DNA-helix bending, stiffening and elongation on ligand binding; analysis for several DNA-drug systems, general viscometric DNA response and stereochemical implications.

For several DNA-ligand systems the DNA helix bending, stiffening and elongation behaviour is treated quantitatively. The experimental basis are viscosity data from literature as a function of r, the ratio of drug molecules bound per DNA monomer unit. If the relative viscosity changes delta y1(r) and delta yh(r) for DNA of low and high molar mass, respectively, are known, the relative changes of contour length, delta L/L degrees, and of persistence length, delta a/a degrees, can be evaluated as a function of r, as repeatedly demonstrated. For random sequence-independent interactions, helix-bending is reflected by a helix-typical increment of delta a/a degrees (r), being zero at r = 0 and also at DNA saturation by bound ligand molecules [Reinert, Biophysical Chemistry 13, 1-14 (1981)]. This characteristic DNA behaviour often enables us to separate the bending and the stiffening increment of delta a/a degrees. The theoretical treatment of this problem (Schütz and Reinert, J. Biomolec. Struct. & Dynam. 9, 315-329, 1991) now permits a more detailed study of the ligand-induced DNA bending. The ligand-DNA systems treated here concern the following drugs (in parentheses DNA bending angle at low r-values): proflavin (8 degrees), daunomycin (11 degrees), aclacinomycin A (9.7 degrees, on cooperative interaction), actinomycin D (16 degrees), mitomycin C (16 degrees), a double intercalating bisphenantridine (12 degrees), 9-deacetyl-daunomycin (8 degrees) and 9-epi-deacetyl-daunomycin (12-18 degrees). We also demonstrate that the consideration of the DNA flexibility and its change on interaction of short DNA molecules with intercalating drugs delivers helix elongation values in better accord with the theoretical value. In the Appendix, a catalogue of simulated delta y(r)-dependences is given for both short and long DNA molecules. It systematically describes the DNA viscosity response upon typical DNA stiffening, elongation, and helix-bending effects.     

Temperature mediated variation of DNA secondary structure in (A.T) clusters; evidence by use of the oligopeptide netropsin as a structural probe.

The titration viscometric investigation of the multi-mode interaction of netropsin (Nt) with (A.T) clusters of NaDNA12 and NH4DNA10 has been extended to different temperatures. The position of two boundaries on the r-scale (r= [Nt]bound/[DNA-P]) with increasing temperature steadily (rI/II) or more abruptly (rO/I) shifts to lower values. For the most (A.T) rich Nt-binding sites of modes (O), (I) and (II) this observation suggests the existence of an equilibrium between different DNA secondary structures with a different translation per base pair. The mode specific changes delta L1Nt of DNA contour length as induced by one Nt molecule proved to be almost independent of temperature. Concomitant stiffening effects increase with decreasing temperature, contrary to initial expectation. Conformational variability of (A.T) clusters may represent an essential feature in specific or selective DNA-protein interaction.     

Interaction of phenylthiolato-(2,2'',2"-terpyridine)platinum(II) cation with DNA.

The interaction between a novel aromatic thiolato derivative from the family of DNA-intercalating platinum complexes, phenylthiolato-(2,2',2"-terpyridine)platinum(II)-[PhS(ter py)Pt+], and nucleic acids was studied by using viscosity, equilibrium-dialysis and kinetic measurements. Viscosity measurements with sonicated DNA provide direct evidence for intercalation, and show that at binding ratios below 0.2 molecules per base-pair PhS(terpy)Pt+ causes an increase in contour length of 0.2 nm per bound molecule. However, helix extension diminishes at greater extents of binding, indicating the existence of additional, non-intercalated, externally bound forms of the ligand. The ability of PhS(terpy)Pt+ to aggregate in neutral aqueous buffers at a range of ionic strengths and temperatures was assessed by using optical-absorption methods. Scatchard plots for binding to calf thymus DNA at ionic strength 0.01 (corrected for dimerization) are curvilinear, concave upward, providing further evidence for two modes of binding. The association constant decreases at higher ionic strengths, in accord with the expectations of polyelectrolyte theory, although the number of cations released per bound unipositive ligand molecule is substantially greater than 1. Stopped-flow kinetic measurements confirm the complexity of the binding reaction by revealing multiple bound forms of the ligand whose kinetic processes are both fast and closely coupled. Thermal denaturation of DNA radically alters the shapes of binding isotherms and either has little effect on, or enhances, the affinity of potential binding sites, depending on experimental conditions. Scatchard plots for binding to natural DNA species with differing nucleotide composition show that the ligand has a requirement for a single G X C base-pair at the highest-affinity intercalation sites.     

