New complex of post-activated neocarzinostatin chromophore with DNA: bulge DNA binding from the minor groove

Neocarzinostatin (NCS-chrom), a natural enediyne antitumor antibiotic, undergoes either thiol-dependent or thiol-independent activation, resulting in distinctly different DNA cleavage patterns. Structures of two different post-activated NCS-chrom complexes with DNA have been reported, revealing strikingly different binding modes that can be directly related to the specificity of DNA chain cleavage caused by NCS-chrom. The third structure described herein is based on recent studies demonstrating that glutathione (GSH) activated NCS-chrom efficiently cleaves DNA at specific single-base sites in sequences containing a putative single-base bulge. In this structure, the GSH post-activated NCS-chrom (NCSi-glu) binds to a decamer DNA, d(GCCAGAGAGC), from the minor groove. This binding triggers a conformational switch in DNA from a loose duplex in the free form to a single-strand, tightly folded hairpin containing a bulge adenosine embedded between a three base pair stem. The naphthoate aromatic moiety of NCSi-glu intercalates into a GG step flanked by the bulge site, and its substituent groups, the 2-N-methylfucosamine carbohydrate ring and the tetrahydroindacene, form a complementary minor groove binding surface, mostly interacting with the GCC strand in the duplex stem of DNA. The bulge site is stabilized by the interactions involving NCSi-glu naphthoate and GSH tripeptide. The positioning of NCSi-glu is such that only single-chain cleavage via hydrogen abstraction at the 5'-position of the third base C (which is opposite to the putative bulge base) in GCC is possible, explaining the observed single-base cleavage specificity. The reported structure of the NCSi-glu-bulge DNA complex reveals a third binding mode of the antibiotic and represents a new family of minor groove bulge DNA recognition structures. We predict analogue structures of NCSi-R (R = glu or other substituent groups) may be versatile probes for detecting the existence of various structures of nucleic acids. The NMR structure of this complex, in combination with the previously reported NCSi-gb-bulge DNA complex, offers models for specific recognition of DNA bulges of various sizes through binding to either the minor or the major groove and for single-chain cleavage of bulge DNA sequences.     

Mode of reversible binding of neocarzinostatin chromophore to DNA: base sequence dependency of binding.

The reversible binding of neocarzinostatin chromophore to polynucleotides was studied in order to understand the molecular basis of its base sequence-specificity in DNA damage production. Studies of the spectroscopic and thermodynamic properties of chromophore-polynucleotide interactions reveal that the binding of the chromophore to poly(dA-dT) is qualitatively and quantitatively different from that to poly(dG-dC) (and poly(dI-dC]. From these and other experiments using double-stranded mixtures of homopolynucleotides, it is proposed that the observed A T specific intercalation might result from differential recognition of minor variations in the B-DNA type structure by the chromophore.     

Cryospectrokinetic evidence for the mode of reversible binding of neocarzinostatin chromophore to poly(deoxyadenylic-thymidylic acid)

The spectra of neocarzinostatin (NCS) chromophore during its reversible association with poly(dA-dT).poly(dA-dT) [poly(dA-dT)] were recorded (at intervals of 17 ms or more) by a cryospectroscopic method. Examination of the spectral changes of a drug during its interaction with DNA has not been previously reported. Such studies indicate binding of chromophore to poly(dA-dT) is a two-step process in which the spectral properties of the intermediate poly(dA-dT). NCS chromophore species closely resemble those of the final equilibrium species. On the basis of cryokinetic studies (at single wavelengths) carried out at low temperature (2 degrees C), the following proposed mechanism of the DNA-drug (PD) interaction was quantitated: (Formula: see text). In analogy with the other reports on the kinetics of drug-DNA interaction, (PD)I and (PD)II could represent externally bound and intercalated complexes, respectively. However, since the spectra of (PD)I and (PD)II are closely similar, it can also be proposed that (PD)I and (PD)II represent two forms of an intercalated complex. The rate and equilibrium constant for each step were determined by examining the kinetics of the forward and reverse reactions. This was accomplished by determining the polynucleotide concentration dependence of the apparent fast and slow first-order rate constants observed during a double-exponential increase in transmittance (at 330 nm) associated with the binding and the apoprotein-induced dissociation rate constant of the chromophore from poly(dA-dT). The opportunity to use apoprotein, instead of a detergent, to follow the kinetics of the reverse reaction provides a novel approach to these studies.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mismatch-induced switch of neocarzinostatin attack sites in the DNA minor groove.

