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. 1973 Feb;228(3):693–712. doi: 10.1113/jphysiol.1973.sp010107

Effects of electrogenic sodium pumping on the membrane potential of longitudinal smooth muscle from terminal ileum of guinea-pig

T B Bolton
PMCID: PMC1331247  PMID: 4702152

Abstract

1. The membrane potential of the separated longitudinal muscle of the guinea-pig terminal ileum was recorded intracellularly with glass micro-electrodes.

2. In tissues kept at room temperature and then brought to 35° C for 15-30 min or about 1 hr, the fall in membrane potential upon changing to potassium-free solution was 21.4 ± 3.5 mV and 13.4 ± 1.8 mV respectively. Ouabain (1.7 × 10-6 M) produced a fall in membrane potential of 8.1 ± 1.1 mV. Returning potassium to potassium-free solution, or changing from ouabain-containing to ouabain-free solution, resulted in an increase in membrane potential which was greater than the initial fall.

3. Readmitting potassium to potassium-free solution produced an increase in membrane potential which began within 10 sec and reached a maximum within 15-30 sec. This response was reduced, abolished, or converted to a depolarization by ouabain. In chloride-deficient (13 mM) solution in which membrane resistance was increased, the response to readmitting potassium was increased 2½-fold so that the membrane potential sometimes exceeded -100 mV, which was probably more negative than EK. On the basis of these results it was assumed that the response to readmitting potassium was due to the electrogenic activity of the sodium pump.

4. The response to briefly readmitting a fixed concentration of potassium increased during the first 30 min in potassium-free solution. This increase was not due to an increase in membrane resistance as this fell with time in potassium-free solution. It was suggested that the increase in the response resulted from the progressive rise in internal sodium concentration which is known to occur in smooth muscle in potassium-free solution.

5. Increasing the concentration of potassium over the range ∼ 0.1-20 mM, increased the size of the electrogenic potential observed upon readmitting potassium to potassium-free solution. There was a fall in membrane resistance upon readmitting potassium (0.6, 5.9, or 20 mM) which was greater the larger the concentration of potassium. When allowance was made for the fall in membrane resistance, the dependency of the electrogenic response upon the concentration of potassium over the range 0.6-20 mM was much increased.

6. The results indicate that the rate of electrogenic sodium pumping in this tissue is increased by increasing the external potassium concentration, and probably by increasing the internal sodium concentration. It was suggested that a rise in the latter could sensitize the pump to an increase in the former.

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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