Change in the activity of DNAse I inhibitor in the mouse spleen on the administration of a synthetic polyanion

Synthetic polyanion pyran (copolimer of divinyl ether and maleic anhydride) injected to mice increases the titre of antibody to sheep red blood cells as well as the activity of serum DNAase I and DNAase I splenic inhibitor. Simultaneously a growth of the spleen weight takes place. A possible role of the DNAase I inhibitor system in the mechanism of the adjuvant action of synthetic polyanion is discussed.     

The association of actin with a thyroid lysosomal fraction.

A lysosome-enriched fraction was prepared from bovine thyroid tissue using sucrose gradient centrifugation. An inhibitor of DNAase I was found to co-sediment and co-purify with the lysosomal fraction. This inhibitory activity is blocked by heavy meromyosin in the absence of ATP, and a component of 42000 molecular weight can be isolated by affinity chromatography on DNAase I linked to Sepharose. These results are consistent with the presence of an actin-like protein in a lysosome-enriched preparation from bovine thyroid tissue. Also, an increase in the level of membrane-associated actin is observed in response to thyrotropin stimulation of the thyroid tissue     

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.     

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.     

Possible role of DNAse I in the development of experimental leukemia]

An increase in the DNAase 1 activity in the serum and an increase in the DNAase inhibitor activity in the spleen in the development of virus Friend leukemia were demonstrated. Increased activity of the inhibitor in the spleen was also revealed after intravenous injection of exogenous DNAase 1 into mice. A potential role of serum DNAase 1 in the development of experimental leukemia is discussed.     

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.     

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.     

Selective assay of monomeric and filamentous actin in cell extracts,using inhibition of deoxyribonuclease I

A simple and selective assay for monomeric and filamentous actin is presented, based on the inhibition of DNAase I by actin. In mixtures of monomeric and filamentous actin, only the monomeric form is measured as DNAase inhibitor. The total amount of actin in a sample can be determined after depolymerization of F actin with guanidine hydrochloride. The assay is rapid enough to detect changes in the polymerization state of actin in vitro over time intervals as short as 3 min. Data characterizing unpolymerized and filamentous actin pools in extracts of human platelets, lymphocytes and HeLa cells are presented.     

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.     

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.     

Effect of X-ray induced DNA damage on DNAase I hypersensitivity of SV40 chromatin: relation to elastic torsional strain in DNA.

The effect of X-irradiation on DNAase I hypersensitivity of SV40 minichromosomes within nuclei or free in solution was investigated. The susceptibility of the specific DNA sites in the control region of minichromosomes to DNAase I decreased in a dose dependent manner after irradiation of isolated nuclei. On the other hand, the irradiation of minichromosomes extracted from nuclei in 0.1 M NaCl-containing buffer almost did not affect the level of their hypersensitivity to DNAase I. This suggests that DNAase I hypersensitivity may be determined by two different mechanisms. One of them may be connected with elastic torsional strain within a fraction of minichromosomes and another seems to be determined by nucleosome free region. The first mechanism may be primarily responsible for the hypersensitivity of minichromosomes within nuclei. After irradiation of the intact cells, DNAase I hypersensitivity tested in nuclei substantially increased. This was connected with activation of endogeneous nucleases by X-irradiation which led to accumulation of single- and double-strand breaks superimposed to DNAase I induced breaks in the control region of SV40 DNA.     

Features of the structure of replicating and non-replicating chromatin in chicken erythroblasts.

The digestion by DNAase I of DNA synthesised by isolated chicken erythroblasts was examined in isolated nuclei. It was found that newly synthesised DNA was susceptible to DNAase I but matured to a relatively resistant form with increasing time after replication as observed in mammalian systems. The presence of trypsin in the digestion exposed all of the DNA to DNAase I action. Examination of the digestion products showed that the newly replicated DNA differed little from the more mature form in the structure of the DNA-protein complex but that the difference in susceptibility was probably a result of a differential rate of access of the DNAase to the new and old DNA.     

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.     

DNAase I sensitivity of genes expressed during myogenesis.

Cultures of a rat myogenic cell line were used to examine the question of whether in proliferating precursor cells genes which are programmed to be expressed later in development, in the same cell lineage, differ in DNAase I sensitivity from genes which are never expressed in these cells. Nuclei isolated from proliferating mononucleated myoblasts, differentiated cultures containing multinucleaged fibers, and rat brain, were treated with DNAase I. The sensitivity of the genes coding for the muscle-specific alpha-actin, myosin light chain 2 and the nonmuscle beta-actin was measured by blot hybridization of nuclear DNA with the corresponding cloned cDNA and genomic DNA probes. The sensitivity of these genes was compared to that of a gene not expressed in the muscle tissue. The results showed that in the muscle precursor cells, the potentiality of tissue-specific genes to be expressed is not reflected in DNAase I sensitivity. The changes which render these genes preferentially sensitive to DNAase I take place during the transition to terminal differentiation. The results showed also that the region of DNAase I sensitivity of the alpha-actin gene in the differentiated cells ends between 40 to 700 bp 5' to the structural gene. No DNAase I hypersensitive site was detected 5' to the alpha-actin gene.     

