Project description:Although reprogramming of somatic cells to generate inducible pluripotent stem cells (iPSCs) is associated with remarkable epigenetic changes, the role and mechanisms of epigenetic factors in this process remains poorly understood. Here we describe identification of Jmjd3 as a potent negative regulator of reprogramming. Jmjd3-deficient MEFs produced significantly more iPSC colonies than did wild-type cells, while ectopic expression of Jmjd3 markedly inhibited reprogramming. We further show that the inhibitory effects of Jmjd3 are produced through both histone demethylase-dependent and -independent pathways acting in concert. The latter pathway is entirely novel and involved Jmjd3 targeting of PHF20 for ubiquitination and degradation by recruiting an E3 ligase Trim26. Importantly, PHF20-deficient MEFs could not be converted to fully reprogrammed iPSCs, even with knockdown of Jmjd3, Ink4a or p21, indicating dominant effects of this protein on reprogramming. Our findings identify a previously unrecognized role of Jmjd3 in reprogramming and provide molecular insight into the mechanisms by which the Jmjd3-PHF20 axis controls the reprogramming process. This study was an examination of phf20 and wdr5 binding patterns in embryonic stem cells, using a ChIP-Sequencing methodology with antibodies for each of these factors in the cell lines indicated.

Project description:The methyl lysine readers PHF (plant homeodomain finger) 20 (PHF20) and its homolog PHF20 Like 1 (PHF20L1) are known components of the NSL (non-specific lethal) complex that regulates gene expression through its histone acetyltransferase activity. In the current model, both PHF homologs coexist in the same NSL complex although this was not formally tested; nor have the functions of PHF20 and PHF20L1 regarding NSL complex integrity and transcriptional regulation been investigated. By performing an in-depth biochemical and functional characterization, we define the association and contributions of the two methyl lysine reader homologs PHF20 and PHF20L1 to the NSL complex.

Project description:Glioblastoma (GBM) is the most common tumor of the central nervous system with poor prognosis. PHF20 was highly expressed in primary human glioma specimens. However, the molecular mechanism of by which PHF20 regulated glioblastoma remains poorly understood. In the study, we investigate the gene expression profile of that regulated by PHF20 in U87 cells.

Project description:The methyl lysine readers PHF (plant homeodomain finger) 20 (PHF20) and its homolog PHF20 Like 1 (PHF20L1) are known components of the NSL (non-specific lethal) complex that regulates gene expression through its histone acetyltransferase activity. In the current model, both PHF homologs coexist in the same NSL complex although this was not formally tested; nor have the functions of PHF20 and PHF20L1 regarding NSL complex integrity and transcriptional regulation been investigated. Here we perform an in-depth biochemical and functional characterization of PHF20 and PHF20L1 in the context of the NSL complex. We identify the existence of two distinct NSL complexes that exclusively contain either PHF20 or PHF20L1; the two PHF homologs do not complex together in the same NSL species. Our data show that the C-terminal domains are essential for PHF20 and PHF20L1 to complex with NSL and the Tudor 2 domains of PHF20 and PHF20L1 are required for chromatin binding. The genome-wide landscape of PHF20/PHF20L1 binding to chromatin shows that they bind mostly to the same genomic regions, at promoters of highly expressed/housekeeping genes. Yet, deletion of PHF20 and PHF20L1 does not abrogate gene expression of the identified targets or impact the recruitment of NSL to the promoters of those genes, suggesting the existence of an alternative mechanism that compensates for the transcription of genes whose sustained expression is important for critical cellular functions.

Project description:PHF20 is a core component of the lysine acetyltransferase complex MOF-NSL that produces the major epigenetic mark, H4K16ac, and is necessary for transcriptional regulation and DNA repair, however the role of PHF20 in the complex remains elusive. Here, we report on functional crosstalk between epigenetic readers of PHF20. We show that the PHF20 PHD finger recognizes dimethylated lysine 4 of histone H3 (H3K4me2) and represents first example of a native PHD reader selective for this modification. Biochemical and structural analyses illuminate the molecular mechanism underlying this function and explain the preference of Tudor2, another reader in PHF20, for dimethylated p53. Binding of the PHD finger to H3K4me2 is required for histone acetylation, accumulation of PHF20 at target genes, and transcriptional activation. Together, our findings establish a novel PHF20-mediated link between MOF HAT, p53 and H3K4me2-dependent cellular events and suggest a model for rapid spreading of H4K16ac-encriched open chromatin.

