Studies on histones and non-histone proteins from rats treated with dimethylnitrosamine.

A study has been made of the histone and non-histone chromosomal proteins of rat liver after treatment in vivo with dimethylnitrosamine (DMN) (2 mg/kg). DMN was found not to affect histone turnover, as measured by 3H-labelled amino-acids incorporation. A decrease was observed in specific activity of the histones with time after injection of [14C]DMN or [14C]-formate and this was attributable to demethylation of both abnormal and normal methylation sites in these proteins. In the case of the non-histone proteins, DMN was found to increase greatly the turnover of those non-histone proteins loosely associated with chromatin DNA and RNA; turnover of those non-histone proteins tightly bound to chromatin DNA and RNA was unaffected. Demethylation of both normal and abnormal methylation sites was found to take place from both non-histone protein fractions. In the case of the loosely bound non-histone proteins a lower rate of demethylation was observed after DMN treatment.     

Acetylation of histones of rat testis.

When [1-¹⁴C]acetate was injected into rats intratesticularly in the presence of cycloheximide to inhibit protein synthesis, the label was incorporated into histone fractions F2a1 and F3 and into non-histone chromosomal proteins of each of the following stages of spermatogenesis: spermatogonia-preleptotene spermatocytes, leptotene-zygotene-pachytene-diplotene primary spermatocytes, and spermatids. Acetylation of histones was particularly active in the spermatid stages. There was no significant incorporation of acetate into the lysine-rich histone fractions F1 and X₁.In early periods of in vivo incorporation of [³H]amino acids into histones the acetylated histone F2a1 fractions had higher specific activities than the main band of F2a1, but with the passage of time the label moved into the principal band to the extent that specific activities in the acetylated and principal bands were approximately equal at 6 days. However, at 24–36 days the specific activities were again higher in the acetylated bands than in the principal band of F2a1. These data support the conclusions of Candido, Louie, and Dixon, from experiments with trout testis, that acetylation of histone F2a1 may be important in the process of combination of this protein with DNA in chromatin at the spermatogonia-primary spermatocyte stage and also in the subsequent removal of this histone for replacement by protamines at the spermatid stage.[³H]Amino acids were incorporated into histone fractions X₁ and F1 at approximately equal rates, and there was no evidence that one of these fractions was a precursor of the other.Chromatin of the seminiferous epithelial cells of rat testis has a firmly bound acetylase which catalyzes the in vitro acetylation of histones F3 and F2a1 by acetyl CoA.     

Metabolic activities of histones in rat liver and spleen.

Synthesis and turnover of histone I and II in normal rat liver and spleen were studied by Amberlite CG 50 column chromatography. Histone I was separated into three or four subfractions, each of which showed a different rate of incorporation of [3H]lysine. This was verified by a more shallow gradient chromatography developed by Kinkade and Cole [3] for very lysine-rich histone (F1), which showed tissue specific differences between liver and spleen in both the elution pattern and synthetic rates. These subfractions were distinguished from each other by dodecylsulphate electrophoresis. The turnover, or disassociation of histone I and II in chromatin was measured by double-labelling of normal rat liver with [3H] and [14C]lysine. A good correspondence was found between the synthesis and turnover patterns of individual histone I fractions, while the histone II synthesized was conserved for over a month. From consideration of the turnover in relation to the cell population of normal liver tissue, which consists of a very small fraction of growing cells and a very large fraction of resting ones, it was concluded that turnover of histone I must occur even in resting cells. When DNA synthesis in the spleen was completely inhibited by hydroxyurea, the synthesis of histone II was inhibited but that of histone I was only partially inhibited. The remaining synthesis seemed to occur in cells in the resting state. It was concluded tentatively, the continuous replacement of very lysine-rich histones of chromatin must occur even in resting cells in which DNA synthesis has ceased. The biological significance of disassociation of histones from chromatin was discussed.     

