Structural organization of copper(II) ions in complexes with DNA

The interaction of Cu(II) ions with native and denatured DNA as a function of ionic strength of the solution was studied by the equilibrium dialysis method. Graphical analysis of binding isotherms confirmed the occurrence of interstrand and intrastrand binding of Cu(II) with DNA and made possible determination of the respective binding constants. To facilitate interpretation of the data, a new molecular model of Cu(II)-DNA binding has been proposed, assuming interstrand intercalation of one Cu(II) ion between two GC pairs both in the successive even and odd groups of GC pairs, and interstrand binding of Cu(II) to the isolated GC pairs, with the exception of T-C-T and T-G-T sequences. In agreement with this model, the DNA-Cu(II) complex is most stable under the equilibrium with free Cu(II) ions at 4 degrees C, pH 6 when the molar ratio of GC pairs to Cu(II) ions bound interstrandially attains GC/Cuinter = 2 +/- 0.1.     

Mixed-ligand copper(II)-phenanthroline-dipeptide complexes: synthesis, characterization, and DNA-cleavage properties

The mixed-ligand complexes [Cu(II)(HisLeu)(phen)](+) (1) and [Cu(II)(HisSer)(phen)](+) (2; phen=1,10-phenanthroline) were synthesized and characterized. The intercalative interaction of the Cu(II) complexes with calf-thymus DNA (CT-DNA) was probed by UV/VIS and fluorescence titration, as well as by thermal-denaturation experiments, and the intrinsic binding constants (K(b)) for the complexes with 1 and 2 were 4.2x10(3) and 4.9x10(3) M(-1), resp. Both complexes were found to be efficient catalysts for the hydrolytic cleavage of plasmid pUC19 DNA, as tested by gel electrophoresis, converting the DNA from the supercoiled to the nicked-circular form at rate constants of 1.32 and 1.40 h(-1) for 1 and 2, resp.     

Study of copper(II) ternary complexes with phosphocreatine and some polyamines in aqueous solution

Ternary systems of Cu(II) with phosphocreatine (PCr) and the polyamines (PAs), ethylenediamine (en), 1,3-diaminopropane (tn), putrescine (Put), spermidine (Spd), and spermine (Spm), were investigated in aqueous solution through potentiometry, ultraviolet-visible, EPR and Raman spectroscopy. The binary complex CuPCr was also studied by Raman spectroscopy, and the calculation of the minimum stabilization energy was done assuming this molecule in aqueous solution. The stability constants of the CuPCrPA ternary complexes were determined by potentiometry (T = 25 °C, I = 0.1 mol L^− 1, KNO₃). The stability order determined was CuPCrSpm > CuPCrSpd > CuPCren > CuPCrtn > CuPCrPut, the same order of the corresponding binary complexes of Cu(II) with these polyamines. The evaluation of intramolecular PA-PCr interactions in protonated and deprotonated species of ternary complexes was carried out using the equation Δlog K = log β_{CuPCrPAHq + p} − (log β_CuPAHq + log β_CuPCrHp). All of the CuPCrPA ternary complexes have a square planar structure and are bonded to PCr through the nitrogen atom of the guanidine group and the oxygen atom of the phosphate group, and to the PAs through two nitrogen atoms of the amine groups. The structure of the complex CuPCrSpm is planar with distortion towards tetrahedral. Calculation of the minimum stabilization energy for the CuPCr and CuPCrenH complexes confirmed the proposed coordination mode.     

The interaction of metal ions with nucleic acids. Ternary complexes of copper(II) with peptides and nucleosides

Difference electronic absorption and electron paramagnetic resonance spectroscopy were used to monitor the formation of the ternary complexes of Cu(II) ions with nucleosides and dipeptides containing Gly, Leu and Trp residues. Stability constants of these mixed-ligand complexes of Cu(II)-peptides with nucleosides were found to decrease in the following order: 6-ketopurines greater than 6-aminopurine greater than pyrimidines. Interpretation of the EPR data indicated that the covalent nature of the copper-ligand bond also decreases in the same order. The EPR findings suggest that nucleosides are bonded in the equatorial position of the Cu(II)-peptide complexes, however, in the case of pyrimidine nucleosides weak axial bonding also seems to occur.     

