Methylene blue binding to DNA with alternating AT base sequence: minor groove binding is favored over intercalation

The results presented in this paper on methylene blue (MB) binding to DNA with AT alternating base sequence complement the data obtained in two former modeling studies of MB binding to GC alternating DNA. In the light of the large amount of experimental data for both systems, this theoretical study is focused on a detailed energetic analysis and comparison in order to understand their different behavior. Since experimental high-resolution structures of the complexes are not available, the analysis is based on energy minimized structural models of the complexes in different binding modes. For both sequences, four different intercalation structures and two models for MB binding in the minor and major groove have been proposed. Solvent electrostatic effects were included in the energetic analysis by using electrostatic continuum theory, and the dependence of MB binding on salt concentration was investigated by solving the non-linear Poisson-Boltzmann equation. We find that the relative stability of the different complexes is similar for the two sequences, in agreement with the interpretation of spectroscopic data. Subtle differences, however, are seen in energy decompositions and can be attributed to the change from symmetric 5'-YpR-3' intercalation to minor groove binding with increasing salt concentration, which is experimentally observed for the AT sequence at lower salt concentration than for the GC sequence. According to our results, this difference is due to the significantly lower non-electrostatic energy for the minor groove complex with AT alternating DNA, whereas the slightly lower binding energy to this sequence is caused by a higher deformation energy of DNA. The energetic data are in agreement with the conclusions derived from different spectroscopic studies and can also be structurally interpreted on the basis of the modeled complexes. The simple static modeling technique and the neglect of entropy terms and of non-electrostatic solute-solvent interactions, which are assumed to be nearly constant for the compared complexes of MB with DNA, seem to be justified by the results.     

Methylene blue binding to DNA with alternating GC base sequence: continuum treatment of salt effects

Methylene blue (MB), an efficient singlet oxygen generating photoactive dye, binds to DNA and allows photosensitized reactions to be used for sequence-specific cleavage of the DNA backbone. Intercalation and groove binding are possible binding modes of the dye, depending on base sequences and environmental conditions. In a recent modeling study of methylene blue binding to a double stranded DNA decamer with an alternating GC sequence, six structural models for intercalation structures and for minor and major groove binding have been obtained. By estimating the binding energies (including electrostatic reaction field contributions of a salt-free aqueous solvent), symmetric intercalation at the 5'-CpG-3' and 5'-GpC-3' steps was found as the predominant binding mode, followed by a slightly weaker binding of the dye in the minor groove. In this study, the stability of the modeled structures has been analysed as a function of salt concentration. The results of finite difference numerical solutions of the non-linear Poisson-Boltzmann equation show that the stabilizing effect of salt is larger for free DNA than for the modeled MB-DNA complexes. Accordingly, the estimated binding energies decrease with increasing ionic strength. A slightly higher stabilization of the groove binding complexes results in comparable binding energies for symmetric intercalation and minor groove binding at high salt concentration. Both results are in qualitative agreement with experimental data.     

Binding free energy of selected anticancer compounds to DNA--theoretical calculations

Many studies have elucidated structures and thermodynamics of complexes formed by different ligands with DNA. However, in most cases structural and free energy binding studies were not correlated with each other because of the problem of identifying which experimental free energy of binding corresponds to which experimental DNA-ligand structure. In the present work, Poisson-Boltzmann and solvent-accessible surface area methods were used to predict unknown modes of interaction between DNA and three different ligands: mitoxantrone and two pyrimidoacridine derivatives. In parallel, experimental measurements of binding free energy for the studied complexes were performed to compare experimental and calculated values. Our studies showed that the calculated values of free energy are only close to experimental data for some models of interaction between ligands and DNA. Based on this correlation, the most likely models of DNA-ligand complexes were postulated: (i) mitoxantrone and one derivative of pyrimidoacridine, both with two charged side chains, intercalate from the minor groove of DNA and bind with both chains in this groove; (ii) pyrimidoacridine, with only one side chain, very likely does not intercalate into DNA at all. Additionally, the non-electrostatic and electrostatic parts of the calculated binding free energy for the DNA-ligands studied are discussed.     

