Natural product DNA major groove binders

Covering: 1980 to 2011. Major groove recognition of DNA by proteins utilizes the variation in hydrogen bond donor/acceptor content that makes DNA base-pairs distinguishable from one another. Specific ligand-DNA interactions in the major groove are necessary to develop approaches for inhibition of DNA-protein interactions. As opposed to minor groove binders, little research has been achieved in recognition of the DNA major groove. This review summarizes the progress in identification of natural products that bind to the major groove of DNA. We first review the natural products, pluramycins, aflatoxins, azinomycins, leinamycin, neocarzinostatin, and ditercalinium, that are known to possess major groove interacting elements. These compounds, however, interact primarily with DNA by intercalation between base-pair steps. Some of these compounds utilize non-covalent interactions in order to position themselves to alkylate DNA at the nucleophilic N7 positions on nearby purine bases. Finally, recent reports of non-covalent major groove binding with carbohydrates, aminoglycosides in particular, have revealed them as promising leads for DNA major groove binding probes or drugs.     

DNA recognition by the anthracycline antibiotic respinomycin D: NMR structure of the intercalation complex with d(AGACGTCT)2

Respinomycin D is a member of the anthracycline family of antitumour antibiotics that interact with double stranded DNA through intercalation. The clinical agents daunomycin and doxorubicin are the most well-studied of this class but have a relatively simple molecular architecture in which the pendant daunosamine sugar resides in the DNA minor groove. Respinomycin D, which belongs to the nogalamycin group of anthracyclines, possesses additional sugar residues at either end of the aglycone chromophore that modulate the biological activity but whose role in molecular recognition is unknown. We report the NMR structure of the respinomycin D-d(AGACGTCT)2 complex in solution derived from NOE restraints and molecular dynamics simulations. We show that the drug threads through the DNA double helix forming stabilising interactions in both the major and minor groove, the latter through a different binding geometry to that previously reported. The bicycloaminoglucose sugar resides in the major groove and makes specific contacts with guanine at the 5'-CpG intercalation site, however, the disaccharide attached at the C4 position plays little part in drug binding and DNA recognition and is largely solvent exposed.     

Major versus minor groove DNA binding of a bisarginylporphyrin hybrid molecule: A molecular mechanics investigation

On the basis of theoretical computations, we have recently synthesised [Perrée-Fauvet, M. and Gresh, N., Tetrahedron Lett., 36 (1995) 4227] a bisarginyl conjugate of a tricationic porphyrin (BAP), designed to target, in the major groove of DNA, the d(GGC GCC)2 sequence which is part of the primary binding site of the HIV-1 retrovirus site [Wain-Hobson, S. et al., Cell, 40 (1985) 9]. In the theoretical model, the chromophore intercalates at the central d(CpG)2 step and each of the arginyl arms targets O6/N7belonging to guanine bases flanking the intercalation site. Recent IR and UV-visible spectroscopic studies have confirmed the essential features of these theoretical predictions [Mohammadi, S. et al., Biochemistry, 37 (1998) 6165]. In the present study, we compare the energies of competing intercalation modes of BAP to several double-stranded oligonucleotides, according to whether one, two or three N- methylpyridinium rings project into the major groove. Correspondingly, three minor groove binding modes were considered, the arginyl arms now targeting N3, O2 sites belonging to the purine or pyrimidine bases flanking the intercalation site. This investigation has shown that: (i) in both the major and minor grooves, the best-bound complexes have the three N-methylpyridinium rings in the groove opposite to that of the phenyl group bearing the arginyl arms; (ii) major groove binding is preferred over minor groove binding by a significant energy (29 kcal/mol); and (iii) the best-bound sequence in the major groove is d(GGC GCC)2 with two successive guanines upstream from the intercalation. On the other hand, due to the flexibility of the arginyl arms, other GC-rich sequences have close binding energies, two of them being less stable than it by less than 8 kcal/mol. These results serve as the basis for the design of derivatives of BAP with enhanced sequence selectivities in the major groove.     

