@M-^Smediated transcription of the centromereM-bM-^@M-^Ys central domain, coupled to decreased H3 stability. H2Bub1-deficient cells have centromere cores that, despite their intact centromeric heterochromatin barriers, exhibit characteristics of heterochromatin, such as silencing histone modifications, reduced nucleosome turnover and reduced levels of transcription. In the H2Bub1-deficient cells, centromere functionality is hampered, thus resulting in unequal chromosome segregation. Therefore, centromeric H2Bub1 is essential for maintaining active centromeric chromatin. ChIP: In total 17 samples; 15 ChIP DNA files (7 different conditions) 2 Input files. Cnp1_WT_input.bar (antibody against Cnp1 in strains Hu303, Hu29 (WT) (Cnp1_Hu303.CEL, AS_10.CEL) vs input (JW_1.CEL, JW_2_2.CEL)); Cnp1_Hu2640_WT.bar (antibody against Cnp1 in strain Hu2640 (htb1K119R) (Cnp1_Hu2640_A.CEL, Cnp1_Hu2640_B.CEL) vs strains Hu303, Hu29 (WT) (Cnp1_Hu303.CEL, AS_10.CEL)); Cnp1_Hu2640_input.bar (antibody against Cnp1 in strain Hu2640 (htb1K119R) (Cnp1_Hu2640_A.CEL, Cnp1_Hu2640_B.CEL) vs input (JW_1.CEL, JW_2_2.CEL)); H2Bub1_Hu303_input.bar (antibody against H2Bub1 in strain Hu303 (WT) (H2Bub1_Hu303_A.CEL, H2Bub1_Hu303_B.CEL) vs input (JW_1.CEL, JW_2_2.CEL)); H3_WT_input.bar (antibody against H3 in strains Hu303, Hu29 (WT) (H3_Hu303.CEL, As_12.CEL) vs input (JW_1.CEL, JW_2_2.CEL); H3_Hu2640_WT.bar (antibody against H3 in strain Hu2640 (htb1K119R) (H3_Hu2640_A.CEL, H3_Hu2640_B.CEL, H3_Hu2640_C.CEL) vs strains Hu303, Hu29 (WT) (H3_Hu303.CEL, AS_12.CEL)); H3_Hu2640_input.bar (antibody against H3 in strain Hu2640 (htb1K119R) (H3_Hu2640_A.CEL, H3_Hu2640_B.CEL, H3_Hu2640_C.CEL) vs input (JW_1.CEL, JW_2_2.CEL)); H3K9me2_Hu303_input.bar (antibody against H3K9me2 in strains Hu303, Hu29 (WT) (H3K9me2_Hu303.CEL, AS_6.CEL) vs input (JW_1.CEL, JW_2_2.CEL)); H3k9me2_Hu2640_Hu303.bar (antibody against H3K9me2 in strain Hu2640 (htb1K119R) (H3K9me2_Hu2640_A.CEL, H3K9me2_Hu2640_B.CEL) vs strain Hu303, Hu29 (WT) (H3K9me2_Hu303.CEL, AS_6.CEL)); H3K9me2_Hu2640_input.bar (antibody against H3K9me2 in strain Hu2640 (htb1K119R) (H3K9me2_Hu2640_A.CEL, H3K9me2_Hu2640_B.CEL) vs input (JW_1.CEL, JW_2_2.CEL)). RNA: 4 RNA samples: 2 replicates of WT RNA (RNA_Hu303_A.CEL, RNA_Hu303_B.CEL) and 2 replicates of htb1-K119R RNA (RNA_Hu2640_A.CEL, RNA_Hu2640_B.CEL).

Project description:At Schizosaccharomyces pombe centromeres, heterochromatin formation is required for de novo incorporation of the histone H3 variant CENP-A/Cnp1, which in turn directs kinetochore assembly and ultimately chromosome segregation during mitosis. Noncoding RNAs (ncRNAs) transcribed by RNA polymerase II (Pol II) directs heterochromatin formation via the RNAi machinery, but also through RNAiindependent RNA processing factors. Control of centromeric ncRNA transcription is therefore a key factor for proper centromere function. We here use transcriptional profiling, gene inactivation experiments, and chromatin immunoprecipitation analyses to demonstrate that the Mediator complex directs ncRNA transcription and regulates centromeric heterochromatin formation in fission yeast. Mediator co-localizes with Pol II at centromeres and loss of the Mediator subunit Med20 causes a dramatic increase in pericentromeric transcription and desilencing of the core centromere. As a consequence, heterochromatin formation is impaired both via the RNAi dependent and independent pathways, resulting in loss of CENP-A/Cnp1 from the core centromere, defect kinetochore function, and a severe chromosome segregation defect. Interestingly, the increased centromeric transcription observed in med20Δ appears to directly block CENP-A/Cnp1 incorporation and inhibition of Pol II transcription can suppress the observed phenotypes. Our data thus identify Mediator as a crucial regulator of ncRNA transcription at fission yeast centromeres and add another crucial layer of regulation to centromere function. 3 samples examined: wild type chromatin incubated with beads as the non antibody control, wild type chromatin incubated with RNA Polymerase II CTD domain antibody and Protein G beads, and TAP-Med7 cells chromatin incubated with IgG beads.