Thermodynamics and kinetics of the interaction of copper (II) ions with native DNA.

Based on equilibrium binding studies, as well as on kinetic investigations, two types of interactions of Cu²⁺ ions with native DNA at low ionic strength could be characterized, namely, a nondenaturing and a denaturing complex formation. During a fast nondenaturing complex formation at low relative ligand concentrations and at low temperatures, different binding sites at the DNA bases become occupied by the metal ions. This type of interaction includes chelate formation of Cu²⁺ ions with atoms N₍₇₎ of purine bases and the oxygens of the corresponding phosphate groups, chelation between atoms N₍₇₎ and O of C₍₆₎ of the guanine bases, as well as the formation of specific intestrand crosslink complexes at adjacent G°C pairs of the sequence dGpC. CD spectra of the resulting nondenatured complex (DNA–Cu²⁺)_nat may be interpreted in terms of a conformational change of DNA from the B-form to a C-like form on ligand binding. A slow cooperative denaturing complex formation occurs at increased copper concentrations and/or at increased temperatures. The uv absorption and CD spectra of the resulting complex, (DNA–Cu²⁺)_denat, indicate DNA denaturation during this type of interaction. Such a conclusion is confirmed by microcalorimetric measurements, which show that the reaction consumes nearly the same amount of heat as acid denaturation of DNA. From these and the kinetic results, the following mechanism for the denaturing action of the ligands is suggested: binding of Cu²⁺ ions to atoms N₍₃₎ of the cytosine bases takes place when the cytosines come to the outside of the double helix as a result of statistical fluctuations. After the completion of the binding process, the bases cannot return to their initial positions, and thus local denaturation at the G·C pairs is brought about. The probability of the necessary fluctuations occurring is increased by chelation of Cu²⁺ ions between atoms N₍₇₎ and O of C₍₆₎ of the guanine bases during nondenaturing complex formation, which loosens one of the hydrogen bonds within the G·C pairs, as well as by raising the temperature. The implications of the new binding model, which comprises both the sequence-specific interstand crosslinks and the described mechanism of denaturing complex formation, are discussed and some predictions are made. The model is also used to explain the different renaturation properties of the denatured complexes of Cu²⁺, Cd²⁺, and Zn²⁺ ions with DNA. In temperature-jump experiments with the nondenatured complex (DNA–Cu²⁺)_nat, a specific kinetic effect is observed, namely, the appearance of a lag in the response to the perturbation. The resulting sigmoidal shape of the kinetic curves is considered to be a consequence of the necessity of disrupting a certain number of the crosslinks existing in the nondenatured complex before the local unwinding of the binding regions (a main step of denaturing complex formation) may proceed.     

DNA interaction of new copper(II) complexes with sulfonamides as ligands

New copper(II) complexes with sulfonamide ligands have been prepared and characterized. Sulfonamide ligands were prepared through a reaction between 8-aminoquinoline and either 2-mesitylene (Hqmesa), 4-tert-butylbenzene (Hqtbsa), or alpha-toluene (Halphaqtsa) sulfonyl chlorides. The structural analysis carried out for complex [Cu(alphaqtsa)(2)] indicated that the local environment of the Cu(II) cation is between a square planar and a tetrahedral geometry, with stacking of the benzene rings of the sulfonyl ligands between neighbor molecules. Powder EPR spectra at room temperature gave rhombic spectra for the [Cu(alphaqtsa)(2)] and [Cu(qmesa)(2)] complexes and an axial spectrum for the [Cu(qtbsa)(2)] complex, probably due to the steric hindrance of the methyl groups. Complexes [Cu(alphaqtsa)(2)] and [Cu(qmesa)(2)] are artificial chemical nucleases that degrade DNA in the presence of sodium ascorbate. A study of the radical scavengers revealed that the ROS (reactive oxygen species) involved in the DNA damage were hydroxyl, singlet oxygen-like species, and superoxide anion.     

