Variations in the phosphate content and thiol/disulphide ratio of histones during the cell cycle. Studies with regenerating rat liver and sea urchins

1. In regenerating rat liver the phosphate content of the lysine-rich histone F1, but not that of the more arginine-rich histone F3-1, increases during the period of DNA synthesis. 2. The phosphorylation of histone F1 in this ;S period' is decreased by gamma-irradiation, but, like phosphate uptake into DNA, is affected to an even greater extent if the irradiation is given in the presynthetic period. 3. Histones from three species of sea-urchin eggs show similarities to the F2 and F3 groups of histones from mammalian thymus gland. 4. The proportion of thiol to total thiol plus disulphide in acid extracts from sea-urchin eggs varies from less than 20% in mature unfertilized eggs to 59% just before cleavage. 5. The phosphorylated forms of histones F1 and F3 are less effective in decreasing DNA synthesis by DNA polymerase than the non-phosphorylated forms. 6. Oxidation of thiol groups on histone F3-1 does not affect its capacity to decrease DNA synthesis in vitro.     

Further studies on phosphorylation and the thiol/disulphide ratio of histones in growth and development

1. The proportion of thiol groups in the total thiol+disulphide of histone extracts from fertilized eggs from Echinus and Psammechinus was increased during periods of structural alterations in the nucleus. 2. The probable start of DNA synthesis in the fertilized eggs coincided with periods of maximum thiol content. 3. Histone extracts from rat liver and regenerating liver were predominantly in the thiol form and no significant variations could be detected during the first 30hr. after partial hepatectomy. 4. An assay system was developed to follow the phosphorylation believed to be associated with the arginine-rich histone F3. Phosphorylation increased by 50% at 1 and 2hr. after partial hepatectomy. The phosphate content also increased during the period of DNA synthesis. 5. The increased phosphorylation found 1hr. after partial hepatectomy was not prevented by actinomycin or prior irradiation. 6. The phosphate content of histone F1 was very high in livers from foetal rats and declined in neonatal rats similarly to the decline in DNA synthesis.     

Histone kinase and cell division

1. The activity of the soluble phosphokinase for histone F1 increases in regenerating rat liver during the first period of DNA synthesis after partial hepatectomy. The increase probably represents new enzyme synthesis. 2. A dose of 500rd of gamma-irradiation given early in G1 decreases the amount of histone F1 phosphokinase found 22h after partial hepatectomy by 60-70%. 3. The enzyme preparations also contained a histone F1 phosphatase; the presence together of the kinase and phosphatase caused a disproportion between net (31)P uptake and (32)P incorporation into histone F1. 4. All four subclasses of histone F1 could accept phosphate from ATP. 5. Crude enzyme preparations transferred more (31)P into histone F1 with an initially low phosphate content than into one with a high phosphate content; conversely, more (32)P was transferred into the latter.     

Regulation of DNA primase activity by phosphorylation of histone-H1 in regenerating rat liver

The biological importance of histone H1 was investigated in relation to the cell cycle using liver regeneration in rat. Histone H1 was extracted from the regenerating rat liver at various intervals after partial hepatectomy and the number of phosphate residues was measured. The inhibitory effect of the extracted histone H1 on DNA primase was assayed. The activities of DNA polymerase-alpha, DNA primase and DNA synthesis were also determined in the regenerating rat liver. It was found that: 1) phosphate residue in histone H1 from normal rat liver was between 2-3 mol/mol of histone H1. 2) The number of phosphate residues did not change for the first 16h after partial hepatectomy. 3) A dramatic sudden increase of phosphate residues was detected at 18h after partial hepatectomy. 4) The high levels of phosphate residues remained constant thereafter up to 50h. 5) DNA primase activity was less inhibited by highly phosphorylated than by slightly phosphorylated histone H1. It seems probable that phosphorylation of histone H1 is needed for the releasing of DNA primase activity from its inhibited state, which would start DNA synthesis together with DNA polymerase-alpha.     

