Direct folding simulation of α‐helices and β‐hairpins based on a single all‐atom force field with an implicit solvation model
Citations Over TimeTop 11% of 2006 papers
Abstract
Recently, we have shown that a modified energy model based on the param99 force field with the generalized Born (GB) solvation model produces reliable free energy landscapes of mini-proteins with a betabetaalpha motif (BBA5, 1FSD, and 1PSV), with the native structures of the mini-proteins located in their lowest free energy minimum states. One of the main features in the modified energy model is a significant improvement for more balanced treatments of alpha and beta strands in proteins. In this study, using the replica exchange molecular dynamics (REMD) simulation method with this new force field, we have carried out extensive ab initio folding studies of several well-known peptides with alpha or beta strands (C-peptide, EK-peptide, le0q, and gbl). Starting from fully extended conformations as the initial conditions, all of the native-like structures of the target peptides were successfully identified by REMD, with reasonable representations of free energy surfaces. The present simulation results with the modified energy model are consistent with experiments, demonstrating an extended applicability of the energy model to folding studies of a variety of alpha-helices, beta-strands, and alpha/beta proteins.
Related Papers
- → Nonpolar Solvation Free Energies of Protein−Ligand Complexes(2010)37 cited
- → Atomic decomposition of the protein solvation free energy and its application to amyloid-beta protein in water(2011)40 cited
- → Assessing the performance of implicit solvation models at a nucleic acid surface(2008)20 cited
- → Comparative Study of Implicit and Explicit Solvation Models for Probing Tryptophan Side Chain Packing in Proteins(2012)4 cited
- → Liquid-state theory derivation of surface accessible solvation potential models for proteins(2002)4 cited