Folding of the prion peptide GGGTHSQW around the copper(II) ion: identifying the oxygen donor ligand at neutral pH and probing the proximity of the tryptophan residue to the copper ion

The GGGTHSQW sequence in the amyloidogenic part of the prion protein is a potential binding site for Cu(II). We have previously studied the binding of copper to the shorter GGGTH peptide and showed that it is highly pH dependent (Hureau et al. in J. Biol. Inorg. Chem. 11:735–744, 2006). Two predominant complexes could be characterized at pH 6.7 and 9.0 with equatorial binding modes of 3N1O and 4N for the metal ion, respectively. In this work, we have further investigated the coordination of Cu(II) to the GGGTH peptide as well as the longer GGGTHSQW peptide in order to identify the oxygen donor ligand at neutral pH and to study the proximity and redox activity of the tryptophan residue of the latter. The results for both peptides show that, at pH 6.7, Cu(II) is coordinated by a carbonyl peptide backbone. At higher pH values, the carbonyl ligand dissociates and the coordination changes to a 4N binding mode, inducing a structural rearrangement that brings the GGGTHSQW peptide’s tryptophan residue into the vicinity of the copper ion, thus affecting their respective redox properties.     

Sequence and length dependent thermodynamic differences in heterocyclic diamidine interactions at AT base pairs in the DNA minor groove

With the goal of developing a better understanding of the antiparasitic biological action of DB75, we have evaluated its interaction with duplex alternating and nonalternating sequence AT polymers and oligomers. These DNAs provide an important pair of sequences in a detailed thermodynamic analysis of variations in interaction of DB75 with AT sites. The results for DB75 binding to the alternating and nonalternating AT sequences are quite different at the fundamental thermodynamic level. Although the Gibbs energies are similar, the enthalpies for DB75 binding with poly(dA).poly(dT) and poly(dA-dT).poly(dA-dT) are +3.1 and -4.5 kcal/mol, respectively, while the binding entropies are 41.7 and 15.2 cal/mol.K, respectively. The underlying thermodynamics of binding to AT sites in the minor groove plays a key role in the recognition process. It was also observed that DB75 binding with poly(dA).poly(dT) can induce T.A.T triplet formation and the compound binds strongly to the dT.dA.dT triplex.     

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

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

DNA molecular recognition and cellular selectivity of anticancer metal(II) complexes of ethylenediaminediacetate and phenanthroline: multiple targets

Abstract  

By inhibiting only two or three of 12 restriction enzymes, the series of [M(phen)(edda)] complexes [M(II) is Cu, Co, Zn; phen is 1,10-phenanthroline; edda is N,N′-ethylenediaminediacetate] exhibit DNA binding specificity. The Cu(II) and Zn(II) complexes could differentiate the palindromic sequences 5′-CATATG-3′ and 5′-GTATAC-3′, whereas the Co(II) analogue could not. This and other differences in their biological properties may arise from distinct differences in their octahedral structures. The complexes could inhibit topoisomerase I, stabilize or destabilize G-quadruplex, and lower the mitochondrial membrane potential of MCF7 breast cells. The pronounced stabilization of G-quadruplex by the Zn(II) complex may account for the additional ability of only the Zn(II) complex to induce cell cycle arrest in S phase. On the basis of the known action of anticancer compounds against the above-mentioned individual targets, we suggest the mode of action of the present complexes could involve multiple targets. Cytotoxicity studies with MCF10A and cisplatin-resistant MCF7 suggest that these complexes exhibit selectivity towards breast cancer cells over normal ones.     

Triple helix formation at (AT)n adjacent to an oligopurine tract.

We have used DNase I footprinting to investigate the recognition of (AT) n tracts in duplex DNA using GT-containing oligonucleotides designed to form alternating G.TA and T.AT triplets. Previous studies have shown that the formation of these complexes is facilitated by anchoring the triplex with a block of adjacent T.AT triplets, i.e. using T11(TG)6to recognize the target A11(AT)6. (AT)6T11. In the present study we have examined how the stability of these complexes is affected by the length of either the T.AT tract or the region of alternating G.TA and T.AT triplets, using oligonucleotides of type T x (TG) y to recognize the sequence A11(AT)11. We find that successful triplex formation at (AT)n (n = 3, 6 or 11) can be achieved with a stabilizing tail of 11xT.AT triplets. The affinity of the third strand increases with the length of the (GT) n tract, suggesting that the alternating G.TA and T.AT triplets are making a positive contribution to stability. These complexes are stabilized by the presence of manganese or a triplex-specific binding ligand. Shorter oligo-nucleotides, such as T7(TG)5, bind less tightly and require the addition of a triplex-binding ligand. T4(GT)5showed no binding under any conditions. Oligo-nucleotides forming a 3'-terminal T.AT are marginally more stable that those with a terminal G.TA. The stability of these complexes was further increased by replacing two of the T.AT triplets in the T n tail region with two C+.GC triplets.     