Multimode Interaction of Hoechst 33258 with Eukaryotic DNA; Quantitative Analysis of the DNA Conformational Changes

Abstract

The interaction of the minor groove binding ligand Hoechst 33258 (Hoe) with natural DNA was investigated by high resolution titration rotational viscometry. Analysis of the concomitant DNA conformational changes was performed with two DNA samples of sufficiently different molar mass M, at 4°C, 22°C and 40°C, for Hoe/DNA-P ratios below r = 0.02. In this narrow r range several interaction modes could be resolved. The measured conformational changes were quantified in terms of relative changes of both apparent DNA persistence length, Δa/a, and hydrodynamically operative DNA contour length, ΔL/L. Δa/a(r) primarily is a measure of ligand-induced DNA helix stiffening, but both, Δa/a(r) and ΔL/L(r), generally depend also on ligand binding induced DNA bending or DNA unbending. The essential difference obviously is that Δa/a(r) is influenced by the randomly distributed helix bends and ΔL/L(r) by phased ones. The measurements performed at different temperatures deliver informations about existence and temperature dependent abolition of intrinsic helix curvature.

Both Hoe and netropsin (Nt) prefer binding to AT rich DNA segments, which are candidates for intrinsic DNA helix bends. But our data for Hoe interaction with calf thymus DNA (ctDNA) show characteristic differences to those for Nt-ctDNA interaction. Especially for Hoe, the mode of highest affinity is saturated already at a ligand concentration of roughly 1 nM (r = 0.0015 Hoe/DNA-P). It exhibits an unusually strong temperature dependence of the conformational DNA response. A Hoe-Nt competition experiment shows that Hoe binding to the sites of the very first Hoe mode is almost unaffected by bound Nt. But Hoe binding to the sites of the following Hoe modes does not occur due to the competition with Nt. Thus this mode of strongest Hoe-DNA interaction reflects a unique mechanism, possibly of high relevance for gene regulatory systems.     

Aspects of specific protein-DNA interaction; multi-mode binding of the oligopeptide antibiotic netropsin to (A.T)-rich DNA segments.

By means of titration viscometry a number of distinct modes could be resolved for the interaction between the antibiotic netropsin and DNA species of 50, 58, and 69 mole + (A+T) below r = 0.04 netropsin molecules bound per DNA phosphate group. The number of corresponding binding sites increases with a high power of the (A+T) content. The apparent association constants are very high (greater than 10(6) M-1, some perhaps greater than 10(6) M-1) and also rather different for most of the binding sites. It is suggested that some of these interaction modes differ in the number of hydrogen bonds formed between donors of the ligand and acceptors of the binding sites. The interaction modes were characterized quantitatively by their (species-independent) changes of DNA contour length and by the percentage of local DNA stiffening.     

DNA multimode interaction with berenil and pentamidine; double helix stiffening, unbending and bending

