Development and degeneration of retina in rds mutant mice: ultraimmunohistochemical localization of S-antigen

In the developing photoreceptor cells of the homozygous rds mutant mice S-antigen is localized over the ciliary protrusion as in the control mice, and to a lesser extent over the inner segments, perikaryal cytoplasma and the cell terminals. As the outer segments develop in the normal retina, the discs become increasingly immunoreactive. In the rds/rds retina the outer segments fail to develop but small membrane bound vesicles, immunoreactive for S-antigen are extruded and phagocytized by the retinal pigment epithelium. In the retina of older mutant mice, as the photoreceptor cells degenerate slowly, the surviving cells continue to show persistent immunoreactivity for S-antigen in the different regions of the photoreceptor cells. In the heterozygotes the outer segments are reduced and appear abnormal, but the localization of S-antigen is similar to normal. In the receptor region of the normal retina and in the deviant membranous structures in the mutant retina the localization of S-antigen is similar to that of opsin. However, some differences in the subcellular localization of these two photoreceptor specific proteins have been observed. It is concluded that the rds gene acts subsequent to the synthesis of these proteins and possibly at the site of disc assembly.     

Proteoglycans in the mouse interphotoreceptor matrix. III. Changes during photoreceptor development and degeneration in the rds mutant

The distribution of sulfated proteoglycans in the interphotoreceptor matrix (IPM) was examined during development and degeneration of photoreceptors in the rds mouse with electron microscopy after staining with the cationic dye Cupromeronic Blue (CmB). Three distinct CmB-positive filaments types were observed: type A (45-55 nm long and around 5 nm in diameter), type B (up to 0.5 micron long and 5-10 nm in diameter), and type C filaments (up to 1 micron long and 15-25 nm in diameter. During early postnatal development, before degenerative changes occur in photoreceptors, CmB-positive filaments were virtually identical in morphology and pattern of development as those recently reported for the normal mouse IPM (Tawara, Varner and Hollyfield, 1989, Exp. Eye Res. 48, 815-39). From 10 days to 1 year of age, during the period of progressive degeneration and loss of photoreceptor cells, numerous type B and type C filaments were present in the IPM. Type B filaments were distributed throughout the IPM, whereas type C were predominantly located around the apical termination of photoreceptor inner segments and between the pigment epithelial microvilli. Type A filaments were located principally in the apical cytoplasm of the pigment epithelial cells and in the proximal IPM. In the 20-month-old rds mouse, a time when virtually no photoreceptor cells remain, only minimal CmB staining was evident at the interface between the pigment epithelium and retina. Pretreatment with chondroitinase AC eliminated most CmB-positive filaments from the 18-day-old and 20-month-old mouse IPM. These findings suggest that there are no major differences in structural type or early postnatal development of chondroitin sulfate-type proteoglycans in the IPM between rds and normal mice. Any differences in distribution of chondroitin sulfate-type proteoglycans between rds and normal mice can be accounted for by the absence of photoreceptor outer segments and progressive loss of photoreceptor cells in this mutant. The disappearance of these IPM proteoglycans following photoreceptor degeneration suggests that photoreceptors may be critically involved in the maintenance of these matrix components.     

Development and degeneration of retina in rds mutant mice: light and electron microscopic observations in experimental chimaeras

Mice, homozygous for the rds gene, fail to develop the receptor outer segments and show a slow reduction of the outer nuclear layer. A series of 13 chimaeric mice was produced by combining morulae from albino rds/rds and pigmented normal (+/+) mice. At 3-4 weeks, variable stretches of visual cells without outer segments were observed together with stretches of visual cells with normal outer segments. The location of these areas was unrelated to the genotype of the overlying pigment epithelium. Phagosomes containing outer segment debris were present in albino pigment epithelial cells, located over normal outer segments, indicating normal functional properties of rds/rds pigment epithelial cells. At 9 months, regions with visual cell loss were observed underlying both types of pigment epithelial cells. Regions showing normal and intermediate thicknesses of the outer nuclear layer were seen more often than regions showing rds/rds type distribution. In another series of eight chimaeras, consisting of albino rds/rds and pigmented rd/rd genotypes, the eyes examined at 22 days showed more pronounced visual cell loss than in the rds----normal retinas at 9 months. Regions of the outer nuclear layer, containing a single row of cone perikarya, were similar to the rd/rd phenotype and differed from the phenotype of the double homozygous rd/rd rds/rds retina, which has a slower rate of degeneration than in rd/rd mice. Visual cell loss in these chimaeras at 9 months was similar to that in the rds/rds retina of the same age. The findings show that the expression of the rds gene, resulting in failure of outer segment development and eventual death of visual cells is unrelated to the genotype of the overlying pigment epithelial cells and suggest that the gene acts within the neural retina and possibly intracellularly in the visual cells.     

