Project description:Sin3A and Sin3B bind to distinct and overlapping target sites. Sin3 proteins bind to distinct sites in cycling myoblasts whereas there is a converge of Sin3A and Sin3B proteins to sites in differentiated myotubes. We identified a subset of Sin3 target genes involved in muscle differentiation and physiology and showed that conditional ablation of Sin3 proteins in vivo in mouse results in sarcomere defects

Project description:Autophagy is the primary catabolic process triggered in response to starvation. Although autophagic regulation within the cytosolic compartment is well established, it is becoming clear that nuclear events also regulate the induction or repression of autophagy. Nevertheless, a thorough understanding of the mechanisms by which sequence-specific transcription factors modulate expression of genes required for autophagy is lacking. Here, we identify Foxk proteins (Foxk1 and Foxk2) as transcriptional repressors of autophagy in muscle cells and fibroblasts. Interestingly, Foxk1/2 serve to counter-balance another forkhead transcription factor, Foxo3, which induces an overlapping set of autophagic and atrophic targets in muscle. Foxk1/2 specifically recruits Sin3A-HDAC complexes to restrict acetylation of histone H4 and expression of critical autophagy genes. Remarkably, mTOR promotes the transcriptional activity of Foxk1 by facilitating nuclear entry to specifically limit basal levels of autophagy in nutrient-rich conditions. Our study highlights an ancient, conserved mechanism whereby nutritional status is interpreted by mTOR to restrict autophagy by repressing essential autophagy genes via Foxk-Sin3-mediated transcriptional control. Examination of (1) chromatin binding of Foxk1 and Sin3A in non-starved myoblasts and (2) gene expression profiling upon either starvation or siRNA-mediated depletion of Foxk1 relative to a non-starved control.

Project description:Proteins involved in transcriptional regulation harbor a demonstrated enrichment of mutations in neurodevelopmental disorders. The Sin3 (Swi-independent 3)/histone deacetylase (HDAC) complex plays a central role in histone deacetylation and transcriptional repression. Among the two vertebrate paralogs encoding the Sin3 complex, SIN3A variants cause syndromic intellectual disability, but the clinical consequences of SIN3B haploinsufficiency in humans are uncharacterized. Here, we describe a syndrome hallmarked by intellectual disability, developmental delay, and dysmorphic facial features with variably penetrant autism spectrum disorder, congenital malformations, corpus callosum defects, and impaired growth caused by disruptive SIN3B variants. Using chromosomal microarray or exome sequencing, and through international data sharing efforts, we identified nine individuals with heterozygous SIN3B deletion or single-nucleotide variants. Five individuals harbor heterozygous deletions encompassing SIN3B that reside within a ~230 kb minimal region of overlap on 19p13.11, two individuals have a rare nonsynonymous substitution, and two individuals have a single-nucleotide deletion that results in a frameshift and predicted premature termination codon. To test the relevance of SIN3B impairment to measurable aspects of the human phenotype, we disrupted the orthologous zebrafish locus by genome editing and transient suppression. The mutant and morphant larvae display altered craniofacial patterning, commissural axon defects, and reduced body length supportive of an essential role for Sin3 function in growth and patterning of anterior structures. To investigate further the molecular consequences of SIN3B variants, we quantified genome-wide enhancer and promoter activity states by using H3K27ac ChIP-seq. We show that, similar to SIN3A mutations, SIN3B disruption causes hyperacetylation of a subset of enhancers and promoters in peripheral blood mononuclear cells. Together, these data demonstrate that SIN3B haploinsufficiency leads to a hitherto unknown intellectual disability/autism syndrome, uncover a crucial role of SIN3B in the central nervous system, and define the epigenetic landscape associated with Sin3 complex impairment.

Project description:We report the application of single-molecule-based sequencing technology for REST and its cofactors genome wide binding sites in E14 cells.We then combine these binding sirtes with REST regulating gene profiling, to understand REST binding and regulation in E14 cells. Examination of REST and 5 cofactors(RCOR1, RCOR2,RCOR3,SIN3A,SIN3B) in E14 cells, REST and SIN3A endogenous antibody were used for ChIP experiment. The stable E14 cells expressing low level exogenous RCOR1, RCOR2, RCOR3,and SIN3B with V5 tag were used for ChIP experiment with V5 antibody to obtain individual ChIP DNA.