Project description:Protein post-translational modifications transmit signals in part by creating binding sites for effector molecules. This is especially true in epigenetic pathways where histone tails are heavily modified, resulting in the recruitment of molecules that can affect transcription. One such molecule, plant homeodomain finger protein 20 (PHF20), uses a Tudor domain to read dimethyl-lysine residues and is a known component of the MOF histone acetyltransferase protein complex, suggesting it plays a role in the crosstalk between lysine methylation and histone acetylation. We sought to investigate the biological role of PHF20 by generating a knockout mouse. Without PHF20, mice die shortly after birth and display a wide variety of phenotypes within the skeletal and hematopoietic systems. Mechanistically, PHF20 is not required for maintaining the global H4K16 acetylation levels, but instead works downstream in transcriptional regulation of MOF target genes. ChIP sequencing of H4K16ace ChIP DNA from PHF20 knockout and wild type cells using Illumina Solexa Genome Analyzer II single end sequencing protocol.

Project description:CYLD is a tumor suppressor gene coding for a deubiquitinating enzyme that has a critical regu-latory function in a variety of signaling pathways and biological processes involved in cancer development and progression, many of which are also key modulators of somatic cell repro-gramming. Nevertheless, the potential role of CYLD in this process has not been studied. With the dual aim of investigating the involvement of CYLD in reprogramming and better under-standing the intricate regulatory system governing this process, we reprogrammed control (CYLDWT/WT ) and CYLD-deficient (CYLDΔ9/Δ9 ) Mouse Embryonic Fibroblasts (MEFs) into induced Pluripotent Stem Cells (iPSCs) through ectopic overexpression of the Yamanaka factors (Oct3/4, Sox2, Klf4, c-Myc) . CYLD deficiency led to significantly reduced reprogramming efficiency and slower early reprogramming kinetics. Nevertheless, CYLD-deficient cells were capable of estab-lishing pluripotent colonies with full spontaneous differentiation potential. The introduction of WT CYLD to CYLDΔ9/Δ9 MEFs rescued the phenotype. Whole proteome analysis revealed that the Mesenchymal to Epithelial transition (MET) during the early stages of reprogramming was dis-rupted in CYLDΔ9/Δ9 MEFs. Interestingly, pathway analysis revealed that the primary processes affected by CYLD deficiency were associated with the extracellular matrix and several metabolic pathways. Our findings not only establish CYLD's significance as a regulatory component of early reprogramming but also highlight its role as an extracellular matrix regulator, which has profound implications in cancer research.

Project description:We established a new reprogramming cocktail named JGES, which is capable of converting MEFs to iPSCs with high efficiency. Mechanism study shown NuRD-Sall4 interaction is the key.

Project description:We investigated genome-wide nucleosome coverage and histone methylation occupancies in somatic MEFs, intermediate pre-iPSCs and fully reprogrammed iPSCs. We found that nucleosome occupancies increased in promoter regions and decreased in intergenic regions in pre-iPSCs and then recover to an intermediate level in iPSCs. Nucleosomes in pre-iPSCs are much more phased than those in MEFs and iPSCs. Bivalent, active, repressive domains are cell type-specific and change dynamically during reprogramming. HCG and LCG promoters exhibit distinct nucleosome occupancy patterns and are dynamically marked by H3K4me3/H3K27me3 during reprogramming, correspondingly showing different gene activities. Surprisingly, Vitamin C promotes nucleosome reorganization from pre-iPSCs to iPSCs. CTCF binding sites change dynamically during reprogramming, though they share a conserved binding motif. Nucleosome occupies CTCF sites to a higher extent in pre-iPSCs than those in MEFs and iPSCs. Taken together, our study reveals that dynamic changes of nucleosome positioning and chromatin organization associated gene regulation during reprogramming. Examine dynamics of nucleosome positioning and histone modification profiles as well as gene expression regulation during somatic cell reprogramming

Project description:We investigated genome-wide nucleosome coverage and histone methylation occupancies in somatic MEFs, intermediate pre-iPSCs and fully reprogrammed iPSCs. We found that nucleosome occupancies increased in promoter regions and decreased in intergenic regions in pre-iPSCs and then recover to an intermediate level in iPSCs. Nucleosomes in pre-iPSCs are much more phased than those in MEFs and iPSCs. Bivalent, active, repressive domains are cell type-specific and change dynamically during reprogramming. HCG and LCG promoters exhibit distinct nucleosome occupancy patterns and are dynamically marked by H3K4me3/H3K27me3 during reprogramming, correspondingly showing different gene activities. Surprisingly, Vitamin C promotes nucleosome reorganization from pre-iPSCs to iPSCs. CTCF binding sites change dynamically during reprogramming, though they share a conserved binding motif. Nucleosome occupies CTCF sites to a higher extent in pre-iPSCs than those in MEFs and iPSCs. Taken together, our study reveals that dynamic changes of nucleosome positioning and chromatin organization associated gene regulation during reprogramming.