Development and degeneration of retina in rds mutant mice: ultraimmunohistochemical localization of opsin

In normal retina the developing photoreceptor cells first show presence of opsin over the distal ends of the ciliary protrusions. In a fully differentiated cell intense activity is seen over the rod outer-segment discs; some activity is also seen over the Golgi zone and near the distal ends of the inner segments but the other parts of the receptor cell appear negative. In the pigment epithelium opsin is seen only over phagosomes containing rod outer segment debris. In the homozygous rds mutant retina, developing receptor cells show opsin activity over the ciliary protrusions as in the normal. These ciliary protrusions grow in size and show increased opsin activity and presumably constitute the site of phototransduction in the mutant retina. Although typical disc structures remain lacking, variable amounts of immunopositive, irregular, membranous structures are occasionally observed. The inner segments in the mutant cells show very little immunoreactivity but the perikarya and the spherule terminals show increased immunoreactivity in comparison with the normal. At the onset of degeneration, some of the receptor cells in the mutant retina show extrusion of small, membrane-bound vesicles which are immunopositive for opsin. Some receptor cells undergoing lysis disintegrate and also add to the opsin-positive vesicular structures in the interphotoreceptor space. The vesicles are phagocytized by pigment epithelial cells. In older mutant mice at an advanced stage of degeneration, the receptor cells show reduced opsin activity. In heterozygous mutant mice the outer segments are reduced in length and the discs are abnormal in form. However, the intensity and the pattern of opsin localization in the outer segments and at other sites are similar to normal.     

Localization of an endogenous substrate for cyclic AMP-stimulated protein phosphorylation in retina

Incubation of mouse or rabbit whole retina homogenates in the presence of [gamma 32P]-ATP and Mg2+ leads to the phosphorylation of various proteins, as demonstrated using SDS-polyacrylamide gel electrophoresis and autoradiography. The phosphorylation of one protein (ca. approximately equal to 31000 mol. wt) was increased by cyclic AMP in both species, with half-maximal stimulation at 5 x 10(-7)M. Cyclic GMP was also active, but much less potent. Protein phosphorylation patterns were compared in retina homogenates from normal mice (C57BL/6J), from adult C57BL/6J mice homozygous for the retinal degeneration gene (rd/rd) in which rod photoreceptor cells are absent, and from 21-day-old 020/Cpb mice homozygous for the retinal degeneration slow gene (rds/rds) in which only the outer segments of the rod photoreceptors are missing. The 31 K protein was only present in normal and in 21-day-old rds/rds mice. When rabbit retina was microdissected into outer segment, inner segment plus outer nuclear, and inner retina layers, cyclic AMP-stimulated phosphorylation of the 31 K protein was evident only in the inner segment plus outer nuclear layer. These data indicated the presence of a specific, endogenous substrate for a cAMP-dependent protein kinase which is found in the inner portions of rod photoreceptor cells.     

Specialization of the interphotoreceptor matrices around cone and rod photoreceptor cells in the monkey retina, as revealed by lectin cytochemistry

