Structures and mechanisms of actin ATP hydrolysis

Yusuke Kanematsu; Akihiro Narita; Toshiro Oda; Ryotaro Koike; Motonori Ota; Yu Takano; Kei Moritsugu; Ikuko Fujiwara; Kotaro Tanaka; Hideyuki Komatsu; Takayuki Nagae; Nobuhisa Watanabe; Mitsusada Iwasa; Yuichiro Maéda; Shuichi Takeda

doi:10.1073/pnas.2122641119

Structures and mechanisms of actin ATP hydrolysis

Yusuke Kanematsu, Akihiro Narita, Toshiro Oda, Ryotaro Koike, Motonori Ota, Yu Takano, Kei Moritsugu, Ikuko Fujiwara, Kotaro Tanaka, Hideyuki Komatsu, Takayuki Nagae, Nobuhisa Watanabe, Mitsusada Iwasa, Yuichiro Maéda, Shuichi Takeda

Research Institute for Interdisciplinary Science

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

Abstract

The major cytoskeleton protein actin undergoes cyclic transitions between the monomeric G-form and the filamentous F-form, which drive organelle transport and cell motility. This mechanical work is driven by the ATPase activity at the catalytic site in the F-form. For deeper understanding of the actin cellular functions, the reaction mechanism must be elucidated. Here, we show that a single actin molecule is trapped in the F-form by fragmin domain-1 binding and present their crystal structures in the ATP analog-, ADP-Pi-, and ADP-bound forms, at 1.15-Å resolutions. The G-to-F conformational transition shifts the side chains of Gln137 and His161, which relocate four water molecules including W1 (attacking water) and W2 (helping water) to facilitate the hydrolysis. By applying quantum mechanics/molecular mechanics calculations to the structures, we have revealed a consistent and comprehensive reaction path of ATP hydrolysis by the F-form actin. The reaction path consists of four steps: 1) W1 and W2 rotations; 2) P^G–O^3B bond cleavage; 3) four concomitant events: W1–PO₃² formation, OH² and proton cleavage, nucleophilic attack by the OH² against P^G, and the abstracted proton transfer; and 4) proton relocation that stabilizes the ADP-Pi–bound F-form actin. The mechanism explains the slow rate of ATP hydrolysis by actin and the irreversibility of the hydrolysis reaction. While the catalytic strategy of actin ATP hydrolysis is essentially the same as those of motor proteins like myosin, the process after the hydrolysis is distinct and discussed in terms of Pi release, F-form destabilization, and global conformational changes.

Original language	English
Article number	e2122641119
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	119
Issue number	43
DOIs	https://doi.org/10.1073/pnas.2122641119
Publication status	Published - Oct 25 2022

Keywords

actin
ATP hydrolysis
protein crystallography
QM/MM simulation

ASJC Scopus subject areas

General

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10.1073/pnas.2122641119

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Kanematsu, Y., Narita, A., Oda, T., Koike, R., Ota, M., Takano, Y., Moritsugu, K., Fujiwara, I., Tanaka, K., Komatsu, H., Nagae, T., Watanabe, N., Iwasa, M., Maéda, Y., & Takeda, S. (2022). Structures and mechanisms of actin ATP hydrolysis. Proceedings of the National Academy of Sciences of the United States of America, 119(43), [e2122641119]. https://doi.org/10.1073/pnas.2122641119

Kanematsu, Y, Narita, A, Oda, T, Koike, R, Ota, M, Takano, Y, Moritsugu, K, Fujiwara, I, Tanaka, K, Komatsu, H, Nagae, T, Watanabe, N, Iwasa, M, Maéda, Y & Takeda, S 2022, 'Structures and mechanisms of actin ATP hydrolysis', Proceedings of the National Academy of Sciences of the United States of America, vol. 119, no. 43, e2122641119. https://doi.org/10.1073/pnas.2122641119

