An NMR study on the conformation of the chromomycin-d(GGGGCCCC)2 complex

The conformation of the chromomycin-d(GGGGCCCC)2 complex in aqueous solution was studied by NMR spectroscopy. The NMR spectrum of the complex indicated that the chromomycin binds as a symmetry-related dimer to the minor groove of the central four residues of d(GGGGCCCC)2. The drastic conformational change in the central four residues of d(GGGGCCCC)2 from the B form family to the A-form was demonstrated by the characteristic NOEs and coupling patterns. The change seems to be indispensable for accommodation of the bulky chromomycin dimer in the minor groove. On the basis of the intermolecular NOEs between chromomycin and d(GGGGCCCC)2, the structure of the complex has been constructed and refined by energy minimization.     

Solution structure of the chromomycin-DNA complex

The structure of the chromomycin-DNA complex at the deoxyoctanucleotide duplex level has been determined from one- and two-dimensional proton NMR studies in Mg-containing aqueous solution. The NMR results demonstrate that the antitumor agent binds as a symmetrical dimer to the self-complementary d[T-T-G-G-C-C-A-A] duplex with retention of the 2-fold symmetry in the complex. A set of intermolecular nuclear Overhauser enhancements (NOEs) establishes that two chromomycin molecules in the dimer share the minor groove at the G-G-C-C.G-G-C-C segment in such a way that each hydrophilic edge of the chromophore is located next to the G-G.C-C half-site and each C-D-E trisaccharide chain extends toward the 3'-direction of the octanucleotide duplex. In addition, the A-B disaccharide segment and the hydrophilic side chain of the antitumor agent are directed toward the phosphate backbone. The observed changes in nucleic acid NOEs and coupling patterns on complex formation establish a transition to a wider and shallower minor groove at the central G-G-C-C.G-G-C-C segment required for accommodating the chromomycin dimer. The present demonstration that chromomycin binds as a dimer and switches the conformation of the DNA at its G.C-rich minor groove binding site provides new insights into antitumor agent design and the sequence specificity of antitumor agent-DNA recognition.     

Sequence-dependent recognition of DNA duplexes. Netropsin complexation to the AATT site of the d(G-G-A-A-T-T-C-C) duplex in aqueous solution

We have investigated intermolecular interactions and conformational features of the netropsin X d(G-G-A-A-T-T-C-C) complex by one- and two-dimensional NMR studies in aqueous solution. Netropsin removes the 2-fold symmetry of the d(G-G-A-A-T-T-C-C) duplex at the AATT binding site and to a lesser extent at adjacent dG X dC base pairs resulting in doubling of resonances for specific positions in the spectrum of the complex at 25 degrees C. We have assigned the amide, pyrrole, and CH2 protons of netropsin, and the base and sugar H1' protons of the nucleic acid from an analysis of the nuclear Overhauser effect (NOESY) and correlated (COSY) spectra of the complex at 25 degrees C. We observe intermolecular nuclear Overhauser effects (NOE) between all three amide and both pyrrole protons on the concave face of the antibiotic and the minor groove adenosine H2 proton of the two central A4 X T5 base pairs of the d(G1-G2-A3-A4-T5-T6-C7-C8) duplex. Weaker intermolecular NOEs are also observed between the pyrrole concave face protons and the sugar H1' protons of residues T5 and T6 in the AATT minor groove of the duplex. We also detect intermolecular NOEs between the guanidino CH2 protons at one end of netropsin and adenosine H2 proton of the two flanking A3 X T6 base pairs of the octanucleotide duplex. These studies establish a set of intermolecular contacts between the concave face of the antibiotic and the minor groove AATT segment of the d(G-G-A-A-T-T-C-C) duplex in solution. The magnitude of the NOEs require that there be no intervening water molecules sandwiched between the antibiotic and the DNA so that release of the minor groove spine of hydration is a prerequisite for netropsin complex formation.     