Alteration in the choice of DNA repair pathway with increasing sequence selective DNA alkylation in the minor groove

BACKGROUND: Many conventional DNA alkylating anticancer drugs form adducts in the major groove of DNA. These are known to be chiefly repaired by both nucleotide (NER) and base (BER) excision repair in eukaryotic cells. Much less is known about the repair pathways acting on sequence specific minor groove purine adducts, which result from a promising new class of anti-tumour agents. RESULTS: Benzoic acid mustards (BAMs) tethering 1-3 pyrrole units (compounds 1, 2 and 3) show increasing DNA sequence selectivity for alkylation from BAM and 1, alkylating primarily at guanine-N7 in the major groove, to 3 which is selective for alkylation in the minor groove at purine-N3 in the sequence 5'-TTTTGPu (Pu=guanine or adenine). This increasing sequence selectivity is reflected in increased toxicity in human cells. In the yeast Saccharomyces cerevisiae, the repair of untargeted DNA adducts produced by BAM, 1 and 2 depends upon both the NER and BER pathways. In contrast, the repair of the sequence specific minor groove adducts of 3 does not involve known BER or NER activities. In addition, neither recombination nor mismatch repair are involved. Two disruptants from the RAD6 mutagenesis defective epistasis group (rad6 and rad18), however, showed increased sensitivity to 3. In particular, the rad18 mutant was over three orders of magnitude more sensitive to 3 compared to its isogenic parent, and 3 was highly mutagenic in the absence of RAD18. Elimination of the sequence specific DNA adducts formed by 3 was observed in the wild type strain, but these lesions persisted in the rad18 mutant. CONCLUSIONS: We have demonstrated that the repair of DNA adducts produced by the highly sequence specific minor groove alkylating agent 3 involves an error free adduct elimination pathway dependent on the Rad18 protein. This represents the first systematic analysis of the cellular pathways which modulate sensitivity to this new class of DNA sequence specific drugs, and indicates that the enhanced cytotoxicity of certain sequence specific minor groove adducts in DNA is the result of evasion of the common excision repair pathways.     

Long range 1,4 and 1,6-interstrand cross-links formed by a trinuclear platinum complex. Minor groove preassociation affects kinetics and mechanism of cross-link formation as well as adduct structure

Reported here is a comparison of the kinetics of the stepwise formation of 1,4- and 1,6-GG interstrand cross-links by the trinuclear platinum anticancer compound (15)N-[[trans-PtCl(NH(3))(2)](2)[mu-trans-Pt(NH(3))(2)(H(2)N(CH(2))(6)NH(2))(2)]](4+), (1,0,1/t,t,t (1) or BBR3464). The reactions of (15)N-1 with the self-complementary 12-mer duplexes 5'-[d(ATATGTACATAT)(2)] (I) and 5'-[d(TATGTATACATA)(2)] (II) have been studied at 298 K, pH 5.3 by [(1)H,(15)N] HSQC 2D NMR spectroscopy. The kinetic profiles for the two reactions are similar. For both sequences initial electrostatic interactions with the DNA are observed for 1 and the monoaqua monochloro species (2) and changes in the chemical shifts of certain DNA (1)H resonances are consistent with binding of the central charged [PtN(4)] linker unit in the minor groove. The pseudo first-order rate constants for the aquation of 1 to 2 in the presence of duplex I (3.94 +/- 0.03 x 10(-5) s(-1)), or II(4.17 +/- 0.03 x 10(-5) s(-1)) are ca. 40% of the value obtained for aquation of 1 under similar conditions in the absence of DNA. Monofunctional binding to the guanine N7 of the duplex occurs with rate constants of 0.25 +/- 0.02 M(-1) s(-1) (I) and 0.34 +/- 0.02 M(-1) s(-1) (II), respectively. Closure to form the 1,4- or 1,6-interstrand cross-links (5) was treated as direct from 3 with similar rate constants of 4.21 +/- 0.06 x 10(-5) s(-1) (I) and 4.32 +/- 0.04 x 10(-5) s(-1) (II), respectively. Whereas there is only one predominant conformer of the 1,6 cross-link, evidence from both the (1)H and [(1)H,(15)N] NMR spectra show formation of two distinct conformers of the 1,4 cross-link, which are not interconvertible. Closure to give the major conformer occurs 2.5-fold faster than for the minor conformer. The differences are attributed to the initial preassociation of the central linker of 1 in the minor groove and subsequently during formation of both the monofunctional and bifunctional adducts. For duplex I, molecular models indicate two distinct pathways for the terminal [PtN(3)Cl] groups to approach and bind the guanine N7 in the major groove with the central linker anchored in the minor groove. To achieve platination of the guanine residues in duplex II the central linker remains in the minor groove but 1 must diffuse off the DNA for covalent binding to occur. Clear evidence for movement of the linker group is seen at the monofunctional binding step from changes of chemical shifts of certain CH(2) linker protons as well as the Pt-NH(3) and Pt-NH(2) groups. Consideration of the (1)H and (15)N shifts of peaks in the Pt-NH(2) region show that for both the 1,4 and 1,6 interstrand cross-links there is a gradual and irreversible transformation from an initially formed conformer(s) to product conformer(s) in which the amine protons of the two bound [PtN(3)] groups exist in a number of different environments. The behavior is similar to that observed for the 1,4-interstrand cross-link of the dinuclear 1,1/t,t compound. The potential significance of preassociation in determining kinetics of formation and structure of the adducts is discussed. The conformational flexibility of the cross-links is discussed in relation to their biological processing, especially protein recognition and repair, which are critical determinants of the cytotoxicity of these unique DNA-binding agents.     

