Histone phosphokinase activity in nuclear and cytoplasmic cell fractions from normal and regenerating rat livers

1. Liver cell fractions were prepared by non-aqueous procedures and nuclei were also obtained in a hyperosmotic sucrose medium. Histone phosphokinase activity, assayed with histone F1 as substrate, was present in the soluble fraction of the cytoplasm and also bound on to the chromatin fraction of the nucleus. 2. The activity of the enzyme increased sixfold in nuclei from regenerating livers 22h after partial hepatectomy. 3. The enzyme bound in the nucleus was only marginally activated by 1mum-3':5'-cyclic AMP which stimulated the cytoplasmic soluble enzyme fourfold. 4. Nuclei prepared by the non-aqueous technique were also able to phosphorylate histones F2a and F3 and showed histone phosphatase activity with histone F1 phosphate as substrate.     

Cytoplasmic origin of the so-called nuclear neutral histone protease.

1. We have investigated the origin of proteolytic activity which causes degradation of histones in chromatin isolated from Xenopus liver and the rat liver at neutral pH. Polyacrylamide disc gel electrophoresis was used for detection of proteolytic products of histones. 2. No proteolytic degradation of histones occurs in chromatin isolated from Xenopus erythrocytes and rat liver according to our procedure even after prolonged incubation at pH 8.0 and pH 5.0. However with chromatin isolated from Xenopus liver a high level of histone degradation is observed under similar conditions. 3. Mixing isolated nuclei from Xenopus erythrocytes with a crude cytoplasmic fraction from Xenopus liver causes histone proteolysis in isolated chromatin at pH 8.0. In similar experiments with corresponding fractions from rat liver histone proteolysis can be introduced only after repeated freezing and thawing of the cytoplasmic fraction. 4. A purified lysosomal preparation from rat liver causes a similar type of histone degradation upon incubation with chromatin from Xenopus erythrocytes and rat liver. 5. The neutral proteolytic activity that can be introduced in isolated chromatin by a crude cytoplasmic fraction and by a purified lysosomal erythrocytes and rat liver. 5. The neutral proteolytic activity that can be introduced in isolated chromatin by a crude cytoplasmic fraction and by a purified lysosomal fraction from rat liver is inhibited by sodium bisulphite. 6. We conclude that the neutral proteolytic activity which causes degradation of histones in isolated chromatin is due to a contamination with neutral protease(s) originating from cytoplasmic organelles.     

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.     

Transformation of sperm histone during formation and maturation of rat spermatozoa.

Changes of chromosomal basic proteins of rats have been followed during transformation of spermatids into spermatozoa in the testis and during maturation of spermatozoa in the epididymis. Rat testis chromatin has been fractionated on the basis of differing sensitivity to shearing, yielding a soluble fraction and a condensed fraction. The sperm histone is found in the condense fraction. Somatic-type histones are found in both fractions. The somatic-type histones in the condensed fraction contains much more lysine-rich histone I, than does the somatic-type histones in the soluble fraction. This may suggest that the lysine-rich histone I is the last histone to be displaced during the replacement of somatic-type histones by sperm histone. After extensive shearing followed by sucrose centrifugation, the condensed portion of testis chromatin can be further fractionated into two morphologically distinctive fractions. One is a heavy fraction possessing an elongated shape typical of the head of late spermatids. The other is a light fraction which is presumably derived from spermatids at earlier stages of chromatin condensation and which is seen as a beaded structure in the light microscope. Sperm histone of testis chromatin can be extractable completely by guanidinium chloride without a thiol, wheras 2-mercaptoethanol is required for extraction of sperm histone from caput and cauda epididymal spermatozoa. The light fraction of the condensed testis chromatin contains unmodified and monophospho-sperm histone. The sperm histones of the heavy fraction is mainly of monophospho and diphospho species, whereas unmodified and monophosphosperm histones are found in caput and cauda epididymal spermatozoa. Labeling of cysteine sulfhydryl groups of sperm histone releases by 2-mercaptoethanol treatment shows that essentially all of the cysteine residues of sperm histone in testis chromatin are present as sulfhydryl groups, while those of sperm histone isolated from mature (cauda epididymal) spermatozoa are present as disulfide forms and approximately 50% of the cysteine residues of sperm histone obtained from caput epididymal spermatozoa are in disulfide forms. These results suggest that phosphorylation of sperm histone is involved in the process of chromatin condensation during transformation of spermatozoa in the epididymis.     

