Characterization of pea histone deacetylases

The present paper is the first report on histone deacetylases from plants. Three enzyme fractions with histone deacetylase activity (HD0, HD1 and HD2) have been partially purified from pea (Pisum sativum) embryonic axes. They deacetylate biologically acetylated chicken histones and, to a lesser extent, chemically acetylated histones, this being a criterion of their true histone deacetylase nature. The three enzymes are able to accept nucleosomes as substrates. HD1 is not inhibited by n-butyrate up to 50 mM, whereas HD0 and HD2 are only slightly inhibited, thereby establishing a clear difference to animal histone deacetylases. The three activities are inhibited by acetate, Cu²⁺ and Zn²⁺ ions and mercurials, but are only scarcely affected by polyamines, in strong contrast with yeast histone deacetylase. Several criteria have been used to obtain cumulative evidence that HD0, HD1 and HD2 actually are three distinct enzymes. In vitro experiments with free histones show that HD0 deacetylates all four core histones, whereas HD1 and HD2 show a clear preference for H2A and H2B, the arginine-rich histones being deacetylated more slowly.     

Subcellular localization and nucleosome specificity of yeast histone acetyltransferases

We have previously reported [López-Rodas et al. (1989) J. Biol. Chem. 264, 19028-19033] that the yeast Saccharomyces cerevisiae contains four histone acetyltransferases, which can be resolved by ion-exchange chromatography, and their specificity toward yeast free histones was studied. In the present contribution we show that three of the enzymes are nuclear, type A histone acetyltransferases and they are able to acetylate nucleosome-bound histones. They differ in their histone specificity. Enzyme A1 acetylates H2A in chicken nucleosomes, although it is specific for yeast free H2B; histone acetyltransferase A2 is highly specific for H3, and histone acetyltransferase A3 preparations acetylate both H3 and H4 in nucleosomes. The fourth enzyme, which is located in the cytoplasm, does not accept nucleosomes as substrate, and it represents a canonical type B, H4-specific histone acetyltransferase. Finally, histone deacetylase activity is preferentially found in the nucleus.     

Yeast contains multiple forms of histone acetyltransferase

We have assayed several methods to quantitatively recover yeast histone acetyltransferases in an attempt to study the multiplicity of enzymatic activities. Two methods, namely (NH4)2SO4 precipitation and salt dissociation of chromatin in 0.5 M NaCl, yielded convenient preparations of total histone acetyltransferases. DEAE-Sepharose chromatography of the crude extracts resulted in the separation of three peaks of activity when total yeast histones were used as substrate. However, the scanning of the enzymatic activity toward individual histones along the chromatography, achieved by determining the specific activity of the individual histones after incubating whole histones and [14C]acetyl-CoA with the chromatographic fractions, yielded four peaks. The first two peaks showed specificity toward H2B and H3, respectively. Although they partially overlapped, rechromatography on cation exchangers allowed us to resolve the two activities, and several criteria were used to prove that they correspond to different enzyme molecules. The last two peaks were H4-specific, but the present data suggest that one of the activities is chromatin-bound, whereas the other surely corresponds to the cytoplasmic B-form of the enzyme. The enzyme specific for yeast H2B acetylates chicken erythrocyte H2A, rather than H2B. The detected multiplicity of yeast histone acetyltransferases may correspond to the multiplicity of roles proposed for histone acetylation.     

Development of a scintillation proximity assay for histone deacetylase using a biotinylated peptide derived from histone-H4

Measurement of histone deacetylase activity is usually accomplished by incubation of the enzyme(s) with acetate-radiolabeled histones or synthetic peptides based on histone sequences, followed by extraction and quantification of released radiolabeled acetic acid. Consequently, this assay is both time consuming and extremely limiting when large numbers of samples are involved. We have now developed a simple, two-step histone deacetylase assay that is based on the scintillation proximity assay (SPA) principle. A biotinylated [3H]acetyl histone H4 peptide substrate was synthesized and shown to generate a radioactive signal upon binding to streptavidin-coated SPA beads. Incubation of biotinylated [3H]acetyl peptide with HeLa nuclear extract (source of histone deacetylase) resulted in a time- and protein-dependent decrease in the SPA signal, providing a measure of enzyme activity. The histone deacetylase-mediated decrease in SPA counts was accompanied by a proportional appearance in free 3H-labeled acetate in the assay mixture. Histone deacetylase activity measured by SPA was concordant with that determined via the traditional ethyl acetate extraction procedure. Furthermore, a broad range of histone deacetylase inhibitors was demonstrated to have comparable effects on the catalytic activity of the HeLa nuclei enzyme using both assays. The histone deacetylase SPA system described here should be readily applicable for automated high-throughput screening and therefore facilitate the discovery of new inhibitors of histone deacetylases.     