IN VIVO METHYLATION AND TURNOVER OF RAT BRAIN HISTONES

Abstract— The turnover of the different histone components from brain nuclei was studied after the administration of l -[³H]lysine and l -[¹⁴C-methyl]methionine to newborn rats. The radioactivities of the different histone subfractions as well as other proteins were determined over a 280-day period. Biphasic type decay curves (³H and ¹⁴C) were obtained for total brain histones and all the subfractions. From 6 to 40 days of age the half life of total brain histones was 19 days. After reaching brain maturity the half life was 132 days. The lysine rich histone (F₁) was found to turnover the fastest of all the histones, having half lives of 13 and 112 days, respectively. The decay curve for the slightly lysine rich histones (F_2a2, F_2b) gave half lives of 25 days up to 40 days of age and 189 days after reaching brain maturity. The arginine rich histones (F_2a1, F₃) gave a half life of 32 days up to 40 days of age, while no turnover was observed after maturity. The turnover rates of the methyl groups and/or methionyl residues did not vary significantly from the turnover rates of the lysyl residues in the F₂ and F₃ histones. The lysine-rich histones did not contain significant amounts of methionyl residues or methyl groups.
Amino acid analysis of the brain histones revealed that about 3·6 per cent of the lysyl residues in the slightly lysine rich histones were methylated, mainly as ε-N-dimethyllysine. About 13 per cent of the lysyl residues in the arginine rich histones were methylated, mainly as ε-N-monomethyllysine and ε-N-dimethyllysine.     

Chromatin proteins from normal,vegetalized, and animalized sea urchin embryos

The chemical composition of the chromatin, the fractional content of histones and nonhistone chromatin proteins (NHP), and the biosynthesis of these proteins in normal, vegetalized, and animalized embryos of the sea urchin Strongylocentrotus droebachiensis at the blastula, mesenchyme blastula, and gastrula stages have been studied. The amount of the NHP in the chromatin from normal and vegetalized embryos increases during early embryonic development while that in animalized embryos remains without change at the mesenchyme blastula stage and then decreases. During development the histone content in all three cases slightly decreases. Polyacrylamide gel electrophoresis reveals that both fractional composition of histones and their biosynthesis in normal, vegetalized, and animalized embryos display no differences. During development, however, some changes occur, so that the relative amount of histones F1 and F2a2 increases, F2b decreases, while F3 and F2a1 remains constant. Histone F1 at the blastula stage consists of two subfractions while at the gastrula stage it consists of three subfractions. The histone F2a1 consists of one and two, respectively. Histone F3 at all stages is made up of three subfractions; histone F2b is made up of two; and the histone F2a2 is electrophoretically homogeneous. Specific radioactivity of the arginine-rich histones F3 and F2a1 tends to increase during development, while that of moderately lysine-rich histones F2b and F2a2 does not change, and that of the lysine-rich histone F1 decreases. The NHP in normal, vegetalized, and animalized embryos at different developmental stages consist of 17 fractions that can be separated by isoelectrofocusing within the 4.5-8.8 pH range. Quantitative changes have been observed in the fractions focused at pH 4.5-6.1 during development and in normal and modified embryos at the gastrula stage.     

The effect of sodium butyrate on acetylation in vitro of chromosomal proteins in three classes of liver nuclei from different ages of rats

The optimum conditions of in vitro incorporation of sodium [³H]acetate into sliced rat liver were studied. The incubations with sliced liver from three different ages of rats were performed in the presence of sodium n-butyrate. It was found that butyrate decreases the incorporation of sodium [³H]acetate into the homogenate, isolated nuclei, non-histone chromosomal proteins and histones for all age groups. The acetylations of non-histone chromosomal proteins and histones increase with age upto 2-months and decrease in 4-month-old rats both in the absence and presence of butyrate. Liver nuclei were fractionated by the simple method of zonal centrifugation into three classes, namely diploid stromal, diploid parenchymal and tetraploid parenchymal nuclei. The acetylations of non-histone chromosomal proteins and histones in three classes of nuclei of three ages of rats were studied in the presence and absence of butyrate. Butyrate can decrease the overall acetylations of non-histone chromosomal proteins and histones but increase the amount of polyacetylated histone H4 in all classes of nuclei of the three ages.     

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.     

Effect of extraction of histones and their reconstitution on [3H] actinomycin D binding to isolated nuclei of the root of Pinus silvestris.