The binding sites of two lectins, peanut agglutinin (PNA) and wheat germ agglutinin (WGA), in the interphotoreceptor matrix (IPM) and photoreceptor plasma membranes of the Japanese monkey (Macaca fuscata) retina were localized using a pre-embedding staining method with ferritin-conjugated (Fer) lectins as well as a postembedding staining method with fluorescence-labeled (FITC) lectins. FITC-PNA, but not WGA, stained cylindrical domains of the IPM around cone outer and inner segments, while the IPM around rods stained with FITC-WGA but not PNA. When the intact (not detached) retinal tissues were incubated with Fer-lectin, the lectin generally labeled neither the IPM nor photoreceptor plasma membranes, but labeled only those structures in detached portions occurring at the edges of occasional retinal tissue blocks. Thus, the neural retinas physically isolated from the retinal pigment epithelium (RPE) were utilized principally here. Ultrastructurally, the IPM in the intact retina consisted of granular and filamentous materials; the IPM in the isolated neutral retina also retained those components, although somewhat loosely organized, and the IPM around cones appeared to be preserved better than did the IPM around rods. Fer-PNA bound to the IPM associated with cones, but not rods; Fer-WGA bound to the rod- but not cone-associated IPM. The ferritin particles were found to lie close to the granular and filamentous materials. Those photoreceptor-associated IPMs extended to the apical surface of the RPE in detached portions or to the apical villi of the RPE which were frequently found in the isolated neural retinas. Also, Fer-PNA labeled the cone, but not rod, plasma membranes; Fer-WGA bound heavily to the plasma membranes of rod and cone outer segments, but sparsely to those of their inner segments. These results suggest that the IPM comprises chemically and physically differential domains specialized for cone and rod photoreceptor cells, and that these specialized IPM are structurally so stable that may be involved in isolating photoreceptor cells physicochemically from each other and in the interactions between the photoreceptors and the RPE, such as retinal adhesion.     

Uveoretinitis in rabbits following immunization with interphotoreceptor retinoid-binding protein

Interphotoreceptor retinoid-binding protein (IRBP) is a glycoprotein found in the interphotoreceptor matrix between the neurosensory retina and the retinal pigment epithelium and is thought to shuttle retinol among cells that border the interphotoreceptor space. Immunization of rabbits with bovine IRBP caused subsequent photoreceptor degeneration, as documented by light- and electron microscopy. Beginning on post-injection day 18, scattered regions had photoreceptor outer segments that were disorganized and shortened or absent. Macrophages were found between the retinal pigment epithelium and neurosensory retina and within choroidal interstitium and blood vessels. Labeling of these cells with a marker specific for monocytic macrophages (RAM11) and absence of labeling with a marker for retinal pigment epithelium (rabbit anti-bovine cellular retinaldehyde-binding protein) suggest that these macrophages were hematogenous in origin. Staining of retinas with fluorescein isothiocyanate (FITC)-conjugated sheep anti-rabbit IgG revealed leakage of rabbit IgG into the interphotoreceptor matrix on and after day 18 in experimental animals but not in controls, suggesting breakdown of the outer blood-retinal barrier. Indirect immunofluorescence with anti-glial fibrillary acidic protein revealed labeling of Müller cells in experimental retinas on and after day 18, but not in control or shorter survival experimental retinas. There were foci of increased cellularity in the choroid on days 18, 26 and 39. From days 26 through 67, the retinal pathology became more widespread. Varying degrees of outer-segment degeneration were present in all parts of the retina and in many areas there was total loss of outer segments and loss of some photoreceptor-cell bodies. The inner retina appeared unaffected in all experimental and control retinas. These results demonstrate that injection of rabbits with bovine IRBP causes retinal photoreceptor degeneration as anti-IRBP titers increase and breakdown of the outer blood-retinal barrier ensues. Further studies will be required to elucidate factor(s) that control accessibility of the neurosensory retina to circulating antibodies against IRBP and other intrinsic retinal proteins.     

Development and degeneration of retina in rds mutant mice: photoreceptor abnormalities in the heterozygotes

