Two binding modes of netropsin are involved in the complex formation with poly(dA-dT).poly(dA-dT) and other alternating DNA duplex polymers

Using CD measurements we show that the interaction of netropsin to poly(dA-dT).poly(dA-dT) involves two binding modes at low ionic strength. The first and second binding modes are distinguished by a defined shift of the CD maximum and the presence of characteristic isodichroic points in the long wavelength range from 313 nm to 325 nm. The first binding mode is independent of ionic strength and is primarily determined by specific interaction to dA.dT base pairs. Employing a netropsin derivative and different salt conditions it is demonstrated that ionic contacts are essential for the second binding mode. Other alternating duplexes and natural DNA also exhibit more or less a second step in the interaction with netropsin observable at high ratio of ligand per nucleotide. The second binding mode is absent for poly(dA).poly(dT). The presence of a two-step binding mechanism is also demonstrated in the complex formation of poly(dA-dT).poly(dA-dT) with the distamycin analog consisting of pentamethylpyrrolecarboxamide. While the binding mode I of netropsin is identical with its localization in the minor groove, for binding mode II we consider two alternative interpretations.     

Interaction of the nonintercalative antitumour drugs SN-6999 and SN-18071 with DNA: influence of ligand structure on the binding specificity

Binding to DNA's of the non-intercalative ligands SN-6999 and SN-18071 has been studied by means of circular dichroism, UV absorption, thermal melting and for SN-6999 by viscosity measurements. Both antitumour drugs show a preference for dA.dT rich DNA's, but the base pair selectivity of SN-18071 is lower as indicated by some affinity to dG.dC containing duplex DNA. The dA.dT base pair specificity of SN-6999 is comparable to that of netropsin. It forms very stable complexes with dA.dT containing duplex DNA and competes with netropsin binding on DNA. The ligands SN-18071 and pentamidine are totally released from their complexes with poly(dA-dT).poly(dA-dT) by competitive netropsin binding. The results demonstrate that hydrogen bonding capacity of the ligand in addition to other factors strongly contribute to the base sequence specificity in the recognition process of the ligand with DNA. A binding model of SN-6999 with five dA.dT pairs in the minor groove of B-DNA is suggested.     

Two Binding Modes of Netropsin are Involved in the Complex Formation with Poly(dA-dT)·Poly(dA-dT) and other Alternating DNA Duplex Polymers

Abstract

Using CD measurements we show that the interaction of netropsin to poly(dA-dT)·poly(dA-dT) involves two binding modes at low ionic strength. The first and second binding modes are distinguished by a defined shift of the CD maximum and the presence of characteristic isodichroic points in the long wavelength range from 313 nm to 325 nm. The first binding mode is independent of ionic strength and is primarily determined by specific interaction to dA·dT base pairs. Employing a netropsin derivative and different salt conditions it is demonstrated that ionic contacts are essential for the second binding mode. Other alternating duplexes and natural DNA also exhibit more or less a second step in the interaction with netropsin observable at high ratio of ligand per nucleotide. The second binding mode is absent for poly(dA)·poly(dT). The presence of a two-step binding mechanism is also demonstrated in the complex formation of poly(dA-dT)·poly(dA-dT) with the distamycin analog consisting of pentamethylpyrrolecarboxamide. While the binding mode I of netropsin is identical with its localization in the minor groove, for binding mode II we consider two alternative interpretations.     

