Studies on Nucleic Acids – Structure and Dynamics

Abstract: This thesis is based on six papers, Papers I-VI, focusing on the interplay between the stabilizing elements of nucleic acids self-assembly; hydrogen bonding, stacking and solvent effects. In Paper I we investigate how the substitution of the O4' for CH2 in the sugar moiety of adenosine (2'-deoxyaristeromycin) at the A6 position of the Dickerson-Drew dodecamer makes the two modified bases exist in a dynamic equilibrium between Hoogsteen and Watson-Crick base pairing in the NMR time scale. Paper II is a structural study of the incorporation of 1-(1',3'-O-anhydro-?-D-psicofuranosyl)thymine in the T7 position of the Dickerson-Drew dodecamer. NMR constrained molecular dynamics and hydration studies show the base-base distortions caused by the introduction of a North-type locked sugar in an otherwise B-type DNA•DNA duplex. Paper III shows that the stacking distortion caused by the 1-(1',3'-O-anhydro-?-D-psicofuranosyl)thymine building block perturbs the charge transfer similar to a DNA mismatch. Paper IV highlights how the sequence context affects the physico-chemical properties, monitored by the pKa of guanine itself as well as how the charge perturbation is experienced by the neighboring bases, in ssDNA and ssRNA. Paper V focuses on the differences between the structural equilibria of single-stranded ssDNA and ssRNA. Directional differences in single-stranded stacking between ssDNA and ssRNA are identified and provide a basis to explain directional differences in pKa modulation and dangling-end stabilization. In Paper VI the thermodynamic gains of dangling ends on DNA and RNA core duplexes are found to correlate with the X-ray geometries of dangling nucleobases relative to the hydrogen bonds of the closing base pairs.