Organization and development of horizontal cells in the goldfish retina, II: Use of monoclonal antibody MH1.

We have produced and characterized a monoclonal antibody, MH1, which selectively labels rod horizontal cells and Müller cells in the goldfish retina. Biochemical and tissue distribution studies indicate that MH1 may recognize four out of five classes of intermediate filament proteins in goldfish: vimentin, desmin, glial fibrillary acidic protein (GFAP), and keratin, but not neurofilament. The intermediate filament which is labeled strongest in the retina is vimentin. In the goldfish retina, the only type of horizontal cells recognized by MH1 appear to be rod horizontal cells. This result suggests that the rod horizontal cell, an interneuron, and Müller (glial) cells share a common antigen: vimentin, which is usually only expressed in mesenchymal origin cells. The development of rod horizontal cells in the goldfish retina was also studied using MH1. The cells were not labeled by MH1 until 4-6 weeks posthatching, a stage in which the animals are already visually active. MH1 also did not label any horizontal cell in the region close to the ora terminalis in the goldfish retina. These results suggest that either the emergence and maturation of rod horizontal cells occur late during goldfish retinal development or the expression of vimentin itself occurs late in the development of rod horizontal cells.     

Immunocytochemical identification of Müller's glia as a component of human epiretinal membranes

Sections of seven human epiretinal membranes of diverse pathologic origin were labeled with antibodies to cellular retinaldehyde binding protein (CRALBP) and two intermediate filament proteins: glial fibrillary acidic protein (GFAP) and vimentin. All of the membranes studied contained heterogeneous cell populations that exhibited diverse morphologic characteristics. Double labeling with both anti-GFAP and anti-CRALBP positively identified one of the cellular components in these membranes as Müller's glia. In addition, other epiretinal cells exhibited immunolabeling patterns consistent with those found in fibrous astrocytes and retinal pigment epithelial (RPE) cells normally. The results demonstrate that a double-labeling method using CRALBP antibodies, in combination with antibodies to other appropriate antigens, can be used to distinguish between the different epiretinal cell types.     

Ultrastructural and immunocytochemical changes in retinal pigment epithelium, retinal glia, and fibroblasts in vitreous culture.

Retinal pigment epithelial (RPE) cells, retinal glial, and fibroblasts, three cell types believed to play a role in the pathogenesis of epiretinal membrane formation, were maintained in vitreous culture to determine the influence of vitreous on their ultrastructure and expression of cytokeratin, glial fibrillary acidic protein (GFAP), vimentin, and glutamine synthetase (GS). Using a highly sensitive, preembedding technique for the immunolocalization of these antigens at the ultrastructural level, most RPE cells were found to lose cytokeratin and vimentin within 1 day after seeding on irradiated vitreous. The percentage of keratin-positive cells then increased with time in culture. If the vitreous was placed on RPE cells cultured in monolayer instead of placing the cells on the vitreous, keratin and vimentin were expressed these intermediate filament proteins diminished with time. Glutamine synthetase was found in RPE cells grown in monolayer with or without a vitreous overlay, but not in RPE cells grown on the surface of vitreous. Retinal glial grown on vitreous showed a time-dependent decrease in the number of cells expressing GFAP and a corresponding increase in cells expressing vimentin or GS. Some fibroblasts in vitreous culture expressed vimentin but not the other antigens evaluated. A substantial number of cells in each culture did not stain positively for cytokeratin, GFAP, vimentin, or GS. All three cell types showed phenotypic diversity at the ultrastructural level with each cell type being capable of assuming the same morphologic appearance under certain conditions. These results demonstrate the phenotypic plasticity of RPE cells, retinal glia, and fibroblasts when grown in contact with vitreous and provide further evidence that neither ultrastructure, intermediate filament protein expression, nor the presence of GS is sufficient to determine the cell type of origin of cells in epiretinal membranes.     

Müller cells express the neuronal progenitor cell marker nestin in both differentiated and undifferentiated human foetal retina

Tritiated thymidine studies suggest that Müller cells are the last cells born in the retina, although several authors describe Müller cells throughout the retina from very early ages. In this study immunohistochemistry was used to identify progenitor and Müller cells in human foetal retina. Antibodies to nestin (an intermediate filament protein expressed by neural progenitor cells), vimentin, cellular retinaldehyde binding protein (CRALBP) and glutamate and aspartate transporter (GLAST), which are each expressed by Müller cells, were used in combination with anti-Ki67 to identify proliferating cells. By definition, Ki67-positive proliferating cells were present in undifferentiated retina, but not in differentiated retina. Nestin-immunoreactive (IR) cells colocalized with vimentin throughout the retina. CRALBP-IR was detected in differentiated retina and in some proliferating cells. GLAST-IR cells were present only within the differentiated region. Nestin, vimentin and CRALBP each colocalized with mitotic Ki67-IR cells, suggesting that in foetal retina Müller cells and retinal progenitor cells are overlapping populations and that Müller cells are end-stage progenitor cells.     

