Complete displacement of somatic histones during transformation of spermatid chromatin: a model experiment.

Displacement of histones from calf thymus chromatin has been studied in an attempt to postulate the mechanisms involved in the total removal of somatic-type histones during transformation of spermatid chromatin. When chromatin is saturated with protamine (protamine/DNA, 0.5), histone I becomes displaceable at 0.15-0.3 M NaCl, suggesting that direct replacement by highly basic sperm histone could be a mechanism for its removal. While histone I is the only histone which is extensively degraded upon incubation of chromatin and, therefore, proteolysis might provide an additional mechanism for the removal of this histone, acetylation of chromatin by acetic anhydride greatly increases suscpetibility of histones IIb1, IIb2, and III to the chromosomally associated protease. These histones are extensively degraded and displaced from the DNA upon incubation of the acetylated chromatin. Although histone IV is not appreciably degraded, the proteolytic removal of acetylated histone III from chromatin weakens the interaction of acetylated histone IV to the DNA, and this histone becomes dissociable at 0.3 M NaCl. A comparison of the extent of chemical acetylation of individual histones observed in this investigation with that of enzymatic acetylation which can be achieved in vivo suggests that acetylation and proteolysis could be a mechanism for the removal of histone IIb2 and III. The displacement of histones IIb1 and IV could be explained on the basis of decreased binding to DNA as a result of their acetylation together with the proteolytic removal of their respective partner histones, IIb2 and III.     

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.     

Changes in basic chromosomal proteins during spermatogenesis in the mature rat.

Nuclei of the seminiferous epithelial cells of rat testis were filtered through glass wool to remove sperm heads, flagellae and late-stage spermatids and then centrifuged through sucrose gradients to yield three fractions. The cellular origins of the predominant nuclei in these fractions were identified through the kinetics of labeling with [³H]thymidine. The relative amounts of the different histone fractions changed during the various stages of spermatogenesis in an interesting and systematic manner. For example, the ratio of the trailing (acetylated) to the leading member of the histone F2a1 doublet was greater in spermatid nuclei than in nuclei of a fraction enriched in primary spermatocytes. Similarly, the ratio $\text{X}{}_1\text{F}\text{1}$ was greatest in spermatid nuclei. On the other hand, the ratio $\text{X}{}_3\text{F}\text{2b}$ was greater in the nuclei of pachytene-diplotene primary spermatocytes than in the fraction enriched in nuclei of spermatogonia and preloptotene primary spermatocytes.A basic protein fraction with some of the properties of a protamine was extracted from rat sperm heads and from the nuclei of spermatids. This protein fraction has high contents of arginine and cysteine (after reduction), and it appears to be identical with the protamine described by Kistler et al. In addition, a new protamine was isolated from rat sperm heads which has high arginine content but appears to be devoid of lysine and cyst(e)ine. Two other basic protein fractions with high electrophoretic mobilities were extracted with acid from the nuclei of testicular seminiferous epithetial cells without prior reduction. One of these proteins may be identical with the testis-specific protein of Kistler et al.     

The histones of rat testis

Polyacrylamide gel electrophoresis of the histones of the nuclei of seminiferous epithelial cells of rat testis revealed the five principal histone fractions which are found in liver and other somatic tissues, but, in addition, three unusual bands (desginated X₁, X₂, and X₃) were observed. Fraction X₁ had a mobility slightly less than that of F1 and was isolated with F1 in the fractionation procedure of Johns. F1 and X₁ were separated by chromatography on carboxymethylcellulose, and they were shown by amino acid analyses to be closely related lysine-rich histones. However, X₁ had lower content of lysine and alanine and higher content of arginine, aspartic acid, serine, proline, valine and leucine than F1. Both of these fractions had blocked amino-terminal residues, and both had a lysine residue at the carboxyl terminus. These fractions had similar molecular weights by electrophoresis on sodium dodecyl sulfate gels.Fraction X₂ migrated between histone fractions F1 and F3 on electrophoresis while X₃ migrated between fractions F2b and F3. Fraction X₃ was isolated with F2b during fractionation by the Johns procedure. Fraction X₂ has received minimal study, and this fraction may not be unique to the testis inasmuch as a faint band in approximately the position of X₂ can be seen in electrophoretic patterns of rat liver histones.The results of the treatment of the histone fractions with alkaline phosphatase indicated that the electrophoretic differences between X₁ and F1, or X₃ and F2b are not attributable to phosphorylation.     

