Expression of P2Y1, P2Y2, P2Y4, and P2Y6 receptor subtypes in the rat retina

PURPOSE: To elucidate the expression pattern of different types of metabotropic P2Y receptors in the adult rat retina. METHODS: Qualitative RT-PCR was used to investigate the expression profile of different P2Y receptor subtypes (P2Y1, P2Y2, P2Y4, and P2Y6), and in situ hybridization studies were performed to show their cellular localization within the retina. Immunohistochemical staining was used to detect the corresponding P2Y proteins (P2Y1, P2Y2, and P2Y4) and their cellular localization. Southern blot analysis and sequencing verified the identity of the P2Y PCR products. RESULTS: RT-PCR revealed the presence of P2Y1, -2, -4, and -6 mRNA in the neural retina and the retinal pigment epithelium (RPE) and choroid. In situ hybridization showed labeling in the retinal ganglion cell layer for all four P2Y receptor subtypes, although the intensity varied. In addition, staining for P2Y1, -4, and -6 mRNA was shown in the inner nuclear layer, but was absent for the P2Y2 receptor subtype. Immunohistochemistry showed intense staining for P2Y1, -2, and -4 in the ganglion cell layer and the outer plexiform layer. There was also a specific subtype staining in the inner plexiform layer (P2Y2, -4), the inner (P2Y1, -4) and outer (P2Y1) nuclear layers and the inner segments of the photoreceptors (P2Y1, -2). discussion. The data suggest that extracellular nucleotides may play complex roles as autocrine-paracrine mediators and may have neuromodulatory effects in the retina through metabotropic P2Y receptors.     

Expression of the sodium-coupled monocarboxylate transporters SMCT1 (SLC5A8) and SMCT2 (SLC5A12) in retina

PURPOSE: Monocarboxylates are primary energy substrates in the retina. Recently, the authors identified two sodium-coupled monocarboxylate transporters (SMCTs), SMCT1 (a high-affinity transporter) and SMCT2 (a low-affinity transporter). Expression of SMCT1 and SMCT2 has been studied in several tissues; however, little is known about their expression in retina. In the present study, the authors asked whether SMCT1 and SMCT2 are also expressed in retina and, if so, in which particular retinal cell types. METHODS: SMCT1 and SMCT2 expression was analyzed in intact mouse retina and cultured retinal cells (ganglion, Müller, RPE) by RT-PCR, in situ hybridization, and immunofluorescence. Uptake assays were performed to demonstrate SMCT1 (RGC-5 and ARPE-19 cells) and SMCT2 (rMC-1 cells) expression at the functional level. RESULTS: SMCT1 mRNA and protein were detected in the ganglion cell layer, inner nuclear layer, inner/outer plexiform layers, photoreceptor inner segments, and RPE. In RPE, the expression of SMCT1 was restricted to the basolateral membrane. SMCT2 mRNA and protein were detected only in neural retina, with a pattern of protein localization consistent with labeling of Müller cells. In vitro studies confirmed the cell type-specific expression of SMCT1 and SMCT2. Uptake assays demonstrated Na(+)-coupled monocarboxylate transport in RGC-5, ARPE-19, and rMC-1 cells. CONCLUSIONS: These data provide the first evidence for the expression of SMCT1 and SMCT2 in the retina and for the cell-type specific distribution of these transporters within the retina. These studies suggest that SMCT1 and SMCT2 play a differential role in monocarboxylate transport in the retina in a cell type-specific manner.     

Neural cell adhesion molecule (NCAM) in adult vertebrate retinas: tissue localization and evidence against its role in retina-pigment epithelium adhesion

The presence of neural cell adhesion molecule (NCAM) was examined in the neural retina, interphotoreceptor matrix (IPM), and retinal pigment epithelium (RPE) of adult bovine and frog eyes. Using polyclonal antibodies raised against adult isoforms of NCAM. Western blot analyses revealed the presence of NCAM in the neural retina, but not in the IPM or RPE of these species. As a control, Western blot analysis was used to demonstrate the presence of interphotoreceptor retinoid-binding protein (IRBP) in the IPM preparations. NCAM immunoreactivity was detected by light microscopic immunocytochemistry primarily in the plexiform layers and nerve fibre layer of the frog retina. Minor immunoreactivity was also detected in the inner and outer nuclear layers, but there was no detectable NCAM immunoreactivity in the IPM, outer segments, or RPE. These results indicate that NCAM is not a likely participant in the process of retina-RPE adhesion in the adult eye.     

