Iron(II)-ethylenediaminetetraacetic acid catalyzed cleavage of DNA is highly specific for duplex DNA

We show that iron(II)-EDTA-catalyzed cleavage of duplex DNA is much more rapid than cleavage of single-stranded DNA that does not form intramolecular base pairs. Comparisons of the extent of cleavage of the fully single-stranded oligonucleotides d(pT)70, d(pA)70, and d(pC)35 and the duplex DNA d(pT)70.d(pA)70 indicate that the extent of cleavage increases significantly upon formation of the duplex structure. These observations indicate that accessibility of the DNA sugars to the presumed cleaving agent, hydroxyl radical, is not the major determinant for cleavage and that most likely a direct interaction between Fe(II) and the DNA is required. As a result, the interpretation of DNA cleavage experiments performed with this reagent to obtain detailed structural information should be pursued with caution until the mechanism of the cleavage reaction is better understood.     

Iron(II)-ethylenediaminetetraacetic acid catalyzed cleavage of RNA and DNA oligonucleotides: similar reactivity toward single- and double-stranded forms

Fe(II)-EDTA catalyzes the cleavage of nucleic acids with little or no base-sequence specificity. We have now studied the preference of this reagent in catalyzing the cleavage of single- versus double-stranded nucleic acid structures. Three RNA and two DNA molecules, each expected to contain both single- and double-stranded regions, were synthesized and their structures characterized by enzymatic digestion using secondary structure specific nucleases. Fe(II)-EDTA catalyzed nearly uniform strand scission along the entire length of each molecule; no correlation with secondary structure was observed. The homopolymer sequence dA30:dT30, embedded in a mixed-sequence context to promote exact register of the homopolymer tract, was cleaved to an extent similar to that of flanking sequences. The reactions were relatively insensitive to K+, Na+, and Mg2+ in the range 10-100 mM and were quenched by Tris-HCl buffer. We conclude that the Fe(II)-EDTA-catalyzed strand scission reaction does not discriminate between typical single- and double-stranded regions, which simplifies the interpretation of experiments in which the reaction is used to probe the tertiary structure of RNA molecules [Latham, J. A., & Cech, T. R. (1989) Science 245, 276-282].     

Hydrolytic cleavage of DNA by quercetin zinc(II) complex

Quercetin zinc(II) complex was investigated focusing on its hydrolytic activity toward DNA. The complex successfully promotes the cleavage of plasmid DNA, producing single and double DNA strand breaks. The amount of conversion of supercoiled form (SC) of plasmid to the nicked circular form (NC) depends on the concentration of the complex as well as the duration of incubation of the complex with DNA. The rate of conversion of SC to NC is 1.68x10(-4) s(-1) at pH 7.2 in the presence of 100 microM of the complex. The hydrolytic cleavage of DNA by the complex is supported by the evidence from free radical quenching, thiobarbituric acid-reactive substances (TBARS) assay, and T4 ligase ligation.     

Charge dependence of Fe(II)-catalyzed DNA cleavage.

The effect of charge of the Fe(II) reagent used to induce DNA strand cleavage reactions in the presence of a source of reducing equivalents is investigated using two oligonucleotide models. The first consists of the two strands dA20 and dT20, and an equimolar complex between them. The second is a short four-arm branched DNA complex composed of four 16-mer strands. In the former case, cleavage of the 1:1 complex by three reagents with different formal charge, Fe(II).EDTA2-, Fe(II).EDDA and Fe2+, is comparable in rate to that of the individual dT20 and the dA20 strands. While the three reagents show similar cleavage rates for the duplex and single stranded molecules, they give distinctive cutting patterns in the DNA tetramer, consistent with the presence of a site of excess negative charge at the branch point. Scission induced by Fe(II).EDTA2- shows lower reactivity at the branch site relative to duplex controls, whereas Fe(II)2+ shows enhanced reactivity. Formally neutral Fe(II).EDDA shows weak loss of cutting reactivity at the branch. The position of attack by Fe(II)2+ in the branched tetramer is shifted with respect to those of Fe(II).EDTA2- or Fe(II).EDDA; a slower migrating species is also detected in the scission of dA20.dT20 duplex by Fe(II) reaction. These results suggest that the Fe(II)2+ reaction proceeds by a different mechanism from the other agents. The difference in cutting profiles induced by the neutral and negatively charged chelated complexes is consistent with a local electrostatic repulsion of a negatively charged source of radicals, not a positively charged one.     

