Comparative thermodynamics for monomer and dimer sequence-dependent binding of a heterocyclic dication in the DNA minor groove

Phenylamidine cationic groups linked by a furan ring (furamidine) and related symmetric diamidine compounds bind as monomers in the minor groove of AT sequences of DNA. DB293, an unsymmetric derivative with one of the phenyl rings of furamidine replaced with a benzimidazole, can bind to AT sequences as a monomer but binds more strongly to GC-containing minor-groove DNA sites as a stacked dimer. The dimer-binding mode has high affinity, is highly cooperative and sequence selective. In order to develop a better understanding of the correlation between structural and thermodynamic aspects of DNA molecular recognition, DB293 was used as a model to compare the binding of minor-groove agents with AT and mixed sequence DNA sites. Isothermal titration calorimetry and surface plasmon resonance results clearly show that the binding of DB293 and other related compounds into the minor groove of AT sequences is largely entropy-driven while the binding of DB293 as a dimer into the minor groove of GC-containing sequences is largely enthalpy-driven. At 25 degrees C, for example, the AT binding has DeltaG degrees, DeltaH degrees and TDeltaS degrees values of -9.6, -3.6 and 6.0 kcal/mol while the values for dimer binding to a GC-containing site are -9.0, -10.9 and -1.9 kcal/mol (per mol of bound compound), respectively. These results show that the thermodynamic components for binding of compounds of this type to DNA are very dependent on the structure, solvation and sequence of the DNA binding site.     

Influence of compound structure on affinity, sequence selectivity, and mode of binding to DNA for unfused aromatic dications related to furamidine

In the course of a program aimed at developing sequence-specific gene-regulatory small organic molecules, we have investigated the DNA interactions of a new series of nine diphenylfuran dications related to the antiparasitic drug furamidine (DB75). Two types of structural modifications were tested: the terminal amidine groups of DB75 were shifted from the para to the meta position, and the amidines were replaced with imidazoline or dimethyl-imidazoline groups, to test the importance of both the position and nature of positively charged groups on DNA interactions. The interactions of these compounds with DNA and oligonucleotides were studied by a combination of biochemical and biophysical techniques. Absorption and CD measurements suggested that the drugs bind differently to AT and GC sequences in DNA. The para-para dications, like DB75, bind into the minor groove of poly(dAT)(2) and intercalate between the base pairs of poly(dGC)(2), as revealed by electric linear dichroism experiments. In contrast, the meta-meta compounds exhibit a high tendency to intercalate into DNA whatever the target sequence. The lack of sequence selectivity of the meta-meta compounds containing amidines or dimethyl-imidazoline groups was also evident from DNase I footprinting and surface plasmon resonance (SPR) experiments. Accurate binding measurements using the BIAcore SPR method revealed that all nine compounds bind with similar affinity to an immobilized GC sequence DNA hairpin but exhibit very distinct affinities for the corresponding AT hairpin oligonucleotide. The minor groove-binding para-para compounds have a high specificity for AT sequences. The biophysical data clearly indicate that shifting the cationic substituents from the para to the meta position results in a loss of specificity and change in binding mode. The strong AT selectivity of the para-para compounds was independently confirmed by DNase I footprinting experiments performed with a range of DNA restrictions fragments. In terms of AT selectivity, the compounds rank in the order para-para > para-meta > meta-meta. The para dications bind preferentially to sequences containing four contiguous AT base pairs. Additional footprinting experiments with substrates containing the 16 possible [A.T](4) blocks indicated that the presence of a TpA step within an [A.T] (4) block generally reduces the extent of binding. The diverse methods, from footprinting to SPR to dichroism, provide a consistent model for the interactions of the diphenylfuran dications with DNA of different sequences. Altogether, the results attest unequivocally that the binding mode for unfused aromatic cations can change completely depending on substituent position and DNA sequence. These data provide a rationale to explain the relationships between sequence selectivity and mode of binding to DNA for unfused aromatic dications related to furamidine.     

Ethidium bromide (EB) binding to nucleosomal DNA : Effects on DNA cleavage patterns

Binding of ethidium bromide (EB) to chromatin DNA induces structural changes in nucleosomes. The characteristic cleavage patterns of nucleosomal DNA after digestion with either micrococcal nuclease or pancreatic deoxyribonuclease are altered in the presence of the intercalating dye. Instead, apparently random digestion occurs. Polylysine reduces the amount of EB-binding sites in nucleosomal DNA. Since the intercalation of EB is known to proceed from the minor groove of DNA, polylysine supposedly occupies the same site of the nucleosomal DNA moiety.     