Project description:At Schizosaccharomyces pombe centromeres, heterochromatin formation is required for de novo incorporation of the histone H3 variant CENP-A/Cnp1, which in turn directs kinetochore assembly and ultimately chromosome segregation during mitosis. Noncoding RNAs (ncRNAs) transcribed by RNA polymerase II (Pol II) directs heterochromatin formation via the RNAi machinery, but also through RNAiindependent RNA processing factors. Control of centromeric ncRNA transcription is therefore a key factor for proper centromere function. We here use transcriptional profiling, gene inactivation experiments, and chromatin immunoprecipitation analyses to demonstrate that the Mediator complex directs ncRNA transcription and regulates centromeric heterochromatin formation in fission yeast. Mediator co-localizes with Pol II at centromeres and loss of the Mediator subunit Med20 causes a dramatic increase in pericentromeric transcription and desilencing of the core centromere. As a consequence, heterochromatin formation is impaired both via the RNAi dependent and independent pathways, resulting in loss of CENP-A/Cnp1 from the core centromere, defect kinetochore function, and a severe chromosome segregation defect. Interestingly, the increased centromeric transcription observed in med20Δ appears to directly block CENP-A/Cnp1 incorporation and inhibition of Pol II transcription can suppress the observed phenotypes. Our data thus identify Mediator as a crucial regulator of ncRNA transcription at fission yeast centromeres and add another crucial layer of regulation to centromere function.

Project description:Centromere is the chromosomal locus at which kinetochore is assembled to direct chromosome segregation. Histone H3 variant CENP-A epigenetically marks active centromeres; however, the mechanism by which CENP-A propagates at the centromere, replacing histone H3, remains poorly understood. Using fission yeast, we find that CENP-ACnp1 chromatin assembly at the centromere requires the Ino80 ATP-dependent chromatin remodeling complex which removes histone H3-containing nucleosomes from associated chromatin. CENP-ACnp1 chromatin actively recruits the Ino80 complex to centromeres to elicit eviction of histone H3-containing nucleosomes. Artificial targeting of Ino80 subunits to a non-centromeric DNA placed in a native centromere enhances the spreading of CENP-ACnp1 chromatin into the non-centromeric DNA. Based on these results, we propose that CENP-ACnp1 chromatin employs the Ino80 complex to mediate replacement of histone H3 with CENP-ACnp1, and thereby reinforces itself.

Project description:In higher eukaryotes centromeres often coalesce into a large intranuclear domain called the chromocenter. Chromocenters are important for the organization of pericentric heterochromatin and a disturbance of their formation results in an upregulation of repetitive elements and causes defects in chromosome segregation. Mutations in the gene encoding for the centromere associated Drosophila speciation factor HMR show very similar phenotypes suggesting a role of HMR in chromocenter architecture and function. We performed confocal and super resolution microscopy as well as proximity based biotinylation experiments of HMR, centromeric protein dCenpA and heterochromatic protein HP1a to generate a molecular map of HMR, dCenpA and HP1a bound chromatin. Our work reveals an intricate internal structure of the centromeric chromatin region, which suggests a role of HMR in separating heterochromatin from centromeric chromatin.

Project description:The centromere is defined by the presence of a centromere-specific histone H3 variant, CENH3. Establishment and maintenance of the centromeric chromatin (CEN chromatin) is determined by poorly understood epigenetic mechanisms. Interestingly, CEN chromatin in several eukaryotes showed euchromatic characteristics although being embedded within pericentromeric heterochromatin. Specifically, H3K4me2 appeared to be a unique histone modification mark associated with animal centromeres. We developed a genomic tiling array for four fully sequenced rice centromeres. A ChIP-chip approach was used to study the patterns of several euchromatic histone modification marks, including H3K4me2, H3K4me3, H3K36me3, and H3K4K9a, associated with rice centromeres. We demonstrate that the CENH3 subdomains within the four centromeres are depleted with the four histone H3 marks. The vast majority of the four histone marks were associated with the genes located in the H3 subdomains within the centromeric cores. Genes in the centromeres showed similar histone modification patterns as those located outside of the centromeres. Thus, the euchromatic characteristics of rice CEN chromatin are trademarks of the transcribed sequences embedded in the H3 subdomains of the centromeres. We propose that the constitutively expressed genes located in rice centromeres may provide a barrier for loading of CENH3 into the H3 subdomains. The separation of CENH3 into the H3 subdomains is favorable for the three dimensional structure and its associated function of rice centromeres. We developed a genomic tiling array that covers four rice centromeres (Cen4, Cen5, Cen7, and Cen8) using the NimbleGen 3x720K array based on the NimbleGen HD2 platform. We used four antibodies (H3K4me3, H3K4me2, H3K36me3, H3K4K9ac) to perform ChIP-chip experiments. ChIP was conducted using leaf tissue from two-week old rice seedlings. We have 3 biological replicates for each antibody and 6 technological replicates of hybridization with position exchange on the array. Thus, each histone modification included 18 hybridization experiments.