Based on the finding that the wobble G.T mismatch 5' to the C of AGC.GCT results in switching of the attack chemistry by neocarzinostatin chromophore (NCS-Chrom) on the deoxyribose moiety of C from C-1' to C-4' [Kappen, L. S. & Goldberg, I. H. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 6706-6710], a series of mismatches has been explored for their effect on the chemistry of damage at the T of AGT.ACT in oligodeoxynucleotides, a site at which 4'-chemistry ordinarily occurs. Placement of a G.T mispair 5' to the T results in a marked increase in 4'-chemistry, as measured by the formation of breaks with 3'-phosphoglycolate ends and abasic sites due to 4'-hydroxylation. Strikingly, 4'-chemistry is induced at the T on the complementary strand, a site ordinarily restricted to 5'-chemistry. Substitution of dioxygen by the radiation sensitizer misonidazole exerts a pronounced effect on the partitioning of the 4'-chemistry in favor of the 3'-phosphoglycolate product. Both stable T.G and unstable T.C mismatches at the attack site itself are associated with marked inhibition of damage at this site. Whereas placement of the relatively stable G.A mismatch on the 5'-side of the T residue (AGT) results in substantial inhibition of damage at the T without shifting of chemistry, the same mismatch at the 3'-side of the attack site decreases damage only slightly but is associated with the appearance of significant 1'-chemistry. By contrast, no shift in chemistry is found with bleomycin, which attacks at C-4'.(ABSTRACT TRUNCATED AT 250 WORDS)     

DAPI binding to the DNA minor groove: a continuum solvent analysis

A continuum solvent model based on the generalized Born (GB) or finite-difference Poisson-Boltzmann (FDPB) approaches has been employed to compare the binding of 4'-6-diamidine-2-phenyl indole (DAPI) to the minor groove of various DNA sequences. Qualitative agreement between the results of GB and FDPB approaches as well as between calculated and experimentally observed trends regarding the sequence specificity of DAPI binding to B-DNA was obtained. Calculated binding energies were decomposed into various contributions to solvation and DNA-ligand interaction. DNA conformational adaptation was found to make a favorable contribution to the calculated total interaction energy but did not change the DAPI binding affinity ranking of different DNA sequences. The calculations indicate that closed complex formation is mainly driven by nonpolar contributions and was found to be disfavored electrostatically due to a desolvation penalty that outbalances the attractive Coulomb interaction. The calculated penalty was larger for DAPI binding to GC-rich sequences compared with AT-rich target sequences and generally larger for the FDPB vs the GB continuum model. A radial interaction profile for DAPI at different distances from the DNA minor groove revealed an electrostatic energy minimum a few Angstroms farther away from the closed binding geometry. The calculated electrostatic interaction up to this distance is attractive and it may stabilize a nonspecific binding arrangement.     

A new protein domain for binding to DNA through the minor groove.

