Atomistic Simulations and Analysis of Peripheral Membrane Proteins with Model Lipid Bilayers

All-atom molecular dynamics (AAMD) is a computational technique that predicts the movement of particles based on the intermolecular forces acting on the system. It enables the study of biological systems at atomic detail, complements observations from experiments, and can help the selection of experimental targets. Here, we describe the applications of MD simulations to study the interaction between peripheral membrane proteins and lipid bilayers. Specifically, we provide step-by-step instructions to set up MD simulations to study the binding and interaction of ALPS, the amphipathic helix of the lipid transport protein Osh4, and Thanatin, an antimicrobial peptide with model membranes. We describe examples of systems built with fully atomistic lipid tails and those truncated with the highly-mobile-membrane-mimetic method to enhance conformational sampling. We also comment on the importance of lipid diversity, molecular resolution, and best practices for constructing, running, and analyzing protein-lipid simulation systems. In this second edition, we include a brief discussion on alternative approaches and software to construct protein-membrane coordinate systems, as well as analysis tools and practices that have become relevant to examining protein-lipid interactions since the first edition of this chapter.