Cu2+对腺嘧啶-胸腺嘧啶碱基对阴离子质子转移的影响

采用B3LYP/DZP++方法研究了腺嘌呤-胸腺嘧啶(A-T)碱基对阴离子(AT)-的单质子转移机理以及金属离子Cu2+对(AT)-碱基对质子转移的影响.(AT)-碱基对的单质子转移路径是由胸腺嘧啶N25位上的质子H26沿分子间的氢键N25-H26…N10转移到腺嘌呤的N10位.金属Cu2+可通过络合作用分别吸附在(AT)-碱基对O24、O28、N4、N13上,从而影响(AT)-碱基对中质子转移过程.Cu2+络合作用在胸腺嘧啶(T)的O24、O28上时,发生了从胸腺嘧啶到腺嘌呤方向上的单质子转移反应;而作用在腺嘌呤(A)的N4、N13上时,得到了双质子转移的稳定产物.     

Interligand interactions controlling the mu-N7,N9-metal bonding of adenine (AdeH) to the N-benzyliminodiacetato(2-) copper(II) chelate and promoting the N9 versus N3 tautomeric proton transfer: molecular and crystal structure of [Cu2(NBzIDA)(2)(H2O)(2)(mu-N7,N9-Ade(N3)H)].(3)H2O

The reaction in water of the N-benzyliminodiacetate-copper(II) chelate ([Cu(NBzIDA)]) and the adenine:thymine base pair complex (AdeH:ThyH) with a Cu/NBzIDA/AdeH/ThyH molar ratio of 2:2:1:1 yields [Cu(2)(NBzIDA)(2)(H(2)O)(2)(mu-N7,N9-Ade(N3)H)].3H(2)O and free ThyH. The compound has been studied by thermal, spectral, and X-ray diffraction methods. In the asymmetric dinuclear complex units both Cu(II) atoms exhibit a square pyramidal coordination, where the four closest donors are supplied by NBzIDA in a mer-tridentate conformation and the N7 or N9 donors of AdeH, which is protonated at N3. The mu-N7,N9 bridge represents a new coordination mode for nonsubstituted AdeH, except for some adeninate(1-)-[methylmercury(II)] derivatives studied earlier. The dinuclear complex is stabilized by the Cu-N7 and Cu-N9 bonds and N6-H(exocyclic)...O(carboxyl) and N3-H(heterocyclic)...O(carboxyl) interligand interactions, respectively. The structure of the new compound differs from that of the mononuclear compound [Cu(NBzIDA)(Ade(N9)H)(H(2)O)].H(2)O, in which the unusual Cu-N3(AdeH) bond is stabilized by a N9-H...O(carboxyl) interligand interaction and where alternating benzyl-AdeH intermolecular pi,pi-stacking interactions produce infinite stacked chains. The possibility for ThyH to be involved in the molecular recognition between [Cu(NBzIDA)] and the AdeH:ThyH base pair is proposed.     

Cation-pi Interactions and oxidative effects on Cu+ and Cu2+ binding to Phe, Tyr, Trp, and His amino acids in the gas phase. Insights from first-principles calculations

The coordination properties of the four natural aromatic amino acids (AA(arom) = Phe, Tyr, Trp, and His) to Cu+ and Cu2+ have been exhaustively studied by means of ab initio calculations. For Cu+-Phe, Cu+-Tyr and Cu+-Trp, the two charge solvated tridentate N/O/ring and bidentate N/ring structures, with the metal cation interacting with the pi system of the ring, were found to be the lowest ones, relative DeltaG(298K) energies being less than 0.5 kcal/mol. The Cu+-His ground-state structure has the metal cation interacting with the NH2 group and the imidazole N. For these low-lying structures vibrational features are also discussed. Unlike Cu+ complexes, the ground-state structure of Cu2+-Phe, Cu2+-Tyr, and Cu2+-Trp does not present cation-pi interactions due to the oxidation of the aromatic ring induced by the metal cation. The ground-state structure of Cu2+-His does not present oxidation of the amino acid, the coordination to Cu2+ being tridentate with the oxygen of the carbonyl group, the nitrogen of the amine, and the N of the imidazole. Other less stable isomers, however, show oxidation of His, particularly of the imidazole ring, which can induce spontaneous proton-transfer reactions from the NH of the imidazole to the NH2 of the backbone. Finally, the computed binding energies for Cu+-AA(arom) and Cu2+-AA(arom) systems have been computed, the order found for the single charged systems being Cu+-His > Cu+-Trp > Cu+-Tyr > Cu+-Phe, in very good agreement with the experimental data.     

