Abstract
Signaling events at membranes are often mediated by membrane lipid composition or membrane physical properties. These membrane properties could act either by favoring the membrane binding of downstream effectors or by modulating their activity. Several proteins can sense/generate membrane physical curvature (i.e. shape). However, the modulation of the activity of enzymes by a membrane's shape has not yet been reported. Here, using a cell-free assay with purified diacylglycerol kinase ϵ (DGKϵ) and liposomes, we studied the activity and acyl-chain specificity of an enzyme of the phosphatidylinositol (PI) cycle, DGKϵ. By systematically varying the model membrane lipid composition and physical properties, we found that DGKϵ has low activity and lacks acyl-chain specificity in locally flat membranes, regardless of the lipid composition. On the other hand, these enzyme properties were greatly enhanced in membrane structures with a negative Gaussian curvature. We also found that this is not a consequence of preferential binding of the enzyme to those structures, but rather is due to a curvature-mediated allosteric regulation of DGKϵ activity and acyl-chain specificity. Moreover, in a fine-tuned interplay between the enzyme and the membrane, DGKϵ favored the formation of structures with greater Gaussian curvature. DGKϵ does not bear a regulatory domain, and these findings reveal the importance of membrane curvature in regulating DGKϵ activity and acyl-chain specificity. Hence, this study highlights that a hierarchic coupling of membrane physical property and lipid composition synergistically regulates membrane signaling events. We propose that this regulatory mechanism of membrane-associated enzyme activity is likely more common than is currently appreciated.
Highlights
Signaling events at membranes are often mediated by membrane lipid composition or membrane physical properties
This acyl-chain enrichment is in part believed to be due to the action of diacylglycerol kinases (DGK)⑀, an enzyme of the PI cycle, the major metabolic pathway for the synthesis of inositol phospholipids
By using a purified system with DGK⑀ and model membranes, where we systematically varied the properties of the membranes, we identified highly curved membranes as the minimum requirement to activate the enzyme
Summary
Marked differences in DGK⑀ activity and acyl-chain specificity between mixed micelles and liposomes. Using purified DGK⑀ we can for the first time, assay the kinase activity and acyl-chain specificity in liposomes and compare the results with those using mixed micelles (Fig. 1). Activity as a function of DAG mol % in 20 mol % POPE liposomes prepared as large unilamellar vesicles (LUVs) showed marked differences from mixed micelles (Fig. 1C). In this system, the enzyme exhibited Michaelis–Menten kinetics; the activity and acyl-chain specificity were much lower than those observed in mixed micelles (note the difference in y axis scale). The results are presented as the mean Ϯ S.E. (n ϭ 3)
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