Quantitative estimation of the contribution of pyrrolcarboxamide groups of the antibiotic distamycin A into specificity of its binding to DNA AT pairs.

Interaction of DNA with the analogs of the antibiotic distamycin A having different numbers of pyrrolcarboxamide groups and labeled with dansyl was studied. The binding isoterms of the analogs to synthetic polydeoxyribonucleotides were obtained. Analysis of the experimental data leads to the following conclusions: (1) the free energy of binding of the analogs to poly(dA).poly(dT) depends linearly on the number of amide groups in the molecule of the analog whereas attachment of each pyrrolcarboxamide group produces changes of 2 kcal/mole in the free energy; (2) attachment of a pyrrolcarboxamide unit to the GC pair results in the free energy change of 0.95 kcal/mole; (3) the binding of analogs to poly(dA).poly(dT) is a cooperative process, presumbly, dependent on conformational changes induced by the binding of analogs to DNA.     

A code controlling specific binding of regulatory proteins to DNA

A possible code is suggested that describes a correspondence between amino acid sequences in stereospecific sites of regulatory proteins and nucleotide sequences at the control sites on DNA. Stereospecific sites of regulatory proteins are assumed to contain pairs of antiparallel polypeptide chain segments which form a right-hand twisted antiparallel -sheet with single-stranded regions at the ends of the -structure. The binding reaction between regulatory protein and double-helical DNA is accompanied by significant structural alterations at stereospecific sites of the protein and DNA. Half of the hydrogen bonds normally existing in -structure are broken upon complex formation with DNA and a new set of hydrogen bonds is formed between polypeptide amide groups and DNA base pairs. The code states a correspondence between four amino acid residues at a stereospecific site of the regulatory protein and an AT (GC) base pair at the control site. It predicts that there are six fundamental amino acid residues (serine, threonine, histidine, asparagine, glutamine and cysteine) whose arrangement in the stereospecific site determines the base pair sequence to which a given regulatory protein would bind preferentially.     

Binding of Bis-linked Netropsin Derivatives in the Parallel-Stranded Hairpin Form to DNA

Abstract

Cis-diammine Pt(II)- bridged bis-netropsin and oligomethylene-bridged bis-netropsin in which two monomers are linked in a tail-to-tail manner bind to the DNA oligomer with the sequence 5′-CCTATATCC-3′ in a parallel-stranded hairpin form with a stoichiometry 1:1. The difference circular dichroism (CD) spectra characteristic of binding of these ligands in the hairpin form are similar. They differ from CD patterns obtained for binding to the same duplex of another bis-netropsin in which two netropsin moieties were linked in a head-to-tail manner. This reflects the fact that tail-to-tail and head-to-tail bis-netropsins use parallel and antiparallel side-by-side motifs, respectively, for binding to DNA in the hairpin forms. The binding affinity of cis -diammine Pt(II)- bridged bis-netropsin in the hairpin form to DNA oligomers with nucleotide sequences 5′-CCTATATCC-3′ (I), 5′-CCTTAATCC-3′ (II), 5′-CCTTATTCC-3′ (III), 5′-CCTTTTTCC-3′ (IV) and 5′-CCAATTTCC-3′ (V) decreases in the order I = II > III > IV> V. The binding of oligomethylene-bridged bis-netropsin in the hairpin form follows a similar hierarchy. An opposite order of sequence preferences is observed for partially bonded monodentate binding mode of the synthetic ligand.     

Raman and surface-enhanced Raman scattering spectroscopy of bis-netropsins and their DNA complexes

The interactions of three bis-netropsins (bis-Nts), which are potent catalytic inhibitors of DNA-binding enzymes, with three double-stranded oligonucleotides (OLIGs), which contain sites of different specific affinities for each bis-Nt, were analyzed. Raman spectroscopy was performed for selective monitoring of modifications of the bis-Nt or the OLIG structure upon bis-Nt-DNA binding, and surface-enhanced Raman scattering spectroscopy (SERS) was an additional tool for topology studies of ligand-DNA complexes. The spectral data showed conformational changes of both partners (bis-Nt and OLIG) upon complexation. Structural variations of bis-Nts appeared to be dependent on a bis-Nt-OLIG binding constant and were found to be small in the specific DNA binding and highest for nonspecific binding of bis-Nt with the corresponding OLIG. The conformational changes of the OLIGs were varied with a bis-Nt-OLIG binding constant in the same manner. The bis-Nts seemed to induce a perturbation in the OLIG's structure, as well as in the positions of their direct binding. These DNA structural modification effects may explain the inhibition of DNA-binding enzymes in the variety of very distinct DNA-enzyme binding sites by bis-Nts reported previously.     