Simple inhibitors of histone deacetylase activity that combine features of short-chain fatty acid and hydroxamic acid inhibitors

Butyric acid and trichostatin A (TSA) are anti-cancer compounds that cause the upregulation of genes involved in differentiation and cell cycle regulation by inhibiting histone deacetylase (HDAC) activity. In this study we have synthesized and evaluated compounds that combine the bioavailability of short-chain fatty acids, like butyric acid, with the bidentate binding ability of TSA. A series of analogs were made to examine the effects of chain length, simple aromatic cap groups, and substituted hydroxamates on the compounds' ability to inhibit rat-liver HDAC using a fluorometric assay. In keeping with previous structure-activity relationships, the most effective inhibitors consisted of longer chains and hydroxamic acid groups. It was found that 5-phenylvaleric hydroxamic acid and 4-benzoylbutyric hydroxamic acid were the most potent inhibitors with IC₅₀'s of 5 μM and 133 μM respectively.     

Constitutive hyperactivity of histone deacetylases enhances radioresistance in Lepidopteran Sf9 insect cells

BackgroundLepidopteran insect cells withstand multifold higher radiation doses and suffer far less DNA damage despite carrying numerous structural/functional homologies with mammalian cells. Since DNA–histone interactions significantly influence radiation-induced DNA damage, we investigated the role of histones in insect cell radioresistance.MethodsModified comet assay was used to assess the γ-radiation-induced DNA damage following serial histone depletion by varied salt concentrations. Acid–Urea–Triton (AUT) gel analysis combined with in silico predictions was used to compare mammalian and insect histones and acetylation status while HDAC activity was assessed/modified for studying the latter's role in radioresistance. Cell death was measured by morphological analysis and flow cytometry.ResultsHigh-salt extraction pattern from Sf9 nuclei suggested stronger DNA–histone affinity as the two core histones H2A/H2B could be extracted at much higher (2 M) concentration as compared to 1.2 M NaCl in mammalian (AA8) cells. Electrophoretic mobility of unirradiated Sf9 cells remained unaltered at all salt concentrations (0.14 M–2 M NaCl), and radiation-induced DNA damage increased only by 2 M-NaCl pre-treatment. In silico analysis confirmed excellent conservation of Lepidopteran H2A/H2B sequence with human histones including comparable N-terminal lysine residues, yet these had ~ 60% lower acetylation. Importantly, insect cells showed ~ 70% higher histone deacetylase activity whose inhibition by Trichostatin-A reversed hypo-acetylation state and caused significant radiosensitization, thereby confirming the protective contribution of reduced acetylation.ConclusionOur study reveals that the hypo-acetylated state of well-conserved core histones, maintained by considerable HDAC activity, contributes significantly in Lepidopteran radioresistance.General SignificanceThis investigation shows constitutively high activity of HDACs as a potential radioprotective mechanism existing in insect cells.     

Effect of urea on proteolysis of histone H2A in calf thymus nuclei

The 1 hour incubation of calf thymus nuclei at 37 degrees C leads to a proteolysis of the histones H1, H3 and H2B. Urea does not influence the histone degradation while 1.5 and 2.0 M NaCl lead to the proteolysis of the H2A histone. On this background, 2 M urea restrains the degradation of the H2A histone. It is assumed that hydrogen bonds are very important for the activity of the proteinases and its interaction with the H2A histone.     

