Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Embryonic stem cells (ESCs) maintain pluripotency through unique epigenetic states. When ESCs commit to a specific cell lineage, changes in histone modifications and DNA methylation accompany the transition to more specialized cell types. Investigating how epigenetic regulation maintains pluripotency is a critical component in order to generate the required cell types for future clinical application. Uhrf1 is a widely known hemi-methylated DNA binding protein, playing a role in heterochromatin formation alongside G9a, Trim28 and HDACs. In addition, it has been demonstrated that Uhrf1 functions to maintain DNA methylation through the recruitment of Dnmt1. Although Uhrf1 is not essential in ESC self-renewal, it still remains elusive how Uhrf1 regulates pluripotency. Here, we set out to elucidate the role of Uhrf1 in pluripotent stem cells. We found that Uhrf1 forms a complex with the active trithorax group of transcriptional regulators, in particular the Setd1a/COMPASS complex. Our data show that loss of Uhrf1 causes a dramatic reduction of bivalent histone marks, in particular those associated with neuroectoderm and mesoderm specification. Overall, our data demonstrate that Uhrf1 safeguards the balance between pluripotency and differentiation via the Setd1a/COMPASSS complex, through which Uhrf1 mediates bivalent histone modifications.

Project description:Embryonic stem cells (ESCs) maintain pluripotency through unique epigenetic states. When ESCs commit to a specific cell lineage, changes in histone modifications and DNA methylation accompany the transition to more specialized cell types. Investigating how epigenetic regulation maintains pluripotency is a critical component in order to generate the required cell types for future clinical application. Uhrf1 is a widely known hemi-methylated DNA binding protein, playing a role in heterochromatin formation alongside G9a, Trim28 and HDACs. In addition, it has been demonstrated that Uhrf1 functions to maintain DNA methylation through the recruitment of Dnmt1. Although Uhrf1 is not essential in ESC self-renewal, it still remains elusive how Uhrf1 regulates pluripotency. Here, we set out to elucidate the role of Uhrf1 in pluripotent stem cells. We found that Uhrf1 forms a complex with the active trithorax group of transcriptional regulators, in particular the Setd1a/COMPASS complex. Our data show that loss of Uhrf1 causes a dramatic reduction of bivalent histone marks, in particular those associated with neuroectoderm and mesoderm specification. Overall, our data demonstrate that Uhrf1 safeguards the balance between pluripotency and differentiation via the Setd1a/COMPASSS complex, through which Uhrf1 mediates bivalent histone modifications.

Project description:Embryonic stem cells (ESCs) maintain pluripotency through unique epigenetic states. When ESCs commit to a specific cell lineage, changes in histone modifications and DNA methylation accompany the transition to more specialized cell types. Investigating how epigenetic regulation maintains pluripotency is a critical component in order to generate the required cell types for future clinical application. Uhrf1 is a widely known hemi-methylated DNA binding protein, playing a role in heterochromatin formation alongside G9a, Trim28 and HDACs. In addition, it has been demonstrated that Uhrf1 functions to maintain DNA methylation through the recruitment of Dnmt1. Although Uhrf1 is not essential in ESC self-renewal, it still remains elusive how Uhrf1 regulates pluripotency. Here, we set out to elucidate the role of Uhrf1 in pluripotent stem cells. We found that Uhrf1 forms a complex with the active trithorax group of transcriptional regulators, in particular the Setd1a/COMPASS complex. Our data show that loss of Uhrf1 causes a dramatic reduction of bivalent histone marks, in particular those associated with neuroectoderm and mesoderm specification. Overall, our data demonstrate that Uhrf1 safeguards the balance between pluripotency and differentiation via the Setd1a/COMPASSS complex, through which Uhrf1 mediates bivalent histone modifications.

Project description:Uhrf1 regulates active transcriptional marks at bivalent domains in pluripotent stem cells through Setd1a

Project description:Uhrf1 regulates active transcriptional marks at bivalent domains in pluripotent stem cells through Setd1a [ATAC-Seq]

Project description:Uhrf1 regulates active transcriptional marks at bivalent domains in pluripotent stem cells through Setd1a [RNA-Seq]

Project description:Uhrf1 regulates active transcriptional marks at bivalent domains in pluripotent stem cells through Setd1a [ChIP-Seq]

Project description:Histone methyltransferase SETD1A is critical for acute myeloid leukemia (AML) cell survival, but the molecular mechanism driving SETD1A gene regulation remains elusive. To delineate the role of SETD1A, we utilize a protein degrader technology to induce rapid SETD1A degradation in AML cell lines. SETD1A degradation results in immediate downregulation of transcripts associated with DNA repair and heme biosynthesis pathways. CRISPR-based functional analyses and metabolomics reveal an essential role of SETD1A to maintain mitochondrial respiration in AML cells. These SETD1A targets are enriched in head-to-head (H2H) genes. SETD1A degradation disrupts a non-enzymatic SETD1A domain-dependent cyclin K function, increases the Ser5P RNA polymerase II (RNAPII) at the transcriptional start site (TSS), and induces the promoter-proximal pausing of RNAPII in a strand-specific manner. This study reveals a non-enzymatic role for SETD1A in transcriptional pause release and provides insight into the mechanism of RNAPII pausing and its function in cancer.

Project description:This SuperSeries is composed of the SubSeries listed below.