Abolition of intrinsically bent DNA structure components in AT clusters by netropsin interaction; titration viscometric investigations

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.

Multimode interaction of Hoechst 33258 with eukaryotic DNA; quantitative analysis of the DNA conformational changes

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 degrees C, 22 degrees C and 40 degrees 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, delta a/a, and hydrodynamically operative DNA contour length, deltaL/L. Delta a/a(r) primarily is a measure of ligand-induced DNA helix stiffening, but both, delta a/a(r) and deltaL/L(r), generally depend also on ligand binding induced DNA bending or DNA unbending. The essential difference obviously is that delta a/a(r) is influenced by the randomly distributed helix bends and deltaL/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 approximately = 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.

DNA binding properties of minor groove binders and their influence on the topoisomerase II cleavage reaction

We present titrations of the human delta beta-globin gene region with DNA minor groove binders netropsin, bisnetropsin, distamycin, chromomycin and four bis-quaternary ammonium compounds in the presence of calf thymus topoisomerase II and DNase I. With increasing ligand concentration, stimulation and inhibition of enzyme activity were detected and quantitatively evaluated. Additionally we show a second type of stimulation, the appearance of strong new topoisomerase II cleavage sites at high ligand concentrations. The specific binding sites of the minor groove binders of the DNA sequence and their microscopic binding constants were determined from DNase I footprints. A binding mechanism for minor groove binders is proposed in order to explain these results especially when ligand concentration is increased.

Deformyldistamycin-DNA interaction; DNA conformational changes as revealed by titration rotational viscometry

The conformational changes of a natural DNA species on binding of deformyl-distamycin (dDst) have been analysed, at 22 degrees C and 7.6 degrees C, in terms of changes of apparent persistence length (a) and of apparent contour length (L), by means of titration rotational viscometry with both high and low molar mass calf thymus (ct) DNA molecules. Next to ligand binding mediated alterations in DNA stiffness, changes of a are the result of helix bending and also of unbending of intrinsic helix bends. A test for the latter are viscosity measurements at different temperatures. Changes of L, on binding of non-intercalating ligands, are interpreted as the result of changes in the intrinsic solenoidal structure components of the natural eukaryotic DNA. Such tertiary-structure components do exist if base sequence dependent helix bends of (nucleosomal) DNA are phased with the helix screw [Drew & Travers, JMB 186, 773 (1985); Reinert et al., JBSD 9, 537 (1991)]. Hence, the measured very small changes of L at ligand/DNA-P ratios r < 0.02 are mainly understood as a partial abolition of intrinsic tertiary structure components and the following negative ones as a respective reinforcement of such structures by dDst binding to AT rich binding sites. Several r-intervals with different slope of the viscosity changes could be resolved at r < 0.05. The resolution of more than four modes of dDst interaction with ctDNA at very low r values is comparable to DNA interaction of Nt and several other ligands but not of distamycin. Advanced titration rotational DNA-viscometry is again able to resolve subtle quantitative details of ligand mediated DNA conformational changes of high stereochemical relevance.

Fluorescence anisotropy of DNA/DAPI complex: torsional dynamics and geometry of the complex

Fluorescence depolarization of synthetic polydeoxynucleotide/4'-6-diamidino-2-phenylindole dihydrochloride complexes has been investigated as a function of dye/polymer coverage. At low coverage, fluorescence depolarization is due to local torsional motions of the DNA segment where the dye resides. At relatively high coverage, fluorescence depolarization is dominated by energy transfer to other dye molecules along the DNA. The extent of the observed depolarization due to torsional motion depends on the angle the dye molecule forms with the DNA helical axis. A large torsional motion and a small angle produce the same depolarization as a small torsional motion and a large projection angle. Furthermore, the extent of transfer critically depends on the relative orientation of dye molecules along the DNA. The effect of multiple transfer is examined using a Monte Carlo approach. The measurement of depolarization with transfer, at high coverage, allows determination of the dye orientation about the DNA helical axis. The value of the torsional spring constant is then determined, at very low coverage, for few selected polydeoxynucleotides.

