Modulation of DNA supercoiling by interaction with netropsin and other minor groove binders

PICH and TOP3A cooperate to induce positive DNA supercoiling

All known eukaryotic topoisomerases are only able to relieve torsional stress in DNA. Nevertheless, it has been proposed that the introduction of positive DNA supercoiling is required for efficient sister-chromatid disjunction by Topoisomerase 2a during mitosis. Here we identify a eukaryotic enzymatic activity that introduces torsional stress into DNA. We show that the human Plk1-interacting checkpoint helicase (PICH) and Topoisomerase 3a proteins combine to create an extraordinarily high density of positive DNA supercoiling. This activity, which is analogous to that of a reverse-gyrase, is apparently driven by the ability of PICH to progressively extrude hypernegatively supercoiled DNA loops that are relaxed by Topoisomerase 3a. We propose that this positive supercoiling provides an optimal substrate for the rapid disjunction of sister centromeres by Topoisomerase 2a at the onset of anaphase in eukaryotic cells.

Probing the relative orientation of molecules bound to DNA by second-harmonic generation

We develop a model to probe the relative orientation of two second-order polarizable daunomycin molecules that are intercalated into a DNA duplex using optical second-harmonic (SH) generation. The SH field generated by the daunomycin molecules interfere with each other. Because the interference depends on the relative orientation of the daunomycin molecules, we can control the interference by changing the number of base pairs separating them. The relative orientation changes as the number of base pairs separating them, multiplied by 36°, which is the twist angle between neighboring base pairs. In this paper, we derive a set of relationships between the relative angle of the molecules and the nonlinear susceptibility elements, and we calculate the SH field generated by the DNA/molecular-pair complex attached to an isotropic dielectric sphere. Calculations reveal that the SH intensity varies periodically with the relative orientation of the two chromophores in the plane perpendicular to the helical axis. The predicted periodicity is in close agreement with experimental results. Structural changes induced by foreign molecules binding to DNA will change the relative orientation of the two chromophores and thereby change the SH interference pattern. We discuss the potential of this SH interference method in providing a new way to probe structural changes induced by the formation of biomolecule complexes. An important feature of the method is that it is label-free, that is, the binding molecule, in this case, daunomycin, is not tagged.

Atomic force microscopy study of DNA conformation in the presence of drugs

Binding of ligands to DNA gives rise to several relevant biological and biomedical effects. Here, through the use of atomic force microscopy (AFM), we studied the consequences of drug binding on the morphology of single DNA molecules. In particular, we quantitatively analyzed the effects of three different DNA-binding molecules (doxorubicin, ethidium bromide, and netropsin) that exert various pharmacologic and therapeutic effects. The results of this study show the consequences of intercalation and groove molecular binding on DNA conformation. These single-molecule measurements demonstrate morphological features that reflect the specific modes of drug-DNA interaction. This experimental approach may have implications in the design of therapeutically effective agents.

Torsional sensing of small-molecule binding using magnetic tweezers

DNA-binding small molecules are widespread in the cell and heavily used in biological applications. Here, we use magnetic tweezers, which control the force and torque applied to single DNAs, to study three small molecules: ethidium bromide (EtBr), a well-known intercalator; netropsin, a minor-groove binding anti-microbial drug; and topotecan, a clinically used anti-tumor drug. In the low-force limit in which biologically relevant torques can be accessed (<10 pN), we show that ethidium intercalation lengthens DNA ∼1.5-fold and decreases the persistence length, from which we extract binding constants. Using our control of supercoiling, we measure the decrease in DNA twist per intercalation to be 27.3 ± 1° and demonstrate that ethidium binding delays the accumulation of torsional stress in DNA, likely via direct reduction of the torsional modulus and torque-dependent binding. Furthermore, we observe that EtBr stabilizes the DNA duplex in regimes where bare DNA undergoes structural transitions. In contrast, minor groove binding by netropsin affects neither the contour nor persistence length significantly, yet increases the twist per base of DNA. Finally, we show that topotecan binding has consequences similar to those of EtBr, providing evidence for an intercalative binding mode. These insights into the torsional consequences of ligand binding can help elucidate the effects of small-molecule drugs in the cellular environment.

