Sergey A. Streltsov

The hoechst 33258 covalent dimer covers a total turn of the double-stranded DNA

Abstract With the goal to design ligands recognizing extended regions on dsDNA, a covalent dimer of the fluorescent dye Hoechst 33258 [bis-HT(NMe)] composed of two dye molecules linked via the phenol oxygen atoms with a (CH2)3-N+H(CH3)-(CH2)3 fragment was constructed using computer modeling and then synthesized. Its interactions with the double-stranded DNA (dsDNA) were studied by fluorescent and UV-Vis spectroscopy and circular (CD) and linear dichroism (LD). Based on variations in the affinity to the dsDNA, it was shown that complexes of three types are formed. The first type complexes result from binding of a bis- HT(NMe) monomer in the open conformation; in this case the ligand covers the total dsDNA turn and is located in the minor groove according to the positive value of CD at 370 nm. In addition, the ability to form bis-HT(NMe)-bridges between two dsDNA molecules, i.e., each of the two bis-HT(NMe) ends binds to two different dsDNA molecules, was demonstrated for the first type complexes. Spectral characteristics (maximal absorption at 362 nm, positive sign, and maximal value of CD at 370 nm) of the first type complexes conform to those of the specific Hoechst 33258 complex with poly[d(A-T)] · poly[d(A-T]. The second type complexes correspond to the bis-HT(NMe) sandwich (as an inter- or intramolecular) binding to dsDNA with stoichiometry ≥ 5 bp. Thereby, a negative LD at 360 nm and the location of bis- HT(NMe) sandwiches in the minor groove of B form dsDNA seems contradictory. Spectral characteristics (maximal positive CD at 345 nm, a dramatic decrease in fluorescence intensity and the shift of its maximum to 490 nm) of these complexes favor a suggestion that this binding correlates to the formation of nonspecific dimeric Hoechst 33258 complex with dsDNA. The third type complexes are characterized by stoichiometry of one bis-HT(NMe) molecule per ≈ 2 bp and the tendency to zero of LD values at 270 and 360 nm. We assume that in these complexes bis-HT(NMe) sandwich dimers are formed on dsDNA. The complexes of this type conform to the aggregation type complex of Hoechst 33258 with dsDNA. The ability of bis-HT(NMe) to cover the whole dsDNA turn or form bridges with two dsDNA upon the formation of the first type complexes essentially distinguishes it from Hoechst 33258, which can only occupy 5 bp and does not form such bridges. This specific property of bis-HT(NMe) may support new biological activities.

Inhibition of the helicase activity of the HCV NS3 protein by symmetrical dimeric bis-benzimidazoles

Dimeric bis-benzimidazoles (DBn) are the compounds specifically binding to A-T enriched sequences in the DNA minor groove. Due to this property they can inhibit DNA-dependent enzymes. We show that inhibition of the helicase activity of HCV NS3 protein by DBn was due to a novel mechanism, which involved direct binding of the ligands to the enzyme. The binding potency and inhibition efficacy depended on the length of the linker between the benzimidazole fragments. The most effective inhibitor DB11 partially prevented activation of NTPase activity of NS3 by poly(U) and increased affinity of the enzyme to the helicase substrate DNA.

Mixed Mode of Ligand-DNA Binding Results in S-Shaped Binding Curves

Abstract S-shaped binding curves often characterize interactions of ligands with nucleic acid molecules as analyzed by different physicochemical and biophysical techniques. S-shaped experimental binding curves are usually interpreted as indicative of the positive cooperative interactions between the bound ligand molecules. This paper demonstrates that S-shaped binding curves may occur as a result of the “mixed mode” of DNA binding by the same ligand molecule. Mixed mode of the ligand-DNA binding can occur, for example, due to 1) isomerization or dimerization of the ligands in solution or on the DNA lattice, 2) their ability to intercalate the DNA and to bind it within the minor groove in different orientations. DNA- ligand complexes are characterized by the length of the ligand binding site on the DNA lattice (so-called “multiple-contact” model). We show here that if two or more complexes with different lengths of the ligand binding sites could be produced by the same ligand, the dependence of the concentration of the complex with the shorter length of binding site on the total concentration of ligand should be S-shaped. Our theoretical model is confirmed by comparison of the calculated and experimental CD binding curves for bis-netropsin binding to poly(dA-dT) poly(dA-dT). Bis-netropsin forms two types of DNA complexes due to its ability to interact with the DNA as monomers and trimers. Experimental S-shaped bis-netropsin-DNA binding curve is shown to be in good correlation with those calculated on the basis of our theoretical model. The present work provides new insight into the analysis of ligand-DNA binding curves.

Hoechst 33258—poly(dG-dC)·poly(dG-dC) Complexes Of Three Types

Abstract It was found recently that Hoechst 33258, a dsDNA fluorescent dye used in cytological studies, is an efficient inhibitor of the interaction of TATA-box-binding protein with DNA, DNA topoisomerase I, and DNA helicases. In addition it proved to be a radioprotector. Biological activity of Hoechst 33258 may be associated with dsDNA complexes of not only monomeric, but also dimeric type. In this work, the Hoechst 33258 interaction with poly(dG-dC)·poly(dG- dC) was studied using UV-vis and fluorescent spectroscopy, circular and flow-type linear dichroism. It was found that Hoechst 33258 formed with poly(dG-dC)·poly(dG-dC) complexes of three types, namely, monomeric, dimeric, and, apparently, tetrameric, and their spectral properties were studied. Complexes of monomeric and dimeric types competed with distamycin A, a minor groove ligand, for binding to poly(dG-dC)·poly(dG-dC). We proposed that Hoechst 33258 both monomers and dimers form complexes of the external type with poly(dG-dC)·poly(dG-dC) from the side of the minor groove.

