骨骼肌中的钾电导变化及横管中的钾浓度
Potassium conductance changes in skeletal muscle and the potassium concentration in the transverse tubules.
作者信息
Almers W
出版信息
J Physiol. 1972 Aug;225(1):33-56. doi: 10.1113/jphysiol.1972.sp009928.
Abstract
- When one hyperpolarizes a muscle fibre by passing electric current, the K conductance declines with time. Voltage-clamp experiments on frog sartorius muscle fibres showed that two components contribute to this decline.2. A rapid component operates when the fibre is hyperpolarized to potentials more negative than -120 mV. Decline by this mechanism is reversed completely within 200 msec. The large effect of temperature on the kinetics of this process indicates that it represents a time-dependent membrane permeability change.3. A slow component operates also at less negative potentials. Recovery at -65 mV takes place with half-times of about 0.4 sec. The Q(10) for the rate of recovery is 1.3, indicating that this process is diffusion limited.4. After prolonged hyperpolarization to potentials positive to -120 mV, membrane current at the resting potential is outward and persists for several seconds. At that time, the potential measured in the absence of membrane current is shifted in the negative direction by 3-5 mV.5. This shift and the time course of currents near the resting potential after hyperpolarization as well as the Q(10) of 1.3 indicate that the slow process is due to changes in tubular K concentration and not to a time-dependent membrane permeability change.6. At potentials less negative than -120 mV, tubular depletion can satisfactorily account for the decline of K conductance. At more negative potentials, the decline appears to be due to both depletion and a permeability change.
摘要
当通过电流使肌肉纤维超极化时,钾电导随时间下降。对青蛙缝匠肌纤维进行的电压钳实验表明,这种下降由两个因素导致。
当纤维超极化到比 -120 mV更负的电位时,快速成分起作用。通过这种机制导致的下降在200毫秒内完全逆转。温度对该过程动力学的显著影响表明它代表了一种随时间变化的膜通透性变化。
慢成分在电位不太负时也起作用。在 -65 mV时恢复的半衰期约为0.4秒。恢复速率的Q(10)为1.3,表明该过程受扩散限制。
在长时间超极化到比 -120 mV更正的电位后,静息电位下的膜电流向外且持续数秒。此时,在无膜电流时测量的电位向负方向移动3 - 5 mV。
这种移动以及超极化后静息电位附近电流的时间进程以及Q(10)为1.3表明,慢过程是由于管状钾浓度的变化,而不是随时间变化的膜通透性变化。
在电位比 -120 mV不太负时,管状钾的耗尽可以很好地解释钾电导的下降。在更负的电位下,下降似乎是由于耗尽和通透性变化共同导致的。
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