Mg 2+-induced Variations in the Conformation and Dynamics of HIV-1 TAR RNA Probed Using NMR Residual Dipolar Couplings

Abstract

The effects of divalent Mg 2+ on the conformation and dynamics of the stem-loop transactivation response element (TAR) RNA from HIV-1 have been characterized using NMR residual dipolar couplings (RDCs). Order matrix analysis of one bond 13C– 1H RDCs measured in TAR at [Mg 2+]:[TAR] stoichiometric ratios of ∼3:1 (TAR(3.0 Mg)) and ∼4.5:1 (TAR(4.5 Mg)) revealed that Mg 2+ reduces the average inter-helical angle from 47(±5)° in TAR(free) to 5(±7)° in TAR(4.5 Mg). In contrast to the TAR(free) state, the generalized degree of order for the two stems in TAR(4.5 Mg) is found to be identical within experimental uncertainty, indicating that binding of Mg 2+ leads to an arrest of inter-helical motions in TAR(free). Results demonstrate that RDC-NMR methodology can provide new insight into the effects of Mg 2+ on both the conformation and dynamics of RNA.