Use of Electric Linear Dichroism and Competition Experiments with Intercalating Drugs to Investigate the Mode of Binding of Hoechst 33258, Berenil and DAPI to GC Sequences

Abstract

The drugs Hoechst 33258, berenil and DAPI bind preferentially to the minor groove of AT sequences in DNA Despite a strong selectivity for AT sites, they can interact with GC sequences by a mechanism which remains so far controversial. The 2-amino group of guanosine represents a steric hindrance to the entry of the drugs in the minor groove of GC sequences. Intercalation and major groove binding to GC sites of GC-rich DNA and polynucleotides have been proposed for these drugs. To investigate further the mode of binding of Hoechst 33258, berenil and DAPI to GC sequences, we studied by electric linear dichroism the mutual interference in the DNA binding reaction between these compounds and a classical intercalator, proflavine, or a DNA-threading intercalating drug, the amsacrine-4-carboxamide derivative SN16713. The results of the competition experiments show that the two acridine intercalators markedly affect the binding of Hoechst 33258, berenil and DAPI to GC polynucleotides but not to DNA containing AT/GC mixed sequences such as calf thymus DNA Proflavine and SN16713 exert dissimilar effects on the binding of Hoechst 33258, berenil and DAPI to GC sites. The structural changes in DNA induced upon intercalation of the acridine drugs into GC sites are not identically perceived by the test compounds. The electric linear dichroism data support the hypothesis that Hoechst 33258, berenil and DAPI interact with GC sites via a non-classical intercalation process.     

Theoretical Exploration of Netropsin Binding to tRNAPhe

Abstract

Theoretical exploration of the possible interaction of netropsin with tRNA^Phe indicates that binding should occur preferentially with the major groove of the TψC stem of the macromolecule, specifically with the bases G51, U52, G53 and phosphates 52, 53, 61 and 62. This agrees with the recent crystallographic result of Rubin and Sundaralingam. It is demonstrated that the difference with respect to netropsin binding with B-DNA, where it occurs specifically in the minor groove of AT sequences, is due to the differences in the distribution of the electrostatic molecular potential generated by these different types of DNA: this potential is sequence dependent in B-DNA (located in the minor groove of AT sequences and the major groove of GC sequences), while it is sequence independent and always located in the major groove in A-RNA. The result demonstrates the major role of electrostatics in determining the location of the binding site.     

Cationic porphyrins as probes of DNA structure.

The DNA binding specificity of a group of cationic manganese porphyrin complexes has been examined using DNase I footprinting methodology and by observing the sites of porphyrin-induced DNA strand scission in the presence of potassium superoxide. The compounds, which possess systematic changes in total charge, its distribution on the periphery on the macrocycle and ligand shape, bind in the minor groove of AT rich regions of DNA. While changes in total charge and charge arrangement do not significantly influence specificity, a shape change which blocks close ligand contact with the minor groove relaxes the original AT specificity causing the compound to cleave at both AT and GC sites. The observed changes in binding sequence specificity were interpreted in terms of electrostatic and steric factors associated with both the compounds and DNA.     

Energetics and stereochemistry of DNA complexation with the antitumor AT specific intercalators tilorone and m-AMSA.

Computations by the SIBFA method on the intercalative interaction energies of tilorone and m-AMSA with B-DNA representative oligonucleotides account for the specificity of these antitumor drugs for AT sites and minor groove intercalation. In tilorone this specificity is due to the strong preference of the side chains for the minor groove, which overcomes the preference of the chromophore for a GC intercalation site. In m-AMSA the specificity is due to the combined preference of both the chromophore and the anilino side chain for AT intercalation site and minor groove, respectively. o-AMSA is shown to manifest a similar (although significantly less pronounced specificity) as m-AMSA but a higher affinity for DNA. A comparison of the energetics and stereochemistry of intercalative binding to DNA of m-AMSA (AT minor groove specific) and 9-aminoacridine-4-carboxamide (GC major groove specific), which possess the same chromophore and differ only by the nature and position of the side chains, shows the possibility of important variations in the intercalative behaviour of chromophoric drugs as a function of the substituent groups attached to them.     

