Rod outer segment lipid--opsin ratios in the developing normal and retinal dystrophic rat

Retinal light toxicity

The ability of light to enact damage on the neurosensory retina and underlying structures has been well understood for hundreds of years. While the eye has adapted several mechanisms to protect itself from such damage, certain exposures to light can still result in temporal or permanent damage. Both clinical observations and laboratory studies have enabled us to understand the various ways by which the eye can protect itself from such damage. Light or electromagnetic radiation can result in damage through photothermal, photomechanical, and photochemical mechanisms. The following review seeks to describe these various processes of injury and many of the variables, which can mitigate these modes of injury.

Reduced G protein-coupled signaling efficiency in retinal rod outer segments in response to n-3 fatty acid deficiency

The fatty acid (FA) docosahexaenoic acid (DHA, 22: 6n-3) is highly enriched in membrane phospholipids of the central nervous system and retina. Loss of DHA because of n-3 FA deficiency leads to suboptimal function in learning, memory, olfactory-based discrimination, spatial learning, and visual acuity. G protein-coupled receptor (GPCR) signal transduction is a common signaling motif in these neuronal pathways. Here we investigated the effect of n-3 FA deficiency on GPCR signaling in retinal rod outer segment (ROS) membranes isolated from rats raised on n-3-adequate or -deficient diets. ROS membranes of second generation n-3 FA-deficient rats had approximately 80% less DHA than n-3-adequate rats. DHA was replaced by docosapentaenoic acid (22:5n-6), an n-6 FA. This replacement correlated with desensitization of visual signaling in n-3 FA-deficient ROS, as evidenced by reduced rhodopsin activation, rhodopsin-transducin (G(t)) coupling, cGMP phosphodiesterase activity, and slower formation of metarhodopsin II (MII) and the MII-G(t) complex relative to n-3 FA-adequate ROS. ROS membranes from n-3 FA-deficient rats exhibited a higher degree of phospholipid acyl chain order relative to n-3 FA-adequate rats. These findings reported here provide an explanation for the reduced amplitude and delayed response of the electroretinogram a-wave observed in n-3 FA deficiency in rodents and nonhuman primates. Because members of the GPCR family are widespread in signaling pathways in the nervous system, the effect of reduced GPCR signaling due to the loss of membrane DHA may serve as an explanation for the suboptimal neural signaling observed in n-3 FA deficiency.

Evidence that light modulates protein nitration in rat retina

As part of ongoing efforts to better understand the role of protein oxidative modifications in retinal pathology, protein nitration in retina has been compared between rats exposed to damaging light or maintained in the dark. In the course of the research, Western methodology for detecting nitrotyrosine-containing proteins has been improved by incorporating chemical reduction of nitrotyrosine to aminotyrosine, allowing specific and nonspecific nitrotyrosine immunoreactivity to be distinguished. A liquid chromatography MS/MS detection strategy was used that selects all possible nitrotyrosine peptides for MS/MS based on knowing the protein identity. Quantitative liquid chromatography MS/MS analyses with tetranitromethane-modified albumin demonstrated the approach capable of identifying sites of tyrosine nitration with detection limits of 4-33 fmol. Using two-dimensional gel electrophoresis, Western detection, and mass spectrometric analyses, several different nitrotyrosine-immunoreactive proteins were identified in light-exposed rat retina compared with those maintained in the dark. Immunocytochemical analyses of retina revealed that rats reared in darkness exhibited more nitrotyrosine immunoreactivity in the photoreceptor outer segments. After intense light exposure, immunoreactivity decreased in the outer segments and increased in the photoreceptor inner segments and retinal pigment epithelium. These results suggest that light modulates retinal protein nitration in vivo and that nitration may participate in the biochemical sequela leading to light-induced photoreceptor cell death. Furthermore, the identification of nitrotyrosine-containing proteins from rats maintained in the dark, under non-pathological conditions, provides the first evidence of a possible role for protein nitration in normal retinal physiology.

