龙虾肌肉兴奋性突触后膜上由L-谷氨酸引起的通透性变化。
Permeability changes produced by L-glutamate at the excitatory post-synaptic membrane of the crayfish muscle.
作者信息
Onodera K, Takeuchi A
出版信息
J Physiol. 1976 Mar;255(3):669-85. doi: 10.1113/jphysiol.1976.sp011302.
Abstract
- Permeability changes produced by L-glutamate at the neuromuscular junction of the crayfish (Cambarus clarkii) were investigated by application of the drug iontophoretically to the voltage-clamped junction and measuring the resulting 'glutamate current'. 2. Reversal potentials were determined by measuring the glutamate current at different membrane potentials. They were +39-1 +/- 3-6 mV (mean +/- S.E. of mean) in normal solution and +16-5 +/- 2-0 mV in solutions made twice as hypertonic by the addition of sucrose. 3. Decreasing external Na+ concentration shifted the reversal potential in the negative direction; increased Na+ in the positive direction. 4. The relation between the amplitude of the glutamate current and extracellular Na+ concentration was approximately linear. 5. Alteration of the external K+ or Cl- concentration did not affect the amplitude or reversal potential of glutamate current. 6. In Na+-free solution the application of L-glutamate produced a small inward current at the resting potential and its amplitude was augmented by increasing the external Ca2+ concentration. 7. Increasing the Ca2+ concentration in the normal Na+ media produced no appreciable effect on the reversal potential but decreased the amplitude of glutamate current. 8. The results indicate that L-glutamate increases the membrane permeability mainly to Na+ and slightly to Ca2+. 9. The time course of glutamate current was shorter than that of the concentration calculated from the diffusion equation and it was simulated more closely by the square of the concentration.
摘要
- 通过将L-谷氨酸离子电泳施加到电压钳制的小龙虾(克氏原螯虾)神经肌肉接头处,并测量由此产生的“谷氨酸电流”,研究了L-谷氨酸在该神经肌肉接头处引起的通透性变化。2. 通过测量不同膜电位下的谷氨酸电流来确定反转电位。在正常溶液中,反转电位为+39.1±3.6 mV(平均值±平均值的标准误差),在通过添加蔗糖使其渗透压变为两倍的溶液中,反转电位为+16.5±2.0 mV。3. 降低细胞外Na⁺浓度会使反转电位向负方向移动;增加Na⁺浓度则向正方向移动。4. 谷氨酸电流的幅度与细胞外Na⁺浓度之间的关系大致呈线性。5. 改变细胞外K⁺或Cl⁻浓度不会影响谷氨酸电流的幅度或反转电位。6. 在无Na⁺溶液中,施加L-谷氨酸在静息电位时会产生一个小的内向电流,并且通过增加细胞外Ca²⁺浓度可增强其幅度。7. 在正常Na⁺培养基中增加Ca²⁺浓度对反转电位没有明显影响,但会降低谷氨酸电流的幅度。8. 结果表明,L-谷氨酸主要增加膜对Na⁺的通透性,对Ca²⁺的通透性略有增加。9. 谷氨酸电流的时间进程比根据扩散方程计算出的浓度的时间进程短,并且用浓度的平方能更接近地模拟它。
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