9-氨基吖啶对大鼠海马神经元NMDA受体开放通道阻断过程中谷氨酸和甘氨酸的捕获
Trapping of glutamate and glycine during open channel block of rat hippocampal neuron NMDA receptors by 9-aminoacridine.
作者信息
Benveniste M, Mayer M L
机构信息
Laboratory of Cellular and Molecular Neurophysiology, NICHD, Bethesda, MD 20892, USA.
出版信息
J Physiol. 1995 Mar 1;483 ( Pt 2)(Pt 2):367-84. doi: 10.1113/jphysiol.1995.sp020591.
Abstract
- N-methyl-D-aspartate (NMDA) receptor responses were recorded from rat hippocampal neurons grown in dissociated culture, using whole-cell, outside-out and nucleated patch recording techniques. Rapid perfusion was used to study voltage-dependent block of NMDA receptors by 9-aminoacridine (9-AA) and by Mg2+. 2. Large amplitude tail currents were evoked on depolarization to +60 mV after application at -100 mV of NMDA and 9-AA but not NMDA and Mg2+. These tail currents were resistant to block by competitive antagonists to the glutamate and glycine binding sites on NMDA receptors and were not evoked when either NMDA or 9-AA were applied alone. 3. The decay kinetics of the tail current were dependent on agonist affinity; the time required for 80% charge transfer was 10-fold briefer for NMDA than for glutamate and 7-fold briefer for L-alanine than for glycine. These results are in accord with a sequential model for block of NMDA receptors by 9-AA, in which neither glutamate nor glycine can dissociate from the open-blocked state of the receptor. 4. Tail current responses had amplitudes 2- to 4-fold larger than responses to maximally effective concentrations of glutamate and glycine, indicating that NMDA receptor channels accumulate in the open-blocked state during co-application of agonist and 9-AA. The rise time and decay kinetics of tail current responses were faster than the response to brief applications of a maximally effective concentration of glutamate. Together, these results suggest that at +60 mV recovery from block by 9-AA occurs faster than the rate of opening of NMDA receptors in response to glutamate. 5. Our experiments suggest that open channel block of NMDA receptors can provide a novel approach for measurement of both open probability and the first latency distribution for ion channel opening in response to the binding of agonists, and provide additional evidence suggesting that the delayed opening of NMDA receptor channels underlies slow activation and deactivation of responses to glutamate.
摘要
- 采用全细胞、外向膜片和有核膜片记录技术,在解离培养的大鼠海马神经元中记录N-甲基-D-天冬氨酸(NMDA)受体反应。利用快速灌流研究9-氨基吖啶(9-AA)和Mg2+对NMDA受体的电压依赖性阻断作用。2. 在 -100 mV施加NMDA和9-AA后,去极化至 +60 mV可诱发大幅度尾电流,但施加NMDA和Mg2+时则不会诱发。这些尾电流对NMDA受体上谷氨酸和甘氨酸结合位点的竞争性拮抗剂的阻断具有抗性,单独施加NMDA或9-AA时不会诱发。3. 尾电流的衰减动力学取决于激动剂亲和力;NMDA使80%电荷转移所需时间比谷氨酸短10倍,L-丙氨酸比甘氨酸短7倍。这些结果符合9-AA阻断NMDA受体的顺序模型,即谷氨酸和甘氨酸都不能从受体的开放-阻断状态解离。4. 尾电流反应的幅度比最大有效浓度的谷氨酸和甘氨酸反应大2至4倍,表明在激动剂和9-AA共同施加期间,NMDA受体通道积聚在开放-阻断状态。尾电流反应的上升时间和衰减动力学比短暂施加最大有效浓度谷氨酸的反应更快。总之,这些结果表明在 +60 mV时,从9-AA阻断中恢复的速度比NMDA受体对谷氨酸反应的开放速度更快。5. 我们的实验表明,NMDA受体的开放通道阻断可为测量离子通道响应激动剂结合的开放概率和首次延迟分布提供一种新方法,并提供额外证据表明NMDA受体通道的延迟开放是谷氨酸反应缓慢激活和失活的基础。
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