Theoretical Studies Using an Ab Initio and Molecular Modelling Combination Method on the Binding of Sequence Recognition Altered Bis-Benzimidazoles to the Minor Groove of DNA

Abstract

Ab initio calculations (Hartree-Fock) using the 3–21G and the STO-3G Gaussian basis sets were performed on synthetic analogues of the minor groove binding bis-benzimidazole Hoechst 33258 designed to exhibit altered sequence recognition. Geometry optimized conformations, energies and distribution of electrostatic charges within the molecule were derived. The binding of the optimized conformations of the drug to both alternating and non-alternating (AT)_n and (GC)_n sequences were studied.     

Drug-DNA sequence-dependent interactions analysed by electric linear dichroism.

The interactions between 20 drugs and a variety of synthetic DNA polymers and natural DNAs were studied by electric linear dichroism (ELD). All compounds tested, including several clinically used antitumour agents, are thought to exert their biological activities mainly by virtue of their abilities to bind to DNA. The selected drugs include intercalating agents with fused and unfused aromatic structures and several groove binders. To examine the role of base composition and base sequence in the binding of these drugs to DNA, ELD experiments were carried out with natural DNAs of widely differing base composition as well as with polynucleotides containing defined alternating and non-alternating repeating sequences, poly(dA).poly(dT), poly(dA-dT).poly(dA-dT),poly(dG).poly(dC) and poly(dG-dC).poly(dG-dC). Among intercalating agents, actinomycin D was found to be by far the most GC-selective. GC selectivity was also observed with an amsacrine-4-carboxamide derivative and to a lesser extent with methylene blue. In contrast, the binding of amsacrine and 9-aminoacridine was practically unaffected by varying the GC content of the DNAs. Ethidium bromide, proflavine, mitoxantrone, daunomycin and an ellipticine derivative were found to bind best to alternating purine-pyrimidine sequences regardless of their nature. ELD measurements provided evidence for non-specific intercalation of amiloride. A significant AT selectivity was observed with hycanthone and lucanthone. The triphenyl methane dye methyl green was found to exhibit positive and negative dichroism signals at AT and GC sites, respectively, showing that the mode of binding of a drug can change markedly with the DNA base composition. Among minor groove binders, the N-methylpyrrole carboxamide-containing antibiotics netropsin and distamycin bound to DNA with very pronounced AT specificity, as expected. More interestingly the dye Hoechst 33258, berenil and a thiazole-containing lexitropsin elicited negative reduced dichroism in the presence of GC-rich DNA which is totally inconsistent with a groove binding process. We postulate that these three drugs share with the trypanocide 4',6-diamidino-2-phenylindole (DAPI) the property of intercalating at GC-rich sites and binding to the minor groove of DNA at other sites. Replacement of guanines by inosines (i.e., removal of the protruding exocyclic C-2 amino group of guanine) restored minor groove binding of DAPI, Hoechst 33258 and berenil. Thus there are several cases where the mode of binding to DNA is directly dependent on the base composition of the polymer. Consequently the ELD technique appears uniquely valuable as a means of investigating the possibility of sequence-dependent recognition of DNA by drugs.     

Characterization of ciprofloxacin binding to the linear single- and double-stranded DNA

The binding of ciprofloxacin to natural and synthetic polymeric DNAs was investigated at different solvent conditions using a combination of spectroscopic and hydrodynamic techniques. In 10 mM cacodylate buffer (pH 7.0) containing 108.6 mM Na(+), no sequence preferences in the interaction of ciprofloxacin with DNA was detected, while in 2 mM cacodylate buffer (pH 7.0) containing only 1.7 mM Na(+), a significant binding of ciprofloxacin to natural and synthetic linear double-stranded DNA was observed. At low ionic strength of solution, ciprofloxacin binding to DNA duplex containing alternating AT base pairs is accompanied by the largest enhancement in thermal stability (e.g. DeltaT(m) approximately 10 degrees C for poly[d(AT)].poly[d(AT)]), and the most pronounced red shift in the position of the maximum of the fluorescence emission spectrum (lambda(max)). Similar red shift in the position of lambda(max) is also observed for ciprofloxacin binding to dodecameric duplex containing five successive alternating AT base pairs in the row. On the other hand, ciprofloxacin binding to poly[d(GC)].poly[d(GC)], calf thymus DNA and dodecameric duplex containing a mixed sequence is accompanied by the largest fluorescence intensity quenching. Addition of NaCl does not completely displace ciprofloxacin bound to DNA, indicating the binding is not entirely electrostatic in origin. The intrinsic viscosity data suggest some degree of ciprofloxacin intercalation into duplex.     

