Structure and Binding Energy of Double-Stranded A-DNA Mini-helices: Quantum-Chemical Study.

A-DNA is thought to play a significant biological role in gene expression due to its specific conformation and binding features. In this study, double-stranded mini-helices (dA:dT)3 and (dG:dC)3 in A-like DNA conformation were investigated. M06-2X/6-31G(d,p) method has been utilized to identify the optimal geometries and predict physicochemical parameters of these systems. The results show the ability of the corresponding mini-helices to preserve their A-like conformation under the influences of solvent, charge, and Na(+) counterions. Presented structural and energetic data offer evidence that two steps of GG/CC or AA/TT are already enough to turn the DNA helix to generate different forms by favoring specific values of roll and slide at a local level. Our calculations support the experimentally known fact that AA/TT steps prefer the B-form over the A-ones, whereas GG/CC steps may be found in either the B- or A-form. The stability of mini-helices at the level of total energy analysis, ΔEtotal((A–B)), is discussed.