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title = "Structures and mechanisms of actin ATP hydrolysis",

abstract = "The major cytoskeleton protein actin undergoes cyclic transitions between the monomeric G-form and the filamentous F-form, which drive organelle transport and cell motility. This mechanical work is driven by the ATPase activity at the catalytic site in the F-form. For deeper understanding of the actin cellular functions, the reaction mechanism must be elucidated. Here, we show that a single actin molecule is trapped in the F-form by fragmin domain-1 binding and present their crystal structures in the ATP analog-, ADP-Pi-, and ADP-bound forms, at 1.15-{\AA} resolutions. The G-to-F conformational transition shifts the side chains of Gln137 and His161, which relocate four water molecules including W1 (attacking water) and W2 (helping water) to facilitate the hydrolysis. By applying quantum mechanics/molecular mechanics calculations to the structures, we have revealed a consistent and comprehensive reaction path of ATP hydrolysis by the F-form actin. The reaction path consists of four steps: 1) W1 and W2 rotations; 2) PG–O3B bond cleavage; 3) four concomitant events: W1–PO32 formation, OH2 and proton cleavage, nucleophilic attack by the OH2 against PG, and the abstracted proton transfer; and 4) proton relocation that stabilizes the ADP-Pi–bound F-form actin. The mechanism explains the slow rate of ATP hydrolysis by actin and the irreversibility of the hydrolysis reaction. While the catalytic strategy of actin ATP hydrolysis is essentially the same as those of motor proteins like myosin, the process after the hydrolysis is distinct and discussed in terms of Pi release, F-form destabilization, and global conformational changes.",

keywords = "actin, ATP hydrolysis, protein crystallography, QM/MM simulation",

author = "Yusuke Kanematsu and Akihiro Narita and Toshiro Oda and Ryotaro Koike and Motonori Ota and Yu Takano and Kei Moritsugu and Ikuko Fujiwara and Kotaro Tanaka and Hideyuki Komatsu and Takayuki Nagae and Nobuhisa Watanabe and Mitsusada Iwasa and Yuichiro Ma{\'e}da and Shuichi Takeda",

note = "Funding Information: ACKNOWLEDGMENTS. We thank J. Gettemans (Ghent University) for the kind gift of the fragmin complementary DNA; S. Fischer (Heidelberg University) for valuable advice at the early stage of our QM/MM simulations; Atsushi Nakagawa and Kota Nagano (Osaka University) for ITC measurements; and Yasunori Saitoh, Michihiro Suga, and Jian-Ren Shen (Okayama University) for HPLC measurements. The X-ray diffraction data sets were collected at beamline BL2S1 (Aichi SR, Japan) under the proposals 2016N6009-10, 6013, 2017N6007, 2018N5002, 5004, and 6005. We thank the beamline staff for their technical assistance. The QM/MM computations were performed using the Research Center for Computational Science, Okazaki, Japan. This work was supported by Japan Society for the Promotion of Science grants KAKENHI 26251017 (to Y.M. and A.N.), 16K17708 and 20K06522 (to S.T.), 17J08102 (to Y.K.), 20H05883 (to Y.T.), 17K07373 (to T.O., I.F., and S.T.), and 21H00394 and 19K12217 (to R.K.) and by Japan Agency for Medical Research and Development grant JP21am0101111 (to M.O.). Support to Y.M. from Takeda Science Foundation, Daiko Foundation, Toyota Riken, and Actin Research Association is acknowledged. Encouragement and advice from the late Sadashi Hatano and the late Fumio Oosawa are gratefully acknowledged. Funding Information: We thank J. Gettemans (Ghent University) for the kind gift of the fragmin complementary DNA; S. Fischer (Heidelberg University) for valuable advice at the early stage of our QM/MM simulations; Atsushi Nakagawa and Kota Nagano (Osaka University) for ITC measurements; and Yasunori Saitoh, Michihiro Suga, and Jian-Ren Shen (Okayama University) for HPLC measurements. The X-ray diffraction data sets were collected at beamline BL2S1 (Aichi SR, Japan) under the proposals 2016N6009-10, 6013, 2017N6007, 2018N5002, 5004, and 6005. We thank the beamline staff for their technical assistance. The QM/MM computations were performed using the Research Center for Computational Science, Okazaki, Japan. This work was supported by Japan Society for the Promotion of Science grants KAKENHI 26251017 (to Y.M. and A.N.), 16K17708 and 20K06522 (to S.T.), 17J08102 (to Y.K.), 20H05883 (to Y.T.), 17K07373 (to T.O., I.F., and S.T.), and 21H00394 and 19K12217 (to R.K.) and by Japan Agency for Medical Research and Development grant JP21am0101111 (to M.O.). Support to Y.M. from Takeda Science Foundation, Daiko Foundation, Toyota Riken, and Actin Research Association is acknowledged. Encouragement and advice from the late Sadashi Hatano and the late Fumio Oosawa are gratefully acknowledged. Publisher Copyright: {\textcopyright} 2022 the Author(s). Published by PNAS.",