Osteonectin/SPARC secreted by RPE and localized to the outer plexiform layer of the monkey retina

PURPOSE: Osteonectin/SPARC is a secreted protein that has been implicated in ocular disease. Deletion of osteonectin/SPARC causes age-onset cataract in mice and the cataractous human lens has increased expression of osteonectin/SPARC. In this study, the expression and localization of osteonectin/SPARC in the monkey retina were determined as was secretion by cultured human retinal pigment epithelial (RPE) cells. METHODS: Adult Rhesus monkey eyes (Macaca mulatta) were dissected, and 5-mm macula and peripheral retina punches were obtained. Supernatants were collected from cultured human RPE cells. Subcellular fractionation of whole monkey retina was also performed. Osteonectin/SPARC expression and/or secretion was monitored by Northern and Western blot analyses, and localization was determined by immunocytochemistry. RESULTS: Outside of the retina osteonectin/SPARC mRNA is broadly expressed in many human tissues. Northern blot analysis shows that in the retina osteonectin/SPARC is expressed almost exclusively by the macular RPE/choroid. Western blot analysis revealed osteonectin/SPARC in both the macula and the peripheral neural retina but only in trace amounts in the RPE/choroid. In subcellular fractions of the whole retina, osteonectin/SPARC was detected, mainly in the soluble fraction but also in the membrane and nuclear fractions. Immunohistochemical analysis localized osteonectin/SPARC specifically to the outer plexiform layer. Western blot analysis of conditioned medium from human RPE cells cultured on porous substrates indicated that osteonectin/SPARC is secreted in large amounts from both the apical and basal sides of the RPE. CONCLUSIONS: Collectively these data provide evidence that osteonectin/SPARC is synthesized in the macular RPE, secreted, and subsequently transported to the outer plexiform layer. The expression pattern of osteonectin/SPARC in the subcellular retinal fractions is consistent with a soluble protein that is transported and internalized.     

Expression and cellular localization of prolactin and the prolactin receptor in mammalian retina

Prolactin (PRL), originally associated with milk secretion, is known to have a wide variety of biological actions and diverse sites of production beyond the pituitary gland. Recent studies have demonstrated that PRL is synthesized in retinal tissue. To gain insights into the functional role of PRL in the mammalian retina, we mapped the distribution of the PRL protein and the expression and localization of the PRL receptor (PRLR) in the retina of adult rats and green monkeys. PRL was examined in retinal sections by double immunolabeling combining anti-PRL antibodies with antibodies specific for glutamine synthetase (labeling Müller cells), glial fibrillary acidic protein (labeling astrocytes), or neuronal nuclei protein (labeling neurons). PRL was detected throughout the rat retina: in the photoreceptor outer segments, Müller cells, interneurons, ganglion cells, and astrocytes. The PRLR was examined by RT-PCR, in situ hybridization, immunohistochemistry, and Western blot. The long isoform of the PRLR was localized in the photoreceptor nuclear layer, inner nuclear layer, and ganglion cell layer of rat retina. The monkey retina showed a similar distribution of PRL and PRLR immunoreactivities. These findings suggest that PRL functions as a local regulator of various cell types in the mammalian retina.     

A comparative study of distribution of 70 kD stress protein in the retina between the normal and retinal dystrophic rat]

The immunolocalization of 70 kD stress protein (SP70) was investigated in the retinal tissues of normal Sprague-Dawley (SD) rat and that of the Royal College of Surgeons (RCS) rat with inherited retinal dystrophy. From postnatal day 2 to 15, SP70 was present in the maturing retinal tissues of both rat strains. In the RCS rat retina of postnatal day 22, at the onset of retinal degeneration, SP70 was expressed in the retinal pigment epithelium (RPE). At postnatal day 40, immunostaining for SP70 was considerably reduced in the degenerating RCS retina. In the RCS retina at postnatal day 90, immunostaining for SP70 was completely lost except for the ganglion cells and the inner plexiform layers. These results suggested that, at the onset of retinal degeneration, the RCS retina may have a state of metabolic stress, which induced SP70 expression in the RPE. At the end stage of retinal degeneration, the immunostaining for SP70 was lost, suggesting the lack of production of SP70 in the degenerated retinal tissue.     

Changes in mRNA levels of the Myoc/Tigr gene in the rat eye after experimental elevation of intraocular pressure or optic nerve transection.

