Preferential binding specificity of silver cation to a single nucleobase over base pairs evaluated by abasic site-containing DNA

The binding specificity of silver cations to abasic (AP) site-containing DNA was electrochemically investigated by comparison with the fully matched DNA without the AP site. AP site-containing DNA is designed in a way that only the nucleotide opposite the AP site is variable to allow for coexistence of an unpaired nucleotide and a number of DNA base pairs. The surface of a gold electrode was modified by AP site-containing DNA duplex on which Ag⁺ binding specificity was evaluated. Electrochemical investigations on the AP-DNA-modified electrodes reveal that Ag⁺ preferentially associates to the unpaired nucleotides instead of the coexisted base pairs and shows sequence-dependant binding, especially stronger for purines than for pyrimidines. Additionally, the hydrogen bond pattern moieties of the unpaired nucleotides should be involved in Ag⁺ binding evidenced by a decrease of the redox signal when introducing a ligand with its hydrogen bond moiety complementary to the nucleotide deoxycytidine. This is the first attempt to make a comparison in one DNA molecule for metal ion binding to coexisted unpaired nucleotide and DNA base pairs. The present method demonstrates an easy way for investigating binding specificity of heavy metal ions to AP site in the presence of coexisted DNA base pairs.     

Intercalators. 1. Nature of stacking interactions between intercalators (ethidium, daunomycin, ellipticine, and 4',6-diaminide-2-phenylindole) and DNA base pairs. Ab initio quantum chemical, density functional theory, and empirical potential study

Properties of isolated intercalators (ethidium (E), daunomycin (D), ellipticine (EL), and 4,6'-diaminide-2-phenylindole (DAPI)) and their stacking interactions with adenine...thymine (AT) and guanine...cytosine (GC) nucleic acid base pairs were investigated by means of a nonempirical correlated ab initio method. All intercalators exhibit large charge delocalization, and none of them (including the DAPI dication) exhibits a site with dominant charge. All intercalators have large polarizability and are good electron acceptors, while base pairs are good electron donors. MP2/6-31G*(0.25) stabilization energies of intercalator...base pair complexes are large (E...AT, 22.4 kcal/mol; D...GC, 17.8 kcal/mol; EL...GC, 18.2 kcal/mol; DAPI...GC, 21.1 kcal/mol) and are well reproduced by modified AMBER potential (van der Waals radii of intercalator atoms are enlarged and their energy depths are increased). Standard AMBER potential underestimates binding, especially for DAPI-containing complexes. Because the DAPI dication is the best electron acceptor (among all intercalators studied), this difference is explained by the importance of the charge-transfer term, which is not included in the AMBER potential. For the neutral EL molecule, the standard AMBER force field provides correct results. The Hartree-Fock and DFT/B3LYP methods, not covering the dispersion energy, fail completely to reveal any energy minimum at the potential energy curve of the E...AT complex, and these methods thus cannot be recommended for a study of intercalation process. On the other hand, an approximate version of the DFT method, which was extended to cover London dispersion energy, yields for all complexes very good stabilization energies that are well comparable with referenced ab initio data. Besides the vertical dependence of the interaction, an energy twist dependence of the interaction energy was also investigated by a reference correlated ab initio method and empirical potentials. It is concluded that, despite the cationic (E +1, D +1, DAPI +2) or polar (EL) character of the intercalators investigated, it is the dispersion energy which predominantly contributes to the stability of intercalator...base pair complexes. Any procedure which does not cover dispersion energy is thus not suitable for studying the process of intercalation.     

Metahybrid density functional theory and correlated ab initio studies on microhydrated adenine-thymine base pairs

Monohydrated and dihydrated adenine-thymine base pairs are characterized using metahybrid density functional theory and correlated ab initio approaches. The motivation of this work is twofold. First, the high-level geometries and interaction energies computed for different complexes serve as a reference for the testing of recently developed density functional theory (DFT) with respect to its ability to correctly describe the balance between the electrostatic and the dispersion contributions that bind these complexes. Second, these studies of nucleic acid base pairs are important for finding binding sites of water molecules around bases and for a better understanding of the influence of the solvent on the stability of the structure of DNA duplexes.     