Short-chain fatty acid activation by acyl-coenzyme A synthetases requires SIR2 protein function in Salmonella enterica and Saccharomyces cerevisiae

SIR2 proteins have NAD(+)-dependent histone deacetylase activity, but no metabolic role has been assigned to any of these proteins. In Salmonella enterica, SIR2 function was required for activity of the acetyl-CoA synthetase (Acs) enzyme. A greater than two orders of magnitude increase in the specific activity of Acs enzyme synthesized by a sirtuin-deficient strain was measured after treatment with homogeneous S. enterica SIR2 protein. Human SIR2A and yeast SIR2 proteins restored growth of SIR2-deficient S. enterica on acetate and propionate, suggesting that eukaryotic cells may also use SIR2 proteins to control the synthesis of acetyl-CoA by the level of acetylation of acetyl-CoA synthetases. Consistent with this idea, growth of a quintuple sir2 hst1 hst2 hst3 hst4 mutant strain of the yeast Saccharomyces cerevisiae on acetate or propionate was severely impaired. The data suggest that the Hst3 and Hst4 proteins are the most important for allowing growth on these short-chain fatty acids.     

Proteolysis of somatic type histones in transforming rat spermatid chromatin

Elongated rat spermatid nuclei have been isolated on the basis of their resistance to sonication in 0.32 M sucrose containing 1.5 mM CaCl₂. Chemical analyses indicate that approx. 35% of the DNA in these nuclei is associated with somatic type histones, while the remainder represents sperm histone-DNA complex. In contrast to nuclei of somatic cells, when elongated spermatid nuclei are incubated under appropriate conditions, somatic type histones but not sperm histone are rapidly degraded. Differential extraction of elongated spermatid nuclei with 5 mM HCl and then with various concentrations of NaCl followed by 0.2 M HCl has revealed that they contain two kinds of proteases. The protease in the 5 mM HCl extract is acrosin (EC 4.3.21.10). Rapid degradation of somatic type histones is, however, observable upon incubation of elongated spermatid nuclei which have been treated with 5 mM HCl and are therefore free of acrosin or upon incubation of elongated spermatid chromatin where the majority of acrosin is removed, suggesting that the observed proteolysis of somatic type histone is not due to acrosin. Proteases which may represent the enzymes responsible for the histone degradation are extractable from acrosin-free spermatid nuclei with NaCl (0.9 M) and by subsequent treatment of the salt-extracted nuclei with 0.2 M HCl. The proteases in the NaCl and the 0.2 M HCl extract possess identical properties and appear to be the same enyzyme which may exist in spermatid chromatin in two different forms.     

Simple inhibitors of histone deacetylase activity that combine features of short-chain fatty acid and hydroxamic acid inhibitors

Butyric acid and trichostatin A (TSA) are anti-cancer compounds that cause the upregulation of genes involved in differentiation and cell cycle regulation by inhibiting histone deacetylase (HDAC) activity. In this study we have synthesized and evaluated compounds that combine the bioavailability of short-chain fatty acids, like butyric acid, with the bidentate binding ability of TSA. A series of analogs were made to examine the effects of chain length, simple aromatic cap groups, and substituted hydroxamates on the compounds' ability to inhibit rat-liver HDAC using a fluorometric assay. In keeping with previous structure-activity relationships, the most effective inhibitors consisted of longer chains and hydroxamic acid groups. It was found that 5-phenylvaleric hydroxamic acid and 4-benzoylbutyric hydroxamic acid were the most potent inhibitors with IC50's of 5 microM and 133 microM respectively.     

The stepwise removal of histones from chicken erythrocyte nucleoprotein

1. A fractionation of chicken erythrocyte histones was achieved simultaneously with their extraction from saline-washed nuclei by stepwise titrations to progressively lower pH values. 2. Different acids and dilute buffer solutions of comparable pH behaved similarly in stepwise extractions of histones. 3. The histone preparations so obtained were characterized by their amino acid composition and behaviour on zone electrophoresis in starch gels. 4. The fractionation by titration was quite sharp at appropriate pH ranges, and the histone fraction that is apparently unique to avian erythrocytes was obtained without contamination by other histone fractions. 5. Histones prepared by stepwise titration were fractionated further by cation-exchange and exclusion chromatography. The chromatographic behaviour and amino acid composition of the components permitted comparison with histones prepared by other methods. 6. Histone fraction IIb was resolved into its subfractions IIb(1) and IIb(2) by exclusion chromatography on Bio-Gel P-60. 7. Histone fractions III and IV, previously reported to be absent from chicken erythrocyte nuclei, were found in extracts made at pH1.     

