1H NMR study of the structure of a pyridocarbazole dimer-d[CpGpCpG] complex

The structure of the complexes formed between a 7H-pyridocarbazole dimer (ditercalinium) or the corresponding monomer and d[CpGpCpG] is analyzed in aqueous solution by 270 MHz 1H NMR. In both cases the strong upfield shifts observed on most aromatic resonances are assigned to the formation of intercalated complexes. Bisintercalation of the dimer in the tetranucleotide minihelix is then observed at pH 5.5. The observation of intermolecular negative NOEs induced to some drug resonances by irradiation of sugar protons confirms these conclusions. The orientation of the ligand in the intercalation site is discussed.     

Bisintercalation of ditercalinium into a d[CpGpCpG]2 minihelix: structure and dynamics aspects--a 400-MHz 1H-NMR study

The structure of the complex formed in aqueous solution at pH 5.5 between ditercalinium, a potent antitumoral 7H-pyrido[4,3-c]carbazole rigid dimer, and the self-complementary tetranucleotide d[CpGpCpG], was investigated by 400-MHz ¹H-nmr. For a 1:2.5 drug-to-helix ratio, the dimer was only found in bound form, whereas free and complexed tetranucleotide were in slow exchange. This allowed unambiguous assignment of the protons in the complex through exchange polarization transfer measurements. The tetranucleotide existed as a right-handed double helix in the complex. The strong upfield shifts measured on most aromatic protons on both drug and nucleobases as well as on DNA imino protons were consistent with bisintercalation of the dimer. According to the negative nuclear Overhauser effects generated to protons on the convex edge of the bound drug rings by saturation of sugar protons, it was concluded that ditercalinium was intercalated with its rigid bis-ethyl bispiperidine spacer fitting the major groove of the helix. Difference in antitumor activity of various pyridocarbazole dimers is discussed in relation to the binding kinetics and the complex geometry determined in this study.     

Study of the bisintercalation of the antitumor drug ditercalinium by 31P-NMR

Bisintercalation of ditercalinium, a potent antitumoral 7H-pyriodo[4,3-c]carbazole rigid dimer, into the self-complementary tetranucleotides d(CpGpCpG)₂, d(m⁵CpGpm⁵CpG) and the self-complementary hexanucleotide d(CpGpApTpCpG)₂ was investigated by 162-MHz ³¹P-nmr. The slow exchange, on the nmr time scale, observed between the free and complexed nucleotides allows identification of the phosphorus signals in the complexes through two-dimensional chemical exchange spectroscopy. Differences in ³¹P chemical shifts upon intercalation are discussed in relation to the complex geometry and nature of the drug.     

Comparison of the bis-intercalating complexes formed between either ditercalinium or a flexible analogue and d(CpGpCpG)2 or d(TpTpCpGpCpGpApA)2 minihelices: 1H- and 31P-NMR analyses.

The 400-MHz 1H- and 162-MHz 31P-nmr have been used to study complexes constituted by (a) the d(TpTpCpGpCpGpApA)2 or the d(CpGpCpG)2 self-complementary oligonucleotides and (b) two bifunctional 7H-pyrido [4,3-c] carbazole dimer drugs, the antitumoral ditercalinium (NSC 366241), a dimer with a rigid bis-piperidine linking chain and its pharmacologically inactive analogue, a dimer with a flexible spermine-like linking chain. Nearly all proton and phosphorus signals have been assigned by two-dimensional (2D) nmr (correlated spectroscopy, homonuclear Hartmann-Hahn, nuclear Overhauser enhancement spectroscopy, 2D 31P (1H) heteronuclear correlated spectroscopy and 31P-31P chemical exchange experiments). Both drugs bis-intercalate into the two CpG sites. The complexes show small differences in the position of the 7H-pyrido [4,3-c] carbazole ring into the intercalation site and possibly in the ribose-phosphate backbone deformation. However, the inactive analogue exhibits a longer residence lifetime in octanucleotide than the ditercalinium does. All these results are discussed in terms of differences in dimer activities.     

1H-NMR studies of a monointercalating drug into a d[CpGpCpG]2 minihelix

The structure of the complex formed between the 7H-pyridocarbazole monomer [{(2-piperidyl)-2,1-ethane-yl} {10-methoxy-7H-pyrido[4,3-c]carbazolium} dimethane sulfonate] and the autocom-plementary tetranucleotide d(CpGpCpG)₂ in aqueous solution is analyzed by 270-MHz and 400-MHz ¹H-nmr. The strong upfield shifts observed on most aromatic resonances of both the drug and the nucleotide are interpreted as the result of intercalation of the 7H-pyridocarbazole monomer in the base-paired minihelix of d(CpGpCpG). The observation of intermolecular negative nuclear Overhauser effects induced in some drug resonances by irradiation of sugar protons confirms this conclusion. A privileged orientation of the drug in the intercalation site with the quaternizing ethyl piperidine chain protruding in the major groove is proposed.     

