Abstract
The combination of magic angle spinning (MAS) with the high-resolution (1)H NOESY NMR experiment is an established method for measuring through-space (1)H...(1)H dipolar couplings in biological membranes. The segmental motion of the lipid acyl chains along with the overall rotational diffusion of the lipids provides sufficient motion to average the (1)H dipolar interaction to within the range where MAS can be effective. One drawback of the approach is the relatively long NOESY mixing times needed for relaxation processes to generate significant crosspeak intensity. In order to drive magnetization transfer more rapidly, we use solid-state radiofrequency driven dipolar recoupling (RFDR) pulses during the mixing time. We compare the (1)H MAS NOESY experiment with a (1)H MAS RFDR experiment on dimyristoylphosphocholine, a bilayer-forming lipid and show that the (1)H MAS RFDR experiment provides considerably faster magnetization exchange than the standard (1)H MAS NOESY experiment. We apply the method to model compounds containing basic and aromatic amino acids bound to membrane bilayers to illustrate the ability to locate the position of aromatic groups that have penetrated to below the level of the lipid headgroups.