Specific protection of DNA by distamycin A, netropsin and bis-netropsins against the action of DNAse I

Interaction of netropsin, distamycin A and a number of bis-netropsins with DNA fragments of definite nucleotide sequence was studied by footprinting technique. The nuclease protection experiments were made at fixed DNA concentration and varying ligand concentrations. The affinity of ligand for a DNA site was estimated from measurements of ligand concentration that causes 50% protection of the DNA site. Distribution pattern of the protected and unprotected regions along the DNA fragment was compared with the theoretically expected arrangement of the ligand along the same DNA. The comparison led us to the following conclusions: 1. Footprinting experiments show that at high levels of binding the arrangement of netropsin molecules along the DNA corresponds closely to the distribution pattern expected from theoretical calculations based on the known geometry of netropsin--DNA complex. However, the observed differences in the affinity of netropsin for various DNA sequences is markedly greater than that expected from theoretical calculations. 2. Netropsin exhibits a greater selectivity of binding than that expected for a ligand with three specific reaction centers associated with the antibiotic amide groups. It binds preferentially to DNA regions containing four or more successive AT pairs. Among 13 putative binding sites for netropsin with four or more successive AT pairs there are 11 strong binding sites and two weaker sites which are occupied at 2 D/P less than or equal to 1/9 and 2 D/P = 1/4, respectively. 3. The extent of specificity manifested by distamycin A is comparable to that shown by netropsin although the molecule of distamycin A contains four rather than three amide groups. At high levels of binding distamycin A occupies the same binding sites on DNA as netropsin does. 4. The binding specificity of bis-netropsins is greater than that of netropsin. Bis-netropsins can bind to DNA in such a way that the two netropsin-like fragments are implicated in specific interaction with DNA base pairs. However, the apparent affinity of bis-netropsins estimated from footprinting experiments is comparable with that of netropsin for the same DNA region. 5. At high levels of binding bis-netropsins and distamycin A (but not netropsin) can occupy any potential site on DNA irrespectively of the DNA sequence. 6. Complex formation with netropsin increases sensitivity to DNase I at certain DNA sites along with the protection effect observed at neighboring sites.     

Binding of nonintercalative antitumor drugs to DNA-polymers: structural effects of bisquaternary ammonium heterocycles

The binding of the antitumor agents SN-16814 nd SN-13232 to various DNA's in solution was monitored by CD and UV absorption measurements. In addition comparative studies with dA.dT containing duplex DNA of the related ligands SN-6136 and SN-6324 were included with respect to effects of structural variations. In general all four ligands show a dA.dT preference in their binding affinity to DNA. Differences were observed for the reaction of SN-16814 which contains bicyclic ring system: it has a lower base pair selectivity, shows some affinity to poly(dG-dC).poly(dG-dC), poly(rA).poly(rU) and poly(rU). The binding mechanism of SN-16814 is associated with a significant time dependent binding effect in CD spectra and UV absorption in case of reaction with poly(dA).poly(dT) and poly(dI).poly(dC) indicating a slow kinetics. The preferred binding to dA.dT base pairs in DNA decreases in the order from SN-61367 greater than SN-13232 greater than SN-6324,SN-16814 as judged from CD titration studies, salt dissociation and melting temperature data. Competitive binding experiments with netropsin (Nt) or distamycin-5 revealed that SN-16814 and SN-13232 are displaced from poly(dA.dT).poly(dA-dT) suggesting that both ligands are less strongly bound than Nt and Dst-5 within the minor groove of B-DNA. These studies are consistent with results of the DNAse I cleavage of poly(dA-dT).poly(dA-dT) which show the same relative order of inhibition of the cleavage reaction due to ligand binding. The results suggest that the variability of the DNA binding and dA.dT sequence specificity may reside in the adaptability of benzamide-type ligands in the helical groove which is influenced by distinct structural modifications of the ligand conformation.     

Binding of netropsin to DNA in complexes with polypeptides containing repetitive lysine sequences

The interaction of the antibiotic netropsin with calf thymus DNA, T4 DNA and poly(dA-dT) . poly(dA-dT) in complexes with sequential polypeptides containing repetitive lysine sequences and histone H1 was investigated using circular dichroism spectroscopy and equilibrium dialysis. Both soluble DNA-polypeptide complexes and insoluble complexes showed binding of netropsin. The possibility of displacement of polypeptides from DNA binding sites by competition with netropsin molecules was eliminated by experiments using 14C-labelled polypeptides. From the analysis of CD titration behavior as well as from the results of equilibrium dialysis studies it follows that netropsin does not compete with polypeptides for DNA binding sites, which suggests that these two ligands occupy different sites. Various explanations for minor differences in the CD behavior of the bound netropsin in the saturation region are also discussed.     