Mice homozygous for the rds (retinal degeneration slow) gene fail to develop receptor outer segments and show a slow loss of visual cells that starts from 14-21 postnatal days and results in complete absence at 1 year. In the heterozygous rds/+ mice the development of receptor outer segments is initially retarded. Although a distinct layer of outer segments of moderate length is formed, the disc structures remain disarrayed and form irregular whorls. Autoradiograms of rds/+ retinas show reduced incorporation of [3H]-leucine. Scleral movement of label, resulting from the addition of newly formed discs, is also retarded and appears irregular in comparison with the normal. Phagosomes, containing newly shed disc structures, within the retinal pigment epithelium of rds/+ mice are much larger than normal. Counts taken at different times of the dark- and light periods have shown an abnormally high turnover of phagosomes in the pigment epithelium of the rds/+ mice, with higher than normal peak frequency near the end of the light period, in contrast with the peak frequency in the normal pigment epithelium recorded around the beginning of the light period. Starting at 2 months, a very slow loss of visual cells, much slower than in the homozygous mutants, progresses throughout life. As a result, the outer nuclear layer at the age of 18 months or more is reduced to less than half. Prior to the reduction of the outer nuclear layer, the relative frequencies of the rod and cone perikarya in the rds/+ retina are similar to the normal values. With loss of visual cells, a small increase in the relative frequency of the cone perikarya is recorded in older rds/+ mice. This increase is more noticeable in the central than in the peripheral retina. The significance of the partial expression of the rds gene in the retina of the heterozygous mice in comparison with the changes observed in the homozygous retina is discussed. It is concluded that dose-dependent variation in phenotypic expression is an essential feature in the working of the rds gene.     

Zonulae adherentes pore size in the external limiting membrane of the rabbit retina

The interphotoreceptor space (IPS) of the retina is bordered by the retinal pigment epithelium, photoreceptors, and Müller cells and surrounds the photoreceptor outer and inner segments. It contains a matrix composed of glycosaminoglycans and proteins, including interphotoreceptor retinol-binding protein (IRBP). The matrix does not diffuse sclerad through the tight junctions that link cells of the pigment epithelium or vitread beyond the point at which photoreceptors and Müller cells are linked by zonulae adherentes that comprise the external limiting membrane (ELM). Biotinylated protein probes of known Stokes' radius were used to determine the pore size of the ELM. Following exposure of the photoreceptor side of isolated rabbit retinas to each protein, the extent of diffusion of the probe through the retina was determined by avidin D-horseradish peroxidase histochemistry. Each protein with a Stokes' radius of 30 A or less diffused freely through the neurosensory retina while each protein with a Stokes' radius greater than 36 A was blocked abruptly at the ELM. Thus, the pore radius of the zonulae adherentes of the ELM lies between 30 and 36 A, which is sufficiently small to account for containment of IRBP (55 A) within the IPS. This study emphasizes that in addition to providing structural support, the zonulae adherentes of the ELM serve to define an important extracellular space of the retina. This has clinical relevance, since two serum proteins tested, albumin and gamma-globulin, are too large to diffuse through an intact ELM. This may explain why protein-rich fluid accumulates in the IPS when the outer blood retinal barrier is compromised by disease or injury.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cyclic nucleotide content and phosphodiesterase activity in the rds mouse (020/A) retina

Cyclic nucleotide metabolism was examined in the retina and in the retinal pigment epithelium (RPE)-choroid complex of the rds mouse (020/A), a mutant in which discrete photoreceptor outer segment disc structures fail to develop. In retinas of both rds and control (Balb/c) mice, cyclic AMP levels peak at 10-15 days (20-25 pmol mg-1 protein). The level drops to about 10 pmol mg-1 at about one month in normal retinas but remains high in affected retinas. Cyclic GMP levels increase five-fold in Balb/c retinas as ROS develop whereas, in affected retinas, the levels remain constant and low (about 5 pmol mg-1). In RPE-choroid, cyclic nucleotide levels are similar in control and affected mice. Cyclic AMP phosphodiesterase (PDE) activity is somewhat higher in affected than in control retinas; conversely, cyclic GMP-PDE is lower. Both cyclic AMP-PDE and cyclic GMP-PDE activities are different in normal and affected RPE-choroid. Thus, although the rds (020/A) mouse belongs to the early-onset photoreceptor dysplasia group of hereditary retinal degenerations on a morphological basis, it does not exhibit high retinal cyclic GMP levels and thus appears to be distinct from other animals exhibiting early postnatal photoreceptor dysfunction.     

Redistribution and reduction of interphotoreceptor retinoid-binding protein during ocular coronavirus infection.

