DNA interaction with biologically active divalent metal ions: binding constants calculation

In our previous work we have shown that under the action of Cu²⁺, Mn²⁺ and Ca²⁺ ions DNA is able to transit into a compact state in aqueous solution. In the present work we carried out calculations of binding constants for divalent metal ions interacting with DNA in terms of the macromolecule statistical sum. The formula for calculation of the binding constants and cooperativity parameters was proposed. It was shown that on the “coil state”–“compact (globule) state” transition a single DNA molecule may undergo the first-order phase transition while the transition of the assembly of average DNA chains is of sigmoidal character typical of the cooperative and continuous transition.     

Interaction of DNA with divalent metal ions

The interaction between the native DNA macromolecules and Ca2+, Mn2+, Cu2+ ions in solutions of low ionic strength (10(-3) M Na+) is studied using the methods of differential UV spectroscopy and CD spectroscopy. It is shown that the transition metal ions Mn2+ exercise binding to the nitrogen bases of DNA at concentrations approximately 5 x 10(-6) M and form chelates with guanine of N7-Me(2+)-O6 type. Only at high concentrations in solution (5 x 10(-3) M) do Ca2+ ions interact with the nitrogen bases of native DNA. In the process of binding to Ca2+ and Mn2+ the DNA conformation experiences some changes under which the secondary structure of the biopolymer is within the B-form family. The DNA transition to the new conformation is revealed by its binding to Cu2+ ions.     

Effect of divalent metal ions on DNA conformational transitions in water-ethanol solutions

The influence of different MgCl2 and MnCl2 concentrations on DNA conformational transitions in water-ethanol solutions was studied. It was shown that the presence of magnesium ions in solution at a concentration of 5 x 10(-4) M did not influence the decrease in the size of DNA without change in its persistent length at an alcohol concentration of about 17 % v/v. In contrast, manganese ions prevent this change in DNA parameters. At sufficiently high ethanol concentrations, the compaction of DNA followed by its precipitation takes place, which is accompanied by an increase of scattering in solution. As the concentration of Mg2+ and Mn2+ in solution increases, this process is observed at lower ethanol concentrations.     

Interactions of DNA with divalent metal ions. III. Extent of metal binding: Experiment and theory

DNA with Mn²⁺ as the only counterion has been prepared, and the extent of the Mn²⁺ binding was determined under a variety of conditions through measurements of the proton relaxation enhancement of water. The total extent of Mn²⁺ binding per DNA phosphate is found to be 0.43 ± 0.04, independent of the metal ion concentration in the experimental range of 2.8 × 10^?5 to 2.1 × 10^?3M. The predictions of Manning's condensation theory and those obtained from solution of the generalized Poisson-Boltzmann equation regarding the extent of divalent ion binding to polyelectrolytes, in the presence and absence of monovalent counterions, are compared with one another and with the experimental results. Good agreement between the two theoretical approaches is found, with less than 14% variance in the predicted extent of binding over a large range of mono- and divalent ion concentrations. While the predictions of both theoretical approaches generally agree with the experimental results, some discrepancies are noted and their possible origins discussed.     

Winding of the DNA helix by divalent metal ions.

When supercoiled pBR322 DNA was relaxed at 0 or 22 degrees C by topoisomerase I in the presence of the divalent cations Ca2+, Mn2+ or Co2+, the resulting distributions of topoisomers observed at 22 degrees C had positive supercoils, up to an average delta Lk value of +8.6 (for Ca2+at 0 degrees C), corresponding to an overwinding of the helix by 0.7 degrees/bp. An increase of the divalent cation concentration in the reaction mixture above 50 mM completely reversed the effect. When such ions were present in agarose electrophoresis gels, they caused a relaxation of positively supercoiled DNA molecules, and thus allowed a separation of strongly positively supercoiled topoisomers. The effect of divalent cations on DNA adds a useful tool for the study of DNA topoisomers, for the generation as well as separation of positively supercoiled DNA molecules.     

