Conformational flexibility in RNA: the role of dihydrouridine

Abstract

In order to further understand the structural role of the modified nucleoside dihydrouridine in RNA the solution conformations of Dp and ApDpA were analyzed by one- and two-dimensional proton NRM spectroscopy and compared with those of the related uridine-containing compounds. The analyses indicate that dihydrouridine significantly destabilizes the C3'-endo sugar conformation associated with base stacked, ordered, A-type helical RNA. Equilibrium constants (Keq = [C2'-endo]/[C3'-endo]) for C2'-endo-C3'-endo interconversion at 25 degrees C for Dp, the 5'-terminal A of ApDpA and D in ApDpA are 2.08, 1.35 and 10.8 respectively. Stabilization of the C2'-endo form was shown to be enhanced at low temperature, indicating that C2'-endo is the thermodynamically favored conformation for dihydrouridine. DeltaH values show that for Dp the C2'-endo sugar conformation is stabilized by 1.5 kcal/mol compared with Up. This effect is amplified for D in the oligonucleotide ApDpA and propagated to the 5'-neighboring A, with stabilization of the C2'-endo form by 5.3 kcal/mol for D and 3.6 kcal/mol for the 5'-terminal A. Post-transcriptional formation of dihydrouridine therefore represents a biological strategy opposite in effect to ribose methylation, 2-thiolation or pseudouridylation, all of which enhance regional stability through stabilization of the C3'-endo conformer. Dihydrouridine effectively promotes the C2'-endo sugar conformation, allowing for greater conformational flexibility and dynamic motion in regions of RNA where tertiary interactions and loop formation must be simultaneously accommodated.