Endogenous ascorbate regenerates vitamin E in the retina directly and in combination with exogenous dihydrolipoic acid

Vitamin E (alpha-tocopherol) is the major lipid-soluble antioxidant of retinal membranes whose deficiency causes retinal degeneration. Its antioxidant function is realized via scavenging peroxyl radicals as a result of which phenoxyl radicals of alpha-tocopherol are formed. Our hypothesis is that alpha-tocopherol phenoxyl radicals can be reduced by endogenous reductants in the retina, providing for alpha-tocopherol recycling. The results of this study demonstrate for the first time that: (i) endogenous ascorbate (vitamin C) in retinal homogenates and in rod outer segments is able to protect endogenous alpha-tocopherol against oxidation induced by UV-irradiation by reducing the phenoxyl radical of alpha-tocopherol, (ii) in the absence of ascorbate, neither endogenous nor exogenously added glutathione (GSH) is efficient in protecting alpha-tocopherol against oxidation; (iii) GSH does not substantially enhance the protective effect of ascorbate against alpha-tocopherol oxidation; (iv) exogenous dihydrolipoic acid (DHLA), although inefficient in direct reduction of the alpha-tocopherol phenoxyl radical, is able to enhance the protective effect of ascorbate by regenerating it from dehydroascorbate. Thus, regeneration of alpha-tocopherol from its phenoxyl radical can enhance its antioxidant effectiveness in the retina. The recycling of alpha-tocopherol opens new avenues for pharmacological approaches to enhance antioxidants of the retina.

Adaptive changes in visual cell transduction protein levels: effect of light

Long-term environmental light-mediated changes in visual cell transduction proteins were studied to assess the influence of rearing environment on their levels and their potential effects on intense light-induced retinal damage. The levels of rhodopsin, S-antigen and the alpha subunit of transducin were measured in whole eye detergent extracts, retinal homogenates or rod outer segments isolated from rats reared in weak cyclic light or darkness, and following a change in rearing environment. Rats changed from weak cyclic light to darkness had 22% more rhodopsin per eye than cyclic-light rats after 12-14 days in the new environment. Western trans-blot analysis of retinal proteins from these dark-maintained animals contained 65% higher levels of immunologically detectable alpha transducin; S-antigen levels were approximately 45% lower than in cyclic-light rats. In rats changed from the dark environment to weak cyclic light, rhodopsin levels decreased by 18% during a comparable period; retinal alpha transducin was 35% lower, S-antigen was 30% higher. At various times after the change in rearing environment, some rats were exposed to intense visible light to determine their susceptibility to retinal damage. Two weeks after an 8-hr exposure, cyclic-light reared rats had rhodopsin levels only 10% lower than control (2.1 nmol per eye). However, rhodopsin was 75% lower when cyclic-light rats were maintained in darkness for 2 weeks before intense light. For animals originally reared in darkness, rhodopsin was 78% lower following 8 hr of intense light, whereas only 30% rhodopsin loss occurred in dark-reared rats after previous maintenance for 2 weeks in weak cyclic-light.(ABSTRACT TRUNCATED AT 250 WORDS)

Predisposing factors to light-induced photoreceptor cell damage: retinal changes in maturing rats

Retinal changes occurring during the period of growth and maturation of Long Evans pigmented rats were examined to obtain a better understanding of the basis for the age-dependency of light-induced photoreceptor cell damage. Susceptibility to light damage increased markedly between 30 and 60 days of age and to a lesser extent between 60 and 90 days. Although the retinal antioxidant vitamins E and C, and taurine showed a significant increase during the age-period studied, retinal lipid phosphorus and total protein increased by similar amounts indicating that the concentration of these nutrients was not changing. In contrast, rhodopsin content of the retina increased progressively by 44% between 30 and 90 days of age. While ROS length showed no appreciable change with age, rhodopsin per ROS length increased by 31% between 30 and 60 days of age and by 48% between 30 and 90 days. Determinations of ROS phospholipid to rhodopsin ratio and disks per ROS length indicated that rhodopsin did not become more concentrated in photoreceptor cells between 30 and 90 days. However, the 12% increase in ROS diameter between 30 and 90 days of age may partially account for the rhodopsin difference. These findings demonstrate an age-dependent association between greater rhodopsin per ROS length and increased susceptibility to retinal light damage. An increased metabolic demand on photoreceptor cells with greater rhodopsin may be an important factor influencing their destruction by light.

