Structural Biology and Bioinformatics Division, Indian Institute of Chemical Biology, (A unit of CSIR), 4 Raja S.C. Mullick Road, Jadavpur, Kolkata 700032, India.
J Mol Model. 2012 Apr;18(4):1345-54. doi: 10.1007/s00894-011-1142-0. Epub 2011 Jul 7.
To investigate the binding mode of Zolpidem to GABA(A) and to delineate the conformational changes induced upon agonist binding, we carried out atomistic molecular dynamics simulation using the ligand binding domain of GABA(A) α(1) receptor. Comparative molecular dynamics simulation of the apo and the holo form of GABA(A) receptor revealed that γ(2)/α(1) interface housing the benzodiazepine binding site undergoes distinct conformational changes upon Zolpidem binding. We notice that C loop of the α(1) subunit experiences an inward motion toward the vestibule and the F loop of γ(2) sways away from the vestibule, an observation that rationalizes Zolpidem as an alpha1 selective agonist. Energy decomposition analysis carried out was able to highlight the important residues implicated in Zolpidem binding, which were largely in congruence with the experimental data. The simulation study disclosed herein provides a meaningful insight into Zolpidem-GABA(A)R interactions and helps to arrive at a binding mode hypothesis with implications for drug design.
为了研究唑吡坦与 GABA(A) 的结合模式,并描绘激动剂结合诱导的构象变化,我们使用 GABA(A)α(1)受体的配体结合结构域进行了原子分子动力学模拟。GABA(A)受体的apo 和 holo 形式的比较分子动力学模拟表明,容纳苯二氮䓬结合位点的γ(2)/α(1)界面在唑吡坦结合时经历明显的构象变化。我们注意到,α(1)亚基的 C 环向前庭内部移动,γ(2)的 F 环从前庭摆动,这一观察结果表明唑吡坦是一种α1 选择性激动剂。进行的能量分解分析能够突出与唑吡坦结合相关的重要残基,这与实验数据基本一致。本文的模拟研究提供了对唑吡坦-GABA(A)R 相互作用的有意义的见解,并有助于提出具有药物设计意义的结合模式假设。