Synthesis and properties of different metal complexes of the siderophore desferriferricrocin

Desferriferricrocin is a cyclic hexa-peptide siderophore with three hydroxamates as primary coordination groups. It forms metal complexes with Fe(III), Cr(III), Al(III), Ga(III), Cu(II), and Zn(II). These complexes were prepared and characterized using UV–vis, circular dichroism spectroscopy (CD), nuclear magnetic resonance spectroscopy (NMR), and electrospray ionization mass spectroscopy (ESI-MS). The mononuclear trivalent metal complexes of desferriferricrocin were stable in aqueous solutions, and their coordination centers primarily adopted the Λ configuration. The formation of multinuclear complexes of desferriferricrocin was determined by ESI-MS. Desferriferricrocin was able to bind up to three Cu(II) and two Zn(II) respectively. Heteronuclear complexes containing one trivalent and one divalent were also determined. In these complexes, amide nitrogens were utilized as alternative binding groups of desferriferricrocin in addition to the primary binding groups, the hydroxamates. Published online December 2004     

Interaction of copper(II) with the non-steroidal anti-inflammatory drugs naproxen and diclofenac: synthesis, structure, DNA- and albumin-binding

Copper(II) complexes with the non-steroidal anti-inflammatory drugs (NSAIDs) naproxen and diclofenac have been synthesized and characterized in the presence of nitrogen donor heterocyclic ligands (2,2′-bipyridine, 1,10-phenanthroline or pyridine). Naproxen and diclofenac act as deprotonated ligands coordinated to Cu(II) ion through carboxylato oxygens. The crystal structures of (2,2′-bipyridine)bis(naproxenato)copper(II), , (1,10-phenanthroline)bis(naproxenato)copper(II), and bis(pyridine)bis(diclofenac)copper(II), have been determined by X-ray crystallography. The UV study of the interaction of the complexes with calf-thymus DNA (CT DNA) has shown that the complexes can bind to CT DNA with (2,2′-bipyridine)bis(naproxenato)copper(II) exhibiting the highest binding constant to CT DNA. Competitive study with ethidium bromide (EB) indicates that the complexes can displace the DNA-bound EB suggesting strong competition with EB. The cyclic voltammograms of the complexes recorded in the presence of CT DNA have shown that the complexes can bind to CT DNA by the intercalative binding mode which has also been verified by DNA solution viscosity measurements. The NSAID ligands and their complexes exhibit good binding propensity to human or bovine serum albumin protein having relatively high binding constant values. The biological properties of the previously reported complexes [Cu₂(naproxenato)₄(H₂O)₂], [Cu₂(diclofenac)₄(H₂O)₂] and [Cu(naproxenato)₂(pyridine)₂(H₂O)] have been also evaluated. The dinuclear complexes exhibit similar affinity for CT DNA as the 2,2′-bipyridine or 1,10-phenanthroline containing complexes. The pyridine containing complexes exhibit the lowest affinity for CT DNA and the lowest ability to displace EB from its EB-DNA complex.     

DNA-fiber EPR spectroscopy as a tool to study DNA-metal complex interactions: DNA binding of hydrated Cu(II) ions and Cu(II) complexes of amino acids and peptides

DNA-fiber EPR spectroscopy and its application to studies of the DNA binding orientation and dynamic properties of Cu(II) ions and their complexes with amino acids and peptides are reviewed. Cu(II) ions bind in at least two different binding modes; one mode was mobile while the other mode fixed the orientation of the coordination plane. The hydroxyl groups of L-Ser and L-Thr fixed the coordination plane of their respective Cu(II) complexes parallel to the DNA base pair plane, whereas Cu(II) complexes of Lys and Arg induced several binding modes, depending on the tertiary structure of the DNA and the chirality of the amino acids. Unusually broadened signals observed for the His complex were assigned to a mono-L-His complex stacked stereospecifically along the DNA double helix. In comparison, Cu(II). Xaa-Xaa' -His type complexes oriented in the minor groove with different affinities and extents of randomness depending on the Xaa-Xaa' sequence and the chirality of Xaa or Xaa' while the C-terminal Xaa residues in Cu(II).Arg-Gly-His-Xaa (Xaa=L-Leu or L-Glu) decreased the stereospecificity and the stability of the complexes bound to DNA. In contrast to Xaa-Xaa'- His complexes, the coordination planes of Cu(II).Gly-L-His-Gly and Cu(II).Gly-L-His-L-Lys complexes were found to lie parallel to the DNA-fiber axis. Dinuclear Cu(II).carnosine complexes were also shown to bind to DNA stereospecifically.     