Inoculation of the neurotropic coronavirus mouse hepatitis virus strain JHM intravitreally or into the anterior chamber causes acute infection of the retinal pigment epithelium (RPE) and neural retina. Weeks later, many retinas have foci of moderate to severe atrophy. The effect of coronavirus infection (after intravitreal inoculation) was examined on interphotoreceptor retinoid-binding protein (IRBP), the glycolipoprotein in the interphotoreceptor matrix (IPM) thought to transport retinoids between the photoreceptors and the RPE. Changes in IRBP distribution accompanied virus-associated retinal pathology, including photoreceptor loss and RPE abnormalities. Immunohistochemistry on days 3 and 6 showed that IRBP had diffused into the neural retina away from the IPM. The IRBP became localized abnormally in the same areas as virus-induced lesions, shown by staining adjacent sections with a monoclonal antibody specific for the viral nucleocapsid protein. Moreover, the level of IRBP in isolated retinas, measured in an immunoslot-blot assay, decreased significantly by day 3 and remained low through day 23. This decrease was confirmed in eyecups isolated on day 6. It may be caused in part by loss of photoreceptors and diffusion of IRBP through the retina into the vitreous. These studies show that a virus may induce an acute, limited infection in the retina that can be cleared by the host. However, the infection initiated a series of events resulting in long-term reduction and redistribution of a critical photoreceptor protein.     

Expression of the diabetes risk gene wolframin (WFS1) in the human retina

Wolfram syndrome 1 (WFS1, OMIM 222300), a rare genetic disorder characterized by optic nerve atrophy, deafness, diabetes insipidus and diabetes mellitus, is caused by mutations of WFS1, encoding WFS1/wolframin. Non-syndromic WFS1 variants are associated with the risk of diabetes mellitus due to altered function of wolframin in pancreatic islet cells, expanding the importance of wolframin. This study extends a previous report for the monkey retina, using immunohistochemistry to localize wolframin on cryostat and paraffin sections of human retina. In addition, the human retinal pigment epithelial (RPE) cell line termed ARPE-19 and retinas from both pigmented and albino mice were studied to assess wolframin localization. In the human retina, wolframin was expressed in retinal ganglion cells, optic axons and the proximal optic nerve. Wolframin expression in the human retinal pigment epithelium (RPE) was confirmed with intense cytoplasmic labeling in ARPE-19 cells. Strong labeling of the RPE was also found in the albino mouse retina. Cryostat sections of the mouse retina showed a more extended pattern of wolframin labeling, including the inner nuclear layer (INL) and photoreceptor inner segments, confirming the recent report of Kawano et al. [Kawano, J., Tanizawa, Y., Shinoda, K., 2008. Wolfram syndrome 1 (Wfs1) gene expression in the normal mouse visual system. J. Comp. Neurol. 510, 1-23]. Absence of these cells in the human specimens despite the use of human-specific antibodies to wolframin may be related to delayed fixation. Loss of wolframin function in RGCs and the unmyelinated portion of retinal axons could explain optic nerve atrophy in Wolfram Syndrome 1.     

Intense light exposure changes the crystallin content in retina

Toward a better understanding of light-induced photoreceptor damage, the crystallin content of rat retina was examined following intense light exposure. Nine crystallin species were identified by mass spectrometric analysis of rat retina fractionated by 2D gel electrophoresis. The Coomassie blue staining intensity of all crystallin 2D gel components was 2- to 3-fold greater in light exposed than in control retinas. Following light exposure, anti-alphaB-crystallin immunoreactivity was increased in rod outer segments and retinal pigment epithelium. These findings support a possible role for crystallins in protecting photoreceptors from light damage.     

Degenerative changes in a retina affected with autosomal dominant retinitis pigmentosa