High field 1H-NMR analysis of the 1:1 intercalation complex of the antitumor agent mitoxantrone and the DNA duplex [d(CpGpCpG)

Complete 1H-nmr assignment has been achieved of the stoichiometric 1:1 complex of the antitumor agent mitoxantrone with the duplex oligomer [d(CpGpCpG)]2. The techniques used included 2D-COSY, 1D-NOE and 2D-HH-INADEQUATE. Comparisons of 1H and 13C chemical shift changes upon addition of drug suggest symmetrical intercalative binding to the center of the tetramer. NOE difference measurements and 31P studies suggest binding of the terminal OH groups of the side chains to the central phosphate groups such that the methylene groups are proximate to C(3)6, C(3)6 and G(4)8 base protons all in the major groove. The data suggest that the side chains bind to the neighboring base pairs from the intercalation site. This is in accord with independent evidence of G,C base preference for binding from spectroscopic and electron microscopy studies.     

1H- and 31P-NMR studies of ditercalinium binding to a d(GCGC)2 and d(CCTATAGG)2 minihelices: a sequence specificity study

The structures of the complexes formed in aqueous solution between ditercalinium, a bis-intercalating drug, and both the self-complementary tetranucleotide d(GCGC)2 and octanucleotide d(CCTATAGG)2, have been investigated by 400-MHz 1H-nmr and 162-MHz 31P-nmr. All the nonexchangeable protons, as well as the exchangeable imino protons and the phosphorus signals, have been assigned. Both oligonucleotides have been shown to adopt a right-handed B-DNA type structure. The addition of ditercalinium to the oligonucleotides lead to the formation of complexes in slow exchange at the nmr time scale with the free helices. At all drug-to-helix ratios studied, the ditercalinium was found in the bound form, whereas free and complexed oligonucleotides were in slow exchange, allowing resonance assignments through two-dimensional chemical exchange experiments. for d(GCGC)2 the strong upfield shifts induced on all aromatic protons of both the bases and the drug by complexation with ditercalinium suggest an interaction by intercalation of the two rings. However, the loss of twofold symmetry upon binding, as well as the chemical shift variation of the drug proton signals of one of the chromophores with temperature and concentration, favor a model in which the drug-nucleotide complexes have one ring of the drug intercalated and the other stacked on top of the external base pair. The intermolecular contacts between drug protons and nucleotide protons give a defined geometry for complexation that is consistent with the proposed model. In contrast, with d(CCTATAGG)2 several drug-nucleotide complexes were formed and a large increase in line broadening was observed at high drug-to-DNA ratios, precluding a detailed analysis of these complexes. However, the large upfield shift in the imino proton resonances together with the shielding of the ditercalinium ring protons favor a model with bis-intercalation of ditercalinium. This model is supported by the downfield shift of at least 4 out of 14 phosphorus signals. The results are compared with those obtained on ditercalinium binding to the homologous sequences d(CGCG)2 and d(TTCGCGAA)2, and discussed in terms of sequence specificity.     

High Field 1H-NMR Analysis of the 1:1 Intercalation Complex of the Antitumor Agent Mitoxantrone and the DNA Duplex [d(CpGpCpG)]2

Abstract

Complete ¹H-nmr assignment has been achieved of the stoichiometric 1:1 complex of the antitumor agent mitoxantrone with the duplex oligomer [d(CpGpCpG)]₂. The techniques used included 2D-COSY, 1D-NOE and 2D-HH-INADEQUATE. Comparisons of ¹H and ¹³C chemical shift changes upon addition of drug suggest symmetrical intercalative binding to the center of the tetramer. NOE difference measurements and ³¹P studies suggest binding of the terminal OH groups of the side chains to the central phosphate groups such that the methylene groups are proximate to C(3)6, C(3)6 and G(4)8 base protons all in the major groove. The data suggest that the side chains bind to the neighboring base pairs from the intercalation site. This is in accord with independent evidence of G,C base preference for binding from spectroscopic and electron microscopy studies.     