Sequence-recognition and cleavage of DNA by a netropsin-phenazine-di-N-oxide conjugate

We report the synthesis, DNA-binding and cleaving properties, and cytotoxic activities of R-128, a hybrid molecule in which a bis-pyrrolecarboxamide-amidine element related to the antibiotic netropsin is covalently tethered to a phenazine-di-N-oxide chromophore. The affinity and mode of interaction of the conjugate with DNA were investigated by a combination of absorption spectroscopy, circular dichroism, and electric linear dichroism. This hybrid molecule binds to AT-rich sequences of DNA via a bimodal process involving minor groove binding of the netropsin moiety and intercalation of the phenazine moiety. The bidentate mode of binding was evidenced by linear dichroism using calf thymus DNA and poly(dA-dT).(dA-dT). In contrast, the drug fails to bind to poly(dG-dC).poly(dG-dC), because of the obstructive effect of the guanine 2-amino group exposed in the minor groove of this polynucleotide. DNase I footprinting studies indicated that the conjugate interacts preferentially with AT-rich sequences, but the cleavage of DNA in the presence of a reducing agent can occur at different sequences not restricted to the AT sites. The main cleavage sites were detected with a periodicity of about 10 base pairs corresponding to approximately one turn of the double helix. This suggests that the cleavage may be dictated by the structure of the double helix rather than the primary nucleotide sequence. The conjugate which is moderately toxic to cancer cells complements the tool box of reagents which can be utilized to produce DNA strand scission. The DNA cleaving properties of R-128 entreat further exploration into the use of phenazine-di-N-oxides as tools for investigating DNA structure.     

Comparison of binding sites in DNA for berenil, netropsin and distamycin. A footprinting study

Techniques of DNase I and micrococcal nuclease footprinting have been used to compare the binding sites for berenil, netropsin and distamycin on two different DNA fragments. Each ligand binds to the A + T-rich zones which contain clusters of at least four A.T base pairs. Neither guanosine nor cytidine nucleotides appear to be allowed within the A + T-rich runs which constitute the preferred binding sites, although they are sometimes protected from DNase I cleavage in neighbouring regions. Berenil and netropsin share with distamycin the property of causing enhanced rates of cleavage at certain sequences flanking their binding sites. There are significant differences in the concentrations of each ligand required to produce defined patterns of protection, seemingly dependent upon the nature (and possibly the gross base composition) of the piece of DNA being used in the experiment.     

Synthetic DNA-bindings ligands containing reaction centers specific for AT- and GC-pairs in DNA

In the present communication design, synthesis and DNA binding activities of three bis-netropsins and two netropsin analogs containing two N-propylpyrrolecarboxamide fragments linked covalently to peptides Gly-Gly-(analog I) and Val-Val-Val-Gly-Gly-(analog II) are reported. Each bis-netropsin consists of two netropsin-like fragments attached to peptides -Gly-Cys-Gly-NH2 (compound IIIa), H-Gly-Cys-Gly-Gly-Gly-(compound IV) or Gly-Cys-Sar-NH2 (compound IIIb) which are linked symmetrically via S-S bonds. Physico-chemical studies show that each bis-netropsin carries 6 AT-specific reaction centers and covers approximately 10 base pairs upon binding to poly(dA).poly(dT). This indicates that two netropsin-like fragments of the bis-netropsin molecule are implicated in specific interaction with DNA base pairs. The peptide fragments of bis-netropsins IIIa and IV form small beta-sheets containing two-GC-specific reaction centers. The DNase I cleavage patterns of bis-netropsin-DNA complexes visualized by high resolution gel electrophoresis show that the preferred binding sites for bis-netropsins IIIa and IV are identical and contain two runs of three or more AT pairs separated by two GC pairs. Specificity determinants of netropsin analog II binding in the beta-associated dimeric form are identical to those of bis-netropsin IIIa thereby indicating that there is a similarity in the structure of complexes formed by these ligands with DNA. In the monomeric form analog II exhibits binding specificity identical to that of analog I. Replacement of C-terminal glycine residues by sarcosines in the peptide fragments of bis-netropsin IIIa leads to a decrease in the affinity of ligand for DNA.     

