Barbour B, Brew H, Attwell D
Department of Physiology, University College London.
J Physiol. 1991 May;436:169-93. doi: 10.1113/jphysiol.1991.sp018545.
The effects of excitatory amino acids on the membrane current of isolated retinal glial cells (Müller cells) were investigated using whole-cell patch clamping. 2. L-Glutamate evoked an inward current at membrane potentials between -140 and +50 mV. The current was larger at more negative potentials. 3. The glutamate-evoked current was activated by external cations with relative efficacies: Na+ much greater than Li+ greater than K+ greater than Cs+, choline. It was activated by internal cations with relative efficacies K+ greater than Rb+ greater than Cs+ much greater than choline. Chloride and divalent cations did not affect the glutamate-evoked current. 4. Raising the intracellular sodium or glutamate concentrations, or raising the extracellular potassium concentration, reduced the current evoked by external glutamate. The suppressive effect of internal glutamate was larger when the internal sodium concentration was high. 5. Some analogues of glutamate also evoked an inward current. Responses to L-aspartate resembled those to glutamate, but for aspartate the apparent affinity was higher and the voltage dependence of the current was steeper. In the physiological potential range the current evoked by a saturating dose of aspartate was less than that evoked by a saturating dose of glutamate. 6. The uptake blocker threo-3-hydroxy-DL-aspartate (30 microM) reduced the glutamate-evoked current, but also generated a current itself. Dihydrokainate (510 microMs) weakly inhibited the glutamate-evoked current without generating a current itself. 7. The commonly used blockers of glutamate-gated ion channels, 2-amino-5-phosphonovalerate (APV; 100 microMs), 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 20 microMs), and kynurenate (1mM) had no effect on the glutamate-evoked current. 8. The voltage dependence, cation dependence and pharmacological profile of the current evoked by excitatory amino acids indicate that it is caused by activation of the high-affinity glutamate uptake carrier. This carrier appears to transport one glutamate anion into the cell, one K+ ion out of the cell, and two or more Na+ ions into the cell, on each carrier cycle. At the inner membrane surface some or all of the transported Na+ dissociates from the carrier after the transported glutamate has dissociated. 9. In addition to glutamate, the uptake carrier can also transport aspartate and threo-3-hydroxy-DL-aspartate, but not dihydrokainate.
采用全细胞膜片钳技术研究了兴奋性氨基酸对分离的视网膜神经胶质细胞(穆勒细胞)膜电流的影响。2. L-谷氨酸在膜电位-140至+50 mV之间诱发内向电流。在更负的电位下电流更大。3. 谷氨酸诱发的电流被细胞外阳离子激活,其相对效能为:Na+远大于Li+大于K+大于Cs+、胆碱。它被细胞内阳离子激活,相对效能为K+大于Rb+大于Cs+远大于胆碱。氯离子和二价阳离子不影响谷氨酸诱发的电流。4. 提高细胞内钠或谷氨酸浓度,或提高细胞外钾浓度,会降低细胞外谷氨酸诱发的电流。当细胞内钠浓度高时,细胞内谷氨酸的抑制作用更大。5. 一些谷氨酸类似物也诱发内向电流。对L-天冬氨酸的反应与对谷氨酸的反应相似,但对于天冬氨酸,表观亲和力更高,电流的电压依赖性更陡。在生理电位范围内,饱和剂量天冬氨酸诱发的电流小于饱和剂量谷氨酸诱发的电流。6. 摄取阻断剂苏-3-羟基-DL-天冬氨酸(30 μM)降低了谷氨酸诱发的电流,但自身也产生电流。二氢 kainate(510 μM)微弱抑制谷氨酸诱发的电流,自身不产生电流。7. 常用的谷氨酸门控离子通道阻断剂,2-氨基-5-膦酰戊酸(APV;100 μM)、6-氰基-7-硝基喹喔啉-2,3-二酮(CNQX;20 μM)和犬尿烯酸(1 mM)对谷氨酸诱发的电流无影响。8. 兴奋性氨基酸诱发电流的电压依赖性、阳离子依赖性和药理学特征表明,它是由高亲和力谷氨酸摄取载体的激活引起的。在每个载体循环中,该载体似乎将一个谷氨酸阴离子转运到细胞内,一个K+离子转运出细胞,两个或更多Na+离子转运到细胞内。在细胞膜内表面,一些或所有转运的Na+在转运的谷氨酸解离后从载体上解离。9. 除谷氨酸外,摄取载体还可转运天冬氨酸和苏-3-羟基-DL-天冬氨酸,但不能转运二氢 kainate。
