Akaki Tatsuo, Nakamura Shinya, Nishiwaki Keiji, Nakanishi Isao
Computational Drug Design and Discovery, Department of Pharmaceutical Sciences, Kindai University.
Chemical Research Laboratories, Central Pharmaceutical Research Institute, Japan Tobacco Inc.
Chem Pharm Bull (Tokyo). 2023 Apr 1;71(4):299-306. doi: 10.1248/cpb.c22-00866. Epub 2023 Feb 2.
The fragment molecular orbital (FMO) method is a fast quantum-mechanics method that divides systems into pieces of fragments and performs ab initio calculations. The method has been expected to improve the accuracy of describing protein-ligand interactions by incorporating electronic effects. In this article, FMO calculation with solvation methods were applied to the affinity prediction at the ATP-binding site of PDHK4. As the ionized aspartic acid lies at the center and is involved in the complex hydrogen bond networks, this system has turned out to be a difficult target to describe by traditional molecular-mechanics method. In the FMO calculation with the polarizable continuum model (PCM) solvation method, a considerable amount of charge (-0.27e) was transferred from the ionized aspartate to the surrounding residues. We found that using FMO with the PCM solvation method was important to increase the correlation, and by incorporating the ligand deformation energy, the correlation was improved to R = 0.81 for whole twelve compounds and R = 0.91 without one outlier compound.
片段分子轨道(FMO)方法是一种快速量子力学方法,它将系统划分为片段,并进行从头计算。该方法有望通过纳入电子效应来提高描述蛋白质-配体相互作用的准确性。在本文中,采用带有溶剂化方法的FMO计算对丙酮酸脱氢酶激酶4(PDHK4)的ATP结合位点的亲和力进行预测。由于离子化的天冬氨酸位于中心并参与复杂的氢键网络,该系统已证明是传统分子力学方法难以描述的目标。在采用可极化连续介质模型(PCM)溶剂化方法的FMO计算中,相当数量的电荷(-0.27e)从离子化的天冬氨酸转移到周围残基。我们发现,使用带有PCM溶剂化方法的FMO对于提高相关性很重要,并且通过纳入配体变形能,对于全部12种化合物,相关性提高到R = 0.81,排除一个异常化合物后R = 0.91。