An examination of the binding behavior of histidine-containing peptides with immobilized metal complexes derived from the macrocyclic ligand, 1,4,7-triazacyclononane

In this study, two different experimental approaches have been employed to examine the binding behavior of histidine-containing peptides with metal ion complexes derived from the macrocyclic ligand 1,4,7-triazacyclononane (tacn). Firstly, a molecular modeling approach has been employed to derive the strain energies for test peptide sequences that have a predicted propensity to readily adopt an α-helical conformation. To this end, binuclear metal complexes were examined with peptides containing two histidine residues in different locations in a pair of peptides of the same composition but different sequence. These modeling results indicate that there are no energetic constraints for two-point binding to occur with dicopper(II) binuclear complexes when two histidine residues are appropriately placed in an α-helical conformation. Secondly, binding experiments were carried out to establish the effect of one or more histidine residues within a peptide sequence on the affinity of a peptide for these Cu(II)–tacn derived binuclear complexes when immobilized onto a chromatographic support material. The results confirm that for all chelating systems, higher affinity is achieved as the histidine number in the peptide structure increases, although the relative location of the histidine residues in these small peptides did not introduce a significant constraint to the conformation on interacting with the immobilized Cu(II) binuclear complexes.     

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

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

Differential sequence dynamics of homopolymeric and alternating AT tracts in a small plasmid DNA

The location of OsO4 bispyridine hyper- and hyporeactivity in a small deletion derivative of plasmid ColE1 (PTC12, 1727 bp) has been determined for approximately 70% of the molecule. Thymine bases in homopolymeric (dA)n.(dT)n tracts (n greater than or equal to 4) were always found to be resistant toward OsO4 modification. DNA supercoiling did not destabilize these tracts. The extent of OsO4 bispyridine reactivity of homopolymeric (dA)n.(dT)n tracts, where n = 3, was found to be dependent on the rate of base unpairing of the sequence immediately 5' and 3' to the tract. Repressed OsO4 reactivity of thymine bases in (dA)3.(dT)3 tracts was observed if immediately both 5' and 3' to the tract were stable DNA sequences composed of GC base pairs and/or a homopolymeric (dA)n.(dT)n tract (n greater than or equal to 4). Homopolymeric tracts of n = 3 not having adjacent sequences with repressed unpairing rates did not show reduced levels of OsO4 bispyridine reactivity. Alternating d(TA)n tracts (n greater than or equal to 2) were found to exhibit hyperreactivity with OsO4. The extent of this hyperreactivity was dependent on the length of the tract and superhelical torsional stress. The distribution and frequency of homopolymeric (dA)n.(dT)n (n greater than or equal to 4) tracts in Escherichia coli promoter sequences were examined, and the possible implications of these tracts on promoter function are discussed.     

Interaction of echinomycin with An.Tn. and (AT)n regions flanking its CG binding site.

We have prepared DNA fragments containing the sequences A15CGT15, T15CGA15 and T(AT)8CG(AT)15 cloned within the SmaI site of the pUC19 polylinker. These have been used as substrates in footprinting experiments with DNase I and diethylpyrocarbonate probing the effects of echinomycin, binding to the central CG, on the structure of the surrounding sequences. No clear DNase I footprints are seen with T15CGA15 though alterations in the nuclease susceptibility of surrounding regions suggest that the ligand is binding, albeit weakly at this site. All the other fragments show the expected footprints around the CG site. Regions of An and Tn are rendered much more reactive to DNase I and adenines on the 3'-side of the CG become hyperreactive to diethylpyrocarbonate. Regions of alternating AT show unusual changes in the presence of the ligand. At low concentrations (5 microM) cleavage of TpA is enhanced, whereas at higher concentrations a cleavage pattern with a four base pair repeat is evident. A similar pattern is seen with micrococcal nuclease. Modification by diethylpyrocarbonate is strongest at alternate adenines which are staggered in the 5'-direction across the two strands. We interpret these changes by suggesting secondary drug binding within regions of alternating AT, possibly to the dinucleotide ApT. DNase I footprinting experiments performed at 4 degrees C revealed neither enhancements nor footprints for flanking regions of homopolymeric A and T suggesting that the conformational changes are necessary consequence of drug binding.     

