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.     

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.     

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.     

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)     

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.     

Interactions of DNA binding ligands with PNA-DNA hybrids.

The interactions of two representative mixed-sequence (one with an AT-stretch) PNA-DNA duplexes (10 or 15 base-pairs) and a PNA2/DNA triplex with the DNA binding reagents distamycin A, 4',6-diamidino-2-phenylindole (DAPI), ethidium bromide, 8-methoxy-psoralen and the delta and lambda enantiomers of Ru(phen)2-dppz2+ have been investigated using optical spectroscopic methods. The behaviour of these reagents versus two PNA-PNA duplexes has also been investigated. With triple helical poly(dA)/(H-T10-Lys-NH2)2 no significant intercalative binding was detected for any of the DNA intercalators, whereas DAPI, a DNA minor groove binder, was found to exhibit a circular dichroism with a positive sign and amplitude consistent with minor groove binding. Similarly, a PNA-DNA duplex containing a central AATA motif, a typical minor groove binding site for the DNA minor groove binders distamycin A and DAPI, showed binding for both of these drugs, though with strongly reduced affinity. No important interactions were found for any of the ligands with a PNA-DNA duplex consisting of a ten base-pair mixed purine-pyrimidine sequence with only two AT base-pairs in the centre. Nor did any of the ligands show any detectable binding to the PNA-PNA duplexes (one containing an AATT motif). Various PNA derivatives with extentions of the backbone, believed to increase the flexibility of the duplex to opening of an intercalation slot, were tested for intercalation of ethidium bromide or 8-methoxypsoralen into the mixed sequence PNA-DNA duplex, however, without any observation of improved binding. The importance of the ionic contribution of the deoxyribose phosphate backbone, versus interactions with the nucleobases, for drug binding to DNA is discussed in the light of these findings.     

DNase I-induced DNA conformation. 2 A structure of a DNase I-octamer complex.

The structure of a complex between DNase I and d(GCGATCGC)2 has been solved by molecular replacement and refined to an R-factor of 0.174 for all data between 6 and 2 A resolution. The nicked octamer duplexes have lost a dinucleotide from the 3' ends of one strand and are hydrogen-bonded across a 2-fold axis to form a quasi-continuous double helix of 14 base-pairs. DNase I is bound in the minor groove of the B-type DNA duplex forming contacts in and along both sides of the minor groove extending over a total of six base-pairs. As a consequence of binding of DNase I to the DNA-substrate the minor groove opens by about 3 A and the duplex bends towards the major groove by about 20 degrees. Apart from these more global distortions the bound duplex also shows significant deviations in local geometry. A major cause for the observed perturbations in the DNA conformation seems to be the stacking type interaction of a tyrosine ring (Y76) with a deoxyribose. In contrast, the enzyme structure is nearly unchanged compared to free DNase I (0.49 A root-mean-square deviations for main-chain atoms) thus providing a rigid framework to which the DNA substrate has to adapt on binding. These results confirm the hypothesis that groove width and stiffness are major factors determining the global sequence dependence of the enzyme's cutting rates. The nicked octamer present in the crystals did not allow us to draw detailed conclusions about the catalytic mechanism but confirmed the location of the active site near H134 on top of the central beta-sheets. A second cut of the DNA induced by diffusion of Mn2+ into the crystals may suggest the presence of a secondary active site in DNase I.     

NMR studies on the binding of antitumor drug nogalamycin to DNA hexamer d(CGTACG).

The interactions between a novel antitumor drug nogalamycin with the self-complementary DNA hexamer d(CGTACG) have been studied by 500 MHz two dimensional proton nuclear magnetic resonance spectroscopy. When two nogalamycins are mixed with the DNA hexamer duplex in a 2:1 ratio, a symmetrical complex is formed. All non-exchangeable proton resonances (except H5' & H5") of this complex have been assigned using 2D-COSY and 2D-NOESY methods at pH 7.0. The observed NOE cross peaks are fully consistent with the 1.3 A resolution x-ray crystal structure (Liaw et al., Biochemistry 28, 9913-9918, 1989) in which the elongated aglycone chromophore is intercalated between the CpG steps at both ends of the helix. The aglycone chromophore spans across the GC Watson-Crick base pairs with its nogalose lying in the minor groove and the aminoglucose lying in the major groove of the distorted B-DNA double helix. The binding conformation suggests that specific hydrogen bonds exist in the complex between the drug and guanine-cytosine bases in both grooves of the helix. When only one drug per DNA duplex is present in solution, there are three molecular species (free DNA, 1:1 complex and 2:1 complex) in slow exchange on the NMR time scale. This equilibrium is temperature dependent. At high temperature the free DNA hexamer duplex and the 1:1 complex are completely destabilized such that at 65 degrees C only free single-stranded DNA and the 2:1 complex co-exist. At 35 degrees C the equilibrium between free DNA and the 1:1 complex is relatively fast, while that between the 1:1 complex and the 2:1 complex is slow. This may be rationalized by the fact that the binding of nogalamycin to DNA requires that the base pairs in DNA open up transiently to allow the bulky sugars to go through. A separate study of the 2:1 complex at low pH showed that the terminal GC base pair is destabilized.     