Mechanochemical study of NaDNA and NaDNA-netropsin fibers in ethanol-water and trifluoroethanol-water solutions

Highly oriented calf-thymus NaDNA fibers, prepared by a wet-spinning method, were complexed with netropsin in ethanol-water and trifluoroethanol (TFE)-water solutions. The relative fiber length, L/L0, was measured at room temperature as a function of ethanol or TFE concentration to obtain information on the B-A conformational transition. The B-A transition point and transition cooperativity of the fibers were calculated. The binding of netropsin to NaDNA fibers was found to stabilize B form and to displace the B-A transition to higher ethanol concentration, as indicated by its elongational effect on the fiber bundles. An increased salt concentration was found to reduce netropsin binding. In netropsin-free ethanol solution, the dissociation of bound netropsin from the DNA fibers was observable. Pure B-NaDNA fibers were found to be more stable in TFE solution than in ethanol solution. This was interpreted as being due to a different steric factor and a larger polarity of TFE compared with ethanol, resulting in its smaller capacity to reduce the water activity and dielectric constant of the medium in the immediate vicinity of DNA fibers. Therefore, the effect of netropsin binding on the B-A transition of NaDNA fibers became less obvious in TFE solution. In another series of experiments, L/L0 was measured as a function of temperature to obtain information on the helix-coil transition, or melting, as well as the B-A transition of NaDNA and NaDNA-netropsin fibers. The melting temperature and helix-coil transition width were calculated from the melting curves. A phenomenological approach was used to describe the melting behavior of the fibers in and around the B-A transition region. The effect of netropsin on the melting of DNA fibers was attributed mainly to the stabilization of B-DNA and to a higher melting cooperativity in the B-DNA region.

DNA interaction of the imidazole-containing lexitropsin ImPy: titration viscometric study in comparison to netropsin

The imidazole (Im) containing lexitropsin ImPy related to netropsin (Nt) is a sequence reading DNA ligand which, in contrast to Nt, permits binding to a GC base pair. The ImPy induced DNA conformational changes differ significantly from those induced by Nt as monitored by titration viscometry, although interaction modes have also been resolved with boundaries at the same ligand to DNA phosphate ratio, r. Evidently ImPy covers similar binding sites (in the same sequence) as Nt for natural calf thymus DNA at r < 0.023. This result suggests that the preferred binding sites of ImPy are A tracts (cf. K.E.R. JBSD 9(1993) 973), in agreement with previous data. The respective DNA coil expansion, most probably caused by unbending (l.c.), is similar but smaller compared to the Nt-DNA interaction. These results again suggest that, at low r values, the van der Waals interaction in the narrowed minor groove of AT clusters provides a dominating energy contribution to ImPy binding. At r > 0.03 the DNA coil expansion increases to extremely high values in that r range where Nt binding (to mixed AT/GC sequences) induces no effect at all owing to steric hindrance with the amino group of guanine. On the basis of many quantitative results for the Nt-DNA systems these effects can be understood in terms of an unbending of intrinsic helix bends (l.c.). They are of considerable interest in connection with the ability of such compounds to influence the direction of the local regulatory relevant DNA curvature.

Long-range interactions between DNA-bound ligands

We have studied the interaction of the A:T specific minor-groove binding ligand 4',6-diamidino-2-phenylindole (DAPI) with synthetic DNA oligomers containing specific binding sites in order to investigate possible long-range interactions between bound ligands. We find that DAPI binds cooperatively to the oligomers. The degree of cooperativity increases with increasing number of binding sites and decreases with the separation between them. This dependence is paralleled by changes in the induced circular dichroism spectrum of DAPI, which decreases in intensity at 335 nm and increases at 365 nm. These results are consistent with an allosteric interaction of DAPI with DNA, where bound ligands cooperatively alter the structure of the DNA molecule. This structural change seems possible to induce under various conditions, including physiological. One consequence of allosteric binding is that ligands bound at a distance from each other sense each other's presence and influence each others' properties. If some regulatory proteins induce the same conformational change as DAPI, novel mechanisms for controlling gene expression can be anticipated.

Counterion-type characteristic effects on intrinsic bending components of calf thymus DNA; hydrodynamic investigations

This paper stresses structural differences in A.T clusters of the ammonium salt of calf thymus (ct) DNA (ctNH4DNA) and the respective sodium salt, ctNaDNA. Sequence mediated intrinsic helix bends of ctNaDNA, distributed along the molecule partially randomly and partially phased with the helix screw (accompanying paper), are enhanced in ctNH4DNA. Additionally, the number of the most strongly bent segments (of A-tract character) is raised in ctNH4DNA by a counterion mediated shift of the equilibrium between at least two local DNA conformations. Nevertheless, the apparent DNA elongation, induced by the abolition of a single apparent solenoid-related DNA tertiary structure component which generates a special intrinsic DNA bend, is the same for NH4DNA and NaDNA. These conclusions follow from two independent sets of experimental results: (1.) Titration viscometric measurements with ctNH4DNA as a function of the cation concentration in comparison to ctNaDNA (KER et al., JBSD 9,537 (1991)) and respective DNA conformational analyses. (2.) Quantitative viscometric analysis of DNA conformational changes on netropsin (Nt) interaction of ctNH4DNA at different temperatures and comparison with the respective data for ctNaDNA (KER et al., NAR 9,2335 (1981).