POTASSIUM‐INDUCED RELEASE OF [ 3 H]GABA AND OF [ 3 H]NORADRENALINE FROM NORMAL AND RESERPINIZED RAT BRAIN CORTEX SLICES. DIFFERENCES IN CALCIUMDEPENDENCY, AND IN SENSITIVITY TO POTASSIUM IONS

— The release of [ 3 H]GABA induced by elevated extracellular potassium (K) o , from thin rat brain cortex slices, has been compared with that of [ 3 H]noradrenaline ([ 3 H]NA), released by the same procedures, both from normal slices, and from slices pre‐treated with reserpine and nialamide, [ 3 H]NA being predominantly a vesicular component in the former situation, and a soluble substance in the latter one. 46 mM‐(K) o released considerably more [ 3 H]NA from normal than from drug‐treated slices, while the release of GABA was about two thirds of the latter. When 4min ‘pulses’ of increasing concentrations of potassium were applied, it was observed that the release of GABA and of [ 3 H]NA from drug‐treated slices increased in proportion to (K) o , up to 36‐46 mM and then declined considerably with higher (K) o . The dependency of potassium‐induced release on the concentration of calcium in the medium, indicated that release of [ 3 H]NA from normal slices was proportional to calcium up to 1.5‐2 mM, while that of [ 3 H]NA from drug‐treated slices increased up to 0.5 mM‐Calcium, and then declined with higher concentrations. GABA release also increased up to 0.5 mM‐calcium, but no further changes were observed at higher concentrations. The calcium antagonist D‐600 inhibited high (K) o ‐induced release of [ 3 H]NA from normal slices to a greater extent than that of [ 3 H]GABA or of [ 3 H]NA from drug‐treated slices. These results, in which elevated (K) o ‐induced release of [ 3 H]GABA resembles considerably that of soluble NA, but differs from that of NA present in synaptic vesicles, suggest that release of [ 3 H]GABA also occurs from the soluble cytoplasmic compartment, and that the partial calcium requirement that is found is unrelated to that of transmitter secretion. These findings are also a further indication of the lack of specificity of elevated (K) o as a stimulus for inducing transmitter secretions.