The recent discovery and characterization of several proteins that purify with endogenous, bound retinoid have given rise to the suggestion that these proteins, which are abundant in retina, perform a role in transport and function of vitamin A. Immunocytochemical techniques were used to localize two retinoid-binding proteins in the retina of four species. Antisera to cellular retinal-binding protein (CRALBP) and an interphotoreceptor retinoidbinding protein (IRBP) were obtained from rabbits immunized with antigens purified from bovine retina. Antibodies from each antiserum reacted with a single component in retinal homogenates and supernatants which corresponded to the molecular weight and charge of the respective antigen (non-SDS and SDS PAGE, electrophoretic transfer to nitrocellulose, immunochernical staining). Immunocytochemistry controls were antibodies from nonimmune serum and antibodies absorbed with purified antigen. Antigens were localized on frozensectioned bovine, rat, monkey, and human retina using immunofluorescence and the peroxidase-antiperoxidase technique. Specific staining with anti-IRBP was found in the space that surrounds photoreceptor outer segments, with heaviest labeling in a line corresponding to the retinal pigment epithelium (RPE) apical surface. Cone outer segments were positive. Staining with anti-CRALBP was found in two cell types in all species: the RPE and the M011er glial cell. Within the RPE, labeling filled the cytoplasm and was heaviest apically, with negative nuclei. Labeling of M011er cells produced Golgi-like silhouettes with intense staining of all cytoplasmic compartments. Staining of the external limiting membrane was heavy, with labeled microvilli projecting into the interphotoreceptor space. Localization of IRBP to this space bordered by three cell types (RPE, photoreceptor, and Mfiller) is consistent with its proposed role in transport of retinoids among cells. Localization of CRALBP in RPE corroborates previous biochemical studies; its presence in the MOiler cell suggests that this glial cell may play a hitherto unsuspected role in vitamin A metabolism in retina.
Mutations in the human CRALBP gene cause retinal pathology and delayed dark adaptation. Biochemical studies have not identified the primary physiological function of CRALBP. To resolve this, we generated and characterized mice with a non-functional CRALBP gene (Rlbp1(-/-) mice). The photosensitivity of Rlbp1(-/-) mice is normal but rhodopsin regeneration, 11-cis-retinal production, and dark adaptation after illumination are delayed by >10-fold. All-trans-retinyl esters accumulate during the delay indicating that isomerization of all-trans- to 11-cis-retinol is impaired. No evidence of photoreceptor degeneration was observed in animals raised in cyclic light/dark conditions for up to 1 year. Albino Rlbp(-/-) mice are protected from light damage relative to the wild type. These findings support a role for CRALBP as an acceptor of 11-cis-retinol in the isomerization reaction of the visual cycle.
The reduction of all-trans-retinal in photoreceptor outer segments is the first step in the regeneration of bleached visual pigments. We report here the cloning of a dehydrogenase, retSDR1, that belongs to the shortchain dehydrogenase/reductase superfamily and localizes predominantly in cone photoreceptors. retSDR1 expressed in insect cells displayed substrate specificities of the photoreceptor all-trans-retinol dehydrogenase. Homology modeling of retSDR1 using the carbonyl reductase structure as a scaffold predicted a classical Rossmann fold for the nucleotide binding, and an Nterminal extension that could facilitate binding of the enzyme to the cell membranes. The presence of retSDR1 in a subset of inner retinal neurons and in other tissues suggests that the enzyme may also be involved in retinol metabolism outside of photoreceptors.
Dark adaptation requires timely deactivation of phototransduction and efficient regeneration of visual pigment. No previous study has directly compared the kinetics of dark adaptation with rates of the various chemical reactions that influence it. To accomplish this, we developed a novel rapid-quench/mass spectrometry-based method to establish the initial kinetics and site specificity of light-stimulated rhodopsin phosphorylation in mouse retinas. We also measured phosphorylation and dephosphorylation, regeneration of rhodopsin, and reduction of all-trans retinal all under identical in vivo conditions. Dark adaptation was monitored by electroretinography. We found that rhodopsin is multiply phosphorylated and then dephosphorylated in an ordered fashion following exposure to light. Initially during dark adaptation, transduction activity wanes as multiple phosphates accumulate. Thereafter, full recovery of photosensitivity coincides with regeneration and dephosphorylation of rhodopsin.
The reaction catalyzed by all-trans-retinol dehydrogenase of rod outer segments completes the quenching of photoactivated rhodopsin and initiates the cycle of reactions leading to regeneration of visual pigment. The goal of this study was to determine the kinetic parameters of the dehydrogenase at physiological levels of bleaching, to investigate its specificity, and to determine its possible role in modulating phototransduction. Reduction of all-trans-retinal could be measured after bleaching < 0.15% rhodopsin. Kinetic parameters for the forward reaction determined with endogenous all-trans-retinal were Km = 1.1 microM; Vmax = 7 nmol/min/mg rhodopsin. The low enzymatic activity suggests that at high bleach rates, all-trans-retinal could accumulate, increasing the steady state level of bleaching intermediates or promoting formation of pseudophotoproducts. Active pseudophotoproducts, which stimulate Gt activation and opsin phosphorylation by rhodopsin kinase, are formed with opsin and all-trans-retinal as well as retinal analogues lacking the 13 methyl or the terminal two carbons of the polyene chain. Addition of all-trans-retinol, NADP, and [32P]ATP to rod outer segments increased rhodopsin phosphorylation. Kinetic parameters for the reverse reaction determined with exogenous all-trans-retinol were Km = 10 microM; Vmax = 11 nmol/min/mg rhodopsin. Our results support the hypothesis that all-trans-retinol dehydrogenase could influence the phototransduction cascade, including activities of Gt, rhodopsin kinase, and binding of arrestin, by impeding the recycling of rhodopsin at high bleach levels.