year = "2022",

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doi = "10.1073/pnas.2122641119",

language = "English",

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journal = "Proceedings of the National Academy of Sciences of the United States of America",

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TY - JOUR

T1 - Structures and mechanisms of actin ATP hydrolysis

AU - Kanematsu, Yusuke

AU - Narita, Akihiro

AU - Oda, Toshiro

AU - Koike, Ryotaro

AU - Ota, Motonori

AU - Takano, Yu

AU - Moritsugu, Kei

AU - Fujiwara, Ikuko

AU - Tanaka, Kotaro

AU - Komatsu, Hideyuki

AU - Nagae, Takayuki

AU - Watanabe, Nobuhisa

AU - Iwasa, Mitsusada

AU - Maéda, Yuichiro

AU - Takeda, Shuichi

N1 - Funding Information: ACKNOWLEDGMENTS. We thank J. Gettemans (Ghent University) for the kind gift of the fragmin complementary DNA; S. Fischer (Heidelberg University) for valuable advice at the early stage of our QM/MM simulations; Atsushi Nakagawa and Kota Nagano (Osaka University) for ITC measurements; and Yasunori Saitoh, Michihiro Suga, and Jian-Ren Shen (Okayama University) for HPLC measurements. The X-ray diffraction data sets were collected at beamline BL2S1 (Aichi SR, Japan) under the proposals 2016N6009-10, 6013, 2017N6007, 2018N5002, 5004, and 6005. We thank the beamline staff for their technical assistance. The QM/MM computations were performed using the Research Center for Computational Science, Okazaki, Japan. This work was supported by Japan Society for the Promotion of Science grants KAKENHI 26251017 (to Y.M. and A.N.), 16K17708 and 20K06522 (to S.T.), 17J08102 (to Y.K.), 20H05883 (to Y.T.), 17K07373 (to T.O., I.F., and S.T.), and 21H00394 and 19K12217 (to R.K.) and by Japan Agency for Medical Research and Development grant JP21am0101111 (to M.O.). Support to Y.M. from Takeda Science Foundation, Daiko Foundation, Toyota Riken, and Actin Research Association is acknowledged. Encouragement and advice from the late Sadashi Hatano and the late Fumio Oosawa are gratefully acknowledged. Funding Information: We thank J. Gettemans (Ghent University) for the kind gift of the fragmin complementary DNA; S. Fischer (Heidelberg University) for valuable advice at the early stage of our QM/MM simulations; Atsushi Nakagawa and Kota Nagano (Osaka University) for ITC measurements; and Yasunori Saitoh, Michihiro Suga, and Jian-Ren Shen (Okayama University) for HPLC measurements. The X-ray diffraction data sets were collected at beamline BL2S1 (Aichi SR, Japan) under the proposals 2016N6009-10, 6013, 2017N6007, 2018N5002, 5004, and 6005. We thank the beamline staff for their technical assistance. The QM/MM computations were performed using the Research Center for Computational Science, Okazaki, Japan. This work was supported by Japan Society for the Promotion of Science grants KAKENHI 26251017 (to Y.M. and A.N.), 16K17708 and 20K06522 (to S.T.), 17J08102 (to Y.K.), 20H05883 (to Y.T.), 17K07373 (to T.O., I.F., and S.T.), and 21H00394 and 19K12217 (to R.K.) and by Japan Agency for Medical Research and Development grant JP21am0101111 (to M.O.). Support to Y.M. from Takeda Science Foundation, Daiko Foundation, Toyota Riken, and Actin Research Association is acknowledged. Encouragement and advice from the late Sadashi Hatano and the late Fumio Oosawa are gratefully acknowledged. Publisher Copyright: © 2022 the Author(s). Published by PNAS.

