Nascent DNA in nucleosome like structures from chromatin

We have used chromatin sensitivity to cleavage by micrococcal nuclease as a probe for differences between chromatin containing nascent DNA and that containing bulk DNA. Micrococcal nuclease digested the nascent DNA in chromatin of swimming blastulae of sea urchins more rapidly to acid-soluble nucleotides than the DNA of bulk chromatin. A part of the nascent DNA occurred in micrococcal nuclease-resistant structures which were either different from, or temporary modifications of, the bulk nucleosomes. This was inferred from the size differences between bulk and nascent DNA fragments in 10% polyacrylamide gels after micrococcal nuclease digestion of nuclei from a mixture of ¹⁴C-thymidine long- and ³H-thymidine pulse-labeled embryos. Bulk monomer and dimer DNA fragments contained about 170 and 410 base pairs (bp), respectively, when 18% of the bulk DNA had been rendered acid-soluble. At this level of digestion, “nascent monomer DNA” fragments of about 150 bp as well as 305 bp “large nascent DNA fragments” were observed. Increasing levels of digestion indicated that the large nascent DNA fragment was derived from a chromatin structure which was more resistant to micrococcal nuclease cleavage than bulk dimer chromatin subunits. Peaks of ³H-thymidine-labeled DNA fragments from embryos which had been pulse-labeled and then chased or labeled for several minutes overlapped those of ¹⁴C-thymidine long-labeled monomer, dimer and trimer fragments. This indicated that the chromatin organization at or near the replication fork which had temporarily changed during replication had returned to the organization of its nonreplicating state.     

Maturation of newly replicated chromatin of simian virus 40 and its host cell

The DNA in replicating simian virus 40 chromatin and cellular chromatin was labeled with short pulses of [³H]thymidine. The structure of pulse-labeled nucleoprotein complexes was studied by micrococcal nuclease digestion. It was found that in both newly replicated viral and cellular chromatin, a structural state appears which is characterized by an increased sensitivity to nuclease and a faster than usual rate of cleavage to DNA fragments of monomeric nucleosome size and smaller. Pulse-chase experiments show that each of these effects requires a characteristic time to disappear in both systems, suggesting the existence of different sub-processes of chromatin maturation. One of these processes, detectable by the reversion of the unusually fast production of subnucleosomal fragments, is delayed in SV40 chromatin replication.     

Reduced repeat length of nascent nucleosomal DNA is generated by replicating chromatin in vivo

Micrococcal nuclease digestion of nuclei from sea urchin embryos revealed transient changes in chromatin structure which resulted in a reduction in the repeat length of nascent chromatin DNA as compared with bulk DNA. This was considered to be entirely the consequence of in vivo events at the replication fork (Cell 14, 259, 1978). However, a micrococcal nuclease-generated sliding of nucleosome cores relative to nascent DNA, which might account for the smaller DNA fragments, was not excluded. In vivo [3H]thymidine pulse-labeled nuclei were fixed with a formaldehyde prior to micrococcal nuclease digestion. This linked chromatin proteins to DNA and thus prevented any in vitro sliding of histone cores. All the nascent DNAs exhibiting shorter repeat lengths after micrococcal nuclease digestion, were resolved at identical mobilities in polyacrylamide gels of DNA from fixed and unfixed nuclei. We conclude that these differences in repeat lengths between nascent and bulk DNA was generated in vivo by changes in chromatin structure during replication, rather than by micrococcal nuclease-induced sliding of histone cores in vitro.     

Replication of the simian virus 40 chromosome with purified proteins.

SV40 chromosomes prepared from infected CV-1 cells were replicated with the purified proteins of SV40 T antigen, HeLa DNA polymerase alpha-primase complex, single-stranded DNA-binding protein, and topoisomerases I and II, all of which have been shown to be essential for SV40 DNA replication in vitro. Replication started near the origin and proceeded bidirectionally. The maximum speed of replication fork movement was 200-300 nucleotides/min, which was similar to the rate of SV40 DNA replication with the same set of proteins. When replication products were digested with micrococcal nuclease, DNA fragments of 160-180 base pairs, which is the typical size of mononucleosomal DNA, were protected. This result indicates that replicated DNA was reconstructed into the nucleosome structure, complexed with parental histones.     

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.     

