克隆的谷氨酸转运体/氯离子通道的宏观和微观特性
Macroscopic and microscopic properties of a cloned glutamate transporter/chloride channel.
作者信息
Wadiche J I, Kavanaugh M P
机构信息
Vollum Institute, Oregon Health Sciences University, Portland, Oregon 97201, USA.
出版信息
J Neurosci. 1998 Oct 1;18(19):7650-61. doi: 10.1523/JNEUROSCI.18-19-07650.1998.
Abstract
The behavior of a Cl- channel associated with a glutamate transporter was studied using intracellular and patch recording techniques in Xenopus oocytes injected with human EAAT1 cRNA. Channels could be activated by application of glutamate to either face of excised membrane patches. The channel exhibited strong selectivity for amphipathic anions and had a minimum pore diameter of approximately 5A. Glutamate flux exhibited a much greater temperature dependence than Cl- flux. Stationary and nonstationary noise analysis was consistent with a sub-femtosiemen Cl- conductance and a maximum channel Po << 1. The glutamate binding rate was similar to estimates for receptor binding. After glutamate binding, channels activated rapidly followed by a relaxation phase. Differences in the macroscopic kinetics of channels activated by concentration jumps of L-glutamate or D-aspartate were correlated with differences in uptake kinetics, indicating a close correspondence of channel gating to state transitions in the transporter cycle.
摘要
利用细胞内和膜片钳记录技术,对注射了人EAAT1编码RNA的非洲爪蟾卵母细胞中与谷氨酸转运体相关的氯离子通道行为进行了研究。通过向切除的膜片两侧施加谷氨酸,可激活该通道。该通道对两亲性阴离子具有很强的选择性,最小孔径约为5埃。谷氨酸通量比氯离子通量表现出更大的温度依赖性。稳态和非稳态噪声分析与亚飞西门子的氯离子电导以及最大通道开放概率Po << 1一致。谷氨酸结合速率与受体结合的估计值相似。谷氨酸结合后,通道迅速激活,随后进入松弛阶段。由L-谷氨酸或D-天冬氨酸浓度阶跃激活的通道宏观动力学差异与摄取动力学差异相关,表明通道门控与转运体循环中的状态转变密切对应。
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