Abstract
GPI-Anchored proteins (GPI-APs) can be exogenously transferred onto bilayer membranes both in vivo and in vitro, while the mechanism by which this transfer process occurs is unknown. In this work, we used atomistic molecular dynamics simulations and free energy calculations to characterize the essential influence of cholesterol on insertion of the GPI anchors into plasma membranes. We demonstrate, both dynamically and energetically, that in the presence of cholesterol, the tails of GPI anchors are able to penetrate inside the core of the lipid membrane spontaneously with a three-step mechanism, while in the absence of cholesterol no spontaneous insertion was observed. We ascribe the failure of insertion to the strong thermal fluctuation of lipid molecules in cholesterol-free bilayer, which generates a repulsive force in entropic origin. In the presence of cholesterol, however, the fluctuation of lipids is strongly reduced, thus decreasing the barrier for the anchor insertion. Based on this observation, we propose a hypothesis that addition of cholesterol creates vertical creases in membranes for the insertion of acyl chains. Moreover, we find that the GPI anchor could also spontaneously inserted into the boundary between cholesterol-rich and cholesterol-depleted domains. Our results shed light on the mechanism of cholesterol-mediated interaction between membrane proteins with acyl chain and plasma membranes in living cells.
Highlights
Glycosylphosphatidylinositol (GPI) anchor is a complex glycolipid commonly found in the outer leaflet of cell membranes.[1,2,3] It acts as a bridge connecting the anchored proteins with the target membrane site
In order to verify dynamically whether the hydrophobic tails of GPI anchors can spontaneously insert into membranes of different types, a GPI anchor was initially placed above a lipid bilayer either containing 0 or 50% cholesterol (CHOL) molecules
Our atomistic molecular dynamics (MD) simulation results are given in Fig. 2, which shows that in the presence of cholesterol molecules, the GPI can penetrate into the lipid bilayer spontaneously within a short simulation time (Fig. 2(b))
Summary
Glycosylphosphatidylinositol (GPI) anchor is a complex glycolipid commonly found in the outer leaflet of cell membranes.[1,2,3] It acts as a bridge connecting the anchored proteins with the target membrane site. Such structural complexity is expected to encode diverse functions of the anchors,[7,8] which can organize, transport and even modify the membrane proteins, namely GPI-APs.[3,9]
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