Immunocytochemical characteristics of Müller cells cultured from adult rabbit retina

The antigenic expression of glial fibrillary acidic protein (GFAP), vimentin, S-100 protein and neurofilament triplex polypeptide was examined in cultured glial (Müller) cells from adult rabbit retina using immunocytochemical techniques. Most of the cultured cells were labelled with carbonic anhydrase C which has been considered to be the most specific marker of Müller cells. Most of the cultured cells were also positive for GFAP, a result which differs from previous observations on whole retina. Using a double labelling technique, 70-90% of cultured cells showed positive labelling for GFAP and vimentin although the staining intensity was stronger in the case of the latter. Fifty to seventy percent of cultured cells showed positive immunofluorescence to S-100 protein. Immunoelectron microscopy confirmed that GFAP and vimentin were localised along the intermediate glial filaments. S-100 protein was present in both the cytoplasm and the nucleoplasm of the majority of cells, but surprisingly in approximately 30% of cells the nucleoplasm was not labelled, a result which again is different from previously reported studies on whole retina. Neurofilament triplex polypeptide was not identified either by immunofluorescence or by immunoelectron microscopy. The results indicate that Müller cells in culture show a different antigenic expression to similar cells in whole retina.     

Nestin positive cells in adult human retina and in epiretinal membranes

BACKGROUND/AIM: Nestin is an intermediate filament marker for neural progenitor cells. The authors aimed to identify nestin positive cells in adult human retina and within surgically removed epiretinal membranes. METHODS: Adult human retina and epiretinal membranes were studied. Tissue was fixed and processed for semithin sections or whole mount preparations for immunohistochemical detection of nestin and glial fibrillary acidic protein (GFAP) expression. RESULTS: Nestin positive cells are most prominent at the ora serrata, possess fibrillary processes, small amounts of perinuclear cytoplasm, and are arranged radially within or superficially on the retina. In the posterior retina, speckled cytoplasmic nestin staining is seen around the nuclei of neurons. In the peripapillary retina most of the cells in the retinal ganglion cell layer are nestin positive. These cells appear to represent nestin positive neurons. Speckled cells are also seen in the myelinated portion of the optic nerve. In epiretinal membranes patches of elongated nestin positive cells were found. These cells were also positive for GFAP. CONCLUSIONS: Some neurons and glia in the adult human retina are nestin positive. Their pattern in anterior retina suggests an analogy with the ciliary marginal zone found in many other species. The role of these cells in pathological responses to retinal disease is suggested by the presence of large numbers of ectopic nestin positive cells in epiretinal membranes. The authors hypothesise that nestin positive cells represent a population of progenitor cells from normal adult human retina that differentiate to make up retinal scar tissue.     

Intermediate filaments and their organization in human corneal endothelium

The native intermediate filament network within human corneal endothelium was identified by a monoclonal antibody to vimentin intermediate filament protein. Human corneal endothelial cells in tissue culture were shown to react positively to this monoclonal antibody by indirect immunofluorescence microscopy. In cryostat sections of human cornea, only the endothelial cells and keratocytes stained for vimentin. Fluorescent staining patterns of the cultured endothelial cells demonstrated that vimentin forms arrays of cytoplasmic filaments which encapsulate the nucleus and anchor in the apical junctions. These results reveal a previously undescribed cytoskeleton in human corneal endothelium and suggest that the intermediate filament vimentin comprises this structural network which is, in part, responsible for nuclear centration and cell-to-cell contacts. In addition, these results may indicate the possible embryogenesis of the corneal endothelium, since vimentin is a marker for cells of mesenchymal origin.     

Retinoblastoma. Immunohistochemistry and cell differentiation

Tumor from eight enucleated eyes was analyzed by immunohistochemistry, using a panel of specific antibodies including interphotoreceptor retinoid-binding protein (IRBP), S-antigen (S-Ag), opsin, neuron-specific enolase (NSE), glial fibrillary acidic protein (GFAP), laminin, and vimentin. In addition, immunoelectron microscopy and enzyme-linked immunosorbent assay (ELISA) for IRBP were performed. Immunohistochemical staining disclosed the most pronounced labeling of tumor cells with NSE and IRBP antibodies. A correlation was found between the degree of tumor differentiation and amount of IRBP, a protein specifically synthesized by photoreceptor cells. Moderate labeling of the better differentiated tumors was also observed with antibodies against S-Ag and focal labeling in a few tumors with opsin antibodies. Anti-GFAP labeling was limited to a smaller number of reactive glial cells and perivascular glial cells. These data indicate the essential neuronal nature of retinoblastoma tumor cells in situ as well as at least partial photoreceptor-like features, as shown by the presence of recognized photoreceptor cell markers (IRBP, S-Ag, opsin). Tissue culture studies using the human Y-79 retinoblastoma cell line also demonstrate that the tumor cells are primitive multipotential retinoblasts capable of at least partial differentiation along neuronal, glial, or pigment epithelial cell lines.     