Regulated hyperacetylation of core histones during mouse spermatogenesis: involvement of histone deacetylases

Here we report a detailed analysis of waves of histone acetylation that occurs throughout spermatogenesis in mouse. Our data showed that spermatogonia and preleptotene spermatocytes contained acetylated core histones H2A, H2B and H4, whereas no acetylated histones were observed throughout meiosis in leptotene or pachytene spermatocytes. Histones remained unacetylated in most round spermatids. Acetylated forms of H2A and H2B, H3 and H4 reappeared in step 9 to 11 elongating spermatids, and disappeared later in condensing spermatids. The spatial distribution pattern of acetylated H4 within the spermatids nuclei, analyzed in 3D by immunofluorescence combined with confocal microscopy, showed a spatial sequence of events tightly associated with chromatin condensation. In order to gain an insight into mechanisms controlling histone hyperacetylation during spermiogenesis, we treated spermatogenic cells with a histone deacetylase inhibitor, trichostatin A (TSA), which showed a spectacular increase of histone acetylation in round spermatids. This observation suggests that deacetylases are responsible for maintaining a deacetylated state of histones in these cells. TSA treatment could not induce histone acetylation in condensing spermatids, suggesting that acetylated core histones are replaced by transition proteins without being previously deacetylated. Moreover, our data showed a dramatic decrease in histone deacetylases in condensing spermatids. Therefore, the regulation of histone deacetylase activity/concentration appears to play a major role in controling histone hyperacetylation and probably histone replacement during spermiogenesis.     

Acetylation of the Entamoeba histone H4 N-terminal domain is influenced by short-chain fatty acids that enter trophozoites in a pH-dependent manner

Treatment of higher eukaryotic cells with short-chain fatty acids (SCFA) such as butyrate causes decreased levels of histone deacetylase (HDAC) activity and hyperacetylation of histones, and thereby affects gene expression, cell growth and differentiation. Entamoeba parasites encounter high levels of SCFA in the host colon, and in vitro these compounds allow trophozoite stage parasites to multiply but prevent their differentiation into infectious cysts. The Entamoeba invadens IP-1 histone H4 protein has an unusual number of lysines in its N-terminus, and these become hyperacetylated in trophozoites exposed to the HDAC inhibitors trichostatin A (TSA) or HC-toxin, but not in trophozoites exposed to butyrate. We have now found that several other commonly studied isolates of Entamoeba parasites also have an extended set of histone H4 acetylation sites that become hyperacetylated in response to TSA, but hypoacetylated in response to butyrate, suggesting an unusual sensitivity of this parasite's histone modifying enzymes to SCFA. Butyrate was found to enter trophozoites in a pH-dependent manner consistent with diffusive entry of the un-ionised form of the fatty acid into the amoebae. Transit of the Entamoeba organism through areas of the host intestine with distinct pH and SCFA concentrations would therefore result in very different levels of SCFA within the parasite. Entamoeba appears to have acquired unique alterations of its histone acetylation mechanism that may allow for its growth in the presence of varying amounts of the bacterial fermentation products.     

Purification and properties of a histone acetyltransferase from Artemia salina, highly efficient with H1 histone.

An histone acetyltransferase has been purified from nuclei of 40-h-old Artemia salina larvae. The enzyme is very unstable at 0 degrees C, requires free -SH groups for activity and is rapidly inactivated at 40 degrees C. The optimal pH for activity is 8.5 and the activity is half inhibited by millimolar concentrations of Mn2+, Ca2+ or Mg2+ or decimolar concentrations of Na+ and K+. The molecular weight of the enzyme, determined by gel filtration chromatography, changed with the ionic strength of the medium (280,000 in 10 mM Tris . HCl, 170,000 in 0.2 M KCl). The very-lysine-rich histone H1 is a better substrate acceptor than the arginine-rich histones H3 or H4. Under proper conditions, the enzyme can modify all the internal lysyl residues in histones H1 and H4. The acetylation of H1 is inhibited when all the other histone fractions are present in the assay mixture.