The eyes of a 17-year-old male donor who was affected with autosomal dominant retinitis pigmentosa with variable expressivity have recently become available for study. Initial macroscopic examination of the fundus revealed bone spicules located in 180 degrees of the postequatorial fundus centered on the inferonasal quadrant. Light microscopic examination of the retina showed degeneration within each quadrant characterized by an absence of rods and cones in the equatorial areas, and the presence of photoreceptors in the more peripheral and central retina. Ultrastructural examination disclosed photoreceptors that were abnormal in all regions when compared to a control eye from a 26-year-old donor. Intact rods were restricted to the peripheral quadrants, and intact cones were identified in the fovea and far periphery. In areas of intermediate degeneration, many outer segments were either shortened and disorganized or absent. Regions of severe degeneration were characterized by the complete loss of the photoreceptors and apposition of the external limiting membrane to the retinal pigment epithelium. The density of rods and cones was found to be substantially lower than normal in all regions. In areas of relatively intact photoreceptor outer segments, we found ultrastructural evidence of recent phagocytic activity, and fluorescence microscopy revealed no unusual accumulation of lipofuscin within the pigment epithelium or subepithelial debris. The choroid and inner retina were normal throughout the eye. The normal condition of the choroid, retinal pigment epithelium, and inner retina implies that the primary disorder resides within the photoreceptor cell.     

A developmental study of interphotoreceptor retinoid-binding protein (IRBP) in single and double homozygous rd and rds mutant mouse retinae

Interphotoreceptor retinoid-binding protein (IRBP) was studied using immunochemical and immunocytochemical techniques in retinae of mice with allelic combinations at the rd and rds loci at different stages of development and degeneration. Until postnatal day 7 (P7), IRBP is located intracellularly in developing retinae of the different genotypes. Thereafter, IRBP is present mainly in the interphotoreceptor matrix. As previously noted, cell death is slowest in the heterozygous +/+,rds/+ mutant with loss increasing in order in +/+,rds/rds, rd/rd, rds/rds and rd/rd,+/+ animals. The IRBP content of the total retina also approximates this pattern, with lowest amounts by far in rd/rd, rds/rds and rd/rd,+/+ mutants (after P14). Interestingly though, IRBP loss significantly precedes visual cell loss in the rd/rd,rds/rds retina. In all the mutants, the remaining rod cells in the outer nuclear layer exhibit synthesis of intracellularly located IRBP at late stages of degeneration. In the single homozygous rd/rd,+/+ and the double homozygous rd/rd,rds/rds mutants, IRBP is present intracellularly during the entire degenerative process with somewhat less intracellular IRBP in the rd/rd,rds/rds mutant. Retinae of homozygous +/+,rds/rds and heterozygous +/+,rds/+ animals exhibit a normal distribution pattern of IRBP immunoreactivity until loss of photoreceptor cells becomes pronounced at later stages of the disease. Many of the remaining cells at this time are probably cone elements although they are structurally changed. Double labeling with IRBP and S-antigen demonstrates, in many but not all, the presence of both proteins in the same cell body. Immunocytochemistry clearly demonstrated the presence of IRBP in remaining photoreceptor cells at late stages of the disease. Thus, the biochemically measured loss of IRBP appears to be a complex process neither directly dependent on the loss of photoreceptor outer segments and reduced interphotoreceptor matrix space (e.g. there is a sustained IRBP level in rodless rds mutants) nor simply due to cell death (e.g. in the rd/rd,rds/rds mutant, IRBP loss significantly precedes cell loss). That this IRBP is mainly intracellular, however, may indicate an abnormality in secretion which, combined with other factors, induces a degenerated and less differentiated phenotype.     

Photoreceptor-specific activity of the human interphotoreceptor retinoid-binding protein (IRBP) promoter in transgenic mice.

In order to define the cellular specificity of the interphotoreceptor retinoid-binding protein (IRBP) promoter in the retina, we linked the human IRBP promoter to the beta-galactosidase (lacZ) gene and made five lines of transgenic mice. In three of the five transgenic mouse lines, retinas showed positive staining upon incubation with 5-bromo-4-chloro-3-indolyl-beta-D-galactoside (X-gal). Mice from one line (OVE278B) showed positive X-gal staining throughout the retina except for the most peripheral regions. Interestingly, the staining was heterogeneous throughout the retina. Heavily stained regions were interspersed with lightly stained areas. Mice in two other lines showed highly mosaic X-gal staining patterns. Histological examination demonstrated that staining was confined to photoreceptor cells in all three expressing families. Furthermore, electron microscopy showed that the promoter is active in both rod and cone cells. Our results demonstrate that the human IRBP promoter can be used to obtain photoreceptor-specific gene expression in transgenic mice.     

