利用片段分子轨道计算和机器学习对蛋白质系统进行高精度原子电荷预测。

High-Precision Atomic Charge Prediction for Protein Systems Using Fragment Molecular Orbital Calculation and Machine Learning.

机构信息

Science Solutions Division, Mizuho Information & Research Institute, Inc., 2-3 Kanda Nishiki-cho, Chiyoda, Tokyo 101-8443, Japan.

Department of Applied Chemistry, Graduate School of Engineering, Kyushu University, 744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan.

出版信息

J Chem Inf Model. 2020 Jul 27;60(7):3361-3368. doi: 10.1021/acs.jcim.0c00273. Epub 2020 Jun 30.

DOI:10.1021/acs.jcim.0c00273

PMID:32496771

Abstract

Here, we have constructed neural network-based models that predict atomic partial charges with high accuracy at low computational cost. The models were trained using high-quality data acquired from quantum mechanics calculations using the fragment molecular orbital method. We have succeeded in obtaining highly accurate atomic partial charges for three representative molecular systems of proteins, including one large biomolecule (approx. 2000 atoms). The novelty of our approach is the ability to take into account the electronic polarization in the system, which is a system-dependent phenomenon, being important in the field of drug design. Our high-precision models are useful for the prediction of atomic partial charges and expected to be widely applicable in structure-based drug designs such as structural optimization, high-speed and high-precision docking, and molecular dynamics calculations.

摘要

在这里，我们构建了基于神经网络的模型，这些模型可以以较低的计算成本高精度地预测原子部分电荷。该模型使用碎片分子轨道方法从量子力学计算中获得的高质量数据进行训练。我们成功地为三个具有代表性的蛋白质分子系统获得了高度准确的原子部分电荷，其中包括一个大型生物分子（约 2000 个原子）。我们方法的新颖之处在于能够考虑系统中的电子极化，这是一种系统相关的现象，在药物设计领域很重要。我们高精度的模型可用于预测原子部分电荷，并有望广泛应用于基于结构的药物设计，如结构优化、高速高精度对接和分子动力学计算。

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利用片段分子轨道计算和机器学习对蛋白质系统进行高精度原子电荷预测。

High-Precision Atomic Charge Prediction for Protein Systems Using Fragment Molecular Orbital Calculation and Machine Learning.

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