鲶鱼视网膜水平细胞电生性转运γ-氨基丁酸所需的离子。
Ions required for the electrogenic transport of GABA by horizontal cells of the catfish retina.
作者信息
Cammack J N, Schwartz E A
机构信息
Department of Pharmacological and Physiological Sciences, University of Chicago, IL 60637.
出版信息
J Physiol. 1993 Dec;472:81-102. doi: 10.1113/jphysiol.1993.sp019938.
Abstract
- Solitary horizontal cells were isolated from catfish retinas. Membrane currents activated by extracellular and intracellular GABA were characterized during a whole-cell voltage clamp. 2. Extracellular GABA activated two currents: a GABAA current, and an 'influx' current mediated by a GABA transporter. The influx current was studied after the GABAA current was blocked with 0.5 mM picrotoxin. The influx current required extracellular Na+ and Cl-. Extracellular Na+ could not be replaced by another alkali metal cation. 3. The influx current also depended upon the identity of ions in the intracellular solution. Either an intracellular alkali metal cation or Cl- was required to produce an influx current. 4. The influx current was inward at -75 mV and decreased as the membrane was depolarized towards +20 mV. When the membrane was depolarized beyond +25 mV, the polarity of the current depended upon the ion composition of the intracellular solution and could be inward, zero or outward. 5. The introduction of GABA into a cell during the course of an experiment produced an outward current. This 'efflux' current was small at -75 mV and increased with depolarization. The efflux current required intracellular Na+ and Cl-. Intracellular Na+ could not be replaced by another alkali metal cation. 6. The efflux current also depended upon the identity of ions in the extracellular solution. An extracellular alkali metal cation was required to produce an efflux current. Removing extracellular Cl- did not affect the efflux current. 7. The outward movement of GABA produced a local accumulation in extracellular GABA concentration that could be detected by the activation of the GABAA current. GABA efflux only occurred during conditions that produced an efflux current. Electroneutral efflux did not occur. 8. In the absence of GABA, extracellular alkali metal cations produced a 'leakage' current. The leakage current was inward at -75 mV and decreased as the membrane was depolarized towards +20 mV. When the membrane was depolarized beyond +25 mV, the polarity of the leakage current depended, like the GABA influx current, upon the ion composition of the intracellular solution and could be inward, zero or outward. The addition of GABA to the intracellular solution produced an efflux current and suppressed the leakage current. 9. We conclude that the transporter mediates electrogenic influx, efflux and leakage. Each mode of operation depends upon ions on both sides of the membrane. Influx and efflux are not symmetrical.
摘要
- 从鲶鱼视网膜中分离出单个水平细胞。在全细胞膜片钳实验中,对细胞外和细胞内γ-氨基丁酸(GABA)激活的膜电流进行了特性分析。2. 细胞外GABA激活两种电流:一种是GABAA电流,另一种是由GABA转运体介导的“内流”电流。在用0.5 mM苦味毒阻断GABAA电流后,对该内流电流进行了研究。内流电流需要细胞外的钠离子(Na⁺)和氯离子(Cl⁻)。细胞外的Na⁺不能被其他碱金属阳离子替代。3. 内流电流还取决于细胞内溶液中离子的种类。产生内流电流需要细胞内的碱金属阳离子或Cl⁻。4. 在 -75 mV时,内流电流是内向的,随着膜电位向 +20 mV去极化,电流减小。当膜电位去极化超过 +25 mV时,电流的极性取决于细胞内溶液的离子组成,可能是内向(inward)、零或外向(outward)。5. 在实验过程中,向细胞内引入GABA会产生外向电流。这种“外流”电流在 -75 mV时较小,并随着去极化而增加。外流电流需要细胞内的Na⁺和Cl⁻。细胞内的Na⁺不能被其他碱金属阳离子替代。6. 外流电流还取决于细胞外溶液中离子的种类。产生外流电流需要细胞外的碱金属阳离子。去除细胞外的Cl⁻不影响外流电流。7. GABA的外向移动导致细胞外GABA浓度局部积累,这可以通过GABAA电流的激活来检测。GABA外流仅在产生外流电流的条件下发生。电中性外流不会发生。8. 在没有GABA的情况下,细胞外碱金属阳离子会产生“泄漏”电流。在 -75 mV时,泄漏电流是内向的,随着膜电位向 +20 mV去极化而减小。当膜电位去极化超过 +25 mV时,泄漏电流的极性与GABA内流电流一样,取决于细胞内溶液的离子组成,可能是内向、零或外向。向细胞内溶液中添加GABA会产生外流电流并抑制泄漏电流。9. 我们得出结论,该转运体介导了生电内流、外流和泄漏。每种运作模式都取决于膜两侧的离子。内流和外流并不对称。
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