Relation between DNA replication and neutral Mn 2+-dependent DNAse activity in chromatin

In cultures of primary murine fibroblasts the 10% serum stimulates the replicative synthesis of DNA inhibited by aphidicolin and araC (cytosine arabinoside). Using direct immunofluorescence analysis, it was shown that antibodies penetrate inside the cells and after 4 hours are pooled in the nuclei, where they remain for another 20 hours. The substitution of antibodies against chromatin DNAase by bovine serum albumin of normal serum gamma-globulins does not interfere with the DNA synthesis induction.     

Electron immunohistochemical analysis of localization of neutral Mn2+-dependent DNAase. III. Visualization of DNAse binding to isolated chromatin

Neutral Mn(2+)-dependent DNAse is localized on isolated chromatin structures in both normal and regenerating rat liver. The enzyme was revealed located along the whole length of nucleosomal chain and in hypernucleosomal structures. However, as concerns the quantity of the enzyme, it was distributed unevently along the chromatin, thus reflecting the pattern of different functional states of native chromatin. According to biochemical and immunohistochemical data, DNAse can hydrolyse in vitro only one-stranded DNA. One of possible explanations of the observed differences in DNAse binding with native DNA chromatin and its inability to adsorb on native DNA in vitro may be the presence of hypothetical DNA-binding proteins in native chromatin making complexes with DNAse and thereby responsible for immobilization of the enzyme on chromatin structures in vivo.     

Mg2+-dependent interaction of DNA with eukaryotic cells

Interaction of DNA with eukaryotic cells under conditions similar to those providing DNA adsorption onto liposomes was studied. It was revealed that mouse fibroblasts (line A9) and myeloma cells bind phage and plasmid DNA in 0.3 M sucrose solution containing Mg2+-ions. Additional pretreatment of the cells by trypsin did not affect DNA adsorption efficiency. The major part of the adsorbed DNA recovered by salt treatment of the cells, but 10-15% of DNA was found to be irreversible. Up to 50% of the irreversibly bound DNA molecules retain their linear size after treatment of cells with DNAse I. Efficiencies of DNA adsorption and irreversibly binding depend on the concentration of Mg2+ in the medium. The process of DNA irreversible binding is not inhibited by drugs affecting cell metabolism. It is assumed that DNA adsorbs onto the phospholipid domains of the cell membrane, and part of the adsorbed DNA is taken up into the interior of the cells.     

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.     

Ultrastructural localization of neutral DNAse in hepatocytes by immune electron microscopy using colloidal gold

A method for obtaining of the colloidal gold with particles 20 nm in diameter is described. The use of conjugate of colloidal gold-specific antibodies to the neutral DNAase is shown to determine the DNAase localization on ultrathin epontic sections of rat liver fixed by glutaraldehyde. The conditions of fixation, filling and immune reactions are described. The neutral DNAase has been found to localize mainly in heterochromatin.     

DNA interaction with Mn2+ ions at elevated temperatures: VCD evidence of DNA aggregation

Interaction of natural calf thymus DNA with Mn(2+) ions was studied at room temperature and at elevated temperatures in the range from 23 degrees C to 94 degrees C by means of IR absorption and vibrational circular dichroism (VCD) spectroscopy. The Mn(2+) concentration was varied between 0 and 1.3M (0 and 10 [Mn]/[P]). The secondary structure of DNA remained in the frame of the B-form family in the whole ion concentration range at room temperature. No significant DNA denaturation was revealed at room temperature even at the highest concentration of metal ions studied. However at elevated temperatures, DNA denaturation and a significant decrease of the melting temperature of DNA connected with a decrease of the stability of DNA induced by Mn(2+) ions occurred. VCD demonstrated sensitivity to DNA condensation and aggregation as well as an ability to distinguish between these two processes. No condensation or aggregation of DNA was observed at room temperature at any of the metal ion concentrations studied. DNA condensation was revealed in a very narrow range of experimental conditions at around 2.4 [Mn]/[P] and about 55 degrees C. DNA aggregation was observed in the presence of Mn(2+) ions at elevated temperatures during or after denaturation. VCD spectroscopy turned out to be useful for studying DNA condensation and aggregation due to its ability to distinguish between these two processes, and for providing information about DNA secondary structure in a condensed or aggregated state.     

