Exchange of histones H1, H2A, and H2B in vivo

We have asked whether histones synthesized in the absence of DNA synthesis can exchange into nucleosomal structures. DNA synthesis was inhibited by incubating hepatoma tissue culture cells in medium containing 5.0 mM hydroxyurea for 40 min. During the final 20 min, the cells were pulsed with [3H]lysine to radiolabel the histones (all five histones are substantially labeled under these conditions). By two electrophoretic techniques, we demonstrate that histones H1, H2A, and H2B synthesized in the presence of hydroxyurea do not merely associate with the surface of the chromatin but instead exchange with preexisting histones so that for the latter two histones there is incorporation into nucleosome structures. On the other hand, H3 and H4 synthesized during this same time period appear to be only weakly bound, if at all, to chromatin. These two histones have been isolated from postnuclear washes and purified. Some possible implications of in vivo exchange are discussed.     

Nonrandom assembly of chromatin during hydroxyurea inhibition of DNA synthesis

Incubation of MSB-1 chicken lymphoblastoid cells with hydroxyurea leads to a rapid 25-fold decrease in the incorporation of [3H]thymidine into DNA and a 5-fold decrease [3H]lysine into the nucleosome core histones. I have investigated whether the distortion in the normal proportion of histone-DNA synthesis results in alterations in the nucleosome assembly process and find that neither the stoichiometry of new histone synthesis nor the deposition is appreciably changed during hydroxyurea incubation. Protein cross-linking and micrococcal nuclease digestion show that the histones synthesized during hydroxyurea treatment form octamer structures and are assembled into typical nucleosome particles. Minor nucleosome subpopulations are found which exhibit altered sensitivity to nuclease digestion and which are depleted in new histones H3 and H4. When MSB-1 cells incubated in hydroxyurea are pulsed briefly with density-labeled amino acids and [3H]lysine, the radiolabeled core histone octamers formed are as dense as individual monomer histones. These results suggest that the newly synthesized histone octamers are uniformly dense and do not contain mixtures of new and old histones. Thus, histones synthesized during hydroxyurea incubation are deposited nonrandomly and do not exchange with preexisting histones.     

Distribution of the core histones H2A.H2B.H3 and H4 during cell replication.

The distribution of newly synthesized core histones H2A, H2B, H3 and H4 relative to the DNA strand synthesized in the same generation has been examined in replicating Chinese Hamster ovary cells. Cells are grown for one generation in [14C]-lysine and thymidine, and then for one generation in [3H]-lysine and 5-bromodeoxyuridine (BrUdRib) and a further generation in unlabeled lysine and thymidine. This protocol produces equal amounts of unifilarly substituted and unsubstituted DNA. Monomer nucleosomes isolated from chromatin containing these two types of DNA can be distinguished by crosslinking with formaldehyde and banding to equilibrium in CsCl density gradients. The results indicate that the core histones are equally distributed between the two types of DNA. These findings are discussed in terms of current models for chromatin replication; they do not support any long term association of newly replicated histones with either the leading or lagging side of the replication fork.     

Structural state of newly replicated closed circular simian virus 40 DNA.

We have studied the early transition of newly replicated, segregated daughter molecules of simian virus 40 (SV40) into their mature, fully supercoiled state. The DNA of SV40 replicating in African green monkey kidney CV1 cells was chronically labeled with [14C]thymidine and pulse-labeled with [3H]thymidine. The cells were lysed and the viral DNA was isolated. Density gradient centrifugation of viral DNA in cesium chloride revealed that the pulse-labeled, newly synthesized, closed circular supercoiled DNA molecules banded at a slightly higher density (delta sigma = 0.0025) than the chronically labeled DNA, suggesting that the newly completed molecules were in a different structural state. Electrophoresis of DNA in agarose gels at appropriate chloroquine concentrations demonstrated that the mobility of the pulse-labeled closed, superhelical DNA was retarded relative to that of the chronically labeled DNA. These observations indicated that the newly completed SV40 DNA molecules existed in a structural state more relaxed than that of mature DNA by one or two linking numbers.     

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.     

Histone methylation. Its occurrence in different cell types and relation to histone H4 metabolism in developing trout testis.