Effects of protonation on proton-transfer processes in guanine–cytosine Watson–Crick base pairs

Intermolecular proton-transfer processes in guanine–cytosine Watson–Crick base pairs have been studied using the B3LYP density functional method. Protonation of the base pair was carried out both at the N7 and at the O6 atoms of guanine. It is found that protonation induces a strengthening of the base pair and facilitates the N1–N3 single-proton-transfer reaction. The double-proton-transfer reaction, however, turns out to be unfeasible when the system is protonated at these sites. Mutagenic implications of these proton-transfer processes are discussed.Proceedings of the 11th International Congress of Quantum Chemistry satellite meeting in honor of Jean-Louis Rivail     

Effect of adenine moiety on DNA binding property of copper(II)-terpyridine complexes

Two novel copper(ii) terpyridine complexes, [Cu(atpy)(NO(3))(H(2)O)](NO(3)).3H(2)O () and [Cu(ttpy)(NO(3))(2)] () (atpy = 4'-p-N9-adeninylmethylphenyl-2,2':6,2'-terpyridine; ttpy = 4'-p-tolyl-2,2':6,2'-terpyridine) have been prepared and structurally characterized by X-ray crystallography. Both complexes show a CuN(3)O(2) coordination in a square pyramidal (4 + 1) geometry with terpyridine acting as an equatorial ligand. For complex , intermolecular AA base pairing interaction is observed between N(6) and N(1) of adjacent adenines with N(6)N(1) of 3.027(7) A. A molecular dynamics simulation of the DNA binding of two complexes showed that the adenine moiety plays an important role in the intercalation of into DNA. This is verified by UV, fluorescence, circular dichroism and flow linear dichroism studies. The promotional effect from the adenine moiety to the intracellular DNA binding of complex is also confirmed by the inductively coupled plasma mass (ICP-MS) spectrometry data which showed a significant higher copper content in DNA isolated from complex treated MCF-7 and HeLa cells.     

Density functional study toward understanding dehydrogenation of the adenine-thymine base pair and its anion

The dehydrogenated radicals and anions of Watson-Crick adenine-thymine (A-T) base pair have been investigated by the B3LYP/DZP++ approach. Calculations show that the dehydrogenated radicals and anions have relatively high stabilities compared with the single base adenine and thymine. The electron attachment to the A-T base pair and its derivatives significantly modifies the hydrogen bond interactions and results in remarkable structural changes. As for the dehydrogenated A-T radicals, they have relatively high electron affinities and different dehydrogenation properties with respect to their constituent elements. The relatively low-cost hydrogen eliminations correspond to the (N9)-H (adenine) and (N1)-H (thymine) bonds cleavage. Both dehydrogenation processes have Gibbs free energies of reaction DeltaG degrees of 13.4 and 17.2 kcal mol-1, respectively. The solvent water exhibits significant effect on electron attachment and dehydrogenation properties of the A-T base pair and its derivatives. In the dehydrogenating process, the anionic A-T fragment gradually changes its electronic configuration from pi* to sigma* state, like the single bases adenine and thymine.     

Theoretical study on the gas-phase acidity of multiple sites of Cu+-adenine and Cu2+-adenine complexes

The acidities of multiple sites in Cu(+)-adenine and Cu(2+)-adenine complexes have been investigated theoretically. To compare, the acidities of adenine (A) and adenine radical cation (A(*+)) have also been included. The results clearly indicate that the acidities of C-H and N-H groups in Cu(+/2+)-adenine are significantly enhanced relative to the neutral adenine. The acidic order for a given site on adenine and adenine derivatives is as follows: Cu(2+)-adenine > A(*+) > Cu(+)-adenine > A. For Cu(+)-adenine and Cu(2+)-adenine, N3-coordination exhibits N9-H acid, and N1- and N7-coordination exhibits N6-H(a) and N6-H(b) acid, respectively. Additionally, it is found that C2-H group is surprisingly acidic in the coordination complexes. Calculations in aqueous solution reveal that our results can be extrapolated to aqueous solution. Analyses of the electronic properties interpret the highest acidity of Cu(2+)-adenine among the adenine derivatives studied. Also, Electrostatic potential calculations of [A(-H(+))](-) and [A(-H(+))](*) indicate that the removal of H(a) or H(b) from the amino group favors the bidentate coordination, which provides a dative bond from the deprotonated N and the original coordination ligand to copper ion besides the electrostatic interaction between them and thereby stabilizes the [A(-H(+))](-)/[A(-H(+))](*). NBO analysis confirms the electrostatic potential result.     