Histone variants and histone modifications in chromatin fractions from heterochromatin-rich Peromyscus cells

In order to investigate the relationship between condensed heterochromatin and histone modification by acetylation, phosphorylation and amino acid variation, chromatin from cultured Peromyscus eremicus cells, containing 35% constitutive heterochromatin, was fractionated into heterochromatin-enriched and heterochromatin-depleted fractions. The constitutive heterochromatin content of these fractions was determined from satellite DNA content. The distribution of phosphorylated and acetylated histones and amino acid variants of histone H2A in these chromatin fractions was examined by gel electrophoresis. Fractionation of histones demonstrated that endogenous histone phosphatase activity was high in chromatin fractions and could not be inhibited sufficiently to allow accurate histone phosphorylation measurements. However, sodium butyrate did inhibit deacetylation activity in the fractions, allowing histone acetylation measurements to be made. It was found that the constitutive heterochromatin content of these fractions was proportional to both their unacetylated H4 content and their more-hydrophobic H2A content. These observations support, by direct measurement, earlier experiments (Exp cell res 111 (1978) 373; 125 (1980) 377; 132 (1981) 201) suggesting that constitutive heterochromatin is enriched in unacetylated arginine-rich histones, and in the more hydrophobic variant of histone H2A.     

L-Carnitine Is an Endogenous HDAC Inhibitor Selectively Inhibiting Cancer Cell Growth In Vivo and In Vitro

L-carnitine (LC) is generally believed to transport long-chain acyl groups from fatty acids into the mitochondrial matrix for ATP generation via the citric acid cycle. Based on Warburg''s theory that most cancer cells mainly depend on glycolysis for ATP generation, we hypothesize that, LC treatment would lead to disturbance of cellular metabolism and cytotoxicity in cancer cells. In this study, Human hepatoma HepG2, SMMC-7721 cell lines, primary cultured thymocytes and mice bearing HepG2 tumor were used. ATP content was detected by HPLC assay. Cell cycle, cell death and cell viability were assayed by flow cytometry and MTS respectively. Gene, mRNA expression and protein level were detected by gene microarray, Real-time PCR and Western blot respectively. HDAC activities and histone acetylation were detected both in test tube and in cultured cells. A molecular docking study was carried out with CDOCKER protocol of Discovery Studio 2.0 to predict the molecular interaction between L-carnitine and HDAC. Here we found that (1) LC treatment selectively inhibited cancer cell growth in vivo and in vitro; (2) LC treatment selectively induces the expression of p21^cip1 gene, mRNA and protein in cancer cells but not p27^kip1; (4) LC increases histone acetylation and induces accumulation of acetylated histones both in normal thymocytes and cancer cells; (5) LC directly inhibits HDAC I/II activities via binding to the active sites of HDAC and induces histone acetylation and lysine-acetylation accumulation in vitro; (6) LC treatment induces accumulation of acetylated histones in chromatin associated with the p21^cip1 gene but not p27^kip1 detected by ChIP assay. These data support that LC, besides transporting acyl group, works as an endogenous HDAC inhibitor in the cell, which would be of physiological and pathological importance.     

Histones from exponential and stationary L-cells. Evidence for metabolic heterogeneity of histone fractions retained after isolation of nuclei

Histones of exponential and G₁-arrested mouse L-cells were double-labeled with either [³H]lysine and [³²P]phosphate or with [¹⁴C]arginine and [³H]acetate in order to investigate cell cycle-dependent changes in rates of synthesis and metabolic modifications as well as the effect of the method of nuclear isolation on retention of the labeled fractions. Results indicate that newly synthesized lysine-rich histones incorporate ³²P at the highest rate. However, phosphorylation can also be detected in G₁-arrested cells and in the case of F_2b, F_1⁰, and F_1¹, with no detectable new synthesis.On the other hand, acetylation proceeded at similar rates in both exponential and stationary cells with the exception of F_{2a 2} and F₃ which showed higher acetylation levels in the latter.In relation to the method used for nuclear isolation, we observed that, even in cases where no difference in the relative amount of a given histone could be detected, the species recovered were not identical. We conclude that none of the methods commonly employed retains all of the histones. In general, the acetylated species appear to be best preserved at a higher divalent cation concentration while the newly synthesized ones are better conserved at lower ionic strengths.     

Methylation of lysine residues of histone fractions in synchronized mommalian cells

Synchronized cultures of mammalian cells were labeled with ¹⁴C-methyl methionine. Labeled methionine methyl groups were incorporated into certain histone fractions, forming methyl lysine. Incorporation of labeled methyl group into histone fractions as ¹⁴C-methyl lysine was followed through the cell cycle from late G₁ into early M. The ¹⁴C-methyl lysine contents of fractions F2a and F3 began to rise in S and reached maxima after termination of DNA and histone synthesis, coincident with the beginning of mitosis, and began to fall by mid-M. The ¹⁴C-methyl lysine content of fraction F2b rose to a maximum early in S, coincident with initiation of DNA synthesis, and rapidly decreased to its original unmethylated level by late S. Fraction F1 remained unmethylated during the period G₁-M. Evidence is presented to demonstrate differential methylation of histone fractions and to substantiate differential temporal coupling of the methylation of specific histone fractions with histone and DNA biosynthesis.     

