Effect of Salvia miltiorrhiza on acetylcholinesterase: Enzyme kinetics and interaction mechanism merging with molecular docking analysis

Acetylcholinesterase (AchE) serves as an important target for Alzheimer's disease. Salvia miltiorrhiza has been used to treat cardiovascular disease for hundreds of years. However, the interaction between S. miltiorrhiza and AchE is still inadequate. Herein, an integrated method including molec...

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Published in:International journal of biological macromolecules 2019-08, Vol.135, p.303-313
Main Authors: Tang, Hongjin, Song, Ping, Li, Jun, Zhao, Dongsheng
Format: Article
Language:English
Subjects:
Acetylcholinesterase
Acetylcholinesterase - chemistry
Acetylcholinesterase - metabolism
Algorithms
Binding Sites
Cholinesterase Inhibitors - chemistry
Cholinesterase Inhibitors - pharmacology
Enzyme Activation - drug effects
Humans
Interaction mechanism
Kinetics
Molecular Conformation
Molecular Docking Simulation
Molecular Dynamics Simulation
Plant Extracts - chemistry
Plant Extracts - pharmacology
Protein Binding
Salvia miltiorrhiza
Salvia miltiorrhiza - chemistry
Spectrum Analysis
Structure-Activity Relationship
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container_title International journal of biological macromolecules
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creator Tang, Hongjin
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Li, Jun
Zhao, Dongsheng
description Acetylcholinesterase (AchE) serves as an important target for Alzheimer's disease. Salvia miltiorrhiza has been used to treat cardiovascular disease for hundreds of years. However, the interaction between S. miltiorrhiza and AchE is still inadequate. Herein, an integrated method including molecular docking and experimental studies was employed to investigate the interaction. Consequently, some components were screened as potent AchE inhibitors by in silico and in vitro. Among them, miltirone (MT) and salvianolic acid A (SAA) reversibly inhibited AchE in a mixed-competitive manner. Fluorescence data revealed that SAA and salvianolic acid C (SAC) strongly quenched the intrinsic fluorescence of AchE through a static quenching mechanism, and the binding was spontaneous and dominated by hydrophobic interaction inferred by the thermodynamic parameters. The synchronous and ANS-binding fluorescence spectra suggested that SAA and SAC could bind to the enzyme and induce its conformation changes of secondary structures, which was further confirmed by Fourier transform infrared spectra. Meanwhile, molecular docking presented the probable binding modes of inhibitors to AchE and highlighted the key role of hydrophobic interaction and hydrogen bonds for the stability of docking complex. These findings put more insights into understanding the interaction of S. miltiorrhiza chemicals and AchE, as well as Alzheimer's disease. [Display omitted] •Herb-AchE interaction inspires the study on AchE binding of Salvia miltiorrhiza.•MT and SAA were found as potent AchE inhibitors by in silico and in vitro.•SAA induced the conformation changes of secondary structures of AchE.•Hydrophobic interactions and hydrogen bonds were of great importance for the interaction.
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Salvia miltiorrhiza has been used to treat cardiovascular disease for hundreds of years. However, the interaction between S. miltiorrhiza and AchE is still inadequate. Herein, an integrated method including molecular docking and experimental studies was employed to investigate the interaction. Consequently, some components were screened as potent AchE inhibitors by in silico and in vitro. Among them, miltirone (MT) and salvianolic acid A (SAA) reversibly inhibited AchE in a mixed-competitive manner. Fluorescence data revealed that SAA and salvianolic acid C (SAC) strongly quenched the intrinsic fluorescence of AchE through a static quenching mechanism, and the binding was spontaneous and dominated by hydrophobic interaction inferred by the thermodynamic parameters. The synchronous and ANS-binding fluorescence spectra suggested that SAA and SAC could bind to the enzyme and induce its conformation changes of secondary structures, which was further confirmed by Fourier transform infrared spectra. Meanwhile, molecular docking presented the probable binding modes of inhibitors to AchE and highlighted the key role of hydrophobic interaction and hydrogen bonds for the stability of docking complex. These findings put more insights into understanding the interaction of S. miltiorrhiza chemicals and AchE, as well as Alzheimer's disease. [Display omitted] •Herb-AchE interaction inspires the study on AchE binding of Salvia miltiorrhiza.•MT and SAA were found as potent AchE inhibitors by in silico and in vitro.•SAA induced the conformation changes of secondary structures of AchE.•Hydrophobic interactions and hydrogen bonds were of great importance for the interaction.</description><identifier>ISSN: 0141-8130</identifier><identifier>EISSN: 1879-0003</identifier><identifier>DOI: 10.1016/j.ijbiomac.2019.05.132</identifier><identifier>PMID: 31128195</identifier><language>eng</language><publisher>Netherlands: Elsevier B.V</publisher><subject>Acetylcholinesterase ; Acetylcholinesterase - chemistry ; Acetylcholinesterase - metabolism ; Algorithms ; Binding Sites ; Cholinesterase Inhibitors - chemistry ; Cholinesterase Inhibitors - pharmacology ; Enzyme Activation - drug effects ; Humans ; Interaction mechanism ; Kinetics ; Molecular Conformation ; Molecular Docking Simulation ; Molecular Dynamics Simulation ; Plant Extracts - chemistry ; Plant Extracts - pharmacology ; Protein Binding ; Salvia miltiorrhiza ; Salvia miltiorrhiza - chemistry ; Spectrum Analysis ; Structure-Activity Relationship</subject><ispartof>International journal of biological macromolecules, 2019-08, Vol.135, p.303-313</ispartof><rights>2019 Elsevier B.V.</rights><rights>Copyright © 2019 Elsevier B.V. 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Salvia miltiorrhiza has been used to treat cardiovascular disease for hundreds of years. However, the interaction between S. miltiorrhiza and AchE is still inadequate. Herein, an integrated method including molecular docking and experimental studies was employed to investigate the interaction. Consequently, some components were screened as potent AchE inhibitors by in silico and in vitro. Among them, miltirone (MT) and salvianolic acid A (SAA) reversibly inhibited AchE in a mixed-competitive manner. Fluorescence data revealed that SAA and salvianolic acid C (SAC) strongly quenched the intrinsic fluorescence of AchE through a static quenching mechanism, and the binding was spontaneous and dominated by hydrophobic interaction inferred by the thermodynamic parameters. 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The synchronous and ANS-binding fluorescence spectra suggested that SAA and SAC could bind to the enzyme and induce its conformation changes of secondary structures, which was further confirmed by Fourier transform infrared spectra. Meanwhile, molecular docking presented the probable binding modes of inhibitors to AchE and highlighted the key role of hydrophobic interaction and hydrogen bonds for the stability of docking complex. These findings put more insights into understanding the interaction of S. miltiorrhiza chemicals and AchE, as well as Alzheimer's disease. 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subjects Acetylcholinesterase
Acetylcholinesterase - chemistry
Acetylcholinesterase - metabolism
Algorithms
Binding Sites
Cholinesterase Inhibitors - chemistry
Cholinesterase Inhibitors - pharmacology
Enzyme Activation - drug effects
Humans
Interaction mechanism
Kinetics
Molecular Conformation
Molecular Docking Simulation
Molecular Dynamics Simulation
Plant Extracts - chemistry
Plant Extracts - pharmacology
Protein Binding
Salvia miltiorrhiza
Salvia miltiorrhiza - chemistry
Spectrum Analysis
Structure-Activity Relationship
title Effect of Salvia miltiorrhiza on acetylcholinesterase: Enzyme kinetics and interaction mechanism merging with molecular docking analysis
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