Binding of a Hoechst dye to d(CGCGATATCGCG) and its influence on the conformation of the DNA fragment

Hoechst dye 33258 is a planar drug molecule that binds to the minor groove of DNA, especially where there are a number of A.T base pairs. We have solved the structure of the Hoechst dye bound to the DNA dodecamer d(CGCGATATCGCG) at 2.3 A. This structure is compared to that of the same dodecamer with the minor-groove-binding drug netropsin bound to it, as well as to structures that have been solved for this Hoechst dye bound to a DNA dodecamer containing the central four base pairs with the sequence AATT. We find that the position of the Hoechst drug in this dodecamer is quite different from that found in the other dodecamer since it has an opposite orientation compared to the other two structures. The drug covers three of the four A.T base pairs and extends its piperazine ring to the first G.C base pair adjacent to the alternating AT segment. Furthermore, the drug binding has modified the structure of the DNA dodecamer. Other DNA dodecamers with alternating AT sequences show an alternation in the size of the helical twist between the ApT step (small twist) and the TpA step (large twist). In this structure the alternation is reversed with larger twists in the ApT steps than in the TpA step. In addition, there is a rotation of one of the thymine bases in the DNA dodecamer that is associated with hydrogen bonding to the Hoechst drug. This structure illustrates the considerable plasticity found in the DNA molecule when it binds to different planar molecules inserted into the minor groove.     

Molecular structure of the netropsin-d(CGCGATATCGCG) complex: DNA conformation in an alternating AT segment

The molecular structure of the complex between a minor groove binding drug (netropsin) and the DNA dodecamer d(CGCGATATCGCG) has been solved and refined by single-crystal X-ray diffraction analysis to a final R factor of 20.0% to 2.4-A resolution. The crystal is similar to that of the other related dodecamers with unit cell dimensions of a = 25.48 A, b = 41.26 A, and c = 66.88 A in the space group P2(1)2(1)2(1). In the complex, netropsin binds to the central ATAT tetranucleotide segment in the narrow minor groove of the dodecamer B-DNA double helix as expected. However, in the structural refinement the drug is found to fit the electron density in two orientations equally well, suggesting the disordered model. This agrees with the results from solution studies (chemical footprinting and NMR) of the interactions between minor groove binding drugs (e.g., netropsin and distamycin A) and DNA. The stabilizing forces between drug and DNA are provided by a combination of ionic, van der Waals, and hydrogen-bonding interactions. No bifurcated hydrogen bond is found between netropsin and DNA in this complex due to the unique dispositions of the hydrogen-bond acceptors (N3 of adenine and O2 of thymine) on the floor of the DNA minor groove. Two of the four AT base pairs in the ATAT stretch have low propeller twist angles, even though the DNA has a narrow minor groove. Alternating helical twist angles are observed in the ATAT stretch with lower twist in the ApT steps than in the TpA step.     

Solution structure of DAPI selectively bound in the minor groove of a DNA T.T mismatch-containing site: NMR and molecular dynamics studies.

The solution structure of the complex between 4', 6-diamidino-2-phenylindole (DAPI) and DNA oligomer [d(GCGATTCGC)]2, containing a central T.T mismatch, has been characterized by combined use of proton one- and two-dimensional NMR spectroscopy, molecular mechanics and molecular dynamics computations including relaxation matrix refinement. The results show that the DAPI molecule binds in the minor groove of the central region 5'-ATT-3' of the DNA oligomer, which predominantly adopts a duplex structure with a global right-handed B-like conformation. In the final models of the complex, the DAPI molecule is located nearly isohelical with its NH indole proton oriented towards the DNA helix axis and forming a bifurcated hydrogen bond with the carbonyl O2 groups of a mismatched T5 and the T6 residue of the opposite strand. Mismatched thymines adopt a wobble base pair conformation and are found stacked between the flanking base pairs, inducing only minor local conformational changes in global duplex structure. In addition, no other binding mechanisms were observed, showing that minor groove binding of DAPI to the mismatch-containing site is favoured in comparison with any other previously reported interaction with G.C sequences.     

The molecular structure of the complex of Hoechst 33258 and the DNA dodecamer d(CGCGAATTCGCG).

