The determination of the nature of the interaction of neutral Mn2+-dependent DNAse with DNA by immunoelectron microscopy

The interaction of neutral DNAase with native and denatured DNA was shown by immunoelectron microscopy method with the help of colloidal gold. The neutral DNAase of the rat liver nuclear chromatin is absorbed both to denatured DNA, in which the denatured regions are arranged at 5'-3' ends, and to DNA in which these regions are distributed along the whole molecule.     

Some aspects of the desoxyribonuclease activities of animal tissues

It has been found that many animal tissues contain "acid" desoxyribonucleases with pH optima near 5.2. A chemical method for the determination of this activity is described. The pancreatic desoxyribonuclease crystallized by Kunitz and shown to have a neutral pH optimum occurs in the pancreas together with the "acid" enzyme, but only the "neutral" enzyme occurs in the pancreatic juice. The ratio of "neutral" to "acid" DNAase activities in the pancreas is greater than 200, but in all other tissues examined there is no appreciable concentration of the neutral enzyme. It is concluded that neutral DNAase, like trypsin or lipase, has a digestive function. Some problems in the activation of the secretory enzyme in neutral pancreatic extracts are described. This activation can be interpreted in terms of a specific inhibitor or an inactive form of the enzyme. A comparison of the "acid" DNAase activities of different organs of the calf, horse, chicken, mouse, and rat indicates a possible connection between the DNAase concentration of a tissue and its capacity for proliferation or regeneration. However, the comparative DNAase activities of fetal and adult tissues do not support the view that DNAase function is limited to some simple role in the mechanics of cell division. Studies on the incorporation of glycine-N¹⁵ into the desoxypentose nucleic acids of avian red cells, and mouse liver, pancreas, and kidney show that the N¹⁵ uptake into the DNA of the chromosome is most rapid in tissues with high DNAase concentrations. No N¹⁵ incorporation is observed in the DNA of avian red cells, which have negligible concentrations of the enzyme. The analyses of tissues and nuclei isolated in non-aqueous media show that the bulk of the enzyme occurs in the cytoplasm of the cell, and that nuclear concentrations vary from tissue to tissue. A theory relating the DNAase activity of the cell to its over-all desoxypentose nucleotide metabolism is discussed. No evidence has been found for the presence of inhibitors of the "acid" DNAase in animal tissues.     

Stimulation of DNA synthesis in isolated nuclei of rat liver cells by neutral Mn-dependent DNase of chromatin

It was demonstrated that neutral Mn-dependent DNAase from rat liver chromatin stimulates the incorporation of labeled precursors of DNA into high molecular weight fractions of isolated nuclear DNA. The effects of DNA-polymerase inhibitors and the properties of DNA synthesis products suggest that neutral Mn-dependent DNAase can induce replicative synthesis of DNA in the nuclei of normal and regenerating rat liver.     

Nuclear endogenous Ca2+-dependent endodeoxyribonuclease in differentiating chick embryonic lens fibers

During terminal differentiation of lens epithelial cells into fiber cells, nuclei become pycnotic and DNA degradation occurs. We investigated the putative role in this process of an endogenous DNAase. After incubation of isolated nuclei of both cell types at 37 degrees C, DNAase activity was revealed by DNA size analysis on 0.3-1% neutral and alkaline agarose, one- and two-dimensional gels. This DNAase activity is more prominent in lens fiber nuclei than in epithelial nuclei at all the embryonic stages probably because of a preexisting higher concentration of divalent cations in the former. This activity is calcium or magnesium dependent in both types of nuclei.     

Nuclear DNAase of the yeast Candida tropicalis

Using stepwise extraction of chromatin from Candida tropicalis by NaCl (0.1-1.0 M) the protein dissociated by 0.3 and 0.6 M NaCl (fractions 0.3 and 0.6) possessing the DNAase activity were obtained. These DNAases are activated by Mg2+ and cause preferential hydrolysis of heat-denaturated DNA. Fraction 0.3 DNAase has a maximum at neutral values of pH (around 7.0) and causes endonucleolytic hydrolysis of DNA. Fraction 0.6 DNAase causes exonucleolytic hydrolysis of DNA but a maximum at alkaline pH (8.0). The properties of isolated chromatin DNAases of Candida tropicalis differ from those of the known DNAases of the yeast Saccharomyces cerevisiae.     