Histone methylation in developing trout testis has been observed in the diploid stem cells and primary spermatocytes, which actively synthesize DNA and histones. In spermatids, histone methylation is minimal and so probably plays no role in the replacement of histones by protamine which is characteristic of this cell type. No turnover of histone methyl groups could be detected over several hours, so that unlike acetylation or phosphorylation of histones, methylation in this tissue appears to be a stable, irreversible modification. When histone H4, labeled with [14C]methyl groups, is separated on starch gels into acetylated and phosphorylated derivatives, [14C]methyl label does not appear in positions characteristic of newly synthesized histone H4, i.e. the highly acetylated (di-, tri-, and tetra-acetylated), unphosphorylated species. [14C]Methyl label appears rather in the unphosphorylated, and unacetylated or monoacetylated species, shifting with time to the monophosphorylated form of histone H4. These data suggest a temporal sequence of events for histone H4: synthesis, then acetylation and deacetylation, followed by methylation and phosphorylation. Occurring late after histone synthesis and assembly into chromatin, histone methylation might then be necessary for histone interactions with other molecules (e.g. histone phosphokinase) prior to mitosis.     

A reevaluation of new histone deposition on replicating chromatin

In this study, we have density-labeled newly replicated DNA in hepatoma tissue culture cells and separated the newly replicated nucleoprotein from bulk material using density gradient centrifugation. These experiments indicate that only newly synthesized histones H3 and H4 deposit specifically on newly replicated DNA. Histones H2A and H2B show a partial preference and histone H1 shows no preference for deposition on new DNA. These experiments also indicate that for a whole cell cycle, the non-H1 histones remain associated with the same DNA upon which they were initially deposited. However, when that region is replicated during the next cell cycle, the histones distribute equally to both daughter strands. An increase or decrease in the level of histone modification (acetylation) induced by sodium butyrate treatment does not alter the in vivo stability of the histone-DNA interactions. Experiments which involved labeling SV40 minichromosomes with [3H]lysine confirm our observations that only newly synthesized histone H3 and H4 are selectively depend on replicated DNA.     

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.     

Establishment of Histone Modifications after Chromatin Assembly

Every cell has to duplicate its entire genome during S-phase of the cell cycle. After replication, the newly synthesized DNA is rapidly assembled into chromatin. The newly assembled chromatin ‘matures’ and adopts a variety of different conformations. This differential packaging of DNA plays an important role for the maintenance of gene expression patterns and has to be reliably copied in each cell division. Posttranslational histone modifications are prime candidates for the regulation of the chromatin structure. In order to understand the maintenance of chromatin structures, it is crucial to understand the replication of histone modification patterns. To study the kinetics of histone modifications in vivo, we have pulse-labeled synchronized cells with an isotopically labeled arginine (¹⁵N₄) that is 4 Da heavier than the naturally occurring ¹⁴N₄ isoform. As most of the histone synthesis is coupled with replication, the cells were arrested at the G1/S boundary, released into S-phase and simultaneously incubated in the medium containing heavy arginine, thus labeling all newly synthesized proteins. This method allows a comparison of modification patterns on parental versus newly deposited histones. Experiments using various pulse/chase times show that particular modifications have considerably different kinetics until they have acquired a modification pattern indistinguishable from the parental histones.     

Formation and repair of DNA-protein crosslinks in newly replicated DNA

The production and removal of gamma-radiation-induced DNA-protein crosslinks (DPC) in nuclear matrix-associated newly replicated DNA were examined, as well as the relationship of DPC to DNA replication. In unirradiated, exponentially growing Chinese hamster V79 cells, DNA pulse labeled with [3H]thymidine was observed to be bound preferentially to protein. The pulse-labeled DNA subsequently became dissociated from protein. After a 30- to 60-min chase period, the level of labeled DNA in DPC was reduced to the same level as for bulk DNA. The radiation dose response for the formation of DPC was similar in newly replicated DNA that had been chased for various times and in mature chromatin DNA. Labeled DNA, in the DPC formed after 60 Gy, was rapidly removed from protein during the postirradiation incubation period. However, no recovery of DNA synthesis was observed, even after the majority of DPC were released. Thus either DPC are not the sole cause of the inhibition of DNA synthesis or their removal is not sufficient for DNA synthesis to resume.     

The sites of deposition of newly synthesized histone.

The chromosomal fragments produced by nuclease digestion of freshly replicated chromatin migrate more rapidly relative to bulk chromatin when analyzed in nucleoprotein gels. The cause of the anomalous migration has been studied and the evidence indicates that rather than reflecting a shorter nucleosomal repeat in vivo that it may be a consequence of nucleosome sliding during the digestion itself. The distinct electrophoretic characteristics of nucleosomal material containing newly replicated DNA have enabled us to examine their histone composition by two dimensional electrophoresis. We find that nucleosomes containing new DNA also contain newly synthesized histones H3 and H4. In contrast more than 50% of newly synthesized H2A and H2B, and essentially all of new H1, are deposited at sites on the bulk chromatin distinct from that material containing newly replicated DNA. In addition we show that newly synthesized histones H3 and H4 are bound unusually weakly when they first become associated with the chromatin.     