Differential Histone Acetylation in Alfalfa (Medicago sativa) Due to Growth in NaCl : Responses in Salt Stressed and Salt Tolerant Callus Cultures

The steady state distribution of histone variant proteins and their modifications by acetylation were characterized in wild type and salinity stress adapted alfalfa (Medicago sativa). Isotopic labeling detected dynamic acetylation at four sites in the histone H3 variants and five sites in histones H4 and H2B. Histone variant H3.2 was the most highly acetylated histone with 25% higher steady state acetylation and a two- to threefold higher acetylation labeling than histone H3.1. Histone phosphorylation was limited to histone variants H1.A, H1.B, and H1.C and to histone H2A.3, which was also acetylated. Histone variant composition was unaffected by cellular exposure to NaCl. Histone acetylation was qualitatively similar in salt-tolerant and salt-sensitive cells under normal growth conditions. However, short term salt stress in salt sensitive cells or continued growth at 1% NaCl in salt tolerant cells led to major increases in the multiacetylated forms of histone H4 and the two variants of histone H3. These changes were more pronounced in the diploid than in the tetraploid alfalfa strains. The increase in multiacetylation of core histones serves as an in vivo reporter suggesting an altered intranuclear ionic environment in the presence of salt. It may also represent an adaptive response in chromatin structure to permit chromatin function in a more saline intranuclear environment.     

Replication-independent nucleosome exchange is enhanced by local and specific acetylation of histone H4

We used a novel single-cell strategy to examine the fate of histones during G₂-phase. Consistent with previous results, we find that in G₂-phase, the majority of nuclear histones are assembled into chromatin, whereas a small fraction comprises an unassembled pool. Small increases in the amount of histones within the free pool affect the extent of exchange, suggesting that the free pool is in dynamic equilibrium with chromatin proteins. Unexpectedly, acetylated H4 is preferentially partitioned to the unassembled pool. Although an increase in global histone acetylation did not affect overall nucleosome dynamics, an H4 containing lysine to glutamine substitutions as mimics of acetylation significantly increased the rate of exchange, but did not affect the acetylation state of neighbouring nucleosomes. Interestingly, transcribed regions are particularly predisposed to exchange on incorporation of H4 acetylation mimics compared with surrounding regions. Our results support a model whereby histone acetylation on K8 and K16 specifically marks nucleosomes for eviction, with histones being rapidly deacetylated on reassembly.     

Histone acetylation and heterochromatin content of cultured Peromyscus cells

In order to explore the relationship between unacetylated arginine-rich histones and condensed chromatin structure, the extent of histone acetylation was examined in cultured cell lines derived from three species of deer mice. These species differ considerably in their genomic content of heterochromatin but contain essentially the same euchromatin content. Cells of Peromyscus eremicus, containing 34–36% more constitutive heterochromatin than Peromyscus boylii or Peromyscus crinitus cells were found to contain 28–35% more unacetylated histone H4, 22–29% more unacetylated histone H3, and 18–22% more unacetylated histone H2B. This relationship between unacetylated histones and heterochromatin content was further explored by inducing hyperacetylation of P. eremicus and P. boylii histones through treatment of cells with 15 mM sodium butyrate for 24 h. It was found that the percentages of unacetylated histones H3 and H4 remaining after butyrate treatment were proportional to the amount of constitutive heterochromatin in the genome. These data support the concept that a small core of histones in constitutive heterochromatin is inaccessible to acetylation. It was also found that the acetylated state of isolated histones was sensitive to the method of histone extraction. Thus concern must be given to preparative procedures when studying histone acetylation in order to minimize these acetate losses.     

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.     

Trypanosoma cruzi bromodomain factor 2 (BDF2) binds to acetylated histones and is accumulated after UV irradiation

Histone tail post-translational modifications (acetylation, methylation, phosphorylation, ubiquitination and ADP-ribosylation) regulate many cellular processes. Among these modifications, phosphorylation, methylation and acetylation have already been described in trypanosomatid histones. Bromodomains, together with chromodomains and histone-binding SANT domains, were proposed to be responsible for “histone code” reading. The Trypanosoma cruzi genome encodes four coding sequences (CDSs) that contain a bromodomain, named TcBDF1-4. Here we show that one of those, TcBDF2, is expressed in discrete regions inside the nucleus of all the parasite life cycle stages and binds H4 and H2A purified histones from T. cruzi. Immunolocalization experiments using both anti-histone H4 acetylated peptides and anti-TcBDF2 antibodies determined that TcBDF2 co-localizes with histone H4 acetylated at lysines K10 and K14. TcDBF2 and K10 acetylated H4 interaction was confirmed by co-immunoprecipitation. It is also shown that TcBDF2 was accumulated after UV irradiation of T. cruzi epimastigotes. These results suggest that TcBDF2 could be taking part in a chromatin remodelling complex in T. cruzi.     