The quantitative determination of the DNAse activity in Staphylococcus aureus isolated from monkeys

A new, cheaper and more sensitive method for the quantitative determination of DNAase produced by S. aureus is described. The method permits the determination of DNAase activity in a wider range of titers. The method is based on the detection of the depolymerizing action of staphylococcal nuclease on DNA dyed with ethidium bromide. In this work 22 S. aureus strains isolated from monkeys and 12 strains isolated from humans have been used. The amount of produced by these strains has been determined. The DNAase results of this determination have shown that among S. aureus strains isolated from monkeys and humans the occurrence of strains with both high and low DNAase activity can be observed.     

Yeast mitochondrial deoxyribonuclease stimulated by ethidium bromide: III. Possible involvement in the induction of “petite” mutation by phenanthridinium derivatives

We previously described a yeast-mitochondrial deoxyribonuclease (EtdBr DNAase), whose activity is stimulated by ethidium bromide. In this paper, we have compared the ability of a series of phenanthridinium derivatives to activate the EtdBr DNAase “in vitro” and their efficiency in inducing “petite” mutants in the yeast S. cerevisiae. Kinetics studies, in the absence or the presence of SDS, were first carried out to compare the penetration rates of the various compounds. Dose-response curves were then established to quantify their mutagenic efficiencies. From these data, a linear correlation was established between the level of EtdBr DNAase activation produced by a drug and its mutagenic efficiency, thus demonstrating that the two processes display similar drug-structural requirements. These results suggest that the EtdBr DNAase might be involved in the induction of petite mutations by these derivatives.     

The mechanism of action of the deoxyribonuclease of rat liver chromatin on DNA]

A mechanism of action of DNAase, isolated by chromatin extraction with 0.4 M NaCl, on DNA is described. The enzyme is an endonuclease, it does not require the presence of double-stranded regions in the DNA molecule, does not distinct single-stranded breaks in DNA, and it preferably attacks single-stranded DNA. It hydrolyses DNA for 3'-phosphodiester bonds to octane nucleotides which are resistant to the enzyme activity. The action of the enzyme on DNA does not depend on the position of terminal phosphates. Chromatin DNAase is not specific to DNAs from different origins.     

Differential solubilization of nuclear glucocorticoid receptors by DNAase I and DNAase II

This study analyzes the sensitivity of nuclear bound glucocorticoid receptors to solubilization from nuclei by DNAase I and DNAase II. Thymocytes were incubated with 10(-8) M [3H]dexamethasone, [3H]cortisol or [3H]triamcinolone acetonide, without or with 10(-6) M unlabelled dexamethasone, for 30 min at 37 degrees C and nuclei from these cells were digested with either DNAase I and DNAase II. DNAase I for 2 h at 3 degrees C leads to solubilization of 60% of the nuclear DNA and release of 10--20% triamcinolone acetonide-receptor, 30--40% dexamethasone-receptor and 85--90% cortisol-receptor. DNAase II at the same enzymatic concentration solubilizes only 10--20% of the nuclear DNA, but releases 40--50% triamcinolone-receptor, 60--70% dexamethasone-receptor and 100% cortisol-receptor. Release of nuclear bound dexamethasone-receptor by DNAase I parallels the solubilization of DNA, reaching maximum values by 2 h at 3 degrees C, whereas maximal release by DNAase II is obtained within 45 min when DNA solubilization is not complete. When nuclei initially extracted with DNAase I are re-extracted with DNAase II, greater than 65% of the DNAase I residual dexamethasone-receptors are solubilized, whereas DNAase I is ineffective in solubilizing DNAase II residual dexamethasone-receptors. DNAase I solubilizes only 30% of the 0.4 M KCl residual dexamethasone-receptor whereas DNAase II digests over 90% of this fraction. DNAase I extracts of nuclear dexamethasone-receptor chromatograph on G-100 Sephadex as a single radioactive peak just after the void volume, whereas DNAase II extracts of nuclear dexamethasone-receptor chromatograph as two peaks of radioactivity, one which is similar to the DNAase I solubilized receptor and a second broad peak of macromolecular bound radioactivity which is smaller in size.     

