Elucidating the Membrane Binding Process of a Disordered Protein: Dynamic Interplay of Anionic Lipids and the Polybasic Region

Abstract

AbstractIntrinsically disordered regions of proteins are responsible for many biological processes such as in the case of liver kinase LKB1 – a serine/threonine kinase, relevant for cell proliferation and cell polarity. LKB1 itself becomes fully activated upon recruitment to the plasma membrane by binding of its disordered C-terminal polybasic motif consisting of eight lysines/arginines to phospholipids. Here we present extensive molecular dynamics (MD) simulations of the polybasic motif interacting with a model membrane composed of phosphatidylcholin (POPC) and phosphatidic acid (PA) and cell culture experiments. Protein-membrane binding effects are due to the electrostatic interactions between the polybasic amino acids and PAs. For significant binding the first three lysines turn out to be dispensable, which was also recapitulated in cell culture using transfected GFP-LKB1 variants. LKB1-membrane binding results in a non-monotonous changes in the structure of the protein as well as of the membrane, in particular accumulation of PAs and reduced thickness at the protein-membrane contact area. The protein-lipid binding turns out to be highly dynamic due to an interplay of PA-PA repulsion and protein-PA attraction. The thermodynamics of this interplay is captured by a statistical fluctuation model, which allows the estimation of both energies. Quantification of the significance of each polar amino acid in the polybasic provides detailed insights into the molecular mechanism of the protein-membrane binding of LKB1. These results can be likely transferred to other proteins, which interact by intrinsically disordered polybasic regions with anionic membranes.