Project description:SIN3 associates with RPD3 and other accessory proteins to form the SIN3 histone modifying complex. A single Sin3A gene encodes multiple SIN3 isoforms, of which SIN3 187 and SIN3 220 are predominant. Previous studies from our laboratory and others have indicated that SIN3 isoforms play non-redundant roles during fly development, however, the genes regulated by SIN3 isoforms are not known. We mapped the genome-wide binding sites of SIN3 isoforms in Drosophila. We established stable S2 cell lines that express either HA-tagged SIN3 187 or SIN3 220. The binding profiles revealed that the majority of the binding sites of SIN3 isoforms are overlapping. Our data revealed that SIN3 isoforms localize to euchromatic regions of the genome and enrichment of SIN3 isoforms are generally concentrated around the transcription start sites of genes. In addition, the extent of SIN3 binding confirmed previous findings indicating that SIN3 is a global transcriptional regulator. Genome-wide binding analysis of SIN3 187 and SIN3 220 in Drosophila. Using chromatin prepared from cell lines expressing either of the isoforms, we performed chromatin immunoprecipitation on chromatin prepared from cells that expresses either of the isoforms using an antibody against HA (ChIP). We coupled our ChIP with high resolution deep sequencing (ChIP-seq) to identify genomic targets of SIN3 isoforms.

Project description:SIN3 associates with RPD3 and other accessory proteins to form the SIN3 histone modifying complex. A single Sin3A gene encodes multiple SIN3 isoforms, of which SIN3 187 and SIN3 220 are predominant. Previous studies from our laboratory and others have indicated that SIN3 isoforms play non-redundant roles during fly development, however, the genes regulated by SIN3 isoforms are not known. We mapped the genome-wide binding sites of SIN3 isoforms in Drosophila. We established stable S2 cell lines that express either HA-tagged SIN3 187 or SIN3 220. The binding profiles revealed that the majority of the binding sites of SIN3 isoforms are overlapping. Our data revealed that SIN3 isoforms localize to euchromatic regions of the genome and enrichment of SIN3 isoforms are generally concentrated around the transcription start sites of genes. In addition, the extent of SIN3 binding confirmed previous findings indicating that SIN3 is a global transcriptional regulator.

Project description:SIN3 is a master transcriptional scaffold protein. SIN3 interacts with RPD3 and other accessory proteins to form a histone modifying complex. A single Sin3A gene encodes multiple isoforms of SIN3, of which SIN3 187 and SIN3 220 are the predominant isoforms. Previous studies demonstrated that SIN3 isoforms play non-redundant roles during fly development. In the current study, we sought to investigate the genes regulated by SIN3 187. S2 cells and cells carrying a stable transgene of SIN3 187HA (SIN3 187HA cells) were treated with 0.07 µM CuSO4. CuSO4 treatment led to ectopic expression of SIN3 187HA. S2 cells were used as a control. Following induction, total mRNA was extracted. mRNA profiling of these samples were performed by deep sequencing using Illumina Hiseq2500. Three biological replicates were performed.

Project description:SIN3 is a master transcriptional scaffold protein. SIN3 interacts with RPD3 and other accessory proteins to form a histone modifying complex. A single Sin3A gene encodes multiple isoforms of SIN3, of which SIN3 187 and SIN3 220 are the predominant isoforms. Previous studies demonstrated that SIN3 isoforms play non-redundant roles during fly development. In the current study, we sought to investigate the genes regulated by SIN3 187.

Project description:Transcription products influenced by decreased SIN3A or SIN3B are analyzed and compared.

Project description:SIN3 the scaffold protein of a histone deacetylase complex interacts with a histone demethylase KDM5 (little imaginal discs - LID) in Drosophila. Reduction of SIN3 or dKDM5/LID both result in similar phenotypes during cell proliferation and wing development. To identify underlying transcriptional changes that may contribute to these phentypic defects we performed whole genome expression analysis in Drosophila cultured cells upon RNAi-mediated knockdown of Sin3A, lid or both. We identified a large number of genes regulated by SIN3, dKDM5/LID or both. While many common genes were regulated by SIN3 and dKDM5/LID an enrichment for genes involved in stress tolerance pathways was observed. Additional RNAseq analysis of expression changes upon knockdown of Sin3A, lid or both under paraquat mediated oxidative stress conditions identified significant changes in genes involved in cell cycle related processes. Drosophila S2 cells were treated with dsRNA targetting Sin3A, lid and both or GFP as control under normal or oxidative stress conitions induced by treatment with paraquat. mRNA profiling of these samples were performed by deep sequencing using Illumina Hiseq2500.Three biological replicates were performed.