Quantification of in vivo anaerobic metabolism in the normal cat retina through intraretinal pH measurements

We examined intraretinal [H(+)] in the intact retina of anesthetized cats using H(+)-sensitive microelectrodes to obtain spatial profiles of extracellular [H(+)]. One H(+) is produced when an anaerobically generated ATP is utilized. We theorized that H(+) production directly reflects anaerobic glucose consumption. From the choroid (pH similar to7.40), [H(+)](o) steadily increased to a maximum concentration in the proximal portion of the outer nuclear layer (pH similar to7.20). The shape of the profile was always concave down, indicating that a net production of H(+) occurred across the avascular outer retina. A three-layer diffusion model of the outer retina was developed and fitted to the data to quantify photoreceptor H(+) extrusion into the extracellular space Q(OR-H)+ It was determined that the outer segment (OS) layer had negligible H(+) extrusion. The data were then refitted to a special three-layer model in which the OS layer Q(H)+ was set equal to zero, but in which the inner segments and outer nuclear layer produced H(+). The resulting Q(OR-H)+ was several orders of magnitude lower than previous measurements Of Q(OR-lactate), which were based on choroidal mass balances of lactate. Stoichiometrically, one H(+) is produced for each lactate produced, so we concluded that Q(OR-H)+ is a measure of net rather than total H(+) production. Because retinal acid production is so high, the retina must contain efficient H(+) clearance and/or neutralization mechanisms that prevent severe acidosis. The effect of light on retinal extracellular [H(+)] and Q(OR-H)+ was also examined. As expected, light adaptation caused a retinal alkalinization that resulted from a 52% reduction in Q(OR-H)+. This is in agreement with previous studies that have shown that both oxidative (e.g. Haugh et al., 1990) and glycolytic metabolism (Wang et al., 1997a,c) in the photoreceptor are decreased by a factor of 2 during light adaptation. Although we could not obtain absolute values for outer retinal glycolysis, changes in QOR-H+ appear to directly reflect changes in glycolytic metabolism.