Binding of Nonintercalative Antitumor Drugs to DNA-Polymers: Structural Effects of Bisquaternary Ammonium Heterocycles

Abstract

The binding of the antitumor agents SN-16814 nd SN-13232 to various DNA's in solution was monitored by CD and UV absorption measurements. In addition comparative studies with dA · dT containing duplex DNA of the related ligands SN-6136 and SN-6324 were included with respect to effects of structural variations. In general all four ligands show a dA · dT preference in their binding affinity to DNA.

Differences were observed for the reaction of SN-16814 which contains bicyclic ring system: it has a lower base pair selectivity, shows some affinity to poly(dG-dC) · poly(dG-dC), poly(rA) · poly(rU) and poly(rU). The binding mechanism of SN-16814 is associated with a significant time dependent binding effect in CD spectra and UV absorption in case of reaction with poly(dA) · poly(dT) and poly(dI) · poly(dC) indicating a slow kinetics.

The preferred binding to dA · dT base pairs in DNA decreases in the order from SN-61367 > SN-13232 > SN-6324, SN-16814 as judged from CD titration studies, salt dissociation and melting temperature data. Competitive binding experiments with netropsin (Nt) or distamycin-5 revealed that SN-16814 and SN-13232 are displaced from poly(dA-dT) · poly(dA-dT) suggesting that both ligands are less strongly bound than Nt and Dst-5 within the minor groove of B-DNA. These studies are consistent with results of the DNAase I cleavage of poly(dA-dT) · poly(dA-dT) which show the same relative order of inhibition of the cleavage reaction due to ligand binding. The results suggest that the variability of the DNAbinding and dA · dT sequence specificity may reside in the adaptability of benzamide-type ligands in the helical groove which is influenced by distinct structural modifications of the ligand conformation.     

Variation of DNA sequence specificity of DNA-oligopeptide binding ligands related to netropsin: imidazole-containing lexitropsins

CD binding studies of nonintercalative oligopeptides related to netropsin, named lexitropsins, have been carried out with synthetic duplex DNAs and natural DNA. While netropsin possesses a high dA.dT sequence specificity, these ligands show a progressive lowering of the ability to bind to dA.dT basepairs in DNA and a dramatic reduction of the sequence specificity seen at high salt concentration due to a replacement of pyrrole moieties by imidazoles. This variation in DNA sequence specificity of lexitropsins is mirrored in corresponding large differences in the template inactivation of poly(dA-dT).poly(dA-dT) in the RNA polymerase reaction by these drugs. The presence of imidazole permits binding of the oligopeptide to dG.dC pairs, which is most effective for the triimidazole peptide. Results at increasing salt concentration reveal, however, that a tight binding to pure dG.dC sequences does not occur. A proper sequence containing dG.dC and dA.dT pairs is supposed to be required for a higher specificity. The CD data accord well with previously reported melting studies and are in favor of recent theoretical results suggesting that the diminished AT preference may be due to an increase in the complexation energy with the dG.dC pairs.     