Structure refinement of the chromomycin dimer-DNA oligomer complex in solution.

We have refined the initial docking model of the Mg(II)-co-ordinated chromomycin-d(A2G2C2T2) complex (2 drug equivalents per duplex) by a complete relaxation matrix analysis simulation of the two-dimensional nuclear Overhauser effect (NOESY) spectrum of the complex in 2H2O solution. This relaxation matrix refined structure of the complex exhibits the following characteristics. (1) We observe an unwound and elongated duplex that exhibits characteristics distinct from the A and B-DNA family of helices at the central (G-G-C-C).(G-G-C-C) chromomycin dimer binding and flanking sites. On the other hand sugar puckers, glycosidic torsion angles, displacement of the base-pairs from the helix axis and the minor groove width for this central tetranucleotide segment all fall within the A-family of helical parameters. (2) The chromomycin monomers are aligned in a head-to-tail orientation in the Mg(II)-co-ordinated dimer in the complex. The chromophores are aligned with a slight tilt relative to each other and make an angle of 75 degrees between their planes. The C-D-E trisaccharide segments from individual monomers adopt an extended conformation that projects in opposite directions in the dimer. The divalent metal cation is co-ordinated to the O(1) carbonyl and O(9) enolate atoms of the chromophores and aligns them such that the O(9)-Mg-O(9) angle is 170 degrees while all other O-Mg-O angles are in the 95(+/- 15)degrees range. (3) The sequence specificity of the chromomycin dimer for the widened and shallower (G3-G4-C5-C6).(G3-G4-C5-C6) minor groove binding site is associated with intermolecular hydrogen bonds formed between the OH group at C(8) of the chromophore and the minor groove NH2 group at position 2 and N(3) groups of G4 and between the O(1) oxygen of the E-sugar and the minor groove NH2 group at position 2 of G3 in the complex. (4) Additional intermolecular interactions are primarily van der Waals contacts between anomeric and adjacent CH2 protons on each sugar in the C-D-E trisaccharide segments of the chromomycin dimer and the minor groove surface of the DNA. These results provide insights into the induced conformational transitions required to generate a complementary match between the drug dimer and its DNA binding site on complex formation.     

Dynamics and binding mode of Hoechst 33258 to d(GTGGAATTCCAC)2 in the 1:1 solution complex as determined by two-dimensional 1H NMR.

We have investigated the interaction of the bisbenzimidazole derivative Hoechst 33258 with the self-complementary dodecadeoxynucleotide duplex d(GTGGAATTCCAC)2 using one-dimensional (1D) and two-dimensional (2D) proton nuclear magnetic resonance (1H NMR) spectroscopy. To monitor the extent of complex formation, we used the imino proton region of the 1D 1H NMR spectra acquired in H2O solution. These spectra show that the DNA duplex loses its inherent C2v symmetry upon addition of the drug, indicating that the two molecules form a kinetically stable complex on the NMR time scale (the lifetime of the complex has been measured to be around 450 ms). We obtained sequence-specific assignments for all protons of the ligand and most protons of each separate strand of the oligonucleotide duplex using a variety of homonuclear 2D 1H NMR experiments. The aromatic protons of the DNA strands, which are symmetrically related in the free duplex, exhibit exchange cross peaks in the complex. This indicates that the drug binds in two equivalent sites on the 12-mer, with an exchange rate constant of 2.2 +/- 0.2 s-1. Twenty-five intermolecular NOEs were identified, all involving adenine 2 and sugar 1' protons of the DNA and protons in all four residues of the ligand, indicating that Hoechst 33258 is located in the minor groove at the AATT site. Only protons along the same edge of the two benzimidazole moieties of the drug show NOEs to DNA protons at the bottom of the minor groove. Using molecular mechanics, we have generated a unique model of the complex using distance constraints derived from the intermolecular NOEs. We present, however, evidence that the piperazine group may adopt at least two locally different conformations when the drug is bound to this dodecanucleotide.     