Mn2+-dependent endonuclease activity of chromatin

The endogenous endonuclease activity of chromatin in isolated rat liver nuclei in the presence of Mn2+, Mg2+ and Ca2+ + Mg2+ was studied. The existence of a Mn2+-dependent endonuclease activity not coupled with the Ca2+, Mg2+-dependent endonuclease was demonstrated, which was weaker than the former one in isolated cell nuclei but higher than in the preparation of Ca2+, Mg2+-dependent nuclease obtained by gel filtration through Toyopearl HW 60F. The Mn2+-dependent splitting of chromatin predominantly occurs at linker DNA of distal parts of chromatin loops. A split-off of purified DNA was more universal than in the presence of Ca2+, Mg2+-dependent endonuclease; the hydrolysis rate of native and denaturated DNA appeared to be the same.     

Ca2+-dependent interaction of BAPTA with phospholipids

Starting from a comparative study of different Ca2+ chelators on the G-protein-induced inhibition of the CaV2.1 Ca channels, we demonstrate that BAPTA and DM-nitrophen are able to interact, in a Ca2+- and lipid-dependent manner, with phospholipid monolayers. Critical insertion pressure and sensitivity to charged lipids indicated that insertion in the lipid film may occur in biological membranes as those found on Xenopus oocytes. This novel property is not found for EGTA and EDTA and may participate to the unusual ability of BAPTA-related molecules to chelate Ca2+ ions in the very close vicinity of the plasma membrane, where most of the Ca2+-dependent signalling triggered by voltage-gated Ca2+ currents occurs.     

The reversible activation by Mn2+ ions of the Ca2+-requiring neutral proteinase of human erythrocytes

Mn2+ (50 microM) satisfies the requirement for activity of the purified Ca2+-dependent neutral proteinase from human erythrocytes. Unlike the activation by Ca2+ [E. Melloni et al. (1984) Biochem. Int. 8, 477-489], the effect of Mn2+ is fully reversible and does not involve autodigestion of the native 80-kDa catalytic subunit. However, the native dimeric proenzyme (procalpain), which contains both the 80-kDa subunit and a smaller 30-kDa subunit, is not activated by Mn2+ alone but also requires the presence of micromolar concentrations of Ca2+. Under these conditions, 40% of the maximum activity is expressed without dissociation of the 80- and 30-kDa subunits. Mn2+, but not micromolar Ca2+, can also partially satisfy the metal requirement of the native 80-kDa subunit isolated after dissociation of the heterodimer. This activity is further enhanced by the addition of 5 microM Ca2+, which is ineffective in the absence of Mn2+. After procalpain is converted to active calpain by incubation with Ca2+ and substrate [S. Pontremoli et al. (1984) Biochem. Biophys. Res. Commun. 123, 331-337] full activity is observed with 5 microM Mn2+, which now substitutes completely for Ca2+. Activation of procalpain by Mn2+ represents a new mechanism for modulation of the Ca2+-dependent proteinase activity.     

Activation of tyrosine hydroxylase by Ca2+-dependent neutral protease, calpain

Two molecular species of Ca2+-dependent neutral protease (calpains I and II) and its endogenous inhibitor (calpastatin) in cytosol fraction of bovine adrenal medulla were separated by hydrophobic interaction chromatography. Both calpains I and II, having low and high Ca2+ requirements for casein hydrolysis, respectively, were found to activate tyrosine hydroxylase(TH) that had been purified from cytosol fraction of bovine adrenal medulla. This activation of TH by calpain was inhibited by leupeptin and the endogenous inhibitor, calpastatin. The activated TH with calpain II, characterized by high-performance gel permeation chromatography, had a reduced Mr of 120,000 from the Mr of 230,000 of native enzyme.     

DNAses of the cell nuclei: Mn2+-dependent endonuclease

Comparison of catalytic properties of a Mn2(+)-dependent and a Ca2+, Mg2+ dependent endonucleases of rat liver cell nuclei was carried out. The Mn2(+)-dependent endonuclease has Mr 31 kDa by SDS-PAAG-electrophoresis; pH optimum 5.5; calcium-magnesium synergism less than 3 in rat liver DNA, RF M13 DNA and phage M13 DNA. The rate of hydrolysis of single strand and double strand circular DNA was the same. The Mn2(+)-dependent endonuclease split DNA by double hit manner, and didn't change the manner in the presence of different divalent cations. Ca2+, Mg2(+)-dependent endonuclease has pH optimum 6.5; calcium-magnesium synergism up to 40 in rat liver DNA and 175 in RF M13 DNA. The rate of hydrolysis of single strand DNA was higher than double-strand DNA.     

