Binding-linked protonation of a DNA minor-groove agent

Unusually strong binding to the DNA minor groove by a highly twisted benzimidazole diphenylether: induced fit and bound water

RT29 is a dicationic diamidine derivative that does not obey the classical "rules" for shape and functional group placement that are expected to result in strong binding and specific recognition of the DNA minor groove. The compound contains a benzimidazole diphenyl ether core that is flanked by the amidine cations. The diphenyl ether is highly twisted and gives the entire compound too much curvature to fit well to the shape of the minor groove. DNase I footprinting, fluorescence intercalator displacement studies, and circular dichroism spectra, however, indicate that the compound is an AT specific minor groove binding agent. Even more surprisingly, quantitative biosensor-surface plasmon resonance and isothermal titration calorimetric results indicate that the compound binds with exceptional strength to certain AT sequences in DNA with a large negative enthalpy of binding. Crystallographic results for the DNA complex of RT29 compared to calculated results for the free compound show that the compound undergoes significant conformational changes to enhance its minor groove interactions. In addition, a water molecule is incorporated directly into the complex to complete the compound-DNA interface, and it forms an essential link between the compound and base pair edges at the floor of the minor groove. The calculated DeltaCp value for complex formation is substantially less than the experimentally observed value, which supports the idea of water being an intrinsic part of the complex with a major contribution to the DeltaCp value. Both the induced fit conformational changes of the compound and the bound water are essential for strong binding to DNA by RT29.

Physical and Structural Basis for the Strong Interactions of the -ImPy- Central Pairing Motif in the Polyamide f-ImPyIm

The polyamide f-ImPyIm has a higher affinity for its cognate DNA than either the parent analogue, distamycin A (10-fold), or the structural isomer, f-PyImIm (250-fold), has for its respective cognate DNA sequence. These findings have led to the formulation of a two-letter polyamide "language" in which the -ImPy- central pairings associate more strongly with Watson-Crick DNA than -PyPy-, -PyIm-, and -ImIm-. Herein, we further characterize f-ImPyIm and f-PyImIm, and we report thermodynamic and structural differences between -ImPy- (f-ImPyIm) and -PyIm- (f-PyImIm) central pairings. DNase I footprinting studies confirmed that f-ImPyIm is a stronger binder than distamycin A and f-PyImIm and that f-ImPyIm preferentially binds CGCG over multiple competing sequences. The difference in the binding of f-ImPyIm and f-PyImIm to their cognate sequences was supported by the Na(+)-dependent nature of DNA melting studies, in which significantly higher Na(+) concentrations were needed to match the ability of f-ImPyIm to stabilize CGCG with that of f-PyImIm stabilizing CCGG. The selectivity of f-ImPyIm beyond the four-base CGCG recognition site was tested by circular dichroism and isothermal titration microcalorimetry, which shows that f-ImPyIm has marginal selectivity for (A.T)CGCG(A.T) over (G.C)CGCG(G.C). In addition, changes adjacent to this 6 bp binding site do not affect f-ImPyIm affinity. Calorimetric studies revealed that binding of f-ImPyIm, f-PyImIm, and distamycin A to their respective hairpin cognate sequences is exothermic; however, changes in enthalpy, entropy, and heat capacity (DeltaC(p)) contribute differently to formation of the 2:1 complexes for each triamide. Experimental and theoretical determinations of DeltaC(p) for binding of f-ImPyIm to CGCG were in good agreement (-142 and -177 cal mol(-)(1) K(-)(1), respectively). (1)H NMR of f-ImPyIm and f-PyImIm complexed with their respective cognate DNAs confirmed positively cooperative formation of distinct 2:1 complexes. The NMR results also showed that these triamides bind in the DNA minor groove and that the oligonucleotide retains the B-form conformation. Using minimal distance restraints from the NMR experiments, molecular modeling and dynamics were used to illustrate the structural complementarity between f-ImPyIm and CGCG. Collectively, the NMR and ITC experiments show that formation of the 2:1 f-ImPyIm-CGCG complex achieves a structure more ordered and more thermodynamically favored than the structure of the 2:1 f-PyImIm-CCGG complex.

Binding of netropsin and 4,6-diamidino-2-phenylindole to an A2T2 DNA hairpin: a comparison of biophysical techniques

Isothermal titration calorimetry (ITC), differential scanning calorimetry (DSC), and biosensor-surface plasmon resonance (SPR) are evaluated for their accuracy in determining equilibrium constants, ease of use, and range of application. Systems chosen for comparison of the three techniques were the formation of complexes between two minor groove binding compounds, netropsin and 4,6-diamidino-2-phenylindole (DAPI), and a DNA hairpin having the sequence 5'-d(CGAATTCGTCTCCGAATTCG)-3'. These systems were chosen for their structural differences, simplicity (1:1 binding), and binding affinity in the range of interest (K approximately 10(8) M(-1)). The binding affinities determined from all three techniques were in excellent agreement; for example, netropsin/DNA formation constants were determined to be K = 1.7x10(8) M(-1) (ITC), K = 2.4x10(8) M(-1) (DSC), and K = 2.9x10(8) M(-1) (SPR). DSC and SPR techniques have an advantage over ITC in studies of ligands that bind with affinities greater than 10(8) M(-1). The ITC technique has the advantage of determining a full set of thermodynamic parameters, including deltaH, TdeltaS, and deltaC(p) in addition to deltaG (or K). The ITC data revealed complex binding behavior in these minor groove binding systems not detected in the other methods. All three techniques provide accurate estimates of binding affinity, and each has unique benefits for drug binding studies.