Dickson Alex, Brooks Charles L
Department of Chemistry, University of Michigan , Ann Arbor, Michigan, United States.
J Phys Chem B. 2014 Apr 3;118(13):3532-42. doi: 10.1021/jp411479c. Epub 2014 Feb 11.
As most relevant motions in biomolecular systems are inaccessible to conventional molecular dynamics simulations, algorithms that enhance sampling of rare events are indispensable. Increasing interest in intrinsically disordered systems and the desire to target ensembles of protein conformations (rather than single structures) in drug development motivate the need for enhanced sampling algorithms that are not limited to "two-basin" problems, and can efficiently determine structural ensembles. For systems that are not well-studied, this must often be done with little or no information about the dynamics of interest. Here we present a novel strategy to determine structural ensembles that uses dynamically defined sampling regions that are organized in a hierarchical framework. It is based on the weighted ensemble algorithm, where an ensemble of copies of the system ("replicas") is directed to new regions of configuration space through merging and cloning operations. The sampling hierarchy allows for a large number of regions to be defined, while using only a small number of replicas that can be balanced over multiple length scales. We demonstrate this algorithm on two model systems that are analytically solvable and examine the 10-residue peptide chignolin in explicit solvent. The latter system is analyzed using a configuration space network, and novel hydrogen bonds are found that facilitate folding.
由于生物分子系统中的大多数相关运动无法通过传统的分子动力学模拟进行研究,因此增强对罕见事件采样的算法必不可少。对内在无序系统的兴趣日益增加,以及在药物开发中针对蛋白质构象集合(而非单一结构)的需求,促使人们需要一种不限于“双阱”问题、能够有效确定结构集合的增强采样算法。对于研究较少的系统,通常必须在几乎没有或完全没有关于感兴趣动力学信息的情况下完成这项工作。在此,我们提出一种确定结构集合的新策略,该策略使用在分层框架中组织的动态定义采样区域。它基于加权系综算法,通过合并和克隆操作将系统副本的集合(“复制品”)引导到构型空间的新区域。采样层次结构允许定义大量区域,同时仅使用少量可以在多个长度尺度上保持平衡的复制品。我们在两个可解析求解的模型系统上演示了该算法,并在明确溶剂中研究了10个残基的肽chignolin。使用构型空间网络对后一个系统进行了分析,并发现了有助于折叠的新型氢键。