The antitrypanosomal drugs berenil (Ber) and pentamidine (Pm) preferentially bind to DNA in the minor groove of A.T-rich domains. The properties of A.T clusters are essential for sequence-mediated helix bending. Groove binding drugs locally stiffen the DNA helix but may also change intrinsic helix bends or may bend straight DNA. Ligand binding to randomly distributed sites alters the apparent DNA persistence length, a. Criteria permit the distinction of the underlying mechanism(s). Helix bends, if phased with the helix screw, however, generate solenoidal superhelix components mediating an apparent change of the hydrodynamically effective DNA contour length, L. The measurement of relative changes of both, a and L, as induced by Ber or Pm is performed by titration rotational viscometry. The determination of the two quantities requires two independent measurements: the relative change of DNA intrinsic viscosity, deltay, for short (tending to rod-like) DNA molecules and for comparably long (almost coil-like) ones as a function of r, the bound drug molecules per DNA-P, and this under conditions effectively excluding intramolecular DNA-DNA crosslinking effects. At least at r< or =0.05 and < or =0.03, respectively, the two drugs virtually bind completely to a eukaryotic DNA. r ranges of different drug binding strength and, concomitantly, of different specific conformational response, could be resolved. They represent (sub)modes of different DNA sequences... Whereas the mode-specific elongation effects are fairly similar for both systems, there are pronounced quantitative differences in the relative change of DNA persistence length. The sites of highest Ber-binding strength are correlated to unbent alternating helical A.T segments followed by bent and by less bent or unbent dAn.dTn tracts straightened on Ber-binding. For Pm-DNA interaction the ligand bends the sites of highest Pm affinity. Generally, ligand induced and sequence mediated local DNA-bend removal or DNA bending, as observed for several modes of interaction with A.T rich DNA, are considered to be of gene regulatory relevance.     

Intercalative binding to DNA of antitumour drugs derived from 3-nitro-1,8-naphthalic acid.

Two new antitumour drugs, imide derivatives of 3-nitro-1,8-naphthalic acid having different basic side chains linked to the imide nitrogen, have been shown to bind to double-helical DNA by intercalation. At ionic strength 0.01 mol/litre, pH 7, their intrinsic association constants are about 1.45 x 10(5) M-1 and each bound ligand molecule occludes about 3.4 nucleotides of the DNA lattice. They remove and reverse the supercoiling of closed circular duplex PM2 DNA with apparent unwinding angles of 11-12 degrees per bound drug molecule, referred to an assumed unwinding angle of 26 degrees for ethidium. They increase the viscosity of sonicated rod-like DNA fragments, each bound drug molecule producing a calculated increment in length of 2.2 - 2.5 A. No important differences between the DNA-binding characteristics of the two drugs were detected, though one appears marginally more active than the other in certain biological tests.     

DNA‐doxorubicin interaction: New insights and peculiarities

We have investigated the interaction of the DNA molecule with the anticancer drug doxorubicin (doxo) by using three different experimental techniques: single molecule stretching, single molecule imaging, and dynamic light scattering. Such techniques allowed us to get new insights on the mechanical behavior of the DNA‐doxo complexes as well as on the physical chemistry of the interaction. First, the contour length data obtained from single molecule stretching were used to extract the physicochemical parameters of the DNA‐doxo interaction under different buffer conditions. This analysis has proven that the physical chemistry of such interaction can be modulated by changing the ionic strength of the surrounding buffer. In particular we have found that at low ionc strengths doxo interacts with DNA by simple intercalation (no aggregation) and/or by forming bound dimers. For high ionic strengths, otherwise, doxo‐doxo self‐association is enhanced, giving rise to the formation of bound doxo aggregates composed by 3 to 4 molecules along the double‐helix. On the other hand, the results obtained for the persistence length of the DNA‐doxo complexes is strongly force‐dependent, presenting different behaviors when measured with stretching or non‐stretching techniques.     

DNA-bending on ligand binding; change of DNA persistence length.

This paper simulates the helix-characteristic changes of apparent DNA persistence length caused by randomly distributed helix bends as induced, e.g., by DNA-bound ligand molecules. The parameters varied are the constant angle gamma of helix bending and the size alpha of the DNA drug binding site, but also the degree of DNA-ligand binding cooperativity and the helix-unwinding angle. If the size of the binding site is comparable with the helix pitch, the influence of phasing between helix bends and helix screw upon the apparent persistence length is obvious. In the accompanying paper experimental data are analyzed in terms of this theoretical background.     

Counterion dependent variation of DNA secondary structure in (A . T) clusters: evidence by use of netropsin as a structural probe.

