Modulation of PI-specific phospholipase C by membrane curvature and molecular order.

Phosphatidylinositol-specific phospholipase C (PI-PLC) from Bacillus cereus has been assayed on large and small unilamellar vesicles consisting of PI, either pure or in mixtures with other lipids. Vesicle diameter (in the 50-300 nm range) influences PI-PLC activity, enzyme rates increasing with decreasing curvature radii. With sonicated unilamellar vesicles of pure PI, two apparent K(s) values are observed, one in the 0-2 mM concentration range and the other in the 2-12 mM concentration range. The latter ( approximately 4.2 mM) corresponds to previously published values, while the low-concentration K(s) is on the same order of magnitude as the single apparent K(m) value found with large unilamellar liposomes ( approximately 0.30 mM). PI-PLC appears to be very sensitive to bilayer composition. Certain nonsubstrate lipids, e.g., galactosylceramide or cholesterol, inhibit PI-PLC in a dose-dependent way, at least up to 33 mol % in the bilayers, under conditions with a constant PI concentration. Simultaneous measurements of enzyme activity, interfacial enzyme binding, and fluorescence of different probes, on a variety of bilayer compositions, reveal that both the level of enzyme binding and activity decrease with increasing lipid order, as measured by the fluorescence polarization of the hydrophobic probe diphenylhexatriene. In contrast, no correlation is found for enzyme activity with fluorescence changes of probes, e.g., laurdan, that report on phenomena occurring mainly at the lipid-water interface. Sphingomyelin has a dual effect. Up to 40 mol %, it increases PI-PLC activity, with little effect on bilayer molecular order. At higher proportions, the increased lipid chain order causes a decrease in enzyme activity. The same effects are observed for distearoylphosphatidylcholine when added to PI bilayers. These results support the "two-stage model" for binding of PI-PLC to lipid bilayers, and underline the significance of the enzyme partial penetration into the membrane hydrophobic matrix for its catalytic activity.