Effect of inhibition of DNA synthesis on histone synthesis, turnover, and deposition in the rat testis

In testicular seminiferous epithelial cells (SEC) of normal and hypophysectomized rats, 1-beta-D-arabinofuranosylcytosine and hydroxyurea (at concentrations which inhibited DNA synthesis nearly completely) inhibited histone synthesis only partially, and to a different extent for each histone fraction. In the presence of the inhibitors, the extent of synthesis relative to the corresponding control was TH1-x greater than H1 greater than TH2B-x = X2 = H2A greater than H2B = H3 greater than H4, in which synthesis of the H4 fraction was about 50% of control and that of TH1-x was 90-95% of control. The extent of inhibition of synthesis of each histone fraction was similar after hypophysectomy and, therefore, the changing of the relative populations of heterogeneous cells in the SEC did not influence the relative effects of the inhibitors of DNA synthesis on the synthesis of the various histone fractions. After [3H]leucine injection, the molar proportions of labeled histones relative to H4 decreased markedly between 1.5 h and 6-15 days; this finding indicated that there was rapid removal of histones compared to the H4 fraction during this period. When [14C]thymidine was injected 24 h prior to hydroxyurea treatment and [3H]leucine injection, the ratios of specific activities of histone H4 to DNA did not change significantly over an 11-day period. It appears that newly synthesized histone H4 and other somatic histones are associated with existing DNA in the presence of DNA inhibitors.     

Interactions of the nuclear thyroid hormone receptor with core histones

These studies concern the interactions of the rat liver thyroid hormone nuclear receptor with histones and factors influencing the receptor's assay and stability. Heating certain crude receptor preparations at 50 degrees C produces a selective loss of triiodothyronine (T3) but not thyroxine (T4) binding activity, whereas, with more purified preparations, such heating decreases both T3 and T4 binding. The selective T3-binding loss in crude preparations was found to be due to the simultaneous denaturation of the receptor's high-affinity hormone-binding activity for both T3 and T4 and generation of new low-affinity T4-binding sites. The fraction in which T4 binding can be activated could be separated from the receptors by Sephadex G-100 chromatography. Core histones stimulated both T3- and T4-binding activity of 6-fold-purified receptor preparations, and data from several different experimental approaches suggest that this stimulation is due to the capability of the core histones to prevent the receptor from binding to or being denatured by Sephadex G-25 assay columns. The core histones were also found to stabilize 500-fold-purified but not 6-fold-purified or crude receptor preparations. A number of other acidic or basic proteins had little or none of these stimulatory effects, whereas a few proteins (such as the insulin B chain and histone H1) did have activity, although it was less than that of the core histones. There were no significant differences between the purified core histone subfractions (H2A, H2B, H3, and H4). That core histones can interact with the thyroid hormone receptors was demonstrated more directly by the finding that the receptors bind to histone-Sepharose but not Sepharose or insulin- or ovalbumin-Sepharose columns and that this binding was blocked by core histones at concentrations suggestive of an affinity for the receptor-core histone interaction of around 3 microM at 0.15 M salt concentration. The results demonstrate the utility of the histones in the assay and stabilization of purified thyroid hormone receptors, but they fail to support our previous hypothesis of a receptor subunit where T3- but not T4-binding activity is regulated selectively by histones. However, the results indicate that histones may interact with the receptors with some degree of specificity, and they raise the possibility that the histones participate in the nuclear localization of the receptors.     