Effect of 3-5 monocyclizations of angiotensin II and 4-aminoPhe6-Ang II on AT2 receptor affinity

The endogenous angiotensin II (Ang II) and the synthetic AT(2) selective agonist 4-aminoPhe(6)-Ang II respond very differently to identical cyclizations. Cyclizations of Ang II by thioacetalization, involving the 3 and 5 amino acid residue side chains, provided ligands with almost equipotent binding affinities to Ang II at the AT(2) receptor. In contrast, the same cyclization procedures applied on the AT(2) selective 4-aminoPhe(6)-Ang II delivered significantly less potent AT(2) receptor ligands, although the AT(2)/AT(1) selectivity was still very high. The fact that different structure-activity relationships are observed after imposing conformational restrictions on Ang II and 4-aminoPhe(6)-Ang II, respectively, suggests that the peptides, despite large similarities might adopt quite different backbone conformations when binding to the AT(2) receptor.     

Preferential binding of quinolones to DNA with alternating G,C / A,T sequences: a spectroscopic study

The binding of quinolones, nalidixic acid (Nal), oxolinic acid (Oxo) with double stranded polynucleotides was undertaken by using UV-melting, UV-Vis absorption, fluorescence and CD spectroscopic techniques. The binding of Nal or Oxo to the polynucleotides under low-salt buffer conditions were determined for poly (dA).(dT), poly [d(A-T)], poly (dG).(dC), poly [d(G-C)] and E. coli DNA. The fluorescence data were analyzed using a previously established two step mechanism with two different DNA-Drug complexes [Rajeswari et al., Biochemistry 26, 6825-31 (1987)]. The first complex [DN](1) with a binding constant K(1), is formed where the interactions are 'nonspecific' and complex [DN](2) with a binding constant K(2), is formed where the interactions are "specific" which involve (additional) hydrophobic type of interactions like 'stacking' of the drug and the overall association constant is represented as K(=K(1)K(2)). The order of binding for Nal and Oxo is: poly [d(G-C)] > poly [d(A- T)] > E. coli > poly (dG).(dC) > poly (dA).(dT). Interaction of quinolones seems to be preferential in the alternating G, C or A, T stretches of DNA than those of non-alternating. Within any alternating or non-alternating in DNA sequences the G, C rich sequences have distinctly greater binding than A, T sequences. The overall association constant data (K) reveal higher binding of Oxo to DNA compared to Nal to any given polynucleotide investigated; which also explains the higher antibacterial potency of Oxo. Changes in the absorption difference spectra and in circular dichroic spectra also manifest these results. As the melting temperatures of the polynucleotides were only marginally raised in presence of the quinolone, we rule out the possibility of 'classical intercalation' of the drug. Amino group of guanine facilitates the binding of quinolones and therefore has the greater binding with the DNA. However, poly (dG).(dC) is known to exist in 'A' conformation which is not adopted by quinolones as in the case of poly (dA).(dT). Present results suggest that Nal or Oxo bind to DNA in a non-classical fashion which is partially stacking in nature.     

Two Binding Modes of Netropsin are Involved in the Complex Formation with Poly(dA-dT)·Poly(dA-dT) and other Alternating DNA Duplex Polymers

Abstract

Using CD measurements we show that the interaction of netropsin to poly(dA-dT)·poly(dA-dT) involves two binding modes at low ionic strength. The first and second binding modes are distinguished by a defined shift of the CD maximum and the presence of characteristic isodichroic points in the long wavelength range from 313 nm to 325 nm. The first binding mode is independent of ionic strength and is primarily determined by specific interaction to dA·dT base pairs. Employing a netropsin derivative and different salt conditions it is demonstrated that ionic contacts are essential for the second binding mode. Other alternating duplexes and natural DNA also exhibit more or less a second step in the interaction with netropsin observable at high ratio of ligand per nucleotide. The second binding mode is absent for poly(dA)·poly(dT). The presence of a two-step binding mechanism is also demonstrated in the complex formation of poly(dA-dT)·poly(dA-dT) with the distamycin analog consisting of pentamethylpyrrolecarboxamide. While the binding mode I of netropsin is identical with its localization in the minor groove, for binding mode II we consider two alternative interpretations.     

