The effect of carbon dioxide on the intracellular pH and buffering power of snail neurones.

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The effect of carbon dioxide on the intracellular pH and buffering power of snail neurones.

R C Thomas

1. Intracellular pH (pHi) was measured using pH-sensitive glassmicro-electrodes. The effects on pHi of CO2 applied externallyand HCO3-, H+ and NH4+ injected iontophoretically, were investigated.2. The transport numbers for iontophoretic injection into aqueousmicro-droples were found by potentiometric titration to be 0-3for HCO3- and 0-94 for H+. 3. Exposure to Ringer, pH 7-5, equilibratedwith 2-2% CO2 caused a rapid, but only transient, fall in pHi.Within 1 or 2 min pHi began to return exponentially to normal,with a time constant of about 5 min. 4. When external CO2 wasremoved, pHi rapidly increased, and then slowly returned tonormal. The pHi changes with CO2 application or removal gavea calculated intracellular buffer value of about 30 m-equivH+/pH unit per litre. 5. Injection of HCO3- caused a rise inpHi very similar to that seen on removal of external CO2. 6.The pHi responses to CO2 application, CO2 removal and HCO3-injection were slowed by the carbonic anhydrase inhibitor acetazolamide.7. H+ injection caused a transient fall in pHi. In CO2 RingerpHi fell less and recovered faster than in CO2-free Ringer.Calculation of the internal buffer value from the pHi responsesto H+ and HCO3- injection gave very similar values. 8. The internalbuffer value (measured by H+ injection) was greatly increasedby exposure to CO2 Ringer. Acetazolamide reduced this effectof CO2, suggesting that the function of intracellular carbonicanhydrase may be to maximize the internal buffering power inCO2. 9. It was concluded that the internal HCO3- was determinedprimarily by the CO2 level and pHi, that internal HCO3- madea large contribution to the buffering power, and that afterinternal acidfication pHi was restored to normal by active transportof H+, OH- or HCO3- across the cell membrane. The active transportwas much faster in CO2 than in CO2-free Ringer.

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