Aggregated states have been alluded to for many DNA minor groove binders but details of the molecule-on-molecule relationship have either been under-reported or ignored. Here we report our findings from ITC and NMR measurements carried out with AIK-18/51, a compound representative of the thiazotropsin class of DNA minor groove binders. The free aqueous form of AIK-18/51 is compared with that found in its complex with cognate DNA duplex d(CGACTAGTCG)2. Molecular self-association of AIK-18/51 is consistent with anti-parallel, face-to-face dimer formation, the building block on which the molecule aggregates. This underlying structure is closely allied to the form found in the ligand's DNA complex. NMR chemical shift and diffusion measurements yield a self-association constant Kass = (61 ± 19) × 103 M− 1 for AIK-18/51 that fits with a stepwise self-assembly model and is consistent with ITC data. The deconstructed energetics of this assembly process are reported with respect to a design strategy for ligand/DNA recognition.
The structural and thermodynamic basis for the strength and selectivity of the interactions of minor groove binders (MGBs) with DNA is not fully understood. In 2003, we reported the first example of a thiazole-containing MGB that bound in a phase-shifted pattern that spanned six base pairs rather than the usual four (for tricyclic distamycin-like compounds). Since then, using DNA footprinting, NMR spectroscopy, isothermal titration calorimetry, and molecular dynamics, we have established that the flanking bases around the central four being read by the ligand have subtle effects on recognition. We have investigated the effect of these flanking sequences on binding and the reasons for the differences and established a computational method to rank ligand affinity against varying DNA sequences.