荧光法研究手性金属配合物与DNA的作用机理

以溴化乙锭为荧光探针，研究手性金属配合物［Ｎｉ（ｐｈｅｎ）３］＾＋和［Ｆｅ（ｐｈｅｎ）３］＾２＋与ＤＮＡ的反应机理。结果表明，配合物与ＤＮＡ作用存在插入和静电结合两种模式，即部分菲咯啉配体插入ＤＮＡ双螺旋碱基对中，同时带正电荷的配合物与ＤＮＡ的磷酸基团发生静电结合。     

DNA脱碱基位点存在下非氢键配体的增强结合研究

众所周知,插入剂的DNA特性结合位点位于DNA碱基对之间,然而这种非共价相互作用对于含脱碱基（AP）位点的DNA来讲还没有引起足够的重视,虽然在生物细胞中总是存在着DNA脱碱基位点。本文以原黄素（proflavine,PF）为例研究了插入剂对DNA中AP位点的结合特性。实验结果表明,相对于插入位点而言,AP位点是PF的优先结合位点,AP位点的本征结合常数比插入结合常数高一个数量级以上。此外,PF的结合使含脱碱基位点DNA的热稳定性明显提高,表明PF在脱碱基位点的结合构像明显不同于插入结合时的分子定向。本文结果将有助于判断小分子的DNA结合方式所决定的药物的生物化学及生物物理效用。     

Designed Intercalators for Modification of DNA Origami Surface Properties

The modification of the backbone properties of DNA origami nanostructures through noncovalent interactions with designed intercalators, based on acridine derivatized with side chains containing esterified fatty acids or oligo(ethylene glycol) residues is reported. Spectroscopic analyses indicate that these intercalators bind to DNA origami structures. Atomic force microscopy studies reveal that intercalator binding does not affect the structural intactness but leads to altered surface properties of the highly negatively charged nanostructures, as demonstrated by their interaction with solid mica or graphite supports. Moreover, the noncovalent interaction between the intercalators and the origami structures leads to alteration in cellular uptake, as shown by confocal microscopy studies using two different eukaryotic cell lines. Hence, the intercalator approach offers a potential means for tailoring the surface properties of DNA nanostructures.     

Structure–affinity relationships for the binding of actinomycin D to DNA

Molecular models of the complexes between actinomycin D and 14 different DNA hexamers were built based on the X-ray crystal structure of the actinomycin–d(GAAGCTTC)2 complex. The DNA sequences included the canonical GpC binding step flanked by different base pairs, nonclassical binding sites such as GpG and GpT, and sites containing 2,6-diamino- purine. A good correlation was found between the intermolecular interaction energies calculated for the refined complexes and the relative preferences of actinomycin binding to standard and modified DNA. A detailed energy decomposition into van der Waals and electrostatic components for the interactions between the DNA base pairs and either the chromophore or the peptidic part of the antibiotic was performed for each complex. The resulting energy matrix was then subjected to principal component analysis, which showed that actinomycin D discriminates among different DNA sequences by an interplay of hydrogen bonding and stacking interactions. The structure–affinity relationships for this important antitumor drug are thus rationalized and may be used to advantage in the design of novel sequence-specific DNA-binding agents.     

Hydrogen-bonding interactions in peptide nucleic acid and deoxyribonucleic acid: a comparative study

Peptide nucleic acid (PNA) is a synthetic analogue of deoxyribonucleic acid (DNA) capable of tightly binding to itself and DNA with high specificity. Using hybrid density functional methods, hydrogen-bond (H-bond) strengths have been evaluated for isolated Watson-Crick base pairs, PNA base pairs, and charged as well as neutral DNA base pairs. Heterogeneous base pairs of PNA with charged and neutral DNA have also been investigated. The competing effects of short-range H-bonding and long-range Coulombic repulsions in charged DNA base pairs have been analyzed. Polarizable continuum models have been employed to evaluate solvation effects on the binding energies.     

