A thermodynamic and structural analysis of DNA minor-groove complex formation.

As part of an effort to develop a better understanding of the structural and thermodynamic principles of DNA minor groove recognition, we have investigated complexes of three diphenylfuran dications with the d(CGCGAATTCGCG)(2) duplex. The parent compound, furamidine (DB75), has two amidine substituents while DB244 has cyclopentyl amidine substituents and DB226 has 3-pentyl amidines. The structure for the DB244-DNA complex is reported here and is compared to the structure of the DB75 complex. Crystals were not obtained with DB226 but information from the DB75 and DB244 structures as well as previous NMR results on DB226 indicate that all three compounds bind in the minor groove at the AATT site of the duplex. DB244 and DB75 penetrate to the floor of the groove and form hydrogen bonds with T8 on one strand and T20 on the opposite strand while DB226 forms a complex with fewer interactions. Binding studies by surface plasmon resonance (SPR) yield -delta G degrees values in the order DB244>DB75>DB226 that are relatively constant with temperature. The equilibrium binding constants for DB244 are 10-20 times greater than that for DB226. Isothermal titration calorimetric (ITC) experiments indicate that, in contrast to delta G degrees, delta H degrees varies considerably with temperature to yield large negative delta Cp degrees values. The thermodynamic results, analyzed in terms of structures of the DNA complexes, provide an explanation of why DB244 binds more strongly to DNA than DB75, while DB266 binds more weakly. All three compounds have a major contribution to binding from hydrophobic interactions but the hydrophobic term is most favorable for DB244. DB244 also has strong contributions from molecular interactions in its DNA complex and all of these factors combine to give it the largest-delta G degrees for binding. Although the factors that influence the energetics of minor groove interactions are varied and complex, results from the literature coupled with those on the furan derivatives indicate that there are some common characteristics for minor groove recognition by unfused heterocyclic cations that can be used in molecular design.

Amplification of bleomycin-mediated degradation of DNA.

Three simple and independent tests have been introduced for studying the effect of DNA intercalating compounds on the bleomycin-mediated digestion of DNA in vitro. These methods are based on hyperchromic changes of DNA solution, changes in viscosity of DNA solution, and HPLC quantitative analysis of the four bases released from digested DNA. All three tests give comparable results. However, the viscometric method is technically the simplest and at the same time the most sensitive. The amplification of the bleomycin-mediated degradation of DNA by three unfused heteropolyaromatic intercalator molecules, namely N-[2''-(dimethylamino)ethyl]-4-thien-2'-ylpyrimidin-2-amine (1N), N,N-dimethyl-2-[(4'-thien-2''-ylpyrimidin-2'-yl)thio] ethylamine (1S), and newly synthesized 2,5-bis[2'-[[2''-(dimethylamino)ethyl]thio]pyrimidin-4'yl]thiophene (2) correlates well with the respective DNA binding constants for these compounds and is concentration dependent. The amplification activity of these compounds increases with increasing concentrations. The strongly binding compound 2 is the best amplifier of bleomycin in vitro found so far. Fused heteropolyaromatic systems, like ethidium bromide, are modest amplifiers of bleomycin at low concentrations but strongly inhibit the bleomycin chemistry at high concentrations.

Synthesis and DNA interactions of benzimidazole dications which have activity against opportunistic infections.