Biological significance of cimetidine sulfoxide complexes with copper(II) and zinc(II) ions during cimetidine treatment

Following a recent investigation into cimetidine interactions with copper(II) and zinc(II), the present work deals with the study of coordination equilibria relative to the main metabolite of this drug, i.e. cimetidine sulfoxide, with the same metal ions under physiological conditions.Computer simulations were run on the basis of the corresponding complex stability constants, in order to assess the extent to which cimetidine sulfoxide may affect copper(II) and zinc(II) plasma distributions during long term cimetidine therapy.No significant effect of this kind can be expected from cimetidine sulfoxide for plasma concentrations corresponding to usual therapeutic levels of the patent molecule, even for patients presenting with impaired renal function.     

Spectroscopic studies on the anticancer antibiotic Altromycin H and the interaction with copper(II) ions

The antitumor antibiotic Altromycin H was studied using electronic absorption (UV-Vis.) and circular dichroism (CD) spectroscopy. The dissociation constants of the phenolic groups on C(5) and C(11) were estimated as pK(1)=6.7 and pK(2)=11.8 at 25 degrees C, respectively, and a complete assignment of the CD and UV-Vis. bands is proposed. The interaction of Cu(II) ions with the Altromycin H has been also investigated by UV-Vis., CD and electron paramagnetic resonance (EPR) spectroscopy. A pH depended stepwise complex formation was observed. At pH<4 no copper-Altromycin H interactions were detected. At the 4相似文献   

LHRH interaction with Zn(II) ions

Luteinizing hormone-releasing hormone (LHRH), a hypothalamic neurohormone, forms a complex with Zn ions in solution. In order to explain the structure of this complex, the stability constants of Zn(II) complexes of LHRH and also pyroglutamyl-histidine-methylester, N-acetyl-histamine, and N-acetyl-histidine were established with the use of potentiometric technique. The nuclear magnetic resonance spectroscopy shows that the mode of coordination of Zn(II) to LHRH consists of binding to the imidazole nitrogen and the peptide oxygen of the His-Trp bond.     

Mechanistic flexibility in the reduction of copper(II) complexes of aliphatic polyamines by mercapto amino acids

The reactions of copper(II)-aliphatic polyamine complexes with cysteine, cysteine methyl ester, penicillamine, and glutathione have been investigated, with the goal of understanding the relationship between RS- -Cu(II) adduct structure and preferred redox decay pathway. Considerable mechanistic flexibility exists within this class of mercapto amino acid oxidations, as changes in the rate law could be induced by modest variations in reductant concentration (at fixed [Cu(II)]0), pH, and the structure of the redox partners. With excess cysteine present at 25 degrees C, pH 5.0, I = 0.2 M (NaOAc), decay of 1:1 cys-S- -Cu(II) transient adducts was found to be first order in both cys-SH and transient. Second-order rate constants characteristic of Cu(dien)2+(6.1 X 10(3) M-1 sec-1), Cu(Me5dien)2+ (2.7 X 10(3) M-1 sec-1), Cu(en)22+ (2.1 X 10(3) M-1 sec-1), and Cu(dien)22+ (4.7 X 10(3) M-1 sec-1) are remarkably similar, considering substantial differences in the composition and geometry of the oxidant first coordination sphere. A mechanism involving attack of cysteine on the coordinated sulfur atom of the transient, giving a disulfide anion radical intermediate, is proposed to account for these results. Moderate reactivity decreases in the cysteine-Cu(dien)2+, Cu(Me5dien)2+ reactions with increasing [H+] (pH 4-6) reflect partial protonation of the polyamine ligands. A very different rate law, second order in the RS- -Cu(II) transient and approximately zeroth order in mercaptan, applies in the pH 5.0 oxidations of cysteine methyl ester, penicillamine, and glutathione by Cu(dien)2+ and Cu(Me5dien)2+. This behavior suggests the intermediacy of di-mu-mercapto-bridged binuclear Cu(II) species, in which a concerted two-electron change yields the disulfide and Cu(I) products. Similar hydroxo-bridged intermediates are proposed to account for the transition from first- to second-order transient dependence in cysteine oxidations by Cu(dien)2+ and Cu(Me5dien)2+ as the pH is increased from 5 to 7. Yet another rate law, second order in transient and first order in cysteine, applies in the pH 5.0 oxidation of cysteine by Cu(Me6tren)2+ (k(25 degrees C) 7.5 X 10(7) M-2 sec-1, I = 0.2M). Steric rigidity of this trigonal bipyramidal oxidant evidently protects the coordinated sulfur atom from attack in a RSSR- -forming pathway. Formation of a coordinated disulfide in the rate-determining step is proposed, coupled with attack of a noncoordinated cysteine molecule on a vacated coordination position to stabilize the (Me6tren)Cu(I) product.     

