Influence of histone acetylation on the solubility, H1 content and DNase I sensitivity of newly assembled chromatin.

In a previous report [Annunziato, A.T. and Seale, R.L. (1983) J. Biol. Chem. 258:12675] a novel intermediate in chromatin assembly was described (detected by labeling new DNA in the presence of the deacetylase inhibitor sodium butyrate), which retained approximately 50% of the heightened sensitivity of newly replicated chromatin to DNaseI. It is now reported that nucleosomes replicated in butyrate are considerably more soluble in the presence of magnesium, relative to chromatin replicated under control conditions, and that this heightened magnesium-solubility is reflected in a concomitant increase in the preferential solubility of nucleosomes containing newly synthesized core histones. This differential solubility was accompanied by a 5- to 6-fold depletion of histone H1, and was completely abolished by the selective removal of H1 from isolated nuclei. The removal of H1 also markedly reduced the preferential DNaseI sensitivity of chromatin replicated in butyrate. Further, when mononucleosomes of control and (acetylated) nascent chromatin were compared, no differences in DNaseI sensitivity were detected. These results provide evidence that the interactions between newly assembled nucleosomes and histone H1 are altered when histone deacetylation is inhibited during chromatin replication, and suggest a mechanism for the control of H1 deposition during nucleosome assembly in vivo.     

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.     

Fate of newly synthesized histones shortly after interruption of DNA replication

The synthesis and association of histones with chromatin were studied using MH-134SC cells in suspension culture. Cultures containing approximately equal numbers of cells were pulse-labeled with [3H]lysine at various times after the interruption of DNA synthesis with hydroxyurea. Each culture was mixed with a fixed volume of a culture generally labeled with [14C]lysine at the time of harvesting. Acid-soluble proteins extracted from different subcellular fractions of cells labeled under various conditions were compared by electrophoresis on polyacrylamide gels containing acetic acid and urea. All types of chromatin histones were labeled nearly equally as [14C]marker histones by a 15 min pulse under normal conditions, except that a considerable portion of pulse-labeled H4 was in highly acetylated forms. Addition of hydroxyurea at the start of the pulse markedly reduced the labeling of H3 and H4, but affected the labeling of the other histones only slightly. When DNA synthesis was inhibited before the start of the pulse, labeling of all histones decreased significantly. The addition of hydroxyurea was found to cause transient accumulation of newly synthesized proteins in the cytoplasmic soluble fraction; these were characterized as H3 and H4 from their metabolic properties and their electrophoretic mobilities on sodium dodecyl sulfate-polyacrylamide gels. The results suggest that association of newly synthesized H3 and H4 histones is closely coupled with ongoing DNA replication. The implications of the results for the mechanism of formation of new nucleosomes are discussed.     

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.     

Acetylation of histone H3 lysine 56 regulates replication-coupled nucleosome assembly

Chromatin assembly factor 1 (CAF-1) and Rtt106 participate in the deposition of newly synthesized histones onto replicating DNA to form nucleosomes. This process is critical for the maintenance of genome stability and inheritance of functionally specialized chromatin structures in proliferating cells. However, the molecular functions of the acetylation of newly synthesized histones in this DNA replication-coupled nucleosome assembly pathway remain enigmatic. Here we show that histone H3 acetylated at lysine 56 (H3K56Ac) is incorporated onto replicating DNA and, by increasing the binding affinity of CAF-1 and Rtt106 for histone H3, H3K56Ac enhances the ability of these histone chaperones to assemble DNA into nucleosomes. Genetic analysis indicates that H3K56Ac acts in a nonredundant manner with the acetylation of the N-terminal residues of H3 and H4 in nucleosome assembly. These results reveal a mechanism by which H3K56Ac regulates replication-coupled nucleosome assembly mediated by CAF-1 and Rtt106.     