Oxidative cleavage of DNA by tridentate copper (II) complex

Copper (II) complex 1 having planar tridentate ligand, bzimpy, where bzimpy is 2,6-bis(benzimidazo-2-yl) pyridine was synthesized and characterized by UV-visible, FAB (fast atom bombardment) mass and infrared spectroscopy. From absorption titration data, the binding constant of Cu(II) with DNA was calculated to be (1.8+/-0.02)x10(4) M(-1). Thermal denaturation study of DNA with 1 revealed deltaT(m) of 5+/-0.5 degrees C. Viscosity measurement showed that complex binds with DNA through intercalative mode. Copper (II) complex induces cleavage in plasmid DNA in the presence of coreductants such as ascorbic acid or glutathione.     

Enantioselective cleavage of supercoiled plasmid DNA catalyzed by chiral macrocyclic lanthanide(III) complexes

The enantiomers of the Sm (III), Eu (III) and Yb (III) complexes [LnL(NO₃)₂](NO₃) of a chiral hexaazamacrocycle were tested as catalysts for the hydrolytic cleavage of supercoiled plasmid DNA. The catalytic activity was remarkably enantioselective; while the [LnL^SSSS(NO₃)₂](NO₃) enantiomers promoted the cleavage of plasmid pBR322 from the supercoiled form (SC) to the nicked form (NC), the [LnL^RRRR(NO₃)₂](NO₃) enantiomers were inactive. Kinetics of plasmid DNA hydrolysis was also investigated by agarose electrophoresis and it indicated typical single-exponential cleavage reaction. The hydrolytic mechanism of DNA cleavage was confirmed by the successful ligation of hydrolysis product by T4 ligase. The NMR study of the solutions of the complexes in various buffers indicated that the complexes exist as monomeric cationic complexes [LnL(H₂O)₃]^3 + in slightly acidic solutions and as dimeric cationic complexes [Ln₂L₂(μ-OH)₂(H₂O)₂]^4 + in slightly basic 8 mM solutions, with the latter form being a possible catalyst for hydrolysis of phosphodiester bonds.     

DNA conformational changes and cleavage by ruthenium(II) nitrofurylsemicarbazone complexes

Metal complexes that establish interactions with DNA are being studied not only because of their potential use as therapeutic agents but also as tools for biochemistry and molecular biology. Searching for drugs with anti-trypanosome activity, we previously synthesized a series of ruthenium mixed ligand dimethyl sulfoxide complexes of the type [Ru(II)Cl(2)(DMSO)(2)L], where L is 5-nitrofurylsemicarbazone derivatives and DMSO is dimethyl sulfoxide. Though they present the ability to bind DNA, no activity against parasites in cell culture was observed. Considering their potential application as molecular tools we further analyzed the interactions with DNA through an electrophoretic approach. Non covalent withdrawal of superhelicity and a rapid nicking activity upon covalent interaction was observed. Inhibition of both effects was observed in the presence of distamycin suggesting the involvement of the DNA minor groove in the interaction with the nitrofurylsemicarbazone ruthenium complexes. In addition cleavage inhibition by dimethyl sulfoxide suggests an oxidative mechanism of action.     

DNA cleavage by novel copper (II) complex and the role of beta-cyclodextrin in promoting cleavage

A new cyclen derivative N-1-naphthyl-[4-amino-5-oxo-5-(1,4,7,10-tetraazacyclododecan-1-yl)]valeramide and the copper (II) complex were synthesized and characterized. The copper (II) complex showed DNA cleavage ability without the existence of other additives. The pUC19 plasmid DNA was cleaved to linear form by 0.71 microM of complex under physiological conditions. beta-Cyclodextrin was used to investigate the relationship of nuclease activity and DNA binding ability. The addition of beta-cyclodextrin exhibited an unexpected ability to promote the cleavage of DNA. The role of the beta-cyclodextrin in DNA cleavage process was studied by (1)H NMR and fluorescence spectrum. According to the data of viscosity measurement, it was confirmed that the binding of complex with DNA should be a groove binding model. All the results suggested that the increasing of the DNA cleavage ability was attributed to the interaction between beta-cyclodextrin and the naphthyl moieties. beta-Cyclodextrin could include the naphthyl moieties and keep it from the minor/major groove of DNA and decreased the DNA binding ability, therefore, the copper (II) center was activated to generate more reactive oxygen species, which was responsible for DNA cleavage.     

