1988 Volume 104 Issue 1 Pages 141-148
In order to investigate the effect of cholesteryl ester (CE) accumulation in plasma lipoprotein on its metabolism, change of the cholesterol (CHOL) microenvironment was studied by using a lipid microemulsion model system (J. Biol. Chem. 258, 10073-10082, 1983 and 260, 16375-16382, 1985) in the presence of CE and apolipoproteins. Solubility of CHOL in the triolein (TG) core of the emulsion was limited (0.4 weight percent), so that most of the CHOL in the emulsion was found to be associated with the phosphatidylcholine (PC) surface membrane. CE was associated almost exclusively with the TG core without any significant effect on the partitioning of cholesterol between the core and the surface. However, membrane-associated CHOL seems to be present in the TG core adjacent to the surface membrane in the microemulsion without CE, and it is likely to be shifted into the membrane by the presence of CE in the core according to the compositional analysis. Binding parameters of apolipoproteins (apo) A-I, A-II, C-III1, and E were not significantly different among the emulsions with and without CHOL and/or CE at CHOL/PC ratios up to 0.17 (w/w). Susceptibility of CHOL to cholesterol oxidase was observed as an enzymatic probe for CHOL microenvironment. In the absence of apolipoproteins, CHOL reacted similarly to the enzyme regardless of its shift by CE. When apolipoproteins bound to the emulsion containing only CHOL, the rate of CHOL oxidation was decreased by 40% with apoE but not with the others. In the presence of CE, it was decreased by 80% with apoA-I and E, and by 65 and 35% with apoC-III, and apoA-II, respectively. These results indicated that apolipoproteins modulate CHOL environment more potently when lipoprotein contains more CE and that this modulation is the strongest with apoE.