13C NMR relaxation studies of RNA base and ribose nuclei reveal a complex pattern of motions in the RNA binding site for human U1A protein.

The widespread importance of induced fit and order-disorder transition in RNA recognition by proteins and small molecules makes it imperative that RNA motional properties are characterized quantitatively. Until now, however, very few studies have been dedicated to the systematic characterization of RNA motion and to their changes upon protein or small-molecule binding. The U1A protein-RNA complexes provide some of the best-studied examples of the role of RNA motional changes upon protein binding. Here, we report (13)C NMR relaxation studies of base and ribose dynamics for the RNA internal loop target of human U1A protein located within the 3'-untranslated region (3'-UTR) of the mRNA coding for U1A itself. We also report the semi-quantitative analysis of both fast (nano- to picosecond) and intermediate (micro- to millisecond) motions for this paradigmatic RNA system. We measure (13)C T(1), T(1rho) and heteronuclear nuclear Overhauser effects (NOEs) for sugar and base nuclei, as well as the power dependence of T(1rho) at 500 MHz and 750 MHz, and analyze these results using the model-free formalism. The results provide a much clearer picture of the type of motions experienced by this RNA in the absence of the protein than was provided by the analysis of the structure based solely on NOEs and scalar couplings. They define a model where the RNA internal loop region "breathes" on a micro- to millisecond timescale with respect to the double-helical regions. Superimposed on this slower motion, the residues at the very tip of the loop undergo faster (nano- to picosecond) motions. We hypothesize that these motions allow the RNA to sample multiple conformations so that the protein can select a structure within the ensemble that optimizes intermolecular contacts.