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.     

Characterization of parazoanthoxanthin A binding to a series of natural and synthetic host DNA duplexes

Parazoanthoxanthin A is a fluorescent yellow nitrogenous pigment of the group of zoanthoxanthins, which show a broad range of biological activity. These include, among others, the ability to bind to DNA. In this study we have used a variety of spectroscopic (intrinsic fluorescence emission and UV-spectroscopy) and hydrodynamic techniques (viscometry) to characterize in more detail the binding of parazoanthoxanthin A to a variety of natural and synthetic DNA duplexes in different buffer conditions. Our results reveal the following five significant features: (i) Parazoanthoxanthin A exhibits two modes of DNA binding: One binding mode exhibits properties of intercalation, while the second binding mode is predominantly electrostatic in origin. (ii) The apparent binding "site size" for parazoanthoxanthin A near physiological salt concentration (100 mM NaCl) is in the range of 7 +/- 1 base pairs for natural genomic DNA duplexes (calf thymus and salmon testes DNA) and alternating synthetic polynucleotides (poly[d(AT)]. poly[d(AT)] and poly[d(GC)]. poly[d(GC)]). A slightly larger apparent binding site size of 9 +/- 1 bp was obtained for parazoanthoxanthin A binding to the synthetic homopolymer poly[d(A)]. poly[d(T)]. (iii) Near physiological salt concentration (100 mM NaCl) parazoanthoxanthin A binds with the same approximate binding affinity of 2-5 x 10(5) M(-1) to all DNA polymers studied. (iv) At low salt concentration, parazoanthoxanthin A preferentially binds alternating poly[d(AT)]. poly[d(AT)] and poly[d(GC)]. poly[d(GC)] host duplexes. (v) Parazoanthoxanthin A inhibits DNA polymerase in vitro.     

Selective Binding of Synthetic Polypeptides to DNA of Varying Composition and Sequence: Effect of Minor Groove Binding Drugs

Abstract

Repetitive basic polypeptides containing lysine or arginine as every third amino acid were shown to cause DNA condensation at physiological salt concentration connected with selective DNA binding with respect to DNA composition and sequence. This selectivity is very similar to that existing in the case of histone H1 and other basic proteins and does not depend on polypeptide chain conformation. The effect of the minor groove binding drugs netropsin and distamycin was tested to elucidate the origin of the binding selectivity. The results suggest that the binding preferences are due to the variations in the conformation in various types of B-DNA that depend on DNA composition and sequence. The most important factor affecting the selectivity is probably the value of the negative electrostatic potential in the minor groove.     

DAPI (4',6-diamidino-2-phenylindole) binds differently to DNA and RNA: minor-groove binding at AT sites and intercalation at AU sites.

The interaction of DAPI and propidium with RNA (polyA.polyU) and corresponding DNA (polydA.polydT) sequences has been compared by spectroscopic, kinetic, viscometric, Tm, and molecular modeling methods. Spectral changes of propidium are similar on binding to the AT and AU sequences but are significantly different for binding of DAPI. Spectral changes for DAPI with the DNA sequence are consistent with the expected groove-binding mode. All spectral changes for complexes of propidium with RNA and DNA and for DAPI with RNA, however, are consistent with an intercalation binding mode. When complexed with RNA, for example, DAPI aromatic protons signals shift significantly upfield, and the DAPI UV-visible spectrum shows significantly larger changes than when complexed with DNA. Slopes of log kd (dissociation rate constants) versus-log [Na+] plots are similar for complexes of propidium with RNA and DNA and for the DAPI-RNA complex and are in the range expected for an intercalation complex. The slope for the DAPI-DNA complex, however, is much larger and is in the range expected for a groove-binding complex. Association kinetics results also support an intercalation binding mode for the DAPI-RNA complex. The viscosity of polyA.polyU solutions increases significantly on addition of both propidium and DAPI, again in agreement with an intercalation binding mode for both molecules with RNA. Molecular modeling studies completely support the experimental findings and indicate that DAPI forms a very favorable intercalation complex with RNA. DAPI also forms a very stable complex in the minor groove of AT sequences of DNA, but the stabilizing interactions are considerably reduced in the wide, shallow minor groove of RNA. Modeling studies,thus,indicate that DAPI interaction energetics are more favorable for minor-groove binding in AT sequences but are more favorable for interaction in RNA.     