Considerable evidence now indicates that DNA is the receptor site for dicationic benzimidazole anti-opportunistic infections agents (Bell, C.A.; Dykstra, C.C.; Naiman N.A.I.; Cory, M.; Fairley, T.A.; Tidwell, R.R. Antimicrob. Agents Chemother. 1993, 37, 2668-2673. Tidwell R.R.; Jones, S.K.; Naiman, N.A.; Berger, I.C.; Brake, W.R.; Dykstra, C.C.; Hall, J.E. Antimicrob. Agents Chemother. 1993, 37, 1713-1716). To obtain additional information on benzimidazole-receptor complexes, the syntheses and DNA interactions of series of symmetric benzimidazole cations, linked by alkyl or alkenyl groups, have been evaluated. Biophysical techniques, thermal denaturation measurement (deltaTm), kinetics, and circular dichroism (CD) have been used in conjunction with NMR and molecular modeling to evaluate the affinities, binding mode, and structure of complexes formed between these compounds and DNA. All the compounds bind strongly to DNA samples with four or more consecutive AT base pairs, and they bind negligibly to GC rich DNA or to RNA. Spectral and kinetics characteristics of the benzimidazole complexes indicate that the compounds bind in the DNA minor groove at AT sequences. NMR and molecular modeling of the complex formed between an ethylene-linked benzimidazole derivative, 5, and the self-complementary oligomer d(GCGAATTCGC) have been used to establish structural details for the minor groove complex. These results have been used as a starting point for molecular mechanics calculations to refine the model of the minor groove-benzimidazole complex and to draw conclusions regarding the molecular basis for the effects of substituent changes on benzimidazole-DNA affinities.

Molecular basis for bleomycin amplification: conformational and stereoelectronic effects in unfused amplifiers.

Sixteen unfused heterobiaromatic and biphenyl compounds substituted with an amino side chain (protonated in water) have been tested for (i) binding with DNA and (ii) their effect on the digestion of the DNA double helix by a bleomycin-iron complex. Only the DNA intercalating molecules amplify the digestion of DNA. One 2,2'-bipyridine derivative tested is an inhibitor of the bleomycin reaction because it removes ferrous ion from the bleomycin complex. Polarity of the intercalating unfused biaromatic system is of primary importance for effective binding of the molecule with native DNA and, at the same time, for its amplification activity. The molecules that have the biaromatic system polarized extensively in the direction of the side cationic chain, so that the intercalating sites constitutes a positive part of the dipole, show strong binding with DNA and good amplification activity. For strong intercalative forces that determine the amplification activity, it is important that both the heteroaromatic subsystems of the molecule have positive ends of their dipoles positioned away from the side chain. This work provides general guidelines for synthesis of new highly effective bleomycin amplifiers.

Quantitative structure-activity relationship analysis of cation-substituted polyaromatic compounds as potentiators (amplifiers) of bleomycin-mediated degradation of DNA.

A set of 21 polyheteroaromatic compounds substituted with flexible cationic groups and of similar molecular size has been analyzed for binding with DNA and for effects of the bleomycin-mediated degradation of the DNA double helix. Increases in apparent rates of the DNA digestion were observed in all cases under the experimental conditions of noncompetitive binding of these compounds and bleomycin to DNA. Surprisingly, the quantitative structure-activity relationship analysis revealed two distinct correlations despite close structural similarities for the set of bleomycin amplifiers. These unusual results are explained in terms of the formation of two stereochemically different ternary complexes of activated bleomycin-DNA-amplifier. The relevance of this finding for the design of new bleomycin amplifiers is discussed.

2,4-Diphenyl furan diamidines as novel anti-Pneumocystis carinii pneumonia agents.

Dicationic 2,4-bis(4-amidinophenyl)furans 5-10 and 2, 4-bis(4-amidinophenyl)-3,5-dimethylfurans 14 and 15 have been synthesized. Thermal melting studies revealed high binding affinity of the compounds to poly(dA-dT) and to the duplex oligomer d(CGCGAATTCGCG)2. All of the new compounds were effective against Pneumocystis carinii pneumonia in the immunosuppressed rat model with up to 200-fold increase in activity compared to the control compound pentamidine. No toxicity was noted for 5, 7-10 at the dose of 10 micromol/kg/d; however, the isopropyl analogue 7 showed toxicity comparable to pentamidine at the dosage of 20 micromol/kg/d. Dimethylation of the parent compound on the furan ring resulted in reduced activity and increased toxicity.

Synthesis and structure-DNA binding relationship analysis of DNA triple-helix specific intercalators.