The interaction of the oligopeptide antibiotic netropsin (Nt) with (A . T) regions of DNA is characterized by a spectrum of discrete modes. This has been revealed by viscometric analysis, at 20 degrees C and 0.2 M "counterions", for NaDNA in a preceding and for NH4DNA in this paper. The increase of DNA contour length as induced by one Nt molecule was found to depend on the special mode only, while the respective stiffening is generally higher for NH4DNA. The latter property is interpreted in terms of an enhanced flexibility, relative to that of NaDNA, of the (A . T) cluster segments before complex formation. For some of the interaction modes of the DNA-Nt systems a difference in the number of corresponding binding sites has been observed. This phenomenon is understood by assuming an influence of the counterion species upon existing equilibria between different forms of the (A . T) cluster secondary structure. Not less than 5 to 10% of the total DNA are effected in this manner. Upper limits for the local differences in the axial rise per base pair are 0.04 nm and 0.02 nm.     

Interaction of netropsin and distamycin with deoxyribonucleic acid: electric dichroism study

We report dichroism and equilibrium binding studies of netropsin (Net) and distamycin A3 (Dist) binding to deoxyribonucleic acid (DNA). We show that at low degrees of binding (r) to calf thymus DNA, Net induces a considerable increase in the apparent DNA length (14 A/drug molecule bound), closely analogous to the results reported earlier for Dist. In addition, we show that chicken erythrocyte DNA shows length changes similar to those of calf thymus DNA upon distamycin binding. DNA length reaches a maximum at 1 bound drug/20-30 base pairs and then decreases to its initial value by r = 0.1. This effect is not seen for two other DNAs with nearly identical A + T base pair content and may therefore arise from the details of base sequence or base modification in eukaryotic DNA. We also show that Dist binding to calf thymus DNA at low r values is positively cooperative and shows a DNA affinity which is primarily nonionic. We demonstrate that independent of the DNA to which they are bound, the Net and Dist transition moments are inclined by 43 +/- 3 degrees from the helix axis, consistent with the idea that both drugs bind inside and parallel to the DNA small groove. From dichroism measurements, we show that the conformational change induced in calf thymus DNA by Dist does not kink or bend the helix and does not substantially alter the average inclination of the bases. Finally, we outline a statistical mechanical theory for calculation of binding isotherms when binding is coupled to a DNA structural change.     

Interaction of phenosafranine with nucleic acids and model polyphosphates: II. Characterisation of phenosafranine binding to DNA

The binding of phenosafranine (PS) to DNA was studied by a combination of spectroscopic methods (absorption and fluorescence) together with hydrodynamic measurements (sedimentation and viscosity), Analysis of spectroscopic binding curves revealed that the strength of binding of PS to DNA is generally lower than that of proflavine. These measurements enabled recognition of several modes of interaction between PS and native DNA: strong monomer binding prevailing at high DNA phosphate/dye ratios (p) comprising binding outside the DNA helix as well as intercalation; two modes of dimer binding at lower values of p; and probably also weak surface-binding of monomers as p approaches unity. Longer surface-bound aggregates of PS were not detected because of the low tendency of the dye to form aggregates, though the presence of dimeric species distinct frorn pure surface-stacked PS dimer was indicated by various observations. It occurs over a broad range of p values Starting at p ≈110 for ionic strengths 10^?3–10^?1. Thermal denaturation data indicate that this species is bound more strongly than pure surface-bound stacked dimer. Its dimeric character may be explained in terms of interaction of an intercalated dye molecule with an adjacent outside-bound one as suggested for acridines by Armstrong et al. Various properties of this species are discussed. Both strong and weak modes or binding of PS to DNA are sensitive to the presence of organic solvents. The effectiveness of solvents to destabilise the complexes substantially coincides with their capacity to alter the water activity. Viscometric investigations reveal that in the region of strongest bindins (p ? 15) the elongation of the DNA helix by approximately 0.18 nm per bound PS molecule is accompanied by a strong negative change in persistence length, i.e. bending. Similar bending is also found at higher levels of binding (p ? 15) induced by less lightly bound PS molecules, in which region, however, the unusually high elongation of approximately 0.34 nm per bound PS molecule is observed.     