Molecular recognition in noncovalent antitumor agent-DNA complexes: NMR studies of the base and sequence dependent recognition of the DNA minor groove by netropsin

We have investigated intermolecular interactions and conformational features of the netropsin complexes with d(G1-G2-A3-A4-T5-T6-C7-C8) duplex (AATT 8-mer) and the d(G1-G2-T3-A4-T5-A6-C7-C8) duplex (TATA 8-mer) by one and two-dimensional NMR studies in solution. We have assigned the amide, pyrrole and methylene protons of netropsin and the base and sugar H1' protons of the nucleic acid from an analysis of the nuclear Overhauser effect (NOESY) and correlated (COSY) spectra of the complex at 25 degrees C. The directionality of the observed distance-dependent NOEs demonstrates that the 8-mer helices remain right-handed and that the arrangement of concave and convex face protons of netropsin are retained in the complexes. The observed changes in NOE patterns and chemical shift changes on complex formation suggest small conformational changes in the nucleic acid at the AATT and TATA antibiotic binding sites and possibly the flanking G.C base pairs. We observe intermolecular NOEs between all three amide and both pyrrole protons on the concave face of the antibiotic and the minor groove adenosine H2 proton of the two central A4.T5 base pairs of the AATT 8-mer and TATA 8-mer duplexes. The concave face pyrrole protons of the antibiotic also exhibit NOEs to the sugar H1' protons of residues 5 and 6 in the AATT and TATA 8-mer complexes. We also detect intermolecular NOEs between the guanidino and propioamidino methylene protons at either end of netropsin and the adenosine H2 proton of the two flanking A3.T6 base pairs in the AATT 8-mer and T3.A6 base pairs in the TATA 8-mer duplexes. These studies establish a set of nine contacts between the concave face of the antibiotic and the minor groove AATT segment and TATA segment of the 8-mer duplexes in solution. The observed magnitude of the NOEs require that there be no intervening water molecules sandwiched between the concave face of the antibiotic and the minor groove of the DNA so that release of the minor groove spine of hydration is a prerequisite for netropsin complex formation. The observed differences in the netropsin amide proton chemical shifts in the AATT 8-mer and TATA 8-mer complexes suggest differences in the strength and/or type of intermolecular hydrogen bonds at the AATT and TATA binding sites.(ABSTRACT TRUNCATED AT 400 WORDS)     

Chromomycin dimer-DNA oligomer complexes. Sequence selectivity and divalent cation specificity

This paper reports on a solution NMR characterization of the sequence selectivity and metal ion specificity in chromomycin-DNA oligomer complexes in the presence of divalent cations. The sequence selectivity studies have focused on chromomycin complexes with the self-complementary d(A1-A2-G3-G4-C5-C6-T7-T8) duplex containing a pair of adjacent (G3-G4).(C5-C6) steps and the self-complementary d(A1-G2-G3-A4-T5-C6-C7-T8) duplex containing a pair of separated (G2-G3).(C6-C7) steps in aqueous solution. The antitumor agent (chromomycin) and nucleic acid protons have been assigned following analysis of distance connectivities in NOESY spectra and coupling connectivities in DQF-COSY spectra for both complexes in H2O and D2O solution. The observed intermolecular NOEs establish that chromomycin binds as a Mg(II)-coordinated dimer [1 Mg(II) per complex] and contacts the minor-groove edge with retention of 2-fold symmetry centered about the (G3-G4-C5-C6).(G3-G4-C5-C6) segment of the d(A2G2C2T2) duplex. By contrast, complex formation is centered about the (G2-G3-A4-T5).(A4-T5-C6-C7) segment and results in removal of the two fold symmetry of the d(AG2ATC2T) duplex. Thus, the binding of one subunit of the chromomycin dimer at its preferred (G-G).(C-C) site assists in the binding of the second subunit to the less preferred adjacent (A-T).(A-T) site. These observations suggest a hierarchy of chromomycin binding sites, with a strong site detected at the (G-G) step due to the hydrogen-bonding potential of acceptor N3 and donor NH2 groups of guanosine that line the minor groove. The divalent cation specificity has been investigated by studies on the symmetric chromomycin-d(A2G2C2T2) complex in the presence of diamagnetic Mg(II), Zn(II), and Cd(II) cations and paramagnetic Ni(II) and Co(II) cations. A comparative NOESY study of the Mg(II) and Ni(II) symmetric complexes suggests that a single tightly bound divalent cation aligns the two chromomycins in the dimer through coordination to the C1 carbonyl and C9 enolate ions on the hydrophilic edge of each aglycon ring. Secondary divalent cation binding sites involve coordination to the major-groove N7 atoms on adjacent guanosines in G-G steps. This coordination is perturbed on lowering the pH below 6.0, presumably due to protonation of the N7 atoms. The midpoint of the thermal dissociation of the symmetric complex is dependent on the divalent cation with the stability for reversible transitions decreasing in the order Mg(II) greater than Zn(II) greater than Cd(II) complexes.(ABSTRACT TRUNCATED AT 400 WORDS)     

