Project description:Loss of the chromatin remodeler WSTF (BAZ1B), a gene deleted in Williams syndrome, causes reproducible, genome-scale reprogramming of chromatin states and transcript processing that links altered chromatin composition to misprocessed transcripts and aberrant signaling. Using engineered HCT116-WSTFKO cells and patient-derived Williams syndrome cell lines, we combine transcriptome profiling, microscopy, chromatin CUT&RUN, and histone post-translational modification (HPTM)-defined chromatin state modeling to show that WSTF localizes to promoters and gene bodies of actively transcribed loci together with ASH2L and CBP. Loss of WSTF causes depletion of ASH2L/CBP, selective loss of H3K4me2 and multiple acetylation marks, and gain of Polycomb components. This loss results in systematic conversion from a multi-mark active promoter/enhancer chromatin landscape to a hypoacetylated, H3K4me2-depleted, PRC-enriched landscape. These chromatin changes coincide with widespread isoform switching and splicing alterations in genes encoding chromatin regulators and signaling pathways. This WSTF deficiency produces Wnt/β-catenin hyperactivation. A locus-specific example at TCF7L2 demonstrates how gene body loss of active marks drives isoform switching that alters DNA binding domains and decouples stabilized nuclear β-catenin from canonical target engagement. Our results link signaling dysregulation to developmental pathway misregulation consistent with Williams syndrome phenotypes.

Project description:Williams syndrome transcription factor (WSTF) is a multifaceted protein that is involved in several nuclear processes, including replication, transcription, and the DNA damage response. WSTF participates in a chromatin-remodeling complex with the ISWI ATPase, SNF2H, and is thought to contribute to the maintenance of heterochromatin, including at the human inactive X chromosome (Xi). WSTF is encoded by BAZ1B, and is one of twenty-eight genes that are hemizygously deleted in the genetic disorder Williams-Beuren syndrome (WBS). To explore the function of WSTF, we performed zinc finger nuclease-assisted targeting of the BAZ1B gene and isolated several independent knockout clones in human cells. Our results show that, while heterochromatin at the Xi is unaltered, new inappropriate areas of heterochromatin spontaneously form and resolve throughout the nucleus. In three independent mutants, the expression of a large number of genes were impacted, both up and down, by WSTF loss. In addition, we found that cells lacking WSTF responded appropriately to vitamin D treatment, a process we expected to be disrupted. Given the inappropriate appearance of regions of heterochromatin in BAZ1B knockout cells, it is evident that WSTF performs a critical role in maintaining chromatin and transcriptional states. Clearly, further exploration is necessary to fully understand the role of WSTF in maintenance of the epigenome and how WSTF haploinsufficiency contributes to the wide array of symptoms exhibited in WBS patients. Samples include three replicate miroarray hybridizations of the parental cells (hTERT-RPE1), three replicates from three independent knock-out clones (D5, F3 and M1), and one set of replicates for a heterozygous mutant clone (A6).

Project description:Williams syndrome transcription factor (WSTF) is a multifaceted protein that is involved in several nuclear processes, including replication, transcription, and the DNA damage response. WSTF participates in a chromatin-remodeling complex with the ISWI ATPase, SNF2H, and is thought to contribute to the maintenance of heterochromatin, including at the human inactive X chromosome (Xi). WSTF is encoded by BAZ1B, and is one of twenty-eight genes that are hemizygously deleted in the genetic disorder Williams-Beuren syndrome (WBS). To explore the function of WSTF, we performed zinc finger nuclease-assisted targeting of the BAZ1B gene and isolated several independent knockout clones in human cells. Our results show that, while heterochromatin at the Xi is unaltered, new inappropriate areas of heterochromatin spontaneously form and resolve throughout the nucleus. In three independent mutants, the expression of a large number of genes were impacted, both up and down, by WSTF loss. In addition, we found that cells lacking WSTF responded appropriately to vitamin D treatment, a process we expected to be disrupted. Given the inappropriate appearance of regions of heterochromatin in BAZ1B knockout cells, it is evident that WSTF performs a critical role in maintaining chromatin and transcriptional states. Clearly, further exploration is necessary to fully understand the role of WSTF in maintenance of the epigenome and how WSTF haploinsufficiency contributes to the wide array of symptoms exhibited in WBS patients.

