氯离子转移对青蛙背根神经节细胞中γ-氨基丁酸门控电流衰减的作用。
Contribution of chloride shifts to the fade of gamma-aminobutyric acid-gated currents in frog dorsal root ganglion cells.
作者信息
Akaike N, Inomata N, Tokutomi N
机构信息
Department of Physiology, Faculty of Medicine, Kyushu University, Fukuoka, Japan.
出版信息
J Physiol. 1987 Oct;391:219-34. doi: 10.1113/jphysiol.1987.sp016735.
Abstract
- The contribution of Cl- redistribution to the decay phase of the GABA (gamma-aminobutyric acid) response was investigated in isolated frog sensory neurones, using a suction-pipette technique which allows for internal perfusion under conditions of voltage clamp. 2. In neurones perfused with 120 mM [Cl-]i and [Cl-]o at driving forces (delta VH) of less than 15 mV, no shift of GABA equilibrium potential (EGABA) occurred during a continuous application of GABA, at various concentrations. However, increases of delta VH towards negative or positive potentials over 15 mV induced EGABA shifts. 3. The degree of EGABA shift was governed by the total amount of Cl- flux across the soma membrane, an event which depends upon delta VH, GABA concentration and drug application time. 4. The time-dependent EGABA shift due to Cl- redistribution during GABA application induced a current run-down resulting from a decreased Cl- gradient and a diminished Cl- conductance (gCl), the latter brought about by a drop in the intracellular ionic density of Cl-. 5. The EGABA shift during a continuous GABA application was also affected by [Cl-]i; e.g. the shift more readily occurred at lower [Cl-]i. 6. In neurones perfused with internal and external solutions containing 120 mM-Cl- at a delta VH of less than 10 mV, the change of gCl occurred with no shift of EGABA during the continuous application of GABA at concentrations over 6 x 10(-5) M, thereby indicating a 'real' GABA receptor desensitization. The desensitization depended solely upon the agonist concentrations but not upon the amount of ICl. Under these conditions, the time course of recovery from GABA desensitization was estimated. The decrease of gCl at the desensitization phase was a single exponential. 7. At a delta VH greater than 15 mV, therefore, the decay of ICl induced by GABA concentrations over 6 x 10(-6) M consists of the sum of both the 'real' GABA receptor desensitization and the current run-down brought about by Cl- shifts. The gCl at the current decay phase consisted of a double exponential. In the present experiments we chose experimental conditions with which Cl- shift become negligible. 8. The 'pure' GABA receptor desensitization during a continuous application of GABA developed rapidly at GABA concentrations over 10(-5) M. The speed of desensitization was facilitated by increasing the magnitude of desensitization.
摘要
- 运用一种吸液管技术在分离的青蛙感觉神经元中研究了氯离子再分布对γ-氨基丁酸(GABA)反应衰减期的作用,该技术可在电压钳制条件下进行内部灌注。2. 在驱动力(ΔVH)小于15 mV时,用120 mM [Cl⁻]i和[Cl⁻]o灌注的神经元中,持续施加不同浓度的GABA期间,GABA平衡电位(EGABA)未发生偏移。然而,当ΔVH向负电位或正电位增加超过15 mV时,会诱导EGABA发生偏移。3. EGABA偏移的程度由跨体细胞体膜的氯离子通量总量决定,这一事件取决于ΔVH、GABA浓度和药物施加时间。4. GABA施加期间由于氯离子再分布导致的时间依赖性EGABA偏移引起了电流衰减,这是由于氯离子梯度降低和氯离子电导(gCl)减小所致,后者是由细胞内氯离子离子密度下降引起的。5. 持续施加GABA期间的EGABA偏移也受[Cl⁻]i影响;例如,在较低的[Cl⁻]i时更容易发生偏移。6. 在ΔVH小于10 mV时,用含有120 mM-Cl⁻的内部和外部溶液灌注的神经元中,在持续施加浓度超过6×10⁻⁵ M的GABA期间,gCl发生变化而EGABA未发生偏移,从而表明存在“真正的”GABA受体脱敏。脱敏仅取决于激动剂浓度,而不取决于ICl的量。在这些条件下评估了从GABA脱敏中恢复的时间进程。脱敏阶段gCl的降低呈单指数形式。7. 因此,在ΔVH大于15 mV时,由浓度超过6×10⁻⁶ M的GABA诱导的ICl衰减由“真正的”GABA受体脱敏和氯离子移位引起的电流衰减之和组成。电流衰减阶段的gCl由双指数组成。在本实验中,我们选择了使氯离子移位可忽略不计的实验条件。8. 在持续施加GABA期间,“纯粹的”GABA受体脱敏在GABA浓度超过10⁻⁵ M时迅速发展。脱敏速度通过增加脱敏程度而加快。
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