The three-dimensional structure of the 4:1 mithramycin:d(ACCCGGGT)(2) complex: evidence for an interaction between the E saccharides

Mithramycin and chromomycin, two antitumor drugs, each having an identical aglycone and nearly identical disaccharide and trisaccharide side chains, have differing binding properties to a small oligonucleotide, d(ACCCGGGT)(2) (M. A. Keniry et al., Journal of Molecular Biology, 1993, Vol. 231, pp. 753-767). In order to understand the forces that induce four mithramycin molecules to bind to d(ACCCGGGT)(2) instead of two drug molecules in the case of chromomycin, the structure of the 4:2:1 mithramycin: Mg(2+):d(ACCCGGGT)(2) complex was investigated by (1)H-nmr and restrained molecular dynamics. The resulting three-dimensional model showed that in order to accommodate the close approach of one neighboring mithramycin dimer, the inwardly directed CDE saccharide chain of the neighboring mithramycin dimer undergoes a conformational change such that the E saccharide no longer spans the minor groove but reorients so that the hydrophilic face of the E saccharides from the two dimers oppose each other. Two hydrogen bonds are formed between the hydroxyl groups of the two opposing E saccharide groups. The results are interpreted in terms of the differences in stereochemistry and functional group substitutions between mithramycin and chromomycin. A mithramycin dimer is able to self-associate on an oligonucleotide template because it has two hydroxyl groups on the same face of its terminal E saccharide. A chromomycin dimer is unable to self-associate because one of these hydroxyl groups is acetylated and the neighboring hydroxyl group has a stereochemistry that cannot permit close contact of the hydroxyl group with a neighbouring chromomycin dimer.Copyright 2000 John Wiley & Sons, Inc.     

Minor groove hydration of DNA in aqueous solution: sequence-dependent next neighbor effect of the hydration lifetimes in d(TTAA)2 segments measured by NMR spectroscopy.

