Christopher J. Guérin

Glial fibrillary acidic protein increases in Müller cells after retinal detachment

Retinal detachment, separation of the neural retina from the retinal pigment epithelium (RPE), initiates a series of changes in the eye which result in loss of vision if the retina is not rapidly reattached to the RPE. Many of the complex effects of this separation on the cell biology of the retina have yet to be determined. We report here a change in the amount and location of a specific cytoskeletal protein, glial fibrillary acidic protein (GFAP), within Müller cells after retinal detachment. Cat neural retina and RPE were separated by injecting fluid into the extracellular space between the retina and RPE. Normal retinas and retinas detached for 30 days were fixed and embedded for conventional electron microscopy or immunocytochemistry, or homogenized and processed by SDS-PAGE for immunoblot analysis with anti-GFAP. In normal retinas and in attached retinal regions of eyes with retinal detachment, GFAP was detected only in the end feet of the Müller cells as 10 nm diameter filaments and as a diffuse component over the cytoplasm. By contrast, in regions where the retina was detached from the RPE, GFAP was localized throughout the Müller cells in both of these forms. Immunoblots revealed a significant increase in anti-GFAP labeling of a 51,000 MW band from the detached retina.

Changes in the expression of specific Müller cell proteins during long-term retinal detachment.

Retinal detachments were produced in domestic cats by injecting fluid between the retinal pigment epithelium and neural retina. Retinas were allowed to remain detached for 30 or 60 days at which time the animals were killed. Tissue areas from detached and attached retinal regions from the same eye were processed for correlative biochemical and structural analysis, i.e. SDS-PAGE and Western blots of tissue homogenates were correlated with tissue processed for postembedding immunoelectron microscopy. Antibodies to six proteins were used as probes. Glial fibrillary acidic protein in Müller cells has previously been shown to increase after retinal detachment; here we show that vimentin, another intermediate filament protein present in Müller cells, also increases after detachment. In contrast, cellular retinaldehyde binding protein, cellular retinol binding protein, glutamine synthetase, and carbonic anhydrase C--all normally found in Müller cells--decrease after detachment. The results of this study indicate that retinal Müller cells dramatically alter their expression of proteins in response to retinal detachment.

Rapid changes in the expression of glial cell proteins caused by experimental retinal detachment

We examined the expression of several proteins normally present in Müllers glia after the production of experimental retinal detachment in adult cats. Retinas were detached for one-half to seven days, after which the tissue was processed for correlative immunocytochemistry and biochemistry. Previous studies demonstrated that the intermediate filament proteins glial fibrillary acidic protein and vimentin, increase after long-term retinal detachment (30 to 60 days), whereas glutamine synthetase, carbonic anhydrase C, and cellular retinaldehyde-binding protein all decrease to barely detectable levels. Alterations in Müller cell protein expression are rapid and specific events that can be detected as early as two days after retinal detachment. By seven days, levels of protein expression are similar to those in the long-term retinal detachments. Within the first week after injury the Müller cell processes hypertrophy and begin forming glial scars, which indicates that early intervention may be required to halt or reverse the effects of detachment.

Basic fibroblast growth factor: a potential regulator of proliferation and intermediate filament expression in the retina

Proliferation of astrocytes, and a concomitant increase of intermediate filaments in astrocytes are two fundamental responses of the CNS to injury. We have previously identified these two events in the retinas response to detachment of the neural retina from the adjoining monolayer of retinal pigmented epithelium. In order to analyze the potential role of basic fibroblast growth factor (bFGF) in these responses, we studied cellular proliferation and intermediate filament protein expression in the retinas of cats and rabbits 4 d and 4 weeks after a single intravitreal injection of 1 microgram of bFGF. Our results show that bFGF stimulates both of these processes in an otherwise normal eye. The eyes that received bFGF had significantly elevated numbers of 3H-thymidine-labeled Muller cells, astrocytes, vascular cells, retinal pigmented epithelial cells, microglia, and macrophages by comparison to control eyes. This proliferation was apparent at 4 d after the injection of bFGF but not after 4 weeks. In control eyes, antibodies to glial fibrillary acidic protein and vimentin labeled intermediate filaments only in the inner (vitread) portion of the Muller cells, the specialized radial astrocytes that span the width of the retina. In eyes that had been injected with bFGF, almost the entire Muller cell cytoplasm was labeled at 4 d after injection; after 4 weeks, the cytoplasmic labeling intensity had increased significantly. Release or activation of endogenous stores of bFGF after injury or disease may be involved in the control of cellular proliferation and intermediate filament expression in the retina and elsewhere in the CNS.

