青蛙有髓神经纤维郎飞结电压钳制下平衡电位与钾电导的同步变化。
Simultaneous changes in the equilibrium potential and potassium conductance in voltage clamped Ranvier node in the frog.
作者信息
Dubois J M
出版信息
J Physiol. 1981 Sep;318:279-95. doi: 10.1113/jphysiol.1981.sp013864.
Abstract
- In voltage clamped myelinated nerve fibres, the K+ conductance has been calculated from current recordings obtained in low and high K+ media, taking into account the changes in EK resulting from accumulation of depletion of K+ ions near to nodal membrane. 2. At the end of a depolarization, the instantaneous K+ current reverses at a potential (instantaneous reversal potential) differing from the Nernst potential calculated using the external and internal bulk concentrations (theoretical Nernst potential). During a depolarization, EK, as estimated from the instantaneous reversal potential, changes continuously. This change depends on the size, the duration and the direction of the time dependent K+ current. The variation of EK is attributed to continuous changes in K+ concentration near the membrane during voltage pulses which turn on the K+ conductance. 3. The chord conductance [GK = IK/(E-EK), as calculated using the instantaneous reversal potential values for EK, has been analysed as a function of time and membrane potential. As previously reported it increases with the initial K+ concentration in the external medium. 4. The time course of the K+ current depends on both the kinetics of the conductance increase and the rate of change in the driving force for K. The kinetics of the conductance increase can satisfactorily be described by a single exponential function following a delay after the onset of the depolarizing voltage clamp pulse. 5. This delay increases when the holding potential is made more negative. It decreases with membrane depolarization and it is independent of the external K+ concentration. At a given membrane potential, the turning on of the K+ conductance is found to be faster at high than at low external K+ concentrations. 6. At repolarization the turning off of the conductance cannot be described by a single exponential function. It is faster at low than at high external K+ concentrations. 7. The results suggest that the change in K+ conductance proceeds in a multi-step transition or (and) that the K+ conductance is determined by several types of K+ channels.
摘要
- 在电压钳制的有髓神经纤维中,钾离子电导是根据在低钾和高钾介质中获得的电流记录计算得出的,同时考虑到结膜附近钾离子积累或耗尽所导致的能斯特电位(EK)变化。2. 在去极化结束时,瞬时钾电流在一个与使用外部和内部总体浓度计算出的能斯特电位(理论能斯特电位)不同的电位(瞬时反转电位)处反转。在去极化过程中,根据瞬时反转电位估算的EK会持续变化。这种变化取决于时间依赖性钾电流的大小、持续时间和方向。EK的变化归因于电压脉冲开启钾离子电导时膜附近钾离子浓度的持续变化。3. 使用EK的瞬时反转电位值计算得出的弦电导[GK = IK/(E - EK)]已作为时间和膜电位的函数进行了分析。如先前报道的那样,它随外部介质中的初始钾离子浓度增加。4. 钾电流的时间进程取决于电导增加的动力学以及钾驱动力的变化速率。电导增加的动力学可以通过去极化电压钳制脉冲开始后的延迟后跟随的单个指数函数来令人满意地描述。5. 当保持电位变得更负时,这种延迟会增加。它随膜去极化而减小,并且与外部钾离子浓度无关。在给定的膜电位下,发现高外部钾离子浓度下钾离子电导的开启比低外部钾离子浓度下更快。6. 在复极化时,电导的关闭不能用单个指数函数来描述。在低外部钾离子浓度下比在高外部钾离子浓度下更快。7. 结果表明,钾离子电导的变化以多步转变进行或(并且)钾离子电导由几种类型的钾通道决定。
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本文引用的文献
1
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J Physiol. 1949 Mar 1;108(1):37-77. doi: 10.1113/jphysiol.1949.sp004310.
2
A QUANTITATIVE DESCRIPTION OF POTASSIUM CURRENTS IN MYELINATED NERVE FIBRES OF XENOPUS LAEVIS.非洲爪蟾有髓神经纤维中钾电流的定量描述
J Physiol. 1963 Nov;169(2):424-30. doi: 10.1113/jphysiol.1963.sp007268.
3
Potassium permeability in myelinated nerve fibres of Xenopus laevis.非洲爪蟾有髓神经纤维中的钾通透性。
J Physiol. 1962 Jan;160(1):54-61. doi: 10.1113/jphysiol.1962.sp006834.
4
Potassium ion current in the squid giant axon: dynamic characteristic.鱿鱼巨轴突中的钾离子电流:动态特性
Biophys J. 1960 Sep;1(1):1-14. doi: 10.1016/s0006-3495(60)86871-3.
5
The after-effects of impulses in the giant nerve fibres of Loligo.枪乌贼巨大神经纤维冲动的后效应
J Physiol. 1956 Feb 28;131(2):341-76. doi: 10.1113/jphysiol.1956.sp005467.
6
Post-tetanic membrane potential in single axon and myelinated nerve trunk.单根轴突和有髓神经干的强直后膜电位。
Ann N Y Acad Sci. 1980;339:21-38. doi: 10.1111/j.1749-6632.1980.tb15965.x.
7
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