Project description:This SuperSeries is composed of the SubSeries listed below Histone methylation is essential for regulating gene expression during organogenesis to maintain stem cells and execute a proper differentiation program for their descendants. Here, we show that the COMPASS family histone methyltransferase co-factor ASH2L is required for maintaining neural progenitor cells (NPCs) and the production and positioning of projection neurons during neocortex development. Specifically, loss of ASH2L in NPCs results in malformation of the neocortex; the mutant neocortex shows fewer neurons that are also abnormal in composition and laminar position. Moreover, ASH2L loss impairs the trimethylation of H3K4 and the transcriptional machinery specific for Wnt-β-catenin signaling, inhibiting the proliferation ability of NPCs at late stages of neurogenesis by disrupting S phase entry to inhibit cell cycle progression. Overexpressing β-catenin after ASH2L elimination rescues the proliferation deficiency. Therefore, our findings demonstrate ASH2L is crucial for modulating Wnt signaling to maintain NPCs and generate a full complement of neurons during mammalian neocortex development.

Project description:Cell fate decisions are closely associated with changes in gene expression programs. A large number of post-translational modifications of core histones contribute to controlling the expression of genes. A modification that is closely correlated with open chromatin and gene transcription is methylation of lysine 4 of histone H3 (H3K4). It is catalyzed by methyltransferases of the KMT2 family, which require interaction with 4 core subunits, WDR5, RBBP5, ASH2L and DPY30, for catalytic activity. Ash2l is required for organismal development and for tissue homeostasis in the mouse. In mouse embryo fibroblasts (MEFs), the loss of Ash2l results in downregulated gene expression, which provokes a senescence phenotype. We now find that both H3K4 mono- and tri-methylation (H3K4me1 and me3, respectively) are deregulated. H3K4me3 is lost while H3K4me1 is increased at promoters upon knockout of Ash2l. In particular, loss of H3K4me3 at promoters correlates with downregulation of gene expression, which is particularly obvious at CpG island promoters. Ash2l loss results in an increase of histone H3 loading at promoters, paralleled by enhanced chromatin compaction. This is accompanied by an increase of repressing and a decrease of activating histone marks. One of the sequence-specific transcription factors with altered binding upon depletion of Ash2l is CTCF. It is lost from some promoter-associated sites, but gained binding in other regions of the genome. This suggests that in addition to the well-known effects on H3K4 methylation upon depleting KMT2 complex components, Ash2l loss affects chromatin compaction. Whether the decrease of H3K4me3 promotes chromatin compaction at promoters or whether these are independent consequences of Ash2l loss remains to be determined. We suggest that both contribute mechanistically to gene repression and thus to the observed cellular effects.

Project description:Cell fate decisions are closely associated with changes in gene expression programs. A large number of post-translational modifications of core histones contribute to controlling the expression of genes. A modification that is closely correlated with open chromatin and gene transcription is methylation of lysine 4 of histone H3 (H3K4). It is catalyzed by methyltransferases of the KMT2 family, which require interaction with 4 core subunits, WDR5, RBBP5, ASH2L and DPY30, for catalytic activity. Ash2l is required for organismal development and for tissue homeostasis in the mouse. In mouse embryo fibroblasts (MEFs), the loss of Ash2l results in downregulated gene expression, which provokes a senescence phenotype. We now find that both H3K4 mono- and tri-methylation (H3K4me1 and me3, respectively) are deregulated. H3K4me3 is lost while H3K4me1 is increased at promoters upon knockout of Ash2l. In particular, loss of H3K4me3 at promoters correlates with downregulation of gene expression, which is particularly obvious at CpG island promoters. Ash2l loss results in an increase of histone H3 loading at promoters, paralleled by enhanced chromatin compaction. This is accompanied by an increase of repressing and a decrease of activating histone marks. One of the sequence-specific transcription factors with altered binding upon depletion of Ash2l is CTCF. It is lost from some promoter-associated sites, but gained binding in other regions of the genome. This suggests that in addition to the well-known effects on H3K4 methylation upon depleting KMT2 complex components, Ash2l loss affects chromatin compaction. Whether the decrease of H3K4me3 promotes chromatin compaction at promoters or whether these are independent consequences of Ash2l loss remains to be determined. We suggest that both contribute mechanistically to gene repression and thus to the observed cellular effects.