Sequence-specific ultrasonic cleavage of DNA

We investigated the phenomenon of ultrasonic cleavage of DNA by analyzing a large set of cleavage patterns of DNA restriction fragments using polyacrylamide gel electrophoresis. The cleavage intensity of individual phosphodiester bonds was found to depend on the nucleotide sequence and the position of the bond with respect to the ends of the fragment. The relative intensities of cleavage of the central phosphodiester bond in 16 dinucleotides and 256 tetranucleotides were determined by multivariate statistical analysis. We observed a remarkable enhancement of the mean values of the relative intensities of cleavage (cleavage rates) in phosphodiester bonds following deoxycytidine, which diminished in the row of dinucleotides: d(CpG) > d(CpA) > d(CpT) >> d(CpC). The cleavage rates for all pairs of complementary dinucleotides were significantly different from each other. The effect of flanking nucleotides in tetranucleotides on cleavage rates of all 16 types of central dinucleotides was also statistically significant. The sequence-dependent ultrasonic cleavage rates of dinucleotides are consistent with reported data on the intensity of the conformational motion of their 5′-deoxyribose. As a measure of local conformational dynamics, cleavage rates may be useful for characterizing functional regions of the genome.     

Head-to-head bis-hairpin polyamide minor groove binders and their conjugates with triplex-forming oligonucleotides: studies of interaction with target double-stranded DNA

Two hairpin hexa(N-methylpyrrole)carboxamide DNA minor groove binders (MGB) were linked together via their N-termini in head-to-head orientation. Complex formation between these bis-MGB conjugates and target DNA has been studied using DNase I footprinting, circular dichroism, thermal dissociation, and molecular modeling. DNase I footprint revealed binding of these conjugates to all the sites of 492 b.p. DNA fragment containing (A/T)(n)X(m)(A/T)(p) sequences, where n>3, p>3; m=1,2; X = A,T,G, or C. Binding affinity depended on the sequence context of the target. CD experiments and molecular modeling showed that oligo(N-methylpyrrole)carboxamide moieties in the complex form two short antiparallel hairpins rather than a long parallel head-to-head hairpin. Binding of bis-MGB also stabilized a target duplex thermodynamically. Sequence specificity of bis-MGB/DNA binding was validated using bis-conjugates of sequence-specific hairpin (N-methylpyrrole)/(N-methylimidazole) carboxamides. In order to increase the size of recognition sequence, the conjugates of bis-MGB with triplex-forming oligonucleotides (TFO) were synthesized and compared to TFO conjugated with single MGB hairpin unit. Bis-MGB-oligonucleotide conjugates also bind to two blocks of three and more A.T/T.A pairs similarly to bis-MGB alone, independently of the oligonucleotide moiety, but with lower affinity. However, the role of TFO in DNA recognition was demonstrated for mono-MGB-TFO conjugate where the binding was detected mainly in the area of the target sequence consisting of both MGB and TFO recognition sites. Basing on the molecular modeling, three-dimensional models of both target DNA/bis-MGB and target DNA/TFO-bis-MGB complexes were built, where bis-MGB forms two antiparallel hairpins. According to the second model, one MGB hairpin is in the minor groove of 5'-adjacent A/T sequence next to the triplex-forming region, whereas the other one occupies the minor groove of the TFO binding polypurine tract. All these data together give a key information for the construction of MGB-MGB and MGB-oligonucleotide conjugates possessing high specificity and affinity for the target double-stranded DNA.     