Poly-intercalators Carrying Threading Intercalator Moieties as Novel DNA Targeting Ligands

Threading intercalators are a novel class of intercalators that carry two substituents along the diagonal positions of an aromatic ring. These substituents are projecting out in DNA grooves when bound to DNA. Poly-intercalators carrying threading intercalating parts are quite novel and were recently found to show a unique DNA binding behavior. We review herein two types of poly-intercalators. First, tris-intercalators carrying a threading intercalator part in the middle of the molecule are described. These intercalators appear to intercalate into double stranded DNA in a special binding manner, which we call the penetrating mode, in which all the three intercalating units are arranged linearly with one of them penetrating into the DNA ladder. We synthesized two tris-intercalators ( 3 and 4) of this type and studied their binding behavior for double stranded DNA. All the experimental results were consistent with the proposed penetrating mode. Another type of threading poly-intercalators is a macrocyclic bis-threading intercalator ( 5). We found that this compound can bis-intercalate to double stranded DNA when the base pairing is disrupted temporarily to form a complex with a unique structure like a catenane. On the basis of a study of the interaction of such intercalators we envisage that DNA is a flexible and dynamic entity. These novel families of poly-intercalators will expand the scope of DNA poly-intercalation chemistry with possible medicinal applications.     

Orientation of dye molecules in DNA-based films with chain alignment and judgment of their DNA-binding modes

Novel composite films of chain-oriented DNA, which contain the DNA-binding dyes aligned in specific orientation, were successfully prepared by drying the solution under a horizontal magnetic field. Most of the dye-DNA composite films showed linear dichroism, as revealed by polarized ultraviolet-visible (UV-vis) spectroscopy. The intercalators, ethidium bromide and acridine orange, were fixed in chain-oriented DNA films in a similar binding manner as in solutions. Also, Hoechst 33258 and 4',6-diamidino-2-phenylindole were found to be aligned along the minor groove, even in the solid films. Thus, our new method of preparing dye-DNA composite films with chain orientation is useful for aligning small molecules, and it will provide views of the novel anisotropic materials expected in various application fields. We used this method to prepare composite DNA films with newly designed original compounds. Seven of nine dyes were judged to bind obviously to DNA as intercalators by polarized UV-vis spectroscopy. The DNA-binding manners were further analyzed by fluorescence anisotropy measurements. On the basis of the curves for the rotational angle dependence of the anisotropy, we were able to estimate the angles between the transition-dipole moments of dyes and the aligned chain axis of DNA. Interestingly, two original compounds were found to be in the tilted forms with regard to the plane of base pairs. We emphasize here that the method using aligned dye-DNA films is very convenient for identifying the binding modes of the compounds for double-stranded DNA.     

A new strategy for the design of water-soluble synthetic receptors: specific recognition of DNA intercalators and diamines

Water-soluble zinc bisporphyrin receptors 1 and 2 having two Lewis acidic sites (zinc) in the hydrophobic environment consisting of alkyl chains and a bisporphyrin framework, and covered with hydrophilic exterior (twelve or eighteen carboxyl groups) were prepared. The receptors show high affinity for diamines and DNA intercalators in water where the binding constants K(a) are of the order of 10(7) and 10(8) M(-1), respectively. Diamines and DNA intercalators are bound to the receptor through different mechanisms. Diamines are bound through hydrophobic interactions and zinc-nitrogen interactions, while DNA intercalators are bound through hydrophobic interactions and charge-transfer interactions. Flexible alkyl chains can make van der Waals contact with guests and create a hydrophobic environment around the bound guest by an induced-fit-type mechanism. For the binding of DNA intercalators, the following features are noteworthy: 1). Binding constants are similar between the zinc porphyrins and zinc-free porphyrins; 2). the binding constant is larger for the guest having the lower LUMO; this indicates the important contribution of charge-transfer interactions to binding; 3). the hydrophobic and cationic nature of DNA intercalators is substantially important, and 4). higher ionic strength reduced the binding affinities; this shows a moderate contribution of electrostatic interactions. The conformational instability of the receptors also contributes to the tight binding: hydrophobic and electrostatic interactions cannot both be favorable at the same time in the guest-free receptor. Enthalpy-entropy compensation observed for the binding of diamines and DNA intercalators is characterized by a relatively small slope (alpha=0.74) and a large intercept (beta=7.75 kcal mol(-1)) in the DeltaH degrees versus TDeltaS degrees plot; this shows that a conformational change of receptors and a significant desolvation occur upon binding. The receptor can competitively bind to propidium iodide to deprive DNA of the intercalated propidium iodide. These features of water-soluble receptors consisting of a rigid framework and flexible side chains with a large solvent-accessible area are in contrast to highly preorganized rigid receptors, and they can provide useful guidelines for rational design of induced-fit artificial receptors in water.     