The influence of the lipid bilayer phase state on the p-aminohippurate (PAH) transport and the activity of the alkaline phosphatase in brush-border membrane vesicles from normal and mutant rats

The kinetic parameters of p-aminohippurate transport and activity of the alkaline phosphatase were studied using brush-border membrane vesicles isolated from the kidney cortex of normal and mutant (strain of Campbell) rats. p-Aminohippurate (PAH) transport of both normal and mutant animals was carried out by the mechanism of facilitated diffusion. The apparent Michaelis constant at 36 degrees C was equal to 7 mM, the maximal rate of PAH transport was 15 nmol/min per mg protein and the constant of inhibition by probenecid was 0.5 mM for normal rats and, respectively, 29 mM, 62 nmol/min per mg protein and 1.4 mM for mutant rats. The Arrhenius plot for the PAH transport and activity of the alkaline phosphatase showed the breakpoints at 28-30 degrees C for normal rats and at 36-38 degrees C for the Campbell strain rats. The thermotropic phase transitions detected by the EPR method with 5-doxylstearate as a probe were recorded at 21-30 degrees C and 30-35 degrees C for normal and mutant rats, respectively. Therefore, characteristic features of the PAH carrier and alkaline phosphatase activity in normal and Campbell strain rats are determined by the difference in the phase state of their membrane lipid bilayers. We suppose that mutation in the Campbell strain gives rise to a membrane pleiotropic effect which enables us to understand the mechanism of genetic control of the lipid structure and membrane fluidity.

Filipin and digitonin studies of cell membrane changes during junction breakdown in the dystrophic rat retinal pigment epithelium

We have previously found that a breakdown of tight junctions in retinal pigment epithelial cells of Royal College of Surgeons' rats is associated with a redistribution of intramembrane particles and Na-K-ATPase activity. Changes in the lipid and sterol composition of membranes can alter their fluidity, permeability and enzyme activity, and may contribute to changes in cell barrier function in the dystrophic epithelium. We have now used filipin and digitonin, which bind to membrane sterols and produce membrane deformations recognizable by freeze-fracture and thin-section electron microscopy, to study the distribution of cholesterol and related 3-B-hydroxysterols in the dystrophic epithelium. The results of these studies show that in the normal pigment epithelium and prior to tight junction breakdown in the dystrophic epithelium, filipin- and digitonin-sterol complexes are rare in the membranes between tight junctions and adhering junctions, and in areas of attachment between the plasma membrane and basal lamina. Complexes are more numerous in the basal infoldings, and most densely packed in the lateral and apical microvillous membranes. During junction breakdown, complexes increase substantially in apical, basal, junctional, and nuclear membranes. Later, after the junctions disappear, complexes decrease. These results indicate that alterations in the expression of membrane sterols accompany the changes in structure and function of tight junctions in the dystrophic retinal pigment epithelium.

Docosahexaenoate metabolism and fatty-acid composition in developing retinas of normal and rd mutant mice

The fatty-acid composition of retinal lipids in developing control and rd mice (C57BL/6J) was determined. In addition, fatty-acid composition in brain and retina of normal and rd adult animals was compared. At 11 days of postnatal age, rd retinas contained proportionally less docosahexaenoate than controls, whereas the reverse relationship held for oleate at 20 days of age. In contrast, no differences in the fatty-acid composition of brain lipids were observed between rd and control animals. We also examined docosahexaenoate metabolism in rd and control retinas of different postnatal ages in vitro. These studies of [1-14C]docosahexaenoic-acid incorporation into retinal phospholipids and neutral lipids demonstrated significantly higher incorporation into triacylglycerols of the rd retina, beginning at 14-15 days of postnatal age. Incorporation into diacylglycerols and phospholipids was also higher in rd retinas than in controls at 14 days of age and older. Moreover, the concentration of ganglioside (a glycolipid class probably enriched within inner retinal layers) was higher in adult rd retinas. Degeneration of the rd retina can be detected histologically as early as 8-9 days. Therefore, the alterations of fatty-acid composition and docosahexaenoate metabolism described here are probably an effect, rather than a cause, of retinal degeneration in the rd mouse.