Electrophoretic analysis of liver and testis histones of the frog Rana pipiens

Histones were extracted from frog livers and testes and analyzed by electrophoresis on long polyacrylamide gels and on sodium dodecyl sulfate (SDS)-containing polyacrylamide gels. Frog histones were found to be similar to those of calf thymus except that frog histone fraction F2A2 showed a marked dependence on the temperature at which the long gels were run, and frog histone fraction F3 could be separated from frog F2B on SDS-containing gels. Comparisons between frog liver and frog testis histones indicated that the testis contains as its major F1 component a fast migrating species not found in liver. Testis histones also showed less microheterogeneity of fractions F3 and F2A1 than liver histones. These were the only differences observed between liver and testis histones, even when testis histones were prepared from sperm suspensions that were rich in cells in the late stages of spermiogenesis. Thus it seems that, in Rana, the electrophoretic properties of the basic proteins of sperm differ from those of somatic cells only in the nature of histone F1 and in the degree of microheterogeneity of fractions F2A1 and F3.     

Histone mediated changes in morphology and confluent density of cultured cells

Calf thymus histones and histone subfractions were added to media overlying subconfluent mouse fibroblast cells in culture. The histones caused significantly higher cell densities at confluence than control cultures and disruption of the normal ordered arrangement of cells. These changes were seen on application of histones to growing cells but not confluent cells and were reversed when the histones were removed and the cells replated with more growth area. The slightly lysine rich histone fraction had the greatest effect and the lysine rich fraction had the least effect on cell morphology and cell number at confluence. These effects could not be duplicated with other highly charged basic proteins.     

Effect of leukocyte cation proteins in vitro on the activity of the pathogen of meningopneumonitis

A study was made of the influence of cation proteins from the lysosomes and nuclei of rabbit polymorphonuclear leukocytes on the survival of the causative agent of meningopneumonia in vitro. As revealed, the greatest antibiotic activity was possessed by the nuclear histones and the low molecular basic proteins of lysosomes. Biological significance of the detected effects is discussed.     

Comparative study of histones from slime mold Physarum polycephalum and calf thymus

The histones from slime mold Physarum polycephalum and calf thymus were characterized in terms of some physico-chemical properties. The molecular weights of six principal histone fractions of Ph. polycephalum were found to be the following: P1--22 700, P3--15 700, P4a--15 000, P4b--14 300, P5--12 800 and P6--10 500. Electrophoretically homogenous histone fractions H1, H2b and H4 of calf thymus and histones P1, P3, P4b and P6 of slime mold were obtained by gel-filtration on Acrylex P-60. These findings suggest that fractions P1, P4a, P4b, P5 and P6 of slime mold Ph. polycephalum are homologus with respect to the histone fractions H1, H3, H2b, H2a and H4 of calf thymus. Only fraction P3 has no corresponding fraction in the calf thymus histones; a fraction corresponding to histone P3 of slime mold was absent.     

Only a small fraction of avian erythrocyte histone is involved in ongoing acetylation.

We have studied histone acetylation in chicken erythrocytes. We find that about 30% of the histone in these cells is acetylated, however the majority of these histones are not in a dynamic steady state typical of other chicken cells and of mammalian cells, but rather are frozen in this state of modification. A very small fraction of erythrocyte histones are being modified normally but cannot be detected as shifting to higher levels of acetylation upon treatment with butyrate because the amount of histone so modified is small. Nonetheless, chicken erythrocytes incorporate 3H-acetate into histones about 40% as well as seen in the dynamically active HTC cells. This is most likely due to the formation of very high specific activity Acetyl CoA pools in erythrocytes which have very low levels of coenzyme A. We conclude that these genetically inactive cells are involved in only a minor way with histone acetylation.     

Segregation of rapidly acetylated histones into a chromatin fraction released from intact nuclei by the action of micrococcal nuclease.

