Global assessment of combinatorial post-translational modification of core histones in yeast using contemporary mass spectrometry. LYS4 trimethylation correlates with degree of acetylation on the same H3 tail

A global view of all core histones in yeast is provided by tandem mass spectrometry of intact histones H2A, H2B, H4, and H3. This allowed detailed characterization of >50 distinct histone forms and their semiquantitative assessment in the deletion mutants gcn5Delta, spt7Delta, ahc1Delta, and rtg2Delta, affecting the chromatin remodeling complexes SAGA, SLIK, and ADA. The "top down" mass spectrometry approach detected dramatic decreases in acetylation on H3 and H2B in gcn5Delta cells versus wild type. For H3 in wild type cells, tandem mass spectrometry revealed a direct correlation between increases of Lys(4) trimethylation and the 0, 1, 2, and 3 acetylation states of histone H3. The results show a wide swing from 10 to 80% Lys(4) trimethylation levels on those H3 tails harboring 0 or 3 acetylations, respectively. Reciprocity between these chromatin marks was apparent, since gcn5Delta cells showed a 30% decrease in trimethylation levels on Lys(4) in addition to a decrease of acetylation levels on H3 in bulk chromatin. Deletion of Set1, the Lys(4) methyltransferase, was associated with the linked disappearance of both Lys(4) methylation and Lys(14) and Lys(18) or Lys(23) acetylation on H3. In sum, we have defined the "basis set" of histone forms present in yeast chromatin using a current mass spectrometric approach that both quickly profiles global changes and directly probes the connectivity of modifications on the same histone.     

Dynamics of histone acetylation in Saccharomyces cerevisiae

Rates of turnover for the posttranslational acetylation of core histones were measured in logarithmically growing yeast cells by radioactive acetate labeling to near steady-state conditions. On average, acetylation half-lives were approximately 15 min for histone H4, 10 min for histone H3, 4 min for histone H2B, and 5 min for histone H2A. These rates were much faster than the several hours that have previously been reported for the rate of general histone acetylation and deacetylation in yeast. The current estimates are in line with changes in histone acetylation detected directly at specific chromatin locations and the speed of changes in gene expression that can be observed. These results emphasize that histone acetylation within chromatin is subject to constant flux. Detailed analysis revealed that the turnover rates for acetylation of histone H3 are the same from mono- through penta-acetylated forms. A large fraction of acetylated histone H3, including possibly all tetra- and penta-acetylated forms, appears subject to acetylation turnover. In contrast, the rate of acetylation turnover for mono- and di-acetylated forms of histones H4 and H2B, and the fraction subject to acetylation turnover, was lower than for multi-acetylated forms of these histones. This difference may reflect the difference in location of these histones within the nucleosome, a difference in the spectrum of histone-specific acetylating and deacetylating enzymes, and a difference in the role of acetylation in different histones.     

Turnover of chromatin proteins in rat liver during induction of RNA synthesis by electrostimulation of the hypothalamus

It has been shown that the induction of D-RNA synthesis in rat liver nuclei by electrostimulation of hypothalamus is accompanied by a decrease in chromatin protein synthesis and an increase in phosphorylation and acetylation of chromatin proteins. The decrease of the histone synthesis is mainly due to the decrease of [14C]lysine and [14C]alanine incorporation into histones H1 and H4. The relationship between H1, H2b-H3, H2a and H4 histone fractions remains unchanged. Electrostimulation of hypothalamus increases acetylation of H2a and H4 histone fractions and phosphorylation of all histones with the exception of histone H1.     

Acetylation of core histones in response to HDAC inhibitors is diminished in mitotic HeLa cells

Histone acetylation is a key modification that regulates chromatin accessibility. Here we show that treatment with butyrate or other histone deacetylase (HDAC) inhibitors does not induce histone hyperacetylation in metaphase-arrested HeLa cells. When compared to similarly treated interphase cells, acetylation levels are significantly decreased in all four core histones and at all individual sites examined. However, the extent of the decrease varies, ranging from only slight reduction at H3K23 and H4K12 to no acetylation at H3K27 and barely detectable acetylation at H4K16. Our results show that the bulk effect is not due to increased or butyrate-insensitive HDAC activity, though these factors may play a role with some individual sites. We conclude that the lack of histone acetylation during mitosis is primarily due to changes in histone acetyltransferases (HATs) or changes in chromatin. The effects of protein phosphatase inhibitors on histone acetylation in cell lysates suggest that the reduced ability of histones to become acetylated in mitotic cells depends on protein phosphorylation.     

State of histone modification in the rat Ig-beta/growth hormone locus.

The state of acetylation in H3 and H4 histones and dimethylation in the H3 histone Lys4 residue were examined by chromatin immunoprecipitation (ChIP) at 11 targets in the rat Ig-beta/growth hormone locus. Marked enhancement of the acetylation of histones H3 and H4 and the dimethylation of H3 Lys4 was observed in the chromatin situated close to the promoter of an actively transcribed gene. Chromatin positioned near a cell-type-specific DNase I-hypersensitive site with enhancer activity had the same histone modifications as the active promoter. In one transcribed intron, chromatin with fewer histone modifications was found, and in another transcribed intron, chromatin with markedly enhanced modifications was found. In most cases, no appreciable difference in the acetylation of histones H3 and H4 was found at prominently enhanced targets. However, different acetylation levels of H3 and H4 were found at one target. The targets with enhanced dimethylation of the H3 Lys4 residue coincided with those with prominently enhanced acetylation of histones H3 and H4.     

