Extracellular pH in the isolated retina of the toad in darkness and during illumination.

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Extracellular pH in the isolated retina of the toad in darkness and during illumination.

B Oakley, 2nd and R Wen

Department of Electrical and Computer Engineering, University of Illinois at Urbana-Champaign 61801-2991.

1. Extracellular pH (pHo) was measured in the isolated retinapreparation of the toad, Bufo marinus, using H(+)-selectivemicroelectrodes. During superfusion with phosphate-bufferedsolution (pH 7.8), which had a low buffering capacity, pHo inthe inner retina was 7.0-7.2 and there was a pHo gradient throughoutthe distal retina and into the bathing solution. 2. The retinalacidity appears to be due in part to the combined reactionsof glycolysis and ATP hydrolysis, since anoxia greatly increasedthe pHo gradient, while superfusion with either glucose-freepyruvate solution or strophanthidin decreased this gradient.3. Maintained illumination evoked both an acidification in theproximal retina and an alkalinization in the distal retina.Blocking synaptic transmission to second-order neurones (1.0mM-aspartate) decreased the acidification but had little effecton the alkalinization, consistent with the notion that the alkalinizationis of receptoral origin, while the acidification is of post-receptoralorigin. 4. Retinal neurones extrude a significant amount ofacid via Na(+)-H+ exchange, since 2.0 mM-amiloride, a blockerof Na(+)-H+ exchange, caused a sustained alkalinization in darknessand decreased the light-evoked changes in pHo, while 1.0 mM-4-acetamido-4'-isothiocyanatostilbene-2.2'-disulphonicacid (SITS), a blocker of Cl(-)-HCO3- exchange, produced a muchsmaller alkalinization. 5. Switching to a bicarbonate-bufferedsolution having a 75 times greater buffering capacity than thephosphate-buffered solution caused retinal pHo to become lessacidic and significantly decreased the amplitude of the light-evokedpHo changes. 6. Addition of 2.0 mM-acetazolamide, a carbonicanhydrase inhibitor, to the bicarbonate-buffered solution increasedboth the pHo gradient and the light-evoked changes in pHo. Thesedata are consistent with the idea that carbonic anhydrase, whichis concentrated in Müller (glial) cells and to a lesserextent in horizontal cells, increases the effectiveness of thebicarbonate buffer system. 7. Switching from bicarbonate-bufferedto phosphate-buffered solutions attenuated the b-wave of theelectroretinogram, most likely by acidifying pHo. Overall, ourresults emphasize the importance of the bicarbonate buffer systemin buffering pHo during periods of variable acid extrusion inlight and in darkness.

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