Details

Autor(en) / Beteiligte

• Yoo, Jejoong
• Aksimentiev, Aleksei

Titel

New tricks for old dogs: improving the accuracy of biomolecular force fields by pair-specific corrections to non-bonded interactionsElectronic supplementary information (ESI) available. See DOI: 10.1039/c7cp08185e

Erscheinungsjahr

2018-03

Link zum Volltext

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• In contrast to ordinary polymers, the vast majority of biological macromolecules adopt highly ordered three-dimensional structures that define their functions. The key to folding of a biopolymer into a unique 3D structure or to an assembly of several biopolymers into a functional unit is a delicate balance between the attractive and repulsive forces that also makes such self-assembly reversible under physiological conditions. The all-atom molecular dynamics (MD) method has emerged as a powerful tool for studies of individual biomolecules and their functional assemblies, encompassing systems of ever increasing complexity. However, advances in parallel computing technology have outpaced the development of the underlying theoretical models-the molecular force fields, pushing the MD method into an untested territory. Recent tests of the MD method have found the most commonly used molecular force fields to be out of balance, overestimating attractive interactions between charged and hydrophobic groups, which can promote artificial aggregation in MD simulations of multi-component protein, nucleic acid, and lipid systems. One route towards improving the force fields is through the NBFIX corrections method, in which the intermolecular forces are calibrated against experimentally measured quantities such as osmotic pressure by making atom pair-specific adjustments to the non-bonded interactions. In this article, we review development of the NBFIX (Non-Bonded FIX) corrections to the AMBER and CHARMM force fields and discuss their implications for MD simulations of electrolyte solutions, dense DNA systems, Holliday junctions, protein folding, and lipid bilayer membranes. Recent advances in parallel computing have pushed all-atom molecular dynamics simulations into an untested territory. This article reviews the applications of the NBFIX approach for testing and improving molecular dynamics force fields and discuses the implications of the NBFIX corrections for simulations of various biomolecular systems.