Protein p6 of the Bacillus subtilis phage phi 29 binds with low sequence specificity to DNA through the minor groove, forming a multimeric nucleoprotein complex that activates the initiation of phi 29 DNA replication. Deletion analysis suggested that the N-terminal part of protein p6, predicted to form an amphipathic alpha-helix, is involved in DNA binding. We have constructed site-directed mutants at the polar side of the putative alpha-helix. DNA binding and activation of initiation of phi 29 DNA replication were impaired in most of the mutant proteins obtained. A 19 amino acid peptide comprising the N-terminus of protein p6 interacted with a DNA fragment containing high-affinity signals for protein p6 binding with approximately 50-fold higher affinity than the peptide corresponding to an inactive mutant. Both wild-type peptide and protein p6 recognized the same sequences in this DNA fragment. This result, together with distamycin competition experiments, suggested that the wild-type peptide also binds to DNA through the minor groove. In addition, CD spectra of the wild-type peptide showed an increase in the alpha-helical content when bound to DNA. All these results indicate that an alpha-helical structure located in the N-terminal region of protein p6 is involved in DNA binding through the minor groove.     

DNA recognition by lexitropsins,minor groove binding agents

Consideration is given to alternative approaches to the development of DNA sequences selective binding agents because of their potential applications in diagnosis and treatment of cancer as well as in molecular biology. The concept of lexitropsins, or information-reading molecules, is introduced within the antigene strategy as an alternative to, and complementary with, the antigene approach for cellular intervention and gene control The chemical, physical and paharmacological factors involved in the design of effective lexitropsins are discussed and illustrated with experimental results. Among the factors contributing to the molecular recognition processes are: the presence and disposition of hydrogen bond accepting and donating groups, ligand shape, chirality, stereochemistry, flexibility and charge. For longer ligands, such as are required to target unique sequences in biological systems (14–16 base pairs), the critical feature is the phasing or spatial corresponding between repeat units in the ligand and receptor. The recently discovered 2:1 lexitropsin-DNA binding motif provides a further refinement in molecular recognition in permitting discrimination between GC and CG base pairs. The application of these factors in the design and synthesis of novel agents which exhibits anticancer, antiviral and antitretroviral properties, and inhibition of critical cellular enzymes including topoisomerases is discussed. The emerging evidence of a relationship between sequence selectivity of the new agents and the biological responses they invoke is also described.     

Modeling DNA deformations induced by minor groove binding proteins

Molecular modeling is used to demonstrate that the major structural deformations of DNA caused by four different minor groove binding proteins, TBP, SRY, LEF-1, and PurR, can all be mimicked by stretching the double helix between two 3'-phosphate groups flanking the binding region. This deformation reproduces the widening of the minor groove and the overall bending and unwinding of DNA caused by protein binding. It also reproduces the principal kinks associated with partially intercalated amino acid side chains, observed with such interactions. In addition, when protein binding involves a local transition to an A-like conformation, phosphate neutralization, via the formation of protein-DNA salt bridges, appears to favor the resulting deformation.     

Hydration changes accompanying the binding of minor groove ligands with DNA

4',6-diamidino-2-phenylindole (DAPI), netropsin, and pentamidine are minor groove binders that have terminal -C(NH2)2+ groups. The hydration changes that accompany their binding to the minor groove of the (AATT)2 sequence have been studied using the osmotic stress technique with fluorescence spectroscopy. The affinity of DAPI for the binding site decreases with the increasing osmolality of the solution, resulting in acquisition of 35+/-1 waters upon binding. A competition fluorescence assay was utilized to measure the binding constants and hydration changes of the other two ligands, using the DNA-DAPI complex as the fluorescence reporter. Upon their association to the (AATT)2 binding site, netropsin and pentamidine acquire 26+/-3 and 34+/-2 additional waters of hydration, respectively. The hydration changes are discussed in the context of the terminal functional groups of the ligands and conformational changes in the DNA.     