The crystal structure of the complex between the dodecamer d(CGCGAATTCGCG) and a synthetic dye molecule Hoechst 33258 was solved by X-ray diffraction analysis and refined to an R-factor of 15.7% at 2.25 A resolution. The crescent-shaped Hoechst compound is found to bind to the central four AATT base pairs in the narrow minor groove of the B-DNA double helix. The piperazine ring of the drug has its flat face almost parallel to the aromatic bisbenzimidazole ring and lies sideways in the minor groove. No evidence of disordered structure of the drug is seen in the complex. The binding of Hoechst to DNA is stabilized by a combination of hydrogen bonding, van der Waals interaction and electrostatic interactions. The binding preference for AT base pairs by the drug is the result of the close contact between the Hoechst molecule and the C2 hydrogen atoms of adenine. The nature of these contacts precludes the binding of the drug to G-C base pairs due to the presence of N2 amino groups of guanines. The present crystal structural information agrees well with the data obtained from chemical footprinting experiments.     

Conformational properties and thermodynamics of the RNA duplex r(CGCAAAUUUGCG)2: comparison with the DNA analogue d(CGCAAATTTGCG)2.

The thermodynamic stability of nine dodecamers (four DNA and five RNA) of the same base composition has been compared by UV-melting. TheDeltaG of stabilisation were in the order: r(GACUGAUCAGUC)2>r(CGCAAATTTGCG)2 approximately r(CGCAUAUAUGCG)2>d(CGCAAATTTGCG)2 approximately r(CGCAAAUUUGCG)2>d(CGCATATATGCG)2 approximately d(GACTGATCAGTC)2>r(CGCUUUAAAGCG)2 approximately d(CGCTTTAAAGCG)2. Compared with the mixed sequences, both r(AAAUUU) and r(UUUAAA) are greatly destablising in RNA, whereas in DNA, d(TTTAAA) is destabilising but d(AAATTT) is stabilising, which has been attributed to the formation of a special B'structure involving large propeller twists of the A-T base pairs. The solution structure of the RNA dodecamer r(CGCAAAUUUGCG)2has been determined using NMR and restrained molecular dynamics calculations to assess the conformational reasons for its stability in comparison with d(CGCAAATTTGCG)2. The structures refined to a mean pairwise r.m.s.d. of 0.89+/-0.29 A. The nucleotide conformations are typical of the A family of structures. However, although the helix axis displacement is approximately 4.6 A into the major groove, the rise (3.0 A) and base inclination ( approximately 6 degrees ) are different from standard A form RNA. The extensive base-stacking found in the AAATTT tract of the DNA homologue that is largely responsible for the higher thermodynamic stability of the DNA duplex is reduced in the RNA structure, which may account for its low relative stability.     

Conformation of B-DNA containing O6-ethyl-G-C base pairs stabilized by minor groove binding drugs: molecular structure of d(CGC[e6G]AATTCGCG complexed with Hoechst 33258 or Hoechst 33342.

O6-ethyl-G (e6G) is an important DNA lesion, caused by the exposure of cells to alkylating agents such as N-ethyl-N-nitrosourea. A strong correlation exists between persistence of e6G lesion and subsequent carcinogenic conversion. We have determined the three-dimensional structure of a DNA molecule incorporating the e6G lesion by X-ray crystallography. The DNA dodecamer d(CGC[e6G]AATTCGCG), complexed to minor groove binding drugs Hoechst 33258 or Hoechst 33342, has been crystallized in the space group P212121, isomorphous to other related dodecamer DNA crystals. In addition, the native dodecamer d(CGCGAATTCGCG) was crystallized with Hoechst 33342. All three new structures were solved by the molecular replacement method and refined by the constrained least squares procedure to R-factors of approximately 16% at approximately 2.0 A resolution. In the structure of three Hoechst drug-dodecamer complexes in addition to the one published earlier [Teng et al. (1988) Nucleic Acids Res., 16, 2671-2690], the Hoechst molecule lies squarely at the central AATT site with the ends approaching the G4-C21 and the G16-C9 base pairs, consistent with other spectroscopic data, but not with another crystal structure reported [Pjura et al. (1987) J. Mol. Biol., 197, 257-271]. The two independent e6G-C base pairs in the DNA duplex adopt different base pairing schemes. The e6G4-C21 base pair has a configuration similar to a normal Watson-Crick base pair, except with bifurcated hydrogen bonds between e6G4 and C21, and the ethyl group is in the proximal orientation. In contrast, the e6G16-C9 base pair adopts a wobble configuration and the ethyl group is in the distal orientation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Probing the conformations of eight cloned DNA dodecamers; CGCGAATTCGCG, CGCGTTAACGCG, CGCGTATACGCG, CGCGATATCGCG, CGCAAATTTGCG, CGCTTTAAAGCG, CGCGGATCCGCG and CGCGGTACCGCG.

