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

Koichiro Kato; Tomohide Masuda; Chiduru Watanabe; Naoki Miyagawa; Hideo Mizouchi; Shumpei Nagase; Kikuko Kamisaka; Kanji Oshima; Satoshi Ono; Hiroshi Ueda; Atsushi Tokuhisa; Ryo Kanada; Masateru Ohta; Mitsunori Ikeguchi; Yasushi Okuno; Kaori Fukuzawa; Teruki Honma

doi:10.1021/acs.jcim.0c00273

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

Koichiro Kato, Tomohide Masuda, Chiduru Watanabe, Naoki Miyagawa, Hideo Mizouchi, Shumpei Nagase, Kikuko Kamisaka, Kanji Oshima, Satoshi Ono, Hiroshi Ueda, Atsushi Tokuhisa, Ryo Kanada, Masateru Ohta, Mitsunori Ikeguchi, Yasushi Okuno, Kaori Fukuzawa, Teruki Honma

Research output: Contribution to journal › Article › peer-review

16 Citations (Scopus)

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.

Original language	English
Pages (from-to)	3361-3368
Number of pages	8
Journal	Journal of chemical information and modeling
Volume	60
Issue number	7
DOIs	https://doi.org/10.1021/acs.jcim.0c00273
Publication status	Published - 2020 Jul 27
Externally published	Yes

ASJC Scopus subject areas

Chemistry(all)
Chemical Engineering(all)
Computer Science Applications
Library and Information Sciences

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10.1021/acs.jcim.0c00273

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Kato, K., Masuda, T., Watanabe, C., Miyagawa, N., Mizouchi, H., Nagase, S., Kamisaka, K., Oshima, K., Ono, S., Ueda, H., Tokuhisa, A., Kanada, R., Ohta, M., Ikeguchi, M., Okuno, Y., Fukuzawa, K., & Honma, T. (2020). High-Precision Atomic Charge Prediction for Protein Systems Using Fragment Molecular Orbital Calculation and Machine Learning. Journal of chemical information and modeling, 60(7), 3361-3368. https://doi.org/10.1021/acs.jcim.0c00273

Kato, K, Masuda, T, Watanabe, C, Miyagawa, N, Mizouchi, H, Nagase, S, Kamisaka, K, Oshima, K, Ono, S, Ueda, H, Tokuhisa, A, Kanada, R, Ohta, M, Ikeguchi, M, Okuno, Y, Fukuzawa, K & Honma, T 2020, 'High-Precision Atomic Charge Prediction for Protein Systems Using Fragment Molecular Orbital Calculation and Machine Learning', Journal of chemical information and modeling, vol. 60, no. 7, pp. 3361-3368. https://doi.org/10.1021/acs.jcim.0c00273

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title = "High-Precision Atomic Charge Prediction for Protein Systems Using Fragment Molecular Orbital Calculation and Machine Learning",

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.",

author = "Koichiro Kato and Tomohide Masuda and Chiduru Watanabe and Naoki Miyagawa and Hideo Mizouchi and Shumpei Nagase and Kikuko Kamisaka and Kanji Oshima and Satoshi Ono and Hiroshi Ueda and Atsushi Tokuhisa and Ryo Kanada and Masateru Ohta and Mitsunori Ikeguchi and Yasushi Okuno and Kaori Fukuzawa and Teruki Honma",

note = "Funding Information: The authors gratefully acknowledge Dr. Shuntaro Chiba for his fruitful discussion, Dr. Yoshio Okiyama for useful comments of quantum atomic charge, Dr. Tomohiro Sato for an essential suggestion of machine learning dataset, and Prof. Yuji Mochizuki and Dr. Hiromasa Watanabe for their technical support of ABINIT-MP program. This research was conducted as part of the activities of the Life Intelligence Consortium (LINC, https://linc-ai.jp/ ), the FMO Drug Design Consortium (FMODD, https://fmodd.jp/ ), the Research Complex Promotion Program from the Japan Science and Technology Agency (RCH, https://rc.rien.jp ), and the FOCUS Establishing Supercomputing Center of Excellence. The FMO calculations were performed on the K computer (project IDs: hp150160, hp160103, hp170183, and hp180147; Riken Advanced Institute for Computational Science, Hyogo, Japan), the HOKUSAI supercomputer (RIKEN Advanced Center for Computing and Communications, Yokohama, Japan), and the TSUBAME3.0 supercomputer (Tokyo Institute of Technology, Tokyo, Japan). Funding Information: This research was partially supported by the Platform Project for Supporting Drug Discovery and Life Science Research (Basis for Supporting Innovative Drug Discovery and Life Science Research (BINDS)) of the Japan Agency for Medical Research and Development (AMED) under grant number JP19am0101113. Publisher Copyright: Copyright {\textcopyright} 2020 American Chemical Society.",

year = "2020",

month = jul,

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doi = "10.1021/acs.jcim.0c00273",

language = "English",

volume = "60",

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T1 - High-Precision Atomic Charge Prediction for Protein Systems Using Fragment Molecular Orbital Calculation and Machine Learning

AU - Kato, Koichiro

AU - Masuda, Tomohide

AU - Watanabe, Chiduru

AU - Miyagawa, Naoki

AU - Mizouchi, Hideo

AU - Nagase, Shumpei

AU - Kamisaka, Kikuko

AU - Oshima, Kanji

AU - Ono, Satoshi

AU - Ueda, Hiroshi

AU - Tokuhisa, Atsushi

AU - Kanada, Ryo

AU - Ohta, Masateru

AU - Ikeguchi, Mitsunori

AU - Okuno, Yasushi

AU - Fukuzawa, Kaori

AU - Honma, Teruki

N1 - Funding Information: The authors gratefully acknowledge Dr. Shuntaro Chiba for his fruitful discussion, Dr. Yoshio Okiyama for useful comments of quantum atomic charge, Dr. Tomohiro Sato for an essential suggestion of machine learning dataset, and Prof. Yuji Mochizuki and Dr. Hiromasa Watanabe for their technical support of ABINIT-MP program. This research was conducted as part of the activities of the Life Intelligence Consortium (LINC, https://linc-ai.jp/ ), the FMO Drug Design Consortium (FMODD, https://fmodd.jp/ ), the Research Complex Promotion Program from the Japan Science and Technology Agency (RCH, https://rc.rien.jp ), and the FOCUS Establishing Supercomputing Center of Excellence. The FMO calculations were performed on the K computer (project IDs: hp150160, hp160103, hp170183, and hp180147; Riken Advanced Institute for Computational Science, Hyogo, Japan), the HOKUSAI supercomputer (RIKEN Advanced Center for Computing and Communications, Yokohama, Japan), and the TSUBAME3.0 supercomputer (Tokyo Institute of Technology, Tokyo, Japan). Funding Information: This research was partially supported by the Platform Project for Supporting Drug Discovery and Life Science Research (Basis for Supporting Innovative Drug Discovery and Life Science Research (BINDS)) of the Japan Agency for Medical Research and Development (AMED) under grant number JP19am0101113. Publisher Copyright: Copyright © 2020 American Chemical Society.

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N2 - 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.

AB - 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.

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

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