Torus-shaped particles formed due to intermolecular condensation of circular DNA upon interaction with synthetic tripeptide.

The morphology of complexes between relaxed circular plasmid pBR322 DNA and tripeptide L‐Val‐L‐Val‐L‐Val‐NH‐NH‐Dns (TVP) at different peptide/DNA ratios was studied by electron microscopy. The results show that interaction of TVP with circular DNA leads to the formation of perfect torus‐shaped particles. The torus parameter measurements offer the possibility to conclude that DNA condensation observed is of intermolecular nature. On the basis of the analysis of the structures corresponding to the early stages of DNA compaction the model for intermolecular condensation of circular DNA into torus‐shaped particles is proposed.

Interaction of Topotecan, DNA Topoisomerase I Inhibitor, with Double-stranded Polydeoxyribonucleotides. 3. Binding at the Minor Groove

Interaction of topotecan (TPT) with calf thymus DNA, coliphage T4 DNA, and poly(dGdC) · poly(dG-dC) was studied by optical (linear flow dichroism, UV-vis spectroscopy) and quantum chemical methods. The linear dichroism signal of TPT bound to DNA was shown to have positive sign in the range 260–295 nm. This means that the plane of quinoline fragment (rings A and B) of TPT forms an angle less than 54° with the long axis of DNA, and hence the TPT molecule cannot intercalate between DNA base pairs. TPT was established to bind to calf thymus DNA as readily as to coliphage T4 DNA whose cytosines in the major groove were all glycosylated at the 5th position. Consequently, the DNA major groove does not participate in TPT binding. TPT molecule was shown to compete with distamycin for binding sites in the minor groove of DNA and poly(dG-dC) · poly(dG-dC). Thus, it was demonstrated for the first time that TPT binds to DNA at its minor groove.

Trivaline ‘catalyzes’ 5′‐pdGTT oligomerization in solution

We have found that the 5′‐pdGTT molecules at a concentration of 10−4 M are oligomerized in solution in the presence of 10−4 M tripeptide ‐ (L‐Val)3‐NH‐NH‐DNS‐CF3COOH and the condensation reagents (carbodiimide and imidazole). Oligonucleotides not less than 12 bases long were formed in the yield which was over 15%. It is known that in the absence of peptide 10−2 M mono‐ or dinucleotides are required. Thus trivaline can be considered as one of the simplest enzymes. This oligomerization seems to be an essential way for the synthesis of long enough oligonucleotides of the random GC‐sequence, which could be used at the earliest steps of evolution.

Novel Antitumor L-Arabinose Derivative of Indolocarbazole with High Affinity to DNA

Novel indolocarbazole derivative 12‐(α‐L‐arabinopyranosyl)indolo[2,3‐α]pyrrolo[3,4‐c]carbazole‐5,7‐dione (AIC) demonstrated high potency (at submicromolar concentrations) against the NCI panel of human tumor cell lines and transplanted tumors in vivo. In search of tentative targets for AIC, we found that the drug formed high affinity intercalative complexes with d(AT)20, d(GC)20 and calf thymus DNA (binding constants (1.6×106) M−1≤Ka≤(3.3×106) M−1). The drug intercalated preferentially into GC pairs of the duplex. Importantly, the concentrations at which AIC formed the intercalative complexes with DNA (C≤1 μM) were identical to the concentrations that triggered p53‐dependent gene reporter transactivation, the replication block, the inhibition of topoisomerase I‐mediated DNA relaxation and death of HCT116 human colon carcinoma cells. We conclude that the formation of high affinity intercalative complexes with DNA is an important factor for anticancer efficacy of AIC.

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.

Interaction of topotecan, DNA topoisomerase I inhibitor, with double-stranded polydeoxyribonucleotides. 4. Topotecan binds preferably to the GC base pairs of DNA

Interaction of topotecan (TPT) with synthetic double-stranded polydeoxyribonucleotides has been studied in solutions of low ionic strength at pH 6.8 by linear flow dichroism (LD), circular dichroism (CD), UV-Vis absorption, and Raman spectroscopy. The complexes of TPT with poly(dG-dC) · poly(dG-dC), poly(dG) · poly(dC), poly(dA-dC) · poly(dG-dT), and poly(dA) · poly(dT), as well as complexes of TPT with calf thymus DNA and coliphage T4 DNA studied by us previously, have been shown to have negative LD in the long-wavelength absorption band of TPT, whereas the complex of TPT with poly(dA-dT) · poly(dA-dT) has positive LD in this absorption band of TPT. Thus, there are two different types of TPT complex with the polymers. TPT has been established to bind preferably to GC base pairs because its affinity to the polymers of different composition decreases in the following order: poly(dG-dC) · poly(dG-dC) > poly(dG) · poly(dC) > poly(dA-dC) · poly(dG-dT) > poly(dA) · poly(dT). The presence of DNA has been shown to shift the monomer–dimer equilibrium in TPT solutions toward dimer formation. Several duplexes of the synthetic polynucleotides bound together by bridges of TPT dimers may participate in the formation of the studied type of TPT–polynucleotide complex. Molecular models of TPT complex with linear and circular supercoiled DNAs and with deoxyguanosine have been considered. TPT (and presumably the whole camptothecin family) proved to represent a new class of DNA-specific ligands whose biological action is associated with formation of dimeric bridges between two DNA duplexes.