INTERACTION OF ACRIDINE DRUGS WITH DNA AND NUCLEOTIDES

Abstract— At high phosphate-to-drug ratios acridine drugs intercalate between hydrogen bonded DNA base pairs causing significant changes in the physico-chemical properties of DNA. The determination of the nature of the strong (or primary) interaction between acridine drugs and DNA is of great importance for elucidating the mode of the biological action of the drugs. Nanosecond measurements have revealed a fast depolarization of the fluorescence of proflavine, one of the most extensively studied acridines, bound to DNA. The electronic structure of the complex, however, is not substantially altered during the lifetime of the excited singlet electronic state of the drug. Guanine has been shown to be responsible for the quenching of the proflavine fluorescence upon binding to DNA. A temperature-jump relaxation study has demonstrated a rather external complexation of this drug with the G-C base pairs; this complex, whose formation occurs in the strong binding region, is distinct from the weak electrostatic complex. The findings that the binding ability of a series of acridines correlates with their basicity and that the drug–binding behavior of methylated DNA is significantly different from that of DNA suggested that specific forces may be also involved in the drug–DNA binding in addition to hydrophobic forces. Recent experiments employing molecular complexes of acridines with nucleotides as model systems have provided strong support for the specificity of the drug-DNA interaction. Hydrogen bonding between the drug and reactive groups of the DNA bases that do not contribute directly to the stability of the helix may be involved in that interaction. The stoichiometry of the proflavine-guanosine 5′-phosphate complex is 1:1. Its association constant increases from 310 M^-1 when proflavine is in its ground electronic state, to 1550 M^-1, when proflavine is in its first excited singlet state. Thus, light absorbed by the drug alters its reactivity which, in turn, results in an appreciable increase in its ability to bind to the nucleotide. In view of the proposed importance of the drug–base interaction in explaining the mutagenic properties of acridine drugs and, in particular, of the proposed involvement of the G-C base pairs, this finding emphasizes the possible importance of drug photoexcitation in acridine mutagenesis; it also contributes to the elucidation of photodynamic action. X-ray diffraction studies have recently provided very interesting demonstrations of strong binding of 9-aminoacridine and of the phenanthridine drug ethidium bromide to adenine-uracil base pairs in the crystalline phase. The ability of photoexcited acridine drugs to inactivate viruses has been recently used for therapeutic purposes. The carcinogenic risk involved, however, is still under investigation.     

A comparative DFT study of some N-based aromatic ligand metal complexes as anticancer agents and analysis of their mode of interaction with DNA base pair

Metal complexed anticancer agents interact with DNA nucleobase pairs (AT and GC) through different types of binding mode such as intercalation, groove binding, covalent binding, etc. Minor and major groove binding mechanism of DNA base pair is the key factor for all kinds of anticancer agent; as metal complexes have a great affinity to bind with DNA nucleobase either through minor or major groove. Ligands in metal complexes also play a vital role during the interaction with DNA base pairs; these ligands directly interact with DNA through different interacting modes. Generally, anticancer agents with less sterically hindered N-based aromatic and planar ligands are the key component for DNA binding; as the structure of such ligands are quite compatible for following intercalation and groove binding mechanism. Since, the experimental investigation for drug-DNA nucleobase complexes are extremely complicated, therefore; quantum mechanical calculations might be very helpful for computing the actual interactions in drug-DNA complexes. Quantum mechanical approaches such as density functional theory (DFT) might be a very important and useful tool to investigate the actual mode of interaction of metal complexed antitumor agents with DNA nucleobase. Herein, we have taken some metal complexes with N-based aromatic ligands as antitumor agents to investigate the proper mode of interaction between drug-DNA complexes.     