Project description:Cell fate decisions are closely associated with changes in gene expression programs. A large number of post-translational modifications of core histones contribute to controlling the expression of genes. A modification that is closely correlated with open chromatin and gene transcription is methylation of lysine 4 of histone H3 (H3K4). It is catalyzed by methyltransferases of the KMT2 family, which require interaction with 4 core subunits, WDR5, RBBP5, ASH2L and DPY30, for catalytic activity. Ash2l is required for organismal development and for tissue homeostasis in the mouse. In mouse embryo fibroblasts (MEFs), the loss of Ash2l results in downregulated gene expression, which provokes a senescence phenotype. We now find that both H3K4 mono- and tri-methylation (H3K4me1 and me3, respectively) are deregulated. H3K4me3 is lost while H3K4me1 is increased at promoters upon knockout of Ash2l. In particular, loss of H3K4me3 at promoters correlates with downregulation of gene expression, which is particularly obvious at CpG island promoters. Ash2l loss results in an increase of histone H3 loading at promoters, paralleled by enhanced chromatin compaction. This is accompanied by an increase of repressing and a decrease of activating histone marks. One of the sequence-specific transcription factors with altered binding upon depletion of Ash2l is CTCF. It is lost from some promoter-associated sites, but gained binding in other regions of the genome. This suggests that in addition to the well-known effects on H3K4 methylation upon depleting KMT2 complex components, Ash2l loss affects chromatin compaction. Whether the decrease of H3K4me3 promotes chromatin compaction at promoters or whether these are independent consequences of Ash2l loss remains to be determined. We suggest that both contribute mechanistically to gene repression and thus to the observed cellular effects.

Project description:We discovered that WSTF is downregulated in senescent cells by autophagy degradation. Forced expression of WSTF inhibits senescence-associated secretory phenotype, via inhibition of chromatin accesibility over inflammatory genes.

Project description:We discovered that WSTF is downregulated in senescent cells by autophagy degradation. Forced expression of WSTF inhibits senescence-associated secretory phenotype, via inhibition of chromatin accesibility over inflammatory genes.

Project description:BAF (SWI/SNF) chromatin remodelers engage binding partners to generate sitespecific DNA accessibility. However, the basis for interactions between BAF and divergent binding partners has remained unclear. Here we tested the hypothesis that scaffold proteins augment BAF’s binding repertoire by examining β-catenin and steroidogenic factor-1 (SF-1, NR5A1), a β-catenin–dependent transcription factor central to steroid production. In steroidogenic cell lines, BAF inhibition rapidly opposed overlapping SF-1/β-catenin enhancer occupancy, thereby impairing SF-1 target activation, steroid production, and SF-1/β-catenin autoregulation. These effects arise due to β-catenin’s role as an adapter between SF-1 and an intrinsically disordered region (IDR) of the canonical BAF (cBAF) subunit ARID1A. In contrast to exclusively IDR-driven mechanisms, folded Armadillo repeats on β-catenin were required to bind cBAF. β-catenin similarly linked cBAF to SOX2, FOXO3, YAP1, and CBP/p300. Visualization of contacts highlighted β-catenin’s central role in IDR-dependent interaction of cBAF with diverse transcription factors and chromatin regulators. The cross-linking dataset was used to validate the interaction interface obtained with computational modelling.