The self complementary DNA dodecamers d(CGCGAATTCGCG), d(CGCGTTAACGCG), d(CGCGTATACGCG), d(CGCGATATCGCG), d(CGCAAATTTGCG), d(CGCTTTAAAGCG), d(CGCGGATCCGCG) and d(CGCGGTACCGCG) have been cloned into the Smal site of plasmid pUC19. Radiolabelled polylinker fragments containing these inserts have been digested with nucleases and chemical agents, probing the structure of the central AT base pairs. The sequences AATT and AAATTT are relatively resistant to digestion by DNase I, micrococcal nuclease and hydroxyl radicals, consistent with the suggestion that they possess a narrow minor groove. Nuclease digestion of TTAA is much more even, and comparable to that at mixed sequence DNA. TpA steps in ATAT, TATA and GTAC are cut less well by DNAse I than in TTAA. DNasel cleavage of surrounding bases, especially CpG is strongly influenced by the nature of the central sequence.     

Base pair opening dynamics of a 2-aminopurine substituted Eco RI restriction sequence and its unsubstituted counterpart in oligonucleotides.

Studies of 1H NMR selective saturation recovery were performed to determine the imino proton exchange with solvent water of the base pairs in the Eco RI endonuclease recognition sequence GAATTC, placed at the center of self-complementary decamer and dodecamer oligonucleotides. In one oligonucleotide the innermost adenine was replaced by the fluorescent base analogue 2-aminopurine (2AP). From the measurements at different concentrations of TRIS buffer acting as proton exchange catalyst, base pair lifetimes were evaluated. The results at 25 degrees show that the AT base pairs have lifetimes of the order of a few ms, whereas the surrounding GC base pairs in a dodecamer have lifetimes of about 100 ms. The (2AP)T base pair has a shorter lifetime than the corresponding AT base pair. The temperature dependent optical absorption, and for the 2AP containing oligonucleotide fluorescence, were used to study the single strand-duplex equilibrium of the decamers. The results indicate that NMR and the optical techniques, although applied at very different concentrations, monitor the same conformational transition of the oligonucleotide.     

NMR studies of the complex between the decadeoxynucleotide d-(GCATTAATGC)2 and a minor-groove-binding drug

Nearly all 1H NMR lines of the complex formed between the bis(quaternary ammonium) heterocycle 4-[p-[p-(4-quinolylamino)benzamido]anilino]pyridine (1, also known as SN 6999) and the decadeoxyribonucleoside nonaphosphate d-(GCATTAATGC)2 were sequentially assigned by using one- and two-dimensional NMR techniques. Intermolecular nuclear Overhauser effects between the ligand and the DNA show that the drug binds in the minor groove of the DNA, interacting with the central A-T base pairs. Over the temperature range from 277 to 313 K, the lifetime of the drug in the DNA binding sites is short relative to the NMR time scale, since fast exchange is observed for all but a few protons. A model for the binding of 1 to d-(GCATTAATGC)2 is proposed, where the drug binds to two equivalent sites covering approximately five A-T base pairs, which assumes exchange of 1 between these two binding sites.     

Crystal structure of a B-DNA dodecamer containing inosine, d(CGCIAATTCGCG), at 2.4 A resolution and its comparison with other B-DNA dodecamers.

The crystal structure of the dodecamer, d(CGCIAATTCGCG), has been determined at 2.4 A resolution by molecular replacement, and refined to an R-factor of 0.174. The structure is isomorphous with that of the B-DNA dodecamer, d(CGCGAATTCGCG), in space group P2(1)2(1)2(1) with cell dimensions of a = 24.9, b = 40.4, and c = 66.4 A. The initial difference Fourier maps clearly indicated the presence of inosine instead of guanine. The structure was refined with 44 water molecules, and compared to the parent dodecamer. Overall the two structures are very similar, and the I:C forms Watson-Crick base pairs with similar hydrogen bond geometry to the G:C base pairs. The propeller twist angle is low for I4:C21 and relatively high for the I16:C9 base pair (-3.2 degrees compared to -23.0 degrees), and the buckle angles alter, probably due to differences in the contacts with symmetry related molecules in the crystal lattice. The central base pairs of d(CGCIAATTCGCG) show the large propeller twist angles, and the narrow minor groove that characterize A-tract DNA, although I:C base pairs cannot form the major groove bifurcated hydrogen bonds that are possible for A:T base pairs.     

