Abstract
Potential of mean force (PMF) calculations are used to characterize the free energy landscape of protein–lipid and protein–protein association within membranes. Coarse-grained simulations allow binding free energies to be determined with reasonable statistical error. This accuracy relies on defining a good collective variable to describe the binding and unbinding transitions, and upon criteria for assessing the convergence of the simulation toward representative equilibrium sampling. As examples, we calculate protein–lipid binding PMFs for ANT/cardiolipin and Kir2.2/PIP2, using umbrella sampling on a distance coordinate. These highlight the importance of replica exchange between windows for convergence. The use of two independent sets of simulations, initiated from bound and unbound states, provide strong evidence for simulation convergence. For a model protein–protein interaction within a membrane, center-of-mass distance is shown to be a poor collective variable for describing transmembrane helix–helix dimerization. Instead, we employ an alternative intermolecular distance matrix RMS (DRMS) coordinate to obtain converged PMFs for the association of the glycophorin transmembrane domain. While the coarse-grained force field gives a reasonable Kd for dimerization, the majority of the bound population is revealed to be in a near-native conformation. Thus, the combination of a refined reaction coordinate with improved sampling reveals previously unnoticed complexities of the dimerization free energy landscape. We propose the use of replica-exchange umbrella sampling starting from different initial conditions as a robust approach for calculation of the binding energies in membrane simulations.
Highlights
Biological membranes are a complex mixture of multiple species of lipids and proteins, the interactions of which play a key role in cell function
Protein−lipid interactions play a key role in membrane protein stability and function[1] and so it is important to be able to characterize the strength of such interactions via potentials of mean force (PMF) calculations
We have illustrated our case with an example of the interaction of an integral membrane protein with cardiolipin, a topic of general importance as the energetics of such interactions have been explored by CG MD for a number of proteins from mitochondrial membranes, e.g., refs 70, 71, 20, and 72
Summary
Biological membranes are a complex mixture of multiple species of lipids and proteins, the interactions of which play a key role in cell function. Of particular interest are the intramembrane interactions of proteins with lipids[1] and adjacent proteins, the latter playing key roles in membrane protein folding[2] and function.[3] Molecular simulations have the potential to provide a detailed and quantitative understanding of protein and lipid interactions in membranes. Simulations permit the computation of free energy landscapes or potentials of mean force (PMF) of interactions between the different membrane components (e.g., refs 4 and 5). By enabling binding free energies to be computed, PMFs can provide mechanistic insights into biologically relevant intermolecular interactions, which in turn can be compared to available experimental measurements. Determining free energies for molecules embedded in lipid membranes is challenging. Sampling methods based on molecular dynamics will be impeded by the resulting slow diffusion of any molecule embedded in the membrane, a situation which is exacerbated in complex and crowded membrane environments.[7]
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