DNA sequence recognition by the antitumor drug ditercalinium

The antitumor drug ditercalinium is a rare example of a noncovalent DNA-binding ligand that forms bisintercalation complexes via the major groove of the double helix. Previous structural studies have revealed that the two connected pyridocarbazolium chromophores intercalate into DNA with the positively charged bis(ethylpiperidinium) linking chain oriented to the wide groove side of the helix. Although the interaction of ditercalinium with short oligonucleotides containing 4-6 contiguous GC base pairs has been examined in detail by biophysical and theoretical approaches, the sequence preference for ditercalinium binding to long DNA fragments that offer a wide variety of binding sites has been investigated only superficially. Here we have investigated both sequence preferences and possible molecular determinants of selectivity in the binding of ditercalinium to DNA, primarily using methods based upon DNase I footprinting. A range of multisite DNA substrates, including several natural restriction fragments and different PCR-generated fragments containing unconventional bases (2,6-diaminopurine, inosine, uridine, 5-fluoro- and 5-methylcytosine, 7-deazaguanine, 7-deazaadenine, and N(7)-cyanoboranoguanine), have been employed to show that ditercalinium selectively recognizes certain GC-rich sequences in DNA and to identify some of the factors which affect its DNA-binding sequence selectivity. Specifically, the footprinting data have revealed that the 2-amino group on the purines or the 5-methyl group on the pyrimidines is not essential for the formation of ditercalinium-DNA complexes whereas the major groove-oriented N(7) of guanine does appear as a key element in the molecular recognition process. The loss of N(7) at guanines but not adenines is sufficient to practically abolish sequence-selective binding of ditercalinium to DNA. Thus, as expected for a major groove binding drug, the N(7) of guanine is normally required for effective complex formation with GC base pairs, but interestingly the substitution of the N(7) with a relatively bulky cyanoborane group does not markedly affect the sequence recognition process. Therefore, the hydrogen bond accepting capability at N(7) of guanines is not sufficient to explain the GC-selective drug-DNA association, and the implications of these findings are considered.     

Theoretical study of the geometrical arrangement of GT and GA wobble pairs in two short duplexes, Proton NMR chemical shifts and interaction energy calculations

NMR shielding constants are calculated for the base protons of duplexes formed by the dodecamer d(CGTGAATTCGCG) and the decamer d(CCAAGATTGG). A good agreement with experimental data is obtained for B-DNA helices in which the wobble GT and GA pairs are in the plane of the corresponding GC pairs of the parent duplexes formed by d(CGCGAATTCGCG) and d(CCAAGCTTGG), if the glycosyl bonds of T and G or A and G are symmetrical with respect to the dyad axis of the Watson-Crick GC pair. Interaction energy calculations show that this type of geometrical arrangement, which implies a distortion of the ribonphosphate backbone of both strands of the duplexes are more stable than those in which only one strand has its conformation modified by the presence of the wobble pair. For the duplex containing the GA pair, NMR chemical shifts as well as interaction energy computations favour the Watson-Crick hydrogen bonding scheme. The variation of the different contributions (intrastrand, interstrand, pair-pair) to the interaction energy between the bases of the duplexes, with the geometrical arrangement of the wobble pairs, is reported.     

The DNA sequence at echinomycin binding sites determines the structural changes induced by drug binding: NMR studies of echinomycin binding to [d(ACGTACGT)]2 and [d(TCGATCGA)]2

The complexes formed between the cyclic octadepsipeptide antibiotic echinomycin and the two DNA octamers [d(ACGTACGT)]2 and [d(TCGATCGA)]2 have been investigated by using one- and two-dimensional proton NMR spectroscopy techniques. The results obtained for the two complexes are compared to each other, to the crystal structures of related DNA-echinomycin complexes, and to enzymatic and chemical footprinting results. In the saturated complexes, two echinomycin molecules bind to each octamer by bisintercalation of the quinoxaline moieties on either side of each CpG step. Binding of echinomycin to the octamer [d(ACGTACGT)]2 is cooperative so that only the two-drug complex is observed at lower drug-DNA ratios, but binding to [d(TCGATCGA)]2 is not cooperative. At low temperatures, both the internal and terminal A.T base pairs adjacent to the binding site in the [d(ACGTACGT)]2-2 echinomycin complex are Hoogsteen base paired (Gilbert et al., 1989) as observed in related crystal structures. However, as the temperature is raised, the internal A.T Hoogsteen base pairs are destabilized and are observed to be exchanging between the Hoogsteen base-paired and an open (or Watson-Crick base-paired) state. In contrast, in the [d(TCGATCGA)]2-2 echinomycin complex, no A.T Hoogsteen base pairs are observed, the internal A.T base pairs appear to be stabilized by drug binding, and the structure of the complex does not change significantly from 0 to 45 degrees C. Thus, the structure and stability of the DNA in echinomycin-DNA complexes depends on the sequence at and adjacent to the binding site. While we conclude that no single structural change in the DNA can explain all of the footprinting results, unwinding of the DNA helix in the drug-DNA complexes appears to be an important factor while Hoogsteen base pair formation does not.     