4-[N-(Aminoalkyl)amino]-2-arylquinolines with conformational freedom around positions 2 and 4 of the quinoline stabilize strongly poly(dT.dA.dT) (triplex DNA) and bind weakly to poly-(dA.dT) (duplex DNA). Basicity of N1 of the quinoline parallels the interaction strength of these compounds with the triple-helical DNA structure suggesting that N1 of the quinoline is protonated in the complex with the DNA triplex. The experimental results support the interaction model suggested previously.

Diguanidino and "reversed" diamidino 2,5-diarylfurans as antimicrobial agents.

Dicationic 2,5-bis(4-guanidinophenyl)furans 5a-5f, 2,5-bis[4-(arylimino)aminophenyl]furans 6a-6b and 6e-6k, and 2,5-bis[4-(alkylimino)aminophenyl]furans 6c-6d have been synthesized starting from 2,5-bis[tri-n-butylstannyl]furan. Thermal melting studies with poly dA*dT and the duplex oligomer d(CGCGAATTCGCG)2 demonstrated high DNA binding affinities for a number of the compounds. The binding affinities are highly dependent on structure and are significantly affected by substituents both on the phenyl rings of the 2,5-diphenylfuran nucleus and on the cationic centers. Of the 17 novel dicationic compounds synthesized, six (6a, 6b, 5b, 6f, 6h, 6i) exhibited MICs of 2 microg/mL or less versus Mycobacterium tuberculosis. Of the compounds screened against Candida albicans, three gave MICs of 2 microg/mL or less (5b, 6h, 6i), and two (5b, 6i) were fungicidal, unlike a standard antifungal drug fluconazole, which was fungistatic. In addition, one of the tested compounds (6i) exhibited a MIC of <1 microg/mL against Aspergillus fumigatus, while also being a fungicidal against this organism. Finally, when evaluated against an expanded fungal panel, compound 6h showed good activity against Cryptococcus neoformans and Rhizopus arrhizus.

The interaction with DNA of unfused aromatic systems containing terminal piperazino substituents. Intercalation and groove-binding.

A number of unfused tricyclic aromatic intercalators have shown excellent activity as amplifiers of the anticancer activity of the bleomycins and the 4',6-diphenylpyrimidines, 2a and 2b, with terminal basic functions (4-methylpiperazino groups) have been synthesized to test the structural requirements for amplifier-DNA interactions. The terminal piperazine rings are bulky, have limited flexibility, and are twisted out of the phenyl ring plane in both 2a and 2b. With 2a the pyrimidine is unsubstituted at position 5 and the conformation predicted by molecular mechanics calculations has a 25-30 degrees twist between the phenyl and pyrimidine ring planes. With 2b the 5-position is substituted with a methyl group and this causes a larger twist angle (50-60 degrees) between the phenyl and pyrimidine planes. These conformational variations lead to markedly different DNA interactions for 2a and 2b. Absorption, CD and NMR spectral, viscometric, flow dichroism and kinetics results indicate that 2a binds strongly to DNA by intercalation while 2b binds more weakly in a groove complex. The general structure and conformation of 2a, a slightly twisted, unfused-aromatic system with terminal piperazino groups is more similar to groove-binding agents such as Hoechst 33258 than to intercalators. The fact that 2a forms a strong intercalation complex with DNA is unusual but in agreement with studies on other amplifiers of anticancer drug action. Molecular modeling studies provide a second unusual feature of the 2a intercalation complex. While most well-characterized intercalators bind with their bulky and/or cationic substitutents in the DNA minor groove, the cationic piperazino groups of 2a are too large to bind in the minor groove in an intercalation complex but can form strong interactions with DNA in the major groove. The tricyclic aromatic ring system of 2a stacks well with adjacent base-pairs in the major-groove complex and the piperazino groups have good electrostatic and van der Waals interactions with the DNA backbone.

Different binding mode in AT and GC sequences for unfused-aromatic dications.