Structure and Dynamics of Netropsin-Poly(dA-dT)· Poly(dA-dT) Complex: 500 MHz 1H NMR Studies

Abstract

Antibiotic netropsin is known to bind specifically to A and T regions in DNA; the mode of binding being non-intercalative. Obviously, H-bonding between the proton donors of netropsin and acceptors N3 of A and 02 of T comes as a strong possibility which might render this specificity. In netropsin there could be 8 proton donors: four terminal amino groups and four internal imino groups. However, methylation of the terminal amino groups does not alter the binding affinity of netropsin to DNA—but the modification of the internal imino groups significantly lowers the binding affinity. Hence, the logical conclusion is that netropsin may specifically interact with A and T through H-bonding and in order to do so, it should approach the helix from the minor groove. The present paper provides experimental data which verify the conclusion mentioned above.

Using poly(dA-dT)? poly(dA-dT) as a model system it was observed following a thorough theoretical stereochemical analysis that netropsin could bind to -(T-A-T) sequence of the polymer in the B-form through the minor groove by forming specific B-bonding. Models could be either right or left-handed B-DNA with a mono or dinucleotide repeat.

By monitoring the ³¹P signals of free poly(dA-dT) ? poly(dA-dT) and netropsin-poly(dA-dT)? poly(dA-dT) complex we show that the drug changes the DNA structure from essentially a mononucleotide repeat to that of very dominant dinucleotide repeat; however the base- pairing in the DNA-drug complex remain to be Watson-Crick. Whether H-bonding is the specific mode of interaction was judged by monitoring the imino protons of netropsin in the presence of poly(dA-dT) ? poly(dA-dT). This experiment was conducted in 90% H₂O + 10% D₂O Using the time-shared long pulse. It was found that exchangeable imino protons of netropsin appear in the drug-DNA complex and disappear upon increasing the D₂O content; thus confirming that H-bonding is indeed the specific mode of interaction. From these and several NOE measurements, we propose a structure for poly(dA-dT)? poly(dA-dT(-netropsin complex.

In summary, experimental data indicate that netropsin binds to poly(dA-dT)? poly(dA-dT) by forming specific hydrogen bonds and that the binding interaction causes the structure to adopt a Watson-Crick paired dinucleotide repeat motif. The proposed hydrogen bonds can form only if the drug approaches the DNA from the minor groove. Within the NMR time scale the interaction between the ligand and DNA is a fast one. From the NOE experimental data, it appears that poly(dA-dT)? poly(dA-dT) in presence of netropsin exists as an equilibrium mixture of right- and left-handed B-DNA duplexes with a dinucleotide repeat—with a predominance of the left-handed form. The last conclusion is a soft one because it was very difficult to make sure the absence of spin diffusion. In a 400 base pairs long DNA duplex- drug complex (as used in this study), equilibrium between right and left-handed helices can also mean the existence of both helical domains in the same molecule with fast interchange between these domains or/and unhindered motion/propagation of these domains along the helix axis.     

Specific DNA cleavage by an analog of netropsin containing a copper(II) chelating peptide Gly-Gly-His]

Experimental data are reported on DNA-cleaving activity of the synthetic netropsin analogs consisting of the two N-propylpyrrole carboxamide units linked covalently through two or three glycine residues to a copper-chelating tripeptide glycyl-glycyl-L-histidine. Incubation of DNA restriction fragment and netropsin analog in the presence of ascorbate, hydrogen peroxide and Cu2+ ions resulted in selective cleavage of the DNA at or near the preferred sites for binding of netropsin analog. A similar cleavage pattern is observed after X-ray irradiation of DNA complexes with netropsin analogs tethered with Cu2+ ions. The cleavage patterns are found to be dependent on the length of the connecting chain between the histidine-containing tripeptide and netropsin analog. The netropsin analog containing three glycine residues in the connecting chain, but not the analog with a shorter linker chain, can generate an intense cleavage of one of the two polynucleotide chains at a position corresponding to the presumed binding site for the dimeric ligand species. More than 50% of the total DNA can be cleaved at this position after X-ray irradiation. From analysis of the nucleotide sequences surrounding the preferred cleavage site on several DNA fragments we found that the consensus is 5'-TTTTNCA*AAA-3', where N is an arbitrary nucleotide. The Cu(2+)-mediated cleavage of DNA occurs at the second adenine (indicated by an asterisk) from the 5'-end of the sequence. The greatest cleavage activity is observed when the molar ratio of Cu2+ to the netropsin analog is equal to 0.5. Evidently, the Cu(2+)-ligated and unligated oligopeptide species interacts with each other to form a heterodimer bound to DNA at the cleavage site. To test the validity of this model we have studied the binding of unligated netropsin analog and netropsin analog complexed with Cu2+ ion to a self-complementary oligonucleotide 5'-GCGTTTTGCAAAACGC-3'. It is found that binding of Cu(2+)-ligated netropsin analog to the DNA oligomer preincubated with unligated form of the oligopeptide is a cooperative process for which interactions between the two bound ligands are responsible. The cooperativity parameter is estimated to be on the order of factor 6. Finally, a model is proposed in which a heterodimer stabilized by interligand beta-sheet binds in the minor DNA groove.     