Avian sulfhydryl oxidase is not a metalloenzyme: adventitious binding of divalent metal ions to the enzyme

Metal- and flavin-dependent sulfhydryl oxidases catalyze the generation of disulfide bonds with reduction of oxygen to hydrogen peroxide. The mammalian skin enzyme has been reported to be copper-dependent, but a recent protein sequence shows it belongs to the Quiescin/sulfhydryl oxidase (QSOX) flavoprotein family. This work demonstrates that avian QSOX is not a metalloenzyme, and that copper and zinc ions inhibit the oxidation of reduced pancreatic ribonuclease by the enzyme. Studies with Zn(2+), as a redox inactive surrogate for copper, show that one Zn(2+) binds to four-electron-reduced QSOX by diverting electrons away from the flavin and into two of the three redox active disulfide bridges in the enzyme. The resulting zinc complex is modestly air-stable, reverting to a spectrum of the native protein with a t(1/2) of 40 min, whereas the four-electron-reduced native QSOX is reoxidized in less than a second under comparable conditions. Using tris(2-carboxyethyl)phosphine hydrochloride (TCEP), an alternate substrate of QSOX that binds Zn(2+) relatively weakly (unlike dithiothreitol), allows rapid inhibition of oxidase activity to be demonstrated at low micromolar metal levels. Zinc binding was followed by rapid-scanning spectrophotometry. Copper also binds the four-electron-reduced form of QSOX with a visible spectrum suggestive of active site occupancy. In addition to interactions with the reduced enzyme, dialysis experiments show that multiple copper and zinc ions can bind to the oxidized enzyme without the perturbation of the flavin spectrum seen earlier. These data suggest that a reinvestigation of the metal content of skin sulfhydryl oxidases is warranted. The redox-modulated binding of zinc to QSOX is considered in light of evidence for a role of zinc-thiolate interactions in redox signaling and zinc mobilization.     

Analytical solution of the Poisson-Boltzmann equation for membrane potential

Analytical solution of the one-dimensional Poisson-Boltzmann equation for membrane potential is obtained in an equilibrium state of the Nemst-Planck Poisson system. Approximations, e.g. constant field or Debye-Hückel approximation, need not be used. Two types of solution, arctangenthyperbolic and arccotangenthyperbolic, exist for every value of membrane potential.A new approximate solution is obtained where V and V_m are electric potential inside the membrane and membrane potential respectively; R, T and F have their usual thermodynamic meanings, κ is Debye constant, τ the membrane thickness. This approximate solution fits the numerical solution by Runge-Kutta method (maximum error being less than 5 × 10^?4) around the potential being 50 mV. The fitness is considerably more accurate than that of Debye-Huckel approximation (error being c. 15 % around the potential 50 mV.).     

Subsite specificity of divalent metal ions to glucosyltransferase

Glucosyltransferase from oral bacteria Streptococcus mutans is the most significant virulent factor in causing dental caries. The enzyme has two subsites. The binding specificity of divalent metal ions to glucosyl or fructosyl subsite was examined using multiple inhibition kinetics. The interaction factor "alpha" identifies whether the two subsites are exclusive or non-exclusive.     

Effect of divalent metal ions on annexin-mediated aggregation of asolectin liposomes

Annexins belong to a family of Ca2+- and phospholipid-binding proteins that can mediate the aggregation of granules and vesicles in the presence of Ca2+. We have studied the effects of different divalent metal ions on annexin-mediated aggregation of liposomes using annexins isolated from rabbit liver and large unilamellar vesicles prepared from soybean asolectin II-S. In the course of these studies, we have found that annexin-mediated aggregation of liposomes can be driven by various earth and transition metal ions other than Ca2+. The ability of metal ions to induce annexin-mediated aggregation decreases in the order: Cd2+ > Ba2+, Sr2+ > Ca2+ > Mn2+ > Ni2+ > Co2+. Annexin-mediated aggregation of vesicles is more selective to metal ions than the binding of annexins to membranes. We speculate that not every type of divalent metal ion can induce conformational change sufficient to promote the interaction of annexins either with two opposing membranes or with opposing protein molecules. Relative concentration ratios of metal ions in the intimate environment may be crucial for the functioning of annexins within specialized tissues and after treatment with toxic metal ions.     

Effect of divalent metal ions on collagenase from Clostridium histolyticum.

The collagenase from Clostridium histolyticum (EC 3.4.24.3) degrades type IV collagen with Km 32 nM, indicating a high affinity for this substrate. Ferrous and ferric ions can inhibit Clostridium collagenase. Inhibition by Fe++ was of the mixed, non-competitive type, with Ki 90 microM. The inhibitory effect of Fe++ may be due to Zn++ displacement from the intrinsic functional center of this metalloprotease, since in the presence of excess amounts of Zn++ enzyme activity is retained. This inhibitory effect of Fe++ may be common for all types of collagenases, since this ion can also inhibit type IV collagenase purified from Walker 256 carcinoma, with IC50 80 microM. Cu++ can only partially inhibit Clostridium collagenase, while other divalent metal ions such as Cd++, Co++, Hg++, Mg++, Ni++ or Zn++ are devoid of any inhibitory effect on the enzyme.     