The hydration in the minor groove of double stranded DNA fragments containing the sequences 5'-dTTAAT, 5'-dTTAAC, 5'-dTTAAA and 5'-dTTAAG was investigated by studying the decanucleotide duplex d(GCATTAATGC)2 and the singly cross-linked decameric duplexes 5'-d(GCATTAACGC)-3'-linker-5'-d(GCGTTAATGC)-3' and 5'-d(GCCTTAAAGC)-3'-linker-5'-d(GCTTTAAGGC)-3' by NMR spectroscopy. The linker employed consisted of six ethyleneglycol units. The hydration water was detected by NOEs between water and DNA protons in NOESY and ROESY spectra. NOE-NOESY and ROE-NOESY experiments were used to filter out intense exchange cross-peaks and to observe water-DNA NOEs with sugar 1' protons. Positive NOESY cross-peaks corresponding to residence times longer than approximately 0.5 ns were observed for 2H resonances of the central adenine residues in the duplex containing the sequences 5'-dTTAAT and 5'-dTTAAC, but not in the duplex containing the sequences 5'-dTTAAA and 5'-dTTAAG. In all nucleotide sequences studied here, the hydration water in the minor groove is significantly more mobile at both ends of the AT-rich inner segments, as indicated by very weak or negative water-A 2H NOESY cross-peaks. No positive NOESY cross-peaks were detected with the G 1'H and C 1'H resonances, indicating that the minor groove hydration water near GC base pairs is kinetically less restrained than for AT-rich DNA segments. Kinetically stabilized minor groove hydration water was manifested by positive NOESY cross-peaks with both A 2H and 1'H signals of the 5'-dTTAA segment in d(GCATTAATGC)2. More rigid hydration water was detected near T4 in d(GCATTAATGC)2 as compared with 5'-d(GCATTAACGC)-3'-linker-5'-d(GCGTTAATGC)-3', although the sequences differ only in a single base pair. This illustrates the high sensitivity of water-DNA NOEs towards small conformational differences.     

Proton exchange and internal motions in two chromomycin dimer-DNA oligomer complexes.

Previous structural studies on the complexes of the chromomycin (CHR) dimer with duplexes of d(A1-A2-G3-G4-C5-C6-T7-T8) and of d(A1-G2-G3-A4-T5-C6-C7-T8) in solution [one Mg(II) and two drugs per duplex] are extended to hydrogen exchange measurements. Exchange of the OH8 proton of chromomycin, measured by real time proton-deuterium exchange, is very slow and requires dissociation of the complex, whose lifetime is thus determined. The lifetimes and apparent dissociation constants of base pairs are deduced from the catalysis of imino proton exchange by ammonia. The four central base pairs, which interact with the CHR chromophores in the minor groove (Gao & Patel, 1990), may open within the complex, but the opening rate is less than in the free duplex by one to two orders of magnitude. The activation energy for base-pair opening and the differences between the lifetimes of adjacent pairs suggest that single base-pair opening is the predominant imino proton exchange pathway in all cases. In the symmetrical complex of chromomycin with the first duplex, the lifetimes of the central base pairs (G3.C6 and G4.C5) are in the same range (52 and 29 ms, respectively, at 38 degrees C). In the asymmetrical complex formed with the second duplex, the base-pair lifetimes in the G2-G3-A4-T5 segment that interacts with the chromophore moiety are strongly increased. That of G3.C6 is particularly long. Above 50 degrees C, exchange of the G3 imino proton is opening limited.(ABSTRACT TRUNCATED AT 250 WORDS)     

NMR studies of the interaction of chromomycin A3 with small DNA duplexes. Binding to GC-containing sequences

The interaction of chromomycin A3 with the oligodeoxyribonucleotides 1, d(ATGCAT), 2, d(ATCGAT), 3, d(TATGCATA), and 4, d(ATAGCTAT), has been investigated by 1H and 31P NMR. In the presence of Mg2+, chromomycin binds strongly to the three GC-containing oligomers 1, 3, and 4 but not to the CG-containing oligomer 2. The proton chemical shift changes for 1 and 3 are similar, and these DNA duplexes appear to bind with a stoichiometry of 2 drugs:1 Mg2+:1 duplex. The same stoichiometry of 2 drugs:1 duplex is confirmed with 4; however, proton chemical shift changes differ. An overall C2 symmetry is exhibited by the drug complex with 1, 3, and 4. At a molar ratio of 2.0 (drugs:duplex), no free DNA proton NMR signals remain. Two-dimensional nuclear Overhauser exchange spectroscopy (NOESY) of the saturated chromomycin complex with 1 and 3 positions both chromomycinone hydroxyls and the E carbohydrates in the minor groove and provides evidence suggesting that the B carbohydrates lie on the major-groove side. This is supported by several dipolar coupling cross-peaks between the drug and the DNA duplex. Drug-induced conformational changes in duplex 1 are evaluated over a range of NOESY mixing times and found to possess some characteristics of both B-DNA and A-DNA, where the minor groove is wider and shallower. A widening of the minor groove is essential for the DNA duplex to accommodate two drug molecules. This current minor-groove model is a substantial revision of our earlier major-groove model [Keniry, M.A., Brown, S.C., Berman, E., & Shafer, R.H. (1987) Biochemistry 26, 1058-1067] and is in agreement with the model recently proposed by Gao and Patel [Gao, X., & Patel, D. J. (1989a) Biochemistry 28, 751-762].     

