An investigation of the ionic mechanism of intracellular pH regulation in mouse soleus muscle fibres.

1. Intracellular pH (pH(i)) of surface fibres of the mouse soleus muscle was measured in vitro by recessed-tip pH-sensitive micro-electrodes. pH(i) was displaced in an acid direction by removal of external (NH(4))(2)SO(4) after a short exposure, and the mechanism of recovery from this acidification was investigated.2. Removal of external K caused a very slow acidification (probably due to the decreasing Na gradient) but had no effect on the rate of pH(i) recovery following acidification. This indicates that K(+)-H(+) exchange is not involved in the pH(i) regulating system.3. Short applications of 10(-4)M ouabain had no obvious effect on pH(i) and did not alter the rate of pH(i) recovery following acidification. This suggests that there is no direct connexion between the regulation of pH(i) and the Na pump.4. Reduction of external Ca from 10 to 1 mM caused a transient fall in pH(i), but the rate of pH(i) recovery following acidification was unaffected. This suggests that Ca(2+)-H(+) exchange is not involved in the pH(i) regulating system.5. An 11% reduction in external Na caused a significant slowing of pH(i) recovery following acidification. 90% or complete removal of external Na almost stopped pH(i) recovery. This suggests that Na(+)-H(+) exchange is involved in pH(i) regulation.6. Amiloride (10(-4)M) reversibly reduced the rate of pH(i) recovery to much the same extent as removal of external Na. Its effect was not additive to that of removal of external Na.7. Internal Na ion concentration (Na(+)), measured using Na(+)-sensitive micro-electrodes, fell on application of (NH(4))(2)SO(4) and increased on its removal. The increase transiently raised Na(+) above the level recorded before (NH(4))(2)SO(4) application. This overshoot of Na(+) was almost completely inhibited by amiloride. This is consistent with the involvement of Na(+)-H(+) exchange in the pH(i) regulating system.8. Removal of external CO(2) or application of SITS (10(-4)M) caused some slowing of the rate of pH(i) recovery following acidification by removal of (NH(4))(2)SO(4). The effect of SITS was additive to that of Na-free Ringer or amiloride. These results suggest that Cl(-)-HCO(3) (-) exchange is also involved in the pH(i) regulating system and that it is a separate mechanism. Under the conditions used, Cl(-)-HCO(3) (-) exchange formed about 20% of the pH(i) regulating system.9. Decreasing the temperature from 37 to 28 degrees C not only caused an increase in pH(i), but also considerably slowed the rate of pH(i) recovery following acidification. We have calculated a Q(10) for Na(+)-H(+) exchange of 1.4 and for Cl(-)-HCO(3) (-) exchange, 6.9.10. We conclude that the pH(i) regulating system is comprised of two separate ionic exchange mechanisms. The major mechanism is Na(+)-H(+) exchange, which is probably driven by the transmembrane Na gradient. The other mechanism is Cl(-)-HCO(3) (-) exchange, which probably requires metabolic energy.