Two-dimensional NMR studies of d(GGTTAATGCGGT).d(ACCGCATTAACC) complexed with the minor groove binding drug SN-6999.

The dodecadeoxynucleotide duplex d(GGTTAATGCGGT).d(ACCGCATTAACC) and its 1:1 complex with the minor groove binding drug SN-6999 have been prepared and studied by two-dimensional 1H nuclear magnetic resonance spectroscopy. Complete sequence-specific assignments have been obtained for the free duplex by standard methods. The line widths of the resonances in the complex are greater than those observed for the free duplex, which complicates the assignment process. Extensive use of two-quantum spectroscopy was required to determine the scalar correlations for identifying all of the base proton and most of the 1'H-2'H-2'H spin subsystems for the complex. This permitted unambiguous sequence-specific resonance assignments for the complex, which provides the necessary background for a detailed comparison of the structure of the duplex, with and without bound drug. A series of intermolecular NOEs between drug and DNA were identified, providing sufficient structural constraints to position the drug in the minor groove of the duplex. However, the combination of NOEs observed can only be rationalized by a model wherein the drug binds in the minor groove of the DNA in both orientations relative to the long helix axis and exchanges rapidly between the two orientations. The drug binds primarily in the segment of five consecutive dA-dT base pairs d(T3T4A5A6T7).d(A18T19T20A21A22), but surprisingly strong interactions are found to extend one residue in the 3' direction along each strand to G8 and C23. The observation of intermolecular contacts to residues neighboring the AT-rich region demonstrates that the stabilization of the bis(quaternary ammonium) heterocycle family of AT-specific, minor groove binding drugs is not based exclusively on interactions with dA-dT base pairs.     

1H NMR studies on the interaction between distamycin A and a symmetrical DNA dodecamer

High-resolution NMR techniques have been used to examine the structural and dynamical features of the interaction between distamycin A and the self-complementary DNA dodecamer duplex d-(CGCGAATTCGCG)2. The proton resonances of d(CGCGAATTCGCG)2 have been completely assigned by previous two-dimensional NMR studies [Hare, D. R., Wemmer, D. E., Chou, S. H., Drobny, G., & Reid, B. R. (1983) J. Mol. Biol. 171, 319-336]. Addition of the asymmetric drug molecule to the symmetric dodecamer leads to the formation of an asymmetric complex as evidenced by a doubling of DNA resonances over much of the spectrum. In two-dimensional exchange experiments, strong cross-peaks were observed between uncomplexed DNA and drug-bound DNA resonances, permitting direct assignment of many drug-bound DNA resonances from previously assigned free DNA resonances. Weaker exchange cross-peaks between formerly symmetry related DNA resonances indicate that the drug molecule flips head-to-tail on one duplex with half the frequency at which it leaves the DNA molecule completely. In experiments performed in H2O, nuclear Overhauser effects (NOEs) were observed from each drug amide proton to an adenine C2H and a pyrrole H3 ring proton. In two-dimensional nuclear Overhauser experiments performed on D2O solutions, strong intermolecular NOEs were observed between each of the three pyrrole H3 resonances of the drug and an adenine C2H resonance, with weaker NOEs observed between the drug H3 resonances and C1'H resonances. The combined NOE data allow us to position the distamycin A unambiguously on the DNA dodecamer, with the drug spanning the central AATT segment in the minor groove.     

Interaction of berenil with the EcoRI dodecamer d(CGCGAATTCGCG)2 in solution studied by NMR