Mechanistic flexibility in the reduction of copper(II) complexes of aliphatic polyamines by mercapto amino acids

The reactions of copper(II)-ahphatic polyamine complexes with cysteine, cysteine methyl ester, penicillamine. and glutathione have been investigated, with the goal of understanding the relationship between RS^?-Cu(II) adduct structure and preferred redox decay pathway. Considerable mechanistic flexibility exists within this class of mercapto ammo acid oxidations, as changes in the rate law could be induced by modest variations in reductant concentration (at fixed [Cu(II)]_o), pH, and the structure of the redox partners. With excess cysteine present at 25°C, pH 5 0, I = 0 2 M (NaOAc), decay of 1:1 cys-S^?-Cu(II) transient adducts was found to be first order in both cys-SH and transient. Second-order rate constants characteristic of Cu(dien)²⁺ (6 1 × 10³M^?1sec^?1), Cu(Me₅dien)²⁺ (2.7 × 10³M^?1 sec^?1), Cu(en)₂²⁺ (2.1 × 10³M^?1 sec^?1), and Cu(dien)₂²⁺ (4.7 × 10³ M^?1 sec ^?1) are remarkably similar, considering substantial differences in the composition and geometry of the oxidant first coordination sphere. A mechanism involving attack of cysteine on the coordinated sulfur atom of the transient, giving a disulfide anion radical intermediate, is proposed to account for these results Moderate reactivity decreases in the cysteine-Cu(dien)²⁺, Cu(Me₅dien)²⁺ reactions with increasing [H⁺] (pH 4–6) reflect partial protonation of the polyamine ligands. A very different rate law, second order in the RS^?-Cu(II) transient and approximately zeroth order in mercaptan, applies in the pH 5.0 oxidations of cysteine methyl ester, penicillamine, and glutathione by Cu(dien)²⁺ and Cu(Me₅dien)²⁺. This behavior suggests the mtermediacy of di-μ-mercapto-bridged binuclear Cu(II) species, in which a concerted two-electron change yields the disulfide and Cu(I) products. Similar hydroxo-bridged intermediates are proposed to account for the transition from first- to second-order transient dependence in cysteine oxidations by Cu(dien)²⁺ and Cu(Me₅dien)²⁺ as the pH is increased from 5 to 7. Yet another rate law, second order in transient and first order in cysteine, applies in the pH 5.0 oxidation of cysteine by Cu(Me₆tren)²⁺ (k(25°C) 7.5 × 10⁷ M^?2 sec^?1, I = 0.2 M). Steric rigidity of this trigonal bipyramidal oxidant evidently protects the coordinated sulfur atom from attack in a RSSR^?-forming pathway. Formation of a coordinated disulfide in the rate-determining step is purposed, coupled with attack of a noncoordinated cysteine molecule on a vacated coordination position to stabilize the (Me₆(tren)Cu(I) product.     

Metal--glutathione interaction in aqueous solution. Nickel(II), cobalt(II) and copper(II) complexes with oxidized glutathione.

