Abstract
RNAs regulate various cellular processes using malleable 3D structures, and understanding the factors that control RNA structure and dynamics is critical for understanding their mechanisms of action. To mitigate factors that have limited studies of large, functionally relevant RNAs by solution nuclear magnetic resonance (NMR) spectroscopy, we have extended a recently described (2)H-enhanced, (1)H-(15)N correlation approach that used uniformly 15N-labeled guanosine triphosphate (GTP) by developing a chemoenzymatic labeling technology that grafts selectively labeled [9-(15)N]-Guanine on to any labeled ribose to make [9-(15)N]-GTP. The approach exploits advantageous NMR properties of the N9 nucleus which, when combined with extensive ribose deuteration and optimized NMR pulse sequences, affords sharp signals without complications that can arise using uniform [(15)N]-guanine labeling. The utility of the approach for NMR signal assignment and dynamics analysis is demonstrated for three large RNAs (20-78 kDa) that play critical roles in viral replication. With this approach, NMR studies of RNAs comprising 200 nt or more should now be feasible.