Abstract
The structural response of 1,2-dimyristoyl-sn-glycero-3-phosphatidylcholine (DMPC)/water bilayers to addition and subsequent solvation of a small amphiphilic molecule - an anesthetic benzyl alcohol - was studied by means of solid-state NMR ((2)H NMR, (31)P NMR) spectroscopy and low-angle X-ray diffraction. The sites of binding of this solute molecule within the bilayer were determined - the solute was shown to partition between several sites in the bilayer and the equilibrium was shown to be dynamic and dependent on the level of hydration and temperature. At the same time, it was shown that solubilization of benzyl alcohol reached a solubility limit and was terminated when the ordering profile of DMPC hydrocarbon chains adopted finite limiting values throughout the whole chain. Such findings were made probably for the first time for any lipid bilayer system and possibly have more general implications for dissolution of other small-molecule amphiphilic solutes in lipid bilayer systems other than DMPC. The limit to the hydrocarbon chain profile is probably a more general property and corresponds to the balance of intrabilayer and interbilayer forces established in combination with the elastic properties of the bilayer system that still consists of one single phase just before the solute forms an excess phase. It is not necessary to quantify the contribution of each individual intrabilayer and interbilayer force acting within such a bilayer system. A model of the dependence of surface density of lipid chains on the chain segment order parameter was also developed - an empirical mathematical model based on experimental data was derived and it was proposed to represent a relationship between intrinsic bilayer forces and bilayer deformation characteristics and might be proven to be of more general significance in the future.