Project description:Reversible protein acetylation provides a central mechanism for controlling gene expression and cellular signaling events. It is governed by the antagonistic commitment of two enzymes families: the histone acetyltransferases (HATs) and the histone deacetylases (HDACs). HDAC4, like its class IIa counterparts, is a potent transcriptional repressor through interactions with tissue-specific transcription factors via its N-terminal domain. Whilst the lysine deacetylase activity of the class IIa HDACs is much less potent than that of the class I enzymes, HDAC4 has been reported to influence protein deacetylation through its interaction with HDAC3. To investigate the influence of HDAC4 on protein acetylation, we employed the unbiased AcetylScan proteomic screen. We identified many proteins known to be modified by acetylation, but found that the absence of HDAC4 had no effect on the acetylation profile of the murine neonate brain. This is consistent with the biochemical data suggesting that HDAC4 may not function as a lysine deacetylase, but these in vivo data do not support the previous report showing that the enzymatic activity of HDAC3 might be modified by its interaction with HDAC4. To complement this work, we used Affymetrix arrays to investigate the effect of HDAC4 knock-out on the transcriptional profile of the postnatal murine brain. There was no effect on global transcription, consistent with the absence of a differential histone acetylation profile. Validation of the array data by Taq-man qPCR indicated that only protamine 1 and Igfbp6 mRNA levels were increased by more than one-fold and only CamK4 was decreased. The lack of a major effect on the transcriptional profile is consistent with the cytoplasmic location of HDAC4 in the P3 murine brain. mRNA expression analysis was performed by microarray in 3-day-old HDAC4 KO pups and WT littermates. Ten samples were analysed for each genotype. Microarray quality control was performed using the software package provided on RACE (http://race.unil.ch).

Project description:Analysis of Class II Histone Deacetylase (HDAC) regulation of hepatic gluconeogenesis at the gene expression level. We show that in liver, Class IIa HDACs (HDAC4, 5, and 7) are all phosphorylated and excluded from the nucleus by AMPK family kinases. In response to the fasting hormone glucagon, Class IIa HDACs rapidly translocate to the nucleus where they directly bind to the promoters of gluconeogenic enzymes such as G6Pase. In turn, HDAC4/5 mediate the acute transcriptional induction of these genes via deacetylation and activation of Foxo family transcription factors. Loss of Class IIa HDACs in the murine liver results in inhibition of FOXO target genes and lowers blood glucose, resulting in increased glycogen storage. Total RNA obtained from primary hepatocytes infected with shGFP or shHDAC4 & 5 subjected to 2 or 4 hours treatment with DMSO or forskolin.

Project description:Analysis of Class II Histone Deacetylase (HDAC) regulation of hepatic gluconeogenesis at the gene expression level. We show that in liver, Class IIa HDACs (HDAC4, 5, and 7) are all phosphorylated and excluded from the nucleus by AMPK family kinases. In response to the fasting hormone glucagon, Class IIa HDACs rapidly translocate to the nucleus where they directly bind to the promoters of gluconeogenic enzymes such as G6Pase. In turn, HDAC4/5 mediate the acute transcriptional induction of these genes via deacetylation and activation of Foxo family transcription factors. Loss of Class IIa HDACs in the murine liver results in inhibition of FOXO target genes and lowers blood glucose, resulting in increased glycogen storage.

Project description:Our class IIa HDAC inhibitor, NVS-HD1, inhibited HDAC4 with less than 1 nM potency while exhibiting >200 fold selectivity on class IIa HDACs compared to class I (HDAC1, 3, 8) and class IIb (HDAC6) HDACs, making it the most potent and selective class IIa HDAC inhibitor reported so far. We tested the efficacy of NVS-HD1 in the mouse denervation model, either alone or on the genetic background of HDAC4 whole-body inducible knockout (HDAC4 iRKO). Global gene expression changes in gastrocnemius muscles were profiled by RNAseq. In the innervated control legs, HDAC4 knockout or NVS-HD1 caused little changes in gene expression compared to WT mice. HDAC4 knockout or NVS-HD1 mainly reversed denervation induced changes and the genes regulated by them largely overlap, suggesting that NVS-HD1 is quite specific against class IIa HDACs.

