Lipid domains in bicelles containing unsaturated lipids and cholesterol.

We have created a stable bicelle system capable of forming micrometer-scale lipid domains that orient in a magnetic field, suitable for structural biology determination in solid-state NMR. The bicelles consisted of a mixture of cholesterol, saturated lipid (DMPC), and unsaturated lipid (POPC), a mixture commonly used to create domains in model membranes, along with a short chain lipid (DHPC) that allows formation of the bicelle phase. While maintaining a constant molar ratio of long to short chain lipids, q = ([POPC]+[DMPC])/[DHPC] = 3, we varied the concentrations of the unsaturated lipid, POPC, and cholesterol to observe the effects of the components on bicelle stability. Using (31)P solid-state NMR, we observed that unsaturated lipids (POPC) greatly destabilized the alignment of the membranes in the magnetic field, while cholesterol stabilized their alignment. By combining cholesterol and unsaturated lipids in the bicelles, we created membranes aligning uniformly in the magnetic field, despite very high concentrations of unsaturated lipids. These bicelles, with high concentrations of both cholesterol and unsaturated lipid, showed similar phase behavior to bicelles commonly used in structural biology, but aligned over a wider temperature range (291-314 K). Domains were observed by measuring time-dependent diffusion constants reflecting restricted diffusion of the lipids within micrometer-scale regions of the bicelles. Micron-scale domains have never been observed in POPC/DMPC/cholesterol vesicles, implying that bilayers in bicelles show different phase behavior than their counterparts in vesicles, and that bilayers in bicelles favor domain formation.