Out-of-shape DNA minor groove binders: induced fit interactions of heterocyclic dications with the DNA minor groove

DB921 and DB911 are benzimidazole-biphenyl isomers with terminal charged amidines. DB911 has a central meta-substituted phenyl that gives it a shape similar to those of known minor groove binding compounds. DB921 has a central para-substituted phenyl with a linear conformation that lacks the appropriate radius of curvature to match the groove shape. It is thus expected that DB911, but not DB921, should be an effective minor groove binder, but we find that DB921 not only binds in the groove but also has an unusually high binding constant in SPR experiments (2.9 x 10(8) M(-)(1), vs 2.1 x 10(7) M(-)(1) for DB911). ITC thermodynamic analysis with an AATT sequence shows that the stronger binding of DB921 is due to a more favorable binding enthalpy relative to that of DB911. CD results support minor groove binding for both compounds but do not provide an explanation for the binding of DB921. X-ray crystallographic analysis of DB921 bound to AATT shows that an induced fit structural change in DB921 reduces the twist of the biphenyl to complement the groove, and places the functional groups in position to interact with bases at the floor of the groove. The phenylamidine of DB921 forms indirect contacts with the bases through a bound water. The DB921-water pair forms a curved binding module that matches the shape of the minor groove and provides a number of strong interactions that are not possible with DB911. This result suggests that traditional views of compound curvature required for minor groove complex formation should be reevaluated.     

The binding of prototype lexitropsins to the minor groove of DNA: quantum chemical studies.

Ab initio calculations (Hartree-Fock) using the 6-31 G basis set have been performed on two prototype lexitropsins or information-reading molecules. The latter are DNA minor groove binding agents related to the A.T recognizing netropsin in which each of the two N-methylpyrrole moieties is replaced in turn by 1-methylimidazole and which thereby confers the property of recognizing G.C sites.Ab initio treatment was possible by examining composities of separate non-conjugated segments of the molecules. Geometry optimized conformations, energies and distribution of electrostatic charges within the molecules were derived. The ab initio derived parameters of the geometry optimized conformations of these lexitropsins were used to interpret their interaction with different sequences within the minor groove of B-DNA.     

Sequence-specific, strand-selective, and directional binding of neocarzinostatin chromophore to oligodeoxyribonucleotides

The sequence-specific interaction of neocarzinostatin chromophore (NCS-C) has been evaluated with a series of synthetic oligodeoxyribonucleotides of defined sequences containing the most preferred nucleotide cleavage site, T or A, or both. NCS-C preferentially cleaves T or A residues in the sequence GN1N2, where N2 is T or A. Greater cleavage occurs on the strand enriched with G residues, provided that they are adjacent to other G residues, but not at N1. These results are compatible with a model for drug binding in which the naphthoate moiety of NCS-C preferentially intercalates at GN1. This is accompanied by electrostatic binding interaction provided by the positively charged amino sugar moiety so as to place the reactive bicyclo[7.3.0]dodecadienediyne epoxide moiety in an appropriate orientation in the minor groove enabling, upon thiol activation, attack at C-5' of T or A. At certain sequences, such as GCT.AGC, a similar binding mode is also able to generate a basic lesions at the C residue on the opposite strand, forming a bistranded lesion. Although the reactions with glutathione generally show the same strand selectivity and sequence specificity as those with dithiothreitol, the former is usually more efficient than the latter.     

Polyhydroxylated azepanes as new motifs for DNA minor groove binding agents.

The synthesis of 1,3-bis-[3,4,5,6-tetrahydroxyazepane-N-p-phenoxy] and 1,3-bis-[3,4,5,6-tetrahydroxyazepane-N-p-benzyloxy] propanes is reported. These compounds have been prepared to investigate the potential of incorporating iminosugars as useful recognition elements in DNA minor groove binding agents. The compounds were shown to have very moderate binding affinities for DNA in thermal denaturation and ethidium bromide displacement assays when compared with propamidine. They were also found to possess some in vitro anticancer activity that did not correlate with their DNA binding affinity.     

DNA sequence preferences of several AT-selective minor groove binding ligands.