米托蒽醌与B-DNA相互作用的分子模拟

针对嵌插型抗癌药物米托蒽醌(mitoxantrone,MTX)同B-DNA间作用模式的争议,采用分子模拟方法研究了米托蒽醌分子与B-DNA分子的相互作用.结果表明:米托蒽醌分子插入到B-DNA中有大小沟选择性及碱基对特异性,更倾向从小沟方向插入到DNA分子中;对5'-CG碱基对有特异性识别.通过详细能量项的分析,揭示了米托蒽醌插入DNA分子的驱动力及对碱基的特异性识别作用主要是空间相互作用特别是静电相互作用.在最佳作用位点复合物的构象分析则表明蒽醌环只有一部分插入碱基对中,侧链在小沟中延磷酸基骨架以3'-5'方向伸展,并通过静电作用进一步增强米托蒽醌与B-DNA的结合.     

An approach to therapeutic agents through selective targeting of destabilised nucleic acid duplex sequences

The binding of ΔΔ/ΛΛ-[{Ru(phen)(2)}(2)(μ-bb(n))](4+) {where phen = 1,10-phenanthroline, bb(n) = 1,n-bis[4(4'-methyl-2,2'-bipyridyl)]-alkane (ΔΔ/ΛΛ-Rubb(n))} to the non-self complementary oligonucleotide 5'-d(CGCGATAAGCCGC·5'-GCGGCATTACGCG) (3-DB) has been examined using a 4',6-diamidino-2-phenylindole dihydrochloride (DAPI) displacement assay. The 3-DB oligonucleotide contains two single adenine bulge nucleotides that are separated by three base pairs. (1)H NMR spectroscopy data demonstrated that the adenine bases are intra-helical and that the segment containing the two bulge nucleotides and the three A·T base pairs between the bulges forms a destabilised segment within the stable duplex oligonucleotide. The DAPI displacement assay demonstrated that ΔΔ-Rubb(7)-bound 3-DB with higher affinity than the other members of the ΔΔ/ΛΛ-Rubb(n) series. Molecular models suggested that the seven-carbon chain length in ΔΔ-Rubb(7) was ideal to span the distance between the two bulge sites. The binding of ΔΔ-Rubb(7) to 3-DB was also studied by (1)H NMR spectroscopy and molecular modelling. The selective changes in chemical shifts for the resonances from 3-DB upon addition of ΔΔ-Rubb(7) suggested that the metal complex specifically bound at the destabilised segment between A(5) and A(19). Observation in NOESY spectra of NOE cross peaks between 3-DB and ΔΔ-Rubb(7) confirmed that one of the ruthenium centres bound at the A(5) bulge site, with the other metal centre positioned at the A(19) bulge. In addition, ΔΔ-Rubb(7) was found to bind chromosomal DNA extracted from a suspension of Staphylococcus aureus that had been incubated with the ruthenium(ii) complex. As inert dinuclear ruthenium(ii) complexes are capable of being transported into a bacterial cell and bind chromosomal DNA, it is possible that they could be developed into anti-microbial agents that specifically target destabilised segments of DNA that are recognised by essential DNA-binding proteins.     

Binding Cofactors with Triplex‐Based DNA Motifs

Cofactors are pivotal compounds for the cell and many biotechnological processes. It is therefore interesting to ask how well cofactors can be bound by oligonucleotides designed not to convert but to store and release these biomolecules. Here we show that triplex‐based DNA binding motifs can be used to bind nucleotides and cofactors, including NADH, FAD, SAM, acetyl CoA, and tetrahydrofolate (THF). Dissociation constants between 0.1 μM for SAM and 35 μM for THF were measured. A two‐nucleotide gap still binds NADH. The selectivity for one ligand over the others can be changed by changing the sequence of the binding pocket. For example, a mismatch placed in one of the two triplets adjacent to the base‐pairing site changes the selectivity, favoring the binding of FAD over that of ATP. Further, changing one of the two thymines of an A‐binding motif to cytosine gives significant affinity for G, whereas changing the other does not. Immobilization of DNA motifs gives beads that store NADH. Exploratory experiments show that the beads release the cofactor upon warming to body temperature.     