Paranemic crossover DNA: a generalized Holliday structure with applications in nanotechnology

Paranemic crossover (PX) DNA is a four-stranded coaxial DNA complex containing a central dyad axis that relates two flanking parallel double helices. The strands are held together exclusively by Watson-Crick base pairing. The key feature of the structure is that the two adjacent parallel DNA double helices form crossovers at every point possible. Hence, reciprocal crossover points flank the central dyad axis at every major or minor groove separation. This motif has been modeled and characterized in an oligonucleotide system; a minor groove separation of five nucleotide pairs and major groove separations of six, seven, or eight nucleotide pairs produce stable PX DNA molecules; a major groove separation of 9 nucleotide pairs is possible at low concentrations. Every strand undergoes a crossover every helical repeat (11, 12, 13, or 14 nucleotides), but the structural period of each strand corresponds to two helical repeats (22, 24, 26, or 28 nucleotides). Nondenaturing gel electrophoresis shows that the molecules are stable, forming well-behaved complexes. PX DNA can be produced from closed dumbbells, demonstrating that the molecule is paranemic. Ferguson analysis indicates that the molecules are similar in shape to DNA double crossover molecules. Circular dichroism spectra are consistent with B-form DNA. Thermal transition profiles suggest a premelting transition in each of the molecules. Hydroxyl radical autofootprinting analysis confirms that there is a crossover point at each of the positions expected in the secondary structure. These molecules are generalized Holliday junctions.     

Direct observation of essential DNA dynamics: melting and reformation of the DNA minor groove

The dynamics of bound water and ions present in the minor groove of a dodecamer DNA has been decoupled from that of the long-range twisting/bending of the DNA backbone, using the minor groove binder Hoechst 33258 as a fluorescence reporter in the picosecond-resolved time window. The bound water and ions are essential structural components of the minor groove and are destroyed with the destruction of the minor groove when the dodecamer melts at high temperatures and reforms on subsequent cooling of the melted DNA. The melting and rehybridization of the DNA has been monitored by the changes in secondary structure using circular dichroism (CD) spectroscopy. The change in the relaxation dynamics of the DNA has been studied with picosecond resolution at different temperatures, following the temperature-dependent melting and rehybridization profile of the dodecamer, using time-resolved emission spectra (TRES). At room temperature, the relaxation dynamics of DNA is governed by a 40 ps (30%) and a 12.3 ns (70%) component. The dynamics of bound water and ions present in the minor groove is characterized by the 40 ps component in the relaxation dynamics of the probe bound in the minor groove of the dodecamer DNA. Analyses of the TRES taken at different temperatures show that the contribution of this component decreases and ultimately vanishes with the destruction of the minor groove and reappears again with the reformation of the groove. The dynamical behavior of bound water molecules and ions of a genomic DNA (from salmon testes) at different temperatures is also found to be consistent with that of the dodecamer. The longer component of approximately 10 ns in the DNA dynamics is found to be associated with the long-range bending/twisting of the DNA backbone and the associated counterions. The transition from bound water to free water at the DNA surface, indicative of the change in the hydration number associated with each base pair, has also been ascertained in the case of the genomic DNA at different temperatures by employing densimetric and acoustic techniques.     

