蛙肌膜上缓慢的钙电流和钾电流:用凡士林间隙技术进行的测量
Slow calcium and potassium currents across frog muscle membrane: measurements with a vaseline-gap technique.
作者信息
Almers W, Palade P T
出版信息
J Physiol. 1981 Mar;312:159-76. doi: 10.1113/jphysiol.1981.sp013622.
Abstract
- A vaseline-gap voltage-clamp technique was used to record slow Ca2+ and K+ currents from frog skeletal muscle fibres loaded with the Ca2+ chelator EGTA. 2. K+ currents were increased when Mg2+ replaced external Ca2+, and they were abolished when internal K+ was replaced by tetraethylammonium (TEA+). Ca2+ currents could be studied in isolation in fibres loaded with (TEA)2EGTA. 3. Under maintained depolarization, Ca2+ currents slowly increase (half-time of 35 msec or more at 25 mV) and then decline to a steady value. Decline under repolarization is rapid (half-time of 6-7 msec) and complete. During an action potential, the Ca2+ influx through this system is probably less than the influx observed with tracers. 4. Ba2+, Sr2+, Ca2+, Mn2+ and Mg2+ can carry current across the membrane; Ni2+ and Co2+ cannot. Ca2+ currents are weakly blocked by external Mg2+.
摘要
- 采用凡士林间隙电压钳技术记录负载Ca2+螯合剂乙二醇双四乙酸(EGTA)的青蛙骨骼肌纤维中的慢钙电流和钾电流。2. 当Mg2+替代细胞外Ca2+时,钾电流增加,而当细胞内钾被四乙铵(TEA+)替代时,钾电流消失。在负载(TEA)2EGTA的纤维中可单独研究钙电流。3. 在持续去极化条件下,钙电流缓慢增加(在25 mV时半衰期为35毫秒或更长),然后下降至稳定值。复极化时下降迅速(半衰期为6 - 7毫秒)且完全。在动作电位期间,通过该系统的Ca2+内流可能少于用示踪剂观察到的内流。4. Ba2+、Sr2+、Ca2+、Mn2+和Mg2+可携带电流通过膜;Ni2+和Co2+则不能。钙电流受到细胞外Mg2+的微弱阻断。
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