Electron immunohistochemical analysis of localization of neutral Mn2+-dependent DNAase. I. Synthesis of ferritin and colloidal gold conjugates with monospecific antibodies against neutral Mn2+-dependent DNAase

Rabbit antibodies against a neutral Mn(2+)-dependent rat liver DNAse were obtained, whose specificity towards DNAse was ascertained by suppression of the enzyme activity both in vitro system and immunoblotting assays. Procedures of synthesis of ferritin and colloidal gold conjugates with antibodies are described. The biological activity of the conjugates proved to be similar to that of the original antibodies.     

The interaction of bovine pancreatic deoxyribonuclease I and skeletal muscle actin

The rate of exchange of actin-bound nucleotide is decreased by a factor of about 20 when actin is complexed with DNAase I without affecting the binding constant of calcium for actin. Binding constants of DNAase I to monomeric and filamentous actin were determined to be 5 X 10(8) M-1 and 1.2 X 10(4) M-1 respectively. The depolymerisation of F-actin by DNAase I appears to be due to a shift in the G-F equilibrium of actin by DNAase I. Inhibition of the DNA-degrading activity of DNAase I by G-actin is of the partially competitive type.     

Identification of RNA molecules which contain 5 S ribosomal RNA and transfer RNA in an RNAase E-RNAase P- double mutant strain of Escherichia coli

In the analysis of DNAase II digestion of chromatin, as described in the preceding paper, interactions between adjacent nucleosomes play an important part. In order to understand the mechanism of DNAase II cleavage we next investigated the role of histone H1 in these interactions and characterized the nucleoprotein particles arising in the course of DNAase II action.H1-free chromatin prepared by three different procedures, using either 0.6 m-NaCl, transfer RNA or an ion-exchange resin, can be cleaved by DNAase II only at the internucleosomal cleavage site leading to 200-bp² digestion patterns regardless of the ionic conditions. When H1 was added back to the three chromatin preparations the 100-bp cleavage pattern could be restored only with material prepared by the resin method at low concentrations of salt. Addition of polylysine instead of H1 has the same effect, but only with material prepared by that method. A direct correlation between extended and condensed states of chromatin as monitored by electron microscopy and DNAase II cleavage in the 200 and 100-bp modes, respectively, could be established.The continuity of the nucleosome chains in DNAase II-digested chromatin is maintained in spite of intranucleosomal cleavage in the terminal section of the core DNA, even in the absence of H1. Addition of 3 m-urea, however, disrupts the nucleosome chains at the intranucleosomal cleavage sites and leads to the formation of novel nucleoprotein particles as seen in sucrose gradient centrifugations. Those sedimenting between mononucleosomes and dinucleosomes contain, almost exclusively, DNA of 300 bp (mouse) or 315 bp (chicken erythrocyte). They can be formed from particles sedimenting in the absence of urea in the dinucleosome region by either a dissociation process or a massive conformational change.On the basis of the results presented here and in the preceding paper a mechanism for DNAase II cleavage of chromatin in the 200-bp and 100-bp modes is proposed and discussed in the context of structural features of chromatin recognized by DNAase II.     

Electron microscopical localization of nucleic acids by means of nuclease-gold complexes

Summary Nucleic acids can be specifically localized at the electron microscope level by means of enzyme-gold complexes. Two enzymes RNAase A and DNAase I were labelled with colloidal gold, and the enzyme-gold complexes obtained applied on thin sections of glutaraldehyde-fixed and Epon-embedded tissues. Using RNAase-gold, the rough endoplasmic reticulum and the nucleolus of different cells appeared densely labelled. With the DNAase-gold the labelling was present over the euchromatin and the mitochondria. The quantitative evaluation, performed on different cellular compartments of the pancreatic acinar cells, confirmed the qualitative observations and ascertained the specificity of the labelling. The application of this technique, for the demonstration of nucleic acids in different tissues, is illustrated.     