NMR structural analysis of a modular threading tetraintercalator bound to DNA

The synthesis and NMR structural studies are reported for a modular threading tetraintercalator bound to DNA. The tetraintercalator design is based on 1,4,5,8-tetracarboxylic naphthalene diimide units connected through flexible peptide linkers. Aided by an overall C(2) symmetry, NMR analysis verified a threading polyintercalation mode of binding, with linkers alternating in the order minor groove, major groove, minor groove, analogous to how a snake might climb a ladder. This study represents the first NMR analysis of a threading tetraintercalator and, as such, structurally characterizes a new topology for molecules that bind to relatively long DNA sequences with extensive access to both DNA grooves.     

Exploring DNA groove water dynamics through hydrogen bond lifetime and orientational relaxation

Dynamics of water molecules in the grooves of DNA are of great interest both for practical (functionality of DNA) and fundamental (as examples of confined systems) interest. Here the authors employ atomistic molecular dynamics simulations to understand varying water dynamics at the minor and the major grooves of a 38 base-pair long DNA duplex in water. In order to understand and quantify the diversity in the nature of hydrogen bond due to many hydrogen bond donors and acceptors present in the four bases, they have undertaken study of hydrogen bond lifetime (HBLT) correlation functions of all the specific hydrogen bonds between the base atoms and water molecules. They find that the HBLT correlation functions are in general multiexponential, with the average lifetime depending significantly on the specificity and may thus be biologically relevant. The average hydrogen bond lifetime is longer in the minor groove than that in the major groove by almost a factor of 2. Analysis further shows that water hydrogen bonds with phosphate oxygen have substantially shorter lifetimes than those with the groove atoms. They also compute two different orientational time correlation functions (OTCFs) of the water molecules present at the major and the minor grooves and attempt to correlate OTCF with HBLT correlation function. The OTCFs in the minor groove exhibit three time scales, with the time constant of the slowest component one to two orders of magnitude longer than what is observed for bulk water. A slow component is also present for the major groove water but with shorter time constant. Interestingly, correlation between reformations allowed HBLT correlation function [C(HB)(t)] and the OTCF markedly deviates from each other in the grooves, indicating enhanced rigidity of water molecules in the grooves.     

The Intehaction of Aqueous Solutions of Chlorine with Malic Acid,Tartaric Acid,and Various Fruit Juices: A Source of Mutagens

Abstract

The interactions of aqueous solutions of chlorine with some fruit acids (citric acid, DL-malic acid, arid L-tartaric acid) at different pH values were studied. Diethyl ether extraction followed by GC/MS analysis indicated that a number of mutagens (certain chlorinated propanones and chloral hydrate) are present as major products in some of these samples. A number of fruit juices (orange, grape, apple, pineapple, and grapefruit) were also treated with aqueous solutions of chlorine at their pH values. The products were analyzed by GC/MS. The same mutagens that were formed by the pure acids (citric acid and DL-malic acid) were identified as major products in ether extracts of these samples. Another mutagen, dichloroacetonitrile, was also identified as a minor product in some of these juice samples. All of the major products observed in the chlorination of all five fruit juices are potentially derived from reactions of aqueous solutions of chlorine with citric or malic acid and with trace amounts of acetaldehyde and acetone in the juices. The minor product, dichloroacetonitrile, is likely derived from the chlorination of certain amino acids in the fruit juices.     

Visualisation of inter loop tertiary base pairing and stacking interactions in an unusual slipped loop DNA structure

The conformation of an unusual slipped loop DNA structure exhibited by the sequence d(GAATTCCCGAATTC)₂ is determined using a combination of geometrical and molecular mechanics methods. This sequence is known to form a B-DNA-like duplex with the central non-complementary cytosines extruded into single stranded loop regions. The unusual feature is that the interior guanine does not pair with the cytosine across, instead, it pairs with the cytosine upstream by skipping two cytosines, leading to a slipped loop DNA structure with the loops staggered by two base pairs. The two loops, despite being very small, can fold across minor or major groove symmetrically or asymmetrically disposed, with one of the loop bases partially blocking the major or minor groove. Most interestingly, for certain conformations, the loop bases approach one another at close proximity so as to engage even in base pairing as well as base stacking interactions across the major groove. While such pairing and stacking are common in the tertiary folds of RNA, this is the first time that such an interaction is visualized in a DNA. This observation demonstrates that a W-C pair can readily be accomplished in a typical slipped loop structure postulated for DNA. Such tertiary loop interaction may prevent access to regulatory proteins across the major groove of the duplex DNA, thus providing a structure-function relation for the occurrence of slipped loop structure in DNA. Contribution no. 839 from this department     

