Nuclear magnetic resonance studies of polyisoprenols in model membranes.

2H-NMR investigation of polyisoprenols (PIs) in model membranes has revealed information about their motions, relative order, and locale within the membrane. Initial 2H-NMR studies of the organization of the shorter chain homologues geraniol (C10), farnesol (C15), and solanesol (C45) were carried out by incorporating 2H-acetyl esters of the alcohol or the di-perdeuterome-thylated derivatives of the omega-labeled prenols into multilamellar phosphatidylcholine (PC) vesicles. 2H-NMR powder patterns interpretable in terms of quadrupole splittings and spin-lattice relaxation times were obtained. Similar experiments have now been carried out with the labeled free alcohol, acetyl ester, and phosphate ester of dolichol (C95) and undecaprenol (C55). 2H-NMR results show that the head and tail 2H-labeled sites of C55 and C95 exhibit a fast motion isotropic signal only; no slower motion anisotropy, as exhibited by the short chain PIs, was observed. These data suggest that C55 and C95 either have substantially different (faster) motions and/or conformations relative to the shorter chain PIs within the membrane, and that the longer PIs alter the membrane host packing matrix. This conclusion was supported by 31P-NMR studies of C55 and C95 derivatives in PC and PE/PC membranes, which showed new pronounced spectral changes relative to the results obtained with the shorter chain PIs. These spectral changes indicate that undecaprenol and dolichol derivatives appear to induce a non-bilayer (isotropic) organization of phospholipid molecules in PE/PC (2:1) vesicles. The possible physiological consequences of this perturbation remains to be determined.