Photosensitive DNA cleavage and phage inactivation by copper(II)-camptothecin

Upon irradiation with 365-nm light, copper(II)-camptothecin significantly produced single- and double-strand breaks of DNA and also induced a marked inactivation of bacteriophage. The nucleotide sequence analysis exhibited considerably random DNA cleavage. The DNA strand scission by the camptothecin-Cu(II)-UV light system, as well as the phage inactivation, was strongly suppressed by bathocuproine and catalase, indicating participation of cuprous species and hydrogen peroxide in the reaction. The present results suggest that (1) Cu(II) ion may play an important role as a cofactor in antitumor action of camptothecin and (2) the combination of copper-camptothecin plus long-wave ultraviolet light is useful against certain cancer treatment as a new photochemotherapy.     

Methidiumpropyl-EDTA-iron(II) cleavage of ribosomal DNA chromatin from Dictyostelium discoideum.

We have used methidiumpropyl-EDTA-iron(II) [MPE.Fe(II)] in parallel with micrococcal nuclease to investigate the chromatin structure of the extrachromosomal palindrome ribosomal RNA genes of Dictyostelium. Confirming our earlier results with micrococcal nuclease (1,2), MPE.Fe(II) digested the coding region of rapidly transcribing rRNA genes as a smear, indicating the absence or severe disruption of nucleosomes, whereas in slowly transcribing rRNA genes, a nucleosomal ladder was produced. In the central non-transcribed spacer region of the palindrome, MPE.Fe(II) digestion resulted in a normal nucleosomal repeat, whereas micrococcal nuclease gave a complex banding pattern. The difference is attributed to the lower sequence specificity of MPE.Fe(II) compared to micrococcal nuclease. In the terminal region of the palindrome, however, both substances gave a complex chromatin digestion pattern. In this region the DNA appears to be packaged in structures strongly positioned with respect to the underlying DNA sequence.     

Novel peptide-based copper(II) complexes for total hydrolytic cleavage of DNA

Stable Cu(II) complexes with histamine- and histidine-containing dipeptides histidylserine and histidylphenylalanine have been developed. Their interaction in solution has been investigated, and the stability of their complexes was determined. The nature of binding in these complexes has been explained with the help of potentiometric pH titrations and 1H-NMR spectroscopy. The geometry of these complexes has been established by electronic spectra. The DNA-binding and -cleavage abilities of these Cu(II) complexes have been probed by the absorption, thermal denaturation, fluorescence, and electrophoresis experiments. The results suggest that these peptide-based Cu(II) complexes effectively bind and efficiently cleave DNA under mild biological conditions. Since Cu(II) complexes are known to play an important role in phosphodiester bond cleavages, these results assume importance.     

DNA cleavage by homo- and heterotetranuclear Cu(II) and Mn(II) complexes with tetrathioether-tetrathiol moiety

Novel homotetranuclear Cu(II) and heteronuclear Cu(II)-Mn(II) complexes with tetrathioether-tetrathiol moiety have been prepared and their DNA relaxation activities with plasmid pCYTEXP (5kb) were electrophoretically established. The cleavage products analyzed by neutral agarose gel electrophoresis indicated that the interaction of the metal complexes with supercoiled plasmid DNA yielded linear, nicked or degraded DNA. The relaxation activities of both homo- and heterotetranuclear (SK4) complexes are time- and concentration-dependent. The findings suggest that SK4 with potent nucleolytic activity is a good nuclease substitute in the presence of cooxidant. Furthermore, the observation of induction of DNA into smaller fragments by SK4 is also significant.     

Mechanism of DNA cleavage catalyzed by Mung Bean Nuclease

The interaction of zinc with different forms of DNA (λ phage DNA, ss-oligo, ds-oligo) and Mung Bean Nuclease was studied by voltammetric techniques in order to investigate the mechanism of DNA cleavage catalyzed by a zinc metalloenzyme. Stoichiometry, dissociation constant, zinc binding sites and functions were determined for these systems. Two zinc ions were found to be involved in stabilization of a 19 mer ds-oligodeoxyribonucleotide, which was synthesized by the phosphoramidite method and used as a DNA model in the studies. Three zinc ions (Zn1, Zn2, and Zn3), which have different roles in ds-oligo cleavage, were identified in the active site of Mung Bean Nuclease. A concerted S_N2 mechanism, which assigns a catalytic function to Zn2 and structural functions to Zn1 and Zn3, was proposed. The hydrolysis of phosphodiester bonds proceeds with inversion of configuration at the phosphorus center, forming a pentacoordinate transition state, which is stabilized by an arginine. Zn2 supplies the nucleophile, which is oriented by an aspartic acid, and activates the ds-oligo by its coordination to the phosphate free oxygen of the phosphodiester bond. Zn1 and Zn3 ions, besides stabilizing the tertiary structure of Mung Bean Nuclease, bind to the leaving group, blocking the cleavage reverse reaction.     

