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AMPA受体和海人酸受体中的结构域间相互作用调节对谷氨酸的亲和力。

Interdomain interactions in AMPA and kainate receptors regulate affinity for glutamate.

作者信息

Weston Matthew C, Gertler Christoph, Mayer Mark L, Rosenmund Christian

机构信息

Department of Neuroscience, Baylor College of Medicine, Houston, Texas 77030, USA.

出版信息

J Neurosci. 2006 Jul 19;26(29):7650-8. doi: 10.1523/JNEUROSCI.1519-06.2006.

DOI:10.1523/JNEUROSCI.1519-06.2006
PMID:16855092
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6674271/
Abstract

Ionotropic glutamate receptors perform diverse functions in the nervous system. As a result, multiple receptor subtypes have evolved with different kinetics, ion permeability, expression patterns, and regulation by second messengers. Kainate receptors show slower recovery from desensitization and have different affinities for agonists than AMPA receptors. Based on analysis of ligand binding domain crystal structures, we identified interdomain interactions in the agonist-bound state that are conserved in kainate receptors and absent in AMPA receptors. Mutations in GluR6 designed to disrupt these contacts reduced agonist apparent affinity, speeded up receptor deactivation and increased the rate of recovery from desensitization. Conversely, introduction of mutations in GluR2 that enabled additional interdomain interactions in the agonist-bound state increased agonist apparent affinity 15-fold, and slowed both deactivation and recovery from desensitization. We conclude that interdomain interactions have evolved as a distinct mechanism that contributes to the unique kinetic properties of AMPA and kainate receptors.

摘要

离子型谷氨酸受体在神经系统中发挥着多种功能。因此,多种受体亚型不断进化,具有不同的动力学、离子通透性、表达模式以及第二信使调节机制。与AMPA受体相比,海人藻酸受体脱敏后的恢复速度较慢,对激动剂的亲和力也有所不同。基于对配体结合域晶体结构的分析,我们确定了激动剂结合状态下的结构域间相互作用,这种相互作用在海人藻酸受体中保守存在,而在AMPA受体中不存在。设计用于破坏这些接触的GluR6突变降低了激动剂的表观亲和力,加快了受体失活,并提高了脱敏恢复速率。相反,在GluR2中引入突变,使其在激动剂结合状态下能够形成额外的结构域间相互作用,这使激动剂的表观亲和力提高了15倍,并减缓了失活和脱敏恢复速率。我们得出结论,结构域间相互作用已演变为一种独特机制,有助于AMPA和海人藻酸受体具有独特的动力学特性。

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