Rod outer segment lipids in vitamin A-adequate and -deficient rats

Weanling albino rats were fed a vitamin-A-adequate diet or vitamin-A-deficient diet and maintained in a cyclic light or dark environment for up to 14 weeks. One half of the rats were supplemented with additional dietary linolenic acid in the form of linseed oil. The lipid composition and rhodopsin-opsin contents of isolated rod outer segments were determined after 6-7 weeks or 12-14 weeks on diet. This study shows that feeding rats a standard vitamin A-adequate or -deficient diet results in an age-dependent loss of omega three docosahexaenoic acid and a concomitant increase in omega six docosapentanoic acid in the rod outer segments. The loss of docosahexaenoate appears to be caused by insufficient dietary omega three fatty acids. The increase in omega six docosapentanoic acid appears to arise from the high concentration of linoleic acid in standard diets containing either cottonseed, or peanut oil or supplemental corn oil. Feeding rats diets supplemented with linseed oil, however, results in a rod outer-segment lipid profile which is the same as for chow-fed animals. The same effects were seen in the fatty-acid profile of lipids from liver, although the content of polyunsaturates was much lower than in rod outer segments. Vitamin A deficiency, itself, does not lead to changes in the fatty-acid composition of either the rod outer segments or liver. After 6-7 weeks on A+ or A- diet, rhodopsin levels were, as expected, higher in dark-reared rats than in cyclic-light animals. Although the rhodopsin levels in dark-reared vitamin A-adequate rats were significantly higher than in vitamin A-deficient animals, measurements of the lipid to opsin ratio of rod outer segments indicate that the rods of vitamin A-deficient rats are not markedly different than those of vitamin A-adequate rats. It is concluded that these diets may be useful in providing a means for evaluating the role of docosahexaenoic acid in visual cell death from damaging light.

Freeze-fracture study of filipin binding in photoreceptor outer segments and pigment epithelium of dystrophic and normal retinas

We have studied sterol distribution in the retinal pigment epithelial (RPE) microvillous and outer segment disc membranes of rats with inherited retinal degeneration (RCS; RCS-p/+) and of normal genetic controls (RCS-rdy+, RCS-rdy+-p/+) by using the polyene antibiotic filipin, which binds specifically to 3-B-hydroxy-sterols, and freeze-fracture techniques. Retinas were perfusion-fixed, incubated with filipin in the same fixative, and prepared routinely for freeze-fracture electron microscopy. In the normal retina, the distribution of filipin binding sites on both RPE microvillous and outer segment disc membranes changes during development. Prior to outer segment elongation and the onset of phagocytosis (10 days postnatal), filipin sterol complexes are homogeneously distributed in both microvillous and outer segment membranes. With the onset of phagocytosis (2 weeks postnatal and later) filipin binding in both tissues forms a proximal-to-distal gradient, and binding sites decrease as distance from the cell body increases. In the normal RPE microvillous membranes, binding sites are numerous proximally and sparse on the distal tips. In the normal outer segment disc membranes, binding sites are often present on the basal discs, but are sparse on the intact apical discs prior to shedding. As the discs are cast off and engulfed by the RPE, however, filipin binding increases on both disc and phagosome membranes. In the dystrophic retina, the distribution of filipin binding sites differs from the normal. First, in the microvillous membranes, the proximal-to-distal gradient in filipin binding is rarely present at 2 weeks postnatal and becomes prominent only after the buildup of membranous debris has begun (3-5 weeks postnatal). Second, as the photoreceptors degenerate and the membrane debris disappears (4 months postnatal), filipin binding on the microvillous membranes becomes relatively sparse and homogeneous. Third, filipin binding on the intact disc membranes does not change with outer segment elongation, and numerous filipin binding sites are present on both apical and basal outer segment disc membranes. Fourth, large aggregates of filipin binding sites occupy the vast expanses of particle-free areas of debris membranes which accumulate between the photoreceptors and the RPE. These changes in the amount and distribution of filipin binding sites in the dystrophic retina add to the evidence that the disease process involves outer segment as well as RPE membranes and suggest that alterations in cholesterol distribution could contribute to the phagocytic defect.