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

We present titrations of the human δβ-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. © 1998 John Wiley & Sons, Ltd.     

Quantitative footprinting analysis of the netropsin-DNA interaction

The results of a series of quantitative footprinting experiments of the netropsin-DNA interaction as studied using two different DNA cleaving probes, the enzyme DNase I and a cationic manganese porphyrin complex, are described. Plots of the relative change in oligonucleotide concentration as a function of drug concentration, covering approximately 110 base pairs of a DNA restriction fragment, revealed netropsin induced changes in the cleavage rates of both probes. These appeared as inhibitions for the binding sites, enhancements where no binding took place, and enhancement/inhibitions for the weak binding sites. Determination of the concentration of drug necessary to reduce the amount of a particular oligomer to half of its initial value allowed a ranking of the affinities of the various binding sites on the fragment. In addition to uncovering the location of a number of overlapping netropsin binding sites, the data allowed additional insight on the manner in which both probes alter their DNA cleavage rates in the drug-footprinting experiment.     

Quantitative Footprinting Analysis of the Netropsin-DNA Interaction

Abstract

The results of a series of quantitative footprinting experiments of the netropsin-DNA interaction as studied using two different DNA cleaving probes, the enzyme DNase I and a cationic manganese porphyrin complex, are described. Plots of the relative change in oligonucleotide concentration as a function of drug concentration, covering ～ 110 base pairs of a DNA restriction fragment, revealed netropsin induced changes in the cleavage rates of both probes. These appeared as inhibitions for the binding sites, enhancements where no binding took place, and enhancement/inhibitions for the weak binding sites. Determination of the concentration of drug necessary to reduce the amount of a particular oligomer to half of its initial value allowed a ranking of the affinities of the various binding sites on the fragment. In addition to uncovering the location of a number of overlapping netropsin binding sites, the data allowed additional insight on the manner in which both probes alter their DNA cleavage rates in the drug-footprinting experiment.     

Interaction of nucleic acids with a non-intercalative anti-leukemic compound containing bisquarternary heterocycles

The binding of an antitumour drug with bisquarternary ammonium heterocyclic structure, NSC-101327, to nucleic acids has been examined by using ultraviolet absorption and CD measurements. Like the minor groove-binding oligopeptides, netropsin and distamycin A, the optically inactive chromophoric system of NSC-101327 shows induced Cotton effects in the CD spectra of complexes with various DNAs, RNA and single-stranded polynucleotides. This property directly reflects interaction of NSC-101327 with different types of nucleic acids at moderate ionic strength, which contrasts with previous findings of a higher selective binding of netropsin to B-DNA. However, an efficient interactin of NSC-101327 with dA·dT basepair sequences is demonstrated by a large melting temperature increase of dA·dT-rich DNAs. NSC-101327 also reacts with dG·dC base pairs of B-DNA and forms a complex with Z-DNA of poly(br⁸dG-dC)·poly(br⁸DG-dC). The affinity of NSC-101327 to poly(dG-dC)·poly(dG-dC) is, however, lower, and the CD spectral binding effect depends on the ionic strength. The CD results of the complex with poly(dA-dT)·poly(dA-dT) suggests at least two binding modes, in accordance with previous conclusions. This is indicated by a clear-cut initial increase of the CD signal and a subsequent large decrease to negative CD signals. Competition experiments with netropsin suggest that binding of NSC-101327 occurs preferentially in the minor groove without intercalation. NSC-101327 also tends to interact with lower binding affinity to dG-dC pairs in B-DNA, with rA·rU pairs of RNA and with single-stranded polynucleotides. Thus our results suggest that NSC-101327 represents a DNA groove-binding ligand of lower basepair specificity and lower conformational selectivity compared to the B-specific netropsin probe.     

