青蛙骨骼肌在极度超极化过程中钾通透性的下降。
The decline of potassium permeability during extreme hyperpolarization in frog skeletal muscle.
作者信息
Almers W
出版信息
J Physiol. 1972 Aug;225(1):57-83. doi: 10.1113/jphysiol.1972.sp009929.
Abstract
- The voltage-clamp technique was used to separate the effects of K depletion in the T-system from the decline in K permeability during hyperpolarization, and to characterize the time- and voltage-dependence of the latter.2. K permeability due to the inward rectifier can be described as being proportional to a parameter which diminishes when the membrane is hyperpolarized beyond -120 mV. The parameter obeys first-order kinetics. At 24 degrees C, it can change with a time constant of 49 msec at -150 mV and 25 msec at -65 mV. At -200 mV the fall in membrane conductance due to the permeability change is to 30% of its initial value. The Q(10) for the rate of conductance change at that potential is about 2.8.3. It is estimated that K inward current can lower the average K concentration in the T-system by more than 50%, and that, on the average, the space enclosed by the T-system should be less than 0.8% of the fibre volume. Assuming the T-system space to be 0.3% of the fibre volume, it is calculated that on the average, and during hyperpolarization to about -150 mV, no more than 20% of the initial current should flow across the surface membrane.
摘要
采用电压钳技术将T管中钾离子缺失的效应与超极化过程中钾离子通透性的下降区分开来,并对后者的时间和电压依赖性进行表征。
内向整流器引起的钾离子通透性可描述为与一个参数成正比,当膜超极化超过 -120 mV时,该参数会减小。该参数服从一级动力学。在24摄氏度时,在 -150 mV下它可以以49毫秒的时间常数变化,在 -65 mV下为25毫秒。在 -200 mV时,由于通透性变化导致的膜电导下降至其初始值的30%。该电位下电导变化速率的Q(10)约为2.8。
据估计,钾离子内向电流可使T管中的平均钾离子浓度降低超过50%,并且平均而言,T管所包围的空间应小于纤维体积的0.8%。假设T管空间为纤维体积的0.3%,据计算,平均而言,在超极化至约 -150 mV期间,流过表面膜的初始电流不应超过20%。
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