Action of Miracil D and related compounds on histone synthesis and phosphorylation in regenerating liver

The effect of Miracil D and hycanthone on ³H-amino acid incorporation into histones was studied under conditions known to cause a greater than 90% inhibition of thymidine incorporation into DNA of regenerating rat liver. A dose level of 50 mg of either drug per kg body weight administered 8 h after partial hepatectomy caused an approximate 50% inhibition of amino acid incorporation into fl, f2b and combined f2a plus f3 histone in 24-h regenerating liver. There was little or no effect on amino acid nitrogen concentration or incorporation of ³H-amino acid into the acid-soluble fraction, cytoplasmic proteins or acid-insoluble nuclear proteins. Under the same conditions, Miracil D caused a 65% inhibition of ³²P incorporation into lysirierich f1 histone whereas a structurally related compound, GE-99, did not have a significant inhibitory effect on this parameter nor on [³H]thymidine incorporation into DNA. Temporal studies with hycanthone revealed a suppression of the increased phosphorylation of fl histone in regenerating rat liver without influencing the phosphorylation of other histones. The data support the concept of coordinated control of DNA synthesis and phosphorylation of fl histone.     

The phosphorylation of nuclear proteins in the regenerating and premalignant rat liver and its significance for cell proliferation.

In liver regeneration or neoplastic transformation, phosphorylation of nuclear proteins is stimulated. In the regenerating liver all main histone fractions are involved in this process. The type of histone phosphorylated seems to be dependent on the position of the partially synchronized cells within the generation cycle. At a time when most cells are exhibiting maximum HnRNA-synthesis, histone F2a2 belongs to those fractions with highly stimulated phosphate incorporation. Phosphorylation of this fraction alone is stimulated by cyclic AMP in parallel to a stimulation of HnRNA-synthesis. The preneoplastic liver is characterized by oscillating phosphorylation and dephosphorylation reactions of nearly all histone fractions during the first days of N-nitroso-diethylamine administration. After 2 months of carcinogen feeding a 50-150% stimulation of the phosphorylation of Fl subfractions is observed. The phosphate content of the other histones, however, has returned to the original level. A series of further proteins, isolated together with the histones, show very similar phosphorylation characteristics. These proteins are mostly of non-histone origin. It is suggested that some of them are responsible for the transport of RNA with messenger properties within the cell.     

THE PHOSPHORYLATION OF NUCLEAR PROTEINS IN THE REGENERATING AND PREMALIGNANT RAT LIVER AND ITS SIGNIFICANCE FOR CELL PROLIFERATION

In liver regeneration or neoplastic transformation, phosphorylation of nuclear proteins is stimulated. In the regenerating liver all main histone fractions are involved in this process. The type of histone phosphorylated seems to be dependent on the position of the partially synchronized cells within the generation cycle. At a time when most cells are exhibiting maximum HnRNA-synthesis, histone F2a2 belongs to those fractions with highly stimulated phosphate incorporation. Phosphorylation of this fraction alone is stimulated by cyclic AMP in parallel to a stimulation of HnRNA-synthesis. The preneoplastic liver is characterized by oscillating phosphorylation and dephosphorylation reactions of nearly all histone fractions during the first days of N-nitroso-diethylamine administration. After 2 months of carcinogen feeding a 50–150% stimulation of the phosphorylation of Fl subfractions is observed. The phosphate content of the other histones, however, has returned to the original level. A series of further proteins, isolated together with the histones, show very similar phosphorylation characteristics. These proteins are mostly of non-histone origin. It is suggested that some of them are responsible for the transport of RNA with messenger properties within the cell.     