The kinetics of substitution reactions of mixed platinum(II)-bis(nucleoside) complexes in aqueous solution in the presence of thiourea; X-ray crystal structure determination of cis-

In aqueous solution, bis(nucleoside) complexes formed by the reaction of cis-[Pt(NH3)2(H2O)2]2+ with an excess of either adenosine (ado) or a mixture of adenosine and guanosine (guo) undergo a slow N7--> N1 linkage isomerisation in the adenine moiety. The isomerisation probably involves the breaking and reformation of Pt-nucleoside bonds, thus favouring the more stable N1 binding mode of the adenine base. Dynamic processes due to the presence of adenosine in the platinum coordination sphere are slow on the NMR time scale. The N7 binding mode of PtII in cis-[Pt(NH3)2(ado-N7)2](ClO4)2. 3.5H2O was confirmed by X-ray crystal structure analysis. In both of the crystallographically independent cations, the PtII coordination sphere is almost ideally square planar, with typical Pt-N bond lengths and angles. The most significant difference between the two cations lies in the sugar conformation of the coordinated nucleosides. In one cation, both have an anti (-ap) conformation, whilst in the other cation one has an anti (-ap) conformation and the other a syn (+sc) conformation stabilised by a relatively strong H-bond. Substitution of the nucleoside(s) by thiourea follows an associative mechanism with only a negligible contribution by the solvent path. For symmetric complexes, the order of lability of different binding modes is ado-N1 相似文献   

Marked variations of dissociation energy and H-bond character of the guanine-cytosine base pair induced by one-electron oxidation and Li+ cation coupling

The variation of dissociation energy and H-bond character of the G-C cation and the Li-GC cation have been investigated by employing density functional theory (B3LYP) with the 6-31+G* basis set. The one-electron oxidation and the coupling of Li(+) to the guanine-cytosine base pair can strengthen the interaction between guanine and cytosine. The interaction of the cation Li(+) with guanine is attractive and is attributed to the polarization of the H-bonds between G-C that enhances G-C interaction. The cooperativity of the three H-bonds in the GC and Li-GC cations is different from that in the neutral GC base pair. The proton-transfer process between N(1) of the guanine and N(3) of the cytosine can occur in the GC cation and the Li-GC cation. The geometries of the transition state are out of plane, especially for the transition state of the Li-GC cation. The analysis of the activation energy for the proton-transfer process shows that the GC(+) before and after proton transfer can exist simultaneously in the gas phase, but for the Li-GC(+) system, the Li-GC(+) without proton transfer is the dominating species in the gas phase.     

Trans-hydrogen-bond (h2)J(NN) and (h1)J(NH) couplings in the DNA A-T base pair: natural bond orbital analysis

Natural bond orbital (NBO) analysis described here demonstrates that trans-hydrogen-bond (trans-H-bond) NMR J couplings in the DNA A-T base pair, h2JNN and h1JNH, are determined largely by three terms: two Lewis-type contributions (the single-orbital contribution from the adenine lone pair and the contribution from the sigmaN3H3 natural bond orbital of the thymine ring) and one contribution from pairwise delocalization of spin density (between the lone pair in adenine and the sigma* antibonding orbital linking N3 and H3 of thymine). For h2JNN coupling, all three contributions are positive, whereas for h1JNH coupling, the delocalization term is negative, and the other two terms are positive, resulting in a small net positive coupling constant. This result rationalizes the experimental findings that the two-bond coupling (h2JNN approximately 9 Hz) is larger than the one-bond coupling (h1JNH approximately 3 Hz) and demonstrates that the same hyperconjugative and steric mechanisms that stabilize the H-bond are involved in the transmission of J coupling information. The N1...H3-N3 H-bond of the DNA A-T base pair is found to exhibit significant covalent character, but steric effects contribute almost equally to the trans-H-bond coupling.     

