Project description:Tissue-specific transcription factors initiate differentiation toward a specialized cell type by inducing transcription-permissive chromatin modifications at target gene promoters, through the recruitment of the SWI/SNF chromatin-remodeling complex (1, 2). The molecular mechanism that regulates the chromatin re-distribution of SWI/SNF in response to differentiation signals is currently unknown. Here we show that the muscle determination factor MyoD and the SWI/SNF structural sub-unit, BAF60c (SMARCD3), form a complex on the regulatory elements of MyoD-target genes in undifferentiated myoblasts, prior to the activation of gene expression. MyoD-BAF60c complex is devoid of the ATP-dependent enzymatic sub-units Brg1 and Brm, is required for stable MyoD binding to Ebox sequences, and marks the chromatin for signal-dependent recruitment of the SWI/SNF core complex to muscle loci. BAF60c phosphorylation on a conserved threonine by differentiation-activated p38 signalling promotes the incorporation of MyoD-BAF60c into a Brg1-based SWI/SNF complex, which is competent to remodel the chromatin and activates transcription of MyoD-target genes. Our data support an unprecedented two-step model, by which pre-assembled BAF60c-MyoD complex directs the SWI/SNF complex chromatin re-distribution to muscle loci in response to differentiation cues. Differentiation of C2C12 cells individually interfered for BRG1, BAF60B, BAF60C

Project description:Signal-dependent incorporation of MyoD-BAF60c into Brg1-based SWI/SNF chromatin-remodeling complex

Project description:The SWI/SNF complex remodels chromatin in an ATP-dependent manner through the ATPase subunits BRG1 and BRM. Chromatin remodeling alters nucleosome structure to change gene expression, however aberrant remodeling and gene expression can result in cancer. The function and localization on chromatin of the SWI/SNF complex depends on the protein makeup of the complex. Here we report the protein-protein interactions of wild-type BRG1 or mutant BRG1 in which the HSA domain has been deleted (BRG1-HSA). We demonstrate the interaction of BRG1 with most SWI/SNF complex members and a failure of a number of these members to interact with BRG1-HSA. These results demonstrate that the HSA domain of BRG1 is a critical interaction platform for the correct formation of SWI/SNF remodeling complexes.

Project description:The composition of chromatin remodeling complexes dictates how these enzymes control transcriptional programs and cellular identity. Here, we investigate the composition of SWI/SNF complexes in embryonic stem cells (ESCs). In contrast to differentiated cells, ESCs have a biased incorporation of certain paralogous SWI/SNF subunits, with low levels of Brm, BAF170 and ARID1B. Upon differentiation, the expression of these subunits increases, resulting in a higher diversity of compositionally distinct SWI/SNF enzymes. We also identify Brd7 as a novel component of the PBAF complex in both ESCs and differentiated cells. Using shRNA-mediated depletion of Brg1, we show that SWI/SNF can function as both a repressor and an activator in pluripotent cells, regulating expression of developmental modifiers and signaling components such as Nodal, ADAMTS1, Bmi-1, CRABP1 and TRH. Knock-down studies of PBAF-specific Brd7 and of a signature subunit within the BAF complex, ARID1A, show that these two sub-complexes affect SWI/SNF target genes differentially, in some cases even antagonistically. This may be due to their different biochemical properties. Finally, we examine the role of SWI/SNF in regulating its target genes during differentiation. We find that SWI/SNF affects recruitment of components of the pre-initiation complex in a promoter-specific manner, to modulate transcription positively or negatively. Taken together, our results provide insight into the function of compositionally diverse SWI/SNF enzymes that underlie their inherent gene-specific mode of action. R1 ESCs were infected in duplicates with shRNA targeting Brg1 or GLUT4 (as a control). Knockdown of Brg1 mRNA affected Brg1 protein levels efficiently. RNA was isolated 67 hours post-infection and analyzed using microarrays.

Project description:Chromatin remodeling complexes instruct cellular differentiation and lineage specific transcription. The BRG1/BRM associated factor (BAF) complexes are important for several aspects of differentiation. We show that the catalytic subunit Brg1 has a specific role in cardiac precursors (CPs) to initiate cardiac gene expression programs and repress non-cardiac expression. Using immunoprecipitation immunopurification with mass spectrometry we determined the dynamic composition of BAF complexes during mammalian cardiac differentiation, identifying several cell-type specific subunits. We focused on the CP- and cardiomyocytes (CM)-enriched subunits BAF60c (SMARCD3) and BAF170 (SMARCC2). Baf60c and Baf170 co-regulate gene expression with Brg1 in CPs, and in CMs their loss results in broadly deregulated cardiac gene expression. BRG1, BAF60, and BAF170 modulate chromatin accessibility, to either promote accessibility at activated genes, while closing up chromatin at repressed genes. BAF60c and BAF170 are required for proper BAF complex composition, and BAF170 loss leads to retention of BRG1 at CP-specific enhancers. Thus, dynamic interdependent BAF complex subunit assembly modulates chromatin states and thereby participates in directing temporal gene expression programs in cardiogenesis.

