Project description:Ikaros encodes a transcription factor that functions as a tumor suppressor in T-ALL. The mechanisms through which Ikaros regulates gene expression and cellular proliferation in T-ALL are unknown. Re-introduction of Ikaros into Ikaros-null T-ALL cells results in cessation of cellular proliferation and induction of T-cell differentiation. We performed dynamic global epigenomic and gene expression analyses to determine the role of Ikaros in tumor suppression during this process. Our results identified novel Ikaros functions in the epigenetic regulation of gene expression: Ikaros directly regulates de novo formation and depletion of enhancers, as well as de novo formation of active enhancers and activation of poised enhancers; Ikaros directly induces the formation of super-enhancers; and Ikaros demonstrates pioneering activity by directly regulating chromatin accessibility. Dynamic analyses demonstrate the long-lasting effect of Ikaros DNA binding on enhancer activation, de novo formation of enhancers and super-enhancers, and chromatin accessibility. Ikaros induces profound, global re-distribution of HDAC1 via recruitment of HDAC1 to promoter and enhancer regions of different target genes. Expression analysis identified a large number of novel signaling pathways that are directly regulated by Ikaros and Ikaros-induced enhancers, and that are responsible for the cessation of proliferation and induction of T-cell differentiation in T-ALL cells.

Project description:Ikaros encodes a transcription factor that functions as a tumor suppressor in T-ALL. The mechanisms through which Ikaros regulates gene expression and cellular proliferation in T-ALL are unknown. Re-introduction of Ikaros into Ikaros-null T-ALL cells results in cessation of cellular proliferation and induction of T-cell differentiation. We performed dynamic global epigenomic and gene expression analyses to determine the role of Ikaros in tumor suppression during this process. Our results identified novel Ikaros functions in the epigenetic regulation of gene expression: Ikaros directly regulates de novo formation and depletion of enhancers, as well as de novo formation of active enhancers and activation of poised enhancers; Ikaros directly induces the formation of super-enhancers; and Ikaros demonstrates pioneering activity by directly regulating chromatin accessibility. Dynamic analyses demonstrate the long-lasting effect of Ikaros DNA binding on enhancer activation, de novo formation of enhancers and super-enhancers, and chromatin accessibility. Ikaros induces profound, global re-distribution of HDAC1 via recruitment of HDAC1 to promoter and enhancer regions of different target genes. Expression analysis identified a large number of novel signaling pathways that are directly regulated by Ikaros and Ikaros-induced enhancers, and that are responsible for the cessation of proliferation and induction of T-cell differentiation in T-ALL cells.

Project description:IKAROS is required for the differentiation of highly proliferative pre-B cell precursors and loss-of-IKAROS function indicates poor prognosis in precursor B-cell acute lymphoblastic leukemia (B-ALL). Here we show that IKAROS regulates this developmental stage by positive and negative regulation of super-enhancers with distinct lineage affiliation. IKAROS together with B cell master regulators, such as PAX5, EBF1 and IRF4, defines super-enhancers at pre-B cell differentiation genes and is required for a highly permissive chromatin environment, a function that cannot be compensated for by the other transcription factors. IKAROS, is also highly enriched at inactive enhancers of genes normally expressed in stem-epithelial cells. Upon IKAROS loss, expression of pre-B cell differentiation genes is attenuated, while a group of extra-lineage transcription factors, directly repressed by IKAROS, and dependent on EBF1 re-localization at their enhancers, are induced. LHX2, LMO2 and TEAD-YAP1 together with other native B cell transcription regulators induce a feed-forward transcriptional loop based on their direct cooperation within a de novo super-enhancer network normally kept separate by IKAROS. Induction of de novo super-enhancers antagonizes Polycomb repression and superimposes aberrant stem-epithelial cell properties in a B cell precursor. This dual mechanism of IKAROS regulation promotes differentiation while safeguarding against a hybrid stem-epithelial-B cell phenotype that underlies high-risk B-ALL.

Project description:Ikaros functions as a master regulator of lymphocyte differentiation and a tumor suppressor. Ikaros binds DNA and regulates gene expression by chromatin remodeling. Mechanisms of Ikaros-mediated tumor suppression are unknown. Here we examined genome-wide occupancy of Ikaros and histone deacetylase 1 (HDAC1) and Histone midificaition markers in human leukemia, and found that the Ikaros and HDAC1 showed similar binding partern and HDAC1–DNA interactions are associated with the presence of bivalent chromatin, and the recruitment of HDAC1 by Ikaros is associated with bivalent chromatin at Ikaros target genes. Examine the genome-wide binding of Ikaros, HDAC1, H3K9me3, H3K9ac, H3K27me3, H3K4me3 and H3K36me3 in Nalm6 ALL leukemia cells.

Project description:Ikaros functions as a master regulator of lymphocyte differentiation and a tumor suppressor. Ikaros binds DNA and regulates gene expression by chromatin remodeling. Mechanisms of Ikaros-mediated tumor suppression are unknown. Here we examined genome-wide occupancy of Ikaros and histone deacetylase 1 (HDAC1) and Histone midificaition markers in human leukemia, and found that the Ikaros and HDAC1 showed similar binding partern and HDAC1–DNA interactions are associated with the presence of bivalent chromatin, and the recruitment of HDAC1 by Ikaros is associated with bivalent chromatin at Ikaros target genes.