The interaction of copper(II), nickel(II) and cobalt(II) ions with oxidized glutathione in aqueous solutions have been examined by spectroscopic methods. Cu(II) is the only ion which interacts with disulphide bridge and forms dimeric species containing the Cu(II)-S-S-Cu(II) unit. Ni(II) and Co(II) bind mainly with the terminal NH2 and COO- groups of glutamic acid, and the complexes formed are of nearly octahedral symmetry. At high pH, in the Co(II)-GSSG solution Co(II) is oxidized to Co(III) with the concomitant reduction of GSSG to GSH. Considerable differences were observed between the oxidized and reduced form of glutathione in the coordination ability towards metal ions.     

Redox-active complexes formed during the interaction between glutathione and mercury and/or copper ions

Prompted by the recently reported capacity of the physiologically occurring Cu(I)-[glutathione]₂ complex (Cu(I)-[GSH)]₂) to reduce oxygen, the effect of various GSH-binding metals (Co²⁺, Cd²⁺, Zn²⁺, Pb²⁺, Al³⁺, Hg²⁺ and Ni²⁺) on the superoxide-generating capacity of such complex was investigated. Amongst all tested metals, only Hg²⁺ was able to substantially affect the capacity of Cu(I)-[GSH]₂ to generate superoxide. When Hg²⁺ and Cu(I)-[GSH]₂ were mixed equimolarly, the superoxide formation, assessed through the cytochrome c reduction and dihydroethidium oxidation, was increased by over 50%. Such effect was totally inhibitable by SOD. Based on the reportedly higher affinity of Hg²⁺ for GSH and the observed ability of Hg²⁺ to lower the concentration of Cu(I)-[GSH]₂ (spectroscopically assessed), we suggest that Hg²⁺ displaces Cu(I) from Cu(I)-[GSH]₂, to release Cu(I) ions and form a Hg(II)-[GSH]₂ complex. The latter species would account for the Hg²⁺-induced exacerbation of the superoxide production. In fact, the present study provides first time evidence that a preformed Hg(II)-[GSH]₂ complex is able to concentration-dependently reduce oxygen. Such redox-activity was evidenced using cytochrome c and confirmed by EPR studies using DMPO (5,5-dimethyl-1-pyrroline N-oxide, a spin-trapping agent). Considering this novel ability of Hg(II)-[GSH]₂ to generate superoxide, a further characterization of its redox-activity and its potential to affect superoxide-susceptible biological targets appears warranted.     

Interactions of the anticancer antibiotic altromycin B with copper(II), palladium(II) and platinum(II) ions and in vitro activity of the formed complexes

Interaction of the anticancer antibiotic altromycin B with Cu(II), Pd(II) and Pt(II) ions was studied using 1H-NMR, EPR, electronic absorption and circular dichroism spectroscopy. The results derived from NMR studies where that the Pt(II) and Pd(II) ions interact with the nitrogen atom of the dimethylamino group of the C(10)-disaccharide, while the C(2)-epoxide group does not participate and remains intact. Cu(II) ions interact in a different way with altromycin B as was concluded by EPR and circular dichroism spectra. Altromycin B coordinates to the Cu(II) ions via the oxygen atoms of the C(11) phenolic and the C(12) carbonyl group while the nitrogen atom does not participate in the complexation. The presence of these metal ions improves the stability of altromycin B in solution. These complexes were studied in vitro against K562 leukemia sensitive and doxorubicin-resistant cells and GLC4 lung tumor cells, sensitive and doxorubicin-resistant. The activity of the complexes compared to the free drug is improved against resistant cells and is affected moderately against sensitive cells. Finally, 20% of platinum added as altromycin B metal complex entered GLC4 cells.     

Coordination mode of adenosine 5'-diphosphate in ternary systems containing Cu(II), Cd(II) or Hg(II) ions and polyamines