Kinetics of accumulation and depletion of soluble newly synthesized histone in the reciprocal regulation of histone and DNA synthesis

Procedures are presented which permit the identification and analysis of cellular histone that is not bound to chromatin. This histone, called soluble histone, could be distinguished from that bound to chromatin by the state of H4 modification and the lack of H2A ubiquitination. Changes in the levels of newly synthesized soluble histone were analyzed with respect to the balance between histone and DNA synthesis in hamster ovary cells. Pulse-chase protocols suggested that the chase of newly synthesized histone from the soluble fraction into chromatin may have two kinetic components with half-depletion times of about 1 and 40 min. When protein synthesis was inhibited, the pulse-chase kinetics of newly synthesized histone from the solubl fraction into chromatin were not significantly altered from those of the control. However, in contrast to the control, when protein synthesis was inhibited, DNA synthesis was also inhibited with kinetics similar to those of the chase of newly synthesized histone from the soluble fraction. There was a rapid decrease in the rate of DNA synthesis with a half-deceleration time of 1 min down to about 30% of the control rate, followed by a slower decrease with an approximate half-deceleration time of 40 min. When DNA synthesis was inhibited, newly synthesized histone accumulated in the soluble fraction, but H2A and H2B continued to complex with chromatin at a significant rate. Soluble histone in G1 cells showed the same differential partitioning of H4/H3 and H2A/H2B between the soluble and chromatin-bound fractions as was found in cycling cells with inhibited DNA synthesis. These results support a unified model of reciprocal regulatory mechanisms between histone and DNA synthesis in the assembly of chromatin.     

Chromatin assembly in isolated mammalian nuclei.

Cellular DNA replication was stimulated in confluent monolayers of CV-1 monkey kidney cells following infection with SV40. Nuclei were isolated from CV-1 cells labeled with [3H]thymidine and then incubated in the presence of [alpha-32P]deoxyribonucleoside triphosphates under conditions that support DNA replication. To determine whether or not the cellular DNA synthesized in vitro was assembled into nucleosomes the DNA was digested in situ with either micrococcal nuclease or pancreatic DNase I, and the products were examined by electrophoretic and sedimentation analysis. The distribution of DNA fragment lengths on agarose gels following micrococcal nuclease digestion was more heterogeneous for newly replicated than for the bulk of the DNA. Nonetheless, the state of cellular DNA synthesized in vitro (32P-labeled) was found to be identical with that of the DNA in the bulk of the chromatin (3H-labeled) by the following criteria: (i) The extent of protection against digestion by micrococcal nuclease of DNase I. (ii) The size of the nucleosomes (180 base pairs) and core particles (145 base pairs). (iii) The number and sizes of DNA fragments produced by micrococcal nuclease in a limit digest. (iv) The sedimentation behavior on neutral sucrose gradients of nucleoprotein particles released by micrococcal nuclease. (v) The number and sizes of DNA fragments produced by DNase I digestion. These results demonstrate that cellular DNA replicated in isolated nuclei is organized into typical nucleosomes. Consequently, subcellular systems can be used to study the relationship between DNA replication and the assembly of chromatin under physiological conditions.     

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.     

Stepwise assembly of chromatin during DNA replication in vitro.

A cell free system that supports replication-dependent chromatin assembly has been used to determine the mechanism of histone deposition during DNA replication. CAF-I, a human cell nuclear factor, promotes chromatin assembly on replicating SV40 DNA in the presence of a crude cytosol replication extract. Biochemical fractionation of the cytosol extract has allowed separation of the chromatin assembly reaction into two steps. During the first step, CAF-I targets the deposition of newly synthesized histones H3 and H4 to the replicating DNA. This reaction is dependent upon and coupled with DNA replication, and utilizes the newly synthesized forms of histones H3 and H4, which unlike bulk histone found in chromatin, do not bind to DNA by themselves. The H3/H4-replicated DNA complex is a stable intermediate which exhibits a micrococcal nuclease resistant structure and can be isolated by sucrose gradient sedimentation. In the second step, this replicated precursor is converted to mature chromatin by the addition of histones H2A and H2B in a reaction that can occur after DNA replication. The requirement for CAF-I in at least the first step of the reaction suggests a level of cellular control for this fundamental process.     

Disruption of the nucleosomes at the replication fork.