It has been previously shown that micrococcal nuclease digestion and subsequent fractionation of hen oviduct nuclei generates fractions enriched (first supernatant fraction - 1SF) and depleted (second supernatant fraction - 2SF) in ovalbumin genes, while a third fraction, the pellet fraction, contains about the same level of this gene as whole chromatin (Bloom and Anderson (1978) Cell 15, 141-150). We have utilized this fractionation method in an attempt to assess the extent and kinetics of histone acetylation associated with chromatin from the 1SF, 2SF, and pellet fraction. Hepatoma Tissue Culture (HTC) cells were labelled for 30 minutes in vivo with 3H-acetate, nuclei isolated and the chromatin fractionated. The specific activity of the histones in the 1SF was slightly greater than that of the 2SF (1.2 to 1.6 fold difference) independent of the length of nuclease digestion. If the labelling period is followed by short (10 to 60 minute) treatment of the cells with sodium butyrate, the more rapidly as well as more extensively acetylated histones are also preferentially found in the 1SF. This is in part the result of segregation of chromatin particles into the 1SF as the histones associated with these particles become hyperacetylated. That is, the extent of histone acetylation regulates the distribution of chromatin in the 1SF, 2SF and pellet fraction.     

Amphibian Lens Histones and Their Relation to the Cell Cycle

Histones have been electrophoretically separated from acid extracts of the frog lens for the first time. The five conventional histone fractions, representing four electrophoretic bands (f1; f2b, f3; f2a2; and f2a1), are present in both the epithelial and fiber cells. In addition, a fifth fraction was isolated from both sources and the evidence suggests that it may be a tissue-specific histone, possibly related to the lysine-rich f2c fraction found previously only in nucleated erythrocytes. The epithelial cells contain a substantially greater amount of histone than the fiber cells. Moreover, the fibers, unlike the epithelium, manifest no net histone synthesis or turnover following lenticular explantation. Microspectrophotometric, radioautographic, and gel electrophoretic studies indicate that the histones are synthesized in frog lenses concurrently with DNA. Inhibition of DNA synthesis does not completely abolish that of histones but reduces it by about one-half. In the early stages of culture (prior to their synthesis and that of DNA) the histones appear to undergo alterations which are prevented by treatment with cycloheximide.     

Sea urchin sperm DNP. I. Chemical composition and template properties of DNP

Electrophoretic mobility, amino acid composition and salt dissociation of histones isolated from sperm of sea urchin Strongylocentrotus intermedius and calf thymus cells were studied. The special arginine-rich histone fraction (I) has been observed in sea urchin sperm chromatin, this fraction being absent in calf thymus chromatin. Dissociation of lysine-containing histone fractions from sea urchin chromatin occured in the range of 0.7 to 1.0 M NaCl concentrations. H1 of calf thymus chromatin was totally extracted with 0.6 M NaCl. In the course of a further increase of salt concentrations (up to 1.5 M NaCl) a practically total extraction of histones from sperm chromatin was observed, while about 20% of proteins remained bound to DNA in thymus chromatin after extraction with 2.0 M NaCl. The template activity of non-extracted DNP preparations from urchin sperm was equal to 2-3% of that of totally deproteinized DNA. The template activity of DNP gradually increased at protein extraction from DNP preparations. The hybridization capacity of RNA transcribed on partially dehistonized DNP templates in vitro also increased.     

Histone-acetylating enzyme of brain

1. Acetylation of histones by an enzyme system derived from rat brain and liver (histone acetylase) was studied by using [1-(14)C]acetyl-CoA as the acetyl group donor. 2. The activity of this enzyme was largely confined to the nucleus. 3. Histone-acetylating activity of cerebral nuclei purified by centrifugation through 1.9m-sucrose was not altered by the presence of the cytoplasmic fraction. 4. Cerebral nuclei from adult rats exhibited greater histone-acetylating activity than did the corresponding preparation from newborn animals. 5. Nuclear acetylating activity was higher in brain than in liver of adult rats but not in newborn animals. 6. The partially purified enzyme from cerebral nuclei, prepared by ammonium sulphate fractionation of an acetone-dried powder, specifically catalysed histone acetylation. 7. Polylysine, protamine, serum albumin and gamma-globulin were not enzymically acetylated by this preparation. 8. Soluble acetylating preparations from both brain and liver nuclei were more active towards arginine-rich F3 and slightly lysine-rich F2a and F2b histone fractions than towards the lysine-rich F1 fraction. 9. Enzymic acetylation of chromatin-bound proteins was much less extensive than that of free histones. 10. The high histone acetylase activity in mature brain may reflect the importance of this process in the genetic control of cerebral function.     

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.