Intracellular chloride in retinal neurons: Measurement and meaning

Intracellular chloride acitivity measurements were obtained from mudpuppy retinal neurons using dual microelectrodes, one of which was made chloride-selective by filling the tip with chloride liquid ion exchange resin. In addition ionic substitution experiments were carried out in the perfused retina-eyecup preparation of the mudpuppy. A comparison of the membrane potential and calculated chloride equilibrium potential shows that retinal neurons differ in relative transmembrane chloride distribution. Ganglion cells have an E_c1, more negative than the resting membrane potential, whereas amacrine cells have a passive distribution of chloride. Horizontal cells have chloride distributed such that an increase in chloride conductance is depolarizing. On-bipolars have a chloride distribution similar to that of horizontal cells whereas off-bipolars show either passive distribution or some chloride accumulation. These findings are consistent with the idea that chloride ions may play a role as a depolarizing driving force for electrogenic activity of horizontal cells and on-bipolars. Results with Cl substitution experiments are consistent with this interpretation.