PURPOSE: To isolate the rat Myoc/Tigr gene and investigate changes in its expression pattern in normal eyes and in eyes with either pressure-induced optic nerve damage or optic nerve transection. METHODS: Expression pattern of the rat Myoc/Tigr gene was investigated by Northern blot hybridization. Optic nerve damage and death of ganglion cells in the retina were induced unilaterally, by injection of hypertonic saline solution, episcleral vein cauterization, or optic nerve transection. The levels of mRNA for Myoc/Tigr were compared between several tissues of the control and surgically altered eyes, by using semiquantitative RT-PCR, real-time PCR, and Northern blot analysis. RESULTS: The rat Myoc/Tigr gene is 10 kb long and contains three exons. Among the eye tissues analyzed, Myoc/Tigr mRNA was detected in the combined tissues of the eye angle, sclera, cornea, retina, and optic nerve head. With pressure-induced optic nerve degeneration, the level of Myoc/Tigr mRNA decreased in the retina and the combined tissues of the eye angle, but increased in the optic nerve head. After optic nerve transection, the level of Myoc/Tigr mRNA increased in the retina, but did not change in the combined tissues of the eye angle. CONCLUSIONS: The decreased level of Myoc/Tigr mRNA in the retina after induction of elevated intraocular pressure compared with that in the control retina cannot be explained by ganglion cell death alone. Differences in Myoc/Tigr mRNA levels in eye tissues after elevation of intraocular pressure or optic nerve transection may reflect the activation of different signaling pathways involved in regulation of this gene.     

Distribution and expression of RhoA in rat retina after optic nerve injury

BACKGROUND: RhoA is a small guanosine triphosphatase which participates in signaling pathways of axonal repellents or inhibitors. However, the distribution and expression of RhoA in the rat retina after optic nerve injury has not been elucidated yet. OBJECTIVES: To study the distribution and expression of RhoA in the rat retina after optic nerve injury. METHODS: Immunohistochemistry was used to determine the distribution of RhoA in rat retina after optic nerve injury. The expression of RhoA was analyzed by Western blot. RESULTS: In normal retina and the retina 1 day after optic nerve injury, RhoA was distributed in the retinal ganglion cell (RGC) layer. Three days after optic nerve injury, it existed in RGCs and the inner plexiform layer. However, 7 days after surgery its immunoreactivity was abundant not only in the RGC and inner plexiform layers but also in the inner nuclear and outer plexiform layers. Western blot analysis showed that the expression of RhoA increased significantly in the retina after optic nerve injury in comparison with normal retina. CONCLUSION: These results indicate that the distribution and expression of RhoA were extended and enhanced after optic nerve injury, and that RhoA plays an important role in optic nerve regeneration.     

Glutathione peroxidase induced in rat retinas to counteract photic injury

PURPOSE: To examine the hypothesis that glutathione peroxidase (GPX) is induced at different time points after retinal exposure to light and localizes in different retinal cells. METHODS: The rats were kept in cyclic light for 2 weeks before the experiments. The animals were maintained in 12-hour light-dark cycles, before and after exposure to intense white fluorescent light, for as long as 24 hours and then returned to cyclic light. Expression of GPX was measured by immunohistocytochemistry and Western and Northern blot analyses. Light-induced retinal damage was determined by the thickness of the outer nuclear layer (ONL) thickness in relation to total retinal thickness. RESULTS: GPX labeling did not appear in the photoreceptor inner segments, and slight labeling was observed in the photoreceptor outer segments or the retinal pigment epithelial (RPE) cells in the normal retina kept in cyclic light. In retinal specimens maintained in light for 12 and 24 hours, GPX labeling was induced in the photoreceptor outer segments and RPE cells. High expression of GPX in the RPE was sustained until day 7 after challenge. In contrast, GPX expression in the photoreceptor outer segments decreased on day 1 and disappeared on days 3 and 7 after exposure. Intense GPX labeling was seen from the internal limiting membrane to the ganglion cell layer. GPX labeling was constantly localized in both high-intensity white light and cyclic conditions, suggesting no induction of GPX in those areas. In addition, GPX labeling was apparent at the posterior retinal pole but not at the peripheral retina. We observed marked upregulation of GPX mRNA in rats kept in high-intensity white light. One, 3, and 7 days after exposure to high-intensity white light, there was a significant difference (P < 0.0001) between the control and experimental groups in the ratio of the outer nuclear layer thickness to the entire retina. CONCLUSIONS: GPX was induced at different time points after exposure to high-intensity white light and localized in different retinal cells. Changes in expression of GPX after exposure to light may be related to the difference in susceptibility of the retina to damage by light.