Computational DNA binding studies of (–)-epigallocatechin-3-gallate

The catechin family of molecules that are present in the leaves of green tea has been under investigation since the antioxidant and anti-inflammatory properties of tea were discovered. Among multiple proposed therapeutic targets of these molecules, the direct interaction with nucleic acids has been proposed and experimentally observed but without clear knowledge about the potential binding modes between these ligands and DNA. One of these catechin structures, (–)-epigallocatechin gallate (EGCG), has three aromatic rings that could interact with double-stranded DNA via terminal base-pair stacking, intercalation, or through groove binding. Using enhanced sampling techniques and molecular dynamics simulations, we have found a stable complex between the EGCG ligand and DNA through intercalation of the trihydroxybenzoate aromatic ring and an ApC step. Moreover, we have calculated the absorption spectra of four possible binding modes and compared these to absorption profiles reported in the literature, and explored the possible DNA sequence preference for the EGCG ligand to bind. Our results suggest that an intercalative mode of interaction through the major groove is possible between the EGCG ligands and DNA with apparently very little DNA sequence selectivity.     

Intercalation of bulky Delta,Delta- and Lambda,Lambda-bis-Ru(II) complex between DNA base pairs

Interaction of Δ,Δ- and Λ,Λ-bis-Ru(II) complexes with native DNA was investigated by isotropic absorption and polarized spectroscopy including circular and linear dichroism (CD and LD). Despite the steric hindrance originating from its four bulky phenanthroline ligands at both ends of the molecule, this molecule rapidly intercalates between DNA base pairs. Intercalation was judged by large hypochromism and red shift in the UV-visible absorption spectra in the absorption region of the bridging moiety as well as in the metal-to-ligand-charge transfer absorption region. Further support for the intercalation is found in the fact that the magnitude of negative reduced LD signal in the absorption region of the bridging moiety was comparable to that of the DNA absorption region, indicating that the bridge connecting the two Ru(II) complexes is nearly parallel to the DNA base planes. No difference in the binding mode between the two enantiomers was observed. In the presence of either bis-Ru(II) complex, ethidium bromide, a classical intercalator, can intercalate into the empty sites but was not able to replace the Ru(II) complexes. Near the saturation, ground state interaction between ethidium and bis-Ru(II) complex was evident by LD.     

Flexible docking of DNA fragments and actinocin derivatives

We have applied molecular docking methods to systems containing nucleic acids as targets and biologically active substances as ligands. The complexes of DNA fragments and actinocin derivatives with different lengths of aminoalkyl side chains were obtained by molecular docking. It was observed that actinocin derivatives could form energetically favourable complexes with DNA both as intercalators and minor groove binders. It was shown that small changes in the binding energy (～1?kcal/mol) could result in complexes with substantially different structure. The complexes of actinocin derivatives and DNA fragments were stabilized by hydrogen bonding upon intercalation and minor groove binding. It was found that the change of solvent-accessible surface area upon binding of the actinocin derivative to DNA linear increased with the growth of methylene groups' number in ligand side chains. The solvation energy change upon binding of actinocin derivatives to DNA calculated by the WSAS method was favourable in the case of small uncharged ligands and unfavourable for positively charged ligands.     

抗菌肽BuforinⅡ衍生物与大肠杆菌基因组DNA的作用机制

【目的】研究抗菌肽BuforinⅡ的衍生物BF2-A/B与大肠杆菌基因组DNA的作用机制。【方法】琼脂糖电泳检测肽对DNA的断裂作用,凝胶阻滞实验研究肽与DNA的结合作用,圆二色谱考察结合肽后DNA结构的变化,荧光光谱分析肽与溴化乙锭竞争性嵌入DNA以及磷酸根对肽与DNA相互作用的影响。【结果】BF2-A/B不断裂基因组DNA而是结合DNA,使DNA双螺旋结构变得松散,削弱碱基对间的堆积作用,并取代EB,使EB-DNA复合体系荧光减弱。而PO43-的加入减弱了肽对DNA-EB荧光的淬灭作用。【结论】衍生肽与DNA的结合方式是先靠静电引力吸附到DNA磷酸基团上,随即插入双螺旋沟槽,嵌入碱基对间。BF2-B有更多的正电荷,更强的插入沟槽和嵌入碱基对的能力,使得其结合DNA的能力比BF2-A强。     