The fate of parental nucleosomes during chromatin replication was studied in vitro using in vitro assembled chromatin containing the whole SV40 genome as well as salt-treated and native SV40 minichromosomes. In vitro assembled minichromosomes were able to replicate efficiently in vitro, when the DNA was preincubated with T-antigen, a cytosolic S100 extract and three deoxynucleoside triphosphates prior to chromatin assembly, indicating that the origin has to be free of nucleosomes for replication initiation. The chromatin structure of the newly synthesized daughter strands in replicating molecules was analysed by psoralen cross-linking of the DNA and by micrococcal nuclease digestion. A 5- and 10-fold excess of protein-free competitor DNA present during minichromosome replication traps the segregating histones. In opposition to published data this suggests that the parental histones remain only loosely or not attached to the DNA in the region of the replication fork. Replication in the putative absence of free histones shows that a subnucleosomal particle is randomly assembled on the daughter strands. The data are compatible with the formation of a H3/H4 tetramer complex under these conditions, supporting the notion that under physiological conditions nucleosome core assembly on the newly synthesized daughter strands occurs by the binding of H2A/H2B dimers to a H3/H4 tetramer complex.     

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.     

Monensin stimulates glycerolipid incorporation into rod outer segment membranes

Monensin is an ionophore which disrupts the structure of the Golgi apparatus and inhibits vesicular transport in eukaryotic cells. In this study, we examined the effects of monensin on the incorporation of newly synthesized glycerolipids into retinal rod outer segment (ROS) membranes. Frog retinas were incubated in the presence or absence of monensin (50 nM) with either [1,2,3-3H]glycerol or [9,10-3H]palmitic acid as radiolabeled substrate. Total lipids were extracted from retinas and ROS membranes and resolved into individual phospholipid classes and neutral lipids by thin-layer chromatography. In the presence of monensin, the specific activity of ROS phospholipids was increased about 2-fold with [3H]glycerol and nearly 3-fold with [3H]palmitate as substrates relative to controls. In contrast, the specific activity of total retinal lipids, the relative incorporation of label into ROS and retinal phospholipids, and the total lipid phosphorous content of ROS membranes and retinas were not significantly different from control values. These data suggest that the enhanced labeling of ROS phospholipids in the presence of monensin was due to altered intracellular routing of lipids rather than increased glycerolipid synthesis. Under the same conditions, total retinal protein synthesis was about 90% of control, but light microscopic autoradiography indicated that newly synthesized proteins were not transported to the ROS for assembly into disc membranes. Thus, newly synthesized glycerolipids can be delivered to the ROS by a mechanism which is independent of protein transport to that cellular compartment.     

Metabolically stable non-histone chromosomal proteins in growing maize roots

DNA and non-histone chromosomal proteins (NHCP) of meristematic cells of maize primary roots were double labelled in vivo with [³H]- or [¹⁴C] thymidine and [¹⁴C]- or [³H]-tryptophan respectively. The ratio of labelled tryptophan to labelled DNA was followed during the transition of the meristematic cells of the root tip into the distal zones of finally differentiated cells. It was found that only 20% of the newly synthesized NHCP in the proliferating cells were turned over, while the rest were preserved and found as metabolically stable proteins in the zone of final differentiation. This result is consistent with the hypothesis that some NHCP remain permanently associated with chromatin of non-dividing differentiated cells in order to maintain the genomic characteristics of a given cellular type.     

Metabolism of dITP in HeLa cell extracts, incorporation into DNA by isolated nuclei and release of hypoxanthine from DNA by a hypoxanthine-DNA glycosylase activity.

dITP may be generated from dATP by a slow, nonenzymatic hydrolysis. While [3H]dITP was degraded rapidly to [3H]deoxyinosine by HeLa cell nuclear extracts, no net degradation of [3H]dITP was observed in the presence of physiological concentrations of ATP, apparently because the extract contained deoxynucleoside diphosphate kinase activity that regenerated [3H]dITP from [3H]dIDP. Isolated HeLa cell nuclei, as well as partially purified DNA polymerase alpha, incorporated [3H]dITP into DNA at 50-60% of the rate of [3H]dGTP incorporation. No rapid release of the incorporated radioactivity was observed. The molecular weight of nascent DNA containing dIMP residues, however, decreased slightly after prolonged incubation in the presence of EDTA, suggesting that a repair process is initiated in dIMP-containing chromatin. Furthermore, release of free [3H]hypoxanthine from [3H]dIMP-containing DNA was detected after incubation with nuclear extracts in the presence of EDTA, suggesting the presence of hypoxanthine-DNA glycosylase activity in HeLa cell nuclei.     

