Relative Affinities of Protein-Cholesterol Interactions from Equilibrium Molecular Dynamics Simulations.

T Bertie Ansell,Suzanne C Letham,Luke Curran,Michael R Horrell,Mark S P Sansom,Phillip J Stansfeld,Robin A Corey,Christian Siebold,Wanling Song,Tanadet Pipatpolkai

doi:10.1021/acs.jctc.1c00547

Abstract

Specific interactions of lipids with membrane proteins contribute to protein stability and function. Multiple lipid interactions surrounding a membrane protein are often identified in molecular dynamics (MD) simulations and are, increasingly, resolved in cryo-electron microscopy (cryo-EM) densities. Determining the relative importance of specific interaction sites is aided by determination of lipid binding affinities using experimental or simulation methods. Here, we develop a method for determining protein–lipid binding affinities from equilibrium coarse-grained MD simulations using binding saturation curves, designed to mimic experimental protocols. We apply this method to directly obtain affinities for cholesterol binding to multiple sites on a range of membrane proteins and compare our results with free energies obtained from density-based equilibrium methods and with potential of mean force calculations, getting good agreement with respect to the ranking of affinities for different sites. Thus, our binding saturation method provides a robust, high-throughput alternative for determining the relative consequence of individual sites seen in, e.g., cryo-EM derived membrane protein structures surrounded by an array of ancillary lipid densities.

Highlights

Eukaryotic integral membrane proteins participate in a range of essential cellular functions including signaling, adhesion, solute transport, and ion homeostasis
Membrane proteins are inserted in a lipid bilayer, the composition of which varies between cellular compartments, metabolic state, and intramembrane localization.[1,2]
Structural elucidation of specific protein−lipid interactions has been aided by advances in cryo-electron microscopy.[11,12]

Summary

■ INTRODUCTION

Eukaryotic integral membrane proteins participate in a range of essential cellular functions including signaling, adhesion, solute transport, and ion homeostasis. PyLipID was used to identify cholesterol binding sites by using a community analysis approach to group residues which simultaneously interact with a bound cholesterol over the course of the trajectories This method is described in detail elsewhere[54,55] and has been applied to a number of recent examples to characterize lipid binding sites and kinetics.[56−58] Since the residue composition of sites A and B varied slightly with the percent cholesterol present in the bilayer, we selected six residues from each site, contacts to which were maintained across all cholesterol concentrations, and used these six residues in our subsequent analysis (Supplementary Figure 1).

■ RESULTS

■ ACKNOWLEDGMENTS

■ REFERENCES