Standard Binding Free Energy and Membrane Desorption Mechanism for a Phospholipase C
Moutoussamy, Emmanuel Edouard; Khan, Hanif Muhammad; Roberts, Mary B; Gershenson, Anne; Chipot, Christophe; Reuter, Nathalie
Journal article, Peer reviewed
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Date
2022Metadata
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- Department of Biological Sciences [2296]
- Registrations from Cristin [10482]
Original version
Journal of Chemical Information and Modeling. 2022, 62 (24), 6602-6613. 10.1021/acs.jcim.1c01543Abstract
Peripheral membrane proteins (PMPs) bind temporarily to cellular membranes and play important roles in signaling, lipid metabolism, and membrane trafficking. Obtaining accurate membrane-PMP affinities using experimental techniques is more challenging than for protein–ligand affinities in an aqueous solution. At the theoretical level, calculation of the standard protein–membrane binding free energy using molecular dynamics simulations remains a daunting challenge owing to the size of the biological objects at play, the slow lipid diffusion, and the large variation in configurational entropy that accompanies the binding process. To overcome these challenges, we used a computational framework relying on a series of potential-of-mean-force (PMF) calculations including a set of geometrical restraints on collective variables. This methodology allowed us to determine the standard binding free energy of a PMP to a phospholipid bilayer using an all-atom force field. Bacillus thuringiensis phosphatidylinositol-specific phospholipase C (BtPI-PLC) was chosen due to its importance as a virulence factor and owing to the host of experimental affinity data available. We computed a standard binding free energy of −8.2 ± 1.4 kcal/mol in reasonable agreement with the reported experimental values (−6.6 ± 0.2 kcal/mol). In light of the 2.3-μs separation PMF calculation, we investigated the mechanism whereby BtPI-PLC disengages from interactions with the lipid bilayer during separation. We describe how a short amphipathic helix engages in transitory interactions to ease the passage of its hydrophobes through the interfacial region upon desorption from the bilayer.