Characterization of interaction between DNA and 4',6-diamidino-2-phenylindole by optical spectroscopy

We have examined the interaction between 4',6-diamidino-2-phenylindole (DAPI) and DNA using flow linear dichroism (LD), circular dichroism (CD), and fluorescence techniques. We show the presence of two spectroscopically distinct binding sites at low binding ratios with saturation values of 0.025 and 0.17, respectively. In both sites DAPI is bound with its long axis approximately parallel to the grooves of the DNA helix. Resolution of CD spectra shows that an exciton component is present at higher binding ratios, which we attribute to the interaction of two accidentally close-lying DAPI molecules. We also find evidence that DAPI, at least in the high-affinity site, binds preferentially to AT-rich regions. From the spectroscopic results, supported by structural considerations, we can completely exclude that DAPI is bound to DNA by intercalation. Binding geometries and site densities are consistent with a location of DAPI in the grooves of DNA, with the high-affinity site most probably in the minor groove.     

Complex of fd gene 5 protein and double-stranded RNA

We report the formation of complexes of the single-stranded DNA binding protein encoded by gene 5 of fd virus, with natural double-stranded RNAs. In the first direct visualization of a complex of the fd gene 5 protein with a double-stranded nucleic acid, we show by electron microscopy that the double-stranded RNA complex has a structure which is distinct from that of complexes with single-stranded DNA and is consistent with uniform coating of the exterior of the double-stranded RNA helix by the protein. Circular dichroism spectral data demonstrate that the RNA double helix in the complex is undisrupted, and that perturbation of the 228-nm circular dichroism assigned to protein tyrosines can occur in the absence of intercalation of nucleotide bases with protein aromatic residues. Our findings emphasize the potential importance of interaction with the sugar-phosphate polynucleotide backbone in binding of the fd gene 5 protein to nucleic acids.     

Unprecedented dual binding behaviour of acridine group of dye: a combined experimental and theoretical investigation for the development of anticancer chemotherapeutic agents

Acridine group of dyes are well known in the field of development of probes for nucleic acid structure and conformational determination because of their relevance in the development of novel chemotherapeutic agents, footprinting agents and for gene manipulation in biotechnology and medicine. Here, we report the interaction of 9-N,N-dimethylaniline decahydroacridinedione (DMAADD), a new class of dye molecule with calf thymus DNA (CT-DNA) which has been studied extensively by means of traditional experimental and theoretical techniques. The changes in the base stacking of CT-DNA upon the binding of DMAADD are reflected in the circular dichroic (CD) spectral studies. Competitive binding study shows that the enhanced emission intensity of ethidium bromide (EB) in presence of DNA was quenched by the addition of DMAADD indicating that it displaces EB from its binding site in DNA and the apparent binding constant has been estimated to be (3.3+/-0.2)x10(5) M(-1). This competitive binding study and further fluorescence experiments reveal that DMAADD is a moderate binder of CT-DNA, while viscosity measurements show that the mode of binding is partial intercalation. Generally, one would expect increase in the melting temperature (T(m)) of DNA in presence of intercalators. Interestingly, an unusual decrease in melting temperature (DeltaT(m) of -4+/-0.2 degrees C) of DNA by the addition of DMAADD was observed. From our knowledge such a decreasing trend in melting point was not reported before for all the possible modes of binding. Molecular modeling gave the pictorial view of the binding model which clearly shows that of the various mode of binding, the dye prefers the major groove binding to the sites rich in GC residues and to the sites rich in AT residues it prefers intercalation mode of binding either through major or minor groove with the inclusion of the N,N-dimethylaniline (DMA) group inside the double helix which has been stacked in between the bases, under physiological relevant pH of 7.5.     

