Abstract
Histone deacetylases (HDACs) play a pivotal role in eukaryotic gene expression by modulating the levels of acetylation of chromatin and related transcription factors. In contrast to class I HDACs (HDAC1, -2, -3 and -8), the class IIa HDACs (HDAC4, -5, -7 and -9) harbor cryptic deacetylases activity and recruit the SMRT-HDAC3 complex to repress target genes in vivo. In this regard, the specific interaction between the HDAC domain of class IIa HDACs and the C-terminal region of SMRT repression domain 3 (SRD3c) is known to be critical, but the molecular basis of this interaction has not yet been addressed. Here, we used an extensive mutant screening system, named the “partitioned one- plus two-hybrid system”, to isolate SRD3c interaction-defective (SRID) mutants over the entire catalytic domains of HDAC4 (HDAC4c) and -5. The surface presentation of the SRID mutations on the HDAC4c structure revealed that most of the mutations were mapped to the rim surface of the catalytic entry site, strongly suggesting this mutational hot-spot region as the major binding surface of SRD3c. Notably, among the HDAC4c surface residues required for SRD3c binding, some residues (C667, C669, C751, D759, T760 and F871) are present only in class IIa HDACs, providing the molecular basis for the specific interactions between SRD3c and class IIa enzymes. To investigate the functional consequence of SRID mutation, the in vitro HDAC activities of HDAC4 mutants immuno-purified from HEK293 cells were measured. The levels of HDAC activity of the HDAC4c mutants were substantially decreased compared to wild-type. Consistent with this, SRID mutations of HDAC4c prevented the association of HDAC4c with the SMRT-HDAC3 complex in vivo. Our findings may provide structural insight into the binding interface of HDAC4 and -5 with SRD3c, as a novel target to design modulators specific to these enzymes.
Highlights
Chromatin is the basic structure of the eukaryotic chromosomes, formed as an array of nucleosomes composed of histone octamers wrapped with 146 bp of DNA [1]
We found that the entire region of HDAC4c was necessary and sufficient for optimal interaction with SRD3c, indicating that the intactness of the SRD3cbinding surface of HDAC4 requires the three-dimensional structure, rather than a short motif of HDAC4c
As mentioned in the introduction, the catalytic domain of class IIa Histone deacetylases (HDACs) exhibits a cryptic deacetylase activity toward acetylated lysine substrate, and plays a major role in the recruitment of the SMRT/NCoR-HDAC3 complex to repress the transcription of target genes in vivo
Summary
Chromatin is the basic structure of the eukaryotic chromosomes, formed as an array of nucleosomes composed of histone octamers wrapped with 146 bp of DNA [1]. The tight binding of DNA with histones in condensed chromatin acts as an obstacle for DNA binding of various proteins involved in DNA metabolism, including transcription In this regard, chromatin remodeling and histone tail modifications are major mechanisms to convert chromatin status from closed conformation (inactive) to open conformation (active), or vice versa [2]. Epigenetic control is regarded as a general mechanism for the gene-specific regulation of eukaryotic transcription, as most epigenetic modifications were proven to be reversible and to arise in a promoter-specific manner [4,5] Among these dynamic epigenetic markers, acetylation and deacetylation occur at specific lysine residues within the N-terminal tail of nucleosomal histones through the opposite actions of two respective families of enzymes, the histone acetyltransferases (HATs) and histone deacetylases (HDACs) [2]. A variety of HDAC inhibitors are under clinical investigation, while two HDAC inhibitors, SAHA (vorinostat) and FK228 (romidepsin), were already approved for the treatment of cutaneous T-cell lymphomas [14]
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