Kinetics of nuclease digestion of Physarum polycephalum nuclei at different stages of the cell cycle

The kinetics of nuclease digestion of Physarum polycephalum nuclei by staphylococcal nuclease and DNase I has been studied at different stages of the cell cycle. Significant differences in the digestion behaviour of nuclei from metaphase and interphase have been detected with DNase I but not with staphylococcal nuclease. Furthermore the structure of newly replicated DNA in S phase differs from the bulk in that it is more easily degraded to acid-soluble products by either staphylococcal nuclease or by DNAase I. At least four types of chromatin structure can be distinguished by our digestion kinetics experiments.     

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.     

Diffusible factors are responsible for differences in nuclease sensitivity among chromatins originating from different cell types

We have examined the kinetics of nuclease digestion of chromatin from committed and uncommitted cells in experiments where the nuclei are mixed and co-digested. Cultures of the sea urchin, Arbacia punctulata, were grown to the 16-cell stage in either [3H]thymidine or [14C]thymidine and the macromere, mesomere, and micromere cell types separated. After isolation, sets of nuclei with two different blastomere types (each having different radionucleotide tagging) were mixed and co-digested with micrococcal nuclease or DNase. I. The extent of digestion was monitored by solubility in 5% perchloric acid (PCA). We find no significant differences in initial digestion rates or limit digests among the different cell types when co-digested with either nuclease. Differences in nuclease sensitivity observed when nuclei are digested separately are abolished when nuclei are probed in a mixing experiment. The results support the hypothesis that phenotypic differences in digestibility among different cell types in vitro reflect differences in chromatin-condensing factors which can diffuse between nuclei.     

DNAase I and cellular factors that affect chromatin structure

The use of DNAase I as a probe of chromatin structure is frequently fraught with problems of irreproducibility. We have recently evaluated this procedure, documented the sources of the problems, and standardized the method for reproducible results (Prentice and Gurley (1983) Biochim. Biophys. Acta 740, 134-144). We have now used this probe to detect differences in chromatin structure between cells blocked (1) in G1 phase by isoleucine deprivation, or (2) in early S phase by sequential use of isoleucine deprivation followed by release into the presence of hydroxyurea. The cells blocked in G1 phase have easily-digestible chromatin, while cells blocked in early S phase have chromatin which is much more resistant to DNAase I. These differences were found to be the result of diffusible factors found in the cytoplasm and nuclei of G1- and S-phase cells, respectively. The G1 cells contained a cytoplasmic factor which modulates the chromatin structure of S-phase nuclei to a more easily digestible state, while cells blocked in S phase contain a nuclear factor which modulates the chromatin structure of G1 nuclei to a state more resistant to digestion. DNAase I is much more sensitive to these cell cycle-specific chromatin changes than is micrococcal nuclease. The results indicate that, under controlled conditions, DNAase I should be a valuable probe for detecting chromatin structural changes associated with cell cycle traverse, differentiation, development, hormone action and chemical toxicity.     

DNAase I and cellular factors that affect chromatin structure

The use of DNAase I as a probe of chromatin structure is frequently fraught with problems of irreproducibility. We have recently evaluated this procedure, documented the sources of the problems, and standardized the method for reproducible results (Prentice and Gurley (1983) Biochim. Biophys. Acta 740, 134–144). We have now used this probe to detect differences in chromatin structure between cells blocked (1) in G₁ phase by isoleucine deprivation, or (2) in early S phase by sequential use of isoleucine deprivation followed by release into the presence of hydroxyurea. The cells blocked in G₁ phase have easily-digestible chromatin, while cells blocked in early S phase have chromatin which is much more resistant to DNAase I. These differences were found to be the result of diffusible factors found in the cytoplasm and nuclei of G₁- and S-phase cells, respectively. The G₁ cells contained a cytoplasmic factor which modulates the chromatin structure of S-phase nuclei to a more easily digestible state, while cells blocked in S phase contain a nuclear factor which modulates the chromatin structure of G₁ nuclei to a state more resistant to digestion. DNAase I is much more sensitive to these cell cycle-specific chromatin changes than is micrococcal nuclease. The results indicate that, under controlled conditions, DNAase I should be a valuable probe for detecting chromatin structural changes associated with cell cycle traverse, differentiation, development, hormone action and chemical toxicity.     