Bisintercalation of ditercalinium into a d(CpGpApTpCpG)2 minihelix: a 1H- and 31P-NMR study

The structure of the complex formed in aqueous solution between ditercalinium, a bisintercalating drug, and the self-complementary hexanucleotide d(CpGpApTpCpG)2 is investigated by 400-MHz 1H-nmr and 162-MHz 31P-nmr. Whatever the drug to helix ratio, ditercalinium occurred in the bound form, whereas free and complexed hexanucleotide are in slow exchange. This allows unambiguous resonance assignment through two-dimensional chemical exchange experiments. The strong upfield shifts measured on most aromatic protons on both drug and bases as well as on DNA imino protons are consistent with bisintercalation of the dimer. Nuclear Overhauser effects observed between drug and nucleotide protons give a defined geometry for complexation, and suggest a DNA conformational change upon drug binding.     

NMR investigation of Hoogsteen base pairing in quinoxaline antibiotic--DNA complexes: comparison of 2:1 echinomycin, triostin A and [N-MeCys3,N-MeCys7] TANDEM complexes with DNA oligonucleotides.

Hoogsteen base pairs have been demonstrated to occur in base pairs adjacent to the CpG binding sites in complexes of triostin A and echinomycin with a variety of DNA oligonucleotides. To understand the relationship of these unusual base pairs to the sequence specificity of these quinoxaline antibiotics, the conformation of the base pairs flanking the YpR binding sites of the 2:1 drug-DNA complexes of triostin A with [d(ACGTACGT)]2 and of the TpA specific [N-MeCys3, N-MeCys7] TANDEM with [d(ATACGTAT)]2 have been studied by 1H NMR spectroscopy. In both the 2:1 triostin A-DNA complex and the 2:1 [N-MeCys3, N-MeCys7] TANDEM-DNA complex, the terminal A.T base pairs are Hoogsteen base paired with the 5' adenine in the syn conformation. This indicates that both TpA specific and CpG specific quinoxaline antibiotics are capable of inducing Hoogsteen base pairs in DNA. However, in both 2:1 complexes, Hoogsteen base pairing is limited to the terminal base pairs. In the 2:1 triostin A complex, the internal adenines are anti and in the 2:1 [N-MeCys3, N-MeCys7] TANDEM-DNA complex, the internal guanines are anti regardless of pH, which indicates that the central base pairs of both complexes form Watson-Crick base pairs. This indicates that the sequence dependent nature of Hoogsteen base pairing is the same in TpA specific and CpG specific quinoxaline antibiotic-DNA complexes. We have calculated a low resolution three-dimensional structure of the 2triostin A-[d(ACGTACGT)]2 complex and compared it with other CpG specific quinoxaline antibiotic-DNA complexes. The role of stacking in the formation of Hoogsteen base pairs in these complexes is discussed.     

Solution structural studies of the Ag(I)-DNA complex.

We report equilibrium dialysis and electric dichroism studies of the two strong complexes (I and II) of silver ion with DNA. Cooperative conversion of DNA to the stronger type I complex results in a 9% length decrease, and a structure in which intercalated ethidium is perpendicular to the helix axis. Upon addition of more Ag+ to form the type II complex, the DNA length reverts to its original value and bound ethidium once again becomes tilted from the plane perpendicular to the helix axis. In both type I and type II Ag (I) - DNA complexes, ethidium binding is mildly cooperative. We interpret the results in terms of a sequence of silver-induced cooperative switches of DNA from its B-form structure with propeller twisted base pairs to a structure with flat base pairs in the type I complex, and back again to propellered base pairs in the type II complex.     