Interaction of benzo[alpha]pyrene diol-epoxide with nuclei and isolated chromatin.

Chicken erythrocyte chromatin and nuclei were labeled with benzo[alpha]-pyrene (B[alpha]P) diol-epoxide (anti) and digested with micrococcal nuclease to mono- and dinucleosomes. Analysis of the distribution of the carcinogen showed that the internucleosomal region bound 3-4 times more carcinogen per unit DNA than did nucleosomes. The enhanced binding of the 'ultimate' carcinogen to the internucleosomal region was similar when isolated chromatin or nuclei were used for in vitro labeling. Furthermore, isolation of the histone core proteins, H2A, H2B, H3 and H4, revealed that only 15% of the carcinogen was associated with the histones and that the majority of the carcinogen was bound to chromosomal DNA. Fluorography of purified nucleosomal histones showed that the covalent association of the carcinogen was mainly with histones H3 and H2B.     

Characterization of Simian virus 40 DNA component II during viral DNA replication

Replicating molecules of Simian virus 40 DNA labeled during a short pulse with [³H]thymidine have been fractionated by ultracentrifugation methods and the open circular form (DNA component II) has been characterized. The pulse-labeled DNA component II is a relatively small constituent (1 to 3%) of the pool of replicating molecules. Examination of the circular (18 S) and linear (16 S) strands of DNA component II by alkaline sedimentation and by degradation using exonuclease III of Escherichia coli reveals that the newly synthesized DNA is principally in the linear strand. Cleavage of pulse-labeled DNA component II by an fi⁺, R-factor restriction endonuclease from E. coli demonstrates that the interruption in the pulse-labeled strand is specifically located at the termination point for replication.During a chase period of 20 minutes the amount of DNA component II increases to about 6 to 8% of the total labeled viral DNA. The kinetics of formation of superhelical, DNA component I and disappearance of replicative intermediates are linear during the chase period. After several hours of continuous labeling of replicating viral DNA, the DNA component II pool consists mainly of molecules labeled in both strands with the interruption non-specifically located in either strand. These molecules probably arise by the random introduction of single-strand breaks in newly synthesized DNA component I. During short periods of continuous labeling with [³H]thymidine, the ratio of DNA components I to II increases as a function of the pulse duration. These results support a model for 8V 40 DNA replication in which the open circular form is a precursor of the superhelical form.     

Histones H1 and H4 are present near the replication fork

The presence of histones H1 and H4 at the sites of actual DNA synthesis has been studied with Ehrlich ascites tumour cells, pulse labeled for different times with ³H-thymidine and then treated with formaldehyde to crosslink histones to DNA. The fixed chromatin fragments were sonicated to reduce the size of DNA, purified in a CsCl gradient and immunoprecipitated with antibodies to histones H1 and H4. Determination of specific radioactivity in precipitated probes showed that both histones have been associated with nascent DNA even upon 1 min pulse with ³H-thymidine, thus indicating their presence near the replication fork.     

Differential stimulation of histone and high mobility group chromatin protein synthesis in the rat uterus by estrogen

Uterine tissue isolated from immature rats at different times after estradiol injection was incubated with medium containing [3H]lysine. The acid-extractable protein from the uterine tissue was subjected to electrophoresis on sodium dodecyl sulfate and acid-urea-Triton X-100 polyacrylamide gels, and the rate of chromatin protein synthesis determined by densitometric analysis of the fluorographs of the gels. Synthesis of chromatin proteins (histones and high mobility group chromatin proteins) was stimulated by 3 h after estrogen treatment and reached a peak at 9 h, several hours before DNA synthesis was stimulated. Synthesis of chromatin proteins occurred at the same time as total cellular protein synthesis. Estrogen stimulated the synthesis of histone variants at different rates, but the accumulation of histone proteins remained coordinated such that equivalent amounts of histone proteins were being produced at any one time.     

Gaps in DNA synthesized by ultraviolet light-irradiated WI38 human cells.

DNA replication in ultraviolet-irradiated human cells was examined by treatment of the extracted DNA with a single-strand specific endonuclease from Neurospora crassa. WI38 cells were uniformly labeled with 32Pi for two generations before irradiation and then labeled with [3H]thymidine after irradiation. The isolated DNA was sedimented in neutral sucrose gradients after incubation with the endonuclease. The endonuclease treatment had no effect on the sedimentation profiles of either [32P]DNA or [3H]DNA from unirradiated control cultures. The endonuclease treatment also did not significantly alter the profile of [32P]DNA from irradiated cultures but did introduce breaks in the 3H pulse-labeled DNA synthesized after irradiation. These results indicate that DNA synthesis after ultraviolet irradiation proceeds in such fashion that gaps are formed along the newly made strand, leaving regions of single strandness in template DNA. As replication proceeds these gaps disappear and 2 h after irradiation (100-250 ergs/mm2) they are barely detectable by the endonuclease assay.     