Structural features and hydration of a dodecamer duplex containing two C.A mispairs.

X-ray diffraction techniques have been used to characterise the crystal and molecular structure of the deoxyoligomer d(C-G-C-A-A-A-T-T-C-G-C-G) at 2.5A resolution. The final R factor is 0.19 with the location of 78 solvent molecules. The oligomer crystallises in a B-DNA type conformation with two strands coiled about each other to produce a duplex. This double helix consists of four A.T and six G.C Watson-Crick base pairs and two C.A mispairs. The mismatched base pairs adopt a "wobble" type structure with the cytosine displaced laterally into the major groove, the adenine into the minor groove. We have proposed that the two close contacts observed in the C.A pairing represent two hydrogen bonds one of which results from protonation of adenine. The mispairs are accommodated in the double helix with small adjustments in the conformation of the sugar-phosphate backbone. Details of the backbone conformation, base stacking interactions, thermal parameters and the hydration are now presented and compared with those of the native oligomer d(C-G-C-G-A-A-T-T-C-G-C-G) and with variations of this sequence containing G.T and G.A mispairs.     

The structure of DAPI bound to DNA

The structure of the DNA fluorochrome 4'-6-diamidine-2-phenyl indole (DAPI) bound to the synthetic B-DNA oligonucleotide C-G-C-G-A-A-T-T-C-G-C-G has been solved by single crystal x-ray diffraction methods, at a resolution of 2.4 A. The structure is nearly isomorphous with that of the native DNA molecule alone. With one DAPI and 25 waters per DNA double helix, the residual error is 21.5% for the 2428 reflections above the 2-sigma level. DAPI inserts itself edgewise into the narrow minor groove, displacing the ordered spine of hydration. DAPI and a single water molecule together span the four AT base pairs at the center of the duplex. The indole nitrogen forms a bifurcated hydrogen bond with the thymine O2 atoms of the two central base pairs, as with netropsin and Hoechst 33258. The preference of all three of these drugs for AT regions of B-DNA is a consequence of three factors: (1) The intrinsically narrower minor groove in AT regions than in GC regions of B-DNA, leading to a snug fit of the flat aromatic drug rings between the walls of the groove. (2) The more negative electrostatic potential within the minor groove in AT regions, attributable in part to the absence of electropositive-NH2 groups along the floor of the groove, and (3) The steric advantage of the absence of those same guanine-NH2 groups, thus permitting the drug molecule to sink deeper into the groove. Groove width and electrostatic factors are regional, and define the relative receptiveness of a section of DNA since they operate over several contiguous base pairs. The steric factor is local, varying from one base pair to the next, and hence is the means of fine-tuning sequence specificity.     

Solution structure of the covalent sterigmatocystin-DNA adduct.