A novel form of intercalation involving four DNA duplexes in an acridine-4-carboxamide complex of d(CGTACG)(2)

The structures of the complexes formed between 9-amino-[N-(2-dimethyl-amino)butyl]acridine-4-carboxamide and d(CG^5BrUACG)₂ and d(CGTACG)₂ have been solved by X-ray crystallography using MAD phasing methodology and refined to a resolution of 1.6 Å. The complexes crystallised in space group C222. An asymmetric unit in the brominated complex comprises two strands of DNA, one disordered drug molecule, two cobalt (II) ions and 19 water molecules (31 in the native complex). Asymmetric units in the native complex also contain a sodium ion. The structures exhibit novel features not previously observed in crystals of DNA/drug complexes. The DNA helices stack in continuous columns with their central 4 bp adopting a B-like motif. However, despite being a palindromic sequence, the terminal GC base pairs engage in quite different interactions. At one end of the duplex there is a CpG dinucleotide overlap modified by ligand intercalation and terminal cytosine exchange between symmetry-related duplexes. A novel intercalation complex is formed involving four DNA duplexes, four ligand molecules and two pairs of base tetrads. The other end of the DNA is frayed with the terminal guanine lying in the minor groove of the next duplex in the column. The structure is stabilised by guanine N7/cobalt (II) coordination. We discuss our findings with respect to the effects of packing forces on DNA crystal structure, and the potential effects of intercalating agents on biochemical processes involving DNA quadruplexes and strand exchanges. NDB accession numbers: DD0032 (brominated) and DD0033 (native).     

A.T and C.C+ base pairs can form simultaneously in a novel multistranded DNA complex

Previous experiments have established that in certain synthetic oligomeric DNA sequences, including mixtures of d(AACC)5 with d(CCTT)5, adenine-thymine (A.T) base pairs form to the exclusion of neighboring protonated cytosine-cytosine (C.C+) base pairs [Edwards, E., Ratliff, R., & Gray, D. (1988) Biochemistry 27, 5166-5174]. In the present work, circular dichroism and other measurements were used to study DNA oligomers that represented two additional classes with respect to the formation of A.T and/or C.C+ base pairs. (1) One class included two sets of repeating pentameric DNA sequences, d(CCAAT)3-6 and d(AATCC)4,5. For both of these sets of oligomers, an increase in the magnitude of the long-wavelength positive CD band centered at about 280 nm occurred as the pH was lowered from 7 to 5 at 0.1 and 0.5 M Na+, indicating that C.C+ base pairs formed. Even though it may have been possible for these oligomers to form duplexes with two antiparallel A.T base pairs per pentamer, no A.T base pairing was detected by monitoring the CD changes at 250 nm. Thus, spectral data showed that as few as 40% C.C+ base pairs were stable in two sets of oligomers in which A.T base pairs did not form adjacent to, or in place of, C.C+ base pairs. (2) Another class of oligomer was represented by d(C4A4T4C4), which was studied by CD, HPLC, and centrifugation experiments. We confirmed previous work that this sequence was able to form both types of base pairs as the pH and temperature were lowered [Gray, D., Cui, T., & Ratliff, R. (1984) Nucleic Acids Res. 12, 7565-7580].(ABSTRACT TRUNCATED AT 250 WORDS)     

Proton exchange and internal motions in two chromomycin dimer-DNA oligomer complexes.

Previous structural studies on the complexes of the chromomycin (CHR) dimer with duplexes of d(A1-A2-G3-G4-C5-C6-T7-T8) and of d(A1-G2-G3-A4-T5-C6-C7-T8) in solution [one Mg(II) and two drugs per duplex] are extended to hydrogen exchange measurements. Exchange of the OH8 proton of chromomycin, measured by real time proton-deuterium exchange, is very slow and requires dissociation of the complex, whose lifetime is thus determined. The lifetimes and apparent dissociation constants of base pairs are deduced from the catalysis of imino proton exchange by ammonia. The four central base pairs, which interact with the CHR chromophores in the minor groove (Gao & Patel, 1990), may open within the complex, but the opening rate is less than in the free duplex by one to two orders of magnitude. The activation energy for base-pair opening and the differences between the lifetimes of adjacent pairs suggest that single base-pair opening is the predominant imino proton exchange pathway in all cases. In the symmetrical complex of chromomycin with the first duplex, the lifetimes of the central base pairs (G3.C6 and G4.C5) are in the same range (52 and 29 ms, respectively, at 38 degrees C). In the asymmetrical complex formed with the second duplex, the base-pair lifetimes in the G2-G3-A4-T5 segment that interacts with the chromophore moiety are strongly increased. That of G3.C6 is particularly long. Above 50 degrees C, exchange of the G3 imino proton is opening limited.(ABSTRACT TRUNCATED AT 250 WORDS)     

The solution structure of the Sac7d/DNA complex: a small-angle X-ray scattering study.