Project description:The centromere is defined by the presence of a centromere-specific histone H3 variant, CENH3. Establishment and maintenance of the centromeric chromatin (CEN chromatin) is determined by poorly understood epigenetic mechanisms. Interestingly, CEN chromatin in several eukaryotes showed euchromatic characteristics although being embedded within pericentromeric heterochromatin. Specifically, H3K4me2 appeared to be a unique histone modification mark associated with animal centromeres. We developed a genomic tiling array for four fully sequenced rice centromeres. A ChIP-chip approach was used to study the patterns of several euchromatic histone modification marks, including H3K4me2, H3K4me3, H3K36me3, and H3K4K9a, associated with rice centromeres. We demonstrate that the CENH3 subdomains within the four centromeres are depleted with the four histone H3 marks. The vast majority of the four histone marks were associated with the genes located in the H3 subdomains within the centromeric cores. Genes in the centromeres showed similar histone modification patterns as those located outside of the centromeres. Thus, the euchromatic characteristics of rice CEN chromatin are trademarks of the transcribed sequences embedded in the H3 subdomains of the centromeres. We propose that the constitutively expressed genes located in rice centromeres may provide a barrier for loading of CENH3 into the H3 subdomains. The separation of CENH3 into the H3 subdomains is favorable for the three dimensional structure and its associated function of rice centromeres.

Project description:Centromeres play an essential role in cell division by specifying the site of kinetochore formation on each chromosome so that chromosomes can attach to the mitotic spindle for segregation. Centromeres are defined epigenetically by the histone  H3 variant CEntromere Protein A (CENP-A). Dividing cells maintain the centromere  by depositing new CENP-A each cell cycle to replenish CENP-A diluted by replication. The CENP-A nucleosome serves as the primary signal to the machinery responsible for its replenishment. Vertebrate centromeres are frequently built on repetitive sequences organized in tandem arrays. Repetitive centromeric DNA has been suggested to play a role in centromere maintenance and in de novo centromere formation, but this has been difficult to dissect because of the difficulty in manipulating centromere in cells. Extracts from Xenopus laevis eggs are able to assemble centromeres and kinetochores in vitro and thus provide a useful system for studying the role of centromeric DNA in centromere formation. However centromeric sequences in X. laevis have not been extensively characterized.. In this study we characterize repeat sequences found at  X. laevis centromeres. We utilize a k-mer based approach in order to uncover the previously unknown diversity of X. laevis centromeric sequences. We validate centromere localization of repeat sequences by in situ hybridization and identify the location of the centromeric repetitive array on each chromosome by mapping the distribution of centromere enriched k-mers on the Xenopus genome. Our identification of X. laevis centromere sequences enables previously unapproachable genomic studies of centromeres. The k-mer based approach that we used to investigate centromeric repetitive DNA is suitable for the analysis of other repetitive sequences found across the genome or the study of repeats in other organisms. 

Project description:CENP-A is a centromere-specific histone 3 variant essential for centromere specification. CENP-A partially replaces canonical histone H3 at the centromeres. How the particular CENP-A/H3 ratio at centromeres is precisely maintained is unknown. It also remains unclear how CENP-A is excluded from non-centromeric chromatin. Here we identify Ccp1, an uncharacterized NAP family protein in fission yeast that antagonizes CENP-A loading at both centromeric and non-centromeric regions. Like the CENP-A loading factor HJURP, Ccp1 interacts with CENP-A, and is recruited to centromeres at the end of mitosis in a Mis16-dependent manner. These data indicate that factors with opposing CENP-A loading activities are recruited to centromeres. Furthermore, Ccp1 also cooperates with H2A.Z to evict CENP-A assembled in euchromatin. Structural analyses indicate that Ccp1 forms a homodimer that is required for its anti-CENP-A loading activity. Our study establishes mechanisms for maintenance of CENP-A homeostasis at centromeres and the prevention of ectopic assembly of centromeres. Examination of cnp1 distribution in one wild type (wt) and two ccp1 mutants.

Project description:CENP-A is a centromere-specific histone 3 variant essential for centromere specification. CENP-A partially replaces canonical histone H3 at the centromeres. How the particular CENP-A/H3 ratio at centromeres is precisely maintained is unknown. It also remains unclear how CENP-A is excluded from non-centromeric chromatin. Here we identify Ccp1, an uncharacterized NAP family protein in fission yeast that antagonizes CENP-A loading at both centromeric and non-centromeric regions. Like the CENP-A loading factor HJURP, Ccp1 interacts with CENP-A, and is recruited to centromeres at the end of mitosis in a Mis16-dependent manner. These data indicate that factors with opposing CENP-A loading activities are recruited to centromeres. Furthermore, Ccp1 also cooperates with H2A.Z to evict CENP-A assembled in euchromatin. Structural analyses indicate that Ccp1 forms a homodimer that is required for its anti-CENP-A loading activity. Our study establishes mechanisms for maintenance of CENP-A homeostasis at centromeres and the prevention of ectopic assembly of centromeres.