Segregation of nucleosomes in replicated mouse alpha-globin gene

DNA of mouse erythroleukemia cells grown in vitro was labeled with bromodeoxyuridine during cycloheximide-inhibited protein synthesis. Isolated nuclei were digested with micrococcal nuclease to obtain monosomes and monosomal dsDNA. The protection of the heavy and of the light strands of the newly replicated DNA was studied by dot hybridization with the coding and with its complementary noncoding strand of the alpha-globin gene. The results show that both sides of the replication fork contain protected sequences of the gene, thus supporting a bilateral (dispersive) mode of nucleosome segregation during DNA replication.     

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.     

Chromatin maturation depends on continued DNA-replication

The structure of [3H]thymidine pulse-labeled chromatin in lymphocytes differs from that of non-replicating chromatin by several operational criteria which are related to the higher nuclease sensitivity of replicating chromatin. These structural features of replicating chromatin rapidly disappear when the [3H]thymidine pulse is followed by a chase in the presence of an excess of non-radioactive thymidine. However, when the rate of DNA replication is reduced, as in cycloheximide-treated lymphocytes, chromatin maturation is retarded. No chromatin maturation is observed when nuclei from pulse-labeled lymphocytes are incubated in vitro in the absence of DNA precursors. In contrast, when these nuclei are incubated under conditions known to be optimal for DNA replication, the structure of replicating chromatin is efficiently converted to that of 'mature', non-replicating chromatin. We conclude that the properties of nascent DNA and/or the distance from the replication fork are important factors in chromatin maturation.     

Nonuniform distribution of DNA repair in chromatin after treatment with methyl methanesulfonate.

The distribution of methyl methanesulfonate induced DNA repair was measured in mouse mammary cell chromatin by digestion of "repair labeled" nuclei with micrococcal nuclease. The results indicate that there is a nonuniform distribution of DNA repair in chromatin. The chromatin fraction digested during the first 5 minutes of incubation with micrococcal nuclease appears to be a primary site of DNA repair after methyl methanesulfoante treatment. The observed nonuniform distribution of DNA repair in chromatin may be due to 1)a nonrandom alkylation of DNA in chromatin by methyl methanesulfonate or 2)areas in chromatin of increased accessibility for the repair enzymes to the DNA lesions.     

Sequence specific cleavage of African green monkey alpha-satellite DNA by micrococcal nuclease

The sequence specificity of micrococcal nuclease complicates its use in experiments addressed to the still controversial issue of nucleosome phasing. In the case of alpha-satellite DNA containing chromatin from African green monkey (AGM) cells cleavage by micrococcal nuclease in the nucleus was reported to occur predominantly at only one location around position 126 of the satellite repeat unit (Musich et al. (1982) Proc. Natl. Acad. Sci. USA 79, 118-122). DNA control experiments conducted in the same study indicated the presence of many preferential cleavage sites for micrococcal nuclease on the 172 bp long alpha-satellite repeat unit. This difference was taken as evidence for a direct and simple phase relationship between the alpha-satellite DNA sequence and the position of the nucleosomes on the DNA. We have quantitatively analyzed the digestion products of the protein-free satellite monomer with micrococcal nuclease and found that 50% of all cuts occur at positions 123 and 132, 5% at position 79, and to a level of 1-3% at about 20 other positions. We also digested high molecular weight alpha-satellite DNA from AGM nuclei with micrococcal nuclease. Again cleavage occurred mostly at positions 123 and 132 of the satellite repeat unit. Thus digestion of free DNA yields results very similar to those reported by Musich et al. for the digestion of chromatin. Therefore no conclusions on a possible phase relationship can be drawn from the chromatin digestion experiments.     