Design and synthesis of sequence-specific DNA-binding peptides

Design, synthesis and DNA binding activities of two peptides containing 32 and 102 residues are reported. A nonlinear 102-residue peptide contains four modified alpha helix-turn-alpha helix motifs of 434 cro protein. These four units are linked covalently to a carboxyterminal crosslinker containing four arms each ending with an aliphatic amino group. From CD studies we have found that in aqueous buffer in the presence of 20% trifluoroethanol the peptide residues assume alpha-helical, beta-sheet and random-coiled conformations with the alpha-helical content of about 16% at room temperature. Upon complex formation between peptide and DNA, a change in the peptide conformation takes place which is consistent with an alpha - beta transition in the DNA binding alpha helix-turn-alpha helix units of the peptide. Similar conformation changes are observed upon complex formation with the synthetic operator of a linear peptide containing residues 7-37 of 434 cro repressor. Evidently, in the complex, residues present in helices alpha 2 and alpha 3 of the two helix motif form a beta-hairpin which is inserted in the minor DNA groove. The last inference is supported by our observations that the two peptides can displace the minor groove-binding antibiotic distamycin A from poly(dA).poly(dT) and synthetic operator DNA. As revealed from DNase digestion studies, the nonlinear peptide binds more strongly to a pseudooperator Op1, located in the cro gene, than to the operator OR3. A difference in the specificity shown by the non-linear peptide and wild-type cro could be attributed to a flexibility of the linker chains between the DNA-binding domains in the peptide molecule as well as to a replacement of Thr-Ala in the peptide alpha 2-helices. Removal of two residues from the N-terminus of helix alpha 2 in each of the four DNA-binding domains of the peptide leads to a loss of binding specificity.     

Interaction of clinically important human DNA topoisomerase I poison, topotecan, with double-stranded DNA

Topotecan (TPT), a water-soluble derivative of camptothecin, is a potent antitumor poison of human DNA topoisomerase I (top1) that stabilizes the cleavage complex between the enzyme and DNA. The role of the recently discovered TPT affinity to DNA remains to be defined. The aim of this work is to clarify the molecular mechanisms of the TPT-DNA interaction and to propose the models of TPT-DNA complexes in solution in the absence of top1. It is shown that TPT molecules form dimers with a dimerization constant of (4.0 +/- 0.7) x 10(3) M(-1) and the presence of DNA provokes more than a 400-fold increase of the effective dimerization constant. Flow linear dichroism spectroscopy accompanied by circular dichroism, fluorescence, and surface-enhanced Raman scattering experiments provide evidence that TPT dimers are able to bind DNA by bridging different DNA molecules or distant DNA structural domains. This effect may provoke modification of the intrinsic geometry of the cruciform DNA structures, leading to the appearance of new crossover points that serve as the sites of the top1 loading position. The data presume the hypothesis of TPT-mediated modulation of top1-DNA recognition before ternary complex formation.     

DNA Sequence-Specific Ligands: XII. Synthesis and Cytological Studies of Dimeric Hoechst 33258 Molecules

We synthesized dimeric Hoechst dye molecules composed of two moieties of Hoechst 33258 fluorescent dye with the phenolic hydroxy groups tethered via pentamethylene, heptamethylene, or triethylene oxide linkers. A characteristic pattern of differential staining of chromosome preparations from human HL60 premonocytic leukemia cells was observed for all the three fluorescent dyes. The most contrasting pattern was obtained for the bisHoechst analogue with the heptamethylene linker; its quality was comparable with the picture obtained in the case of chromosome staining with 4′,6-diamidino-2-phenylindole. The ability to penetrate into live human fibroblasts was studied for the three bisHoechst compounds. The fluorescence intensity of nuclei of live and fixed cells stained with the penta- and heptamethylene-linked bisHoechst analogues was found to differ only slightly, whereas the fluorescence of the nuclei of live cells stained with triethylene oxide-linked bisHoechst was considerably weaker than that of the fixed cells. The bisHoechst molecules are new promising fluorescent dyes that can both differentially stain chromosome preparations and penetrate through cell and nuclear membranes and effectively stain cell nuclei.__________Translated from Bioorganicheskaya Khimiya, Vol. 31, No. 4, 2005, pp. 385–393.Original Russian Text Copyright © 2005 by Gromyko, Popov, Mosoleva, Streltsov, Grokhovsky, Oleinikov, Zhuze.