In vitro phosphorylation of chicken erythrocyte histone by various protein kinases : Absence of phosphorylation from F1 histone

In spite of the presence of nucleus, genetic activity and mitosis are totally depressed in avian erythrocytes. If phosphorylation of histone is involved in such genetic depression, a comparative study of phosphorylation of avian erythrocyte histone can be expected to furnish information about the mechanism of gene control. The present study is the examination of susceptibility of chicken erythrocyte histone to histologically different (liver and muscle) and phylogenically different (avian, mammalian and ichthic) protein kinases. It was found that chicken erythrocyte F1 histone was phosphorylated not only by heterologous (rat and trout liver) but also by homologous (chicken liver and muscle) protein kinases. Addition of cAMP could not elicit phosphorylation of this histone, while phosphorylation of other histones was significantly enhanced by this drug. Avian erythrocyte-specific histone, F2c, was markedly phosphorylated not only by avian enzymes but also by mammalian enzyme. All the enzymes tested phosphorylated F2b histone. F3 histone was phosphorylated at least by avian and mammalian enzymes. F2a1 and F2a2 histones were poor substrate to all the enzymes tested.     

Changes in the nuclear protein kinase activities in the regenerating liver of partially irradiated rat

X rays (4.8 Gy) inhibit both DNA synthesis and phosphorylation of histone H1 in the regenerating liver of the rat. To determine the cause of the inhibition of histone H1 phosphorylation, changes in the nuclear protein kinase activities during the prereplicative phase of regeneration were measured. The cAMP-dependent protein kinase activity was low during regeneration, and the changes in the activity were not statistically significant. The cAMP-independent protein kinase activity increased at 15 h, decreased at 18 h, and increased again at 24 h after partial hepatectomy. X irradiation prior to partial hepatectomy did not inhibit the increase at 15 h, but it did inhibit the increase at 24 h. The activity was not inhibited by isoquinolinesulfonamide inhibitors such as H-7, and it was activated by a commercial preparation of an inhibitor protein of the cAMP-dependent kinase. It was also inhibited by quercetin. The possibility that the radiation-sensitive nuclear protein kinase is a nuclear cAMP-independent protein kinase specific for histone H1 is considered.     

Changes in subfraction composition of chicken lysine-rich histone during ontogenesis]

Lysine-rich histone isolated from different chicken tissues was separated electrophoretically into 4-5 subfractions. The subfrations reffered to as 1, 2, 3, and 4, occur in each the tissue studied, erythrocyte lysine-rich histone containing an additional subfraction 1a. F1 histone from mitotically active tissues (intestinal mucosa, thymus, testes) has a higher content of subfraction 2, while the same histones from mototically inactive tissues (liver, heart, brain) contain an elevated amount of subfraction 3. F1 histone isolated from liver, brain and heart of 21-day embryo has much more of subfraction 2, than the same histone of adult animal. During the chicken development from hatching till maturation the content of subfraction 2 in these organs decreases, and the content of subfraction 3 increases. The rate of this change in liver corresponds to the rate of DNA synthesis. In F1 histone of erythrocytes the content of subfraction 4 falls down during the post hatching ontogenesis.     

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.     

In nondividing cells, histone H1(0) is synthesized and deposited onto chromatin without accompanying phosphorylation

The phosphorylation of H1 histone subfractions was measured in mouse neuroblastoma cells stopped from dividing by three treatments that block cell division: 5 mM butyrate, 2% dimethyl sulfoxide, and serum withdrawal. H1 histone phosphorylation decreased in response to all three treatments, but the response differed in its timing and its extent for the different H 1 subfractions. The different decreases in phosphorylation correlated well with the differential decreases in biosynthesis of the individual H1 subfractions; however, an exception to this parallel decrease in synthesis and phosphorylation was observed in the case of histone H1(0). Phosphorylation of H1(0) was absent in each of the three treatments after 2 days, despite the continued synthesis and deposit of H1(0) on the chromatin. Thus, despite the fact that H1(0) was being synthesized and that the other newly synthesized H1 subfractions were phosphorylated at this time, the phosphorylation of H1(0) became uncoupled from its synthesis after prolonged treatments blocking cell division.     