Magnetic tweezers measurements of the nanomechanical properties of DNA in the presence of drugs

Herein, we study the nanomechanical characteristics of single DNA molecules in the presence of DNA binders, including intercalating agents (ethidium bromide and doxorubicin), a minor groove binder (netropsin) and a typical alkylating damaging agent (cisplatin). We have used magnetic tweezers manipulation techniques, which allow us to measure the contour and persistence lengths together with the bending and torsional properties of DNA. For each drug, the specific variations of the nanomechanical properties induced in the DNA have been compared. We observed that the presence of drugs causes a specific variation in the DNA extension, a shift in the natural twist and a modification of bending dependence on the imposed twist. By introducing a naive model, we have justified an anomalous correlation of torsion data observed in the presence of intercalators. Finally, a data analysis criterion for discriminating between different molecular interactions among DNA and drugs has been suggested.

Inhibition of human papilloma virus E2 DNA binding protein by covalently linked polyamides

Polyamides are a class of heterocyclic small molecules with the potential of controlling gene expression by binding to the minor groove of DNA in a sequence-specific manner. To evaluate the feasibility of this class of compounds as antiviral therapeutics, molecules were designed to essential sequence elements occurring numerous times in the HPV genome. This sequence element is bound by a virus-encoded transcription and replication factor E2, which binds to a 12 bp recognition site as a homodimeric protein. Here, we take advantage of polyamide:DNA and E2:DNA co-crystal structural information and advances in polyamide synthetic chemistry to design tandem hairpin polyamides that are capable of displacing the major groove-binding E2 homodimer from its DNA binding site. The binding of tandem hairpin polyamides and the E2 DNA binding protein to the DNA site is mutually exclusive even though the two ligands occupy opposite faces of the DNA double helix. We show with circular permutation studies that the tandem hairpin polyamide prevents the intrinsic bending of the E2 DNA site important for binding of the protein. Taken together, these results illustrate the feasibility of inhibiting the binding of homodimeric, major groove-binding transcription factors by altering the local DNA geometry using minor groove-binding tandem hairpin polyamides.

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.

Binding of 2-azaanthraquinone derivatives to DNA and their interference with the activity of DNA topoisomerases in vitro

We have investigated the binding ability to DNA of compounds belonging to the 2-azaanthraquinone-type structure and have examined the effect on the activity of DNA gyrase as well as on mammalian topoisomerases in vitro. Using different biophysical techniques it was found that one of these ligands, 9-((2-dimethylamino)ethyl)amino)-6-hydroxy-7-methoxy-5, 10-dihydroxybenzo[g]isoquinoline-5,10-dione (TPL-I), is an intercalating DNA binding agent, whereas the parent compound tolypocladin (TPL) and a derivative (TPL-II) showed almost no similar affinity to DNA. CD measurements demonstrated a significant and selective binding tendency of TPL-I to alternating purine/pyrimidine sequences with some preference for poly(dA-dT). poly(dA-dT). Tm values were increased of the ligand complex with the alternating AT-containing duplex polymer. The binding to various DNAs was characterized by CD and visible absorption spectral changes. From the latter, different binding constants of 6.2 x 10(5) and 1.5 x 10(5) M-1 were obtained for poly(dA-dT).poly(dA-dT) and poly(dA). poly(dT), respectively. Sedimentation measurements with supercoiled pBR322 plasmid DNA clearly indicated an intercalative binding mechanism associated with an unwinding angle of about 18 degrees. These results suggest that the intercalative binding of TPL-I is promoted by the 2-(dimethylamino)ethylamino group substituted on carbon 9 of the anthraquinone system. The cytotoxic compound TPL-I, but not TPL or TPL-II, effectively inhibited the DNA supercoiling reaction of DNA gyrase and the activity of mammalian topoisomerases I and II as measured by the relaxation assay. TPL-I affects the cleavage reaction of topoisomerases on a single site located in alternating purine-pyrimidine sequence regions. The inhibitory potency of TPL-I can be ascribed to a blocking of cleavage sites on the DNA substrate, which correlates with the sequence preference of the ligand.