Activation of the Ca2+-ATPase of human erythrocyte membrane by an endogenous Ca2+-dependent neutral protease

Limited proteolysis of the plasma membrane calcium transport ATPase (Ca2+-ATPase) from human erythrocytes by trypsin produces a calmodulin-like activation of its ATP hydrolytic activity and abolishes its calmodulin sensitivity. We now demonstrate a similar kind of activation of the human erythrocyte membrane Ca2+-ATPase by calpain (calcium-dependent neutral protease) isolated from the human red cell cytosol. Upon incubation of red blood cell membranes with purified calpain in the presence of Ca2+ the membrane-bound Ca2+-ATPase activity was increased and its sensitivity to calmodulin was lost. In contrast to the action of other proteases tested, proteolysis by calpain favors activation over inactivation of the Ca2+-ATPase activity, except at calpain concentrations more than 2 orders of magnitude higher. Exogenous calmodulin protects the Ca2+-ATPase against calpain-mediated activation at concentrations which also activate the Ca2+-ATPase activity. Calcium-dependent proteolytic modification of the Ca2+-ATPase could provide a mechanism for the irreversible activation of the membrane-bound enzyme.     

Stimulation of the hexose monophosphate pathway in the human erythrocyte by Mn2+: evidence for a Mn2+-dependent NADPH peroxidase activity

In human RBC hemolysates, Mn2+ was found to stimulate the HMP as determined by the release of 14CO2 from [1-14C]glucose, providing activities of 125, 200, and 300% of basal at Mn2+ concentrations of 1, 10, and 100 mM, respectively. To explore the possibility that this stimulatory effect upon the HMP is a result of redox recycling of NADPH, RBC hemolysates were used to study NADPH oxidation. Mn2+, alone or in combination with a free radical-generating system, did not enhance the ability of hemolysates to oxidize NADPH. However, hemolysates + 10 mM H2O2 brought about a 10-fold increase in NADPH oxidation (0.51 +/- 0.05 nmole/min to 5.67 +/- 0.84 nmole/min) and the addition of 10 mM Mn2+ to this system increased the rate of oxidation to 34.10 +/- 2.97 nmole/min. Boiled hemolysates, either in the presence or absence of Mn2+, had some residual catalytic activity.     

Inhibition of neutral Mg2+-dependent sphingomyelinase by ubiquinol-mediated plasma membrane electron transport

Summary.  Sphingomyelin is an abundant constituent of the plasma membranes of mammalian cells. Ceramide, its primary catabolic intermediate, has emerged as an important lipid signaling molecule. Previous work carried out by our group has documented that plasma membrane Mg²⁺-dependent neutral sphingomyelinase can be effectively inhibited by exogenous ubiquinol. In this work, we have tested whether or not plasma-membrane-associated electron transport can also achieve this inhibition through endogenous ubiquinol. Our results have shown that Mg²⁺-dependent neutral sphingomyelinase in isolated plasma membranes was inhibited by NAD(P)H under conditions where ubiquinone is reduced to ubiquinol. This inhibition was potentiated in the presence of an extra amount of NAD(P)H:(quinone acceptor) oxidoreductase 1 (EC 1.6.99.2). Depletion of plasma membranes from lipophilic antioxidants by solvent extraction abolished the inhibition by reduced pyridine nucleotides without affecting the sensitivity of the neutral sphingomyelinase to exogenous ubiquinol. Reconstitution of plasma membranes with ubiquinone restored the ability of NAD(P)H to inhibit the enzyme. Our results support that the reduction of endogenous ubiquinone to ubiquinol by NAD(P)H-driven electron transport may regulate the activity of the plasma membrane neutral sphingomyelinase. Received May 20, 2002; accepted September 20, 2002; published online May 21, 2003 RID="**" ID="**" Present address: Department of Biomedical Engineering, School of Medicine, University of Baltimore, Maryland, U.S.A. RID="*" ID="*" Correspondence and reprints: Departamento de Biología Celular, Fisiología e Inmunología, Facultad de Ciencias, Edificio C-6, Campus Rabanales, Universidad de Córdoba, 14014 Córdoba, Spain.     

Mg2+-, Ca2+-dependent unwinding of DNA by poly-L-glutamic acid

In order to examine a possibility that the high acidic amino acid region in the nonhistone protein HMG(1+2) is concerned with the Mg2+-, or Ca2+-dependent unwinding of DNA by the HMG(1+2) (1,2), poly-L-glutamic acid was employed as an acidic model peptide for thermal melting temperature analysis. The poly-L-glutamic acid bound to DNA either in the presence or absence of Mg2+. The poly-L-glutamic acid unwound DNA double-helix to a similar extent to HMG(1+2) in the presence of Mg2+ or Ca2+, but not in the absence of them. These results may suggest that the high acidic amino acid region in HMG(1+2) participates in Mg2+-, Ca2+-dependent unwinding of DNA double-helix.     

