Project description:UTX is a histone H3 lysine 27 demethylase required for development. However, the mechanisms underlying developmental gene regulation by UTX are unclear. Here, we discovered a molecular interaction between UTX and 53BP1 that regulates gene expression in a human neurogenesis model. Human 53BP1 contains a UTX-binding site that diverges from its mouse homolog by 41%, and our data suggest that the UTX-53BP1 interaction is conserved in primates but not rodents. ChIP-Seq revealed that the genome-wide targets of UTX and 53BP1 overlap by 84%. We used CRISPR-Cas9 to generate mutations of 53BP1 and UTX in human embryonic stem cells, and found that both 53BP1 and UTX are required to promote the expression of hundreds of neurogenic genes during neural differentiation. Further, 53BP1 is required for human neural progenitor differentiation into neurons. Our findings suggest that the UTX-53BP1 interaction controls gene expression important for neural differentiation in humans.

Project description:UTX is a histone H3 lysine 27 demethylase required for development. However, the mechanisms underlying developmental gene regulation by UTX are unclear. Here, we discovered a molecular interaction between UTX and 53BP1 that regulates gene expression in a human neurogenesis model. Human 53BP1 contains a UTX-binding site that diverges from its mouse homolog by 41%, and our data suggest that the UTX-53BP1 interaction is conserved in primates but not rodents. ChIP-Seq revealed that the genome-wide targets of UTX and 53BP1 overlap by 84%. We used CRISPR-Cas9 to generate mutations of 53BP1 and UTX in human embryonic stem cells, and found that both 53BP1 and UTX are required to promote the expression of hundreds of neurogenic genes during neural differentiation. Further, 53BP1 is required for human neural progenitor differentiation into neurons. Our findings suggest that the UTX-53BP1 interaction controls gene expression important for neural differentiation in humans.

Project description:UTX and 53BP1 co-regulate genetic programs for neural differentiation of human embryonic stem cells

Project description:UTX and 53BP1 co-regulate genetic programs for neural differentiation of human embryonic stem cells [ChIP-seq]

Project description:UTX and 53BP1 co-regulate genetic programs for neural differentiation of human embryonic stem cells [RNA-seq]

Project description:UTX/KDM6A is known to promote open chromatin structure to facilitate gene activation. Although UTX is important for normal and cancer development, its molecular activities in developmental gene regulation remain unclear. Using genetic knockout of UTX in human embryonic stem cells, we show that UTX promotes human pluripotency and suppresses neural differentiation. In human neural stem cells (hNSCs), UTX modulates self-renewal, is required for neuronal differentiation, and suppresses glial/astrocytic differentiation by positively and negatively regulating its target genes. 70% of UTX-occupied regions are associated with epigenetic modifications known to be influenced by UTX, and UTX knockout leads to significant changes in expression of more than 50% of its target genes but epigenetic changes in less than 6% of its target genes. UTX likely affects gene expression via alternative molecular activities in hNSCs. Our findings reveal new functions of UTX in gene regulation and cell fate decisions in human stem cells.

Project description:UTX/KDM6A is known to promote open chromatin structure to facilitate gene activation. Although UTX is important for normal and cancer development, its molecular activities in developmental gene regulation remain unclear. Using genetic knockout of UTX in human embryonic stem cells, we show that UTX promotes human pluripotency and suppresses neural differentiation. In human neural stem cells (hNSCs), UTX modulates self-renewal, is required for neuronal differentiation, and suppresses glial/astrocytic differentiation by positively and negatively regulating its target genes. 70% of UTX-occupied regions are associated with epigenetic modifications known to be influenced by UTX, and UTX knockout leads to significant changes in expression of more than 50% of its target genes but epigenetic changes in less than 6% of its target genes. UTX likely affects gene expression via alternative molecular activities in hNSCs. Our findings reveal new functions of UTX in gene regulation and cell fate decisions in human stem cells.

Project description:UTX/KDM6A is known to promote open chromatin structure to facilitate gene activation. Although UTX is important for normal and cancer development, its molecular activities in developmental gene regulation remain unclear. Using genetic knockout of UTX in human embryonic stem cells, we show that UTX promotes human pluripotency and suppresses neural differentiation. In human neural stem cells (hNSCs), UTX modulates self-renewal, is required for neuronal differentiation, and suppresses glial/astrocytic differentiation by positively and negatively regulating its target genes. 70% of UTX-occupied regions are associated with epigenetic modifications known to be influenced by UTX, and UTX knockout leads to significant changes in expression of more than 50% of its target genes but epigenetic changes in less than 6% of its target genes. UTX likely affects gene expression via alternative molecular activities in hNSCs. Our findings reveal new functions of UTX in gene regulation and cell fate decisions in human stem cells.

Project description:UTX and 53BP1 co-regulate genetic programs for neural differentiation of human embryonic stem cells [mouse RNA-seq]

Project description:In the present study, we show that UTX plays an essential role in resolving and activating many retinoic acid (RA)-inducible bivalent genes during the RA-driven differentiation of mouse ESCs treated with a physiologically relevant RA concentration (0.2 μM). We showed that UTX loss and UTX knockdown interfered with the RA-induced differentiation of mouse ESCs. Therefore, our findings indicate that the UTX-mediated resolution and activation of many RA-inducible bivalent genes, including numerous Hoxa-d cluster genes, are required for RA-driven differentiation of mouse ESCs. ChIP-Seq data for H3K4me3 and H3K27me3 were generated along with input data for mouse stem cells with wild type or UTX-depleted genotype and with or without RA treatment.