电化学方法研究DNA与不可逆靶向分子的相互作用

用循环伏安法、示差脉冲伏安法、计时库仑法、整体电解法和扫描电化学显微镜研究了具有抗癌活性的双苯并咪唑衍生物(BBID)不可逆电化学行为及BBID与DNA的相互作用,推导了适用于研究不可逆电活性分子与DNA相互作用的电化学公式,该公式可以简便、快速地测定靶向分子与DNA的结合常数和结合位点数。实验发现,BBID与天然鱼精DNA的结合以结构作用为主,同时,由于求得的结合常数(K)值较大,因此其中可能还存在序列作用的因素。结合方式主要为包含4个碱基对的紧密小沟结合。     

Binding of metal ions by pyrimidine base pairs in DNA duplexes

Pyrimidine base pairs in DNA duplexes selectively capture metal ions to form metal ion-mediated base pairs, which can be evaluated by thermal denaturation, isothermal titration calorimetry, and nuclear magnetic resonance spectroscopy. In this critical review, we discuss the metal ion binding of pyrimidine bases (thymine, cytosine, 4-thiothymine, 2-thiothymine, 5-fluorouracil) in DNA duplexes. Thymine-thymine (T-T) and cytosine-cytosine (C-C) base pairs selectively capture Hg(II) and Ag(I) ions, respectively, and the metallo-base pairs, T-Hg(II)-T and C-Ag(I)-C, are formed in DNA duplexes. The metal ion binding properties of the pyrimidine-pyrimidine pairs can be changed by small chemical modifications. The binding selectivity of a metal ion to a 5-fluorouracil-5-fluorouracil pair in a DNA duplex can be switched by changing the pH of the solution. Two silver ions bind to each thiopyrimidine-thiopyrimidine pair in the duplexes, and the duplexes are largely stabilized. Oligonucleotides containing these bases are commercially available and can readily be applied in many scientific fields (86 references).     

Base pairing in RNA structures: A computational analysis of structural aspects and interaction energies

The base pairing patterns in RNA structures are more versatile and completely different as compared to DNA. We present here results of ab-initio studies of structures and interaction energies of eight selected RNA base pairs reported in literature. Interaction energies, including BSSE correction, of hydrogen added crystal geometries of base pairs have been calculated at the HF/6-31G** level. The structures and interaction energies of the base pairs in the crystal geometry are compared with those obtained after optimization of the base pairs. We find that the base pairs become more planar on full optimization. No change in the hydrogen bonding pattern is seen. It is expected that the inclusion of appropriate considerations of many of these aspects of RNA base pairing would significantly improve the accuracy of RNA secondary structure prediction.     

Hydrogen-bonded nucleic acid base pairs containing unusual base tautomers: complete basis set calculations at the MP2 and CCSD(T) levels

The total interaction energies of altogether 15 hydrogen-bonded nucleic acid base pairs containing unusual base tautomers were calculated. The geometry properties of all selected adenine-thymine and guanine-cytosine hydrogen-bonded base pairs enable their incorporation into DNA. Unusual base pairing patterns were compared with Watson-Crick H-bonded structures of the adenine-thymine and guanine-cytosine pairs. The complete basis set (CBS) limit of the MP2 interaction energy and the CCSD(T) correction term, determined as the difference between the CCSD(T) and MP2 interaction energies, was evaluated. Extrapolation to the MP2 CBS limit was done using the aug-cc-pVDZ and aug-cc-pVTZ results, and the CCSD(T) correction term was determined with the 6-31G*(0.25) basis set. Final interaction energies were corrected while taking into account both tautomeric penalization determined at the CBS level and solvation/desolvation free energies. The situation for the adenine-thymine pairs is straightforward, and tautomeric pairs are significantly less stable than the Watson-Crick pair consisting of the canonical forms. In the case of the guanine-cytosine pair, the Watson-Crick structure made by canonical forms is again the most stable. The other two structures are, however, energetically rather similar (by 5 and 6 kcal/mol), which provides a very small but non-negligible chance of detecting these structures in the DNA double helix (1:5000). Due to the fact that DNA bases and base pairs incorporated into DNA are solvated less favorably than in isolated systems, this probability represents the very upper limit. The results clearly show how precisely the canonical building blocks of DNA molecules were chosen and how well their stability is maintained.