Minor groove binding of a bis-quaternary ammonium compound: the crystal structure of SN 7167 bound to d(CGCGAATTCGCG)2.

The X-ray crystal structure of the complex between the synthetic antitumour and antiviral DNA binding ligand SN 7167 and the DNA oligonucleotide d(CGCGAATTCGCG)2 has been determined to an R factor of 18.3% at 2.6 A resolution. The ligand is located within the minor groove and covers almost 6 bp with the 1-methylpyridinium ring extending as far as the C9-G16 base pair and the 1-methylquinolinium ring lying between the G4-C21 and A5-T20 base pairs. The ligand interacts only weakly with the DNA, as evidenced by long range contacts and shallow penetration into the groove. This structure is compared with that of the complex between the parent compound SN 6999 and the alkylated DNA sequence d(CGC[e6G]AATTCGCG)2. There are significant differences between the two structures in the extent of DNA bending, ligand conformation and groove binding.     

DNA binding properties of minor groove binders and their influence on the topoisomerase II cleavage reaction

We present titrations of the human δβ-globin gene region with DNA minor groove binders netropsin, bisnetropsin, distamycin, chromomycin and four bis-quaternary ammonium compounds in the presence of calf thymus topoisomerase II and DNase I. With increasing ligand concentration, stimulation and inhibition of enzyme activity were detected and quantitatively evaluated. Additionally we show a second type of stimulation, the appearance of strong new topoisomerase II cleavage sites at high ligand concentrations. The specific binding sites of the minor groove binders of the DNA sequence and their microscopic binding constants were determined from DNase I footprints. A binding mechanism for minor groove binders is proposed in order to explain these results especially when ligand concentration is increased. © 1998 John Wiley & Sons, Ltd.     

Structure of a beta-alanine-linked polyamide bound to a full helical turn of purine tract DNA in the 1:1 motif

Polyamides composed of N-methylpyrrole (Py), N-methylimidazole (Im) and N-methylhydroxypyrrole (Hp) amino acids linked by beta-alanine (beta) bind the minor groove of DNA in 1:1 and 2:1 ligand to DNA stoichiometries. Although the energetics and structure of the 2:1 complex has been explored extensively, there is remarkably less understood about 1:1 recognition beyond the initial studies on netropsin and distamycin. We present here the 1:1 solution structure of ImPy-beta-Im-beta-ImPy-beta-Dp bound in a single orientation to its match site within the DNA duplex 5'-CCAAAGAGAAGCG-3'.5'-CGCTTCTCTTTGG-3' (match site in bold), as determined by 2D (1)H NMR methods. The representative ensemble of 12 conformers has no distance constraint violations greater than 0.13 A and a pairwise RMSD over the binding site of 0.80 A. Intermolecular NOEs place the polyamide deep inside the minor groove, and oriented N-C with the 3'-5' direction of the purine-rich strand. Analysis of the high-resolution structure reveals the ligand bound 1:1 completely within the minor groove for a full turn of the DNA helix. The DNA is B-form (average rise=3.3 A, twist=38 degrees ) with a narrow minor groove closing down to 3.0-4.5 A in the binding site. The ligand and DNA are aligned in register, with each polyamide NH group forming bifurcated hydrogen bonds of similar length to purine N3 and pyrimidine O2 atoms on the floor of the minor groove. Each imidazole group is hydrogen bonded via its N3 atom to its proximal guanine's exocyclic amino group. The important roles of beta-alanine and imidazole for 1:1 binding are discussed.     

Groove width and depth of B-DNA structures depend on local variation in slide.

The groove widths of DNA helix, especially minor groove width, are generally believed to be important for recognition of DNA by various types of ligands. It has been postulated earlier that large negative propeller twist, in the AT rich regions compresses the minor groove of duplex DNA. A systematic study has now been carried out by generating models with different values of local doublet and intra-basepair parameters and calculating their minor groove widths. It is found that several local doublet parameters affect the minor groove width but it depends most strongly on the local step parameters roll and slide when each parameter is considered individually. However, a detailed analysis of the various local parameters within the B-DNA family of crystal structures indicates that propeller twist and slide are most strongly correlated with the observed values of minor groove width. The groove depth is also strongly correlated with slide. Thus the local base sequence dependent variations in slide can modify both the groove width and depth and consequently determine the ligand binding properties of DNA.     

Groove Width and Depth of B-DNA Structures Depend on Local Variation in Slide

Abstract

The groove widths of DNA helix, especially minor groove width, are generally believed to be important for recognition of DNA by various types of ligands. It has been postulated earlier that large negative propeller twist, in the AT rich regions compresses the minor groove of duplex DNA A systematic study has now been carried out by generating models with different values of local doublet and intra-basepair parameters and calculating their minor groove widths. It is found that several local doublet parameters affect the minor groove width but it depends most strongly on the local step parameters roll and slide when each parameter is considered individually. However, a detailed analysis of the various local parameters within the B-DNA family of crystal structures indicates that propeller twist and slide are most strongly correlated with the observed values of minor groove width. The groove depth is also strongly correlated with slide. Thus the local base sequence dependent variations in slide can modify both the groove width and depth and consequently determine the ligand binding properties of DNA.     