Recognition of ATGA sequences by the unfused aromatic dication DB293 forming stacked dimers in the DNA minor groove

Furamidine and related diamidines represent a promising series of drugs active against widespread parasites, in particular the Pneumocystic carinii pathogen. In this series, the phenylfuranbenzimidazole diamidine derivative DB293 was recently identified as the first unfused aromatic dication capable of forming stacked dimers in the DNA minor groove of GC-containing sequences. Here we present a detailed biochemical and biophysical characterization of the DNA sequence recognition properties of DB293. Three complementary footprinting techniques using DNase I, Fe(II)-EDTA, and an anthraquinone photonuclease were employed to locate binding sites for DB293 in different DNA restriction fragments. Two categories of sites were identified by DNase I footprinting: (i) 4/5 bp sequences containing contiguous A.T pairs, such as 5'-AAAA and 5'-ATTA; and (ii) sequences including the motif 5'-ATGA.5'-TCAT. In particular, a 13-bp sequence including two contiguous ATGA motifs provided a highly preferential recognition site for DB293. Quantitative footprinting analysis revealed better occupancy of the 5'-ATGA site compared to the AT-rich sites. Preferential binding of DB293 to ATGA sites was also observed with other DNA fragments and was confirmed independently by means of hydroxyl radical footprinting generated by the Fe(II)-EDTA system, as well as by a photofootprinting approach using the probe anthraquinone-2-sulfonate (AQS). In addition, this photosensitive reagent revealed the presence of sites of enhanced cutting specific to DB293. This molecule, but not other minor groove binders such as netropsin, induces specific local structural changes in DNA near certain binding sites, as independently shown by DNase I and the AQS probe. Recognition of the ATGA sequence by DB293 was investigated further using melting temperature experiments and surface plasmon resonance (SPR). The use of different hairpin oligonucleotides showed that DB293 can interact with AT sites via the formation of 1:1 drug-DNA complexes but binds much more strongly, and cooperatively, to ATGA-containing sequences to form 2:1 drug-DNA complexes. DB293 binds strongly to ATGA sequences with no significant context dependence but is highly sensitive to the orientation of the target sequence. The formation of 2:1 DB293/DNA complexes is abolished by reversing the sequence 5'-ATGA-->3'-ATGA, indicating that directionality plays an important role in the drug-DNA recognition process. Similarly, a single mutation in the A[T-->G]GA sequence is very detrimental to the dimer interactions of DB293. From the complementary footprinting and SPR data, the 5'-ATGA sequence is identified as being a highly favored dimer binding site for DB293. The data provide clues for delineating a recognition code for diamidine-type minor groove binding agents, and ultimately to guide the rational design of gene regulatory molecules targeted to specific sites of the genetic material.     

Demethylation of thymine residues affects DNA cleavage by endonucleases but not sequence recognition by drugs.

The 5-methyl group of thymidine residues protrudes into the major groove of double helical DNA. The structural influence of this exocyclic substituent has been examined using a PCR-made 160 bp fragment in which thymidine residues were replaced with uridine residues. We show that the dT-->dU substitution and the consequent deletion of the methyl group affects the cleavage of DNA by deoxyribonuclease I and micrococcal nuclease. Analysis of the DNase I cleavage sites, in terms of di and trinucleotides, indicates that homopolymeric tracts of d(AT) become significantly more susceptible to DNase I cleavage when uridine is substituted for thymidine residues. The results indicate that removal of the thymidine methyl groups from the major groove at AT tracts induces structural perturbations that transmit into the opposite minor groove, where they can be detected by endonuclease probing. In contrast, DNase I footprinting experiments with different mono and bis-intercalating drugs reveal that dT-->dU substitution does not markedly affect sequence-specific drug-DNA recognition in the minor or major groove of the double helix. The consequences of demethylation of thymidine residues are discussed in terms of changes in the minor groove width connected to variations in the flexibility of DNA and the intrinsic curvature associated with AT tracts. The study identifies the methyl group of thymine as an important molecular determinant controlling the width of the minor groove and/or the flexibility of the DNA.     

