4.7 Article

Alchemical transformations for concerted hydration free energy estimation with explicit solvation

Journal

JOURNAL OF CHEMICAL PHYSICS
Volume 154, Issue 5, Pages -

Publisher

AIP Publishing
DOI: 10.1063/5.0036944

Keywords

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Funding

  1. National Science Foundation (NSF CAREER) [1750511]
  2. NSF XSEDE [TG-MCB150001]

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The study introduces a family of alchemical perturbation potentials that can calculate hydration free energies of small to medium-sized molecules in a single step, instead of the usual two steps. By optimizing parameters and applying a novel soft-core function, rapid convergence of hydration free energy can be achieved in streamlined molecular dynamics simulation codes.
We present a family of alchemical perturbation potentials that enable the calculation of hydration free energies of small- to medium-sized molecules in a single concerted alchemical coupling step instead of the commonly used sequence of two distinct coupling steps for Lennard-Jones and electrostatic interactions. The perturbation potentials we employ are non-linear functions of the solute-solvent interaction energy designed to focus sampling near entropic bottlenecks along the alchemical pathway. We present a general framework to optimize the parameters of alchemical perturbation potentials of this kind. The optimization procedure is based on the lambda -function formalism and the maximum-likelihood parameter estimation procedure we developed earlier to avoid the occurrence of multi-modal distributions of the coupling energy along the alchemical path. A novel soft-core function applied to the overall solute-solvent interaction energy rather than individual interatomic pair potentials critical for this result is also presented. Because it does not require modifications of core force and energy routines, the soft-core formulation can be easily deployed in molecular dynamics simulation codes. We illustrate the method by applying it to the estimation of the hydration free energy in water droplets of compounds of varying size and complexity. In each case, we show that convergence of the hydration free energy is achieved rapidly. This work paves the way for the ongoing development of more streamlined algorithms to estimate free energies of molecular binding with explicit solvation.

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