New findings in the study on the intercalation of bisdaunorubicin and its monomeric analogues with naked and nucleus DNA

DNA is a target molecule for anthracycline anticancer drugs. We have used new anthracycline derivatives, bisdaunorubicin (WP631) and its monomeric analogues (WP700 serie), and look if there was a relation between the drug binding affinity to naked DNA and to cell nucleus in the cell with its cytotoxicity. Circular dichroism (CD) and fluorescence were used to follow the interaction of anthracycline derivatives with naked DNA and cell nuclei. WP631 interacts with DNA at two distinct stoichiometries, 6:1 and 3:1 base pair (bp)/WP631 molecule (3:1 and 1.5:1 per anthracycline rings). Monomeric daunorubicin (DNR) with its amino sugar N-bound to amino- and nitro-substituted benzyl moiety, representing p-xylenyl linker present in WP631 bisintercalator, is much more binding to DNA than DNR or WP631. These findings are supported by the study of drug binding by nuclei of K562 cells. Around 70% of WP700 intercalate to nucleus DNA in the steady-state, while only 45% of DNR intercalate DNA in the cell. The binding of WP631 by K562 cells is even less effective ( approximately 20%). WP 700 compounds, which are very similar to each other in their binding to DNA, self-association and cell accumulation, differ very distinctly in their cytotoxicity power. The most effective compounds are amino-benzyl derivatives of WP 700 series. The nitro-benzyl compounds have very low toxicity, even if they bind to DNA with similar power with that of the amino derivatives. The comparison of the all data clearly indicates no relation between cytotoxicity of the drug and its ability to intercalate DNA.     

A spectroscopic and surface plasmon resonance study of oleic acid/DNA complexes

The interaction of synthetic polynucleotide double strands with a natural lipid, oleic acid, was examined in diluted aqueous solutions by circular dichroism spectra, UV-absorption measurements, and surface plasmon resonance biosensor investigations. The investigations were performed with defined double and triple stranded oligo- and polydeoxyribonucleotides. Whereas duplexes are influenced by oleic acid ligandation, which could not be removed by ethanol dialysis procedure, no binding occurs to triple stranded DNA. The spectroscopic results indicate that oleic acid shows molecular recognition to AT b.p. motifs by groove binding. GC tracts - in particular alternating d[G-C] motifs - are strongly influenced by ligand interaction up to a ratio of one molecule per two base pairs. Likewise, the spectroscopic and morphologic changes in the supramolecular association of the complexes after treatment occur even after dialysis procedure. This was monitored with scanning force microscopy (SFM) as well. Additionally, monolayers of biotinylated DNA duplexes were immobilized on a streptavidin sensor-layer for surface plasmon resonance (SPR) observations. Small portions of the ligand were injected in continuous flow. Loosely bound molecules were removed by washing procedure. Injections of sodium hydroxide denature the DNA, releasing the tightly bound effectors. The amount of tightly bound oleic acid molecules was determined at one molecule per 2-3 base pairs. As consequence, a new mechanism of regulation of gene expression at nuclear membrane or by lipids inside DNA double helix has to be discussed.     

Interaction of paired homologous series of diacridines and triacridines with deoxyribonucleic acid

Viscometric measurements using covalently closed circular DNA and sonicated rod-like DNA fragments were performed to investigate unwinding and extension of the DNA helix associated with binding of paired homologous series of diacridines and triacridines. The maximum interchromophore distance for members of the diacridine series spans from 15.1 to 27.5 A, permitting the largest of these ligands to cover up to 4 or 5 base-pairs, allowing for helical twist and local unwinding in a bisintercalated complex lacking severe bending or kinking of the DNA backbone. Helix unwinding angles and increments in DNA contour length are characteristic of bifunctional reaction for all the diacridines studied, the DNA lattice appearing to saturate with one ligand molecule bound per 4 base-pairs. The triacridines, whose maximum end-to-end interchromophore distances are the same as those of their paired diacridines, have maximum central-to-terminal interchromophore distances covering the range 7.5-13.8 A and thus have the potential to form trisintercalated complexes with one or two base-pairs sandwiched between each chromophore. However, helix extension and unwinding parameters for the triacridines are similar to those of the diacridines, and we find no evidence of a transition from bifunctional to trifunctional reaction as the homologous series is ascended. In general, the binding site size appears to be 5 base-pairs for the triacridines. The stereochemical requirements for trisintercalation of triacridines are discussed with reference to the present findings and to the work of others.     