Kinetic and equilibrium analysis of a threading intercalation mode: DNA sequence and ion effects

The interaction of a symmetric naphthalene diimide with alkylamino substituents at each imide position was investigated with the alternating sequence polymers, poly[d(A-T)]2 and poly[d(G-C)]2. Spectrophotometric binding studies indicate strong binding of the diimide to both sequences although the GC binding constant is 20-25 times larger than the AT binding constant. Analysis of the effects of salt concentration on the binding equilibria shows that the diimide forms two ion pairs in its complex with both polymers as expected for a simple dication. Stopped-flow kinetics experiments demonstrate that the diimide both associates and dissociates from DNA more slowly than classical intercalators with similar binding constants. Analysis of salt concentration effects on dissociation kinetics rate constants (kd) reveals that slopes in log kd versus log [Na+] plots are only approximately half the value obtained for classical dicationic intercalators that have both charged groups in the same groove. These kinetics results support a threading intercalation model, with one charged diimide substituent in each of the DNA grooves rather than with both side chains in the same groove, for the diimide complex with DNA. In the rate-determining step of the mechanism for dissociation of a threading complex only one ion pair is broken; the free side chain can then slide between base pairs to put both diimide side chains in the same groove, and this is followed by rapid full dissociation of the diimide. This sequential release of ion pairs makes the dissociation slope for dicationic threading intercalators more similar to the slope for classical monocationic intercalating ligands.(ABSTRACT TRUNCATED AT 250 WORDS)     

Theoretical exploration of netropsin binding to tRNA(Phe)

Theoretical exploration of the possible interaction of netropsin with tRNAPhe indicates that binding should occur preferentially with the major groove of the T psi C stem of the macromolecule, specifically with the bases G51, U52, G53 and phosphates 52, 53, 61 and 62. This agrees with the recent crystallographic result of Rubin and Sundaralingam. It is demonstrated that the difference with respect to netropsin binding with B-DNA, where it occurs specifically in the minor groove of AT sequences, is due to the differences in the distribution of the electrostatic molecular potential generated by these different types of DNA: this potential is sequence dependent in B-DNA (located in the minor groove of AT sequences and the major groove of GC sequences), while it is sequence independent and always located in the major groove in A-RNA. The result demonstrates the major role of electrostatics in determining the location of the binding site.     

Drug recognition of DNA. Proposal for GC minor groove specific ligands: vinylexins

In a previous publication in this journal we have proposed an isolexin-like prototype of a GC minor groove specific ligand. The present paper is devoted to refinements of this prototype (increase in specificity and in DNA binding energy). It is shown that only a very limited improvement can be obtained by increasing the proton accepting capabilities of the heteroaromatic ring systems of the prototype, although these rings interact directly with the proton donating NH2 group of guanine. On the other hand a significant increase both in GC specificity and in DNA binding energy is obtained by replacing the NH linkers of the isolexin by C = C double bonds (yielding what we term "vinylexins"). Specificity is still largely conserved and the DNA binding energy is significantly increased in monocationic vinylexins, which should thus be efficient GC minor groove specific ligands. The outstanding importance for the GC specificity of the C = C linkers is evidenced by the disappearance of this specificity when these linkers are replaced by peptide bonds (peptilexins). On the other hand vinylexins with proton donating heteroaromatic rings are, as expected, AT specific. The vinylexin family may thus represent universal minor groove binding agents susceptible to bind to any given base pair sequence of DNA, following the positioning of their proton donor and proton acceptor rings. This study confirms the insufficiency of purely geometrical and/or hydrogen bonding considerations for the correct estimation of GC versus AT specificity of groove binding ligands. These can only be accounted for by taking into consideration the overall electronic properties of the interacting species and explicitly calculating the energies of complex formation including all the relevant contributions.     