The interactions of adenosine 5'-diphosphate (ADP) with some polyamines (PA) (1,3-diaminopropane (tn), 1,4-diaminobutane (Put), 1,7-diamino-4-azaheptane (3,3-tri) and 1,8-diamino-4-azaoctane (Spd)) both in presence and in the absence of metal ions (Cu(II), Cd(II) and Hg(II)) have been studied. In the metal-free systems the formation of adducts (ADP)Hx(PA) has been observed, in which the main reaction centres are the endocyclic nitrogen atoms of the purine ring, the phosphate group of the nucleotide and the protonated nitrogen atoms of the polyamine. The effectiveness of the phosphate group in formation of adducts has been found to decrease in the series Put > Spd > Spm and to be lower than in the reactions with shorter homologues of biogenic amines. In the ternary systems with metal ions the formation of molecular complexes (ML L' type) has been evidenced in which the protonated polyamine interacts with the nitrogen atoms N(1) or N(7) of the purine ring of the nucleotide. In the ternary systems Cu(II)/ADP/polyamine the coordination dichotomy observed in the binary system Cu(II)/ADP disappears. In the systems with Hg(II) ions the pH range of the dichotomy is extended, while for the systems Cd(II)/ADP/polyamine no changes of the range relative to the binary system Cd(II)/ADP have been noted.     

Synthesis and solvatochromism studies of new mixed-chelate dinuclear copper(II) complexes with different counter ions

Four new symmetric mixed-chelate dinuclear complexes type [Cu₂(L)₂(TAE)]X₂, where TAE = tetraacetylethane; L = N,N-dimethyl-N′-benzylethylenediamine (L¹) or N,N′-dibenylethylenediamine (L²); X = ClO₄ or BPh₄ have been synthesized and characterized on the bases of elemental analysis, spectroscopic and conductance measurements. The X-ray crystal analysis of [Cu₂(L¹)₂(TAE)](ClO₄)₂ demonstrated that the two copper(II) ions are not equivalent. The axial position of the first copper is occupied by a ClO₄⁻ ion with a square pyramidal geometry whereas; the second copper ion resides in an octahedral environment determined by two perchlorate anions. However, in solution, the perchlorate ions are driven out by solvent molecules leading to their solvatochromism. The solvatochromism of the complexes were investigated in various organic solvents and also were compared with those of the corresponding mononuclear complexes [Cu(L)(acac)]ClO₄. Their solvatochromism were also investigated with different solvent parameters models using stepwise multiple linear regression (SMLR) method. The results suggested that the DN parameter of the solvent has the dominate contribution to the shift of the d-d absorption band of the complexes. The results demonstrated that the complexes with counter ions of BPh₄ are more solvatochromic in very weak donor solvents owing to their disinclination in ion-pair formation.     

Copper(II) PMDTA and copper(II) TMEDA complexes: precursors for the synthesis of dinuclear dicationic copper(II) complexes

Copper(II) cations coordinated with PMDTA (pentamethyldiethylenetriamine) and TMEDA (tetramethylethylenediamine) possess a high synthetic potential. The synthesis of these cations was carried out by metathesis reactions with silver salts. The cationic copper(II) complexes, [Cu(PMDTA)(Me₂CO)Cl]⁺, [Cu(PMDTA)(H₂O)Cl]⁺, [Cu(PMDTA)(DMF)]⁺, [Cu(PMDTA)Cl]⁺, [Cu(PMDTA)OAc]⁺, [Cu(PMDTA)(MeCN)₂]²⁺, [Cu₂(TMEDA)₂Cl₃]⁺ and [Cu(TMEDA)(MeCN)₃]²⁺ were synthesised as PF₆ salts, crystallised and characterised by single-crystal X-ray diffraction.     

Studies on copper(II) complexes of o-quinone monooximes. 4. Interaction between aquobis(1,2-naphthoquinone 1-oximato)copper(II) and lanthanide(III) ions. New heteropolynuclear complexes containing CuII and LnIII

By reacting aquobis(1,2-naphthoquinone 1-oximato)copper(II) [Cu(nqo)₂·H₂O] with lanthanide chlorides, new heteropolynuclear complexes containing both Cu^II and Ln^III (Ln^III = La^III, Nd^III) were obtained. The compounds have been characterized by elemental and thermogravimetric analysis, electron microprobe analysis, and electronic and vibrational spectral data. A different Cu^II complex, containing nqo ligands and ionic perchlorate but no lanthanide ions, was obtained by reaction of Cu(nqo)₂·H₂O with lanthanide perchlorates.