DNA小沟结合二脒:水分子的识别作用

采用分子动力学模拟了DB921-DNA复合物, 通过7 ns的模拟研究表明: DB921一端的氨基氮原子与一个水分子形成氢键, 同时, 水分子又与DNA的5位A碱基的氮原子形成一个氢键. 水分子在DB921与DNA小沟结合中起了桥连的作用, 使得直线型的芳香二脒化合物DB921通过水桥与DNA小沟结合, 水分子诱导DB921分子与DNA的小沟域构型相适应, 与DNA小沟域的AATTC碱基有较强的结合作用. 在分子水平上提供了DB921与双螺旋DNA相互作用的结构及复合物的动态变化情况, 指出水分子在DNA小沟结合二脒化合物中的识别作用, 为设计出更高生物活性的DNA小沟结合剂提供一定的理论依据.     

A minor groove binding copper-phenanthroline conjugate produces direct strand breaks via beta-elimination of 2-deoxyribonolactone

Copper-phenanthroline complexes and their conjugates are useful reagents for studying nucleic acid interactions. Although DNA cleavage by such complexes was discovered more than 20 years ago, significant questions remain unanswered regarding the chemical mechanism(s) by which DNA is damaged. Kinetic evidence is provided, which demonstrates that the major pathway for DNA damage by a minor groove binding molecule conjugated to copper phenanthroline (6) involves C1'-oxidation. Additional experiments using 6 and a DNA substrate containing 2-deoxyribonolactone (1) show that direct strand breaks are produced via beta-elimination from 1. These studies support the original mechanism for DNA damage by copper phenanthroline put forth by Sigman and a more recent proposal concerning the mechanism for direct strand break formation.     

Surface-enhanced Raman study of the interactions between tripodal cationic polyamines and polynucleotides

Raman and surface-enhanced Raman spectra of new DNA/RNA-binding compounds consisting of three imidazole (Im) and three pyridine (Py) rings connected by tripodal polyaminomethylene linkages were obtained by the near-infrared excitation at 1064 nm. Study of interactions of Im and Py polyamines with single-stranded RNA polynucleotides (poly?A, poly?G, poly?C, poly?U), double-stranded DNA polynucleotides (poly?dAdT-poly?dAdT, poly?dGdC-poly?dGdC) and calf thymus DNA (ct-DNA) by surface-enhanced Raman spectroscopy (SERS) reveals unambiguous enhancement of the Raman scattering from the small molecules as well as appearance of new bands in spectra associated mainly with nucleobases. The SERS experiments point toward comparable interactions of Im and Py polyamines with single-stranded purine and pyrimidine polynucleotides. Furthermore, SERS experiments with double stranded polynucleotides reveal the base-pair dependent selectivity of Im and Py, whereby interactions within both, major and minor groove are indicated for poly?dAdT-poly?dAdT, at variance to preferred binding of Im and Py to only major groove of poly?dGdC-poly?dGdC. SERS spectra of Im and Py with ct-DNA imply that protonated amino groups of these compounds preferentially interact with N7 atoms (adenine, guanine) while nitrogen in aromatic rings of polyamines might be attracted to C6-NH(2) (adenine), all sites being located at the major groove of the DNA helix. Wavenumber downshift of the imidazole (Im) and pyridine (Py) ring vibrations supports aromatic stacking interactions of imidazole and pyridine aromatic moieties with DNA base-pairs.     

The N6-methyl group of adenine further increases the BI stability of DNA compared to C5-methyl groups

Methylated DNA bases are natural modifications which play an important role in protein-DNA interactions. Recent experimental and theoretical results have shown an influence of the base modification on the conformational behavior of the DNA backbone. MD simulations of four different B-DNA dodecamers (d(GC)(6), d(AT)(6), d(G(5mCG)(5)C), and d(A(T6mA)(5)T)) have been performed with the aim to examine the influence of methyl groups on the B-DNA backbone behavior. An additional control simulation of d(AU)(6) has also been performed to examine the further influence of the C5-methyl group in thymine. Methyl groups in the major groove (as in C5-methylcytosine, thymine, or N6-methyladenine) decrease the BII substate population of RpY steps. Due to methylation a clearer distinction of the BI substate stability between YpR and RpY (CpG/GpC or TpA/ApT) steps arises. A positive correlation between the BII substate population and base stacking distances is seen only for poly(GC). A methyl group added into the major groove increases mean water residence times around the purine N7 atom, which may stabilize the BI substate by improving the hydration network between the DNA backbone and the major groove. The N6-methyl group also forms a water molecule bridge between the N6 and O4 atoms, and thus further stabilizes the BI substate.     

