Project description:Within the nucleus, G-Protein Pathway Suppressor 2 (GPS2) was first recognized as a component of the core NCoR/SMRT corepressor complex. This is a multi-protein complex that functions as a corepressor for a variety of transcription factors, including nuclear receptors, and promotes the deacetylation of histones on target regulatory regions via its main catalytic unit, the histone deacetylase HDAC3. Based on this association, GPS2 was initially characterized as a transcriptional corepressor, with transcriptomic analysis of various KO/KD models confirming its role in contributing to the repression of inflammatory genes targeted by the NCoR/SMRT complex. To address this knowledge gap, we asked whether GPS2's dual role in transcription could be attributed to the stabilization of distinct chromatin remodeling factors, with the hypothesis that stabilization of other enzymes may, in turn, affect post-transcriptional modification of histone marks in different directions. In particular, we investigated whether GPS2 presence in the NCoR/SMRT complex may prevent HDAC3 ubiquitination. Our results confirmed that lack of GPS2 leads to aberrant HDAC3 ubiquitination and its dismissal for its target genes.

Project description:Here, we systemically investigated the GPS2 corepressor complex function on cyclooxygenase 1 (Ptgs1) in macrophage M2 activation. We found the inflammatory states changed the DNA topology structure along with the histone modification and the gene expression on Ptgs1 locus. GPS2 related NCOR/SMRT corepressor physically bound to Ptgs1 promoter and enhancer, and depletion of all corepressor subunits caused the basal overexpression of Ptgs1 along with the H3K27ac activation. The corepressor subunits display a conserved function on Ptgs1 expression in M2 activation and this regulation is dependent on STAT6 but not through the direct interaction. We find the GPS2 depletion interferences the DNA accessibility on Ptgs1 locus and promotes the enhancer-promoter interaction and the transcriptional process in M2 activation. We further find the GPS2 depletion caused the recruitments of KDM1A, which specifically demethylated the H3K9me2/3 on Ptgs1 locus. In summary, these findings suggest a new paradigm of the corepressor mediated common gene repression in M2 activation and indicate the potential function of the GPS2/NCOR/SMRT function in the tissue homeostasis and wound healing during Th2-mediated immune responses.

Project description:Obesity-associated lipid overload triggers non-alcoholic fatty liver diseases (NAFLD), which in part may be driven by alterations of regulatory transcription networks and hepatocyte-selective epigenomes. Here we demonstrate that G protein pathway suppressor 2 (GPS2), a subunit of the nuclear receptor corepressor (NCOR)/ histone deacetylase 3 (HDAC3) complex, is a central component of such networks and accelerates the progression of non-alcoholic steatohepatitis (NASH). In hepatocyte-specific Gps2 knockout mice, loss of GPS2 alleviated the development of diet-induced steatosis and fibrosis and caused activation of lipid catabolic genes. By determining differential cistromes, epigenomes and transcriptomes in wild-type, single and double knockout mice, we identified the lipid-sensing nuclear receptor PPARa as a direct target of GPS2. We also provide evidence that in hepatocytes, unlike in macrophages, GPS2 acts in concert with the NCOR subunit of the corepressor complex. By analyzing the liver transcriptomes of human patients, we found that GPS2 expression positively correlated with the expression of NASH/fibrosis signature genes. Collectively, our data suggest that the GPS2-PPARa partnership in hepatocytes may influence the development of NASH/fibrosis in mice and in humans.

Project description:Changing the somatic cell transcriptome to a pluripotent state using exogenous reprogramming factors needs transcriptional co-regulators that help activate or suppress gene expression and rewrite the epigenome. Here, we show that reprogramming-specific engagement of the NCoR/SMRT co-repressor complex at key pluripotency loci creates an epigenetic block to reprogramming. HDAC3 executes the repressive function of NCoR/SMRT in reprogramming by inducing histone deacetylation at these loci. Recruitment of NCoR/SMRT-HDAC3 to pluripotency genes is facilitated by all 4 Yamanaka factors (OCT4, SOX2, KLF4 and c-MYC) but mostly by c-MYC. Class IIa HDACs further potentiate this recruitment by interacting with both the reprogramming factors and NCoR/SMRT. Consequently, depleting NCoR/SMRT-HDAC3 function enables high efficiency of reprogramming, while elevating NCoR/SMRT-HDAC3 recruitment at pluripotency loci by over-expressing constitutively active class IIa HDACs derails it. Our findings thus uncover an unexpected epigenetic mechanism involving c-MYC, whose manipulation greatly enhances reprogramming efficiency.

Project description:Changing the somatic cell transcriptome to a pluripotent state using exogenous reprogramming factors needs transcriptional co-regulators that help activate or suppress gene expression and rewrite the epigenome. Here, we show that reprogramming-specific engagement of the NCoR/SMRT co-repressor complex at key pluripotency loci creates an epigenetic block to reprogramming. HDAC3 executes the repressive function of NCoR/SMRT in reprogramming by inducing histone deacetylation at these loci. Recruitment of NCoR/SMRT-HDAC3 to pluripotency genes is facilitated by all 4 Yamanaka factors (OCT4, SOX2, KLF4 and c-MYC) but mostly by c-MYC. Class IIa HDACs further potentiate this recruitment by interacting with both the reprogramming factors and NCoR/SMRT. Consequently, depleting NCoR/SMRT-HDAC3 function enables high efficiency of reprogramming, while elevating NCoR/SMRT-HDAC3 recruitment at pluripotency loci by over-expressing constitutively active class IIa HDACs derails it. Our findings thus uncover an unexpected epigenetic mechanism involving c-MYC, whose manipulation greatly enhances reprogramming efficiency.

Project description:The association between hyper-inflammatory states and numerous diseases is widely recognized, but our understanding of the molecular strategies that have evolved to prevent uncontrolled activation of inflammatory responses remains incomplete. Here, we report a critical, non-transcriptional role of GPS2 as a guardian against hyperstimulation of TNFA-induced gene program. GPS2 cytoplasmic actions are required to specifically modulate RIP1 ubiquitylation and JNK activation by inhibiting TRAF2/Ubc13 enzymatic activity. In vivo relevance of GPS2 anti-inflammatory role is confirmed by inhibition of TNFA target genes in macrophages and by improved insulin signaling in the adipose tissue of aP2-GPS2 transgenic mice. As the non-transcriptional role is complemented by GPS2 functioning as positive and negative cofactor for nuclear receptors, in vivo overexpression also results in elevated circulating level of resistin and development of hepatic steatosis. Together, these studies define GPS2 as a molecular guardian required for precise control of inflammatory responses involved in immunity and homeostasis. RNA-sequencing of polyA selected RNA molecules in 293T cells and ChIP-seq of GPS2, TBL1, and NCOR.

Project description:We report the genomic regions enriched in Histone Deacetylase 3 (HDAC3) in mouse livers. We also report the change of HDAC3 occupancy upon DAD mutations in NCOR and SMRT. HDAC3 enriched genomic regions in WT and NS-DADm mice livers using Illumina GAIIx.

Project description:We report the genomic regions enriched in Histone Deacetylase 3 (HDAC3) in mouse livers. We also report the change of HDAC3 occupancy upon DAD mutations in NCOR and SMRT.

Project description:GPS2 and HDAC3 ChIP-Seq in GPS2-KO MCF-7 [ChIP-Seq]

Project description:GPS2 and HDAC3 RNA-Seq in GPS2-KO MCF-7 [RNA-Seq]