Molecular Insights into the Intrinsic Dynamics and Their Roles During Catalysis in Pin1 Peptidyl-prolyl Isomerase - Collections | Kyushu University Library

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＜journal article＞
Molecular Insights into the Intrinsic Dynamics and Their Roles During Catalysis in Pin1 Peptidyl-prolyl Isomerase

Creator	Author PID K007665 0000-0003-0188-0794 Creator Name Mori, Toshifumi 森, 俊文モリ, トシフミ Affiliation Affiliation Name Institute for Materials Chemistry and Engineering, Kyushu University 九州大学先導物質化学研究所 Affiliation Affiliation Name Interdisciplinary Graduate School of Engineering Sciences, Kyushu University 九州大学大学院総合理工学府
Creator	Author PID 70262847 0000-0003-4982-4820 Creator Name Saito, Shinji 斉藤, 真司サイトウ, シンジ Affiliation Affiliation Name Institute for Molecular Science 分子科学研究所
Language	English
Publisher	American Chemical Society
Date	2022-07-21
Source Title	Journal of Physical Chemistry B
Vol	126
Issue	28
First Page	5185
Last Page	5193
Publication Type	Accepted Manuscript
Access Rights	open access
Rights	This document is the Accepted Manuscript version of a Published Work that appeared in final form in The Journal of Physical Chemistry B, copyright ©2023 American Chemical Society after peer review and technical editing by the publisher. To access the final edited and published work see Related DOI.
Related DOI	isVersionOf https://doi.org/10.1021/acs.jpcb.2c02095
Related DOI
Abstract	Proteins are intrinsically dynamic and change conformations over a wide range of time scales. While the conformational dynamics have been realized to be important for protein functions, e.g., in activ...ity–stability trade-offs, how they play a role during enzyme catalysis has been of debate over decades. By studying Pin1 peptidyl-prolyl isomerase using extensive molecular dynamics simulations, here we discuss how the slow intrinsic dynamics of Pin1 observed in the NMR relaxation dispersion experiment occur and couple to isomerization reactions in molecular detail. In particular, we analyze the angular correlation functions of the backbone N–H bonds and find that slow conformational transitions occur at about the 3_10 helix in the apo state. These events at the helical region further affect the residues at about the ligand binding site. Unfolding of this helix leads to a tight hydrogen bond between the helical region and the ligand binding loop, thus forming a stable coiled structure. The helical and coiled structures are found to be characteristic of the Pin1–ligand complex with the ligand in the trans and cis states, respectively. These results indicate that the changes in the slow dynamics of Pin1 by the isomerization reaction occur via the shift in populations of the helical and coiled states, where the balance is dependent on the ligand isomerization states.show more

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PISSN	1520-6106
EISSN	1520-5207
NCID	AA11114073
Record ID	6789517
Related PubMed ID	35795989
Type	Article
Funding Information	Funder Name Japan Society for the Promotion of Science (JSPS) 日本学術振興会 Award Number 18K05049 Award Title Theoretical study of enzymatic reaction dynamics 酵素反応の動的機構の理論的解明
	Funder Name Japan Society for the Promotion of Science (JSPS) 日本学術振興会 Award Number 22H02035 Award Title Theoretical study on the molecular mechanism of conformational transitions and catalysis in enzymes 酵素の構造ダイナミクスと活性制御の分子機構の理論的解明
	Funder Name Japan Society for the Promotion of Science (JSPS) 日本学術振興会 Award Number 21H04676 Award Title Theoretical study of efficient excitation energy transfer in light-harvesting antenna of higher plants 高等植物の光捕集アンテナタンパク質における効率的励起エネルギー移動の理論研究
Created Date	2023.06.02
Modified Date	2023.12.08