Sterigmatocystin and aflatoxin are potent mutagens that contaminate foodstuffs stored under conditions that permit fungal growth. These food mycotoxins can be metabolically activated to their epoxides, which subsequently form covalent adducts with DNA and can eventually induce tumor development. We have generated the sterigmatocystin-d(A1-A2-T3-G4-C5-A6-T7-T8) covalent adduct (two sterigmatocystins per duplex) by reacting sterigmatocystin-1,2-epoxide with the self-complementary d(A-A-T-G-C-A-T-T) duplex and determined its solution structure by the combined application of two-dimensional NMR experiments and molecular dynamics calculations. The self-complementary duplex retains its 2-fold symmetry following covalent adduct formation of sterigmatocystin at the N7 position of G4 residues on each strand of the duplex. The H8 proton of [ST]G4 exchanges rapidly with water and resonates at 9.58 ppm due to the presence of the positive charge on the guanine ring following adduct formation. We have assigned the exchangeable and nonexchangeable proton resonances of sterigmatocystin and the duplex in the covalent adduct and identified the intermolecular proton-proton NOEs that define the orientation and mode of binding of the mutagen to duplex DNA. The analysis was aided by intermolecular NOEs between the sterigmatocystin protons with both the major groove and minor groove protons of the DNA. The molecular dynamics calculations were aided by 180 intramolecular nucleic acid constraints, 16 intramolecular sterigmatocystin constraints, and 56 intermolecular distance constraints between sterigmatocystin and the nucleic acid protons in the adduct. The sterigmatocystin chromophore intercalates between the [ST]G4.C5 and T3.A6 base pairs and stacks predominantly over the modified guanine ring in the adduct duplex. The overall conformation of the DNA remains right-handed on adduct formation with unwinding of the helix, as well as widening of the minor groove. Parallel NMR studies on the sterigmatocystin-d(A1-A2-A3-G4-C5-T6-T7-T8) covalent adduct (two sterigmatocystins per duplex) provide supportive evidence that the mutagen covalently adducts the N7 position of G4 and its chromophore intercalates to the 5' side of the guanine and stacks over it. The present NMR-molecular dynamics studies that define a detailed structure for the sterigmatocystin-DNA adduct support key structural conclusions proposed previously on the basis of a qualitative analysis of NMR parameters for the adduct formed by the related food mutagen aflatoxin B1 and DNA [Gopalakrishnan, S., Harris, T. M., & Stone, M. P. (1990) Biochemistry 29, 10438-10448].     

Electronic structure,vibrational assignments and simulation studies with A/T rich DNA duplex of an aromatic bis-amidine derivative

In this paper, computational investigations have been carried out on an aromatic bis-amidine which is considered to be crucial due to its peculiar properties including anti-Pneumocystis carinii pneumonia(PCP), anti-inflammatory and anticancer activities. The raw structure of an aromatic bis-amidine namely; 2,5-bis[4-(N-cyclohexyl-amidino)phenyl]furan was retrieved, optimized and geometrical parameters were computed. The computational results have been compared with those of reported experimental values. In order to check its binding capability, we pave the way a step further by the interaction of the molecule with DNA duplex, 5′(CGCGAATTCGCG)3′, which consisted of A/T base pairs in its central region. In addition to geometrical, MEP, HOMO-LUMO analyses and IR assignments, molecular docking with DNA has also been performed. The best docked complex was subjected to molecular dynamics simulation for 50 ns using AMBER force field. Free energy of binding has been calculated using MM/PBSA method. The outcomes demonstrate that the molecule recognizes both the strands of DNA duplex through hydrogen bonding within the minor groove side, preferably at A/T rich region and remains stable during the course of dynamics. It may be concluded that the compound shows better binding capability with duplex under study and may be used as a drug lead against Pneumocystis carinii pneumonia.     

Sequence specific molecular recognition and binding of a monocationic bis-imidazole lexitropsin to the decadeoxyribonucleotide d-[(GATCCGTATG).(CATACGGATC)]: structural and dynamic aspects of intermolecular exchange studied by 1H-NMR

The non-exchangeable and imino proton NMR resonances of the non self-complementary decadeoxyribonucleotide d-[(GATCCGTATG).(GATACGGATC)] as well as those of the 1:1 complex of the monocatonic bis-imidazole lexitropsin 1 to this sequence have been assigned by using a combination of NOE difference, COSY and NOESY techniques. Confirmation of complete annealing of the two non self-complementary decamer strands to give the duplex decadeoxyribonucleotide is obtained by the detection of ten imino protons. It is established that the sugar-base orientations of all the bases in the duplex decamer are anti. From NOE studies, it is concluded that the duplex oligomer is right-handed and adopts a conformation in solution that belongs to the B family. A population analysis reveals that the sugar moieties exist predominantly in the S-form (2'-endo-3'-exo). Addition of 1 to the DNA solution leads to doubling of the resonances for CH6(4,5), GH8(6), TH6(7) and T-CH3(7). The base, anomeric H1' and imino proton signals for the base sequence 5'-CCGT undergo the most marked drug-induced chemical shift changes. These results provide evidence that the lexitropsin is bound to the sequence 5'-CCGT in the minor groove of the DNA. NOE measurements between the amide protons (NH1 and NH4) and the imino proton (IV and V) signals confirmed the location and orientation of 1 in the 1:1 complex, with the imino terminus oriented to C(4). The specific binding of 1 to the sequence 5'-CCGT-3' deduced in this study is in agreement with the footprinting data obtained using the Hind III/Nci fragment from pBR322 DNA [Kissinger et al. 1987 (13)]. Intramolecular NOEs observed between H4 and H9 of the lexitropsin suggest that the molecule is not planar, but subjected to propeller twisting, in both the free and bound forms. Furthermore, NOE measurements permit assignment of the DNA duplex in the 1:1 complex to the B-form, which is similar to that of the free DNA. The [(T7A8T9).(A12T13A14)] segment of the DNA shows better stacking, by propeller twisting, compared to the rest of the molecule in the free as well as the complex forms. The intermolecular rate of exchange of 1 between the equivalent 5'-CCGT sites, at a concentration of 12 mM, is estimated to be approximately 88s-1 at 308 degrees K with delta G not equal to of 63 +/- 5 KJ mol-1.     