DNA Minor Groove Induced Dimerization of Heterocyclic Cations: Compound Structure, Binding Affinity, and Specificity for a TTAA Site

With the increasing number and variations of genome sequences available, control of gene expression with synthetic, cell-permeable molecules is within reach. The variety of sequence-specific binding agents is, however, still quite limited. Many minor groove binding agents selectivity recognize AT over GC sequences but have less ability to distinguish among different AT sequences. The goal with this article is to develop compounds that can bind selectively to different AT sequences. A number of studies indicate that AATT and TTAA sequences have significantly different physical and interaction properties and different requirements for minor groove recognition. Although it has been difficult to get minor groove binding at TTAA, DB293, a phenyl-furan-benzimidazole diamidine, was found to bind as a strong, cooperative dimer at TTAA but with no selectivity over AATT. In order to improve selectivity, we made modifications to each unit of DB293. Binding affinities and stoichiometries obtained from biosensor-surface plasmon resonance experiments show that DB1003, a furan-furan-benzimidazole diamidine, binds strongly to TTAA as a dimer and has selectivity (K_TTAA/K_AATT = 6). CD and DNase I footprinting studies confirmed the preference of this compound for TTAA. In summary, (i) a favorable stacking surface provided by the pi system, (ii) H-bond donors to interact with TA base pairs at the floor of the groove provided by a benzimidazole (or indole) -NH and amidines, and (iii) appropriate curvature of the dimer complex to match the curvature of the minor groove play important roles in differentiating the TTAA and AATT minor grooves.     

Sequence specificity of the binding of 9-aminoacridine- and amsacrine-4-carboxamides to DNA studied by DNase I footprinting.

DNase I footprinting has been used to probe the sequence selectivity of binding of a series of intercalating amsacrine-4-carboxamides and a related 9-aminoacridine-4-carboxamide to three DNA restriction fragments. These ligands have good experimental antileukemic activity, and for those members of the series that gave evaluable footprints, our principal finding is that they bind preferentially to GC-rich regions in agreement with the conclusion of equilibrium and kinetic measurements. The highest affinity sites generally occur in clusters of GC base pairs with runs of AT pairs being excluded from binding. It is important to appreciate that the 9-aminoacridine- and amsacrine-4-carboxamides exhibit a very high degree of selectivity for GC sites which, to our knowledge, has not been previously matched by acridine derivatives in footprinting experiments. The principal determinant of specificity appears to be the 4-carboxamide group itself since neither variations in the terminal funtionality of the 4-carboxamide sidechain nor the presence of the 9-anilino substituent modifies sequence preferences. The molecular origins of selectivity may be discerned in terms of potential hydrogen bonding interactions between the 4-carboxamide moiety and carbonyl oxygen and amino groups of GC base pairs in the DNA minor groove at CG dinucleotide sites. The related therapeutic agent amsacrine failed to inhibit cleavage by DNase I, so no conclusion can be drawn concerning its binding selectivity, save to note that amsacrine does not possess the 4-carboxamide group which appears to be the crucial determinant of GC specificity. Whether selectivity for binding to GC-rich sequences is an important element in the antitumor activity of both the 9-aminoacridine- and amsacrine-4-carboxamides remains to be determined.     

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.     

Evaluation of the influence of compound structure on stacked-dimer formation in the DNA minor groove

The Human Genome Project as well as sequencing of the genomes of other organisms offers a wealth of DNA targets for both therapeutic and diagnostic applications, and it is important to develop additional DNA binding motifs to fully exploit the potential of this new information. We have recently found that an aromatic dication, DB293, with an amidine-phenyl-furan-benzimidazole-amidine structure can recognize specific sequences of DNA by binding in the minor groove as a dimer [Wang, L., Bailly, C., Kumar, A., Ding, D., Bajic, M., Boykin, D. W., and Wilson, W. D. (2000) Proc. Natl. Acad. Sci. U.S.A. 97, 12-16]. The dimer binding is strong, highly cooperative and, in contrast to many closely related heterocyclic dications, has both GC and AT base pairs in the minor groove binding site. The aromatic heterocycle stacked dimer is quite different in structure from the polyamide-lexitropsin type compounds, and it is a dication while all lexitropsin dimers are monocations. The heterocyclic dimer represents only the second small molecule class that can recognize mixed sequences of DNA. To test the structural limits on the new type of complex, it is important to probe the influence of compound charge, chemical groups, and structural features. The effects of these compound molecular variations on DNA complex formation with several DNA sequences were evaluated by DNase I footprinting, CD and UV spectroscopy, thermal melting, and quantitative analysis with surface plasmon resonance biosensor methods. Conversion of the amidines to guanidinium groups does permit the cooperative dimer to form but removal of one amidine or addition of an alkyl group to the amidine strongly inhibited dimer formation. Changing the phenyl of DB293 to a benzimidazole or the benzimidazole to a phenyl or benzofuran also inhibited dimer formation. The results show that formation of the minor groove stacked-dimer complex is very sensitive to compound structure. The discovery of the aromatic dimer mode offers new opportunities to enhance the specificity and expand the range of applications of the compounds that target DNA.     