Local enrichment with homopolymeric (dA/dT) DNA in genomes of some lower dipterans and Drosophila melanogaster

An investigation into the chromosomal localization of homopolymeric dA/dT was carried out with species of the genera Rhynchosciara, Chironomus, Drosophila and several other taxa. In situ hybridisation probing mitotic and polytene chromosomes with RNA homopolymers was performed, followed by immunological detection of the DNA/RNA hybrid. Use of this method allowed us to assess specific regions of some dipteran genomes, where the signal was generally, but not always, located in heterochromatic regions. Human and Drosophila chromosome regions known to contain dA/dT runs of up to 153 bp were devoid of consistent labelling. The stability of the rA/dT hybrid formed in situ was in agreement with the T(m) for long rA/dT hybrid complexes, suggesting that the method used in this work is able to identify unusually long homopolymeric dA/dT tracts.     

The preferential binding of histone H1 to DNA scaffold-associated regions is determined by its C-terminal domain

Histone H1 preferentially binds and aggregates scaffold-associated regions (SARs) via the numerous homopolymeric oligo(dA).oligo(dT) tracts present within these sequences. Here we show that the mammalian somatic subtypes H1a,b,c,d,e and H1° and the male germline-specific subtype H1t, all preferentially bind to the Drosophila histone SAR. Experiments with the isolated domains show that whilst the C-terminal domain maintains strong and preferential binding, the N-terminal and globular domains show weak binding and poor specificity for the SAR. The preferential binding of SAR by the H1 molecule thus appears to be determined by its highly basic C-terminal domain. Salmine, a typical fish protamine, which could have its evolutionary origin in histone H1, also shows preferential binding to the SAR. The interaction of distamycin, a minor groove binder with high affinity for homopolymeric oligo(dA).oligo(dT) tracts, abolishes preferential binding of the C-terminal domain of histone H1 and protamine to the SAR, suggesting the involvement of the DNA minor groove in the interaction.     

Transfer RNA bindings to antitumor estradiol-platinum(II) hybrid and cisplatin

The anticancer platinum (Pt) drugs exert their antitumor activity by direct or indirect Pt-DNA binding. It has been shown that Pt drugs can induce major DNA damage and minor RNA damage during cancer treatment. A recent report showed that a new anticancer estradiol-Pt(II) hybrid molecule (CD-37) binds DNA bases indirectly, while being more effective than cis-diaminedichloroplatinum(II) (cisplatin) against several types of cancer. In this report, we examine the bindings of CD-37 and cisplatin drugs with transfer RNA (tRNA) in vitro and compare the results to those of the corresponding Pt-DNA complexes. Solutions containing various CD-37 or cisplatin concentrations were reacted with tRNA at physiological pH. Using Fourier transform infrared (FTIR), UV-visible, and circular dichroism spectroscopic methods, the drug binding mode, the binding constant, and RNA structural variations are determined for Pt-tRNA complexes in aqueous solution. Structural analysis showed direct binding of cisplatin drug to guanine and adenine N7 sites, while both direct and indirect interactions of CD-37 with tRNA bases and the backbone phosphate group were observed. The overall binding constants estimated were K(CD-37) = 2.77 (+/-0.90) x 10(4) M(1) and K(cisplatin) = 1.72 (+/-0.50) x 10(4) M(1). Major aggregation of tRNA occurs at high CD-37 concentrations, while RNA remains in the A-family structure.     

Optimization of Cross-Linked Lexitropsins

Abstract

In attempts to optimize the cross-linked lexitropsin design, a number of cross-linked dimers composed of two tris(N-methylpyrrolecarboxamide) strands were synthesized and their binding interactions with poly d(A)? poly d(T) and poly d(A-T)?poly d(A-T) were characterized by circular dichroism and ethidium fluorometry. While all alkanediyl-linked dimers showed a similar binding behavior to the homo AT polymer, particularly at low ligand concentrations, the decanediyl linker was found to be the optimal linker permitting the bidentate anti parallel side-by-side binding of the corresponding dimer to the alternating AT polymer. Thus, in comparison with the monomer, the decanediyl-linked dimer has a binding strength enhancement of about 1400 times in the I: I binding mode. Moreover, the hydrophilicity of the linker has a significant effect on the bidentate binding strength. The (3,6)-dioxaoctanediyl-linked dimer has a further binding strength enhancement of 10 times over the decanediyl-linked dimer. Overall, the best optimized dimer has a binding strength enhancement of over 14,000 times in comparison with the monomer in the I: I binding mode. This binding enhancement parallels that observed in the best optimized bisintercalators. Distance-restrained molecular modeling provides support for the experimental results. Dimers of longer linkers can readily accommodate a bidentate anti parallel side-by-side binding mode but those of shorter linkers necessitate marked structural distortions in the bound ligand molecules. It is further observed that the binding strength enhancement to the alternating AT polymer is not always accompanied by the binding specificity improvement. Our analysis suggests that the non-specific appendage-DNA backbone interaction is a key factor that controls the specificity improvement.