We have previously synthesized a 2,5-diphenylfuranamidine dication (4) and presented evidence that this compound binds to AT sequences in DNA by a minor-groove interaction mode but binds to GC sequences by intercalation (1,2). To probe these sequence-dependent binding modes in more detail, and particularly to obtain additional evidence for the binding mode in GC rich sequences, we have synthesized and studied the DNA complexes of 1-3 which have the furan ring of 4 replaced by 2,6-substituted pyridine (1), pyrimidine (2), or triazine (3) ring systems. The three compounds with a six-membered central ring system bind to AT DNA sequences more weakly than the furan compound, but retain the minor-groove binding mode. The pyridine and pyrimidine derivatives bind to GC sequences of DNA more strongly than the furan, but the triazine derivative binds more weakly. The aromatic proton signals of 1-3, as previously observed with 4 shift upfield by approximately 0.5 ppm or greater on complex formation with polyd(G-C)2. This and other spectroscopic as well as viscosity and kinetics results indicate that 1-4 bind to GC sites in DNA by intercalation. A nonclassical intercalation model, with the twisted-unfused, aromatic ring system intercalated into an intercalation site of matching structure can explain all of our and the literature results for the GC binding mode of these unfused, aromatic compounds.

Synthesis and anti-Pneumocystis carinii pneumonia activity of novel dicationic dibenzothiophenes and orally active prodrugs.

Dicationic carbazoles have been found to be highly active against a rat model of Pneumocystis carinii pneumonia (PCP). Unfortunately, amidoxime derivatives, designed as prodrugs, were inactive against PCP even though the corresponding amidines were highly active. In the present work, a series of 2,8- and 3,7-bis cationic dibenzothiophenes was synthesized and assayed for anti-PCP activity. Three of the compounds proved to be more potent and less toxic than a standard anti-PCP drug (pentamidine) when given intravenously. Unlike the carbazoles, a dibenzothiophene amidoxime prodrug given orally reduced the parasite load by more than 99%. While no quantitative correlation was seen between anti-PCP activity and DNA binding, a strong level of DNA binding was found to be necessary for antimicrobial activity.

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)

A new type of DNA minor-groove complex: carbazole dication-DNA interactions.

The effect of opportunistic infections (OI) on immune-compromised populations has been known for decades, but the recent AIDS epidemic has sparked renewed interest in the development of new anti-OI agents. The mechanism of action of a series of cationic unfused-aromatic anti-OI drugs is believed to involve binding of the drug to AT sequences in the minor groove of DNA. Some new anti-OI drug candidates have been synthesized with fused aromatic ring systems (e.g. carbazoles) that do not resemble the classical paradigm for minor-groove interactions at AT sequences in DNA. To characterize the DNA interactions of these compounds, we have used UV-vis absorbance, fluorescence, kinetic measurements, and circular dichroism in conjunction with NMR spectroscopy to evaluate the structure of the complexes formed between the carbazoles and DNA. Application of these methods to carbazoles substituted at either the 3,6 or 2,7 positions with cationic imidazoline groups gave conclusive, but very surprising, evidence that both compounds bind strongly in the minor groove at AT DNA sequences. NMR and molecular modeling of the complexes formed between the 3,6- and 2,7-carbazoles and the self-complementary oligomer d(GCGAATTCGC) have been used to establish structural details for the minor-groove complex. These results have been used as constraints for molecular modeling calculations to construct models of the minor-groove-carbazole complexes and to draw conclusions regarding the molecular basis for the effects of substituent position on carbazole-DNA affinities. The surprising result is that the 2,7 carbazole binds in AT sequences with hydrogen bonds involving one imidazoline group and the carbazole NH. The 3,6-carbazole compound binds in a more "classical" model that uses both imidazoline groups for H-bonding while the carbazole NH points out of the minor groove. The carbazoles thus form a new type of DNA minor groove complex and their excellent biological activities indicate that a variety of fused-ring minor-groove binding agents should be investigated.

Substituent position dictates the intercalative DNA-binding mode for anthracene-9,10-dione antitumor drugs.