In photoreceptor cells of the retina, photoisomerization of 11-cis-retinal to all-trans-retinal triggers phototransduction. Regeneration of 11-cis-retinal proceeds via a complex set of reactions in photoreceptors and in adjacent retinal pigment epithelial cells where all-transretinol is isomerized to 11-cis-retinol. Our results show that isomerization in vitro only occurs in the presence of apo-cellular retinaldehyde-binding protein. This retinoid-binding protein may drive the reaction by mass action, overcoming the thermodynamically unfavorable isomerization. Furthermore, this 11-cis-retinol/11-cisretinal-specific binding protein potently stimulates hydrolysis of endogenous 11-cis-retinyl esters but has no effect on hydrolysis of all-trans-retinyl esters. Apo-cellular retinaldehyde-binding protein probably exerts its effect by trapping the 11-cis-retinol product. When retinoid-depleted retinal pigment epithelial microsomes were preincubated with different amounts of all-transretinol to form all-trans-retinyl esters and then [ 3 H]alltrans-retinol was added, as predicted, the specific radioactivity of [ 3 H]all-trans-retinyl esters increased during subsequent reaction. However, the specific radioactivity of newly formed 11-cis-retinol stayed constant during the course of the reaction, and it was largely unaffected by expansion of the all-trans-retinyl ester pool during the preincubation. The absence of dilution establishes that most of the ester pool does not participate in isomerization, which in turn suggests that a retinoid intermediate other than all-trans-retinyl ester is on the isomerization reaction pathway.Photoisomerization of 11-cis-retinal to all-trans-retinal is the key reaction that initiates vision (1). 11-cis-retinal is coupled via a Schiff base to a Lys residue located in the transmembrane portion of the rod and cone photoreceptor opsins. Photoisomerization triggers conformational changes in these receptors that lead to activation of G-proteins and subsequent initiation of the signaling cascade of reactions, which comprise phototransduction (2).How all-trans-retinal is isomerized back to 11-cis-retinal is one of the fundamental questions in vision. A pulse of intense light, which occasionally bleaches nearly 100% of our visual pigment, quickly generates 3 mM all-trans-retinal in the photoreceptor cell outer segment. Yet in a matter of minutes (the time constant in humans is 400 s for rhodopsin; Ref.3), the entire cycle of isomerization and pigment regeneration occurs. No free retinals accumulate; all-trans-retinal is either complexed with opsin or reduced and esterified with fatty acids, whereas 11-cis-retinal combines with opsins. Analysis of the visual cycle in mice showed that the concentrations of free retinols and retinals are low compared with the ester pool and with all-trans-retinal and 11-cis-retinal bound to opsins (4). Mutations in any of the genes involved in retinoid metabolism could result in retinal dystrophies and degeneration of photoreceptors. Thus, it is important to understand...
The chromophore of all known visual pigments consists of 11-cis-retinal (derived from either vitamin A1 or A2) or a hydroxylated derivative, bound to a protein (opsin) via a Schiff base. Absorption of a photon results in photoisomerization of the chromophore to all-trans-retinal and conversion of the visual pigment to the signaling form. Regeneration of the 11-cis-retinal occurs in an adjacent tissue and involves several enzymes, several water-soluble retinoid-binding proteins, and intra- and intercellular diffusional processes. Rod photoreceptor cells depend completely on the output of 11-cis-retinal from adjacent retinal pigment epithelial (RPE) cells. Cone photoreceptors cells can use 11-cis-retinal from the RPE and from a second more poorly characterized cycle, which appears to involve adjacent Müller (glial) cells. Recent progress in the characterization of rod and cone visual cycle components and reactions will result in the development of approaches to the amelioration of blinding eye diseases associated with visual cycle defects.
Photoisomerization of 11-cis-retinal to all-trans-retinal and reduction to all-trans-retinol occur in photoreceptor outer segments whereas enzymatic esterification of all-trans-retinol, isomerization to 11-cis-retinol, and oxidation to 11-cis-retinal occur in adjacent cells. The processes are linked into a visual cycle by intercellular diffusion of retinoids. Knowledge of the mechanistic aspects of the visual cycle is very limited. In this study, we utilize chemical analysis of visual cycle retinoids to assess physiological roles for components inferred from in vitro experiments and to understand why excised mouse eyes fail to regenerate their bleached visual pigment. Flash illumination of excised mouse eyes or eyecups, in which regeneration of rhodopsin does not occur, produced a block in the visual cycle after all-trans-retinal formation; constant illumination of eyecups produced a block in the cycle after all-trans-retinol formation; and constant illumination of whole excised eyes resulted in a block of the cycle after formation of all-trans-retinyl ester. These blocks emphasize the role of cellular metabolism in the visual cycle. Interphotoreceptor retinoid-binding protein (IRBP) has been postulated to play a role in intercellular retinoid transfer in the retina; however, the rates of recovery of 11-cis-retinal and of regeneration of rhodopsin in the dark in IRBP-/- mice were very similar to those found with wild-type (wt) mice. Thus, IRBP is necessary for photoreceptor survival but is not essential for a normal rate of visual pigment turnover. Arrestin forms a complex with activated rhodopsin, quenches its activity, and affects the release of all-trans-retinal in vitro. The rate of recovery of 11-cis-retinal in arrestin-/- mice was modestly delayed relative to wt, and the rate of rhodopsin recovery was approximately 80% of that observed with wt mice. Thus, the absence of arrestin appeared to have a minor effect on the kinetics of the visual cycle.
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