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TARP 相关的 AMPA 受体表现出增强的最大通道电导和多种动力学上不同的开放状态。

TARP-associated AMPA receptors display an increased maximum channel conductance and multiple kinetically distinct open states.

机构信息

Department of Neuroscience, University College London, Gower Street, London WC1E 6BT, UK.

出版信息

J Physiol. 2012 Nov 15;590(22):5723-38. doi: 10.1113/jphysiol.2012.238006. Epub 2012 Sep 17.

DOI:10.1113/jphysiol.2012.238006
PMID:22988139
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3528987/
Abstract

Fast excitatory synaptic transmission in the CNS is mediated mainly by AMPA-type glutamate receptors (AMPARs), whose biophysical properties are dramatically modulated by the presence of transmembrane AMPAR regulatory proteins (TARPs). To help construct a kinetic model that will realistically describe native AMPAR/TARP function, we have examined the single-channel properties of homomeric GluA1 AMPARs in combination with the TARPs, γ-2, γ-4 and γ-5. In a saturating concentration of agonist, each of these AMPAR/TARP combinations gave rise to single-channel currents with multiple conductance levels that appeared intrinsic to the receptor-channel complex, and showed long-lived subconductance states. The open time and burst length distributions of the receptor complexes displayed multiple dwell-time components. In the case of γ-2- and γ-4-associated receptors, these distributions included a long-lived component lasting tens of milliseconds that was absent from both GluA1 alone and γ-5-associated receptors. The open time distributions for each conductance level required two dwell-time components, indicating that at each conductance level the channel occupies a minimum of two kinetically distinct open states. We have explored how these data place novel constraints on possible kinetic models of TARP-associated AMPARs that may be used to define AMPAR-mediated synaptic transmission.

摘要

中枢神经系统中的快速兴奋性突触传递主要由 AMPA 型谷氨酸受体 (AMPARs) 介导,其生物物理特性受跨膜 AMPAR 调节蛋白 (TARPs) 的显著调节。为了帮助构建一个能够真实描述天然 AMPAR/TARP 功能的动力学模型,我们研究了同型 GluA1 AMPAR 与 TARPs γ-2、γ-4 和 γ-5 的结合的单通道特性。在激动剂的饱和浓度下,这些 AMPAR/TARP 组合中的每一种都会产生具有多种电导水平的单通道电流,这些电导水平似乎是受体通道复合物的固有特性,并表现出长寿命的亚电导状态。受体复合物的开放时间和爆发长度分布显示出多个停留时间分量。在 γ-2 和 γ-4 相关受体的情况下,这些分布包括一个持续数十毫秒的长寿命分量,而在单独的 GluA1 和 γ-5 相关受体中都不存在。每个电导水平的开放时间分布需要两个停留时间分量,表明在每个电导水平下,通道至少占据两个动力学上不同的开放状态。我们探讨了这些数据如何对可能用于定义 AMPAR 介导的突触传递的 TARP 相关 AMPAR 的可能动力学模型施加新的限制。

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