The current study aims to assess the vulnerability of photoreceptors in rat retina to variations in tissue oxygen levels. Young adult Sprague-Dawley rats were exposed to air with the concentration of oxygen set at 10% (hypoxia), 21% (room air, normoxia), and four levels of hyperoxia (45%, 65%, 70%, and 75%), for up to 3 weeks. Their retinas were then examined for cell death, using the TUNEL technique. Hypoxia (10% oxygen) for 2 weeks caused a limited but significant rise in the frequency of TUNEL+ (dying) cells in the retina, the great majority (> 90%) being located in the outer nuclear layer (ONL). Hyperoxia also induced an increase in the frequency of TUNEL+ cells, again predominantly in the ONL. The increase rose with duration of exposure, up to 2 weeks. At 2 weeks exposure, the increase was limited yet significant at 45% oxygen, and maximal at 65%. Where the frequencies of TUNEL+ cells were high, it was evident that photoreceptor death was maximal in the midperipheral retina. The adult retina is vulnerable to maintained shifts in oxygen availability to the retina, both below and above normal. The vulnerability is specific to photoreceptors; other retinal neurons appeared resistant to the exposures tested. Shifts in retinal oxygen levels caused by variations in ambient light, by the persistence of light through the normally dark (night) half of the day–night cycle, or by depletion of the photoreceptor population, may contribute to photoreceptor death in the normal retina.

In the vertebrate retina, vision is initiated and maintained by the photolysis and regeneration, respectively, of light-sensitive pigments in the disk membranes of the photoreceptor outer segments. This cyclical process depends on an exchange of retinoids between the photoreceptors and the retinal pigment epithelium (RPE). There is a great deal of indirect evidence that the transport of retinoids between these cellular compartments is mediated by the interphotoreceptor retinoid-binding protein (IRBP), a large glycoprotein synthesized in the photoreceptors and extruded into the interphotoreceptor matrix (IPM) that fills the subretinal space. Nevertheless, a number of in vitro experiments have demonstrated that an intermembranous transfer of retinoids can occur through an aqueous medium independent of any retinoid-binding protein. This led to the suggestion that IRBP may play the more passive role of an extracellular buffer, serving to prevent the degradation and potentially cytotoxic effects of free retinoids when large amounts are released into the IPM. We have studied the structural and functional properties of transgenic mice in which homologous recombination was used to delete the IRBP gene. Light- and electron-microscopic examination of the retinas of “knockout” (IRBP−/−) mice revealed a significant loss of photoreceptor nuclei, and profound changes in the structure and organization of the receptor outer segments. Consistent with these observations, electroretinographic recordings showed a marked reduction in response amplitude for both rod- and cone-mediated potentials. However, despite the histological and electrophysiological changes, there was no evidence of gross abnormalities in the visual cycle. After bleaching a significant fraction of the available rhodopsin, electroretinogram amplitude and rhodopsin density gradually increased toward their pre-bleach levels, and the rates of recovery were even more rapid than those seen in wild-type (IRBP+/+) mice.