Supramolecular architectures assembled by the interaction of purine nucleobases with metal-oxalato frameworks. Non-covalent stabilization of the 7H-adenine tautomer in the solid-state

The synthesis, crystal structure and variable-temperature magnetic measurements of the compounds [Mn(mu-ox)(H2O)(7H-pur-kappaN9)]n (1), {[Mn(mu-ox)(H2O)2].(7H-ade).(H2O)}n (2) and {[Cu(mu-ox)(H2O)(7H-ade-kappaN9)][Cu(mu-ox)(mu-H2O)(7H-ade-kappaN9)]. approximately 10/3H2O}n (3), (where ox: oxalato dianion, pur: purine, and ade: adenine) are reported. Compounds 1and 2 contain one-dimensional chains in which manganese(II) atoms are bridged by bis-bidentate oxalato ligands. The distorted octahedral geometry around each metal centre is completed in compound 1 by one water molecule and the imidazole N9 donor site of the purine ligand, which is a rare example of direct binding between the Mn(II) ion and the N donor site of an isolated nucleobase. Unlike 1, the adenine moiety in compound 2 is not bonded to manganese atoms and the metal coordination polyhedron is filled by two water molecules in a cis-arrangement. Its crystal building is constructed from pi-stacked layers of Watson-Crick hydrogen-bonded adenine...(H2O2)...adenine aggregates and zig-zag Mn(II)-oxalato chains held together by means of a strong network of hydrogen bonding interactions. The nucleobase exists in the lattice as the 7H-adenine tautomer which represents an unprecedented solid-state characterization of this minor tautomer as free molecule (without metal coordination) stabilized through non-covalent interactions. Compound consists of two slightly different [Cu(ox)(H2O)(7H-ade-kappaN9)] units in which the nucleobase coordinates through the imidazole N9 atom. The planar complex entities are parallel stacked and joined by means of long Cu-O bonds involving oxygen atoms from the oxalato and the aqua ligands, giving one-dimensional chains with a [4 + 1] square-planar pyramidal and a [4 + 2] octahedral coordination around the metal centre, respectively. Self-assembled process of compound 3 is further driven by an in-plane network of hydrogen bonding interactions to generate a porous 3D structure containing parallel channels filled by guest water molecules. Variable-temperature magnetic susceptibility measurements of all the complexes show the occurrence of antiferromagnetic interactions between the paramagnetic centres. DFT calculations have been performed to check the influence of packing in the stability of the 7H-amino tautomer of 2 and in the complex geometry of 3.     

Multiple proton-transfer reactions in DNA base pairs by coordination of pt complex

The possibility of multiple proton-transfer reactions in DNA base pairs because of coordination of cisplatin is theoretically elucidated by density functional theory (DFT) and by quantum mechanics/molecular mechanics (QM/MM) methods with an ONIOM method. From the energetics of two base pairs with the cisplatin, it is theoretically confirmed that the Pt complex is likely to bind in the order cis-(CG)-Pt-(GC), cis-(CG)-Pt-(AT), cis-(TA)-Pt-(AT), where G, C, A, and T are guanine, cytosine, adenine, and thymine, respectively, and the Pt atom bonds to the N7 site of G and A. This result supports the experimental evidence, where the structure cis-A-Pt-A is seldom observed at room temperature. The single proton-transfer reaction occurs in one of the two GC pairs. No simultaneous single proton-transfer reaction can occur in both base pairs. Two different single proton-transferred structures (cis-(CG*)(d)-Pt-(GC)(p) and cis-(CG)(d)-Pt-(G*C)(p), where the asterisk means a proton donor of G) are as stable as the original structures (CG)(d)-Pt-(GC)(p). The same tendency was observed with cis-(CG*)-Pt-(AT). In contrast to cisplatin, multiple single proton-transfer reactions occur in the system consisting of two base pairs with transplatin. The optimized structure agrees with the experimental data for Pt-G coordination except for the hydrogen-bonding length.     