Small-angle X-ray scattering has been used to study the structure of the multimeric complexes that form between double-stranded DNA and the archaeal chromatin protein Sac7d from Sulfolobus acidocaldarius. Scattering data from complexes of Sac7d with a defined 32-mer oligonucleotide, with poly[d(GC)], and with E. coli DNA indicate that the protein binds along the surface of an extended DNA structure. Molecular models of fully saturated Sac7d/DNA complexes were constructed using constraints from crystal structure and solution binding data. Conformational space was searched systematically by varying the parameters of the models within the constrained set to find the best fits between the X-ray scattering data and simulated scattering curves. The best fits were obtained for models composed of repeating segments of B-DNA with sharp kinks at contiguous protein binding sites. The results are consistent with extrapolation of the X-ray crystal structure of a 1:1 Sac7d/octanucleotide complex [Robinson, H., et al. (1998) Nature 392, 202-205] to polymeric DNA. The DNA conformation in our multimeric Sac7d/DNA model has the base pairs tilted by about 35 degrees and displaced 3 A from the helix axis. There is a large roll between two base pairs at the protein-induced kink site, resulting in an overall bending angle of about 70 degrees for Sac7d binding. Regularly repeating bends in the fully saturated complex result in a zigzag structure with negligible compaction of DNA. The Sac7d molecules in the model form a unique structure with two left-handed helical ribbons winding around the outside of the right-handed duplex DNA.     

Base tilt of B-form poly[d(G)]-poly[d(C)] and the B- and Z-conformations of poly[d(GC)]-poly[d(GC)] in solution

We have measured the CD, isotropic absorption, and linear dichroism (LD) in the vacuum-uv spectral region for the B-conformations of poly[d(G)]-poly[d(C)] and poly[d(GC)]-poly[d(GC)], and for the Z-conformation of poly[d(GC)]-poly[d(GC)] formed in 70% trifluoroethanol. The reduced dichroism (LD divided by isotropic absorption) for all conformations varied with wavelength, indicating that the bases are not perpendicular to the helix axis. Since the directions of the transition dipoles are known, the inclinations and axes of inclination of each base can be determined from the wavelength dependence of the reduced dichroism spectra. The results indicate that the base normals of the (G + C) polymers in the B- and Z-conformations are tilted at angles greater than 19° with respect to the helix axis. The guanine and cytosine bases have different inclinations, and the tilt axes are not parallel. Therefore, the bases for all the (G + C) polymer conformations studied are buckled and propeller twisted.     

Interaction of a macrocyclic bisacridine with DNA

The binding of the macrocycle SDM to DNA was investigated by visible spectroscopy, stopped-flow kinetics, and NMR spectroscopy. SDM is composed of two 9-aminoacridines linked via the amino groups by a spermine side chain and via the 4-positions by a N,N'-[(methylthio)ethyl]succinamide side chain [Zimmerman, S. C., Lamberson, C. R., Cory, M., & Fairley, T. A. (1989) J. Am. Chem. Soc. 111, 6805-6809]. The visible spectrum of SDM bound to poly[d(A-T)]2 or poly[d(G-C)]2 is red-shifted relative to the spectrum of SDM alone and displays considerable hypochromicity. Results from titrations of SDM with polymer indicate a binding site size of three base pairs per macrocycle. The dissociation constant for SDM bound to either poly[d(A-T)]2 or poly[d(G-C)]2 is an order of magnitude lower than that for a similar bisacridine linked only by a spermine side chain. In addition, the dependence of the dissociation constant on ionic strength is significantly reduced. NMR studies of SDM complexes with poly[d(A-T)]2 or a tetramer, d(CGCG)2, show that intercalation is the mode of binding. The magnitudes of the chemical shift differences for SDM aromatic protons in the free and bound states support intercalation with the acridine ring systems essentially parallel to the long axis of the base pairs. Cross peaks from NOESY spectra of the SDM complex with d(CGCG)2 further support this mode of binding and provide information on the structure of the complex. The results are analyzed for consistency with each of three binding models: (i) bisintercalation with the two side chains in the same groove; (ii) bisintercalation according to the neighbor-exclusion principle with the two side chains in opposite grooves; and (iii) bisintercalation with two side chains in opposite grooves but with violation of the neighbor-exclusion principle. Model i is found to be unlikely on the basis of all evidence obtained, including preliminary modeling studies. Both models ii and iii can be reconciled with the experimental evidence and from a modeling standpoint are energetically feasible.