Flexibility of DNA in 2:1 drug-DNA complexes--simultaneous binding of two DAPI molecules to DNA.

Simultaneous binding of two DAPI molecules in the minor groove of (dA)15.(dT)15 B-DNA helix has been simulated by molecular mechanics calculations. The energy minimised structure shows some novel features in relation to binding of DAPI molecules as well as the flexibility of the grooves of DNA helices. The minor groove of the helix expands locally considerably (to 15 angstroms) to accommodate the two DAPI molecules and is achieved by positive propeller twisting of base pairs at the binding site concomitant with small variations in the local nucleotide stereochemistry. The expansion also brings forth simultaneously a contraction in the width of the major groove spread over to a few phosphates. These findings demonstrate another facet of the flexible stereochemistry of DNA helices in which the local features are significantly altered without being propagated beyond a few base pairs, and with the rest of the regions retaining the normal structure. Both the DAPI molecules are engaged in specific hydrogen bonds with the bases and non specific interactions with phosphates. Stacking interactions of DAPI molecules between themselves as well as with sugar-phosphate backbone contribute to the stability of the complex. The studies provide a stereochemical support to the experimental findings that under high drug-DNA ratio DAPI could bind in the 2:1 ratio.     

H-NMR studies on d(GCTTAAGC)2 and its complex with berenil.

Two-dimensional (2D) 1H-NMR spectroscopy has been used to analyze the structure of d(GCTTAAGC)2 and its interaction with berenil in solution. Nuclear Overhauser enhancement connectivities enabled sequential assignments of nearly all proton resonances in the self-complementary octamer duplex and demonstrated that the oligonucleotide is primarily in a B-type conformation. No major conformational changes were observed by the addition of berenil, but proton resonances of the two adenosine nucleotides shifted substantially. Intermolecular nuclear Overhauser effects between berenil and the DNA duplex revealed that the drug binds via the minor groove of d(GCTTAAGC)2 in the A.T-base-pair region. At 18 degrees C the twofold symmetry of the duplex is preserved on berenil binding. However, strongly shifted proton resonances broadened significantly. A model is proposed for the berenil-d(GCTTAAGC)2 complex involving fast exchange of berenil between two equivalent symmetry-related binding sites, which span the 5'-TAA-3' region and are asymmetrically disposed with respect to the dyad axis of the duplex. These results are compared with previous studies on the berenil-d(GCAATTGC)2 complex.     

Synthesis of a dA-dT base pair analogue and its effects on DNA-ligand binding

Two nucleoside derivatives containing the base analogues 3-deazaadenine and 3-methyl-2-pyridone have been prepared as analogues of dA and dT, respectively. After conversion into the appropriately protected phosphoramidites, DNA sequences were prepared with site-specifically placed analogues. When present in a duplex DNA sequence, the analogues result in the deletion of one or both of the hydrogen bonding functional groups (the N3-nitrogen of dA and the O2-carbonyl of dT) present in the minor groove. Binding by two ligands, 4',6-diamidine-2-phenyl indole (DAPI) and Hoechst 33258 in the minor groove has been probed using a variety of DNA sequences. These sequences contain a d(GAATTC)2 core with analogue nucleosides substituted for one or more of the dA and dT residues. DAPI bound strongly to any sequence that contained both O2-carbonyls of the central two dT residues. The presence of a dc3A residue did in some cases enhance binding. With one of the central O2-carbonyls deleted, the binding was noticeably reduced, and with both absent, no significant binding could be detected. Similar although less dramatic results were observed with Hoechst 33258 binding to analogue sequences.     