Interaction of nucleic acids with a non-intercalative anti-leukemic compound containing bisquarternary heterocycles

The binding of an antitumour drug with bisquarternary ammonium heterocyclic structure, NSC-101327, to nucleic acids has been examined by using ultraviolet absorption and CD measurements. Like the minor groove-binding oligopeptides, netropsin and distamycin A, the optically inactive chromophoric system of NSC-101327 shows induced Cotton effects in the CD spectra of complexes with various DNAs, RNA and single-stranded polynucleotides. This property directly reflects interaction of NSC-101327 with different types of nucleic acids at moderate ionic strength, which contrasts with previous findings of a higher selective binding of netropsin to B-DNA. However, an efficient interactin of NSC-101327 with dA·dT basepair sequences is demonstrated by a large melting temperature increase of dA·dT-rich DNAs. NSC-101327 also reacts with dG·dC base pairs of B-DNA and forms a complex with Z-DNA of poly(br⁸dG-dC)·poly(br⁸DG-dC). The affinity of NSC-101327 to poly(dG-dC)·poly(dG-dC) is, however, lower, and the CD spectral binding effect depends on the ionic strength. The CD results of the complex with poly(dA-dT)·poly(dA-dT) suggests at least two binding modes, in accordance with previous conclusions. This is indicated by a clear-cut initial increase of the CD signal and a subsequent large decrease to negative CD signals. Competition experiments with netropsin suggest that binding of NSC-101327 occurs preferentially in the minor groove without intercalation. NSC-101327 also tends to interact with lower binding affinity to dG-dC pairs in B-DNA, with rA·rU pairs of RNA and with single-stranded polynucleotides. Thus our results suggest that NSC-101327 represents a DNA groove-binding ligand of lower basepair specificity and lower conformational selectivity compared to the B-specific netropsin probe.     

Minor groove binding of Co(III)meso-tetrakis(N-methylpyridinium-4-yl)porphyrin to various duplex and triplex polynucleotides

The binding site and the geometry of Co(III)meso-tetrakis(N-methylpyridinium-4-yl)porphyrin (CoTMPyP) complexed with double helical poly(dA)·poly(dT) and poly(dG)·poly(dC), and with triple helical poly(dA)·[poly(dT)]₂ and poly(dC)·poly(dG)·poly(dC)⁺ were investigated by circular and linear dichroism (CD and LD). The appearance of monomeric positive CD at a low [porphyrin]/[DNA] ratio and bisignate CD at a high ratio of the CoTMPyP-poly(dA)·poly(dT) complex is almost identical with its triplex counterpart. Similarity in the CD spectra was also observed for the CoTMPyP-poly(dG)·poly(dC) and -poly(dC)·poly(dG)·poly(dC)⁺ complex. This observation indicates that both monomeric binding and stacking of CoTMPyP to these polynucleotides occur at the minor groove. However, different binding geometry of CoTMPyP, when bind to AT- and GC-rich polynucleotide, was observed by LD spectrum. The difference in the binding geometry may be attributed to the difference in the interaction between polynucleotides and CoTMPyP: in the GC polynucleotide case, amine group protrude into the minor groove while it is not present in the AT polynucleotide.     

Identification of binding mechanisms in single molecule-DNA complexes

Changes in the elastic properties of single deoxyribonucleic acid (DNA) molecules in the presence of different DNA-binding agents are identified using atomic force microscope single molecule force spectroscopy. We investigated the binding of poly(dG-dC) dsDNA with the minor groove binder distamycin A, two supposed major groove binders, an alpha-helical and a 3(10)-helical peptide, the intercalants daunomycin, ethidium bromide and YO, and the bis-intercalant YOYO. Characteristic mechanical fingerprints in the overstretching behavior of the studied single DNA-ligand complexes were observed allowing the distinction between different binding modes. Docking of ligands to the minor or major groove of DNA has the effect that the intramolecular B-S transition remains visible as a distinct plateau in the force-extension trace. By contrast, intercalation of small molecules into the double helix is characterized by the vanishing of the B-S plateau. These findings lead to the conclusion that atomic force microscope force spectroscopy can be regarded as a single molecule biosensor and is a potent tool for the characterization of binding motives of small ligands to DNA.     

Triple recognition of B-DNA

A novel conjugate of Hoechst 33258, pyrene and neomycin was synthesized and examined for its binding and stabilization of A-T rich DNA duplexes using spectroscopic and viscometric techniques. The conjugate, containing three well known ligands that bind nucleic acids albeit in different binding modes, was found to significantly stabilize DNA over parent conjugates containing only one or both of the other recognition elements. The study represents the first example of DNA molecular recognition capable of minor/major groove recognition in conjunction with intercalation.     

