静息和活动状态下小的无髓神经纤维中的磷酸盐外流和氧消耗。

Phosphate efflux and oxygen consumption in small non-myelinated nerve fibres at rest and during activity.

作者信息

Ritchie J M, Straub R W

出版信息

J Physiol. 1979 Feb;287:315-27. doi: 10.1113/jphysiol.1979.sp012661.

DOI:10.1113/jphysiol.1979.sp012661

PMID:430413

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1281497/

Abstract

The oxygen consumption and the movements of labelled phosphate were measured in garfish olfactory nerve at rest and during activity.2. In solutions with 2.5 mM-K and 0.2 mM-phosphate the resting oxygen consumption was 0.206 m-mole/kg.min; activity at 2 sec(-1) produced an extra oxygen consumption of 2.46 mumole/kg.impulse. The extra oxygen consumption declined exponentially with a time constant of 2.62 min at 22-26 degrees C.3. The phosphate efflux, measured simultaneously, had a resting efflux rate constant of 1.24 x 10(-3) min(-1); activity at 2 sec(-1) produced an extra fractional loss of 9.38 x 10(-6) impulse(-1). The increase in phosphate efflux followed almost the same time course as the increase in oxygen consumption.4. Increasing the frequency of stimulation from 2 sec(-1) to 3 or 5 sec(-1) decreased both the extra oxygen consumption and the extra fractional loss of phosphate. When the frequency was decreased to 0.5 or 1 sec(-1) the extra oxygen consumption per impulse increased, while the extra phosphate liberation was lowered.5. Changing the phosphate concentration did not much affect the extra oxygen consumption; on the other hand, lowering or increasing the phosphate from the standard 0.2 mM decreased both the resting and the stimulated phosphate efflux.6. Lowering the K from the standard 2.5 mM did not affect the extra oxygen consumption, but increased both the resting and the extra loss of phosphate. At higher K concentrations the extra oxygen consumption and the extra fractional loss of phosphate decreased without much change in the resting phosphate efflux.7. Application of 1-20 muM-strophanthidin produced a transient decrease in the resting phosphate efflux without much change in resting oxygen consumption. With 10 or 20 muM-strophanthidin the extra fractional loss of phosphate and the extra oxygen consumption were both lowered in approximately the same proportions.8. The findings are consistent with the hypothesis that the increase in intracellular inorganic phosphate that results from increased break-down of ATP after activity, is the main cause for the increased phosphate efflux. A fraction of the increase in intracellular phosphate only appears to be liberated to the outside, the value of the fraction depending on the resting phosphate efflux before activity.9. The initial increase in intracellular inorganic phosphate after an impulse, estimated from the oxygen consumption or the phosphate fluxes, appears to be about 12-19 mumole/kg nerve, remarkably close to the value known from chemical analysis.

摘要

对长吻鱼嗅觉神经在静息状态和活动状态下的耗氧量及标记磷酸盐的移动情况进行了测量。
在含有2.5 mM - K和0.2 mM - 磷酸盐的溶液中，静息耗氧量为0.206微摩尔/千克·分钟；以2秒⁻¹的频率活动时，额外耗氧量为2.46微摩尔/千克·脉冲。在22 - 26摄氏度下，额外耗氧量以2.62分钟的时间常数呈指数下降。
同时测量的磷酸盐外流，其静息外流速率常数为1.24×10⁻³分钟⁻¹；以2秒⁻¹的频率活动时，额外的分数损失为9.38×10⁻⁶脉冲⁻¹。磷酸盐外流的增加与耗氧量的增加几乎遵循相同的时间进程。
将刺激频率从2秒⁻¹增加到3或5秒⁻¹，会降低额外耗氧量和磷酸盐的额外分数损失。当频率降至0.5或1秒⁻¹时，每脉冲的额外耗氧量增加，而额外的磷酸盐释放量降低。
改变磷酸盐浓度对额外耗氧量影响不大；另一方面，将磷酸盐浓度从标准的0.2 mM降低或升高，会降低静息和刺激状态下的磷酸盐外流。
将K浓度从标准的2.5 mM降低，不影响额外耗氧量，但会增加静息和额外的磷酸盐损失。在较高的K浓度下，额外耗氧量和磷酸盐的额外分数损失降低，而静息磷酸盐外流变化不大。
应用1 - 20微摩尔的毒毛花苷会使静息磷酸盐外流短暂降低，而静息耗氧量变化不大。使用10或20微摩尔的毒毛花苷时，磷酸盐的额外分数损失和额外耗氧量均以大致相同的比例降低。
这些发现与以下假设一致：活动后ATP分解增加导致细胞内无机磷酸盐增加，这是磷酸盐外流增加的主要原因。细胞内磷酸盐增加的一部分似乎仅释放到细胞外，释放部分的值取决于活动前的静息磷酸盐外流。
根据耗氧量或磷酸盐通量估算，冲动后细胞内无机磷酸盐的初始增加量似乎约为12 - 19微摩尔/千克神经，与化学分析已知的值非常接近。