Project description:The two catalytic subunits of the SWI/SNF chromatin remodeling complex - Brg1 and Brm - have been often implicated as essential components of common biological processes, suggesting a functional redundancy between these two proteins. For instance, earlier works indicated that both proteins are required for the activation of the myogenic program. However, their mutually exclusive pattern of incorporation in SWI/SNF complexes with variable composition and functional heterogeneity predicts that Brg1- and Brm-based SWI/SNF complexes execute specific functions to coordinate gene expression in multistep programs, such as skeletal myogenesis. We detected a distinct expression profile of Brg1 and Brm during the myogenic program, with Brm being upregulated in differentiating myocytes. Genetic knockdown of either Brg1 or Brm in skeletal myoblasts, followed by gene expression analysis, revealed discrete functions during myogenic differentiation. While Brm is required for the exit from the cell cycle at the early stages of differentiation, by repressing CyclinD1 transcription, Brg1 is required for the activation of muscle gene transcription. Interestingly, at later stages of differentiation Brg1 and Brm cooperate to the activation of a cluster of common target genes. Thus, Brg1 and Brm appear to coordinate activation and repression of distinct subsets of genes during initial phase myogenesis, and converge to cooperatively activate the expression of muscle genes at later stages. C2C12 myoblasts treated with siBRM or siBRG1 or siSCR in growth medium (GM) and differentiated by medium replacemnte (DM ). Celles were collected at 18h and 48h from the onset of DM for RNA extraction and microarray analysis. Arrays were used to generate 6 data sets in duplicate.To address the question of which genes were regulated by BRM and/or BRG1 the fold changes in gene expression were calculated between Scrambled siRNA and the BRM or BRG1 siRNA. The experiments were repeated at 2 different time points (18 hours and 48 hours) .

Project description:We previously identified a gene signature predicted to regulate the epithelial-mesenchymal transition (EMT) in both epithelial tissue stem cells and breast cancer cells. A phenotypic RNA interference (RNAi) screen identified the genes within this 140-gene signature that promoted the conversion of mesenchymal epithelial cell adhesion molecule-negative (EpCAM-) breast cancer cells to an epithelial EpCAM+/high phenotype. The screen identified 10 of the 140 genes whose individual knockdown was sufficient to promote EpCAM and E-cadherin expression. Among these 10 genes, RNAi silencing of the SWI/SNF chromatin-remodeling factor Smarcd3/Baf60c in EpCAM- breast cancer cells gave the most robust transition from the mesenchymal to epithelial phenotype. Conversely, expression of Smarcd3/Baf60c in immortalized human mammary epithelial cells induced an EMT. The mesenchymal-like phenotype promoted by Smarcd3/Baf60c expression resulted in gene expression changes in human mammary epithelial cells similar to that of claudin-low triple-negative breast cancer cells. These mammary epithelial cells expressing Smarcd3/Baf60c had upregulated Wnt5a expression. Inhibition of Wnt5a by either RNAi knockdown or blocking antibody reversed Smarcd3/Baf60c-induced EMT. Thus, Smarcd3/Baf60c epigenetically regulates EMT by activating WNT signaling pathways. sampleXreference

Project description:BRG1-SWI/SNF complex is an important chromatin remodeling complex that involved in various biological processes. Here we described the genome-wide binding of histone acetylation upon BRG1 depletion in mouse embryonic stem cells. Mouse embryonic stem cells were treated with either scrambled siRNA or siRNA against BRG1 for 48 h, and each treatment has three replicates.

Project description:BRG1-SWI/SNF complex is an important chromatin remodeling complex that involved in various biological processes. Here we described the genome-wide binding of histone acetylation upon BRG1 depletion in human embryonic stem cells. Human embryonic stem cells were treated with either scrambled siRNA or siRNA against BRG1 for 48 h, and each treatment has three replicates.

Project description:The two catalytic subunits of the SWI/SNF chromatin remodeling complex - Brg1 and Brm - have been often implicated as essential components of common biological processes, suggesting a functional redundancy between these two proteins. For instance, earlier works indicated that both proteins are required for the activation of the myogenic program. However, their mutually exclusive pattern of incorporation in SWI/SNF complexes with variable composition and functional heterogeneity predicts that Brg1- and Brm-based SWI/SNF complexes execute specific functions to coordinate gene expression in multistep programs, such as skeletal myogenesis. We detected a distinct expression profile of Brg1 and Brm during the myogenic program, with Brm being upregulated in differentiating myocytes. Genetic knockdown of either Brg1 or Brm in skeletal myoblasts, followed by gene expression analysis, revealed discrete functions during myogenic differentiation. While Brm is required for the exit from the cell cycle at the early stages of differentiation, by repressing CyclinD1 transcription, Brg1 is required for the activation of muscle gene transcription. Interestingly, at later stages of differentiation Brg1 and Brm cooperate to the activation of a cluster of common target genes. Thus, Brg1 and Brm appear to coordinate activation and repression of distinct subsets of genes during initial phase myogenesis, and converge to cooperatively activate the expression of muscle genes at later stages.