Relationship between the structure and the DNA binding properties of diazoniapolycyclic duplex- and triplex-DNA binders: efficiency, selectivity, and binding mode

The association of dicationic polycyclic ligands, namely, four diazoniapentaphene derivatives, three diazoniaanthra[1,2-a]anthracenes, diazoniahexaphene, and a partly saturated hydroxy-substituted diazoniapentaphene with double-stranded and triple-helical DNA, was investigated by spectrophotometric and viscosimetric titrations, CD and LD spectroscopy, DNA melting experiments, and molecular modeling studies. All experimental and theoretical data reveal an intercalative DNA-binding mode of the diazoniapentaphenes and diazoniaanthra[1,2-a]anthracenes; the latter have approximately 10-fold higher affinity for the DNA duplex. CD spectroscopic investigations and molecular modeling studies show that only one azonianaphthalene part of the ligand is intercalated between the DNA base pairs, whereas the remaining part of the ligand points outside the intercalation pocket. In contrast, the diazoniahexaphene is a DNA groove binder, which binds selectively to [poly(dAdT)]2. At low ligand-to-DNA ratios (r < 0.15), the diazoniahexaphene also behaves as an intercalator; however, all spectroscopic and viscosimetric data are consistent with significant groove binding of this ligand at r > 0.2. Studies of the interaction of diazoniapolycyclic ions with triplex DNA reveal a preferential binding of both diazoniapentaphenes and diazoniaanthra[1,2-a]anthracenes to the triplex and stabilization thereof. These properties are more pronounced in the case of the hexacyclic diazoniaanthra[1,2-a]anthracenes; however, the diazoniahexaphene shows no preferential binding to the triplex. The DNA binding properties of the diazoniapentaphene derivatives remain essentially the same upon variation of the positions of nitrogen atoms or substitution with methyl groups. In contrast, the interactions of the diazoniaanthra[1,2-a]anthracence isomers with triplex DNA are slightly different. Notably, the 14a,16a-diazoniaanthra[1,2-a]anthracene is among the most efficient triplex stabilizers, with a 9-fold larger binding affinity for the triplex than for the DNA duplex. Moreover, the diazoniapentaphene and diazoniaanthra[1,2-a]anthracene derivatives represent the first examples of triplex-DNA binders that do not require additional aminoalkyl side chains for efficient triplex stabilization.     

Is There Any Interaction Between Telomeric DNA Structures,G-Quadruplex and I-Motif,with Saffron Active Metabolites?

Telomeric DNA contains some unique secondary structures, such as G-quadruplex and I-motif. These structures may be stabilized or changed by binding to specific proteins or small molecules. Herein, we report the in vitro effect of crocin, crocetin, picrocrocin, and safranal on these structures. Circular dichroism (CD) data indicate that crocetin has higher affinity for these structures. Safranal and crocin induce little change in the I-motif and G-quadruplex, respectively. The molecular docking confirms the experimental data and indicates the minor groove binding of ligands with G-quadruplex. The possibility for application of these ligands as sequence-specific drugs should be further investigated.     

The interaction of ellipticine derivatives with nucleic acids studied by optical and 1H-nmr spectroscopy: Effect of size of the heterocyclic ring system

The DNA interaction of derivatives of ellipticine with heterocyclic ring systems with three, four, or five rings and a dimethylaminoethyl side chain was studied. Optical spectroscopy of drug complexes with calf thymus DNA, poly [(dA-dT) · (dA-dT)], or poly [(dG-dC) · (dG-dC)] showed a 10 nm bathochromic shift of the light absorption bands of the pentacyclic and tetracyclic compounds upon binding to the nucleic acids, which indicates binding by intercalation. For the tricyclic compound a smaller shift of 1–3 nm was observed upon binding to the nucleic acids. Flow linear dichroism studies show that the geometry of all complexes is consistent with intercalation of the ring system, except for the DNA and poly [(dG-dC) · (dG-dC)] complexes of the tricyclic compound, where the average angle between the drug molecular plane and the DNA helix axis was found to be 65°. One-dimensional ¹H-nmr spectroscopy was used to study complexes between d(CGCGATCGCG)₂ and the tricyclic and pentacyclic compounds. The results on the pentacyclic compound show nonselective broadening due to intermediate chemical exchange of most oligonucleotide resonances upon drug binding. The imino proton resonances are in slow chemical exchange, and new resonances with upfield shifts approaching 1 ppm appear upon drug binding, which supports intercalative binding of the pentacyclic compound. The results on the tricyclic compound show more rapid binding kinetics and very selective broadening of resonances. The data suggest that the tricyclic compound is in an equilibrium between intercalation and minor groove binding, with a preference to bind close to the AT base pairs with the side chain residing in the minor groove. © 1994 John Wiley & Sons, Inc.     

