Structural analysis of the binding modes of minor groove ligands comprised of disubstituted benzenes

Benzothiazole-based cyanines as fluorescent "light-up" probes for duplex and quadruplex DNA

Analogs of benzothiazole orange (BO) with one, two or three methylbenzothiazolylmethylidene substituents in the 1-methylpyridinium ring were obtained from the respective picolinium, lutidinium or collidinium salts. Fluorescence parameters of the known and new dyes in complexes with various DNA structures, including G-quadruplexes (G4s) and i-motifs (IMs), were analyzed. All dyes efficiently distinguished G4s and ss-DNA. The bi- and tri-substituted derivatives had basically similar distributions of relative fluorescence intensities. The mono-substituted derivatives exhibited enhanced sensitivity to parallel G4s. All dyes were particularly sensitive to a G4 structure with an additional duplex module (the thrombin-binding aptamer TBA31), presumably due to a distinctive binding mode (interaction with the junction between the two modules). In particular, BO showed a strong (160-fold) enhancement in fluorescence quantum yield in complex with TBA31 compared to the free dye. The fluorescence quantum yields of the 2,4-bisubstituted derivative in complex with well-characterized G4s from oncogene promoters were in the range of 0.04-0.28, i.e. comparable to those of ThT. The mono/bi-substituted derivatives should be considered as possible light-up probes for G4 formation.

Superstructure-Dependent Loading of DNA Origami Nanostructures with a Groove-Binding Drug

DNA origami nanostructures are regarded as powerful and versatile vehicles for targeted drug delivery. So far, DNA origami-based drug delivery strategies mostly use intercalation of the therapeutic molecules between the base pairs of the DNA origami's double helices for drug loading. The binding of nonintercalating drugs to DNA origami nanostructures, however, is less studied. Therefore, in this work, we investigate the interaction of the drug methylene blue (MB) with different DNA origami nanostructures under conditions that result in minor groove binding. We observe a noticeable effect of DNA origami superstructure on the binding affinity of MB. In particular, non-B topologies as for instance found in designs using the square lattice with 10.67 bp/turn may result in reduced binding affinity because groove binding efficiency depends on groove dimensions. Also, mechanically flexible DNA origami shapes that are prone to structural fluctuations may exhibit reduced groove binding, even though they are based on the honeycomb lattice with 10.5 bp/turn. This can be attributed to the induction of transient over- and underwound DNA topologies by thermal fluctuations. These issues should thus be considered when designing DNA origami nanostructures for drug delivery applications that employ groove-binding drugs.

Binding of a Flexibly-linked Dinuclear Ruthenium(II) Complex to Adenine-bulged DNA Duplexes

Using 1H NMR spectroscopy and molecular modelling, the DNA binding of a chiral dinuclear ruthenium(ii) complex {Δ,Δ-[{Ru(phen)2}2(μ-bb7)]4+; phen = 1,10-phenanthroline, bb7 = 1,7-bis[4(4′-methyl-2,2′-bipyridyl)]-heptane} involving a bridging ligand containing a flexible aliphatic chain has been studied. The binding of the ruthenium(ii) complex was examined with the non-self-complementary duplexes d(CCGAGAATCGGCC):d(GGCCGATTCCGG) (containing a single adenine bulge: designated SB) and d(CCGAGCCGTGCC):d(GGCACGAGCCGG) (containing two adenine bulge sites separated by two base-pairs: designated DB). The NMR data indicated that the ruthenium(ii) complex bound at the bulge site of SB, with one ruthenium centre located at the bulge site with the second metal centre binding with lower affinity and selectivity in the duplex region adjacent to the bulge site. Less specific binding is inferred from chemical shift changes of nucleotide protons two to five base pairs from the single adenine bulge. The ruthenium(ii) complex selectively bound the DB duplex with one metal centre located at each bulge site. The NMR results also suggested that the metal complex binding induced greater changes to the structure of the SB duplex, compared with the DB duplex. Modelling indicates the bridging ligand allowed each ruthenium(ii) metal centre to bind one adenine bulge of the doubly-bulged duplex without disrupting the DNA structure, using the additional torsional flexibility conferred by the aliphatic bridging ligand. However, the second ruthenium(ii) metal centre is not able to bind in the minor groove of the singly-bulged duplex without disrupting the structure, as the metal centre is too bulky. The results of this study suggest dinuclear ruthenium(ii) complexes have considerable potential as probes for DNA and RNA sequences that contain two bulge sites separated by a small number of base-pairs.

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.

Sequence-specific minor groove binding by bis-benzimidazoles: water molecules in ligand recognition

The binding of two symmetric bis-benzimidazole compounds, 2,2-bis-[4'-(3"-dimethylamino-1"-propyloxy)phenyl]-5,5-bi-1H-benzimidazole and its piperidinpropylphenyl analog, to the minor groove of DNA, have been studied by DNA footprinting, surface plasmon resonance (SPR) methods and molecular dynamics simulations in explicit solvent. The footprinting and SPR methods find that the former compound has enhanced affinity and selectivity for AT sequences in DNA. The molecular modeling studies have suggested that, due to the presence of the oxygen atom in each side chain of the former compound, a water molecule is immobilized and effectively bridges between side chain and DNA base edges via hydrogen bonding interactions. This additional contribution to ligand-DNA interactions would be expected to result in enhanced DNA affinity, as is observed.

High-resolution NMR structure of an AT-rich DNA sequence

We have determined, by proton NMR and complete relaxation matrix methods, the high-resolution structure of a DNA oligonucleotide in solution with nine contiguous AT base pairs. The stretch of AT pairs, TAATTATAA x TTATAATTA, is imbedded in a 27-nucleotide stem-and-loop construct, which is stabilized by terminal GC base pairs and an extraordinarily stable DNA loop GAA (Hirao et al., 1994, Nucleic Acids Res. 22, 576-582). The AT-rich sequence has three repeated TAA x TTA motifs, one in the reverse orientation. Comparison of the local conformations of the three motifs shows that the sequence context has a minor effect here: atomic RMSD between the three TAA x TTA fragments is 0.4-0.5 A, while each fragment is defined within the RMSD of 0.3-0.4 A. The AT-rich stem also contains a consensus sequence for the Pribnow box, TATAAT. The TpA, ApT, and TpT x ApA steps have characteristic local conformations, a combination of which determines a unique sequence-dependent pattern of minor groove width variation. All three TpA steps are locally bent in the direction compressing the major groove of DNA. These bends, however, compensate each other, because of their relative position in the sequence, so that the overall helical axis is essentially straight.