Enrichment of transcribed and newly replicated DNA in soluble chromatin released from nuclei by mild micrococcal nuclease digestion

A chromatin fraction solubilized from mouse myeloma nuclei under near-physiological ionic conditions by very mild micrococcal nuclease digestion at 0°C is enriched at least 7-fold in DNA complementary to total myeloma polyadenylated mRNA, and 15-fold in DNA originating near the replication fork (labeled within 30 s). Newly replicated DNA recovered in solubilized chromatin after brief labeling was incorporated mainly into particles sedimenting with, or faster than, mononucleosomes. A rapid decrease in enrichment of newly replicated DNA in readily released, soluble chromatin with increasing labeling times indicated that newly replicated chromatin matured within 90 s to a form that was partitioned similarly to bulk chromatin by this fractionation method. Previous studies showed that chromatin readily solubilized from myeloma nuclei is enriched in high-mobility-group (HMG) and other non-histone proteins, RNA and single-stranded DNA; and depleted in H1 and 5-methylcytosine, relative to bulk chromatin (Jackson, J.B., Pollock, J.M., Jr., and Rill, R.L. (1979) Biochemistry 18, 3739–3748). Mild digestion of chicken erythrocyte nuclei with micrococcal nuclease yielded a soluble chromatin fraction (1–2% of the total DNA) with similar properties. This fraction was enriched at least 6-fold in DNA complementary to chicken globin mRNA, relative to total erythrocyte DNA.     

Structure of eukaryotic chromatin. Evaluation of periodicity using endogenous and exogenous nucleases.

DNA isolated from (a) liver chromatin digested in situ with endogenous Ca2+, Mg2+-dependent endonuclease, (b) prostate chromatin digested in situ with micrococcal nuclease or pancreatic DNAase I, and (c) isolated liver chromatin digested with micrococcal nuclease or pancreatic DNAase I has been analyzed electrophoretically on polyacrylamide gels. The electrophoretic patterns of DNA prepared from chromatin digested in situ with either endogenous endonuclease (liver nuclei) or micrococcal nuclease (prostate nuclei) are virtually identical. Each pattern consists of a series of discrete bands representing multiples of the smallest fragment of DNA 200 +/- 20 base pairs in length. The smallest DNA fragment (monomer) accumulates during prolonged digestion of chromatin in situ until it accounts for nearly all of the DNA on the gel; approx. 20% of the DNA of chromatin is rendered acid soluble during this period. Digestion of liver chromatin in situ in the presence of micrococcal nuclease results initially in the reduction of the size of the monomer from 200 to 170 base pairs of DNA and subsequently results in its conversion to as many as eight smaller fragments. The electrophoretic pattern obtained with DNA prepared from micrococcal nuclease digests of isolated liver chromatin is similar, but not identical, to that obtained with liver chromatin in situ. These preparations are more heterogeneous and contain DNA fragments smaller than 200 base pairs in length. These results suggest that not all of the chromatin isolated from liver nuclei retains its native structure. In contrast to endogenous endonuclease and micrococcal nuclease digests of chromatin, pancreatic DNAase I digests of isolated chromatin and of chromatin in situ consist of an extremely heterogeneous population of DNA fragments which migrates as a continuum on gels. A similar electrophoretic pattern is obtained with purified DNA digested by micrococcal nuclease. The presence of spermine (0.15 mM) and spermidine (0.5 mM) in preparative and incubation buffers decreases the rate of digestion of chromatin by endogenous endonuclease in situ approx. 10-fold, without affecting the size of the resulting DNA fragments. The rates of production of the smallest DNA fragments, monomer, dimer, and trimer, are nearly identical when high molecular weight DNA is present in excess, indicating that all of the chromatin multimers are equally susceptible to endogenous endonuclease. These observations points out the effects of various experimental conditions on the digestion of chromatin by nucleases.     

Assembly kinetics of replicating chromatin: Isolation and characterization of prenucleosomal and nucleosomal DNA

Replicating chromatin is known to be more sensitive to micrococcal nuclease than bulk chromatin. We have used this property and a fractionation procedure based on the specific release of replicating material under mild micrococcal nuclease digestion, in order to analyse both the kinetics of maturation of newly replicated DNA into nucleosomes and the structure of the replicating material. As other authors, we initially observed that repetitive unit of newly replicated chromatin was shorter than that of bulk chromatin, however this result appears to be due to sliding of nucleosomes along the chromatin fibers close to the replicating fork. Replicative chromatin was fractionated and analysed. A prenucleosomal peak was observed and preliminary characterized.     

Binding of androgen receptor to prostatic chromatin requires intact linker DNA.