Stereochemical control of small molecule binding to bulged DNA: comparison of structures of spirocyclic enantiomer-bulged DNA complexes

The solution structure of the complex formed between an oligonucleotide containing a two-base bulge (5'-CACGCAGTTCGGAC.5'-GTCCGATGCGTG) and ent-DDI, a designed synthetic agent, has been elucidated using high-resolution NMR spectroscopy and restrained molecular dynamic simulation. Ent-DDI is a left-handed wedge-shaped spirocyclic molecule whose aglycone portion is an enantiomer of DDI, which mimics the spirocyclic geometry of the natural product, NCSi-gb, formed by base-catalyzed activation of the enediyne antibiotic neocarzinostatin. The benzindanone moiety of ent-DDI intercalates between the A6.T21 and the T9.A20 base pairs, overlapping with portions of the purine bases; the dihydronaphthalenone moiety is positioned in the minor groove along the G7-T8-T9 bulge sequence; and the aminoglycoside is in the middle of the minor groove, approaching A20 of the nonbulged strand. This alignment of ent-DDI along the DNA helical duplex is in the reverse direction to that of DDI. The aminoglycoside moiety of ent-DDI is positioned in the 3' direction from the bulge region, whereas that of the DDI is positioned in the 5' direction from the same site. This reverse binding orientation within the bulge site is the natural consequence of the opposite handedness imposed by the spirocyclic ring junction and permits the aromatic ring systems of the two spirocyclic enantiomers access to the bulge region. NMR and CD data indicate that the DNA in the DDI-bulged DNA complex undergoes a larger conformational change upon complex formation in comparison to the ent-DDI-bulged DNA, explaining the different binding affinities of the two drugs to the bulged DNA. In addition, there are different placements of the bulge bases in the helical duplex in the two complexes. One bulge base (G7) stacks inside the helix, and the other one (T8) is extrahelical in the DDI-bulged DNA complex, whereas both bulge bases in the ent-DDI-bulged DNA complex prefer extrahelical positions for drug binding. Elucidation of the detailed binding characteristics of the synthetic spirocyclic enantiomers provides a rational basis for the design of stereochemically controlled drugs for bulge binding sites.     

NF-kappa B binding mechanism: a nuclear magnetic resonance and modeling study of a GGG --> CTC mutation

We present the solution structure of the nonpalindromic 16 bp DNA 5'd(CTGCTCACTTTCCAGG)3'. 5'd(CCTGGAAAGTGAGCAG)3' containing a mutated kappaB site for which the mutation of a highly conserved GGG tract of the native kappaB HIV-1 site to CTC abolishes NF-kappaB binding. 1H and 31P NMR spectroscopies have been used together with molecular modeling to determine the fine structure of the duplex. NMR data show evidence for a BI-BII equilibrium of the CpA.TpG steps at the 3'-end of the oligomer. Models for the extreme conformations reached by the mutated duplex (denoted 16M) are proposed in agreement with the NMR data. Since the distribution of BII sites is changed in the mutated duplex compared to that of the native duplex (denoted 16N), large differences are induced in the intrinsic structural properties of both duplexes. In particular, in BII structures, 16M shows a kink located at the 3'-end of the duplex, and in contrast, 16N exhibits an intrinsic global curvature toward the major groove. Whereas 16N can reach a conformation very favorable for the interaction with NF-kappaB, 16M cannot mimic such a conformation and, moreover, its deeper and narrower major groove could hinder the DNA-protein interactions.     

Interaction between the Z-type DNA duplex and 1,3-propanediamine: crystal structure of d(CACGTG)2 at 1.2 A resolution

The crystal structure of a hexamer duplex d(CACGTG)(2) has been determined and refined to an R-factor of 18.3% using X-ray data up to 1.2 A resolution. The sequence crystallizes as a left-handed Z-form double helix with Watson-Crick base pairing. There is one hexamer duplex, a spermine molecule, 71 water molecules, and an unexpected diamine (Z-5, 1,3-propanediamine, C(3)H(10)N(2)) in the asymmetric unit. This is the high-resolution non-disordered structure of a Z-DNA hexamer containing two AT base pairs in the interior of a duplex with no modifications such as bromination or methylation on cytosine bases. This structure does not possess multivalent cations such as cobalt hexaammine that are known to stabilize Z-DNA. The overall duplex structure and its crystal interactions are similar to those of the pure-spermine form of the d(CGCGCG)(2) structure. The spine of hydration in the minor groove is intact except in the vicinity of the T5A8 base pair. The binding of the Z-5 molecule in the minor grove of the d(CACGTG)(2) duplex appears to have a profound effect in conferring stability to a Z-DNA conformation via electrostatic complementarity and hydrogen bonding interactions. The successive base stacking geometry in d(CACGTG)(2) is similar to the corresponding steps in d(CG)(3). These results suggest that specific polyamines such as Z-5 could serve as powerful inducers of Z-type conformation in unmodified DNA sequences with AT base pairs. This structure provides a molecular basis for stabilizing AT base pairs incorporated into an alternating d(CG) sequence.