Repair of daughter strand gaps in nascent DNA from mouse epidermal cells treated with dihydrodiol epoxide derivatives of benzo[a]pyrene

Alkaline sucrose gradient analysis of [methyl-3H]thymidine-pulse-labeled DNA was used to study the effect of (+/-)-7 beta,8 alpha-dihydroxy-9 alpha,10 alpha-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (benzo[a]pyrene-diol epoxide I), a potent mutagen and carcinogen, and (+/-)-7 beta,8 alpha-dihydroxy-9 beta,10 beta-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (benzo[a]pyrene-diol epoxide II), a weaker mutagen and carcinogen, on the size of newly synthesized DNA in primary cultures of mouse epidermal cells. Both isomers caused a dose-dependent decrease in the size of newly synthesized DNA and in the rate of [methyl-3H]thymidine incorporation into DNA. When the pulse time was increased in the treated cells so that the amount of [methyl-3H]thymidine incorporation was equal to the control, newly synthesized DNA from exposed cells was still considerably smaller than DNA from control cells. The low molecular weight of the nascent DNA from treated cells was consistent with, but not indicative of, the presence of gaps in the nascent DNA from the treated cells. Evidence of gapped DNA synthesis was obtained by treatment of extracted DNA with a single-strand specific endonuclease from Neurospora crassa. The endonuclease treatment did not significantly alter the profile of [methyl-3H]thymidine prelabeled DNA from benzo[a]pyrene-diol epoxide-treated cultures but did introduce double-stand breaks in pulse-labeled DNA from treated cultures. The numbers of [14C]benzo[a]pyrene-diol epoxide I or [3H]benzo[a]pyrenediol epoxide II-DNA-bound adducts and daughter strand gaps were compared at several dose levels. Treatment with either isomer yielded one gap in the nascent DNA/DNA-bound adduct. Pulse-chase experiments showed that gaps in the nascent DNA were closed with time.     

Uncoordinate synthesis of histone H1 in cells arrested in the G1 phase

It has been known for several years that DNA replication and histone synthesis occur concomitantly in cultured mammalian cells. Normally all five classes of histones are synthesized coordinately. However, mouse myeloma cells, synchronized by starvation for isoleucine, synthesize increased amounts of histone H1 relative to the four nucleosomal core histones. This unscheduled synthesis of histone H1 is reduced within 1 h after refeeding isoleucine, and is not a normal component of G1. The synthesis of H1 increases coordinately again with other histones during the S phase. The DNA synthesis inhibitors, cytosine arabinoside and hydroxyurea, block all histone synthesis in S-phase cells. The levels of histone H1 mRNA, relative to the other histone mRNAs, is increased in isoeleucine-starved cells and decreases rapidly after refeeding isoleucine. The increased incorporation of histone H1 is at least partially due to the low isoleucine content of histone H1. Starvation of cells for lysine resulted in a decrease in H1 synthesis relative to core histones. Again the ratio was altered on refeeding the amino acid. 3T3 cells starved for serum also incorporated only H1 histones into chromatin. The ratio of different H1 proteins also changed. The synthesis of the H1⁰ protein was predominant in G₀ cells, and reduced in S-phase cells. These data indicate the metabolism of H1 is independent of the other histones when cell growth is arrested.     

Intracellular forms of simian virus 40 nucleoprotein complexes. III. Study of histone modifications.

The modification patterns of histones present in various forms of intracellular simian virus 40 nucleoprotein complexes were analyzed by acetic acid-urea-polyacrylamide gel electrophoresis. The results showed that different viral nucleoprotein complexes contain different histone patterns. Simian virus 40 chromatin, which contains the activities for the synthesis of viral RNA and DNA, exhibits a histone modification pattern similar to that of the host chromatin. However, virion assembly intermediates and mature virions contain highly modified histones. Pulse-chase experiments with [3H]lysine showed that the newly incorporated histones in the virion assembly intermediates were already highly modified. The majority of in vivo acetylation activity of histones occurred on the 70S simian virus 40 chromatin as analyzed by pulse-labeling with [3H]acetate. These results and our previous analysis of the virion assembly pathway suggest that three stages are involved in the packaging of simian virus 40 chromatin into the mature virion: (i) modification of histones, (ii) accumulation of capsid protein around the chromatin with highly modified histones, and (iii) organization of capsid proteins into salt-resistant shells. The role of histone modification in virion assembly is discussed.