Best Practices for Alchemical Free Energy Calculations [Article v1.0].

A. Mey, Bryce K. Allen, H. B. Macdonald, J. Chodera, David F. Hahn, M. Kuhn, J. Michel, D. Mobley, Levi N. Naden, Samarjeet Prasad, A. Rizzi, Jenke Scheen, M. Shirts, G. Tresadern, Huafeng Xu
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引用次数: 123

Abstract

Alchemical free energy calculations are a useful tool for predicting free energy differences associated with the transfer of molecules from one environment to another. The hallmark of these methods is the use of "bridging" potential energy functions representing alchemical intermediate states that cannot exist as real chemical species. The data collected from these bridging alchemical thermodynamic states allows the efficient computation of transfer free energies (or differences in transfer free energies) with orders of magnitude less simulation time than simulating the transfer process directly. While these methods are highly flexible, care must be taken in avoiding common pitfalls to ensure that computed free energy differences can be robust and reproducible for the chosen force field, and that appropriate corrections are included to permit direct comparison with experimental data. In this paper, we review current best practices for several popular application domains of alchemical free energy calculations performed with equilibrium simulations, in particular relative and absolute small molecule binding free energy calculations to biomolecular targets.
炼金术自由能计算的最佳实践[第v1.0条]。
炼金术自由能计算是预测与分子从一种环境转移到另一种环境有关的自由能差的有用工具。这些方法的特点是使用“桥接”势能函数来表示炼金术的中间状态,这些状态不能作为真正的化学物质存在。从这些桥接炼金术热力学状态收集的数据允许有效地计算传递自由能(或传递自由能的差异),其模拟时间比直接模拟传递过程少几个数量级。虽然这些方法非常灵活,但必须注意避免常见的陷阱,以确保计算的自由能差对于所选的力场是可靠的和可重复的,并包括适当的修正,以便与实验数据进行直接比较。在本文中,我们回顾了目前几个流行的炼金术自由能计算应用领域的最佳实践,特别是对生物分子目标的相对和绝对小分子结合自由能计算。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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