Sequence-specific cleavage of double-stranded DNA caused by X-ray ionization of the platinum atom in the Pt-bis-netropsin--DNA complex.

An analog of the antibiotic netropsin containing two netropsin-like fragments linked covalently via a platinum atom has been synthesized. DNase I and hydroxyl radical footprinting studies have shown that this compound binds at selective sites on a DNA restriction fragment with a known nucleotide sequence. After X-ray irradiation of Pt-bis-netropsin--DNA complexes a platinum-mediated cleavage of DNA is observed at specific DNA sites. This enables one to determine the location of the synthetic ligand on the DNA with a precision of about one nucleotide. The cleavage activity seems to be related to the emission of Auger electrons from the platinum atom that cause rupture of the deoxyribose residues on the two DNA strands near the position of the platinum atom in the complex.     

DNA-sequence specific recognition by a thiazole analogue of netropsin: a comparative footprinting study.

Four different footprinting techniques have been used to probe the DNA sequence selectivity of Thia-Net, a bis-cationic analogue of the minor groove binder netropsin in which the N-methylpyrrole moieties are replaced by thiazole groups. In Thia-Net the ring nitrogen atoms are directed into the minor groove where they could accept hydrogen bonds from the exocyclic 2-amino group of guanine. Three nucleases (DNAase I, DNAase II, and micrococcal nuclease) were employed to detect binding sites on the 160bp tyr T fragment obtained from plasmid pKM delta-98, and further experiments were performed with 117mer and 253mer fragments cut out of the plasmid pBS. MPE.Fe(II) was used to footprint binding sites on an EcoRI/HindIII fragment from pBR322. Thia-Net binds to sites in the minor groove containing 4 or 5 base pairs which are predominantly composed of alternating A and T residues, but with significant acceptance of intrusive GC base pairs. Unlike the parent antibiotic netropsin, Thia-Net discriminates against homooligomeric runs of A and T. The evident preference of Thia-Net for AT-rich sites, despite its containing thiazole nitrogens capable of accepting GC sites by hydrogen bonding, supports the view that the biscationic nature of the ligand imposes a bias due to the electrostatic potential differences in the receptor which favour the ligand reading alternating AT sequences.     

DNA sequence preferences of several AT-selective minor groove binding ligands.

We have examined the interaction of distamycin, netropsin, Hoechst 33258 and berenil, which are AT-selective minor groove-binding ligands, with synthetic DNA fragments containing different arrangements of AT base pairs by DNase I footprinting. For fragments which contain multiple blocks of (A/T)4 quantitative DNase I footprinting reveals that AATT and AAAA are much better binding sites than TTAA and TATA. Hoechst 33258 shows that greatest discrimination between these sites with a 50-fold difference in affinity between AATT and TATA. Alone amongst these ligands, Hoechst 33258 binds to AATT better than AAAA. These differences in binding to the various AT-tracts are interpreted in terms of variations in DNA minor groove width and suggest that TpA steps within an AT-tract decrease the affinity of these ligands. The behaviour of each site also depends on the flanking sequences; adjacent pyrimidine-purine steps cause a decrease in affinity. The precise ranking order for the various binding sites is not the same for each ligand.