Intraretinal immunohistochemistry findings in proliferative vitreoretinopathy with retinal shortening

To report the major intraretinal pathological changes in retinas with proliferative vitreoretinopathy (PVR) and retinal shortening, 13 human retinal samples from postoperative PVR after primary surgery for retinal detachment were immunostained for vimentin, glial fibrillary acidic protein (GFAP), cytokeratins, and CD68. One more sample was studied with electron microscopy. Retinal disorganization, neuronal loss, and gliosis were observed in 12 out of 13 samples, but all 13 were positive for GFAP. Muller cell processes showed different degrees of intermediate filament hyperplasia. CD68-positive cells were present in 11 of 13 retinal samples. Conclusion: A gliotic response plays a major role in retinal shortening in PVR. In addition, the presence of macrophage-like cells in retinal tissues suggests a possible role of these cells in the pathogenesis of this variety of PVR.     

Müller cells in detached human retina express glial fibrillary acidic protein and vimentin

We investigated the expression of vimentin and glial fibrillary acidic protein (GFAP) within Müller cells in normal human retinas and in detached human retinas of proliferative vitreoretinopathy (PVR) cases using the immunogold method. Muller cells in normal retinas showed vimentin immunoreactivity and faint GFAP immunoreactivity; however, in detached retinas they showed distinct GFAP immunoreactivity as well as vimentin immunoreactivity. Immunoelectron microscopic observation revealed that intermediate filaments (IF) within Müller cells in normal retinas showed vimentin immunoreactivity and that those within Müller cells in detached retinas showed both vimentin and GFAP immunoreactivity. Double staining for vimentin and GFAP showed that in detached retinas, these two protein immunoreactivities were observed in the same filaments. These results indicate that IF of human Müller cells consist of vimentin under normal conditions and that Müller cells in detached retinas contain different IF, which consist of vimentin and GFAP.Supported by Grant-in-aids for Scientific Research A-61440075 and C-62570798 from the Ministry of Education, Science and Culture of the Japanese government     

Epithelial-mesenchymal transition in proliferative vitreoretinopathy: intermediate filament protein expression in retinal pigment epithelial cells.

PURPOSE: To improve our understanding of how retinal pigment epithelial (RPE) cells behave in vivo and to establish similarities with dedifferentiation and adaptive events observed in RPE cells cultured under simulated intraocular pathologic conditions. At the same time, to examine the origin of epithelioid-shaped and fibroblast/fusiform-shaped cells in epiretinal membranes (ERM) from proliferative vitreoretinopathy (PVR). METHODS: Cells of ERM were studied by electron-immunocytochemical techniques, using simple, double, and triple immunostaining for cytokeratins (CK), vimentin (Vim), and glial fibrillary acidic protein (GFAP). Ultrastructural morphology analysis was also carried out. Adult human RPE cells were obtained and cultured with normal and pathologic vitreous from proliferative vitreoretinal disorders, subretinal fluid aspirates from retinal detachment, and normal human serum. Their cytoskeleton was fractionated at 7 (early cultures) and 24 (late cultures) days of culture, electrophoresed, immunoblotted for intermediate filament proteins, and quantified by densitometric analysis for each condition. Changes in phenotype characteristics were also evaluated. RESULTS: Epithelioid-shaped and fibroblast/fusiform-shaped cells, resembling RPE cells, expressed CK-Vim-GFAP simultaneously as intermediate filament proteins in their cytoskeleton. RPE cells in culture also expressed CK-Vim-GFAP and changed from an epithelial shape to a migratory fibroblast/fusiform-shaped phenotype in the presence of subretinal fluid aspirates and pathologic vitreous from proliferative intraocular disorders. In simulated cultures of proliferative intraocular disorders, cells decreased or retained their CK7, CK8, and CK18, retained Vim, and increased CK19 and GFAP, while their mesenchymal morphology became clearer over time. CONCLUSIONS: Studies of intermediate filament proteins in vivo suggest that dedifferentiation occurs in RPE cells in ERM. Dedifferentiated RPE cells may be responsible for epithelioid-like and fibroblast/fusiform-like cells. Furthermore, changes in intermediate filament protein levels were observed in RPE cells in simulated cultures of proliferative intraocular disorders. These changes were linked to cells acquiring a mesenchymal migratory, phenotype. Results indicate that the dedifferentiation of RPE cells occurs both in vivo and in vitro and that it can be explained as an epithelial-mesenchymal transition.     