Deoxyribonuclease II as a probe for chromatin structure. I. Location of cleavage sites

DNAase II has been shown to cleave condensed mouse liver chromatin at 100-bp² intervals while chromatin in the extended form is cleaved at 200-bp intervals (Altenburger et al., 1976). Evidence is presented here that DNA digestion patterns of a half-nucleosomal periodicity are also obtained upon DNAase II digestion of chicken erythrocyte nuclei and yeast nuclei, both of which differ in their repeat lengths (210 and 165 bp) from mouse liver chromatin. In the digestion of mouse liver nuclei a shift from the 100-bp to the 200-bp cleavage mode takes place when the concentration of monovalent cations present during digestion is decreased below 1 mM. When soluble chromatin prepared by micrococcal nuclease is digested with DNAase II the same type of shift occurs, albeit at higher ionic strength.In order to map the positions of the DNAase II cleavage sites on the DNA relative to the positions of the nucleosome cores, the susceptibility of DNAase II-derived DNA termini to exonuclease III was investigated. In addition, oligonucleosome fractions from HaeIII and micrococcal nuclease digests were end-labelled with polynucleotide kinase and digested with DNAase II under conditions leading to 100 and 200-bp digestion patterns. Analysis of the chain lengths of the resulting radioactively labelled fragments together with the results of the exonuclease assay allow the following conclusions. In the 200-bp digestion mode, DNAase II cleaves exclusively in the internucleosomal linker region. Also in the 100-bp mode cleavage occurs initially in the linker region. Subsequently, DNAase II cleaves at intranucleosomal locations, which are not, however, in the centre of the nucleosome but instead around positions 20 and 125 of the DNA associated with the nucleosome core. At late stages of digestion intranucleosomal cuts predominate and linkers that are still intact are largely resistant to DNAase II due to interactions between adjacent nucleosomes. These findings offer an explanation for the sensitivity of DNAase II to the higher-order structure of chromatin.     

Altered chromatin structure of cerebral nuclei in experimental diabetes mellitus.

To determine whether diabetes alters chromatin structure in vivo, micrococcal nuclease digestion kinetics were analyzed in cerebral cortical and hepatic nuclei of streptozotocin-induced diabetic rats. Cerebral nuclei of diabetic rats maintained for 6 weeks were less susceptible to micrococcal nuclease digestion compared with control rats. Insulin treatment reversed diabetes-related changes in nuclease digestion kinetics. There were no changes in the kinetics of digestion in hepatic nuclei. The reduced digestibility of cerebral DNA in diabetes could not be attributed to altered DNA fluorescence spectra, or altered distribution of most abundant chromatin proteins that were either solubilized or that remained insoluble immediately following nuclease digestion. It is concluded that chronic, uncontrolled hyperglycemia can alter chromatin structure of some tissues in vivo, and this change is probably related to subtle alterations in DNA-protein interactions.     

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.     

Parameters influencing the flow cytometric analysis of DNA sensitivity to nuclease S1

Some parameters that influence the analysis in situ of DNA sensitivity to digestion with nuclease S1 have been studied in isolated HeLa nuclei with flow cytometry. DNA staining with the intercalating fluorochrome propidium iodide allowed the nucleolytic activity on double-stranded (ds) DNA to be determined by monitoring the relative reduction in nuclear fluorescence intensity. Nuclei isolated in buffer at low ionic strength in order to decondense chromatin fibres, showed a lower fluorescence intensity than nuclei with native chromatin, after digestion with nuclease S1 under identical conditions. Nuclei prepared with dispersed chromatin and digested with increasing amounts of enzyme showed a decrease in fluorescence intensity that reached a limit value at about 50% of the value of undigested control samples. On the other hand, in nuclei with native chromatin, fluorescence intensity decreased only about 18%. The NaCl concentration in the reaction buffer strongly influenced the DNA sensitivity to S1 nuclease. By increasing salt molarity from 5 mM to 200 mM, the digestion of dsDNA was significantly reduced as also shown by the amount of released nucleotides from purified calf thymus DNA. The detection of DNA sensitivity to nuclease S1, as assessed by the cytometric method, was shown to be more sensitive than a biochemical technique involving hydrolysis of purines. These results indicate that both the procedure for nuclei isolation and the digestion conditions have to be carefully controlled when evaluating in situ the presence of S1-sensitive sites.     