Ultrasonic cleavage of DNA in complexes with Ag(I), Cu(II), Hg(II)

We investigated a phenomenon of ultrasonic cleavage of DNA complexed with transition metal cations Ag(I), Cu(II) and Hg(II). We found the statistically significant dependence of relative intensity of cleavage on cation type and concentration. Each cation may cause two different types of distortion in the DNA double-helix depending on whether it binds to major or minor DNA groove. The intensity of ultrasonic cleavage decreases where the cation binds to the major DNA groove; the intensity of cleavage increases where the cation binds to the minor DNA groove and disturbs the hydrogen bonds of complementary base pairs or where it intercalates between bases. Both types of DNA distortion can affect the intensity of N?S intercon-version of deoxyribose.     

Oxidative DNA cleavage by Schiff base tetraazamacrocyclic oxamido nickel(II) complexes

Nickel is considered a weak carcinogen. Some researches have shown that bound proteins or synthetic ligands may increase the toxic effect of nickel ions. A systematic study of ligand effects on the interaction between nickel complexes and DNA is necessary. Here, we compared the interactions between DNA and six closely related Schiff base tetraazamacrocyclic oxamido nickel(II) complexes NiL(1-3a,1-3b). The structure of one of the six complexes, NiL(3b) has been characterized by single crystal X-ray analysis. All of the complexes can cleave plasmid DNA under physiological conditions in the presence of H(2)O(2). NiL(3b) shows the highest DNA cleavage activity. It can convert supercoiled DNA to nicked DNA then linear DNA in a sequential manner as the complex concentration or reaction time is increased. The cleavage reaction is a typical pseudo-first-order consecutive reaction with the rate constants of 3.27+/-0.14h(-1) (k(1)) and 0.0966+/-0.0042h(-1) (k(2)), respectively, when a complex concentration of 0.6mM is used. The cleavage mechanism between the complex and plasmid DNA is likely to involve hydroxyl radicals as reactive oxygen species. Circular dichronism (CD), fluorescence spectroscopy and gel electrophoresis indicate that the complexes bind to DNA by partial intercalative and groove binding modes, but these binding interactions are not the dominant factor in determining the DNA cleavage abilities of the complexes.     

New unsymmetric dinuclear Cu(II)Cu(II) complexes and their relevance to copper(II) containing metalloenzymes and DNA cleavage

The new homodinuclear complexes, [Cu(2)(II)(HLdtb)(mu-OCH(3))](ClO(4))(2) (1) and [Cu(2)(II)(Ldtb)(mu-OCH(3))](BPh(4)) (2), with the unsymmetrical N(5)O(2) donor ligand (H(2)Ldtb) - {2-[N,N-Bis(2-pyridylmethyl)aminomethyl]-6-[N',N'-(3,5-di-tert-butylbenzyl-2-hydroxy)(2-pyridylmethyl)]aminomethyl}-4-methylphenol have been synthesized and characterized in the solid state by X-ray crystallography.In both cases the structure reveals that the complexes have a common {Cu(II)(mu-phenoxo)(mu-OCH(3))Cu(II)} structural unit.Magnetic susceptibility studies of 1 and 2 reveal J values of -38.3 cm(-1) and -2.02 cm(-1), respectively, and that the degree of antiferromagnetic coupling is strongly dependent on the coordination geometries of the copper centers within the dinuclear {Cu(II)(mu-OCH(3))(mu-phenolate)Cu(II)} structural unit.Solution studies in dichloromethane, using UV-Visible spectroscopy and electrochemistry, indicate that under these experimental conditions the first coordination spheres of the Cu(II) centers are maintained as observed in the solid state structures, and that both forms can be brought into equilibrium ([Cu(2)(HLdtb)(mu-OCH(3))](2+)=[Cu(2)(Ldtb)(mu-OCH(3))](+)+H(+)) by adjusting the pH with Et(3)N (Ldtb(2-) is the deprotonated form of the ligand).On the other hand, potentiometric titration studies of 1 in an ethanol/water mixture (70:30 V/V; I=0.1M KCl) show three titrable protons, indicating the dissociation of the bridging CH(3)O(-) group.The catecholase activity of 1 and 2 in methanol/water buffer (30:1 V/V) demonstrates that the deprotonated form is the active species in the oxidation of 3,5-di-tert-butylcatechol and that the reaction follows Michaelis-Menten behavior with k(cat)=5.33 x 10(-3)s(-1) and K(M)=3.96 x 10(-3)M. Interestingly, 2 can be electrochemically oxidized with E(1/2)=0.27 V vs.Fc(+)/Fc (Fc(+)/Fc is the redox pair ferrocinium/ferrocene), a redox potential which is believed to be related to the formation of a phenoxyl radical.Since these complexes are redox active species, we analyzed their activity toward the nucleic acid DNA, a macromolecule prone to oxidative damage.Interestingly these complexes promoted DNA cleavage following an oxygen dependent pathway.     