Project description:Histone deacetylases (HDACs) are long recognized for important functions in regulating gene transcription in biology and diseases. However, unlike for ubiquitously expressed class I HDACs, we have little mechanistic understanding of class II HDACs that have postulated tissue specific functions. Here we report that class IIa Hdac4 and Hdac7 are up-regulated in transcription through IL-6-Stat3 signaling selectively in mouse T-helper 17 (Th17) cells during lineage-specific differentiation, but not in Th1, Th2, and Treg subtypes. Genetic knockout of Hdac4 or Hdac7 established their importance for Th17 differentiation with different functional mechanisms. Hdac4 works with Th17 transcription factors JunB-Irf4-Batf for transcriptional activation of Th17 signature genes Il17a/f, whereas Hdac7 acts distinctively in concert with Aiolos/Ncor1/Hdac3 co-repressor complex for transcriptional repression of Th17 negative regulators including Il2. Pharmacological inhibition or gene knockout of Hdac4 and Hdac7 ameliorates development of T-cell transfer induced colitis and experimental autoimmune encephalomyelitis (EAE) in mice through blockage of Th17 cell development in colon and central nervous system that recapitulate inflammatory bowel diseases and multiple sclerosis in humans, respectively. Our study highlights a previously unknown distinct mechanisms of Hdac4 and Hdac7 in transcriptional control of Th17 cell development, and rationalizes a new therapeutic strategy of targeting class IIa HDAC4/7 for the treatment of Th17-related inflammatory and autoimmune diseases.

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:In leiomyosarcoma class IIa HDACs bind MEF2 and convert these transcription factors into repressors to sustain proliferation. Theoretically, disruption of this complex should reverse the transformed phenotype. NKL54, a PAOA (pimeloylanilide o-aminoanilide) derivative, binds a hydrophobic groove of MEF2, that is used as a docking site by class IIa HDACs. However, NKL54 could also act as an HDAC inhibitor (HDACI). Therefore, it is not clear which activity is predominant. Here, we show that NKL54 and similar compounds are unable to release MEF2 from binding to class IIa HDACs. Comparative transcriptomic analysis classifies these compounds as strongly related to SAHA/vorinostat. Low expressed genes are upregulated by HDACI, while abundant genes are repressed. This transcriptional resetting correlates with a reorganization of H3K27 acetylation around the TSS. Among the upregulated genes there are several BH3-only family members, thus explaining the induction of apoptosis. Moreover, NKL54 triggers the upregulation of MEF2 and the downregulation of class IIa HDACs. NKL54 also increases the binding of MEF2D to promoters of genes that are upregulated after treatment. In summary, although NKL54 cannot relieve MEF2 from binding to class IIa HDACs binding, it supports MEF2-dependent transcription through several actions, including potentiation of chromatin binding.

Project description:Purpose: Define the transcriptional networks supervising class IIa HDAC expression. Outcome: We demonstrate that MEF2D is the key factor controlling HDAC9 transcription. Comprehensive genome-wide studies demonstrate that HDAC4 and HDAC9 supervise different genetic programs and show both specific and common genomic bindings. Although the number of MEF2-target genes commonly regulated is similar, only HDAC4 represses many additional genes that are not MEF2D targets. HDAC4-/- and HDAC9-/- cells increase H3K27ac levels around the TSS of the respective repressed genes. However, these genes rarely show bindings of the HDACs at their promoters. Frequently HDAC4 and HDAC9 bind intergenic regions. We demonstrate that these regions, recognized by MEF2D/HDAC4/HDAC9 repressive complexes, show the features of active enhancers.

Project description:Purpose: Define the transcriptional networks supervising class IIa HDAC expression. Outcome: We demonstrate that MEF2D is the key factor controlling HDAC9 transcription. Comprehensive genome-wide studies demonstrate that HDAC4 and HDAC9 supervise different genetic programs and show both specific and common genomic bindings. Although the number of MEF2-target genes commonly regulated is similar, only HDAC4 represses many additional genes that are not MEF2D targets. HDAC4-/- and HDAC9-/- cells increase H3K27ac levels around the TSS of the respective repressed genes. However, these genes rarely show bindings of the HDACs at their promoters. Frequently HDAC4 and HDAC9 bind intergenic regions. We demonstrate that these regions, recognized by MEF2D/HDAC4/HDAC9 repressive complexes, show the features of active enhancers.