The conformation of the EcoRI dodecamer d(CGCGAATTCGCG)2 has been examined in solution by 1H and 31P NMR. Spin-spin coupling constants and nuclear Overhauser (NOE) enhancement spectroscopy show that all deoxyriboses lie in the south domain, with a small admixture of the north conformation (0-20%). The time dependence of the nuclear Overhauser enhancements also reveals a relatively uniform conformation at the glycosidic bonds (average angle, chi = -114 degrees). The average helical twist is 36.5 degrees (9.8 base pairs per turn). Tilt angles are small (in the range 0 to -10 degrees), and roll angles are poorly determined. Unlike single-crystal X-ray studies of the same sequence, there is no evidence for asymmetry in the structure. Both the NOE intensities and 31P relaxation data imply conformational anomalies at the C3-G4/C9-G10 and the A5-A6/T7-T8 steps. Berenil binds in 1:1 stoichiometry to the dodecamer with high affinity (Kd = 1 microM at 298 K) and causes substantial changes in chemical shifts of the sugar protons of nucleotides Ado 5-Cyt 9 and of the H2 resonances of the two Ado residues. No significant asymmetry appears to be induced in the DNA conformation on binding, and there is no evidence for intercalation, although the binding site is not centrosymmetric. NOEs are observed between the aromatic protons of berenil and the H1' of both Thy 7 and Thy 8, as well as to Ado 5 and Ado 6 H2. These results firmly establish that berenil binds via the minor groove and closely approaches the nucleotides Ado 6, Thy 7, and Thy 8. On the basis of quantitative NOE spectroscopy and measurements of spin-spin coupling constants, changes in the conformations of the nucleotides are found to be small. Using the observed NOEs between the ligand and the DNA together with the derived glycosidic torsion angles, we have built models that satisfy all of the available solution data. The berenil molecule binds at the 5'-AAT (identical to 5'-ATT on the complementary strand) site such that (i) favorable hydrogen bonds are formed between the charged amidinium groups and the N3 atoms of Ado 6 and Ado 18 and (ii) the ligand is closely isohelical with the floor of the minor groove.     

Quantitative structure of a complex between a minor-groove-specific drug and a bent DNA decamer duplex: use of 2D NMR data and NOESY constrained energy minimization

Two-dimensional nuclear magnetic resonance (2D NMR) studies on d(GA4T4C)2 and d(GT4A4C)2 [Sarma, M.H., et al. (1988) Biochemistry 27, 3423-3432; Gupta G., et al. (1988) Biochemistry 27, 7909-7919] showed that A.T pairs are propeller twisted. As a result, A/T tracts form a straight rigid structural block with an array of bifurcated inter base pair H bonds in the major groove. It was demonstrated (previous paper) that replacement of methyl group by hydrogen (changing from T to U) in the major groove does not disrupt the array of bifurcated H bonds in the major groove. In this article, we summarize results of 2D NMR and molecular mechanic studies on the effect of a minor-groove-binding A.T-specific drug on the structure d(GA4T4C)2. A distamycin analogue (Dst2) was used for this study. It is shown that Dst2 binds to the minor groove of d(GA4T4C)2 mainly driven by van der Waals interaction between A.T pairs and the drug; as a consequence, an array of bifurcated H bonds can be formed in the minor groove between amide/amino protons of Dst2 and A.T pairs of DNA. NOESY data suggest that Dst2 predominantly binds at the central 5 A.T pairs. NOESY data also reveal that, upon drug binding, d(GA4T4C)2 does not undergo any significant change in conformation from the free state; i.e., propeller-twisted A.T pairs are still present in DNA and hence the array of bifurcated H bonds must be preserved in the major groove. NOESY data for the A5-T6 sequence also indicate that there is little change in junction stereochemistry upon drug binding.     

The P1 phage replication protein RepA contacts an otherwise inaccessible thymine N3 proton by DNA distortion or base flipping

The RepA protein from bacteriophage P1 binds DNA to initiate replication. RepA covers one face of the DNA and the binding site has a completely conserved T that directly faces RepA from the minor groove at position +7. Although all four bases can be distinguished through contacts in the major groove of B-form DNA, contacts in the minor groove cannot easily distinguish between A and T bases. Therefore the 100% conservation at this position cannot be accounted for by direct contacts approaching into the minor groove of B-form DNA. RepA binding sites with modified base pairs at position +7 were used to investigate contacts with RepA. The data show that RepA contacts the N3 proton of T at position +7 and that the T=A hydrogen bonds are already broken in the DNA before RepA binds. To accommodate the N3 proton contact the T₊₇ /A_+7^′ base pair must be distorted. One possibility is that T₊₇ is flipped out of the helix. The energetics of the contact allows RepA to distinguish between all four bases, accounting for the observed high sequence conservation. After protein binding, base pair distortion or base flipping could initiate DNA melting as the second step in DNA replication.     

Base recognition mechanism of bleomycin: solution structure of d(GGGGAGCTCCCC)2 based on 1H-NMR and restrained molecular dynamics.