Molecular modeling studies [Islam, S.A., Neidle, S., Gandecha, B.M., Partridge, M., Patterson, L.H., & Brown, J.R. (1985) J. Med. Chem. 28, 857-864] have suggested that anthracene-9,10-dione (anthraquinone) derivatives substituted at the 1,4 and 1,8 positions with-NH(CH2)2NH(CH2CH3)2+ side chains intercalate with DNA with both substituents in the same groove (classical intercalation) while a similarly substituted 1,5 derivative intercalates in a threading mode with one side chain in each groove. Modeling studies also suggested that anthracene-9,10-dione (anthraquinone) derivatives substituted at the 2,6 positions with -NHCO(CH2)R (where R is a cationic group) should bind to DNA by the threading mode, and several such derivatives have been synthesized [Agbandjie, M., Jenkins, T.C., McKenna, R., Reszka, A., & Neidle, S. (1992) J. Med. Chem. 35, 1418-1429]. We have conducted stopped-flow kinetics association and dissociation experiments on the interaction of these anthraquinones with calf thymus DNA and with DNA polymers with alternating AT and GC base pairs to experimentally determine the binding mode and how the threading mode affects intercalation rates relative to similarly substituted classical intercalators. The binding modes, determined by analysis of relative rates, energies of activation, and effects of salt concentration on association and dissociation rate constants, agree completely with the modes predicted by molecular modeling methods. Association and dissociation rate constants for the threading mode are approximately a factor of 10 lower than constants for the classical intercalation mode, and the two modes, thus, have similar binding constants. Variations in rate constants for changes in cationic substituents at the 2 and 6 positions of the anthraquinone ring were surprisingly small.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

The interaction of intercalators and groove-binding agents with DNA triple-helical structures: the influence of ligand structure, DNA backbone modifications and sequence.

The effects of ligand structure and properties, DNA backbone modifications and DNA sequence on the interaction of a variety of well-known groove-binding agents and intercalators with DNA duplexes and triplexes have been evaluated by thermal melting experiments and molecular modeling. Both methylphosphonate and phosphorothioate substitutions generally destabilize DNA duplexes and triplexes. Modified duplexes can be strongly stabilized by both groove-binding agents and intercalators whereas triplexes are primarily stabilized by intercalators. Of the compounds tested, the intercalators coralyne and quinacrine provide the largest stabilization of the triplex dT19.dA19.dT19. Molecular modeling studies suggest that the large intercalating ring system of coralyne stacks well with the triplex bases whereas the alkylamino side chain of quinacrine fits snugly into the remaining space of the major groove of dT19.dA19.dT19 triplex and forms extensive van der Waals contacts with the thymine methyl groups that line the groove. Converting some of the T.A.T base triples to C+.G.C (e.g. dT19.dA19.dT19 to d(T4C+)3T4.d(A4G)3A4.(T4C)3T4) causes very significant decreases in observed Tm increases for compounds such as quinacrine and coralyne. Although removal of thymine methyl groups and addition of positive charge on substitution of C+.G.C for T.A.T should reduce binding of cationic intercalators, the large difference observed between the pure AT and the mixed sequence triplexes suggest that they may also have differences in structure and properties.

Effect of base-pair sequence on the conformations and thermally induced transitions in oligodeoxyribonucleotides containing only AT base pairs.

Tm curves, CD spectra, and kinetics results of the self-complementary DNA dodecamers d(A6T6), d(A3T3A3T3), d(A2T2A2T2A2T2), d(ATATATATATAT), and d(T6A6) demonstrate that the thermal transitions of these oligomers at low salt concentration involve a hairpin intermediate. At high salt concentrations (greater than 0.1 M Na+) only a duplex to denatured-strand transition appears to occur. The temperature and salt-concentration regions of the transitions are very sequence dependent. Alternating-type AT sequences have a lower duplex stability and a greater tendency to form hairpins than sequences containing more nonalternating AT base pairs. Of the two nonalternating sequences, d(T6A6) is significantly less stable than d(A6T6). Both oligomers have CD curves that are very similar to the unusual CD spectrum of poly(dA).poly(dT). The Raman spectra of these two oligomers are also quite similar, but at low temperature, small intensity differences in two backbone modes and three nucleoside vibrations are obtained. The hairpin to duplex transition for the AT dodecamers was examined by salt-jump kinetics measurements. The transition is faster than transitions for palindromic-sequence oligomers containing terminal GC base pairs. Stopped-flow kinetics studies indicate that the transition is second order and has a relatively low activation energy. The reaction rate increases with increasing ionic strength. These results are consistent with a three-step mechanism for the hairpin to duplex reaction: (i) fraying of the hairpin oligomers' terminal base pairs, (ii) a rate-determining bimolecular step involving formation of a cruciform-type intermediate from two hairpin oligomers with open terminal base pairs, and (iii) base-pair migration and formation in the intermediate to give the duplex.

