葡萄糖诱导的小鼠胰岛β细胞膜电位和电阻的周期性变化。
Cyclic changes in potential and resistance of the beta-cell membrane induced by glucose in islets of Langerhans from mouse.
作者信息
Atwater I, Ribalet B, Rojas E
出版信息
J Physiol. 1978 May;278:117-39. doi: 10.1113/jphysiol.1978.sp012296.
Abstract
- The effects of KCl on the membrane potential were studied in cells from mouse islets of Langerhans identified as beta-cells by the characteristic pattern of electrical activity induced by 11.1 mM glucose. 2. In the absence of glucose, when the beta-cell membrane does not exhibit electrical activity, the dependence of the membrane potential upon external potassium [K+]o, could be described by the constant field equation using a PK/PNa ratio between 30 and 75. 3. In 11.1 mM glucose, when the beta-cell membrane potential fluctuates between a silent phase at about -50 mV and an active phase at about -40 mV giving rise to a train of spikes, the dependence of the membrane potential upon [K+]o could also be described with the constant field equation using a smaller PK/PNa of about 15, during the silent phase, and of about 8, during the active phase (foot of the spikes during the burst). 4. A bridge amplifier for measuring the changes in membrane potential during the application of pulses of current through the same micro-electrode was used to estimate the input resistance of a beta-cell. In 11.1 mM glucose, rough estimates of the membrane resistance during the silent phase averaged 1.2 X 10(8) omega. 5. The time course of the changes in input resistance of the cell when switching from 0 to 11.1 mM glucose showed a transient decrease from 0.9 X 10(8) to 0.7 X 10(8) omega followed by an increase to 1.2 X 10(8) omega. 6. The burst pattern was shown to result from the superposition of two potential changes: (a) 5--10 mV depolarization (lasting about 10 sec in 11.1 mM glucose), and (b) 10--50 mM spikes (lasting about 0.1 sec). Only the latter could be suppressed by hyperpolarizing current injection. 7. Application of pulses of current during the various phases of the electrical activity in 11.1 mM glucose enable us to compare the resistance during the silent and active phases. This was found to be oscillating between a high resistance value at about 1.2 X 10(8) omega before each burst and a low resistance value at 0.9 X 10(8) omega during the active phase at the foot of the spikes. In some cells the resistance during the silent phase remained fairly constant. In other cells it increased gradually from 1.1 X 10(8) to 1.3 X 10(8) omega measured just before each burst of spikes. 8. The observed increase in resistance induced by glucose together with the measured dependency of the membrane potential on [K+]o with and without glucose can be explained by postulating that in the presence of glucose the K+ permeability of the beta-cell membrane is reduced. 9. The oscillations between a high and a low resistance state in the presence of 11.1 mM glucose could be due to a sudden decrease in K+ permeability followed by a much larger increase in permeability to other ions, presumably Na+ and Ca2+.
摘要
- 利用11.1 mM葡萄糖诱导的特征性电活动模式,在已鉴定为β细胞的小鼠胰岛细胞中研究了氯化钾对膜电位的影响。2. 在无葡萄糖的情况下,当β细胞膜不表现出电活动时,膜电位对细胞外钾离子浓度[K+]o的依赖性可以用恒定场方程来描述,此时钾离子通透系数与钠离子通透系数之比(PK/PNa)在30到75之间。3. 在11.1 mM葡萄糖存在时,当β细胞膜电位在约 -50 mV的静息期和约 -40 mV的活动期之间波动并产生一系列尖峰时,膜电位对[K+]o的依赖性同样可以用恒定场方程来描述,在静息期,PK/PNa约为15,在活动期(爆发期尖峰的起始阶段)约为8。4. 使用一个桥式放大器来测量通过同一微电极施加电流脉冲期间的膜电位变化,以此估计β细胞的输入电阻。在11.1 mM葡萄糖环境下,静息期膜电阻的粗略估计平均值为1.2×10⁸Ω。5. 当从0 mM葡萄糖切换到11.1 mM葡萄糖时,细胞输入电阻变化的时间进程显示出先从0.9×10⁸Ω短暂下降到0.7×10⁸Ω,随后增加到1.2×10⁸Ω。6. 爆发模式被证明是由两种电位变化叠加而成:(a) 5 - 10 mV的去极化(在11.1 mM葡萄糖中持续约10秒),以及(b) 10 - 50 mM的尖峰(持续约0.1秒)。只有后者可以通过超极化电流注入来抑制。7. 在11.1 mM葡萄糖环境下电活动的不同阶段施加电流脉冲,使我们能够比较静息期和活动期的电阻。结果发现,电阻在每次爆发前约1.2×10⁸Ω的高电阻值和活动期尖峰起始阶段0.9×10⁸Ω的低电阻值之间振荡。在一些细胞中,静息期电阻保持相当恒定。在其他细胞中,在每次尖峰爆发前测量时,电阻从1.1×10⁸Ω逐渐增加到1.3×10⁸Ω。8. 观察到的葡萄糖诱导的电阻增加以及测量得到的有无葡萄糖时膜电位对[K+]o的依赖性,可以通过假设在葡萄糖存在时β细胞膜的钾离子通透性降低来解释。9. 在11.1 mM葡萄糖存在时高电阻状态和低电阻状态之间的振荡,可能是由于钾离子通透性突然降低,随后对其他离子(可能是钠离子和钙离子)的通透性大幅增加所致。
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