The self-complementary d(GGGGAGCTCCCC) dodecanucleotide cleavage by bleomycin occurs at G(4)pA(5) site rather than G(6)pC(7) site which is known as the preferential sequence. The molecular structure of this dodecamer is observed as the distorted B-DNA by the CD spectra and proton NMR measurements. Three-dimensional structures in solution evaluated by molecular dynamics calculations with inter proton distance restraints have the distorted form of the minor groove structure at G(6)pC(7) site. These evidences offer the recognition mechanism model of the DNA base sequence by bleomycin.     

Crystal and molecular structure of the alternating dodecamer d(GCGTACGTACGC) in the A-DNA form: comparison with the isomorphous non-alternating dodecamer d(CCGTACGTACGG).

The crystal structure of the alternating dodecamer d(GCGTACGTACGC) (5'-GC) has been determined to a resolution of 2.55A using oscillation film data. The crystals belong to space group P6(1) 22, a = b = 46.2A, c = 71.5A with one strand in the asymmetric unit, and are isomorphous with a previously described non-alternating dodecamer, d(CCGTACGTACGG) (5'-CC). Refinement by X-PLOR/NUCLSQ gave a final R factor of 14.2% for 1089 observations. The molecule adopts the A-DNA form. The interchange of the terminal base pairs in the two dodecamers results in differences in the intermolecular contacts and may account for the differences in the bending. This dodecamer shows an axial deflection of 30 degrees, in the direction of the major groove compared to 20 degrees in 5'-CC and may be a consequence of additional contacts generated in 5'-GC by the interchange of end base pairs. The high helical axis deflection appreciably influences the local helical parameters. The molecule exhibits relatively high inclination angles, and has a narrow major groove. The helical parameters when described relative to the dyad-related hexamer halves of the molecule give more reasonable values. The crystal packing, local helical parameters, torsion angles, and hydration are described and also compared with the non-alternating 5'-CC dodecamer.     

Histone h1(0) and its carboxyl-terminal domain bind in the major groove of DNA

The binding of histone H1(0) to T4 bacteriophage DNA was investigated using thermal denaturation of the DNA titrated with varying concentrations of protein. The H1(0) used was expressed in and purified from a strain of E. coli and is therefore homogeneous with respect to H1 subtype and posttranslational modifications. Two types of T4 DNA were used: wild-type, which contains a modification of the cytosine residues that projects into the major groove: and a mutant type, which lacks the modification of the cytosines. Data were compared to simulated thermal denaturation curves to determine estimates for binding affinity and binding site size in base pairs of the protein. Analysis of the data yielded values of 10(8) M(-1) for K, the binding affinity, and 10 base pairs for n, the number of base pairs covered by one protein, for the mutant T4 DNA. Analysis of the wild-type DNA data suggested that the glucose projecting into the major groove of this DNA decreases the number of sites to which the H1(0) protein can bind, indicating that there are interactions between the protein and the major groove of DNA. The binding site size on this DNA is 10 base pairs, the same as on the unmodified DNA. The affinity for wild-type DNA is slightly higher, 10(9) M(-1). Data were collected and analyzed for binding of two domains of the protein as well, the carboxyl-terminal domain and the central globular domain. Binding of the carboxyl-terminal domain was quantitatively and qualitatively similar to that of the full-length protein. In contrast, binding of the globular domain was quite different: it binds much more weakly, with a K of 6 x 10(4) M(-1), and covers fewer base pairs, with an n of 3. Also, there was no evidence that the globular domain interacts with the major groove of DNA.     

Interaction of distamycin A and netropsin with quadruplex and duplex structures: a comparative 1H-NMR study

Homonuclear NMR techniques have been used to investigate the interactions of the minor groove binding agents distamycin A (Dist-A) and the related drug netropsin (Net) with three quadruplexes characterized by different groove widths: [d(TGGGGT)]4 (Q1), [d(GGGGTTTTGGGG)]2 (Q2), and d(GGGGTTGGGGTGTGGGGTTGGGG) (Q3). Netropsin has been found to be in a fast chemical exchange with all three kinds of quadruplexes, whereas Dist-A interacts tightly with Q1 and, at a less extent, with Q2. In order to determine the degree of selectivity of Dist-A for two- rather than four-stranded DNA, we titrated with Dist-A an equimolar solution of Ql and the duplex d(CGCAAATTTGCG)2 (D). This comparative 1H-NMR study allowed us to conclude that Dist-A and, consequently, Net possess higher affinity for duplex DNA.