Abstract
In recent years, a massive increase has been observed in the number of published articles describing accurate and reliable molecular dynamics simulations of lipid bilayers. This is due to several reasons, including the development of fast and efficient methods for treating long-range electrostatic interactions, significant progress in computer hardware, progress in atomistic simulation algorithms and the development of well-validated empirical molecular mechanical force fields. Although molecular dynamics is an effective approach for investigating different aspects of lipid bilayers, to the best of our knowledge, there is no review in the literature that explains the different analyses that can be carried out with membrane simulation. This review gives an overview about the some of the most important possible analyses, technical challenges, and existing protocols that can be performed on the biological membrane by molecular dynamics simulation. The reviewed analyses include the degree of membrane disruption, average area per lipid, probability distributions for the area per lipid molecule, membrane thickness, membrane area compressibility, lateral diffusion, rotational diffusion, order parameters, head group tilt, electron density profile, mass density profile, electrostatic potential profile, ordering of vicinity waters, number of hydrogen bonds, and radial distribution function.
Highlights
Biological lipid bilayers have a multitude of biological roles, such as facilitating the synergy between diverse lipids, proteins, peptides, and carbohydrates.[1]
Molecular dynamics (MD) simulation methods were developed by Alder and Wainwright[4] in 1957 to simulate the behavior of hard spheres in a box depending on temperature and density
The present review gives an overview and discussion about the some of the most important possible analyses, technical challenges, and existing protocols that can be performed on the biological membrane by molecular dynamics simulation
Summary
A large number of structural, biological, and dynamic properties and phenomena of biological membranes have been studied by MD simulation methods. Due to the computational limitations of current computers, a typical MD simulation of a biological membrane, mainly in each direction of the simulation box is about 500 Aor less This only makes it possible to study the behavior of a limited number of membrane-forming molecules. The motions in membranes range from conformational transitions of the lipid hydrocarbon tails on picosecond scales to bending of 10 mm-sized patches extending to several milliseconds Due to these mentioned limitations, it is imperative to have analysis methods that can study phenomena and extract the required information.[20]. Another area in which molecular dynamics can play an important role is the study of the behavior of intrinsically disordered proteins (IDPs) in model membranes since it is very difficult to crystalize and prepare protein XRD patterns in real lipid membranes. The various MD simulation analyses that can be used for lipid bilayers are discussed
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