Evidence for DAPI intercalation in CG sites of DNA oligomer [d(CGACGTCG)]2: a 1H NMR study.

The interaction between 4',6-diamidino-2-phenylindole (DAPI) and the DNA oligomer [d(CGACGTCG)]2 has been investigated by proton one- and two-dimensional NMR spectroscopy in solution. Compared with the minor groove binding of the drug to [d(GCGATCGC)]2, previously studied by NMR spectroscopy, the interaction of DAPI with [d(CGACGTCG)]2 appears markedly different and gives results typical of a binding mechanism by intercalation. C:G imino proton signals of the [d(CGACGTCG)]2 oligomer as well as DAPI resonances appear strongly upfield shifted and sequential dipolar connectivities between cytosine and guanine residues show a clear decrease upon binding. Moreover, protons lying in both the minor and major grooves of the DNA double helix appear involved in the interaction, as evidenced principally by intermolecular drug-DNA NOEs. In particular, the results indicate the existence of two stereochemically non-equivalent intercalation binding sites located in the central and terminal adjacent C:G base pairs of the palindromic DNA sequence. Different lifetimes of the complexes were also observed for the two sites of binding. Moreover, due to the fast exchange on the NMR timescale between free and bound species, different interactions in dynamic equilibrium with the observed intercalative bindings were not excluded.     

Solution structure of the novel antitumor drug UCH9 complexed with d(TTGGCCAA)2 as determined by NMR.

Aureolic acid group compounds, such as chromomycin A3(CHM) and mithramycin (MIT), are known as antitumor drugs. Recently we isolated a novel aureolic acid group antitumor drug, UCH9, from Streptomyces sp. The chemical structure of UCH9 is unique in that mono- (A ring) and tetrasaccharide (B-E rings) segments and a longer hydrophobic sidechain are attached to the chromophore, while di- and trisaccharide segments and a methyl group are attached to it in the cases of CHM and MIT. It has been shown by two-dimensional agarose gel electrophoresis that the three drugs cause DNA unwinding, UCH9 causing less than the others. A photo-CIDNP experiment has revealed that UCH9 binds to the minor groove of DNA. The structure of the UCH9-d(TTGGCCAA)2 complex has been determined by 1H NMR and simulated annealing calculations. The obtained structure indicates that UCH9 binds as a dimer to the minor groove of d(TTGGCCAA)2, like CHM and MIT, but that the structural change in DNA induced on binding of UCH9 is moderate in comparison with those on binding of the other two drugs. It turns out that the dimer structure of UCH9, stabilized presumably through a hydrophobic interaction involving the A, D and E rings and the hydrophobic sidechain is different from that of CHM and thus DNA can interact with UCH9 in the minor groove with a moderate structural change.     

