Project description:Maintaining centromere integrity is crucial for genome stability and proper chromosome segregation during mitosis. CENPA, a conserved histone H3 variant, is localized at the centromeres and plays an essential role in preserving centromere integrity and function. However, the mechanisms that retain CENPA at centromeres remain an enigma. In this study, we identified CENPA as an m6A reader of centromeric RNA (cenRNA), which is essential for its centromeric localization and function in maintaining centromere stability. We discovered a higher level of m6A modification on cenRNA in cancerous cells compared to normal cells. CENPA preferentially binds the cenRNAs with m6A modification, which stabilizes its localization in centromeric regions during the S phase of the cell cycle. We then identified two residues in CENPA responsible for m6A recognition. Mutations in these CENPA residues or removal of m6A on cenRNAs leads to the loss of centromere-bound CENPA during the S phase, thereby resulting in abnormal chromosome separation during mitosis and increased genomic instability. Consequently, this impairment in centromere integrity hindered cancer cell proliferation and tumor growth. Our findings unveiled a novel m6A reading mechanism by CENPA that epigenetically governs centromere integrity in cancer cells, providing potentially new targets for cancer therapy.

Project description:Maintaining centromere integrity is crucial for genome stability and proper chromosome segregation during mitosis. CENPA, a conserved histone H3 variant, is localized at the centromeres and plays an essential role in preserving centromere integrity and function. However, the mechanisms that retain CENPA at centromeres remain an enigma. In this study, we identified CENPA as an m6A reader of centromeric RNA (cenRNA), which is essential for its centromeric localization and function in maintaining centromere stability. We discovered a higher level of m6A modification on cenRNA in cancerous cells compared to normal cells. CENPA preferentially binds the cenRNAs with m6A modification, which stabilizes its localization in centromeric regions during the S phase of the cell cycle. We then identified two residues in CENPA responsible for m6A recognition. Mutations in these CENPA residues or removal of m6A on cenRNAs leads to the loss of centromere-bound CENPA during the S phase, thereby resulting in abnormal chromosome separation during mitosis and increased genomic instability. Consequently, this impairment in centromere integrity hindered cancer cell proliferation and tumor growth. Our findings unveiled a novel m6A reading mechanism by CENPA that epigenetically governs centromere integrity in cancer cells, providing potentially new targets for cancer therapy.

Project description:Maintaining centromere integrity is crucial for genome stability and proper chromosome segregation during mitosis. CENPA, a conserved histone H3 variant, is localized at the centromeres and plays an essential role in preserving centromere integrity and function. However, the mechanisms that retain CENPA at centromeres remain an enigma. In this study, we identified CENPA as an m6A reader of centromeric RNA (cenRNA), which is essential for its centromeric localization and function in maintaining centromere stability. We discovered a higher level of m6A modification on cenRNA in cancerous cells compared to normal cells. CENPA preferentially binds the cenRNAs with m6A modification, which stabilizes its localization in centromeric regions during the S phase of the cell cycle. We then identified two residues in CENPA responsible for m6A recognition. Mutations in these CENPA residues or removal of m6A on cenRNAs leads to the loss of centromere-bound CENPA during the S phase, thereby resulting in abnormal chromosome separation during mitosis and increased genomic instability. Consequently, this impairment in centromere integrity hindered cancer cell proliferation and tumor growth. Our findings unveiled a novel m6A reading mechanism by CENPA that epigenetically governs centromere integrity in cancer cells, providing potentially new targets for cancer therapy.

Project description:Centromeres are the chromosomal loci essential for faithful chromosome segregation during cell division. Although centromeres are transcribed and produce non-coding RNAs (cenRNAs) that affect centromere function, we still lack a mechanistic understanding of how centromere transcription is regulated. Here, using a targeted RNA isoform sequencing approach, we identified the transcriptional landscape at and surrounding all centromeres in budding yeast. Overall, cenRNAs are derived from transcription readthrough of pericentromeric regions but rarely span the entire centromere and are a complex mixture of molecules that are heterogeneous in abundance, orientation, and sequence. While most pericentromeres are transcribed throughout the cell cycle, centromere accessibility to the transcription machinery is restricted to S-phase. This temporal restriction is dependent on Cbf1, a centromere-binding transcription factor, that we demonstrate acts locally as a transcriptional roadblock. Cbf1 deletion leads to an accumulation of cenRNAs at all phases of the cell cycle which correlates with increased chromosome mis-segregation that is partially rescued when the roadblock activity is restored. We propose that a Cbf1-mediated transcriptional roadblock protects yeast centromeres from untimely transcription to ensure genomic stability.