Receptor-chromatin complexes were recovered from prostatic chromatin digested with micrococcal nuclease. The fragments of chromatin were separated on linear 7.6 to 76% (v/v) glycerol density gradients. With extensive digestion of DNA, receptor labeled with [1,2-3H]dihydrotestosterone was released from the chromatin. After 5% digestion of DNA to acid-soluble products, only a trace amount of labeled receptor was detected in the unbound form. In the latter instance, most of the labeled receptor was recovered from the gradients in association with five A260 peaks representing oligomeric and monomeric nucleosomes with a repeat length of 182 +/- 14 (mean +/- S.D.) base pairs. The concentration of receptors was highest in the A260 peaks, which contained large oligomers of nucleosomes, and lowest in fractions containing primarily monomer structures. Hence, the extent to which receptors remained bound to chromatin was dependent on the relative amount of intact, linker DNA present.     

Nucleosome positioning as a critical determinant for the DNA cleavage sites of mammalian DNA topoisomerase II in reconstituted simian virus 40 chromatin.

We have assessed the ability of nucleosomes to influence the formation of mammalian topoisomerase II-DNA complexes by mapping the sites of cleavage induced by four unrelated topoisomerase II inhibitors in naked versus nucleosome-reconstituted SV40 DNA. DNA fragments were reconstituted with histone octamers from HeLa cells by the histone exchange method. Nucleosome positions were determined by comparing micrococcal nuclease cleavage patterns of nucleosome-reconstituted and naked DNA. Three types of DNA regions were defined: 1) regions with fixed nucleosome positioning; 2) regions lacking regular nucleosome phasing; and 3) a region around the replication origin (from position 5100 to 600) with no detectable nucleosomes. Topoisomerase II cleavage sites were suppressed in nucleosomes and persisted or were enhanced in linker DNA and in the nucleosome-free region around the replication origin. Incubation of reconstituted chromatin with topoisomerase II protected nucleosome-free regions from micrococcal nuclease cleavage without changing the overall micrococcal nuclease cleavage pattern. Thus, the present results indicate that topoisomerase II binds preferentially to nucleosome-free DNA and that the presence of nucleosomes at preferred DNA sequences influences drug-induced DNA breaks by topoisomerase II inhibitors.     

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.     

Nuclease-sensitivity of methylated DNA as a probe for chromatin reconstitution by genotoxicants

DNA in Chinese hamster ovary cells was labeled with [¹⁴C]thymidine and [methyl- ³H]-1-methionine in culture, and their nuclei were digested with micrococcal nuclease. Not until 10 percent of bulk DNA was digested did methylated DNA appear in the acid-soluble fraction. When these cells were exposed to UV-radiation, alkylating agents and intercalating agents in culture, the resistance of methylated DNA to digestion by the nuclease was largely or completely eliminated. The change in the sensitivity of methylated DNA to the nuclease indicates a conformational change in chromatin induced by the genotoxicants.     

Changes in chromatin structure at the replication fork. II The DNPs containing nascent DNA and a transient chromatin modification detected by DNAase I.

Discrete deoxyribonucleoproteins (DNPs) containing nascent and/or bulk DNA, were obtained by fractionating micrococcal nuclease digests of nuclei form 3H-thymidine pulse (15-20 sec) and 14C-thymidine long (16 h) labeled sea urchin embryos in polyacrylamide gels. One of these DNPs was shown to contain the micrococcal nuclease resistant 300 bp "large nascent DNA" described in Cell 14, 259-267, 1978. The bulk and nascent mononucleosome fractions provided evidence for the preferential digestion by micrococcal nuclease of nascent over bulk linker regions to yield mononucleosome cores with nascent DNA. DNAase I was used to probe whether any nascent DNA is in nucleosomes. Nascent as well as bulk single-stranded DNA fragments occurred in multiples of 10.4 bases with higher than random frequencies of certain fragment sizes (for instance 83 bases) as expected from a nucleosome structure. However, a striking background of nascent DNA between nascent DNA peaks was observed. This was eliminated by a pulse-chase treatment or by digestion of pulse-labeled nuclei with micrococcal nuclease together with DNAase I. One of several possible interpretations of these results suggests that a transient change in nucleosome structure may have created additional sites for the nicking of nascent DNA by DNAase I; the micrococcal nuclease sensitivity of the interpeak radioactivity suggest its origin from the linker region. Endogenous nuclease of sea urchin embryos cleaves chromatin DNA in a manner similar to that of DNAase I.