NMR and computational characterization of mitomycin cross-linked to adjacent deoxyguanosines in the minor groove of the d(T-A-C-G-T-A).d(T-A-C-G-T-A) duplex

Two-dimensional homonuclear and heteronuclear NMR and minimized potential energy calculations have been combined to define the structure of the antitumor agent mitomycin C (MC) cross-linked to deoxyguanosines on adjacent base pairs in the d(T1-A2-C3-G4-T5-A6).d(T7-A8-C9-G10-T11-A12) duplex. The majority of the mitomycin and nucleic acid protons in the MC-X 6-mer complex have been assigned from through-bond and through-space two-dimensional proton NMR studies in aqueous solution at 5 and 20 degrees C. The C3.G10 and G4.C9 base pairs are intact at the cross-link site and stack on each other in the complex. The amino protons of G4 and G10 resonate at 9.36 and 8.87 ppm and exhibit slow exchange with solvent H2O. The NMR experimental data establish that the mitomycin is cross-linked to the DNA through the amino groups of G4 and G10 and is positioned in the minor groove. The conformation of the cross-link site is defined by a set of NOEs between the mitomycin H1" and H2" protons and the nucleic acid imino and amino protons of G4 and the H2 proton of A8 and another set of NOEs between the mitomycin geminal H10" protons and the nucleic acid imino and amino protons of G10 and the H2 proton of A2. Several phosphorus resonances of the d(T-A-C-G-T-A) duplex shift dramatically on mitomycin cross-link formation and have been assigned from proton-detected phosphorus-proton two-dimensional correlation experiments. The proton chemical shifts and NOEs establish fraying at the ends of the d(T-A-C-G-T-A) duplex, and this feature is retained on mitomycin cross-link formation. The base-base and base-sugar NOEs exhibit similar patterns for symmetry-related steps on the two nucleic acid strands in the MC-X 6-mer complex, while the proton and phosphorus chemical shifts are dramatically perturbed at the G10-T11 step on cross-link formation. The NMR distance constraints have been included in minimized potential energy computations on the MC-X 6-mer complex. These computations were undertaken with the nonplanar five-membered ring of mitomycin in each of two pucker orientations. The resulting low-energy structures MX1 and MX2 have the mitomycin cross-linked in a widened minor groove with the chromophore ring system in the vicinity of the G10-T11 step on one of the two strands in the duplex.(ABSTRACT TRUNCATED AT 400 WORDS)     

Protein--DNA contacts in the structure of a homeodomain--DNA complex determined by nuclear magnetic resonance spectroscopy in solution.

The 1:1 complex of the mutant Antp(C39----S) homeodomain with a 14 bp DNA fragment corresponding to the BS2 binding site was studied by nuclear magnetic resonance (NMR) spectroscopy in aqueous solution. The complex has a molecular weight of 17,800 and its lifetime is long compared with the NMR chemical shift time scale. Investigations of the three-dimensional structure were based on the use of the fully 15N-labelled protein, two-dimensional homonuclear proton NOESY with 15N(omega 2) half-filter, and heteronuclear three-dimensional NMR experiments. Based on nearly complete sequence-specific resonance assignments, both the protein and the DNA were found to have similar conformations in the free form and in the complex. A sufficient number of intermolecular 1H-1H Overhauser effects (NOE) could be identified to enable a unique docking of the protein on the DNA, which was achieved with the use of an ellipsoid algorithm. In the complex there are intermolecular NOEs between the elongated second helix in the helix-turn-helix motif of the homeodomain and the major groove of the DNA. Additional NOE contacts with the DNA involve the polypeptide loop immediately preceding the helix-turn-helix segment, and Arg5. This latter contact is of special interest, both because Arg5 reaches into the minor groove and because in the free Antp(C39----S) homeodomain no defined spatial structure could be found for the apparently flexible N-terminal segment comprising residues 0-6.     

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.     

Structure, dynamics and hydration of the nogalamycin-d(ATGCAT)2Complex determined by NMR and molecular dynamics simulations in solution.