Histones from embryos of the sea urchin Arbacia lixula

Whole histones and histone fractions of the sea urchin, Arbacia lixula, embryos have been characterized by their appearance during development and by their amino acid composition. Comparison of electrophoretic mobility of the histone fractions from hatching blastula and gastrula stage embryos demonstrates the similarity of the basic proteins at these two stages. Histones F2a1 and F3 of hatching embryos are very similar to those of sperm, including the presence of cysteine in F2a1 from both sources. Both F2a1 and F3 display electrophoretic heterogeneity due to acetylation, not observed in the homologous sperm histones. F2a2 from embryos has different electrophoretic mobility than that from sperm, although their amino acid compositions are very similar. The relative proportion of F2a2 increases whereas that of F3 decreases during gastrulation. Slightly lysine-rich histone F2b could not be recovered from embryos by the standard methods of extraction. The very lysine-rich histone F1 of late embryos is partially phosphorylated and is remarkably different from that of sperm, notably by its higher electrophoretic mobility and lower content in arginine and proline. The significance of these results is discussed with regard to the structure and activity of chromatin.     

Tissue-specific histones in the erythrocytes of chicken and turtle

Mature erythrocytes from Leghorn chickens contain lysine-rich histone F1 and a tissue-specific histone F2c. The composition of the F1 fraction was found to be similar to the F1 histones in higher vertebrates. In the erythrocytes of a sea turtle (Chelonia mydas), only lysine-rich histones F1 could be detected. One of these fractions (F1b) differed in amino acid composition from the typical F1 histones described in the literature. The F1b histone fraction was not found in turtle liver. Chromatographic analysis of tryptic peptides of the chicken erythrocyte F1 and F2c histones and of the turtle erythrocyte F1a and F1b histones revealed considerable similarities between these four fractions, thus indicating their possible phylogenetic relationships.     

Acetylation of histones during spermatogenesis in the rat

Acetate was actively incorporated into rat testis histones when testis cells were prepared by the trypsinization technique in the presence of [³H]acetate. The acetylation was enhanced by 10 mm sodium butyrate. Although histones H3 and H4 were the only histones which incorporated high levels of acetate, the testis-specific histones TH2B and TH3 also appeared to incorporate acetate. This was shown by electrophoresis of the histones on polyacrylamide gels containing Triton X-100. Results, obtained from analysis of histones by two-dimensional gel electrophoresis, confirmed a recent report (P. K. Trostle-Weige, M. L. Meistrich, W. A. Brock, K. Nishioka, and J. W. Bremer, (1982) J. Biol. Chem.257, 5560–5567) that TH2A was a testis-specific histone. The results also confirmed the H2A nature of a testis-enriched histone band, previously designated X2. When histones from populations of cells enriched in specific testis cell types, representing various stages of spermatogenesis, were examined, the patterns of acetylation varied dramatically. Very high levels of acetate were incorporated into multiacetylated species of histone H4 from a population of cells enriched in transition stage spermatids (steps 9–12) compared to the levels of acetate incorporated into H4 from round spermatids (steps 1–8) and earlier stages of spermatogenesis, where acetate was incorporated primarily into the monoacetylated species of H4. Thus, a striking correlation exists between the time of hyperacetylation of histone H4 and the time of removal of histones for their replacement by the basic spermatidal transition proteins designated TP, TP2, and TP4. Hyperacetylation of histone H4 may facilitate the removal of the entire histone complement during the protein transition. In any case, it must be an obligatory step in the dramatic process.     

Specific changes in the biosynthesis and acetylation of nucleosomal histones in the early stages of embryogenesis of sea urchin.

Histones of the sea urchin Strongylocentrotus droebachiensis were labelled in vivo with [¹⁴C]protein hydrolysate and [¹⁴C]sodium acetate at the developmental stages of blastula, gastrula and pluteus. They were further resolved by electrophoresis in 15% polyacrylamide gels in the presence of 0.9 M acetic acid, 8 M urea as well as in 20% polyacrylamide gels containing the same concentrations of acetic acid and urea, but in addition, 4.3 mM Triton X-100. On comparison of electrophoretic patterns with autoradiograms it was shown that during the early stages of differentiation the synthesis of several new subfractions of some of the histones takes place, namely of two of H1, of two of H2b and of nine of H2a. At the same time the electrophoretic pattern of the arginine-rich histones remained constant, H3 consisting of three and H4 of four subfractions. The basic reason for this heterogeneity seems to be the specific post-synthetic acetylation of the histones. At the blastula stage all the newly synthesized H4 molecules are equally acetylated, while the histone H3 molecules are acetylated to varying extents. After gastrulation both H3 and H4 are also subject to a different level of acetylation.