On the importance of van der Waals interaction in the groove binding of DNA with ligands: restrained molecular dynamics study

Comparison of interaction energy between an oligonucleotide and a DNA-binding ligand in the minor and major groove modes was made by use of restrained molecular dynamics. Distortion in DNA was found for the major groove mode whereas less significant changes for both ligand and DNA were detected for the minor groove binding after molecular dynamics simulation. The conformation of the ligand obtained from the major groove mode resembles that computed with the ligand soaked in water. The van der Waals contact energy was found to be as significant as electrostatic energy and more important for difference in binding energy between these two binding modes. The importance of van der Waals force in groove binding was supported by computations on the complex formed by the repressor peptide fragment from the bacteriophage 434 and its operator oligonucleotide.     

DNA minor groove recognition by bis-benzimidazole analogues of Hoechst 33258: insights into structure-DNA affinity relationships assessed by fluorescence titration measurements

Fluorescence titration measurements have been used to examine the binding interaction of a number of analogues of the bis -benzimidazole DNA minor groove binding agent Hoechst 33258 with the decamer duplex d(GCAAATTTGC)2. The method of continuous variation in ligand concentration (Job plot analysis) reveals a 1:1 binding stoichiometry for all four analogues; binding constants are independent of drug concentration (in the range [ligand] = 0.1-5 microM). The four analogues studied were chosen in order to gain some insight into the relative importance of a number of key structural features for minor groove recognition, namely (i) steric bulk of the N -methylpiperazine ring, (ii) ligand hydrophobicity, (iii) isohelicity with the DNA minor groove and (iv) net ligand charge. This was achieved, first, by replacing the bulky, non-planar N -methylpiperazine ring with a less bulky planar charged imidazole ring permitting binding to a narrower groove, secondly, by linking the N -methylpiperazine ring to the phenyl end of the molecule to give the molecule a more linear, less isohelical conformation and, finally, by introducing a charged imidazole ring in place of the phenolic OH making it dicationic, enabling the contribution of the additional electrostatic interaction and extended conformation to be assessed. Delta G values were measured at 20 degrees C in the range -47.6 to -37.5 kJ mol-1 and at a number of pH values between 5.0 and 7.2. We find a very poor correlation between Delta G values determined by fluorescence titration and effects of ligand binding on DNA melting temperatures, concluding that isothermal titration methods provide the most reliable method of determining binding affinities. Our results indicate that the bulky N -methylpiperazine ring imparts a large favourable binding interaction, despite its apparent requirement for a wider minor groove, which others have suggested arises in a large part from the hydrophobic effect. The binding constant appears to be insensitive to the isohelical arrangement of the constituent rings which in these analogues gives the same register of hydrogen bonding interactions with the floor of the groove.     

Molecular dynamics simulations and binding free energy analysis of DNA minor groove complexes of curcumin

Curcumin is a natural phytochemical that exhibits a wide range of pharmacological properties, including antitumor and anticancer activities. The similarity in the shape of curcumin to DNA minor groove binding drugs is the motivation for exploring its binding affinity in the minor grooves of DNA sequences. Interactions of curcumin with DNA have not been extensively examined, while its pharmacological activities have been studied and documented in depth. Curcumin was docked with two DNA duplexes, d(GTATATAC)₂ and d(CGCGATATCGCG)₂, and molecular dynamics simulations of the complexes were performed in explicit solvent to determine the stability of the binding. In all systems, the curcumin is positioned in the minor groove in the A·T region, and was stably bound throughout the simulation, causing only minor modifications to the structural parameters of DNA. Water molecules were found to contribute to the stability of the binding of the ligand. Free energy analyses of the complexes were performed with MM-PBSA, and the binding affinities that were calculated are comparable to the values reported for other similar nucleic acid–ligand systems, indicating that curcumin is a suitable natural molecule for the development of minor groove binding drugs.     

Cationic porphyrins as probes of DNA structure.

The DNA binding specificity of a group of cationic manganese porphyrin complexes has been examined using DNase I footprinting methodology and by observing the sites of porphyrin-induced DNA strand scission in the presence of potassium superoxide. The compounds, which possess systematic changes in total charge, its distribution on the periphery on the macrocycle and ligand shape, bind in the minor groove of AT rich regions of DNA. While changes in total charge and charge arrangement do not significantly influence specificity, a shape change which blocks close ligand contact with the minor groove relaxes the original AT specificity causing the compound to cleave at both AT and GC sites. The observed changes in binding sequence specificity were interpreted in terms of electrostatic and steric factors associated with both the compounds and DNA.     