The purpose of the study presented was to investigate the effect of the extraction of histones on the template activity of DNA, measured by the autoradiographically evaluated intensity of [3H]actinomycin D ([3H]AMD) binding. The study was carried out on nuclei isolated from the root meristem of Pinus silvestris. Histones were removed selectively from them and reconstituted in the nuclei deprived of these proteins. The greatest rise in radioactivity was found after the extraction of the arginine fraction and that of lysine-rich and moderately lysine-rich fractions removed together, whereas the extraction of the lysine-rich fraction does not cause such a considerable increase in radioactivity. The reconstitution of particular histone fractions induced a fall in radioactivity to the level of controls in all the cases examined. No [3H]AMD binding to the nucleolus was found. The extraction of lysine histones results in the decondensation of chromatin and their reconstitution in the formation of complexes of compact chromatin.     

MEASUREMENT OF BRAIN PROTEIN TURNOVER WITH [14C]SODIUM BICARBONATE1

Abstract— Protein turnover in rat brain was measured over a period of 30 days by following the decay in specific radioactivity of acidic amino acids in proteins labelled by a single intraperitoneal injection of [¹⁴C]NaHCO₃. Two major populations of brain proteins can be identified from the resultant non-linear decay curve—one with an average half-life of 4 days and another with an average half-life of 12 days. The half-lives of total brain, mitochondrial, microsomal and soluble proteins determined over a period of 5 days were 3.4, 5.8, 2.8, and 2.6 days, respectively. Turnover of these same brain subcellular fractions was also measured by continuous infusion of [¹⁴C]tyrosine. The estimated half-lives were in close agreement with those obtained from the 5 day measurement of radioactive decay following a pulse label of [¹⁴C]NaHCO₃.     

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.     

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.     

Nuclear proteins and DNA in the myocardial myocytes in compensatory cardiac hypertrophy]

Using cytophotometry, the amount of DNA, total nuclear proteins and of histones were studied in the myocardial cells during days 21--36 of experimental compensatory hypertrophy of the heart (in rats). The enlargement of myocardial nuclei during the cardial hyperfunction was accompanied by accumulation of total nuclear protein, in particular, the histone fraction, without distinct changes in DNA. Analysis of correlations between nuclear proteins and DNA in the myocardial cells allows to reveal a delayed accumulation of histones in the big and gigantic nuclei, with a superfluous increase in non-histone nuclear proteins. In middle-sized nuclei, non-histone proteins have little changes against intensive accumulation of histones.     

Effect of X-radiation on DNA and histone synthesis in ataxia telangiectasia and normal lymphoblastoid cells

The possibility that the radiosensitivity of lymphoblastoid cell lines from patients with ataxia telangiectasia (A-T) is due to an aberrant content of histones has been examined. The histone pattern of lymphoblastoid cell lines derived from A-T patients was found to be indistinguishable from that obtained from normal individuals. X-ray irradiation led to a greater decrease in cell growth rate in the A-T cells than in the normal cells but was accompanied by a greater decrease of DNA synthesis rate in the normal cells. This difference in radiosensitivity was not reflected in differences in the content or rates of synthesis of histones or of major non-histone proteins in these cells. Reduction in the rate of DNA synthesis was not associated with the appearance of the lysine-rich histone variant H1. We conclude that the hypersensitivity to ionizing radiation in A-T cells is not due to fundamental differences in the composition or synthesis of the major chromosomal proteins.     

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.     

Two chromatin fractions with different metabolic properties of non-histone proteins and of newly synthesized RNA.

Digestion of chromatin with micrococcal nuclease under mild conditions results in the release of a minor chromatin fraction showing an increased RNA and non-histone protein content, a fast turnover of the non-histone proteins and the presence of rapidly labelled heterogeneous nuclear RNA (hnRNA) with half-life of about 20 min. Further digestion of the chromatin leads to the elimination of about 19% of the initial chromosomal DNA, thus leaving a second chromatin fraction relatively resistant to nuclease attack. This fraction has a low protein and RNA content and contains only metabolically stable non-histone proteins. No differences in the histone complement of the two fractions was found except for a 40% deficiency of H1 in the minor fraction.     

Studies on highly metabolically active acetylation and phosphorylation of histones.