Fluorouracil therapy for proliferative vitreoretinopathy after vitrectomy.

Fluorouracil effectively inhibits epiretinal membrane formation and traction retinal detachment after vitrectomy surgery. When 0.5 mg of fluorouracil was administered intraocularly every 24 hours for seven days, traction retinal detachment two weeks after the intraocular injection of 200,000 cultured retinal pigment epithelial cells occurred in 12 of 12 control eyes but in only six of 14 eyes treated with fluorouracil (P less than .001). Four weeks after cell injection, eight of 12 eyes treated with fluorouracil had traction retinal detachments whereas 12 of 12 control eyes did (P less than .001). The height of the traction retinal detachment four weeks after intraocular injection of 200,000 cultured retinal pigment epithelial cells was reduced 50% in eyes treated with 0.5 mg of fluorouracil every 24 hours for seven days compared to control eyes (P less than .001). When the number of injected retinal pigment epithelial cells was increased to 400,000 cells and 1.25 mg of fluorouracil was administered intraocularly every 24 hours for seven days, traction retinal detachment two weeks after injection occurred in 15 of 15 eyes in the control group but in none of ten eyes in the treated group. Four weeks after cell injection, eight of eight eyes in the control group and five of five eyes in the fluorouracil-treated group had detachments and the mean height of the detachments in the two groups was equal. Autoradiography of the epiretinal membranes in eyes injected with 200,000 cultured retinal pigment epithelial cells and labeled for two hours with tritiated thymidine showed that 0.8% of the epiretinal cell nuclei were labeled two weeks after cell injection but that no labeled cells were present in the fluorouracil-treated eyes. Tritiated thymidine labeling of epiretinal cells in the fluorouracil-treated eyes was first noted three weeks after the cell injection. The presence of tritiated thymidine labeling in the fluorouracil-treated eyes correlated with an increase in the number of epiretinal cells and an increase in the incidence of traction retinal detachment.

Ocular Toxicity of Fluorouracil after Vitrectomy

The retinal and corneal toxicity of fluorouracil in the rabbit eye after lensectomy and vitrectomy depended on both the dosage and the frequency of intraocular injection and was reversible at certain dosages. All eyes in Group 1 (1.25 mg of fluorouracil every 12 hours for four days and then every 24 hours for three days) had opaque corneas by three days; these did not clear for four weeks. Histologic studies showed loss of photoreceptor outer segments and loss of ribosomes in all the retinal cells examined. The electroretinographic b-wave decreased to 0% of the baseline value (no b-wave), and did not recover after three weeks. In Group 2 eyes (1.25 mg of fluorouracil every 24 hours for seven days), corneal opacification increased to a maximum after two weeks and gradually decreased by four weeks. The electroretinographic b-wave diminished to 9.6% of the baseline value at two weeks but later recovered to 62.5% of the baseline value at three weeks. Histologic studies showed loss of photoreceptor outer segments and ribosomes at nine days; both returned to near normal after five weeks. Clinical, electrophysiologic, and histologic studies showed no toxicity in Group 3 eyes (0.5 mg of fluorouracil every 24 hours for seven days). This dosage of fluorouracil exerts a significant antiproliferative effect on injected retinal pigment epithelial cells and is well tolerated by the rabbit eye.

Epiretinal Membrane Formation after Vitrectomy

Our experimental model of epiretinal membrane formation in the rabbit eye after lensectomy and vitrectomy provides a way of studying pharmacologic and surgical approaches to inhibiting epiretinal cellular proliferation and contraction in the eye that has undergone vitrectomy. We injected 400,000 tissue-cultured retinal pigment epithelial cells onto the retinal surface of rabbit eyes that had undergone lensectomy, vitrectomy, and fluid-gas exchange. By one week, a funnel-shaped detachment of the medullary rays had occurred in 100% of the injected eyes. Histologically, the cells formed an epiretinal membrane by six hours after injection and caused major wrinkling of the inner retina after 24 to 48 hours. The percentage of tritiated-thymidine-labeled epiretinal cells increased dramatically 24 hours after injection and then declined. Cellular membranes bridging the optic nerve, followed by growth and contraction of the epiretinal cells on the detached internal limiting membrane, were responsible for the closed funnel appearance of the medullary rays.