Variation in chromatin structure in two cell types from the same tissue: a short DNA repeat length in cerebral cortex neurons

We have used micrococcal nuclease as a probe of the repeating structure of chromatin in four nuclear populations from three tissues of the rabbit. Neuronal nuclei isolated from the cerebral cortex contain about 160 base pairs of DNA in the chromatin repeat unit, as compared with about 200 base pairs for nonastrocytic glial cell nuclei from the same tissue, neuronal nuclei from the cerebellum and liver nuclei. All four types of nuclei show the same features of nucleosomal organization as other eucaryotic nuclei so far studied: nucleosomes liberated by digestion with micrococcal nuclease give a “core particle” containing 140 base pairs as a metastable intermediate on further digestion and a series of single-strand DNA fragments which are mutiples of 10 bases after digestion with DNAase I. Nuclei from cerebral cortex neurons, which have a short repeat, are distinct from the others in being larger, in having a higher proportion of euchromatin (dispersed chromatin) as judged by microscopy and in being more active in RNA synthesis in vitro.     

Purification of 14C-labelled deoxyribonuclease II from HeLa S3 lysosomes and its use as a marker for the study of nuclear deoxyribonuclease II

Deoxyribonuclease II (DNAase II) in mammalian cells has generally been considered to be located in the lysosomes. Several recent studies have indicated that some DNAase II activity is present in purified nuclei; this, however, could have been due to some contamination of the nuclear fraction by lysosomes, or alternatively, it could have been caused by specific binding of lysosomal DNAase II to the nuclear fraction during isolation. Our previous studies have eliminated the possibility that lysosomal contamination was the cause of the presence of DNAase II in isolated nuclei. In this study I have purified (14)C-labelled lysosomal DNAase II and added it to cells during isolation of their nuclei. This study demonstrates that there is no specific binding of lysosomal DNAase II to the nuclear fraction and concludes that DNAase II activity observed in isolated nuclei represents an intrinsic activity that might be involved in nuclear DNA metabolism.     

Analysis of chromatin of skeletal muscle of developing rats using micrococcal nuclease and DNase I

Conformational changes in the chromatin of skeletal muscle of 3-, 14-and 30 day-old developing rats have been studied using DNase I and micrococcal nuclease (MCN). Purified nuclei were digested separately by MCN and DNase I. The rate and extent of digestion by MCN decreases gradually as development proceeds. The electrophoretic pattern of MCN digested DNA, however, shows no change. The kinetics of digestion of nuclei by DNase I show no change with development. However, the electrophoretic pattern of DNase I digested DNA shows a gradual decrease in the amount of 10–30 bp fragments with progressive development. These studies show that the chromatin of the skeletal muscle undergoes certain conformational changes during postnatal development, and such changes in chromatin may be necessary for terminal differentiation of this tissue.     

Polyamine depletion is associated with altered chromatin structure in HeLa cells.

HeLa cells depleted of polyamines by treatment with alpha-difluoromethylornithine (DFMO), methylglyoxal bis(guanylhydrazone) (MGBG) or a combination of the two, were examined for sensitivity to micrococcal nuclease, DNAase I and DNAase II. The degrees of chromatin accessibility to DNAase I and II appeared enhanced somewhat in all three treatment groups, and the released digestion products differed from those in non-depleted cells. DNA released from MGBG- and DFMO/MGBG-treated cells by DNAase II digestion was enriched 4-7-fold for Mg2+-soluble species relative to controls. DNA released by micrococcal nuclease digestion from all three treatment groups was characterized as consisting of higher-order nucleosomal structure than was DNA released from untreated cells. At least some of the altered chromatin properties were abolished by a brief treatment of cells with polyamines, notably spermine. These studies provide the first demonstration in vivo of altered chromatin structure in cells treated with inhibitors of polyamine biosynthesis.     

Cation-dependent solubilization of rat thymocyte chromatin is closely related to decondensation of the nuclei

The cation-dependent solubilization of rat thymocyte chromatin has been compared with decondensation of the nuclei as a function of sodium phosphate-mediated changes in the concentration of Mg2+ and Na+. After digestion of the nuclei with DNase I or Micrococcus nuclease for a time just sufficient to permit extraction of a maximal amount of chromatin (minimum digestion), solubilization of most of the chromatin was found to occur with the same cation dependency as decondensation of untreated nuclei, while further digestion changed the ionic requirements for solubilization. The cation-dependency of the chromatin solubility and of the nuclear decondensation also exhibited the same variations with temperature. The chromatin in the nuclei became up to 4-times more sensitive to DNase I by decondensation, which also induced a shift in the DNase I cleavage mode from a 200 bp to a 100 bp repeat pattern. In contrast, the sensitivity to Micrococcus nuclease appeared to be nearly unchanged. These results suggest that solubilization of chromatin prepared by a mild endonuclease treatment occurs as a direct consequence of structural changes in the chromatin which take place during decondensation of the nuclei.     

