Project description:It is well known that deregulation of chromatin modifiers, such as histone acetylases and methylases, causes malignancies. However, the possible role of histone phosphorylation in carcinogenesis has not yet been elucidated. Here, we found that histone phosphorylation by itself can be the causal event in carcinogenesis. First, we found that histone H2A T120 is phosphorylated in human cancer cell lines and proved that this phosphorylation is catalyzed by hVRK1. By knocking down VRK1, cyclin D1 was found to be downregulated by loss of H2A T120 phosphorylation and increased H2A K119 ubiquitylation of its promoter region, resulting in impaired cell growth. In human cancer tissues, we found that histone H2A is hyperphosphorylated, with upregulated cyclin D1. Mechanistically, histone H2A T120 phosphorylation and histone H2A K119 ubiquitylation, which repress transcription, are mutually inhibitory, suggesting that histone phosphorylation indirectly activates chromatin. Furthermore, mutated H2A T120D, which mimics phosphorylation, causes elevated H3K4 methylation in the same nucleosome. Subsequently, H3K4R, which functionally mimics H3K4 methylation, increases H3 S10 phosphorylation in the same nucleosome. Finally, both VRK1 and the H2A T120D mutant histone transformed NIH/3T3 cells. This suggests that histone H2A T120 phosphorylation by hVRK1 causes inappropriate gene and protein expression, including upregulated cyclin D1, resulting in carcinogenesis.

Project description:Histone H2A T120 phosphorylation promotes oncogenic transformation via upregulation of cyclin D1

Project description:Histone H2A T120 phophorylation promotes oncogenic transformation via upregulation of cyclin D1 [RNA-seq]

Project description:Histone H2A T120 phophorylation promotes oncogenic transformation via upregulation of cyclin D1 [ChIP-seq]

Project description:Histone H2A T120 phophorylation promotes oncogenic transformation via upregulation of cyclin D1y

Project description:In mouse embryonic stem cells (mES cells), ubiquitylation of histone H2A lysine 119 represses a large number of developmental genes and maintains mES cell pluripotency. It has been suggested that a number of H2A ubiquitin ligases as well as deubiquitylases and related peptide fragments contribute to a delicate balance between self-renewal and multi-lineage differentiation in mES cells. Here, we tested whether known H2A ubiquitin ligases and deubiquitylases are involved in mES cell regulation and discovered that Dzip3, the E3 ligase of H2AK119, represses differentiation-inducible genes as well as Ring1B. The two sets of target genes partially overlapped but had　different spectra. We found that Dzip3 represses gene expression by orchestrating changes in 3D organization in addition to regulating ubiquitylation of H2A. Our results shed light on the epigenetic mechanism of transcriptional regulation, which depends on 3D chromatin reorganization to regulate mES cell differentiation. Examination of 3 different histone modifications in 1 cell type.

Project description:N6-methyladenosine (m6A) modification is the major post-transcriptional modification present in mammalian mRNA. m6A controls fundamental biological processes including cell proliferation, but the molecular mechanism remains unclear. Herein, we demonstrate that the m6A demethylase fat mass and obesity-associated (FTO) controls the cell cycle by targeting cyclin D1, the key regulator required for G1 phase progression. FTO silencing suppressed cyclin D1 expression and induced G1 arrest. FTO depletion upregulated cyclin D1 m6A modification, which in turn accelerated the degradation of cyclin D1 mRNA. Importantly, m6A modification of cyclin D1 oscillates in a cell cycle-dependent manner; m6A levels were suppressed during the G1 phase and enhanced during other phases. Low m6A levels during G1 were associated with nuclear translocation of FTO from the cytosol. Furthermore, nucleocytoplasmic shuttling of FTO is regulated by Casein Kinase II-mediated phosphorylation at Thr 150 of FTO. Our results highlight the role of m6A in regulating cyclin D1 mRNA stability, and add a new layer of complexity to cell cycle regulation.