Project description:Chronic lymphocytic leukemia (CLL) is a quiescent B-cell malignancy that depends on transcriptional dysregulation for survival. The histone deacetylases are transcriptional regulators whose role within the regulatory chromatin and consequence on the CLL transcriptome is poorly characterized. Here, we profiled and integrated the genome wide occupancy of HDAC1, BRD4, H3K27Ac and H3K9Ac signals with chromatin accessibility, Pol2 occupancy and target expression signatures in CLL cells. We identified that when HDAC1 was recruited within super-enhancers (SEs) marked by acetylated H3K27 and BRD4, it functioned as a transcriptional activator that drove the de novo expression of select genes to facilitate survival and progression in CLL. Targeting HDACs reduced BRD4 and Pol2 engagement to downregulate the transcript and proteins levels of specific oncogenic driver genes in CLL such as BLK, a key mediator of the B-cell receptor pathway, core transcription factors such as PAX5 and IKZF3 and the anti-apoptotic gene, BCL2. Concurrently, HDAC1, when recruited in the absence of super-enhancers repressed target gene expression. HDAC inhibition reversed silencing of a defined set of protein coding and noncoding RNA genes. We focused on a specific set of microRNA genes and show that their upregulation was inversely correlated with the expression of CLL specific survival, transcription factor and signaling genes. Our findings identify that the transcriptional activator and repressor functions of HDACs cooperate within the same tumor to establish the transcriptional dependencies essential for survival in CLL.

Project description:Chronic lymphocytic leukemia (CLL) is a quiescent B-cell malignancy that depends on transcriptional dysregulation for survival. The histone deacetylases are transcriptional regulators whose role within the regulatory chromatin and consequence on the CLL transcriptome is poorly characterized. Here, we profiled and integrated the genome wide occupancy of HDAC1, BRD4, H3K27Ac and H3K9Ac signals with chromatin accessibility, Pol2 occupancy and target expression signatures in CLL cells. We identified that when HDAC1 was recruited within super-enhancers (SEs) marked by acetylated H3K27 and BRD4, it functioned as a transcriptional activator that drove the de novo expression of select genes to facilitate survival and progression in CLL. Targeting HDACs reduced BRD4 and Pol2 engagement to downregulate the transcript and proteins levels of specific oncogenic driver genes in CLL such as BLK, a key mediator of the B-cell receptor pathway, core transcription factors such as PAX5 and IKZF3 and the anti-apoptotic gene, BCL2. Concurrently, HDAC1, when recruited in the absence of super-enhancers repressed target gene expression. HDAC inhibition reversed silencing of a defined set of protein coding and noncoding RNA genes. We focused on a specific set of microRNA genes and show that their upregulation was inversely correlated with the expression of CLL specific survival, transcription factor and signaling genes. Our findings identify that the transcriptional activator and repressor functions of HDACs cooperate within the same tumor to establish the transcriptional dependencies essential for survival in CLL.

Project description:Chronic lymphocytic leukemia (CLL) is a quiescent B-cell malignancy that depends on transcriptional dysregulation for survival. The histone deacetylases are transcriptional regulators whose role within the regulatory chromatin and consequence on the CLL transcriptome is poorly characterized. Here, we profiled and integrated the genome wide occupancy of HDAC1, BRD4, H3K27Ac and H3K9Ac signals with chromatin accessibility, Pol2 occupancy and target expression signatures in CLL cells. We identified that when HDAC1 was recruited within super-enhancers (SEs) marked by acetylated H3K27 and BRD4, it functioned as a transcriptional activator that drove the de novo expression of select genes to facilitate survival and progression in CLL. Targeting HDACs reduced BRD4 and Pol2 engagement to downregulate the transcript and proteins levels of specific oncogenic driver genes in CLL such as BLK, a key mediator of the B-cell receptor pathway, core transcription factors such as PAX5 and IKZF3 and the anti-apoptotic gene, BCL2. Concurrently, HDAC1, when recruited in the absence of super-enhancers repressed target gene expression. HDAC inhibition reversed silencing of a defined set of protein coding and noncoding RNA genes. We focused on a specific set of microRNA genes and show that their upregulation was inversely correlated with the expression of CLL specific survival, transcription factor and signaling genes. Our findings identify that the transcriptional activator and repressor functions of HDACs cooperate within the same tumor to establish the transcriptional dependencies essential for survival in CLL.

Project description:Histone acetyltransferase p300 induces de novo super-enhancers to drive cellular senescence

Project description:Super-enhancers are principal determinants of cell transcription, development, phenotype, and oncogenesis, not yet implicated in host-pathogen interactions. We found four Epstein-Barr virus (EBV) oncoproteins and five EBV-activated NF-M-oM-^AM-+B subunits co-occupying thousand of enhancer sites in EBV-transformed lymphoblastoid cells (LCLs). Of these, 187 had markedly higher and broader histone H3K27ac signals characteristic of super-enhancer formation, and were designated M-bM-^@M-^\EBV super-enhancersM-bM-^@M-^]. EBV super-enhancer associated genes included MYC and BCL2, which enable LCL proliferation and survival. EBV super-enhancers were enriched for specific B cell transcription factor motifs and had high STAT5 and NFAT co-occupancy. EBV super-enhancer associated genes were more highly expressed than other LCL genes. Disruption of EBV super-enhancers by the bromo-domain inhibitor, JQ1, by conditional inactivation of an EBV oncoprotein or NF-M-oM-^AM-+B, decreased MYC or BCL2 gene expression and arrested LCL growth. These findings provide novel insights into the mechanisms by which EBV causes lymphoproliferation and identify opportunities for therapeutic intervention. ChIP-seq was used to define the BRD4 genome-wide landscape in GM12878 lymphoblastoid cells.