DNA sequence dependent binding modes of 4',6-diamidino-2-phenylindole (DAPI)

The interactions of DAPI with natural DNA and synthetic polymers have been investigated by hydrodynamic, DNase I footprinting, spectroscopic, binding, and kinetic methods. Footprinting results at low ratios (compound to base pair) are similar for DAPI and distamycin. At high ratios, however, GC regions are blocked from enzyme cleavage by DAPI but not by distamycin. Both poly[d(G-C)]2 and poly[d(A-T)]2 induce hypochromism and shifts of the DAPI absorption band to longer wavelengths, but the effects are larger with the GC polymer. NMR shifts of DAPI protons in the presence of excess AT and GC polymers are significantly different, upfield for GC and mixed small shifts for AT. The dissociation rate constants and effects of salt concentration on the rate constants are also quite different for the AT and the GC polymer complexes. The DAPI dissociation rate constant is larger with the GC polymer but is less sensitive to changes in salt concentration than with the AT complex. Binding of DAPI to the GC polymer and to poly[d(A-C)].poly[d(G-T)] exhibits slight negative cooperativity, characteristic of a neighbor-exclusion binding mode. DAPI binding to the AT polymer is unusually strong and exhibits significant positive cooperativity. DAPI has very different effects on the bleomycin-catalyzed cleavage of the AT and GC polymers, a strong inhibition with the AT polymer but enhanced cleavage with the GC polymer. All of these results are consistent with two totally different DNA binding modes for DAPI in regions containing consecutive AT base pairs versus regions containing GC or mixed GC and AT base pair sequences. The binding mode at AT sites has characteristics which are similar to those of the distamycin-AT complex, and all results are consistent with a cooperative, very strong minor groove binding mode. In GC and mixed-sequence regions the results are very similar to those observed with classical intercalators such as ethidium and indicate that DAPI intercalates in DNA sequences which do not contain at least three consecutive AT base pairs.     

Mutagenesis of the DNA binding residues in bovine pancreatic DNase 1: an investigation into the mechanism of sequence discrimination by a sequence selective nuclease.

The sequence selectivity of DNase 1 cleavage has been investigated by site-directed mutagenesis of a chemically synthesised gene. Two key DNA binding residues have been conservatively altered (Y76F and R41K) or have had their side-chains truncated (Y76A and R41A) and the effect on the cleavage of tyr T promoter DNA has been noted. It would appear from these studies that DNase 1 is not sensitive to minor groove width via these DNA-contacting residues, and it is suggested that DNA helical stiffness is a controlling parameter in determining DNase 1 sequence selectivity.     