Na+, Mg2+, and Zn2+ binding to all tautomers of adenine, cytosine, and thymine and the eight most stable keto/enol tautomers of guanine: a correlated ab initio quantum chemical study

Interactions of adenine, cytosine, guanine, and thymine with Na(+), Mg(2+), and Zn(2+) cations were studied using an approximate resolution of identity correlated second-order MP2 (RI-MP2) method with the TZVPP ([5s3p2d1f/3s2p1d]) basis set. All existing tautomers of adenine, cytosine, and thymine and the eight most stable keto/enol tautomers of guanine were considered. Cations bind mostly in a bidentate manner, and stabilization energies of these complexes are larger than those in the case when cations bind in a unidentate manner. The cation...Y (Y equal to N or O) distances for divalent metals are shorter than those for Na(+) and for Zn(2+) are mostly shorter than the Mg(2+)...Y distance. The intermolecular distances between the cation and the base for complexes containing adenine and cytosine are systematically shorter than those for complexes containing guanine and thymine. Only for cytosine the canonical keto/amino tautomer structure with ions represents the global minimum. For guanine, the metalated canonical form is again the most stable, but its stabilization energy is within less than 5% of the stabilization energies of the two other rare tautomers, which indicates that the canonical form and these two rare tautomers could coexist. The canonical structures of adenine and thymine in the presence of ions are considerably less stable (by more than 10%) than the complexes of the rare tautomers. It can be concluded that the interaction of Na(+), Mg(2+), and Zn(2+) cations with cytosine in the gas phase will not induce the change of the canonical form to the rare tautomeric form. In the case of isolated guanine, the equilibrium of the canonical form with rare tautomers can be found. For isolated adenine and thymine the presence of rare tautomers is highly probable.     

Properties of the optimal environment inducing tautomerization of complementary base pairs

The optimal environment charge configurations are predicted for the tautomerization of complementary base pairs into their corresponding rare forms, and vice versa. Results indicate that cations approaching the N₃ guanine site may induce tautomerization of the normal guanine—cytosine (G---C) base pair into its rare form. The reverse process requires that the cation approach the O₂ thymine site of the rare adenine*—thymine* pair (A*---31T*) or the O₆ guanine site of rare guanine*—cytosine* base pair (G*---C*). Possible mutagenic and antimutagenic roles of metal cations approaching base pairs are also discussed.     

Effects of protonation on proton transfer processes in Watson–Crick adenine–thymine base pair

Intermolecular proton transfer processes in the Watson and Crick adenine–thymine neutral and protonated base pairs have been studied using the density functional theory (DFT) with the non-local hybrid B3LYP density functional. Protonated systems subject to study are those resulting from protonation at the main basic sites of the base pair model, namely N₇ and N₃ of adenine and O₂^′ and O₄^′ of thymine. Protonation of adenine induces a strengthening by about 4–5 kcal/mol of the base pair and does not significantly modify the double proton transfer energy profile obtained for the unprotonated system. On the other hand, protonation at the O₄^′ and O₂^′ thymine moiety causes thymine’s N₃ proton to spontaneously transfer to adenine while non-transferred minima disappear at this level of theory. The different behaviour between protonated adenine– thymine and protonated guanine–cytosine is discussed. Electronic Supplementary Material The online version of this article (doi:) contains supplementary material, which is available to authorized users. Contribution to the Fernando Bernardi Memorial Issue.     

水环境对GC和AT碱基对质子转移的影响

采用B3LYP/DZP++的方法研究了第一水化层作用和连续化处理的水溶剂作用对鸟嘌呤-胞嘧啶(GC)碱基对和腺嘌呤-胸腺嘧啶(AT)碱基对质子转移反应的影响. GC和AT碱基对在连续化水溶剂作用下,均发生单质子转移(SPT1)和分步的双质子转移(DPT),而在第一水化层5 个水分子的作用下(GC·5H₂O,AT·5H₂O)或同时考虑第一水化层作用和连续化水溶剂作用(GC·5H₂O+PCM,AT·5H₂O+PCM)时,GC和AT碱基对的质子转移均只得到单质子转移反应(SPT1). 单质子转移过程中的活化能变化情况表明：第一水化层对GC和AT碱基对结构和质子转移影响较大,水环境对碱基对的作用主要发生在第一水化层.     