We have examined the interaction of distamycin, netropsin, Hoechst 33258 and berenil, which are AT-selective minor groove-binding ligands, with synthetic DNA fragments containing different arrangements of AT base pairs by DNase I footprinting. For fragments which contain multiple blocks of (A/T)4 quantitative DNase I footprinting reveals that AATT and AAAA are much better binding sites than TTAA and TATA. Hoechst 33258 shows that greatest discrimination between these sites with a 50-fold difference in affinity between AATT and TATA. Alone amongst these ligands, Hoechst 33258 binds to AATT better than AAAA. These differences in binding to the various AT-tracts are interpreted in terms of variations in DNA minor groove width and suggest that TpA steps within an AT-tract decrease the affinity of these ligands. The behaviour of each site also depends on the flanking sequences; adjacent pyrimidine-purine steps cause a decrease in affinity. The precise ranking order for the various binding sites is not the same for each ligand.     

Methylene blue binding to DNA with alternating AT base sequence: minor groove binding is favored over intercalation

The results presented in this paper on methylene blue (MB) binding to DNA with AT alternating base sequence complement the data obtained in two former modeling studies of MB binding to GC alternating DNA. In the light of the large amount of experimental data for both systems, this theoretical study is focused on a detailed energetic analysis and comparison in order to understand their different behavior. Since experimental high-resolution structures of the complexes are not available, the analysis is based on energy minimized structural models of the complexes in different binding modes. For both sequences, four different intercalation structures and two models for MB binding in the minor and major groove have been proposed. Solvent electrostatic effects were included in the energetic analysis by using electrostatic continuum theory, and the dependence of MB binding on salt concentration was investigated by solving the non-linear Poisson-Boltzmann equation. We find that the relative stability of the different complexes is similar for the two sequences, in agreement with the interpretation of spectroscopic data. Subtle differences, however, are seen in energy decompositions and can be attributed to the change from symmetric 5'-YpR-3' intercalation to minor groove binding with increasing salt concentration, which is experimentally observed for the AT sequence at lower salt concentration than for the GC sequence. According to our results, this difference is due to the significantly lower non-electrostatic energy for the minor groove complex with AT alternating DNA, whereas the slightly lower binding energy to this sequence is caused by a higher deformation energy of DNA. The energetic data are in agreement with the conclusions derived from different spectroscopic studies and can also be structurally interpreted on the basis of the modeled complexes. The simple static modeling technique and the neglect of entropy terms and of non-electrostatic solute-solvent interactions, which are assumed to be nearly constant for the compared complexes of MB with DNA, seem to be justified by the results.     

Probing DNA single strands for single-base bulges with neocarzinostatin chromophore.

Neocarzinostatin chromophore (NCS-Chrom) induces strong cleavage at a single site (C3) in the single-stranded and 5' (32)P-end-labeled 13-mer GCCAGATTTGAGC in a reaction dependent on a thiol. By contrast, in the duplex form of the same 13-mer, strand cleavage occurs only at the T and A residues, and C3 is not cleaved. To determine the minimal structural requirement(s) for C3 cleavage in the single-stranded oligomer, several deletions and mutations were made in the 13-mer. A 10-mer (GCCAGAGAGC) derived from the 13-mer by deletion of the three T residues was also cleaved exclusively at C3 by NCS-Chrom, generating fragments having 5' phosphate ends. That the cleavage at C3 is initiated by abstraction of its 5' hydrogen is confirmed in experiments using 3' (32)P-end-labeled 10-mer. The competent 13-mer and 10-mer were assigned hairpin structures with a stem loop and a single bulged out A base, placing C3 across from and 3' to the bulge. Removal of the bulged A base from the 13-mer and the 10-mer resulted in complete loss of cutting activity, proving that it is the essential determinant in competent substrates. Studies of thiol post-activated NCS-Chrom binding to the DNA oligomers show that the drug binds to the bulge-containing 13-mer (K(d) = 0.78 microM) and the 10-mer (K(d) = 1.11 microM), much more strongly than to the 12-mer (K(d) = 20 microM) and the 9-mer (K(d) = 41 microM), lacking the single-base bulge. A mutually induced-fit between NCS-Chrom and the oligomer resulting in optimal stabilization of the drug-DNA complex is proposed to account for the site-specific cleavage at C3. These studies establish the usefulness of NCS-Chrom as a probe for single-base bulges in DNA.