Project description:Polycomb group (PcG) proteins control organism development by regulating the expression of developmental genes. Transcriptional regulation by PcG proteins is achieved at least partly through the PRC2-mediated methylation on lysine 27 of histone H3 (H3K27) and PRC1-mediated ubiquitylation on lysine 119 of histone H2A (uH2A). As an integral component of PRC1, Bmi1 has been demonstrated to be critical for H2A ubiquitylation. Here we report genome wide localization of the Bmi1-dependent uH2A mark in MEF cells. Gene promoter averaging analysis indicates a peak of uH2A just inside the transcription start site (TSS) of well annotated genes. This peak is enriched at promoters containing the H3K27me3 mark and represents the least expressed genes in WT MEF cells. In addition, peak finding reveals regions of local uH2A enrichment throughout the mouse genome, including almost 700 gene promoters. Genes with promoter peaks of uH2A exhibit lower level expression when compared to genes that do not contain promoter peaks of uH2A. Moreover, we demonstrate that genes with uH2A peaks have increased expression upon Bmi1 knockout. Importantly, local enrichment of uH2A is not limited to regions containing the H3K27me3 mark. We describe the enrichment of H2A ubiquitylation at high density CpG promoters and provide evidence to suggest that DNA methylation may be linked to uH2A at these regions. Thus, our work not only reveals Bmi1-dependent H2A ubiquitylation but also suggests that uH2A targeting in differentiated cells may employ a different mechanism from that in ES cells. Keywords: Epigenetics Examination of uH2A binding in WT and Bmi1 null MEF cells.

Project description:Ubiquitylation of histones provides an important mechanism regulating chromatin remodeling and gene expression. Recent studies have revealed ubiquitin ligases involved in histone ubiquitylation, yet the responsible enzymes and the function of histone ubiquitination in spermatogenesis remain unclear. Here we show that the ubiquitin ligase UBR2, one of the recognition E3 components of the N-end rule proteolytic pathway, localizes to meiotic chromatin regions, including unsynapsed axial elements linked to chromatin inactivation, and mediates, in combination with the ubiquitin-conjugating enzyme HR6B, the ubiquitination of histone H2A. UBR2 interacts with HR6B and H2A and promotes the HR6B-H2A interaction and the HR6B-to-H2A transfer of ubiquitin. UBR2 and ubiquitinated H2A (uH2A) spatiotemporally mark meiotic chromatin regions subject to transcriptional silencing, and UBR2-deficient spermatocytes fail to induce the ubiquitination of H2A during meiosis. UBR2-deficient spermatocytes are profoundly impaired in transcriptional silencing of genes linked to unsynapsed axes of the X and Y chromosomes. We propose a model, in which UBR2 on axial elements of the X-Y pair enables HR6B on the linked chromatin domain to repeat histone ubiquitination cycles while scanning a string of nucleosomes. Our results suggest that histone ubiquitination in germ cells may be mediated by E3-E2 pairs distinct from those in somatic cells, providing a new insight into chromatin remodeling and gene expression regulation. For each genotype, 2 testes were collected from different individual in same litter at 17 days old. Biotinylated cRNA was produced and hybridized on Affimetrix mouse genome 430A 2.0 array.

Project description:In mouse embryonic stem cells (mES cells), ubiquitylation of histone H2A lysine 119 represses a large number of developmental genes and maintains mES cell pluripotency. It has been suggested that a number of H2A ubiquitin ligases as well as deubiquitylases and related peptide fragments contribute to a delicate balance between self-renewal and multi-lineage differentiation in mES cells. Here, we tested whether known H2A ubiquitin ligases and deubiquitylases are involved in mES cell regulation and discovered that Dzip3, the E3 ligase of H2AK119, represses differentiation-inducible genes as well as Ring1B. The two sets of target genes partially overlapped but had different spectra. We found that Dzip3 represses gene expression by orchestrating changes in 3D organization in addition to regulating ubiquitylation of H2A. Our results shed light on the epigenetic mechanism of transcriptional regulation, which depends on 3D chromatin reorganization to regulate mES cell differentiation. mouse ES cell mRNA profiles of control, Ring1B knock down, and Dzip3 knock down, in duplicate, using Illumina MiSeq.