Abstract
Nested Sampling (NS) is a parameter space sampling algorithm which can be used for sampling the equilibrium thermodynamics of atomistic systems. NS has previously been used to explore the potential energy surface of a coarse-grained protein model and has significantly outperformed parallel tempering when calculating heat capacity curves of Lennard-Jones clusters. The original NS algorithm uses Monte Carlo (MC) moves; however, a variant, Galilean NS, has recently been introduced which allows NS to be incorporated into a molecular dynamics framework, so NS can be used for systems which lack efficient prescribed MC moves. In this work we demonstrate the applicability of Galilean NS to atomistic systems. We present an implementation of Galilean NS using the Amber molecular dynamics package and demonstrate its viability by sampling alanine dipeptide, both in vacuo and implicit solvent. Unlike previous studies of this system, we present the heat capacity curves of alanine dipeptide, whose calculation provides a stringent test for sampling algorithms. We also compare our results with those calculated using replica exchange molecular dynamics (REMD) and find good agreement. We show the computational effort required for accurate heat capacity estimation for small peptides. We also calculate the alanine dipeptide Ramachandran free energy surface for a range of temperatures and use it to compare the results using the latest Amber force field with previous theoretical and experimental results.
Highlights
It has been over 50 years since Ramachandran and coworkers first modelled protein peptide bonds [1]
We demonstrate the Galilean Nested Sampling algorithm by using it to calculate the thermodynamics and free energy surfaces of the small peptide alanine dipeptide both in vacuum and implicit solvent
We have demonstrated the algorithm by sampling alanine dipeptide both in vacuo and using a generalised Born implicit solvent model
Summary
It has been over 50 years since Ramachandran and coworkers first modelled protein peptide bonds [1] In their work they used small peptides, containing only one or two peptide bonds, to study the sterically allowed protein dihedral angles. Polypeptide models and force fields of varying levels of complexity have been developed, ranging from simple coarsegrained models [12], through all-atom molecular mechanics force fields [13,14], hybrid quantum mechanics molecular mechanics (QM–MM) models [15,16], up to the full quantum mechanical treatment [17] These models have allowed the computational study of peptide thermodynamics and the exploration of their potential and free energy surfaces [10,18,19,11]
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