Binding of symmetrical cyanine dyes into the DNA minor groove

Optical methods, such as fluorescence, circular dichroism and linear flow dichroism, were used to study the binding to DNA of four symmetrical cyanine dyes, each consisting of two identical quinoline, benzthiazole, indole, or benzoxazole fragments connected by a trimethine bridge. The ligands were shown to form a monomer type complex into the DNA minor groove. The complex of quinoline-containing ligand with calf thymus DNA appeared to be the most resistant to ionic strength, and it did not dissociate completely even in 1 M NaCl. Binding of cyanine dyes to DNA could also be characterized by possibility to form ligand dimers into the DNA minor groove, by slight preference of binding to AT pairs, as well as by possible intercalation between base pairs of poly(dG)-poly(dC). The correlation found between the binding constants to DNA and the extent of cyanine dyes hydrophobicity estimated as the n-octanol/water partition coefficient is indicative of a significant role of hydrophobic interactions for the ligand binding into the DNA minor groove.     

A study of the interaction of Cr(III) complexes and their selective binding with B-DNA: a molecular modeling approach

Molecular modeling and energy minimisation calculations have been used to investigate the interaction of chromium(III) complexes in different ligand environments with various sequences of B-DNA. The complexes are [Cr(salen)(H(2)O)(2)](+); salen denotes 1, 2 bis-salicylideneaminoethane, [Cr(salprn)(H(2)O)(2)](+); salprn denotes 1, 3 bis- salicylideneaminopropane, [Cr(phen)(3)](3+); phen denotes 1, 10 phenanthroline and [Cr(en)(3)](3+); en denotes ethylenediamine. All the chromium(III) complexes are interacted with the minor groove and major groove of d(AT)(12), d(CGCGAATTCGCG)(2) and d(GC)(12) sequences of DNA. The binding energy and hydrogen bond parameters of DNA-Cr complex adduct in both the groove have been determined using molecular mechanics approach. The binding energy and formation of hydrogen bonds between chromium(III) complex and DNA has shown that all complexes of chromium(III) prefer minor groove interaction as the favourable binding mode.     

DNA minor groove recognition of a non-self-complementary AT-rich sequence by a tris-benzimidazole ligand.

The crystal structure of the non-self-complementary dodecamer DNA duplex formed by d(CG[5BrC]ATAT-TTGCG) and d(CGCAAATATGCG) has been solved to 2.3 A resolution, together with that of its complex with the tris-benzimidazole minor groove binding ligand TRIBIZ. The inclusion of a bromine atom on one strand in each structure enabled the possibility of disorder to be discounted. The native structure has an exceptional narrow minor groove, of 2.5-2.6 A in the central part of the A/T region, which is increased in width by approximately 0.8 A on drug binding. The ligand molecule binds in the central part of the sequence. The benzimidazole subunits of the ligand participate in six bifurcated hydrogen bonds with A:T base pair edges, three to each DNA strand. The presence of a pair of C-H...O hydrogen bonds has been deduced from the close proximity of the pyrrolidine group of the ligand to the TpA step in the sequence.     

Selective binding to AT sequences in DNA by an acridine-linked peptide containing the SPKK motif.

The sequence selectivity of binding to DNA by an acridine-linked peptide ligand has been investigated by means of footprinting methodologies. The ligand conjugates an anilino-acridine intercalating chromophore with the potentially minor groove binder octapeptide SPKKSPKK. This basic peptide corresponds to a highly conserved DNA recognition motif found in histone H1 and several other nonhistone proteins. Three complementary techniques using DNase I, hydroxyl radicals and osmium tetroxide as sequencing probes have been employed to evaluate both the sequence specificity of binding and the drug-induced conformational changes in DNA. The results converge to demonstrate the AT-selectivity and support a model in which the peptide moiety lies in the minor groove. DNA-binding sites of the conjugate are restricted to a few alternating AT-sequences proximal to GC-rich regions. Binding to homooligomeric runs of A and T is clearly disfavoured by the hybrid whereas such sequences represent preferred binding sites for the unsubstituted basic peptide. These differences reflect the influence of the anilino-acridine chromophore, which evidently contributes to the DNA recognition process allowing the peptide only to contact defined DNA sequences.     