Mixed mode of ligand-DNA binding results in S-shaped binding curves

S-shaped binding curves often characterize interactions of ligands with nucleic acid molecules as analyzed by different physico-chemical and biophysical techniques. S-shaped experimental binding curves are usually interpreted as indicative of the positive cooperative interactions between the bound ligand molecules. This paper demonstrates that S-shaped binding curves may occur as a result of the "mixed mode" of DNA binding by the same ligand molecule. Mixed mode of the ligand-DNA binding can occur, for example, due to 1) isomerization or dimerization of the ligands in solution or on the DNA lattice, 2) their ability to intercalate the DNA and to bind it within the minor groove in different orientations. DNA-ligand complexes are characterized by the length of the ligand binding site on the DNA lattice (so-called "multiple-contact" model). We show here that if two or more complexes with different lengths of the ligand binding sites could be produced by the same ligand, the dependence of the concentration of the complex with the shorter length of binding site on the total concentration of ligand should be S-shaped. Our theoretical model is confirmed by comparison of the calculated and experimental CD binding curves for bis-netropsin binding to poly(dA-dT) poly(dA-dT). Bis-netropsin forms two types of DNA complexes due to its ability to interact with the DNA as monomers and trimers. Experimental S-shaped bis-netropsin-DNA binding curve is shown to be in good correlation with those calculated on the basis of our theoretical model. The present work provides new insight into the analysis of ligand-DNA binding curves.     

Characterization of dipyridophenazine complexes of ruthenium(II): the light switch effect as a function of nucleic acid sequence and conformation.

Spectroscopic parameters for two novel ruthenium complexes on binding to nucleic acids of varying sequences and conformations have been determined. These complexes, Ru(bpy)2dppz2+ and Ru(phen)2dppz2+ (bpy = 2,2'-bipyridine; phen = 1,10-phenanthroline; dppz = dipyrido[3,2:a-2',3':c]-phenazine) serve as "molecular light switches" for DNA, displaying no photoluminescence in aqueous solution but luminescing intensely in the presence of DNA. The luminescent enhancement observed upon binding is attributed to the sensitivity of the excited state to quenching by water; in DNA, the metal complex, upon intercalation into the helix, is protected from the aqueous solvent, thereby preserving the luminescence. Correlations between the extent of protection (depending upon the DNA conformation) and the luminescence parameters are observed. Indeed, the strongest luminescent enhancement is observed for intercalation into DNA conformations which afford the greatest amount of overlap with access from the major groove, such as in triple helices. Differences are observed in the luminescent parameters between the two complexes which also correlate with the level of water protection. In the presence of nucleic acids, both complexes exhibit biexponential decays in emission. Quenching studies are consistent with two intercalative binding modes for the dppz ligand from the major groove: one in which the metal-phenazine axis lies along the DNA dyad axis and another where the metal-phenazine axis lies almost perpendicular to the DNA dyad axis. Ru(bpy)2dppz2+ and Ru(phen)2dppz2+ are shown here to be unique reporters of nucleic acid structures and may become valuable in the design of new diagnostics for DNA.     

Unspecific DNA binding of the DNA binding domain of the glucocorticoid receptor studied with flow linear dichroism

The unspecific interaction between the DNA-binding domain of the human glucocorticoid receptor and DNA was studied using linear dichroism (LD) and circular dichroism (CD) spectroscopy. The amplitude of the LD signal was found to increase upon addition of protein at ionic strengths less than 60 nM Na+, indicating an increased persistence length of the complex compared to uncomplexed DNA. Analysis of the LD spectrum suggests that the binding does not involve intercalation of tyrosine residues. Evidence of saturation is found at a binding stoichiometry of approximately 5 DNA base pairs per protein monomer.