Depolymerization of F-actin by deoxyribonuclease I.

Deoxyribonuclease I causes depolymerization of filamentous muscle actin to form a stable complex of 1 mole DNAase I:1 mole actin. The regulatory proteins tropomyosin and troponin bind to filamentous actin and slow down but do not prevent the depolymerization. In the absense of ATP, heavy meromyosin binds tightly to actin filaments and blocks completely the DNAase I: actin filament interaction. Addition of ATP releases heavy meromyosin; DNAase I is then rapidly inhibited and the actin filaments are depolymerized.     

Homologous desensitization of ATP-mediated elevations in cytoplasmic calcium and prostacyclin release in human endothelial cells does not involve protein kinase C.

The interaction of echinomycin with a kinetoplast DNA fragment which contains phased runs of adenine residues has been examined by various footprinting techniques. DNAase I footprinting confirms that all drug-binding sites contain the dinucleotide CpG. However, not all such sequences are protected. Three sites, each of which is located between two adenine tracks in the sequence GCGA, are not protected from DNAase I attack. Enhanced cleavage by DNAase I, DNAase II and micrococcal nuclease is observed in regions surrounding drug-binding sites. The results suggest that echinomycin alters the conformation of the AT tracks, making them more like an average DNA structure. Echinomycin renders adenine residues in the sequence CGA hyper-reactive to diethyl pyrocarbonate.     

Differences in the nuclease sensitivity between the two alleles of the immunoglobulin kappa light chain genes in mouse liver and myeloma nuclei.

In mouse myeloma T the productive kappa light chain gene differs from its aberrantly rearranged allele in the patterns of DNAase I hypersensitive sites. In the region of the alleles where they are identical in sequence they have one site in common which lies 0.8 kb downstream of the coding region; but two sites upstream of and within the C gene segment (2) are found only on the non-productive allele. Within the region of different sequences both alleles have analogously located DNAase I hypersensitive sites; they lie 0.15 kb upstream of the respective leader segments and cover putative promoter sequences. Only one of the six DNAase I hypersensitive sites is also very sensitive towards micrococcal nuclease due to its particular DNA sequence. The non-rearranged gene studied in liver nuclei has no DNAase I hypersensitive sites but is preferentially cleaved in A/T rich regions.     

A novel magnesium-dependent structural transition of chicken erythrocyte chromatin in situ

Lowering magnesium concentration below the value of 1 mM leads to a structural transition of chicken erythrocyte chromatin in situ, which results in a change in its fragmentation by pancreatic DNAase (DNAase I) from double-nucleosome to 100-basepairs mode. At 0.75 mM MgCl2, the pattern of chromatin fragmentation by DNAase I is similar to that generated by DNAase II, and it is further changed at lower concentrations of magnesium. This transition is, at least partly, reversible, and is, presumably, related to packing of the 25-30 nm chromatin fiber into higher-order structures.     

Non random distribution of lesions induced by deoxyribonuclease I in human chromosomes

We studied the action of deoxyribonuclease I on human lymphocytes in order to determine the localization of the DNAase induced aberrations. Our results indicate a non-random distribution of the lesions on chromosome regions which may reflect a differential pattern of sensitivity to the enzyme. Furthermore we observed a correspondence between the preferential DNAase induced breaks and fragile sites that are expressed in lymphocytes maintained in medium without folic acid. A possible interpretation of our findings is that the accessibility to DNAase and/or the efficiency of the repair systems depend on the chromatin structure that influences also the expression of some common fragile sites.Abbreviations DNAase I deoxyribonuclease I E.C.3.1.4.5.     

The effect of guanidine hydrochloride on the conformation of bovine pancreatic DNAase I as measured with circular dichroism

The denaturation of bovine pancreatic DNAase I (EC 3.1.21.1) by guanidine hydrochloride (GdnHCl) has been investigated with circular dichroism in the presence and absence of 1 mM Ca2+ at the wavelength region of 210-240 nm at 12.25 and 36 degree C. The change of the molar ellipticity at 220 nm by GdnHCl titration showed cooperative transition at each temperature and the midpoints of the titrations occurred near 2 M GdnHCl. At each temperature, the denaturation of DNAase I in the presence of 1 mM Ca2+ occurred a little slowly as compared with that in the absence of Ca2+. This suggests that 1 mM Ca2+ can to some extent stabilize the secondary structure of DNAase I against GdnHCl denaturation. The apparent free energy for the denaturation of DNAase I obtained by GdnHCl titration was calculated as 9.3 +/- 0.3 kcal/mol and 8.9 +/- 0.2 kcal/mol at 25 degree C in the presence and absence of 1 mM Ca2+, respectively. The possible regions for the alpha -helix and beta -structure of DNAase I were predicted from the amino acid sequence by probability calculation of Chou, P.Y. and Fasman, G.D., Adv. Enzymol. 47, 45-148. The characteristic feature is that the NH2-terminal half of DNAase I is rich in beta -structure and the COOH-terminal half contains mainly alpha -helix.