青蛙慢肌纤维的膜电特性
Membrane electrical properties of frog slow muscle fibres.
作者信息
Gilly W F, Hui C S
出版信息
J Physiol. 1980 Apr;301:157-73. doi: 10.1113/jphysiol.1980.sp013196.
Abstract
- Pyriformis slow (and sartorius twitch) fibres from Rana temporaria were studied with a three-micro-electrode voltage-clamp technique to obtain an approximate measurement of membrane current density at a fibre end. In most experiments, a modified Ringer solution containing 2H20 and 230 mM-sucrose was used to reduce movement. 2. Linear membrane properties of slow fibres obtained with this method are consistent with results from previous studies. Measured Cm (microF/cm2) increases with fibre diameter in a manner consistent with a tubular location of part of the fibre capacitance. 3. Voltage steps to -50mV and more positive potentials result in outward membrane currents in both slow and twitch fibres. These currents develop along similar sigmoid time courses and are blocked by tetraethylammonium (TEA+) ions. The reversal potential for delayed current channels in slow fibres varies with external K+ concentration, suggesting that the delayed current in slow fibres, as in twitch, is carried by K+ ions. 4. Maximum GK,GK, in slow fibres is an order of magnitude smaller than twitch fibres. The steady-state GK-V curve of slow fibres is very broad (e-fold for approximately 15 mV), saturating at very positive voltages, whereas the GK of twitch fibres varies more steeply with voltage. 5. No evidence of inward currents was seen in slow fibres during pulses of duration up to 96 msec. 6. Slow outward currents, which do not inactivate appreciably, are seen in slow fibres during long (10 sec) pulses. Tail currents following such long pulses are very slow. The reversal potential shifts to more positive values with increasing pulse duration.
摘要
- 采用三微电极电压钳技术研究了林蛙梨状肌慢肌纤维(以及缝匠肌快肌纤维),以大致测量纤维末端的膜电流密度。在大多数实验中,使用含有2H₂O和230 mM蔗糖的改良林格氏液来减少纤维移动。2. 用这种方法获得的慢肌纤维的线性膜特性与先前研究结果一致。测得的膜电容(Cm,微法/平方厘米)随纤维直径增加,其方式与部分纤维电容位于肌管一致。3. 向-50 mV及更正电位的电压阶跃在慢肌纤维和快肌纤维中均导致外向膜电流。这些电流沿相似的S形时间进程发展,并被四乙铵(TEA⁺)离子阻断。慢肌纤维中延迟电流通道的反转电位随外部K⁺浓度而变化,这表明慢肌纤维中的延迟电流与快肌纤维一样,是由K⁺离子携带的。4. 慢肌纤维中的最大钾电导(GK)比快肌纤维小一个数量级。慢肌纤维的稳态GK-V曲线非常宽(约15 mV的e倍变化),在非常正的电压下达到饱和,而快肌纤维的GK随电压变化更陡峭。5. 在长达96毫秒的脉冲期间,慢肌纤维中未观察到内向电流的证据。6. 在长时间(10秒)脉冲期间,慢肌纤维中可观察到不会明显失活的慢外向电流。这种长脉冲后的尾电流非常缓慢。随着脉冲持续时间增加,反转电位向更正的值移动。
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