Abstract
BackgroundProtein-lipid interactions play essential roles in the conformational stability and biological functions of membrane proteins. However, few of the previous computational studies have taken into account the atomic details of protein-lipid interactions explicitly.ResultsTo gain an insight into the molecular mechanisms of the recognition of lipid molecules by membrane proteins, we investigated amino acid propensities in membrane proteins for interacting with the head and tail groups of lipid molecules. We observed a common pattern of lipid tail-amino acid interactions in two different data sources, crystal structures and molecular dynamics simulations. These interactions are largely explained by general lipophilicity, whereas the preferences for lipid head groups vary among individual proteins. We also found that membrane and water-soluble proteins utilize essentially an identical set of amino acids for interacting with lipid head and tail groups.ConclusionsWe showed that the lipophilicity of amino acid residues determines the amino acid preferences for lipid tail groups in both membrane and water-soluble proteins, suggesting that tightly-bound lipid molecules and lipids in the annular shell interact with membrane proteins in a similar manner. In contrast, interactions between lipid head groups and amino acids showed a more variable pattern, apparently constrained by each protein's specific molecular function.
Highlights
Protein-lipid interactions play essential roles in the conformational stability and biological functions of membrane proteins
Amino acid propensities from the crystal structure and molecular dynamics (MD) datasets Amino acid propensities of membrane proteins contacting with lipid head and tail groups were derived from both crystal structures and MD simulations
We showed that the patterns of membrane protein-lipid interactions obtained from both the crystal structures and MD trajectories were highly correlated with each other (Figure 1)
Summary
Protein-lipid interactions play essential roles in the conformational stability and biological functions of membrane proteins. About 20-30% of all proteins encoded in a typical genome are estimated to be localized in membranes [1,2], where protein-lipid interactions play crucial roles in the conformational stability and biological functions of membrane proteins. The thermal [3,4] and chemical [5] stability of the potassium channel KcsA has been shown to vary according to the lipid composition of the membrane bilayer. To complement these experimental studies, statistical analyses have been carried out to reveal amino acid preferences and conservation patterns within the lipid bilayer environment [12,13,14,15,16] using available sequence and structural data. All-atom MD simulations enable us to inspect protein-lipid interactions in atomic details [18,19] and can reveal the role of lipids in protein function [20], albeit for a small selection of specific lipid and protein molecules
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