活动诱导的钾离子积累及其在蛙心室肌中的摄取

Activity-induced potassium accumulation and its uptake in frog ventricular muscle.

作者信息

Martin G, Morad M

出版信息

J Physiol. 1982 Jul;328:205-27. doi: 10.1113/jphysiol.1982.sp014260.

DOI:10.1113/jphysiol.1982.sp014260

PMID:6982328

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1225654/

Abstract

Extracellular K+ activity in frog ventricular muscle was monitored with a K+-selective micro-electrode during and following periods of rapid stimulation. 2. During activity K+ accumulated in the paracellular space, declined with continued beating and became depleted below bathing K+ concentrations, [K+], when activity was terminated. 3. The re-uptake and depletion of K+ was inhibited by ouabain, Li+ and lowering bathing [K+], and was enhanced by prolonged stimulation, raising bathing [K+], and by addition of adrenaline. These ionic and drug dependencies of the K+ re-uptake process are similar to the ionic and drug dependencies of the Na+-K+-ATPase system. 4. Frequency-induced K+ accumulation appears to result from a delay in the activation of the Na+ pump. 5. Possible changes in intracellular sodium concentration, [Na+]i, in the response to changes in frequency, appear to be a more powerful stimulant of the K+ re-uptake process than changes in extracellular potassium concentration, [K+]o. 6. Frequency-induced changes in [K+]o were also detected by measurements of resting potential. Alterations in membrane potential and action potential duration observed during and following electrical stimulation are suggestive of an electrogenic K+ re-uptake process. 7. Aside from their direct effects on the action potential, Ca2+ and Mg2+ had little or no effect on Na+ pump activity. While Ni2+ suppressed pump activity, Ba2+ indirectly enhanced the K+ uptake process by blocking the resting K+ conductance. 8. K+ uptake rate was estimated to range between 3 and 8 p-mole/cm2.sec. Since diffusion in and out of the paracellular space was a much slower process (t1/2 60-90 sec), it contributes little to the beat-to-beat control of paracellular [K+].

摘要

在快速刺激期间及之后，用钾选择性微电极监测蛙心室肌细胞外钾离子活性。2. 活动期间，钾离子在细胞旁间隙积累，随着持续跳动而下降，当活动终止时，钾离子浓度低于浴液中钾离子浓度[K⁺]。3. 哇巴因、锂离子和降低浴液[K⁺]可抑制钾离子的再摄取和消耗，而延长刺激、提高浴液[K⁺]以及添加肾上腺素则可增强钾离子的再摄取和消耗。钾离子再摄取过程的这些离子和药物依赖性与钠钾ATP酶系统的离子和药物依赖性相似。4. 频率诱导的钾离子积累似乎是由于钠泵激活延迟所致。5. 细胞内钠离子浓度[Na⁺]i随频率变化可能发生的改变，似乎比细胞外钾离子浓度[K⁺]o的变化对钾离子再摄取过程的刺激作用更强。6. 通过测量静息电位也检测到了频率诱导的[K⁺]o变化。在电刺激期间及之后观察到的膜电位和动作电位持续时间的改变提示存在电生性钾离子再摄取过程。7. 除了对动作电位有直接影响外，钙离子和镁离子对钠泵活性几乎没有影响。镍离子抑制泵活性，而钡离子通过阻断静息钾离子电导间接增强钾离子摄取过程。8. 钾离子摄取速率估计在3至8皮摩尔/平方厘米·秒之间。由于钾离子进出细胞旁间隙的扩散过程要慢得多（半衰期为60 - 90秒），因此它对细胞旁[K⁺]的逐搏控制贡献不大。