Lysine residues in N-terminal and C-terminal regions of human histone H2A are targets for biotinylation by biotinidase

In eukaryotic cell nuclei, DNA associates with the core histones H2A, H2B, H3 and H4 to form nucleosomal core particles. DNA binding to histones is regulated by posttranslational modifications of N-terminal tails (e.g., acetylation and methylation of histones). These modifications play important roles in the epigenetic control of chromatin structure. Recently, evidence that biotinidase and holocarboxylase synthetase (HCS) catalyze the covalent binding of biotin to histones has been provided. The primary aim of this study was to identify biotinylation sites in histone H2A and its variant H2AX. Secondary aims were to determine whether acetylation and methylation of histone H2A affect subsequent biotinylation and whether biotinidase and HCS localize to the nucleus in human cells. Biotinylation sites were identified using synthetic peptides as substrates for biotinidase. These studies provided evidence that K9 and K13 in the N-terminus of human histones H2A and H2AX are targets for biotinylation and that K125, K127 and K129 in the C-terminus of histone H2A are targets for biotinylation. Biotinylation of lysine residues was decreased by acetylation of adjacent lysines but was increased by dimethylation of adjacent arginines. The existence of biotinylated histone H2A in vivo was confirmed by using modification-specific antibodies. Antibodies to biotinidase and HCS localized primarily to the nuclear compartment, consistent with a role for these enzymes in regulating chromatin structure. Collectively, these studies have identified five novel biotinylation sites in human histones; histone H2A is unique among histones in that its biotinylation sites include amino acid residues from the C-terminus.     

Core histone acetylation is regulated by linker histone stoichiometry in vivo

We investigated the relationship between linker histone stoichiometry and the acetylation of core histones in vivo. Exponentially growing cell lines induced to overproduce either of two H1 variants, H1(0) or H1c, displayed significantly reduced rates of incorporation of [(3)H]acetate into all four core histones. Pulse-chase experiments indicated that the rates of histone deacetylation were similar in all cell lines. These effects were also observed in nuclei isolated from these cells upon labeling with [(3)H]acetyl-CoA. Nuclear extracts prepared from control and H1-overexpressing cell lines displayed similar levels of histone acetylation activity on chromatin templates prepared from control cells. In contrast, extracts prepared from control cells were significantly less active on chromatin templates prepared from H1-overexpressing cells than on templates prepared from control cells. Reduced levels of acetylation in H1-overproducing cell lines do not appear to depend on higher order chromatin structure, because it persists even after digestion of the chromatin with micrococcal nuclease. The results suggest that alterations in chromatin structure, resulting from changes in linker histone stoichiometry may modulate the levels or rates of core histone acetylation in vivo.     

Sites of Acetylation on Newly Synthesized Histone H4 Are Required for Chromatin Assembly and DNA Damage Response Signaling

The best-characterized acetylation of newly synthesized histone H4 is the diacetylation of the NH₂-terminal tail on lysines 5 and 12. Despite its evolutionary conservation, this pattern of modification has not been shown to be essential for either viability or chromatin assembly in any model organism. We demonstrate that mutations in histone H4 lysines 5 and 12 in yeast confer hypersensitivity to replication stress and DNA-damaging agents when combined with mutations in histone H4 lysine 91, which has also been found to be a site of acetylation on soluble histone H4. In addition, these mutations confer a dramatic decrease in cell viability when combined with mutations in histone H3 lysine 56. We also show that mutation of the sites of acetylation on newly synthesized histone H4 results in defects in the reassembly of chromatin structure that accompanies the repair of HO-mediated double-strand breaks. This defect is not due to a decrease in the level of histone H3 lysine 56 acetylation. Intriguingly, mutations that alter the sites of newly synthesized histone H4 acetylation display a marked decrease in levels of phosphorylated H2A (γ-H2AX) in chromatin surrounding the double-strand break. These results indicate that the sites of acetylation on newly synthesized histones H3 and H4 can function in nonoverlapping ways that are required for chromatin assembly, viability, and DNA damage response signaling.     

Assembly of newly replicated chromatin.

Mild staphylococcal nuclease digestions under isotonic conditions release fragments of a 200 Å diameter fiber from nuclei of Drosophila melanogaster tissue culture cells. These soluble fragments have high sedimentation coefficients (30–100S) and show tightly packed nucleosomes in the electron microscope. Under the same conditions, newly replicated chromatin is released as more slowly sedimenting fragments (14S). Within 20 min after DNA replication, the nascent chromatin gradually matures into compact supranucleosomal structures which are indistinguishable from bulk chromatin on the isokinetic sucrose gradients.We have used this fractionation technique to examine the question of the fate and assembly of the new histones. After short pulses with either ³⁵S-methionine or ³H-lysine, the radioactive histones do not co-sediment with the bulk chromatin but appear instead in the fractions where the newly replicated DNA is found. Furthermore, the various nascent histones appear in different fractions on the gradient: histones H3 and H4 in 10–15S structures, histones H2A and H2B in 15–50S structures and histone H1 in 30–100S structures. These results, together with the analysis of pulse and pulse-chase experiments of both nascent DNA and histones, strongly suggest that histones H3 and H4 are deposited first on the nascent DNA (during or slightly after the DNA is replicated), histones H2A and H2B are deposited next (2–10 min later) and histone H1 is deposited last (10–20 min after DNA replication). A high turnover 20,000 dalton protein is also associated with the newly replicated chromatin.