Minor groove deformability of DNA: a molecular dynamics free energy simulation study

The conformational deformability of nucleic acids can influence their function and recognition by proteins. A class of DNA binding proteins including the TATA box binding protein binds to the DNA minor groove, resulting in an opening of the minor groove and DNA bending toward the major groove. Explicit solvent molecular dynamics simulations in combination with the umbrella sampling approach have been performed to investigate the molecular mechanism of DNA minor groove deformations and the indirect energetic contribution to protein binding. As a reaction coordinate, the distance between backbone segments on opposite strands was used. The resulting deformed structures showed close agreement with experimental DNA structures in complex with minor groove-binding proteins. The calculated free energy of minor groove deformation was approximately 4-6 kcal mol(-1) in the case of a central TATATA sequence. A smaller equilibrium minor groove width and more restricted minor groove mobility was found for the central AAATTT and also a significantly ( approximately 2 times) larger free energy change for opening the minor groove. The helical parameter analysis of trajectories indicates that an easier partial unstacking of a central TA versus AT basepair step is a likely reason for the larger groove flexibility of the central TATATA case.     

The presence of two modes of binding to calf thymus DNA by metal-free bleomycin: a low frequency Raman study

Double-stranded DNA is targeted by bleomycin in cancer cells and ambiguity exists as to its mode of DNA binding. A conventional Raman study was performed on drug/DNA complexes in which the low frequency spectral region (560-930 cm(-1)) was examined at two temperatures (19 and 30 degrees C). At 30 degrees C, a global Raman hypochromism was observed consistent with partial intercalation of the bithiazole moiety. At 19 degrees C, Raman hypochromism (increased base pair stacking) was detected for bands associated with GC base pairs while Raman hyperchromism (base pair destacking) was evident for bands associated with AT base pairs. These results suggest that intercalation of the bithiazole moiety occurs with greater disruption of the more efficiently stacked AT base pairs at the lower temperature. Evidence for minor groove binding was indicated by an increase in the population of bands corresponding to C3' endo sugar conformations resulting from drug induced local desolvation of the DNA polymer.     

Molecular determinants for DNA minor groove recognition: design of a bis-guanidinium derivative of ethidium that is highly selective for AT-rich DNA sequences

The phenanthridinium dye ethidium bromide is a prototypical DNA intercalating agent. For decades, this anti-trypanosomal agent has been known to intercalate into nucleic acids, with little preference for particular sequences. Only polydA-polydT tracts are relatively refractory to ethidium intercalation. In an effort to tune the sequence selectivity of known DNA binding agents, we report here the synthesis and detailed characterization of the mode of binding to DNA of a novel ethidium derivative possessing two guanidinium groups at positions 3 and 8. This compound, DB950, binds to DNA much more tightly than ethidium and exhibits distinct DNA-dependent absorption and fluorescence properties. The study of the mode of binding to DNA by means of circular and electric linear dichroism revealed that, unlike ethidium, DB950 forms minor groove complexes with AT sequences. Accurate quantification of binding affinities by surface plasmon resonance using A(n)T(n) hairpin oligomer indicated that the interaction of DB950 is over 10-50 times stronger than that of ethidium and comparable to that of the known minor groove binder furamidine. DB950 interacts weakly with GC sites by intercalation. DNase I footprinting experiments performed with different DNA fragments established that DB950 presents a pronounced selectivity for AT-rich sites, identical with that of furamidine. The replacement of the amino groups of ethidium with guanidinium groups has resulted in a marked gain of both affinity and sequence selectivity. DB950 provides protection against DNase I cleavage at AT-containing sites which frequently correspond to regions of enhanced cleavage in the presence of ethidium. Although DB950 maintains a planar phenanthridinium chromophore, the compound no longer intercalates at AT sites. The guanidinium groups of DB950, just like the amidinium group of furamidine (DB75), are the critical determinants for recognition of AT binding sites in DNA. The chemical modulation of the ethidium exocyclic amines is a profitable option to tune the nucleic acid recognition properties of phenylphenanthridinium dyes.