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:Centromeres exert vital cellular functions in mitosis and meiosis. A specialized histone and other chromatin-bound factors nucleate a dynamic protein assembly that is required for the proper segregation of sister chromatids. In several organisms including the fission yeast S. pombe, a RNAi-related pathway further strengthens the epigenetic maintenance of centromere location, primarily through repressing transcription near centromeres. Little is known how accessory factors such as histone chaperones and chromatin remodelling factors might be required to establish a functioning centromere. Here we show that the chaperone and remodelling complex FACT is required for transcriptional gene silencing at centromeres and for accurate chromosome segregation during mitosis. We show that Spt16 and Pob3 are two subunits of the S. pombe FACT complex. Surprisingly, yeast strains deleted for Pob3 are viable and show a marked loss of gene silencing at centromeric repeats and at the mating locus. Importantly, Pob3-null strains fail to undergo mitosis at high accuracy and phenocopy histone methylation and RNAi mutants. Processing of centromeric RNA transcripts into siRNAs is maintained in Pob3 mutants, but Swi6-association at the centromere is affected. Our studies provide the first experimental evidence for a role of the RNA polymerase II cofactor FACT in centromere function. Keywords: Expression profiling of pob3 vs wt

Project description:Overexpression of centromeric proteins has been identified in a number of human malignancies, though their functional and mechanistic contributions to disease progression have not been characterized. CENPA, the centromeric histone H3 variant, is the epigenetic mark that determines centromere identity. Here, we demonstrate that CENPA is highly overexpressed in prostate cancer in both tissue and cell lines, and the level of CENPA expression correlates with the stage of disease. Gain-of- and loss-of-function experimentation confirms that CENPA promotes prostate cancer cell line growth. Integrated sequencing studies further reveal a previously unidentified function of CENPA as a transcriptional regulator that modulates expression of critical proliferation, cell-cycle, and centromere/kinetochore genes. Our findings, therefore, suggest a previously undescribed biological function for CENPA, a protein normally thought to be solely and importantly involved in centromere identity.

Project description:Overexpression of centromeric proteins has been identified in a number of human malignancies, though their functional and mechanistic contributions to disease progression have not been characterized. CENPA, the centromeric histone H3 variant, is the epigenetic mark that determines centromere identity. Here, we demonstrate that CENPA is highly overexpressed in prostate cancer in both tissue and cell lines, and the level of CENPA expression correlates with the stage of disease. Gain-of- and loss-of-function experimentation confirms that CENPA promotes prostate cancer cell line growth. Integrated sequencing studies further reveal a previously unidentified function of CENPA as a transcriptional regulator that modulates expression of critical proliferation, cell-cycle, and centromere/kinetochore genes. Our findings, therefore, suggest a previously undescribed biological function for CENPA, a protein normally thought to be solely and importantly involved in centromere identity.

Project description:The ring-shaped cohesin complex links sister chromatids until their timely segregation during mitosis. Cohesin is enriched at centromeres, where it provides the cohesive counter-force to bi-polar tension produced by the mitotic spindle. As a consequence of spindle tension, centromeric sequences transiently split in pre-anaphase cells, in some organisms up to several micrometeres. This ‘centromere breathing’ presents a paradox, how sister sequences separate where cohesin is most enriched. We now show that in the budding yeast S. cerevisiae, cohesin binding diminishes over centromeric sequences that split during breathing. We see no evidence for cohesin translocation to surrounding sequences, suggesting that cohesin is removed from centromeres during breathing. Two pools of cohesin can be distinguished. Cohesin loaded before DNA replication, that has established sister chromatid cohesion, disappears during breathing. In contrast, cohesin loaded after DNA replication is partly retained. As sister centromeres re-associate after transient separation, cohesin is re-loaded in a manner independent of the canonical cohesin loader Scc2/Scc4. Efficient centromere re-association requires the cohesion establishment factor Eco1, suggesting that re-establishment of sister chromatid cohesion contributes to the dynamic behaviour of centromeres in mitosis. These findings provide new insights into cohesin behaviour at centromeres. Keywords: ChIP-chip

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.