The objective of this research was to determine the sources and sinks of current underlying the slow PIII component of the electroretinogram. Current source density analysis of the ERG evoked by diffuse light flashes was performed in eyecup and isolated retinas of frog. Blockade of synaptic transmission with aminophosphonobutyric + kynurenic acids simplified the CSD profiles through the retina. In addition to the photoreceptor source/sink pair, there was evidence for a major slow PIII source near the outer limiting membrane, a major sink near the inner limiting membrane, and a small source near the inner plexiform layer. Addition of Ba2+ abolished the slow PIII source/sinks, and it left only the photoreceptor source and sink. The results support the idea that slow PIII originates through K+ spatial buffering by Müller cells. Specifically, the light-evoked decrease in [K+]0 in the subretinal space causes a primary K+ efflux from Müller cells (current source) and a primary K+ influx at the Müller cell endfeet (current sink). A decrease in [K+]0 in the proximal retina, caused by diffusion of K+ to the subretinal space, results in K+ efflux (the current source) at the inner plexiform layer.

Retinal neurons and Müller cells express amiloride-sensitive Na+ channels (ASSCs). Although all major subunits of these channels are expressed, their physiological role is relatively unknown in this system. In the present study, we used the electroretinogram (ERG) recorded from anesthetized rabbits and isolated rat and rabbit retina preparations to investigate the physiological significance of ASSCs in the retina. Based upon our previous study showing expression of α-ENaC and functional amiloride-sensitive currents in rabbit Müller cells, we expected changes in Müller cell components of the ERG. However, we observed changes in other components of the ERG as well. The presence of amiloride elicited changes in all major components of the ERG; the a-wave, b-wave, and d-wave (off response) were enhanced, while there was a reduction in the amplitude of the Müller cell response (slow PIII). These results suggest that ASSCs play an important role in retinal function including neuronal and Müller cell physiology.