三重再摄取抑制剂从单胺转运体解离的拉伸分子动力学模拟研究

涂高; 姚小军<sup>*</sup>; 薛伟伟<sup>*</sup>

引用本文:	涂高,姚小军,薛伟伟.三重再摄取抑制剂从单胺转运体解离的拉伸分子动力学模拟研究[J].中国现代应用药学,2022,39(21):2887-2893.
	TU Gao,YAO Xiaojun,XUE Weiwei.Study on the Unbinding of Triple Reuptake Inhibitor from Monoamine Transporters by Steered Molecular Dynamics Simulations[J].Chin J Mod Appl Pharm(中国现代应用药学),2022,39(21):2887-2893.

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三重再摄取抑制剂从单胺转运体解离的拉伸分子动力学模拟研究
涂高^1,2, 姚小军², 薛伟伟¹
1.重庆大学药学院, 重庆 401331;2.澳门科技大学中药质量研究国家重点实验室, 澳门药物及健康应用研究院, 埃尔文内尔博士生物物理与创新药物实验室, 中国澳门 999078

摘要:

目的研究三重再摄取抑制剂(triple reuptake inhibitors，TRIs)与人类单胺转运体(human monoamine transporters，hMATs)的解离机制。方法采用拉伸分子动力学的方法模拟3个TRIs从hSERT、hNET和hDAT主要结合位点解离的动态过程；通过计算解离过程中施加的外力随模拟时间的变化，分析抑制剂解离过程中重要的蛋白-配体间的相互作用；最后通过Jarzynski方程的二次累积展开式计算抑制剂在3种转运蛋白的平均力势。结果力谱图曲线表明影响TRIs解离的残基在单胺转运蛋白上的分布主要如下：跨膜区域(TM1b、TM3、TM6a、TM10)和胞外Loop区域(EL2、EL4、EL5、EL6)，其中主要结合口袋附近的残基极大地阻碍TRIs的解离。比较每个体系的平均力势数值，结果表明EB1020相比NS2359和SEP225289更容易从蛋白中解离。结论本研究从原子水平揭示了hMATs与TRIs结合-解离机制，为基于结构的选择性抗抑郁药物设计提供了理论依据。

关键词: 单胺转运体三重再摄取抑制剂拉伸分子动力学模拟解离机制

DOI：10.13748/j.cnki.issn1007-7693.2022.21.027

分类号:R913

基金项目:国家自然科学基金青年基金项目(21505009)

Study on the Unbinding of Triple Reuptake Inhibitor from Monoamine Transporters by Steered Molecular Dynamics Simulations

TU Gao^1,2, YAO Xiaojun², XUE Weiwei¹

1.School of Pharmaceutical Sciences, Chongqing University, Chongqing 401331, China;2.State Key Laboratory of Quality Research in Chinese Medicine, Macau Institute for Applied Research in Medicine and Health, Dr. Neher's Biophysics Laboratory for Innovative Drug Discovery, Macau University of Science and Technology, Macau 999078, China

Abstract:

OBJECTIVE To investigate the unbinding mechanism between triple reuptake inhibitors(TRIs) and human monoamine transporters(hMATs). METHODS Steered molecular dynamics was used to explore the unbinding process of three inhibitors from hSERT, hNET and hDAT. The important protein-ligand interactions during dissociation were analyzed by calculating the external force-time profiles. Finally, the results of potential of mean force of the three inhibitors in each transporter were calculated by using the second cumulant expansion of Jarzynski’s equality. RESULTS The force-time curve indicated that residues located in transmembrane domains(TM1b, TM3, TM6a and TM10) and extracellular loops domains(EL2, EL4, EL5 and EL6) were mainly involved in the ligand unbinding. The residues were located on the center binding site of protein could greatly hinder ligand dissociation. The average power potential of each system was computed and the result denoted that the dissociation of EB1020 from the hMATs was easier than that of NS2359 and SEP225289. CONCLUSION This study reveals the unbinding dissociation mechanism of hMATs and TRIs at the atomic level, which provides a theoretical basis for structure-based antidepressant drug design with higher potency and selectivity.

Key words: steered molecular dynamics human monoamine transporters triple reuptake inhibitors dissociation mechanism