Histone phosphorylation during liver regeneration.

The pattern of histone phosphorylation at acid-stable, alkali-labile sites has been examined throughout the early stages of liver regeneration, namely at times of “gene activation”. Among the histones, only H1 shows an increase in phosphorylation. This increase initiates near the end of the period of chromatin template activation. Thus, there is no obvious temporal correlation between increased histone phosphorylation and increased RNA synthesis. The relative levels of phosphorylation of the various histones and the change in H1 phosphorylation observed in the liver system closely parallel the patterns exhibited by cultured animal cells during the G1 and S phases of the cycle as described by other investigators.     

Thyroxine stimulation of tadpole liver histone phosphorylation in vivo

The in vivo phosphorylation of histones in the livers of Rana catesbeiana tadpoles was followed during the course of thyroxine-induced metamorphosis. Phosphorylation of histones H1 and H2a, and possibly of histone H4 at a low level, was observed in all animals. After correction for specific radioactivity of liver inorganic phosphate pools, an apparent wave of phosphorylation of histones was found to occur between 2 and 8 days of thyroxine treatment, with a peak increase of approximately 2- to 5-fold for histones H2a and H1. The increases in liver histone phosphorylation are approximately coincident with well-documented increases in the levels of various liver enzymes and occur in the absence of any change in the low basal rate of histone or DNA synthesis in this organ. This is apparently the first instance of increased phosphorylation of both H1 and H2a which is not coincident with or precedent to increases in cellular proliferation rates.     

Modulation of nuclear protein kinase activity and phosphorylation of histone H1 subspecies during the prereplicative phase of rat liver regeneration

We have measured nuclear protein kinase activity during the prereplicative phase of rat liver regeneration. Total nuclear protein kinase activity increased significantly 15-18 h after partial hepatectomy, with the peak of activity occurring at 16 h. DEAE-Sephacel chromatography resolved nuclear protein kinase activity into two cAMP-independent (Ib and II) and two cAMP-dependent (Ia and III) protein kinases. Sixteen h after partial hepatectomy, there was a marked increase in the activities of the nuclear cAMP-dependent protein kinases and a decrease in the activity of nuclear cAMP-independent protein kinase II. Characterization of the two nuclear cAMP-dependent protein kinases revealed them to be identical with the cytosolic type I and II isozymes. Immunotitration of nuclear catalytic subunit and densitometric analysis of autoradiographs from 8-azido-[32P]cAMP-labeled nuclear RI revealed increases in both subunits 16 h afer partial hepatectomy. Concomitantly with the observed increase in nuclear protein kinase activity, we have observed an increase in the phosphorylation of histone H1 subspecies. Administration of the beta-adrenergic antagonist DL-propranolol, which has been shown to cause delays of equal duration in both the second phase of increased intracellular cAMP levels and the initiation of DNA synthesis (MacManus, J. P., Braceland, B. M., Youdale, T., and Whitfield, J. F. (1973) J. Cell. Physiol. 82, 157-164), results in an equivalent delay of increased nuclear protein kinase activity. Colchicine, which has previously been shown to prevent the onset of DNA synthesis (Walker, P. R., and Whitfield, J. F. (1978) Proc. Natl. Acad. Sci. U. S. A. 75, 1394-1398), also prevents the increased protein kinase activity normally observed 16 h after partial hepatectomy. We conclude that the onset of DNA synthesis in the regenerating rat liver is preceded by a cAMP-mediated translocation of type I and type II cAMP-dependent protein kinase to the nucleus and phosphorylative modification of histone H1 subspecies. The inhibitory effects of propranolol and colchicine suggest a common cAMP-mediated, colchicine-sensitive link between protein kinase translocation and the initiation of DNA synthesis.     

Increased phosphorylation of nuclear substrates for rat brain protein kinase C in regenerating rat liver nuclei.

