钴离子对青蛙神经肌肉传导的作用。
The action of cobalt ions on neuromuscular transmission in the frog.
作者信息
Weakly J N
出版信息
J Physiol. 1973 Nov;234(3):597-612. doi: 10.1113/jphysiol.1973.sp010363.
Abstract
- Cobalt ions, in concentrations of 0.05-2 mM, block neuromuscular transmission in the frog sartorius muscle.2. The reduction in the e.p.p. amplitude produced by Co(2+) is due to a decrease in the amount of transmitter released by a nerve impulse (mean quantum content). This reduction is associated with little change in the resting membrane potential of the muscle fibre or in the mean amplitude of spontaneous m.e.p.p.s.3. The reduction in evoked transmitter release produced by Co(2+) may be antagonized by elevation of the external Ca(2+) concentration. It is suggested that the antagonism between Co(2+) and Ca(2+) is competitive in nature.4. The mean dissociation constant for Co(2+) and its hypothetical membrane complex was found to be 0.18 mM. On this basis, it is concluded that Co(2+) is about 20 times more potent than Mg(2+) in suppressing evoked transmitter release.5. In contrast to the inhibitory action on evoked release, Co(2+) increases spontaneous transmitter release. However, concentrations of Co(2+) 20-60 times greater than those which decrease the e.p.p. amplitude are needed to produce a significant increase in m.e.p.p. frequency.
摘要
浓度为0.05 - 2 mM的钴离子会阻断青蛙缝匠肌的神经肌肉传递。
钴离子(Co²⁺)导致的终板电位(e.p.p.)幅度降低是由于神经冲动释放的递质数量减少(平均量子含量)。这种降低与肌肉纤维静息膜电位或微小终板电位(m.e.p.p.s)的平均幅度变化不大有关。
外部钙离子(Ca²⁺)浓度升高可拮抗钴离子(Co²⁺)引起的诱发递质释放减少。提示Co²⁺与Ca²⁺之间的拮抗作用本质上是竞争性的。
发现Co²⁺与其假设的膜复合物的平均解离常数为0.18 mM。据此得出结论,在抑制诱发递质释放方面,Co²⁺的效力约为镁离子(Mg²⁺)的20倍。
与对诱发释放的抑制作用相反,Co²⁺会增加自发递质释放。然而,要使微小终板电位(m.e.p.p.)频率显著增加,所需的Co²⁺浓度要比降低终板电位(e.p.p.)幅度的浓度高20 - 60倍。
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