Tritiated uridine labeling of the retina: Changes after retinal detachment ☆

As part of a study designed to examine the response of photoreceptor cells to outer segment injury (retinal detachment), the pattern of RNA labeling ([3H]uridine incorporation) has been determined in detached cat retinas. Retinas were experimentally detached from the adjacent cellular layer (the retinal pigment epithelium:RPE) by injecting fluid into the extracellular space between the retina and RPE. Twenty-four hours before the animals were killed they received intravitreal injections of [3H]uridine. Autoradiograms were prepared from plastic sections 1.0 micron thick taken from detached retinal regions and, because the detachments do not encompass all of the retina, from nearby attached retinal regions. Twenty-four hours after retinal detachment there is a decrease in labeling intensity of the photoreceptors and Müllers glia in the region of detachment (compared to cells in nearby attached regions). Seventy-two hours after retinal separation, the same result is obtained in the photoreceptors, but labeling intensity is greatly increased in both the nuclei and cytoplasm of Müllers glia. The decrease in [3H]uridine labeling of the photoreceptors correlates with a decreased staining intensity of the cytoplasm and ultrastructural signs of necrosis. The striking change in the pattern and intensity of labeling of the Müller cells precedes extensive hypertrophy of these cells and the appearance within their cytoplasm of numerous 10-nm diameter filaments. Two weeks, and also 1 month, after detachment the pattern and labeling levels are similar to those observed 1 day after retinal separation. These data suggest a highly localized change in metabolism because the change in RNA labeling is restricted to the region of detached retina.

Light and Electron Microscopy of Vertebrate Photoreceptors: Including a Technique for Electron Microscopic Autoradiography

Publisher Summary Light and electron microscopy plays a fundamental role in the development of photoreceptor cell function. This chapter describes the tools necessary to produce high-quality tissue preservation and tissue contrast and how photoreceptors can be studied by those techniques. The chapter also discusses photoreceptor cell structure and illustrates the step-by-step procedures for the preservation of retinal tissue by the standard technique of primary fixation in aldehydes, secondary fixation in osmium tetroxide, and embedment in resin along with the subsequent staining of tissue sections for transmitted light and electron microscopy. A method is also described in the chapter for producing autoradiograms that can be observed by electron microscopy, thus providing a high-resolution technique for the subcellular localization of radiolabeled molecules. The illustrations, derived from mammalian retinas prepared by the procedures described in the chapter, help to clarify the appearance of each anatomical compartment of the photoreceptor cells in tissue generally considered to be “well preserved” for ultrastructural study.

Morphological Recovery in the Reattached Retina

After experimental retinal detachment in the cat, a number of morphological changes take place in retinal and RPE cells. Following reattachment, the ultrastructural relationship between the photoreceptors and the RPE is re-established, but it does not return to the predetachment state even after short detachment episodes coupled with prolonged recovery periods. All of the reattached retinae show some degree of abnormality, ranging from subtle changes in photoreceptor ultrastructure to dramatic degenerative effects in the outer retina. Abrupt transitions in morphology from one reattached area to an adjacent area are not unusual. Photoreceptor recovery varies widely between animals, and between adjacent regions within the same retina. Ensheathment of outer segments by RPE apical processes is abnormal. In some reattached areas rod outer segment dimensions and disc structure are near normal as is the displacement rate of rod outer segment discs. In others, especially in areas of RPE or Müller cell proliferation and hypertrophy, the outer segments are shortened or absent completely, and there is a reduction of cell bodies in the outer nuclear layer. In some retinae, recovery in cones is inferior to that in rods. At short detachment durations (less than 1 wk) morphological recovery in the reattached retina is optimal while at long intervals (greater than 1 month) recovery is poor. The changes at the photoreceptor-RPE interface identified in the reattached cat retina probably have adverse effects on visual recovery when they occur within the human macula.