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 studies and influence on the activity of DNA topoisomerases of bis-netropsins: different effects of analogs containing cis and trans ethylene linkers

Binding to DNA and synthetic duplex polymers of two bifunctional netropsins and effects on supercoiled plasmid DNA as well as their inhibitory potency on DNA topoisomerases have been investigated. Characteristic differences were found in the DNA binding properties of the two bis-netropsins containing a cis and trans tether as reflected by CD, thermal melting and sedimentation measurements. CD results indicate, that the bis-netropsins interact with DNA by a two-step binding mode depending on the ligand concentration. The trans bis-netropsin may form stable complexes with different DNA's at high salt concentration, whereas for cis bis-netropsin DNA complexes the second binding step is completely abolished. The variations in the DNA binding ability of trans and cis bis-netropsin show a close relationship to the differences observed in their inhibitory effects on DNA topoisomerases. It appeared that trans bis-netropsin more strongly blocks topoisomerase activity than the cis isomer and represents the most potent inhibitor of DNA gyrase. Differences in the DNA. binding ability of the bis-netropsins and their inhibitory potency on topoisomerase activity are explained in terms of bidentate and monodentate binding mode of the trans and cis isomer, respectively.

Effects of bifunctional netropsin-related minor groove-binding ligands on mammalian type I DNA topoisomerase

We investigated the effects of compounds with two covalently linked netropsin moieties (bis-netropsin) on the function of mammalian type I DNA topoisomerase (topo I) in vitro. We initiated these studies because earlier studies had shown that certain bis-netropsins possess a several-fold higher antitumor and antiviral activity than netropsin. We confirmed that the parent compound netropsin, but not its bifunctional derivatives, induce supercoils in closed DNA. We determined that bis-netropsins inhibit the binding of topo I to DNA more efficiently than netropsin and that bis-netropsins but not netropsin induce specific DNA strand cleavage in the presence of topo I. We discuss a model explaining the different effects of netropsin and bis-netropsins on topo I.

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.

Interaction of a DNA-threading netropsin-amsacrine combilexin with DNA and chromatin

Combilexins are a group of DNA ligands having a sequence-specific minor groove binding element combined with an intercalating chromophore which stabilizes the DNA complex and can interfere with topoisomerases. In this study, complementary methods of spectroscopy (absorption, circular dichroism, electric linear dichroism) and biochemistry (viscometry, footprinting) have been applied to explore the nature of the complex formed between a new amsacrine-4-carboxamide-netropsin combilexin and DNA or chromatin. Collectively, the structural and kinetic data concur that the conjugate threads through the DNA double helix so as to intercalate its acridine chromophore, leaving the netropsin moiety and the methanesulfonanilino group positioned within the minor and major grooves of the double helix, respectively. The hybrid retains the AT selectivity conferred by the netropsin moiety. The threading-type intercalation process, evidenced by stopped-flow measurements, is affected when the DNA is wrapped around histones. The composite drug can bind to both the DNA linker segments and the nucleosomal cores in chromatin though, unlike its constituents, it antagonizes the salt-induced condensation of chromatin. As far as its mode of binding to DNA is concerned, the netropsin-amsacrine hybrid molecule exhibits structural features reminiscent of the antitumor antibiotics nogalamycin and pluramycin. The design of DNA-threading combilexins provides an original route for the development of sequence-specific ligands capable of forming stable complexes with DNA.

Nuclear matrix protein ARBP recognizes a novel DNA sequence motif with high affinity

ARBP is a nuclear protein that specifically binds to matrix/scaffold attachment regions (MARs/SARs). Here we characterize by DNase I footprinting, dimethyl sulfate protection, and mobility shift assays two binding sites for ARBP within a chicken lysozyme MAR fragment. Our results indicate that ARBP recognizes a novel DNA sequence motif containing the central sequence 5'-GGTGT-3' and flanking AT-rich sequences. Binding occurs through major groove contacts to two guanines of the central sequence. Collective and single-base substitutions in the 5'-GGTGT-3' core motif result in loss or significant reductions of ARBP binding, underscoring the importance of the GC-rich core sequence. Structural elements of the sequence motif are probably also recognized. The affinity of ARBP to both binding sites is surprisingly high [KD = (2-6) x 10(-10) M]. High-affinity recognition of the identified DNA motif in MARs/SARs by ARBP is likely an important feature in the domain organization of chromatin.