Gas-phase theoretical prediction of the metal affinity of copper(I) ion for DNA and RNA bases

The most stable tautomeric forms of free DNA and RNA bases were considered as substrates for the interaction of Cu(+) ion. Several suitable attachment sites were selected that involved mono- and bi-coordination of the cation. B3LYP/6-311 + G(2df,2p) bond energies showed that copper ion has the major affinity for guanine and cytosine bases. The proposed values of Cu(+) ion affinity are 59.9, 60.0, 80.2, 88.0 and 69.0 kcal mol(-1) for uracil, thymine, cytosine, guanine and adenine, respectively. The preference for the mono- or bi-coordination depends on the particular tautomer for each base.     

Activation barriers for DNA alkylation by carcinogenic methane diazonium ions

Methylation reactions of the DNA bases with the methane diazonium ion, which is the reactive intermediate formed from several carcinogenic methylating agents, were examined. The SN2 transition states of the methylation reactions at N7, N3, and O6 of guanine; N7, N3, and N1 of adenine; N3 and O2 of cytosine; and O2 and O4 of thymine were calculated using the B3LYP density functional method. Solvation effects were examined using the conductor-like polarizable continuum method and the combined discrete/SCRF method. The transition states for reactions at guanine N3, adenine N7, and adenine N1 are influenced by steric interactions between the methane diazonium ion and exocyclic amino groups. Both in the gas phase and in aqueous solution, the methylation reactions at N atoms have transition states that are looser, and generally occur earlier along the reaction pathways than reactions at O atoms. The forming bonds in the transition states in water are 0.03 to 0.13 A shorter than those observed in the gas phase, and the activation energies are 13 to 35 kcal/mol higher. The combined discrete/SCRF solvation energy calculations using base-water complexes with three water molecules yield base solvation energies that are larger than those obtained from the CPCM continuum method, especially for cytosine. Reactivities calculated using barriers obtained with the discrete/SCRF method are consistent with the experimentally observed high reactivity at N7 of guanine.     

Adiabatic electron affinities of the polyhydrated adenine-thymine base pair: a density functional study

Adiabatic electron affinities (AEAs) of the adenine-thymine (AT) base pair surrounded by 5 and 13 water molecules have been studied by density functional theory (DFT). Geometries of neutral AT x nH2O and anionic (AT x nH2O)- complexes (n = 5 and 13) were fully optimized, and vibrational frequency analysis was performed at the B3LYP/6-31+G** level of theory. The optimized structures of the neutral (AT x nH2O) and (AT x nH2O)- complexes were found to be somewhat nonplanar. Some of the water molecules are displaced away from the AT ring plane and linked with one another by hydrogen bonds. The optimized structures of the complexes are found to be in a satisfactory agreement with the observed experimental and molecular dynamics simulation results. In the optimized anionic complexes, the thymine (T) moiety was found to be puckered, whereas the adenine (A) moiety remained almost planar. Natural population analysis (NPA) performed using the B3LYP/6-31+G** method shows that the thymine moiety in the anionic (AT x nH2O)- complexes (n = 5 and 13) has most of the excess electronic charge, i.e., approximately -0.87 and approximately -0.81 (in the unit of magnitude of the electronic charge), respectively. The zero-point energy corrected adiabatic electron affinities of the hydrated AT base pair were found to be positive both for n = 5 and 13 and have the values of 0.97 and 0.92 eV, respectively, which are almost three times the AEA of the AT base pair. The results show that the presence of water molecules appreciably enhances the EA of the base pair.     

Gas phase interaction of zinc ion with purine and pyrimidine DNA and RNA bases

The interaction of uracil, thymine, cytosine, adenine, and guanine with zinc ion was studied at the density functional B3LYP/6‐311+G(2df,2p) level. Different binding sites allowing both mono‐metal and bi‐metal coordination were considered for the different low‐lying tautomers of nucleic acid bases. Zinc ion forms stable compounds with all nucleobases. Except for cytosine, mono‐coordination appears to be less favored than bi‐coordination in the other pyrimidines. Instead, the preferred sites in the case of adenine and guanine were found to be the N7 and O6 and N7 and N6 pairs of atoms, respectively. Zinc ion affinity was evaluated for all the complexes and compared with values previously obtained for other transition metal ions. In the present case, the following order of metal ion affinity (MIA) was found: G>A>C>T>U. © 2006 Wiley Periodicals, Inc. Int J Quantum Chem, 2007