Targeting DNA with novel diphenylcarbazoles

Double-stranded DNA is a therapeutic target for a variety of anticancer and antimicrobial drugs. Noncovalent interactions of small molecules with DNA usually occur via intercalation of planar compounds between adjacent base pairs or minor-groove recognition by extended crescent-shaped ligands. However, the dynamic and flexibility of the DNA platform provide a variety of conformations that can be targeted by structurally diverse compounds. Here, we propose a novel DNA-binding template for construction of new therapeutic candidates. Four bisphenylcarbazole derivatives, derived from the combined molecular architectures of known antitumor bisphenylbenzimidazoles and anti-infectious dicationic carbazoles, have been designed, and their interaction with DNA has been studied by a combination of biochemical and biophysical methods. The substitutions of the bisphenylcarbazole core with two terminal dimethylaminoalkoxy side chains strongly promote the interaction with DNA, to prevent the heat denaturation of the double helix. The deletion or the replacement of the dimethylamino-terminal groups with hydroxyl groups strongly decreased DNA interaction, and the addition of a third cationic side chain on the carbazole nitrogen reinforced the affinity of the compound for DNA. Although the bi- and tridentate molecules both derive from well-characterized DNA minor-groove binders, the analysis of their binding mode by means of circular and linear dichroism methods suggests that these compounds form intercalation complexes with DNA. Negative-reduced dichroism signals were recorded in the presence of natural DNA and synthetic AT and GC polynucleotides. The intercalation hypothesis was validated by unwinding experiments using topoisomerase I. Prominent gel shifts were observed with the di- and trisubstituted bisphenylcarbazoles but not with the uncharged analogues. These observations, together with the documented stacking properties of such molecules (components for liquid crystals), prompted us to investigate their binding to the human telomeric DNA sequence by means of biosensor surface plasmon resonance. Under conditions favorable to G4 formation, the title compounds showed only a modest interaction with the telomeric quadruplex sequence, comparable to that measured with a double-stranded oligonucleotide. Their sequence preference was explored by DNase I footprinting experiments from which we identified a composite set of binding sequences comprising short AT stretches and a few other mixed AT/GC blocks with no special AT character. The variety of the binding sequences possibly reflects the coexistence of distinct positioning of the chromophore in the intercalation sites. The bisphenylcarbazole unit represents an original pharmacophore for DNA recognition. Its branched structure, with two or three arms suitable to introduce a structural diversity, provides an interesting scaffold to built molecules susceptible to discriminate between the different conformations of nucleic acids.     

Unprecedented dual binding behaviour of acridine group of dye: a combined experimental and theoretical investigation for the development of anticancer chemotherapeutic agents

Acridine group of dyes are well known in the field of development of probes for nucleic acid structure and conformational determination because of their relevance in the development of novel chemotherapeutic agents, footprinting agents and for gene manipulation in biotechnology and medicine. Here, we report the interaction of 9-N,N-dimethylaniline decahydroacridinedione (DMAADD), a new class of dye molecule with calf thymus DNA (CT-DNA) which has been studied extensively by means of traditional experimental and theoretical techniques. The changes in the base stacking of CT-DNA upon the binding of DMAADD are reflected in the circular dichroic (CD) spectral studies. Competitive binding study shows that the enhanced emission intensity of ethidium bromide (EB) in presence of DNA was quenched by the addition of DMAADD indicating that it displaces EB from its binding site in DNA and the apparent binding constant has been estimated to be (3.3+/-0.2)x10(5) M(-1). This competitive binding study and further fluorescence experiments reveal that DMAADD is a moderate binder of CT-DNA, while viscosity measurements show that the mode of binding is partial intercalation. Generally, one would expect increase in the melting temperature (T(m)) of DNA in presence of intercalators. Interestingly, an unusual decrease in melting temperature (DeltaT(m) of -4+/-0.2 degrees C) of DNA by the addition of DMAADD was observed. From our knowledge such a decreasing trend in melting point was not reported before for all the possible modes of binding. Molecular modeling gave the pictorial view of the binding model which clearly shows that of the various mode of binding, the dye prefers the major groove binding to the sites rich in GC residues and to the sites rich in AT residues it prefers intercalation mode of binding either through major or minor groove with the inclusion of the N,N-dimethylaniline (DMA) group inside the double helix which has been stacked in between the bases, under physiological relevant pH of 7.5.     

DNA conformational analysis in solution by uranyl mediated photocleavage.

Uranyl mediated photocleavage of double stranded DNA is proposed as a general probing for DNA helix conformation in terms of minor groove width/electronegative potential. Specifically, it is found that A/T-tracts known to constitute strong distamycin binding sites are preferentially photocleaved by uranyl in a way indicating strongest uranyl binding at the center of the minor groove of the AT-region. The A-tracts of kinetoplast DNA show the highest reactivity at the 3'-end of the tract--as opposed to cleavage by EDTA/Fell--in accordance with the minor groove being more narrow at this end. Finally, uranyl photocleavage of the internal control region (ICR) of the 5S-RNA gene yields a cleavage modulation pattern fully compatible with that obtained by DNase I which also--in a more complex way--senses DNA minor groove width.     