N-methylpiperazinocarbonyl-2',3'-BcNA and 4'-C-(N-methylpiperazino)methyl-DNA: introduction of basic functionalities facing the major groove and the minor groove of a DNA:DNA duplex

Piperazino-functionalized 2',3'-BcNA and 4'-C-hydroxymethyl-DNA are appropriate molecular architectures for the introduction of basic functionalities facing the major groove and the minor groove of nucleic acid duplexes, respectively. 4'-C-(N-Methylpiperazino)methyl-DNA monomers induce significantly increased thermal stability of a DNA:DNA duplex.     

Molecular dynamics of minimal B‐DNA

Stable and accurate molecular dynamics (MD) of B‐DNA duplexes can be obtained in inexpensive computational conditions where only the minor groove is filled with water while the bulk solvent is represented implicitly. This model system presents significant theoretical as well as practical interest because, due to its simplicity and exceptional computational performance, it can be employed in simulations of very long DNA fragments. To better understand its properties and clarify the physical background of the effects produced by the limited water shell, dynamics of several different DNA oligomers was studied. It is found that optimal simulation conditions are reached when the explicit water is confined within the minor groove while the major groove is cleaned periodically. The internal solvent mobility appears high enough to observe in the nanosecond time scale spontaneous formation of sequence‐specific hydration patterns known from experiments. It is shown that the model produces stable MD trajectories close to the B‐DNA form regardless of the base pair sequence and that, on the other hand, the dynamics are strongly sequence dependent. Independent observations suggest that B‐DNA with only minor groove hydrated resembles its natural thermodynamic state at low water concentration; therefore, this model system can be tentatively called “minimal B‐DNA.” © 2001 John Wiley & Sons, Inc. J Comput Chem 22: 457–467, 2001     

DNA sequence dependent monomer-dimer binding modulation of asymmetric benzimidazole derivatives

A number of studies indicate that DNA sequences such as AATT and TTAA have significantly different physical and interaction properties. To probe these interaction differences in detail and determine the influence of charge, we have synthesized three bisbenzimidazole derivatives, a diamidine, DB185, and monoamidines, DB183 and DB210, that are related to the well-known minor groove agent, Hoechst 33258. Footprinting studies with several natural and designed DNA fragments indicate that the synthetic compounds bind at AT sequences in the minor groove and interact more weakly at sites with TpA steps relative to sites without such steps. Circular dichroism spectroscopy also indicates that the compounds bind in the DNA minor groove. Surprisingly, Tm studies as a function of ratio indicate that the monoamidines bind to TTAA sequences as dimers, whereas the diamidine binds as a monomer. Biosensor-surface plasmon resonance (SPR) studies allowed us to quantitate the interaction differences in more detail. SPR results clearly show that the monoamidine compounds bind to the TTAA sequence in a cooperative 2:1 complex but bind as monomers to AATT. The dication binds to both sequences in monomer complexes but the binding to AATT is significantly stronger than binding to TTAA. Molecular dynamics simulations indicate that the AATT sequence has a narrow time-average minor groove width that is a very good receptor site for the bisbenzimidazole compounds. The groove in TTAA sequences is wider and the width must be reduced to form a favorable monomer complex. The monocations thus form cooperative dimers that stack in an antiparallel orientation and closely fit the structure of the TTAA minor groove. The amidine groups in the dimer are oriented in the 5' direction of the strand to which they are closest. Charge repulsion in the dication apparently keeps it from forming the dimer. It instead reduces the TTAA groove width, in an induced fit process, sufficiently to form a minor groove complex. The dimer-binding mode of DB183 and DB210 is a new DNA recognition motif and offers novel design concepts for selective targeting of DNA sequences with a wider minor groove, including those with TpA steps.