Histone deacetylation is required for the maturation of newly replicated chromatin

The effects of inhibiting histone deacetylation on the maturation of newly replicated chromatin have been examined. HeLa cells were labeled with [3H]thymidine in the presence or absence of sodium butyrate; control experiments demonstrated that butyrate did not significantly inhibit DNA replication for at least 70 min. Like normal nascent chromatin, chromatin labeled for brief periods (0.5-1 min) in the presence of butyrate was more sensitive to digestion with DNase I and micrococcal nuclease than control bulk chromatin. However, chromatin replicated in butyrate did not mature as in normal replication, but instead retained approximately 50% of its heightened sensitivity to DNase I. Incubation of mature chromatin in butyrate for 1 h did not induce DNase I sensitivity: therefore, the presence of sodium butyrate was required during replication to preserve the increased digestibility of nascent chromatin DNA. In contrast, sodium butyrate did not inhibit or retard the maturation of newly replicated chromatin when assayed by micrococcal nuclease digestion, as determined by the following criteria: 1) digestion to acid solubility, 2) rate of conversion to mononucleosomes, 3) repeat length, and 4) presence of non-nucleosomal DNA. Consistent with the properties of chromatin replicated in butyrate, micrococcal nuclease also did not preferentially attack the internucleosomal linkers of chromatin regions acetylated in vivo. The observation of a novel chromatin replication intermediate, which is highly sensitive to DNase I but possesses normal resistance to micrococcal nuclease, suggests that nucleosome assembly and histone deacetylation are not obligatorily coordinated. Thus, while deacetylation is required for chromatin maturation, histone acetylation apparently affects chromatin organization at a level distinct from that of core particle or linker, possibly by altering higher order structure.     

The mechanism of inhibition of DNA replication in HeLa S3 cells by the antitumor drug Ledakrin and other antitumor 1-nitro-9-aminoacridines

These studies were aimed at characterizing the capability of an antitumor DNA-damaging drug, Ledakrin, and its analogs to inhibit DNA replication in HeLa S3 cells. The studied agents are extremely potent inhibitors of [³H]thymidine incorporation in whole cells. These compounds produced also a potent dose- and time-dependent inhibition of DNA synthesis in subcellular systems derived from drug-treated cells, as found by [³H]dGTP incorporation in cellular lysates and nuclei. Experiments in which nuclei from control and drug-treated cells were supplemented with cytoplasmic fractions from either control or drug-treated cells, or with exogenous DNA, demonstrate that Ledakrin and other 1-nitro-9-aminoacridines inhibit DNA replication in HeLa S3 cells by interfering with the DNA template, while not affecting DNA polymerase(s) or other enzymes and replication factors. The negligible effect of Ledakrin added to lysates or nuclei from untreated cells suggests that metabolic activation is a prerequisite for replication inhibition by Ledakrin. Analysis of the size of newly synthesized DNA, by alkaline sucrose gradient sedimentation, indicates that Ledakrin does not inhibit the initiation of replication but does interfere with chain growth. Impairment of DNA replication by 1-nitro-9-aminoacridines seems to originate from DNA damage and to result in the inhibition of cellular growth.     

Chromatin assembly during DNA replication in somatic cells.

Newly replicated DNA is assembled into chromatin through two principle pathways. Firstly, parental nucleosomes segregate to replicated DNA, and are transferred directly to one of the two daughter strands during replication fork passage. Secondly, chromatin assembly factors mediate de-novo assembly of nucleosomes on replicating DNA using newly synthesized and acetylated histone proteins. In somatic cells, chromatin assembly factor 1 (CAF-1) appears to be a key player in assembling new nucleosomes during DNA replication. It provides a molecular connection between newly synthesized histones and components of the DNA replication machinery during the S phase of the cell division cycle.