用于蛋白质模型评分和优化的基于物理学的力场的开发。

Development of a physics-based force field for the scoring and refinement of protein models.

作者信息

Wroblewska Liliana, Jagielska Anna, Skolnick Jeffrey

机构信息

Center for the Study of Systems Biology, School of Biology, Georgia Institute of Technology, Atlanta, Georgia 30318, USA.

出版信息

Biophys J. 2008 Apr 15;94(8):3227-40. doi: 10.1529/biophysj.107.121947. Epub 2008 Jan 4.

DOI:10.1529/biophysj.107.121947

PMID:18178653

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2275715/

Abstract

The minimal requirements of a physics-based potential that can refine protein structures are the existence of a correlation between the energy with native similarity and the scoring of the native structure as the lowest in energy. To develop such a force field, the relative weights of the Amber ff03 all-atom potential supplemented by an explicit hydrogen-bond potential were adjusted by global optimization of energetic and structural criteria for a large set of protein decoys generated for a set of 58 nonhomologous proteins. The average correlation coefficient of the energy with TM-score significantly improved from 0.25 for the original ff03 potential to 0.65 for the optimized force field. The fraction of proteins for which the native structure had lowest energy increased from 0.22 to 0.90. Moreover, use of an explicit hydrogen-bond potential improves scoring performance of the force field. Promising preliminary results were obtained in applying the optimized potentials to refine protein decoys using only an energy criterion to choose the best decoy among sampled structures. For a set of seven proteins, 63% of the decoys improve, 18% get worse, and 19% are not changed.

摘要

能够优化蛋白质结构的基于物理的势能的最低要求是，具有天然相似性的能量与天然结构能量最低得分之间存在相关性。为了开发这样一种力场，通过对一组58个非同源蛋白质生成的大量蛋白质诱饵的能量和结构标准进行全局优化，调整了由显式氢键势能补充的Amber ff03全原子势能的相对权重。能量与TM评分的平均相关系数从原始ff03势能的0.25显著提高到优化力场的0.65。天然结构能量最低的蛋白质比例从0.22增加到0.90。此外，使用显式氢键势能可提高力场的评分性能。在应用优化后的势能仅使用能量标准在采样结构中选择最佳诱饵来优化蛋白质诱饵方面，获得了有希望的初步结果。对于一组七种蛋白质，63%的诱饵得到改善，18%变差，19%不变。

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