Effects of compound structure on carbazole dication-DNA complexes: tests of the minor-groove complex models.

Carbazole dications have shown excellent activity against opportunistic infections, but they are quite different in structure from previously studied unfused aromatic cations that function by targeting the DNA minor groove. In a previous report [Tanious, F. A., Ding, D., Patrick, D. A., Tidwell, R. R., and Wilson, W. D. (1997) Biochemistry 36, 15315-15325] we showed that, despite their fused ring structure, the carbazoles also bind in A/T sequences of the DNA minor groove and we proposed models for the carbazole-DNA complexes with the carbazole nitrogen facing out of the groove for 3,6 substituted compounds but into the groove in 2,7 carbazoles. To test and refine the models, carbazole-N-methyl substituted derivatives have been synthesized in both the 3,6 and 2,7 series as well as a new 2,6 substituted NH derivative that is intermediate in structure. Footprinting results indicate a broad AT specificity of carbazole binding and a pattern in agreement with a minor groove complex. Surface plasmon resonance biosensor analysis of carbazole binding to an oligomer with an AATT central sequence indicated that the 2,7 NH compound has the largest binding constant. Both the 3,6 NH and NMe compounds bind with similar equilibrium constants that are less than for the 2,7 NH compound. The 2,7 NMe compound has the lowest binding constant of all the carbazoles. Spectroscopic results are also similar for the two 3,6 derivatives but are quite different for the 2,7 NH and NMe carbazole dications. Structural analysis of carbazole complexes with an AATT sequence by 2D NMR methods also supported a minor groove complex of the carbazoles in orientations in agreement with the previously proposed models. From these results, it is clear that the fused ring carbazoles can bind strongly in the DNA minor groove with a broad A/T specificity and that the 2,7 and 3,6 substituted carbazoles bind to the minor groove in opposite orientations.

DNA triple-helix specific intercalators as antigene enhancers: unfused aromatic cations.

Triple-helical structures involving the interaction of an oligonucleotide third strand with a duplex nucleic acid sequence have recently gained attention as a therapeutic strategy in the "antigene" approach [cf. Helene, C. (1991) Eur. J. Cancer 27, 1466-1471]. This method utilizes the triple helix formed from the cellular duplex and an added third strand to directly regulate the activity of a selected gene. The limited stability of nucleic acid triple-helical interactions, particularly if the third strand has backbone modifications such as methylphosphonate or phosphorothioate substitutions, is a limiting condition for the use of this approach. We have designed and synthesized compounds, on the basis of the following three criteria, that we feel should provide selective interactions and significant stabilization of triplexes: appropriate aromatic surface area for stacking with triplex bases in an intercalation complex, positive charge, and limited torsional freedom in the aromatic system to match the propeller twist of the triple-base interactions in the triplex. A series of quinoline derivatives with an alkylamine side chain at the 4-position and with different aryl substituents at the 2-position has been synthesized as our first compounds. A 2-naphthyl derivative provides significant and selective stabilization of the triplex. In a 0.2 M NaCl buffer, the naphthyl derivative increased the Tm for the triplex (triplex to duplex and third strand transition) by approximately 30 degrees C more than the Tm increase for the duplex (duplex to single strands transition). Spectral changes and energy-transfer results indicate that the naphthyl compound and related derivatives bind to the triplex by intercalation.(ABSTRACT TRUNCATED AT 250 WORDS)