DRPEER：细胞外前庭中的一个基序，赋予NMDA受体通道高钙离子通量率。

DRPEER: a motif in the extracellular vestibule conferring high Ca2+ flux rates in NMDA receptor channels.

作者信息

Watanabe Junryo, Beck Christine, Kuner Thomas, Premkumar Louis S, Wollmuth Lonnie P

机构信息

Graduate Program in Neurobiology and Behavior, State University of New York at Stony Brook, Stony Brook, New York 11794-5230, USA.

出版信息

J Neurosci. 2002 Dec 1;22(23):10209-16. doi: 10.1523/JNEUROSCI.22-23-10209.2002.

DOI:10.1523/JNEUROSCI.22-23-10209.2002

PMID:12451122

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6758750/

Abstract

The high flux rate of Ca2+ through NMDA receptor (NMDAR) channels is critical for their biological function and may depend on a Ca2+ binding site in the extracellular vestibule. We screened substitutions of hydrophilic residues exposed in the vestibule and identified a cluster of charged residues and a proline, the DRPEER motif, positioned C terminal to M3, that is unique to the NR1 subunit. Charge neutralization or conversion of residues in DRPEER altered fractional Ca2+ currents in a manner consistent with its forming a binding site for Ca2+. Similarly, in a mutant channel in which all of the negative charges are neutralized (ARPAAR), the block by extracellular Ca2+ of single-channel current amplitudes is attenuated. In these same channels, the block by extracellular Mg2+ is unaffected. DRPEER is located extracellularly, and its contribution to Ca2+ influx is distinct from that of the narrow constriction. We conclude that key residues in DRPEER, acting as an external binding site for Ca2+, along with a conserved asparagine in the M3 segment proper, contribute to the high fractional Ca2+ currents in these channels under physiological conditions. Therefore, these domains represent critical molecular determinants of NMDAR function in synaptic physiology.

摘要

钙离子通过N-甲基-D-天冬氨酸受体（NMDAR）通道的高通量速率对其生物学功能至关重要，并且可能依赖于细胞外前庭中的一个钙离子结合位点。我们筛选了前庭中暴露的亲水性残基的替代物，并确定了一组带电荷的残基和一个脯氨酸，即DRPEER基序，位于M3的C末端，这是NR1亚基所特有的。DRPEER中残基的电荷中和或转化以与其形成钙离子结合位点一致的方式改变了钙离子分数电流。同样，在一个所有负电荷都被中和的突变通道（ARPAAR）中，细胞外钙离子对单通道电流幅度的阻断作用减弱。在这些相同的通道中，细胞外镁离子的阻断作用不受影响。DRPEER位于细胞外，其对钙离子内流的贡献与狭窄缩窄处不同。我们得出结论，DRPEER中的关键残基作为钙离子的外部结合位点，与M3段中保守的天冬酰胺一起，在生理条件下有助于这些通道中高钙离子分数电流的形成。因此，这些结构域代表了突触生理学中NMDAR功能的关键分子决定因素。

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本文引用的文献

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