Oxidative cleavage of DNA by homo- and heteronuclear Cu(II)-Mn(II) complexes of an oxime-type ligand

Novel homodinuclear Cu(II) (K1), heterodinuclear Cu(II)-Mn(II) (K2) and homotrinuclear Cu(II) (K3) complexes with a novel oxime-type ligand have been prepared and their nucleolytic activities on pCYTEXP were established by neutral agarose gel electrophoresis. The analyses of the cleavage products obtained electrophoretically indicate that although the examined complexes induces very similar conformational changes on supercoiled DNA by converting supercoiled form to nicked form than linear form in a sequential manner as the complex concentration or reaction period is increased, K3 is less effective than the two others. The oxime complexes were nucleolytically active at physiological pH values but the activities of K1 or K2 were diminished by increasing the pH of the reaction mixture. In contrast, K3 makes dominantly single strand nicking by producing nicked circles on DNA at almost all the applied pH values. Metal complex induced DNA cleavage was also tested for inhibition by various radical scavengers as superoxide dismutase (SOD), azide, thiourea and potassium iodide. The antioxidants inhibited the nucleolytic acitivities of the oxime complexes but SOD afforded no protection indicating that the nucleolytic mechanism involves of copper and/or manganese complex-mediated reactive oxygen species such as hydroxyl radicals being responsible for the oxidative DNA cleavage.     

Chemical cleavage of plasmid DNA by Cu(II), Ni(II) and Co(III) desferal complexes.

It is demonstrated that the Cu(II), Co(III) and Ni(II) complexes of a siderophore chelating drug desferal cleave DNA, in contrast to the corresponding Fe(II) complex which does not bring about DNA scission. Hydroxy radical scavengers inhibit the cleavage reaction.     

DNA binding, DNA cleavage, and cytotoxicity studies of two new copper (II) complexes

The DNA binding behavior of [Cu(phen)(phen-dione)Cl]Cl (1) and [Cu(bpy)(phen-dione)Cl]Cl (2) was studied with a series of techniques including UV-vis absorption, circular dichroism spectroscopy, and viscometric methods. Cytotoxicity effect and DNA unwinding properties were also investigated. The results indicate that the Cu(II) complexes interact with calf-thymus DNA by both partially intercalative and hydrogen binding. These findings have been further substantiated by the determination of intrinsic binding constants spectrophotometrically, 12.5?×?10(5) and 5?×?10(5) for 1 and 2, respectively. Our findings suggest that the type of ligands and structure of complexes have marked effect on the binding affinity of complexes involving CT-DNA. Circular dichroism results show that complex 1 causes considerable increase in base stacking of DNA, whereas 2 decreases the base stacking, which is related to more extended aromatic area of 1,10-phenanthroline in 1 rather than bipyridine in 2. Slow decrease in DNA viscosity indicates partially intercalative binding in addition to hydrogen binding on the surface of DNA. The second binding mode was also confirmed by additional tests: interaction in denaturation condition and acidic pH. Also, these new complexes induced cleavage in pUC18 plasmid DNA as indicated in gel electrophoresis and showed excellent antitumor activity against K562 (human chronic myeloid leukemia) cells.     

DNA binding behaviors and cleavage properties of a Ru(II) polypyridyl complex

A novel complex, [Ru(phen)₂pzip]²⁺1 (phen = 1,10-phenanthroline; pzip = 2-(pyrazine-2-yl)imidazo-[4,5-f][1,10]phenanthroline]), has been synthesized and characterized by elemental analysis, ES-MS, ¹H NMR. The DNA-binding behaviors of this complex were studied by spectroscopic methods and viscosity measurements. The results indicate that the complex can bind to CT-DNA in an intercalative mode. When irradiated at 365 nm, complex 1 can promote the cleavage of plasmid pBR322DNA. Furthermore, Zn²⁺ can trigger the DNA cleavage of complex 1 without irradiation. The mechanism studies revealed that the DNA cleavage by complex 1 in the presence of Zn²⁺ is likely to proceed via a hydrolytic cleavage process.