Sequence-selective, pH-dependent binding to DNA of benzophenanthridine alkaloids

The sequence selectivity associated with binding to DNA of three alkaloids belonging to the benzophenanthridine family has been analysed by DNase I footprinting, and the results were compared with those obtained from an analysis of the behaviour of the standard intercalator, ethidium bromide. Like the ethidium, the benzophenanthridine compounds appear to bind best to regions of mixed nucleotide sequence, especially those containing alternating purines and pyrimidines, although there are some notable differences in behaviour. There is also a marked lack of binding to sequences such as (AT)n, where n greater than or equal to 3. The binding to DNA of the benzophenanthridines is specifically related to the hydrogen ion concentration of the medium, in that the DNase I footprints are considerably enhanced when the reaction is performed at a pH below 7.0. We discuss these results in terms of a greater preponderance of the intercalating species being present at lower pH.     

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.     

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.     

Effect of ionic strength and cationic DNA affinity binders on the DNA sequence selective alkylation of guanine N7-positions by nitrogen mustards

Large variations in alkylation intensities exist among guanines in a DNA sequence following treatment with chemotherapeutic alkylating agents such as nitrogen mustards, and the substituent attached to the reactive group can impose a distinct sequence preference for reaction. In order to understand further the structural and electrostatic factors which determine the sequence selectivity of alkylation reactions, the effect of increased ionic strength, the intercalator ethidium bromide, AT-specific minor groove binders distamycin A and netropsin, and the polyamine spermine on guanine N7-alkylation by L-phenylalanine mustard (L-Pam), uracil mustard (UM), and quinacrine mustard (QM) was investigated with a modification of the guanine-specific chemical cleavage technique for DNA sequencing. For L-Pam and UM, increased ionic strength and the cationic DNA affinity binders dose dependently inhibited the alkylation. QM alkylation was less inhibited by salt (100 mM NaCl), ethidium (10 microM), and spermine (10 microM). Distamycin A and netropsin (100 microM) gave an enhancement of overall QM alkylation. More interestingly, the pattern of guanine N7-alkylation was qualitatively altered by ethidium bromide, distamycin A, and netropsin. The result differed with both the nitrogen mustard (L-Pam less than UM less than QM) and the cationic agent used. The effect, which resulted in both enhancement and suppression of alkylation sites, was most striking in the case of netropsin and distamycin A, which differed from each other. DNA footprinting indicated that selective binding to AT sequences in the minor groove of DNA can have long-range effects on the alkylation pattern of DNA in the major groove.     

Conversion of bovine pancreatic DNase I to a repair endonuclease with a high selectivity for abasic sites.

Bovine pancreatic deoxyribonuclease I (DNase I) is a nuclease of relatively low specificity which interacts with DNA in the minor groove. No contacts are made between the protein and the major groove of the nucleic acid. DNase I is structurally homologous to exonuclease III, a DNA-repair enzyme with multiple activities. One of the main differences between the two enzymes is the presence of an additional alpha-helix in exonuclease III, in a position suggestive of interaction with the major groove of DNA. Recombinant DNA techniques have been used to add 14 amino acids, comprising the 10 amino acids of the exonuclease III alpha-helix flanked by a glycine rich region, to DNase I. The polypeptide has been inserted after serine 174, an amino acid on the surface of DNase I corresponding to the location of the extra alpha-helix in exonuclease III. The recombinant protein, DNase-exohelix, has been purified and its catalytic activities towards DNA investigated. The recombinant protein demonstrated a high selectivity for endonucleolytic cleavage at abasic sites in DNA, a property of exonuclease III but not native DNase I. Thus the insertion of 14 amino acids at Ser174, converts DNase I to an exonuclease III-like enzyme with DNA-repair properties.     

Harnessing DNA intercalation

Numerous small molecules are known to bind to DNA through base pair intercalation. Fluorescent dyes commonly used for nucleic acid staining, such as ethidium, are familiar examples. Biological and physical studies of DNA intercalation have historically been motivated by mutation and drug discovery research. However, this same mode of binding is now being harnessed for the creation of novel molecular assemblies. Recent studies have used DNA scaffolds and intercalators to construct supramolecular assemblies that function as fluorescent 'nanotags' for cell labeling. Other studies have demonstrated how intercalators can be used to promote the formation of otherwise unstable nucleic acid assemblies. These applications illustrate how intercalators can be used to facilitate and expand DNA-based nanotechnology.