The structure of the 1:1 nogalamycin:d(ATGCAT)2 complex has been determined in solution from high-resolution NMR data and restrained molecular dynamics (rMD) simulations using an explicit solvation model. The antibiotic intercalates at the 5'-TpG step with the nogalose lying along the minor groove towards the centre of the duplex. Many drug-DNA nuclear Overhauser enhancements (NOEs) in the minor groove are indicative of hydrophobic interactions over the TGCA sequence. Steric occlusion prevents a second nogalamycin molecule from binding at the symmetry-related 5'-CpA site, leading to the conclusion that the observed binding orientation in this complex is the preferred orientation free of the complication of end-effects (drug molecules occupy terminal intercalation sites in all X-ray structures) or steric interactions between drug molecules (other NMR structures have two drug molecules bound in close proximity), as previously suggested. Fluctuations in key structural parameters such as rise, helical twist, slide, shift, buckle and sugar pucker have been examined from an analysis of the final 500 ps of a 1 ns rMD simulation, and reveal that many sequence-dependent structural features previously identified by comparison of different X-ray structures lie within the range of dynamic fluctuations observed in the MD simulations. Water density calculations on MD simulation data reveal a time-averaged pattern of hydration in both the major and minor groove, in good agreement with the extensive hydration observed in two related X-ray structures in which nogalamycin is bound at terminal 5'-TpG sites. However, the pattern of hydration determined from the sign and magnitude of NOE and ROE cross-peaks to water identified in 2D NOESY and ROESY experiments identifies only a few "bound" water molecules with long residence times. These solvate the charged bicycloaminoglucose sugar ring, suggesting an important role for water molecules in mediating drug-DNA electrostatic interactions within the major groove. The high density of water molecules found in the minor groove in X-ray structures and MD simulations is found to be associated with only weakly bound solvent in solution.     

Solution structure of the nogalamycin-DNA complex

The nogalamycin-d(A-G-C-A-T-G-C-T) complex (two drugs per duplex) has been generated in aqueous solution and its structure characterized by a combined application of two-dimensional NMR experiments and molecular dynamics calculations. Two equivalents of nogalamycin binds to the self-complementary octanucleotide duplex with retention of 2-fold symmetry in solution. We have assigned the proton resonances of nogalamycin and the d(A1-G2-C3-A4-T5-G6-C7-T8) duplex in the complex and identified the intermolecular proton-proton NOEs that define the alignment of the antitumor agent at its binding site on duplex DNA. The analysis was greatly aided by a large number of intermolecular NOEs involving exchangeable protons on both the nogalamycin and the DNA in the complex. The molecular dynamics calculations were guided by 274 intramolecular nucleic acid distance constraints, 90 intramolecular nogalamycin distance constraints, and 104 intermolecular distance constraints between nogalamycin and the nucleic acid protons in the complex. The aglycon chromophore intercalates at (C-A).(T-G) steps with the long axis of the aglycon approximately perpendicular to the long axis of the flanking C3.G6 and A4.T5 base pairs. The aglycon selectively stacks over T5 and G6 on the T5-G6-containing strand with the aglycon edge containing OH-4 and OH-6 substituents directed toward the C3-A4-containing strand. The C3.G6 and A4.T5 base pairs are intact but buckled at the intercalation site with a wedge-shaped alignment of C3 and A4 on the C3-A4 strand compared to the parallel alignment of T5 and G6 on the T5-G6 strand in the complex. The nogalose sugar in a chair conformation, the aglycon ring A in a half-chair conformation, and the COOCH3-10 side chain form a continuous domain that is sandwiched within the walls of the minor groove and spans the three base pair (G2-C3-A4).(T5-G6-C7) segment. The nogalose ring is positioned in the minor groove such that its nonpolar face is directed toward the G6-C7 sugar-phosphate backbone while its polar face containing OCH3 groups is directed toward the G2-C3 sugar-phosphate backbone in the complex. The intermolecular contacts include a nonpolar patch of aglycon (CH3-9) and nogalose (CH3-3') methyl groups forming van der Waals contacts with the base-sugar residues in the minor groove and intermolecular hydrogen bonds involving the amino groups of G2 and G6 with the ether oxygens OCH3-3' and O7, respectively, on the nogalose sugar.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.