Dominantly inherited retinitis pigmentosa. Ultrastructure and biochemical analysis

A 66-year-old white man had dominant retinitis pigmentosa. He developed progressive restriction of his visual field, night blindness, pallor of the optic discs, pigmentary retinopathy and posterior subcapsular cataracts. Postmortem examination of the eyes included electron microscopy and biochemical analysis of cyclic nucleotides and interphotoreceptor retinoid-binding protein (IRBP). Except for the fovea and periphery, the retina showed extensive gliosis and neuronal loss with loss of photoreceptor cells. The choriocapillaris was variably occluded in the regions of absent retinal pigment epithelium (RPE). In places, the pigment epithelium invaded the retina to the level of the internal limiting membrane. Biochemical analysis revealed that the interphotoreceptor retinoid-binding protein (IRBP), an important glycoprotein of the interphotoreceptor space, was virtually absent even in retinal areas where photoreceptor cells were still present. Cyclic nucleotide determinations indicated a decrease in the cyclic GMP concentration that reflected the general loss of photoreceptor elements. On the other hand the cyclic AMP levels in all retinal areas tested were abnormally elevated, indicating the possible involvement of this nucleotide in the pathogenesis of the disease.     

Localization of retinoid-binding proteins in developing rat retina

Antibodies to cellular retinol-binding protein (CRBP) and cellular retinal-binding protein (CRALBP) were obtained from rabbits immunized with antigens purified from bovine retina. Antigens were localized on frozen sections of rat retina using indirect FITC immunofluorescence. In the retinal pigment epithelium of rats from postnatal day 1 (the day of birth) to postnatal day 32, specific staining with anti-CRBP was restricted to the cytoplasm; the nuclei were unstained. In the neurosensory retina, Muller cell endfeet were stained with anti-CRBP at all ages examined. No CRBP reactivity was found in the pigment epithelium of the ciliary body at any age examined. On postnatal days 14 and 32, in addition to Muller cell endfeet and radial processes, two fine laminae in the inner plexiform layer were faintly positive for CRBP. Anti-CRALBP stained the cytoplasm of the RPE and Muller cells in the adult rat. In developing rat retina, in addition to Muller cells and the retinal pigment epithelium, the ciliary body pigment epithelium and the outer epithelium of the iris were stained with anti-CRALBP in the first postnatal week. The intensity of staining of the ciliary body pigment epithelium decreased gradually from postnatal day 8 until postnatal day 14, at which point a clear line of demarcation was found between the positively stained retinal pigment epithelium and the adjacent, lightly stained, pigment epithelial cells of the ciliary body.     

Comparison of photoreceptor-specific matrix domains in the cat and monkey retinas

Two lectins, wheat germ agglutinin (WGA) and peanut agglutinin (PNA), were used to compare domains within the interphotoreceptor matrices (IPM) of the cat and monkey, two species where the morphological relationship between the retinal pigment epithelium (RPE) and photoreceptors is distinctly different. In the monkey, PNA labeling was heaviest over the cone outer segments and a discrete region of the interphotoreceptor matrix bordering the cone inner and outer segments--a region which has been termed the cone matrix sheath. Near the apical border of the RPE, the outer margin of the PNA-labeled matrix is surrounded by a circular array of apical microvilli. In the cat retina, PNA labeling was highest over a region of the IPM lying between the outer margin of the cone sheath processes and surrounding rod matrix. In contrast, intracellular labeling of cone inner and outer segments was sparse. The RPE apical processes forming the cone sheath were not labeled. In the monkey retina, WGA preferentially labeled rod outer segments and the region of the IPM around rod inner and outer segments. The cone matrix sheath was not preferentially labeled using this lectin. Rod inner segments and cone inner and outer segments were labeled moderately. In the cat retina, WGA labeling was dense over both rod outer segments and cone outer segments as well as the cone sheath. Rod and cone inner segments, as well as the IPM around both rods and cones, were moderately labeled. These observations suggest that the specialized processes arising from the apical surface of retinal pigment epithelial cells, together with photoreceptor-specific extracellular matrix domains, contribute to the formation of specific microenvironments around rod and cone photoreceptor cells.