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.     

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.     

The inhibition of bovine and rat parotid deoxyribonuclease I by skeletal muscle actin. A biochemical and immunocytochemical study.

Rat and bovine parotid gland and pancreas contain deoxyribonuclease I (DNAase I) activities in different amounts. The DNAase I activity in tissue homogenates of bovine and rat parotid gland can be inhibited by addition of monomeric actin, as with the enzyme of bovine pancreas. The isolated DNAase I species from bovine and rat parotid gland differ in their molecular weights and also in their affinities for monomeric actin, being lowest for rat parotid DNAase I (5 X 10(6)M(-1). Antibodies raised against rat and bovine parotid and bovine pancreatic DNAase I can be used to study the subcellular localization of DNAase I in these tissues by indirect immunofluorescence. DNAase I was found to be confined solely to the secretory granules of the tissue from which it was isolated.     

DNAase-I-hypersensitive sites in the mouse albumin gene

We have analyzed the DNAase I sensitivity of the mouse alpha-fetoprotein and albumin structural genes from fetal liver, adult liver and kidney. The albumin gene shows distinct hypersensitive sites in adult liver in addition to an overall DNAase I sensitivity, but is only slightly nuclease-sensitive in fetal liver. The alpha-fetoprotein gene does not show hypersensitive sites but displays an overall DNAase I sensitivity in fetal liver; however, it is nuclease-insensitive in adult liver. Both genes are insensitive to DNAase I in kidney. The presence of DNAase-I-hypersensitive sites in the albumin structural gene correlates with extensive demethylation of the gene in adult liver.     

Mapping of DNAase I sensitive regions on mitotic chromosomes

We have shown that in fixed mitotic chromosomes from female G. gerbillus cells the inactive X chromosome is distinctly less sensitive to DNAase I than the active X chromosome, as demonstrated by in situ nick translation. These results indicated that the specific chromatin conformation that renders potentially active genes sensitive to DNAase I is maintained in fixed mitotic chromosomes. We increased the sensitivity and accuracy of in situ nick translation using biotinylated dUTP and a specific detection and staining procedure instead of radioactive label and autoradiography and now show that in both human and CHO chromosomes, the DNAase I sensitive and insensitive chromosomal regions form a specific dark and light banding pattern. The DNAase I sensitive dark D-bands usually correspond to the light G-bands, but not all light G-bands are DNAase I sensitive. Identifiable regions of inactive constitutive heterochromatin are in a DNAase I insensitive conformation. Our methodology provides a new and important tool for studying the structural and functional organization of chromosomes.     

Effect of DNAase I on muscle tropomyosin polymerization

DNAase I, an endonuclease which interacts with G-actin, also affects tropomyosin polymerization. With chicken pectoralis or bovine cardiac ventricle tropomyosin, DNAase I both prevents tropomyosin from polymerizing and disrupts already formed tropomysin filaments. DNAase I and filament tropomyosin can also form a precipitable complex. In the electron microscope, the complex is observed as irregularly margined stellate-shaped structures with a maximum size of 9 micron. Isolated DNAase I-tropomyosin stellate complex consists of a 2:1 molar ratio of DNAase I and tropomyosin, suggesting that each tropomyosin subunit can bind DNAase I.     

Respiration-stimulated activation of DNAase I associated with mitochondria]

The influence of respiration and Ca++ transport in the liver mitochondria on the activation of DNAase I, associated with these organelles, was studied. It was shown that 96% of the total activity of this enzyme in mitochondria is in the latent state. Aeration of the mitochondrial suspension leads to a sharp increase in the enzyme activity. The activation of DNAase I is inhibited by EGTA addition (optimal pH 8.0), and stimulated in mitochondria, releasing Ca++. It is concluded that the activation of DNAase I is dependent on the state of cellular energetics. Participation of mitochondrial phospholypase A, activated by the Ca++ release from mitochondria during DNAase I activation is suggested.