Structures of m-iodo Hoechst-DNA complexes in crystals with reduced solvent content: implications for minor groove binder drug design

The DNA photosensitisers m-iodo Hoechst and m-iodo, p-methoxy Hoechst have been co-crystallised with the oligonucleotide d(CGCGAATTCGCG)₂ and their crystal structures determined. The crystals were then subjected to slow dehydration, which reduced their solvent contents from 40 (normal) to 30 (partially dehydrated) and then 20% (fully dehydrated) and caused a reduction in cell volume from 68 000 to 60 000 then 51 000 ų. The dehydration resulted in a dramatic enhancement of diffraction resolution from ~2.6 to beyond 1.5 Å. Crystal structures have also been determined for the partially and fully dehydrated states. The fully dehydrated crystals consist of an infinite polymeric network, in which neighbouring dodecamer duplexes are crosslinked through phosphate oxygens via direct bonding to bridging magnesium cations. This unique three-dimensional structure for DNA is described in detail in the following companion paper. The present paper details evidence from the sequence of crystal structures that the DNA is able to breathe locally, allowing the ligand to leave the minor groove, re-orient in the surrounding solvent medium and then re-enter the groove in a different orientation and location. The rearrangement of the minor groove binding ligands during the dehydration process mimics the binding behaviour of these ligands in solution and in vivo. We also present details of the DNA–ligand interactions that are consistent with a hydrogen atom abstraction mechanism for photocleavage of DNA.     

Hydration of the RNA duplex r(CGCAAAUUUGCG)2 determined by NMR.

The so-called spine of hydration in the minor groove of AnTn tracts in DNA is thought to stabilise the structure, and kinetically bound water detected in the minor groove of such DNA species by NMR has been attributed to a narrow minor groove [Liepinsh, E., Leupin, W. and Otting, G. (1994) Nucleic Acids Res. 22, 2249-2254]. We report here an NMR study of hydration of an RNA dodecamer which has a wide, shallow minor groove. Complete assignments of exchangeable protons, and a large number of non-exchangeable protons in r(CGCAAAUUUGCG)2 have been obtained. In addition, ribose C2'-OH resonances have been detected, which are probably involved in hydrogen bonds. Hydration at different sites in the dodecamer has been measured using ROESY and NOESY experiments at 11.75 and 14.1 T. Base protons in both the major and minor grooves are in contact with water, with effective correlation times for the interaction of approximately 0.5 ns, indicating weak hydration, in contrast to the hydration of adenine C2H in the homologous DNA sequence. NOEs to H1' in the minor groove are consistent with hydration water present that is not observed in the analogous DNA sequence. Hydration kinetics in nucleic acids may be determined by chemical factors such as hydrogen-bonding more than by simple conformational factors such as groove width.     

Minor groove to major groove, an unusual DNA sequence-dependent change in bend directionality by a distamycin dimer

DNA sequence-dependent conformational changes induced by the minor groove binder, distamycin, have been evaluated by polyacrylamide gel electrophoresis. The distamycin binding affinity, cooperativity, and stoichiometry with three target DNA sequences that have different sizes of alternating AT sites, ATAT, ATATA, and ATATAT, have been determined by mass spectrometry and surface plasmon resonance to help explain the conformational changes. The results show that distamycin binds strongly to and bends five or six AT base pair minor groove sites as a dimer with positive cooperativity, while it binds to ATAT as a weak, slightly anticooperative dimer. The bending direction was evaluated with an in phase A-tract reference sequence. Unlike other similar monomer minor groove binding compounds, such as netropsin, the distamycin dimer changes the directionality of the overall curvature away from the minor groove to the major groove. This distinct structural effect may allow designed distamycin derivatives to have selective therapeutic effects.     

Theoretical Study of the Sequence Selectivity of Isolexins,Isohelical DNA Groove Binding Ligands. Proposal for the GC Minor Groove Specific Compounds

Abstract

Atheoretical study is presented of complex formation between DNA fragments of different base sequences and isolexins, “isohelical base reading polymers”, formed of heteroaromatic pentagonal rings joined by appropriate linkers. Extensive computations are performed for the isolexin composed of the furan-pyrrole-furan sequence. They involve charged ligands with propioamidinium groups at both ends as well eis neutral molecules with terminal methyl, carbonyl and amino groups. Two different groups (C=O and NH) are used as linkers between the base reading moieties. The role of these elements on the binding preference of the ligands has been examined. The results show that the mere possibility of formation of hydrogen bonds between a ligand and the nucleic acid bases is not sufficient to ensure its binding specificity which is determined largely by the interplay of electrostatic factors. Thus the dicationic isolexins uniformly prefer AT sequences. For the neutral isolexins the nature of the groups forming the linkers is a major factor in defining the specificity, although these groups do not participate directly in the interaction with DNA The C=O linkers favour binding to AT sequence while the N-H linkers permit preferential binding to the GAG sequence. Finally, for the first time in theoretical computations, a ligand is proposed which should bind preferentially to the minor groove of GC sequences: this ligand is a neutral isolexin composed of three furan rings linked by two N-H groups. This ligand is considered as an improvable prototype. Altogether the results presented open the path for the designing of minor groove ligands specific for any desirable DNA base sequence.