PY - 2022/10/25

Y1 - 2022/10/25

N2 - The major cytoskeleton protein actin undergoes cyclic transitions between the monomeric G-form and the filamentous F-form, which drive organelle transport and cell motility. This mechanical work is driven by the ATPase activity at the catalytic site in the F-form. For deeper understanding of the actin cellular functions, the reaction mechanism must be elucidated. Here, we show that a single actin molecule is trapped in the F-form by fragmin domain-1 binding and present their crystal structures in the ATP analog-, ADP-Pi-, and ADP-bound forms, at 1.15-Å resolutions. The G-to-F conformational transition shifts the side chains of Gln137 and His161, which relocate four water molecules including W1 (attacking water) and W2 (helping water) to facilitate the hydrolysis. By applying quantum mechanics/molecular mechanics calculations to the structures, we have revealed a consistent and comprehensive reaction path of ATP hydrolysis by the F-form actin. The reaction path consists of four steps: 1) W1 and W2 rotations; 2) PG–O3B bond cleavage; 3) four concomitant events: W1–PO32 formation, OH2 and proton cleavage, nucleophilic attack by the OH2 against PG, and the abstracted proton transfer; and 4) proton relocation that stabilizes the ADP-Pi–bound F-form actin. The mechanism explains the slow rate of ATP hydrolysis by actin and the irreversibility of the hydrolysis reaction. While the catalytic strategy of actin ATP hydrolysis is essentially the same as those of motor proteins like myosin, the process after the hydrolysis is distinct and discussed in terms of Pi release, F-form destabilization, and global conformational changes.

AB - The major cytoskeleton protein actin undergoes cyclic transitions between the monomeric G-form and the filamentous F-form, which drive organelle transport and cell motility. This mechanical work is driven by the ATPase activity at the catalytic site in the F-form. For deeper understanding of the actin cellular functions, the reaction mechanism must be elucidated. Here, we show that a single actin molecule is trapped in the F-form by fragmin domain-1 binding and present their crystal structures in the ATP analog-, ADP-Pi-, and ADP-bound forms, at 1.15-Å resolutions. The G-to-F conformational transition shifts the side chains of Gln137 and His161, which relocate four water molecules including W1 (attacking water) and W2 (helping water) to facilitate the hydrolysis. By applying quantum mechanics/molecular mechanics calculations to the structures, we have revealed a consistent and comprehensive reaction path of ATP hydrolysis by the F-form actin. The reaction path consists of four steps: 1) W1 and W2 rotations; 2) PG–O3B bond cleavage; 3) four concomitant events: W1–PO32 formation, OH2 and proton cleavage, nucleophilic attack by the OH2 against PG, and the abstracted proton transfer; and 4) proton relocation that stabilizes the ADP-Pi–bound F-form actin. The mechanism explains the slow rate of ATP hydrolysis by actin and the irreversibility of the hydrolysis reaction. While the catalytic strategy of actin ATP hydrolysis is essentially the same as those of motor proteins like myosin, the process after the hydrolysis is distinct and discussed in terms of Pi release, F-form destabilization, and global conformational changes.

KW - actin

KW - ATP hydrolysis

KW - protein crystallography

KW - QM/MM simulation

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U2 - 10.1073/pnas.2122641119

DO - 10.1073/pnas.2122641119

M3 - Article

C2 - 36252034

AN - SCOPUS:85140271201

SN - 0027-8424

VL - 119

JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

IS - 43

M1 - e2122641119

ER -

Structures and mechanisms of actin ATP hydrolysis

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