Fourth module of Xenopus interphotoreceptor retinoid-binding protein: activity in retinoid transfer between the retinal pigment epithelium and rod photoreceptors.

PURPOSE: Interphotoreceptor retinoid-binding protein (IRBP), an extracellular protein believed to support the exchange of retinoids between the neural retina and retinal pigment epithelium (RPE) in the vertebrate eye, exhibits a modular, i.e., repeat, structure. The present study was undertaken to determine whether an individual module of IRBP has activity in retinoid transfer between the RPE and rod photoreceptors. METHODS: The retinoid transfer activity of a recombinant protein corresponding to the fourth module of Xenopus laevis IRBP (X4IRBP) was examined in two ways. First, X4IRBP was tested for its ability to support the regeneration of porphyropsin in detached/reattached Xenopus retina/RPE-eyecups. Following illumination and removal of native IRBP, Xenopus eyecups supplemented with 42 microM X4IRBP or (as a control) Ringer's solution were incubated in darkness and then analyzed for regenerated porphyropsin. Second, toad (Bufo marinus) RPE-eyecup preparations were used to evaluate X4IRBP's ability to promote the release of 11-cis retinal from the RPE. RESULTS: The regeneration of porphyropsin in X4IRBP-supplemented Xenopus retina/RPE-eyecups (0.45 +/- 0.04 nmol; mean +/- SEM, n = 11) exceeded that in controls (0.13 +/- 0.02 nmol, n = 11). For promoting the release of 11-cis retinal from the toad RPE, 42 microM X4IRBP was more effective than equimolar bovine serum albumin although considerably less than that of 26 microM native bovine IRBP. CONCLUSIONS: The results indicate a low but significant activity of IRBP's fourth module in reactions relevant to retinoid exchange.

Functional properties of interphotoreceptor retinoid-binding protein.

It has been hypothesized that interphotoreceptor retinoid-binding protein (IRBP) functions as a two-way carrier of retinoid between the retinal pigment epithelium (RPE) and rod photoreceptors in the vertebrate eye. This hypothesis has been tested in recent studies that have employed purified, initially ligand-free, bovine IRBP and the "RPE-eyecup" obtained from the toad (Bufo marinus) eye. The present experiments further characterize the IRBP/RPE-eyecup system with respect to (i) the solubilization and protection of retinol by IRBP, and (ii) the time course of IRBP-mediated release of 11-cis retinal by the RPE. The data, together with previous findings in the IRBP/RPE-eyecup preparation, support the view that 11-cis retinal is the principal retinoid released by the RPE into IRBP-supplemented aqueous medium, and that IRBP in vivo promotes the regeneration of rhodopsin by facilitating the exchange of retinoid between bleached rods and the RPE.

Interphotoreceptor retinoid-binding protein promotes rhodopsin regeneration in toad photoreceptors.

Interphotoreceptor retinoid-binding protein (IRBP) has been hypothesized to function as an intercellular shuttle in the vertebrate eye, serving to transport retinoids between the retinal pigment epithelium (RPE) and photoreceptors in the process by which visual pigment is regenerated after photolysis. This hypothesis was tested in preparations utilizing the toad (Bufo marinus) eye and purified, initially ligand-free IRBP obtained from the bovine eye. Rod outer segments (ROS) or neural retinas were isolated and bleached, then incubated with native RPE (RPE-eyecup) in the presence or absence of IRBP. The amount of rhodopsin present after incubation was determined by spectrophotometric analysis and compared with that in control preparations receiving bovine serum albumin or Ringer's solution only. Supplementation with IRBP enhanced the formation of rhodopsin in both the ROS/RPE-eyecup and retina/RPE-eyecup preparations. Regeneration in ROS/RPE-eyecups receiving IRBP (1.8 nmol) increased in a roughly linear manner with the period of incubation (0-4 hr), at a rate of 0.44 nmol/hr. The extent of regeneration was graded with the quantities of IRBP and opsin introduced into the RPE-eyecup. With increasing amounts of IRBP (up to 5.2 nmol) or of initially available opsin (up to 15.6 nmol), the amount of rhodopsin formed (3-hr incubation) approached the same plateau value, about 2.5 nmol. Analysis of IRBP-supplemented Ringer's solution incubated in the RPE-eyecup showed 11-cis-retinal to be virtually the only retinoid withdrawn from the RPE. With large quantities of IRBP (3.2-9.2 nmol), the amount of 11-cis-retinal (2.7 +/- 0.5 nmol) withdrawn from the RPE during a 3-hr incubation was similar to the plateau value of rhodopsin formed in the ROS/RPE-eyecup. No 11-cis-retinal was observed in albumin-supplemented Ringer's solution (0.4-11.2 nmol of bovine serum albumin) or in Ringer's alone after similar incubation in the RPE-eyecup. The results suggest that an IRBP-mediated transfer of 11-cis-retinal from the RPE to the rods supports rhodopsin regeneration in vivo.

Activity of rhodopsin in vitamin A-deprived rats: light-dependent binding of G-protein.

Levels of rhodopsin in the photoreceptors of Long-Evans rats were reduced by approximately 55% through dietary deprivation of vitamin A. The interaction of visual pigment with G-protein was examined in receptor outer segment (ROS) membranes obtained from these animals. A binding assay was used to quantitate affinity of the visual pigment in unbleached and bleached ROS membranes for the alpha and beta subunits of exogenous G-protein. Extents of binding were similar to those observed for ROS membranes of rats raised on a normal (vitamin A-supplemented) diet. The results are consistent with a normal capacity for G-activation by photoactivated rhodopsin (R*) in vitamin A-deprived animals. They further indicate that "free opsin" arising in vitamin A deficiency, unlike R*, has relatively low affinity for G-protein.

Interaction of visual pigment with G-protein: effects of bleaching in native and reconstituted ROS preparations.

Native and reconstituted preparations of bullfrog rod outer segment (ROS) membranes were analysed for the binding of the alpha and beta subunits of G-protein. Following incubation at 22-28 degrees C under varying conditions of illumination and chemical treatment, preparations were chilled and extracted with hypotonic medium lacking-vs.-containing GTP (H and HG extracts, respectively). The extent of binding of G alpha,beta ('percentage G bound') was determined by measurement of the relative abundance of G alpha, beta in the H and HG extracts. The addition of G to unbleached, G-depleted membranes (D-ROS) yielded relatively little binding of the G (14 +/- 13%). G reintroduced at congruent to 1 min vs. congruent to 90 min after major bleaching yielded, respectively, levels of binding of 88 +/- 8% and 24 +/- 8%. Native G, extracted at congruent to 90 min post-bleach and added to freshly bleached D-ROS, exhibited binding exceeding that in the parent (bleached +90 min) sample. Supplementation of reconstituted suspensions with all-trans retinal, and subsequent incubation in darkness, yielded 30-35% G-binding; similar treatment with 11-cis retinal yielded binding in the range of 0-32%. Upon irradiation, suspensions previously supplemented with either isomer exhibited approximately 60% binding. Incubation with 11-cis retinal had no substantial effect on the condition of tight binding observed shortly after bleaching. The data are discussed in relation to previous studies of visual pigment bleaching and regeneration.