Mechanism of the delta wrench in opening the beta sliding clamp

The beta sliding clamp encircles DNA and tethers DNA polymerase III holoenzyme to the template for high processivity. The clamp loader, gamma complex (gamma 3 delta delta'chi psi), assembles beta around DNA in an ATP-fueled reaction. The delta subunit of the clamp loader opens the beta ring and is referred to as the wrench; ATP modulates contact between beta and delta among other functions. Crystal structures of delta.beta and the gamma 3 delta delta' minimal clamp loader make predictions of the clamp loader mechanism, which are tested in this report by mutagenesis. The delta wrench contacts beta at two sites. One site is at the beta dimer interface, where delta appears to distort the interface by via a steric clash between a helix on delta and a loop near the beta interface. The energy for this steric clash is thought to derive from the other site of interaction, in which delta binds to a hydrophobic pocket in beta. The current study demonstrates that rather than a simple steric clash with beta, delta specifically contacts beta at this site, but not through amino acid side chains, and thus is presumably mediated by peptide backbone atoms. The results also imply that the interaction of delta at the hydrophobic site on beta contributes to destabilization of the beta dimer interface rather than acting solely as a grip of delta on beta. Within the gamma complex, delta' is proposed to prevent delta from binding to beta in the absence of ATP. This report demonstrates that one or more gamma subunits also contribute to this role. The results also indicate that delta' acts as a backboard upon which the gamma subunits push to attain the ATP induced change needed for the delta wrench to bind and open the beta ring.     

DNA protection by aminothiols: study of the cysteamine - DNA interaction by vibrational spectroscopy

Infrared linear dichroism measurements and Roman scattering spectra show that the cysteamine molecule binds strongly to the DNA stabilizing the double helix in a B geometry conformation. The B→A conformational transition is not observed for a cysteamine/DNA ratio of one cysteamine molecule per two phosphate sites. No evidence of interaction has been found between the radioprotector and the DNA bases. A model is proposed in which the cysteamine molecule is bound by its two ends through electrostatic interaction to two consecutive phosphate groups along the same DNA strand.     

Complexes of RecA protein in solution. A study by small angle neutron scattering

RecA complexes on DNA and self-polymers were analysed by small-angle neutron scattering in solution. By Guinier analysis at small angles and by model analysis of a subsidiary peak at wider angles, we find that the filaments fall into two groups: the DNA complex in the presence of ATP gamma S, an open helix with pitch 95 A, a cross-sectional radius of gyration of 33 A and a mass per length of about six RecA units per turn, which corresponds to the state of active enzyme; and the compact form (bound to single-stranded DNA in the absence of ATP, or binding ATP gamma S in the absence of DNA, or just the protein on its own), a helical structure with pitch 70 A, cross-sectional radius of gyration 40 A and mass per length about five RecA units per turn, which corresponds to the conditions of inactive enzyme. The results are discussed in the perspective of unifying previous conflicting structural results obtained by electron microscopy.     

X-ray crystallographic study of DNA duplex cross-linking: simultaneous binding to two d(CGTACG)2 molecules by a bis(9-aminoacridine-4-carboxamide) derivative

Acridine-4-carboxamides form a class of known DNA mono-intercalating agents that exhibit cytotoxic activity against tumour cell lines due to their ability to inhibit topoisomerases. Previous studies of bis-acridine derivatives have yielded equivocal results regarding the minimum length of linker necessary between the two acridine chromophores to allow bis-intercalation of duplex DNA. We report here the 1.7 A resolution X-ray crystal structure of a six-carbon-linked bis(acridine-4-carboxamide) ligand bound to d(CGTACG)2 molecules by non-covalent duplex cross-linking. The asymmetric unit consists of one DNA duplex containing an intercalated acridine-4-carboxamide chromophore at each of the two CG steps. The other half of each ligand is bound to another DNA molecule in a symmetry-related manner, with the alkyl linker threading through the minor grooves. The two crystallographically independent ligand molecules adopt distinct side chain interactions, forming hydrogen bonds to either O6 or N7 on the major groove face of guanine, in contrast to the semi-disordered state of mono-intercalators bound to the same DNA molecule. The complex described here provides the first structural evidence for the non-covalent cross-linking of DNA by a small molecule ligand and suggests a possible explanation for the inconsistent behaviour of six-carbon linked bis-acridines in previous assays of DNA bis-intercalation.