Mechanism of action of GABA on intracellular pH and on surface pH in crayfish muscle fibres.

1. The mode of action of gamma‐aminobutyric acid (GABA) on intracellular pH (pHi) and surface pH (pHs) was studied in crayfish muscle fibres using H(+)‐selective microelectrodes. The extracellular HCO3‐ concentration was varied (0‐30 mM) at constant pH (7.4). 2. GABA (5 x 10(‐6)‐10(‐3) M) produced a reversible fall in pHi which showed a dependence on the concentrations of both GABA and HCO3‐. The fall in pHi was associated with a transient increase in pHs and it was inhibited by a K(+)‐induced depolarization. 3. In the presence of 30 mM‐HCO3‐, a near‐saturating concentration of GABA (0.5 mM) produced a mean fall in pHi of 0.43 units. This change in pHi accounted for about two‐thirds of the GABA‐induced decrease (from ‐66 to ‐29 mV) in the sarcolemmal H+ driving force, while the rest was due to the simultaneous depolarization. 4. The apparent net efflux of HCO3‐ (JHCO3e) produced by a given concentration of GABA was estimated on the basis of the instantaneous rate of change of pHi. In the presence of 30 mM‐HCO3‐, JHCO3e following exposure to 0.5 mM‐GABA had a mean value of 8.0 mmol l‐1 min‐1. Under steady‐state conditions (at plateau acidosis), the intracellular acid load produced by 0.5 mM‐GABA was about 25% of that seen at the onset of the application. 5. The GABA‐induced HCO3‐ permeability, calculated on the basis of the flux data, showed a concentration dependence similar to that of the GABA‐activated conductance described in previous work. 6. The GABA‐induced increase in pHs was immediately blocked by both a membrane‐permeant inhibitor of carbonic anhydrase (acetazolamide, 10(‐6) M) and by a poorly permeant inhibitor (benzolamide, 10(‐6) M). 7. Application of acetazolamide (10(‐4) M) for 5 min or more produced a decrease of up to 60% in the maximum rate of fall of pHi at GABA concentrations higher than 20 microM. 8. The recovery of the GABA‐induced acidosis was associated with a fall in pHs. The recovery was completely blocked in solutions devoid of Na+ or of Cl‐, as well as by DIDS (4,4'‐diisothiocyanostilbene‐2,2'‐disulphonic acid, 10(‐5) M). This indicates that the maintenance of a non‐equilibrium H+ gradient at plateau acidosis and the recovery of pHi are attributable to Na(+)‐dependent Cl(‐)‐HCO3‐ exchange. 9. We conclude that the effects of GABA on pHi and pHs are due to electrodiffusion of HCO3‐ across postsynaptic anion channels.(ABSTRACT TRUNCATED AT 400 WORDS)