Protein phosphorylation catalysed by rat brain protein kinase C (PKC) has been studied in nuclei isolated from normal and regenerating rat liver. Histone H1 and a 40,000 molecular weight protein were hyperphosphorylated at all the explored regeneration times, ranging from 3 to 22 h after partial hepatectomy. Phosphorylation of the two substrates was totally dependent on calcium and lipids and was abolished by low concentration of staurosporine. The observed early change of phosphate content of histone H1 and of the 40,000 molecular weight protein on the time scale of liver regeneration suggests that PKC might be involved in the initial nuclear events leading to cell proliferation.     

Nuclear protein kinases in rat liver: evidence for increased histone H1 phosphorylating activity during liver regeneration.

Comparison of protein kinase activity in normal and regenerating rat liver nuclei indicates that exogenous histone H1 is hyperphosphorylated in 22-h regenerating nuclei. The protein kinase involved is not sensitive to protein kinase A inhibitor, is inhibited by staurosporine and by an anti-PKC polyclonal antibody, utilizes only ATP, and also phosphorylates the C-terminal fragment of histone H1. These data suggest that protein kinase C is responsible for the observed effects, in agreement with the presence of this enzyme in normal and regenerating nuclei demonstrated by immunoblotting.     

The maximum of the histone acetyltransferase activity precedes DNA-synthesis in regenerating rat liver

A pronounced transitory increase of histone acetyltransferase (EC 2.3.1.48) activity before the onset of DNA replication is shown to occur in regenerating rat liver. This effect is followed by an increase in the H1/H1(0) ratio at the start of DNA synthesis; H1(0) de is replaced by H1. Histone acetylation and H1/H1(0) exchange are discussed as steps in the signal transduction for DNA replication.     

Sequential phsophorylation of histone subfractions in the Chinese hamster cell cycle.

Ion exchange chromatography and preparative electrophoresis were used to examine the phosphorylation of histone f1 and f3 subfractions in synchronized Chinese hamster cells (line CHO). Three discrete f1 phosphorylation events were demonstrated to occur in sequence during the cell cycle. The first event (f1G1) commenced in G1 2 hours prior to entry of cells into S phase; the second event (f1s) commenced simultaneously with initiation of DNA synthesis; and the third event (f1M) commenced when cells entered mitosis. F1M phosphorylation occurred simultaneously with the phosphorylation of histone f3 (which is not phosphorylated during G1, S, or G2). Fractionation of f1 and f3 revealed no differences in these sequential phosphorylation patterns among the various f1 and f3 subfractions, indicating that these phosphorylations are general biochemical events of the cell cycle. Phosphorylated (f1G1) was found to accumulate in cells as they traversed THEIR CELL CYCLE. F1s was phosphorylated to twice the extent of f1G1, but f1s did not accumulate in the cells as they passed through interphase. F1M was phosphorylated to about 4 times the extent of the first phosphorylated form (f1G1). A model of the relationship of histone phosphorylation to the cell cycle is presented which suggests that (a) f1G1 phosphorylation is involved with chromatin structural changes necessary for cell proliferation; (b) f1s phosphorylation is involved with DNA replication; (c) F1M and f3 phosphorylations are involved in chromosome condensation.     

Advance of mitosis by histone phosphokinase

The previous observation that growth-associated histone kinase (HKG) from Ehrlich ascites cells brings forward mitosis in Physarum polycephalum has been confirmed with more step 1 histone kinase and a more purified (step 2) histone kinase and the statistical significance of the results assessed. The mitosis appears normal in the phase contrast microscope and DNA synthesis is initiated after mitosis as usual. In vitro the growth-associated histone kinase phosphorylates chromatin, the phosphate appearing in F 1 histone. The results are interpreted as providing support for the hypothesis that growth-associated histone kinase controls the initiation of mitosis through F 1 histone phosphorylation and chromosome condensation.