Abstract
Proteomic analysis of histones has shown that they are subject to a superabundance of acylations, which extend far beyond acetylation, to include: crotonylation, propionylation, butyrylation, malonylation, succinylation, β-hydroxybutyrylation and 2-hydroxyisobutyrylation. To date, much of the functional data has focussed on histone crotonylation which, similar to acetylation, has been associated with positive gene regulation and is added by the acyltransferase, p300. Although Sirtuins 1–3, along with HDAC3, have been shown to possess decrotonylase activity in vitro, there is relatively little known about the regulation of histone crotonylation in vivo. Here we show that Histone Deacetylase 1 and 2 (HDAC1/2), the catalytic core of numerous co-repressor complexes, are important histone decrotonylase enzymes. A ternary complex of HDAC1/CoREST1/LSD1 is able to hydrolyse both histone H3 Lys18-acetyl (H3K18ac) and H3 Lys18-crotonyl (H3K18cr) peptide substrates. Genetic deletion of HDAC1/2 in ES cells increases global levels of histone crotonylation and causes an 85% reduction in total decrotonylase activity. Furthermore, we mapped H3K18cr in cells using ChIP-seq, with and without HDAC1/2, and observed increased levels of crotonylation, which largely overlaps with H3K18ac in the vicinity of transcriptional start sites. Collectively, our data indicate that HDAC1/2 containing complexes are critical regulators of histone crotonylation in vivo.
Highlights
Histone post-translational modifications (PTM) modulate gene expression and chromatin structure in all eukaryotic cells[1]
Acetyl and crotonyl peptides were incubated with HDAC1/CoREST1/LSD1 for a 60 min period with continuous substrate turnover measured using a Caliper assay
The deacetylase activity of the HDAC1 and HDAC3 can be regulated by inositol phosphates (InsP)[23,24], we asked if InsP levels help determine the rate of decrotonylation
Summary
Histone post-translational modifications (PTM) modulate gene expression and chromatin structure in all eukaryotic cells[1]. Mass spectrometry-based proteomics has recently expanded the repertoire of different histone ‘acylations’ far beyond acetylation to include: crotonylation[3] propionylation[4], butyrylation[4], malonylation[5], succinylation[5,6], β-hydroxybutyrylation[7] and 2-hydroxyisobutyrylation[8] These newly characterised histone PTMs have increased the complexity of chromatin biology and raise questions regarding how this assortment of histone acylations influence chromatin structure and function[6]. SiRNA knockdown of HDAC1/221 or treatment with HDAC inhibitors[22] caused increased levels of histone crotonylation; counterintuitively, the average level of H3K18cr at transcriptional start sites (TSS) was reduced following HDAC inhibitor treatment[22] We extend these data by showing a purified ternary complex of HDAC1/ CoREST1/LSD1 is able to directly hydrolyse both histone H3 Lys18-acetyl (H3K18ac) and H3 Lys18-crotonyl (H3K18cr) peptide substrates. These data indicate that HDAC1/2 containing complexes are critical regulators of histone crotonylation in vivo
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