Considerations in the isolation of rat liver nuclear matrix,nuclear envelope,and pore complex lamina

A number of recent studies have demonstrated a salt-, nuclease, and detergent-resistant subnuclear structure termed the nuclear protein matrix which consists of a fibrogranular intranuclear network, residual components of the nucleolus, and a peripheral lamina. Other workers, however, have shown that somewhat similar methods result in the isolation of the peripheral lamina devoid of the intranuclear components. In this report we demonstrate that seemingly slight changes in the isolation procedure cause major changes in the morphology of the residual structures obtained. When freshly purified rat liver nuclei were digested with DNase I and RNase A and then extracted with buffers of low magnesium ion concentration (LS buffer) and high ionic strength (HS buffer), the resulting structures isolated prior to or after Triton X-100 extraction lacked the extensive intranuclear network and the easily identifiable residual nucleoli present in the nuclear protein matrix. Systematic modification of this extraction procedure revealed that morphologically identifiable residual nucleoli were present when digestion with RNase A followed extraction with HS buffer but were absent when the order of these steps was reversed. The removal of the nucleolus by RNase A and HS buffer correlated with the removal of nuclear RNA by the same treatments. These coordinate events could not be prevented by treatment with protease inhibitors but were prevented by treatment of the RNase A with diethylpyrocarbonate, an RNase inhibitor. The extensive intranuclear network seen in the nuclear protein matrix was sparse or absent when residual structures were prepared from DNase- and RNase-treated nuclei under conditions which minimized the oxidation of protein sulfhydryl groups. In contrast, an extensive non-chromatin intranuclear network was seen if the formation of intermolecular protein disulfide bonds was promoted by extraction of nuclei with cationic detergents, by overnight incubation, or by treatment with oxidizing agents like sodium tetrathionate prior to nuclease digestion and subsequent extraction. By varying the order of extraction steps and the extent of disulfide cross-linking, it is possible to isolate from a single batch of nuclei residual structures with a wide range of morphologies and compositions.     

The structural organization of mouse chromatin as a function of age.

Chromatin is organized into a repeating structure (nucleosome) made up of proteins and DNA. Micrococcal nuclease and DNAase I have been used to probe this structure in nuclear populations from three tissues (liver, brain, and heart) of the inbred mouse strain C57BL at different ages. For those parameters examined, for each tissue, chromatin contained essentially the same features of nucleosomal organization, regardless of the age of the mouse. Thus, the rate and extent of nuclease digestion and the size of the DNA repeat unit and nucleosome core are not significantly different as a function of age. However, the accessibility of internucleosomal DNA to micrococcal nuclease, as determined by measuring the DNA size distribution after nuclease cutting, may be partially limited in chromatin of brain (but not liver or heart) of older animals. These results indicate that there are no gross, age-related changes in the conformational state or organization of chromatin in these tissues. The results do not exclude smaller alterations in chromatin that might occur with age, which the current methodology might not be sensitive enough to detect.     

Single-strand-specific degradation of DNA during isolation of rat liver nuclei

We have investigated structural change in rat liver DNA produced by different isolation procedures and specifically compared the integrity of DNA derived by phenol extraction from isolated and purified nuclei with preparations extracted immediately from a crude liver homogenate containing intact nuclei. As indicated by stepwise elution from benzoylated DEAE-cellulose, most structural change in DNA was evident following nuclei isolation. Damage principally involved generation of single-stranded regions in otherwise double-stranded DNA fragments; totally single-stranded DNA was not detected by hydroxylapatite chromatography. Caffeine gradient elution suggested formation of single-stranded regions extending for up to several kilobases. In neutral sucrose gradients, differences in sedimentation rates of respective DNA samples consequent upon S1 nuclease digestion could be detected after isolation of nuclei, though not in other circumstances. The observed single-strand-specific nuclease digestion of DNA could apparently be reduced if steps were taken to reduce autodigestion during nuclei isolation by reduction of temperature and covalent cation concentration. The results are discussed in terms of the use of exogenous and endogenous nucleases in chromatin fractionation studies involving isolated nuclei and possible artifactual findings that may be generated by single-strand-specific autodigestion.