Isolation of plasma membranes from the bovine retinal pigment epithelium

Retinal pigment epithelium plasma membranes have been isolated by differential and density gradient centrifugation of glass-bead-bound, collagenase-treated cells. Electron microscopic evidence indicates that the glass-bead-bound cells were devoid of red blood cells, rod outer segments and other ocular cell contaminants. The plasma membranes were recovered in 4-6 micrograms/eye yields and purified 10-fold by 5'-nucleotidase and alkaline phosphodiesterase I, and 6.5-fold by (Na+ + K+)-ATPase. Plasma membrane purity as measured by covalent labeling of the epithelial cell plasma membrane proteins with p-(diazonium) benzene[32S]sulfonic acid was 8-19-fold. In purified plasma membranes contamination by mitochondria was undetectable and lysosomal contamination reduced 100-fold, while endoplasmic reticulum was 2-fold enriched. SDS-polyacrylamide gel electrophoresis of the plasma membrane proteins revealed 23-26 major bands by Coomassie blue staining and 12-16 major bands by radioactive labeling. The plasma membranes exhibited a 3-fold lower concentration of docosahexaenoic acid, a 3-fold higher cholesterol/phosphate ratio, and were 10-fold enriched in cholesterol per micrograms protein when compared to the whole cell fraction. Retinal epithelial plasma membranes contain an average of 1 mol cholesterol per mol of lipid phosphorus, a high palmitic acid concentration (39 mol%) and a low concentration of docosahexaenoic acid (2 mol%). The lipid profile of the retinal pigment epithelial plasma membranes indicates that they are typical of plasma membranes from many other cell types and that they appear to be less fluid than total rod outer segment membranes.

alpha-Tocopherol in the developing rat retina: a high pressure liquid chromatographic analysis

High pressure liquid chromatography was used to measure alpha-tocopherol in the retinas of rats reared in a cyclic light or dark environment. These measurements were performed on extracts of whole retinas during the developmental period, 18-60 days, and on isolated ROS from adult animals. Similar alpha-tocopherol determinations were performed on retinas and isolated ROS following exposure of rats to intense visible light for 24 hr periods. The results show that alpha-tocopherol is chromatographically separated from the vitamin A derivatives found in the retina and is pure, as judged by mass spectrometry. In the retinas of cyclic light and dark reared rats, alpha-tocopherol accumulates in an age dependent fashion, so that at 60 days the level is nearly double that of animals at 18-20 days of age (P less than 0.001). Because the age dependent accumulation of rhodopsin is greater in dark reared rats, the average molar ratio of rhodopsin to alpha- tocopherol in the retina of dark reared animals is 25% higher than in cyclic light rats. Following exposure of rats to intense visible light for 24 hr periods, alpha-tocopherol concentrations in the retina were unchanged from the levels in control animals. In adult animals the concentration of alpha-tocopherol in ROS is 2.5-3.5 times higher than in whole retina. ROS from adult cyclic light reared rats also contain an average of 43% more alpha-tocopherol per mg protein than ROS from dark maintained animals (P less than 0.005).(ABSTRACT TRUNCATED AT 250 WORDS)

Intracellular distribution and properties of cathepsin B in the rat retina and its inhibition by a cytosolic fraction

The intracellular distribution and properties of cathepsin B in the rat retina are similar to those of cathepsin B in other mammalian tissues. The specific activity of cathepsin B was highest in the mitochondrial-lysosomal fraction [1650 +/- 450 pmole mg-1 protein hr-1 (mean +/- S.D.)]. Inhibition of cathepsin B activity by a cytosol fraction of retina is also described.