The capacity to effectively label tumor cell hostones using very short pulses of [3-H]acetate and [32-P]phosphate (1 to 10 min) has been developed. Four histone fractions F3, F2a1, F2a2, and F2b are extensively acetylated in short time periods. About 70% of the acetate accumulated on the histone during a short pulse is removed with a half-life of similar to 3 min. The rest of the metabolically active acetate is removed with a half-life of 30 to 40 min. Histones F2a1, F2a2, and F1 are acetylated at the NH2 terminus and this modification is metabolically stable. In short pulses, histones are labeled with 32-P in the order F2a2 greater than F1 greater than F3 greater than F2a1 greater than F2b. All fractions have a fairly rapid turnover time (t1/2 similar 20 to 40 min) except F1 phosphate which turns over some 5 times more slowly.     

Proteinase activity of nuclei from various tissues towards endogenous histones]

The proteinase activities of nuclei isolated from tissues differing in their mitotic activities (brain, thymus, liver, ascite lymphoma) towards the histones and non-histone acid -- extractable proteins were studied. The sensitivity of different histone fractions to nuclear proteinase depends on temperature and time of nuclei incubation under conditions providing for complete dissociation of chromatin proteins from DNA (2 M NaCl--5 M urea). The proteinase activity in the brain and thymus nuclei is revealed only under prolonged (43 hrs) incubation of the nuclei at 25 degrees C, which is accompanied by partial proteolysis of histone H1. Histone H4 from brain nuclei and histone H2a from thymus nuclei are preferably degraded. In the nuclei isolated from the mice ascite cell lymphoma NK/ly and from rat liver the enzyme activity is revealed mainly towards the arginine-enriched histones H3 and H4. The proteolysis of the arginine-enriched histones in tumour cell nuclei is more complete. A high sensitivity to proteolysis was observed for non-histone acid-extractable proteins with low electrophoretic mobility, which were found in brain and tumour cell nuclei.     

Properties of the genome in normal and SV40 transformed WI38 human diploid fibroblasts. II. Metabolism and binding of histones.

Composition, metabolism and extractability of histone fractions from WI38 human diploid fibroblasts and SV40 transformed WI38 fibroblasts are compared. Two alternate procedures were used for isolation of nuclei which allow for either optimal recovery of arginine-rich histones F3 (III) and F2a1 (IV) or for optimal retention of lysine-rich F1 (I) and slightly lysine rich F2b (II b2). While the relative amount of each histone fraction was found to be similar in normal and SV40 transformed cells, substantial increases in the levels of F 3 acetylation and F1 and F2a2 phosphorylation are reported for the histones of SV40 transformed cells. Differences in extractability of arginine-rich histones with 0.25 M HCl are also reported. While F 3 is extracted more rapidly than F 2a1 from nuclei of normal WI38 fibroblasts, the reverse is true in SV40 transformed WI38 cells. These differences are discussed in relation to modification reactions, binding of histones to DNA and SV40-induced alterations in gene readout.     

CYTOCHEMICAL AND BIOCHEMICAL DETERMINATIONS OF CHANGES IN NUCLEAR HISTONE CONTENT DURING DIFFERENTIATION OF BARLEY ROOT CELLS

Changes in nuclear histone content in barley root cells have been studied by cytochemical methods for identification of histone subtypes and by conjunction with standard biochemical extraction procedure for various histone fractions and alkaline fast green stainability. The results obtained by the cytochemical methods indicate that the nuclear histones in cell nuclei found in their terminal stages of cellular differentiation or elongation contain histones rich in arginine, whereas the nuclei in meristematic cells contain histones rich in lysine. Cytochemicaly intermediate or transitional types of nuclear histones have been observed in cell nuclei which are undergoing differentiation or elongation and in chromosomes of mitotic nuclei. Information obtained from the conjunction of methods of biochemical extraction procedures for various histone fractions and alkaline fast green stainability indicate that the nuclei in well-differentiated cells contain predominantly histones rich in arginine (f3), whereas the nuclei of meristematic cells contain both very lysine-rich histones (f1) and slightly lysine-rich histones (f2). These results suggest the replacement of lysine-rich histones in the nuclei of meristematic cells by arginine-rich histones during cellular differentiation.