Purification of the Ca2+-dependent proteinase inhibitor from bovine cardiac muscle and its interaction with the millimolar Ca2+-dependent proteinase

A protein inhibitor of the Ca2+-dependent proteinase has been purified from bovine cardiac muscle by using the following steps in succession: salting out 17,600 X gmax supernatants from muscle homogenates in 50 mM Tris acetate, pH 7.5, 4 mM EDTA between 25 and 65% ammonium sulfate saturation; eluting between 25 and 120 mM KCl from a DEAE-cellulose column at pH 7.5; salting out between 30 and 60% ammonium sulfate saturation; Ultrogel-22 gel permeation chromatography at pH 7.5; heating to 80 degrees C followed by immediate cooling to 0 degree C; 6% agarose gel permeation chromatography in 4 M urea, pH 7.5; and elution from a phenyl-Sepharose hydrophobic column between 0.7 and 0.5 M ammonium sulfate. Approximately 1.16-1.69 mg of purified Ca2+-dependent proteinase inhibitor are obtained from 1 kg of bovine cardiac muscle, fresh weight. Bovine cardiac Ca2+-dependent proteinase inhibitor has an Mr of 115,000 as measured by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, a pI of 4.85-4.95, very little alpha-helical structure, a very low specific absorbance of 1.647 (A1% 280), and very low contents of histidine, tryptophan, phenylalanine, and tyrosine. Bovine cardiac Ca2+-dependent proteinase inhibitor probably contains a single polypeptide chain in nondenaturing solvents. One 115-kDa inhibitor polypeptide inactivates 10 110-kDa millimolar Ca2+-requiring proteinase (millimolar Ca2+-dependent proteinase) molecules in assays of purified proteins. Inhibition of millimolar proteinase by the proteinase inhibitor did not change in the pH range 6.2-8.6. The inhibitor requires Ca2+ to bind to millimolar Ca2+-dependent proteinase. The Ca2+ concentration required for one-half-maximum binding of millimolar Ca2+-dependent proteinase to the inhibitor was 0.53 mM, compared with a Ca2+ concentration of 0.92 mM required for one-half maximum activity of millimolar Ca2+-dependent proteinase in the absence of the proteinase inhibitor. Unless millimolar Ca2+-dependent proteinase is located subcellularly in a different place than the proteinase inhibitor or unless the proteinase/inhibitor interaction is regulated, millimolar proteinase could never be active in situ.     

Regulation of the Ca2+-dependent neutral proteinases from rabbit liver by an endogenous inhibitor

An endogenous inhibitor of neutral Ca2+-dependent proteinases has been isolated from rabbit liver cytosol. The inhibitor is a heat-stable, 240-kDa, tetrameric protein. It is dissociated into its 60-kDa subunits by high concentrations of Ca2+ (0.1-1 mM), but not by lower concentrations in the physiological range. Inhibition of the 150-kDa proteinase of rabbit liver [Melloni, E., Pontremoli, S., Salamino, F., Sparatore, B., Michetti, M. and Horecker, B.L. (1984) Arch. Biochem. Biophys. 232, 505-512] requires the monomeric form of the inhibitor, and occurs only at the high concentrations of Ca2+ which also cause dissociation of the dimeric 150-kDa proteinase into its 80-kDa subunits. The molecular weight of the inactive proteinase-inhibitor complex was estimated by the equilibrium gel penetration method to be 140 kDa, suggesting that it contains one subunit of proteinase and one of inhibitor. The mechanism of interaction of the inhibitor with the 200-kDa proteinase at high concentrations of Ca2+ is identical to that observed for the 150-kDa proteinase, namely dissociation of both proteinase and inhibitor into subunits and formation of an inactive 160-kDa proteinase-inhibitor complex. However, unlike the 150-kDa proteinase, which does not interact with the inhibitor at low Ca2+ concentrations, the 200-kDa proteinase is also inhibited at low concentrations of Ca2+. Under these conditions, the high-molecular-weight complex (greater than 400 kDa) formed between the tetrameric inhibitor and the dimeric proteinase prevents conversion of the 200-kDa proenzyme to the active, low-Ca2+-requiring form.