Effect of divalent copper ions on heat denaturation of DNA

Using the thermal denaturation method the effect of bivalent copper of (4-10(-6)-10(-3)) M concentrations on the helix-coil transition of DNA was studied in the solution of Na+ concentrations 10(-3)-10(-1) M. Unlike the previous studies, this paper makes allowance for the effect of impurity ions present in DNA and deionized water. It has been shown that in the region of low Cu2+ and Na+ concentrations, thermal stability increases, the melting range extends and the denaturation curves become asymmetric. At concentrations more than approximately 3-10(-5) M Cu2+, melting temperature starts to fall, and the range reduces to 1-1.5 degrees at [Cu2+] greater than or equal to 2-10(-4) M. As [Cu2+] reaches these values, the denaturation curve asymmetry and melting range increase again, which is due to the inversion of the relative stability of AT- and GC-pairs. Employing experimental and phase-transition-theory data for homopolymers, the constants of Cu2+ binding with phosphates and DNA bases were calculated. The concentration dependence of the DNA denaturation parameters was shown to be governed by the superposition of binding Cu2+ with phosphates and nucleic acid bases.     

A study of the molecular mechanism of DNA interaction with divalent metal ions

The interaction of DNA with divalent metal ions: Ba2+, Mg2+, Mn2+, Ni2+, Cu2+ in solutions at different ionic strengths mu was investigated. The combination of following methods: flow birefringence, viscometry, UV-spectroscopy and circular dichroism made possible to follow the state of the secondary and tertiary structure of the DNA molecule during its interaction with ions. The presence of divalent ions in solution affects the hydrodynamic properties of DNA only at low mu. At high mu the difference in the action of mono- and divalent ions disappears. The persistence length of DNA does not change during the experiment. It is shown that the Mg2+ and Ba2+ ions interact only with phosphate groups of DNA but Mn2+, Ni2+, Cu2+ ions interact also with the nitrogen bases of the macromolecule.     

Effect of metal ions on binding of bilirubin to erythrocyte membranes

Binding of bilirubin to different erythrocyte membranes, namely, human, buffalo, sheep and goat, pre-incubated with different concentrations of metal ions was studied. The results showed that among the different metal ions used, Ca2+ had the highest potential in increasing the amount of bound bilirubin followed by Sr2+ and Mg2+, whereas Ba2+ had the lowest potential. Treatment of these membranes with Ca2+ led to an increase in the amount of bound bilirubin in all membranes. However, human erythrocyte membranes pretreated with Ca2+, bound the highest amount of bilirubin compared to other erythrocyte membranes. Increase in bilirubin binding upon Ca2+-treatment can be ascribed to shielding effect, redistribution of phospholipids as well as increase in surface hydrophobicity induced by Ca2+.     

Use of divalent metal ions in the DNA cleavage reaction of topoisomerase IV

It has long been known that type II topoisomerases require divalent metal ions in order to cleave DNA. Kinetic, mutagenesis and structural studies indicate that the eukaryotic enzymes utilize a novel variant of the canonical two-metal-ion mechanism to promote DNA scission. However, the role of metal ions in the cleavage reaction mediated by bacterial type II enzymes has been controversial. Therefore, to resolve this critical issue, this study characterized the DNA cleavage reaction of Escherichia coli topoisomerase IV. We utilized a series of divalent metal ions with varying thiophilicities in conjunction with oligonucleotides that replaced bridging and non-bridging oxygen atoms at (and near) the scissile bond with sulfur atoms. DNA scission was enhanced when thiophilic metal ions were used with substrates that contained bridging sulfur atoms. In addition, the metal-ion dependence of DNA cleavage was sigmoidal in nature, and rates and levels of DNA cleavage increased when metal ion mixtures were used in reactions. Based on these findings, we propose that topoisomerase IV cleaves DNA using a two-metal-ion mechanism in which one of the metal ions makes a critical interaction with the 3'-bridging atom of the scissile phosphate and facilitates DNA scission by the bacterial type II enzyme.     

Effect of divalent metal ions and glycerol on the GTPase activity of H-ras proteins

The product of the protooncogenic ras gene (p21N ras) exhibits a weak GTPase activity. A significant increase in the GTPase activity associated with p21N ras protein was obtained by using glycerol in the assay mixture. Of the several metal ions tested, only Mg++ and Mn++ are effective divalent cations that support the GTPase activity of p21N ras protein. p21N ras protein exhibits higher GTPase activity and yields higher [3H] GDP binding in the presence of MnCl2 than with MgCl2. Optimal GTPase and [3H] GDP binding are obtained at micromolar concentrations of MgCl2 or MnCl2. Concentrations in the millimolar range of either MgCl2 or MnCl2 are inhibitory to the GTPase activity, whereas [3H] GDP binding was not affected.