Changes in intermediate filament immunolabeling occur in response to retinal detachment and reattachment in primates

The immunolabeling patterns for vimentin and glial fibrillary acidic protein (GFAP) were studied in five rhesus monkeys that had undergone retinal detachment or detachment and reattachment. Anti-vimentin and anti-GFAP labeling intensity increased in Müller cells after 2 days of detachment. Weak anti-vimentin labeling of the basal RPE cytoplasm, which was absent in control tissue, was detected 2 days after detachment. After detachment for 7 days and reattachment for 7 or 14 days, the pattern and extent of intermediate filament (IF) labeling changed. In Müller cells, the labeling, which in controls was restricted to processes near the vitreal border of the retina, was present in Müller processes spanning the entire retina. In retinal pigment epithelium (RPE) cells, prominent anti-vimentin labeling was identified in the basal and basolateral cytoplasm. The extent of RPE and Müller cell IF labeling in two animals whose retinas had been detached and then reattached for 150 days was different from that found at either the 7- or 14-day reattachment time points. This suggests that the abnormal IF distribution triggered by detachment may be attenuated after a lengthy period of reattachment.     

The efficacy of delayed oxygen therapy in the treatment of experimental retinal detachment

PURPOSE: To evaluate the ability of delayed hyperoxia to slow or prevent degenerative and gliotic changes initiated by retinal detachment. DESIGN: An experimental study. METHODS: Rhegmatogenous detachments were produced in the right eyes of eight cats. After 1 day in room air (21% O(2)), four cats were placed in chambers with the O(2) concentration regulated at 70%; the other four were left in room air. At 7 days the retinas were harvested and examined by light and confocal microscopy. Cell specific antibodies, TUNEL and proliferation assays, outer segment length, and photoreceptor counts, were used to assess the condition of the retina. The contralateral unoperated eyes were used as controls. RESULTS: Animals maintained in elevated O(2) showed a dramatic preservation of rod and cone outer segments as well as in the organization of the outer plexiform layer. The number of surviving photoreceptors was increased in the hyperoxia-treated animals. Neurite sprouting, a characteristic of detached retina, was rarely observed in the experimental eyes. Proliferation of non-neuronal cells was reduced, but not halted, by hyperoxia. GFAP and vimentin expression was not effected by hyperoxia; these intermediate filament proteins increased in Müller cells similar to that observed in control detachments. CONCLUSIONS: Exposure to hyperoxia, delayed by 1 day after the onset of retinal detachment, was highly effective in preserving photoreceptor cells and in reducing proliferation within the retina. It did not, however, reduce the hypertrophy of Müller glia. There were no apparent detrimental effects of exposure to 70% O(2) for 6 days. These results suggest that human patients may benefit from breathing elevated oxygen levels while awaiting reattachment surgery, even if the hyperoxia is delayed relative to the time of detachment.     

Distribution of S-100 protein and glial fibrillary acidic protein in normal and gliotic human retina

Monoclonal antibodies and polyclonal antisera were used to examine the distribution of S-100 protein in human retinas both immunohistochemically and immunochemically and to compare it to that of glial fibrillary acidic protein (GFAP). S-100 was not found in normal retinas nor in retinas with areas of reactive gliosis. GFAP was found in perikarya and processes of cells the nuclei of which were in the nerve fiber layer of normal retina. In areas of reactive gliosis there was intense staining with antiserum against GFAP extending from the internal limiting membrane to the external limiting membrane. Some of the glial cells in human retina and fibrillary astrocytes in the brain are identical in their expression of GFAP. However, absence of S-100 from both quiescent and reactive retinoglia distinguishes them from astrocytes in brain and spinal cord.     

Development and role of retinal glia in regeneration of ganglion cells following retinal injury.

AIMS/BACKGROUND: Recent observations have shown that the glial scar resulting from a surgical lesion of the immature retina differs from elsewhere in the central nervous system, in that it permits the through growth and reconnection of regenerating axons. This study in the opossum examines in detail the development and reaction to injury of retinal glia at different developmental stages, and specifically examines the distribution of the gliosis related inhibitory molecule, chondroitin sulphate proteoglycan (CSPG), making comparisons with a control site of gliosis in the cerebral cortex. METHODS: A linear slit was cut into the retina or cortex with a fine tungsten probe. After a variable time delay, immunocytochemistry of the resulting gliosis was employed to detect astrocytes with glial fibrillary acidic protein (GFAP), Müller cells with vimentin, and CSPG with CS-56 antibodies. GFAP was also used at different ages to examine the normal development of astrocytes in the retina of this species. RESULTS: Astrocytes entered the retina 12 days after birth (P12), closely associated with blood vessels in the nerve fibre layer. In experiments at all ages studied, cellular continuity was re-established across the lesioned retina, which did not result in a significant astrocyte proliferation or CSPG expression. In contrast, cortical injury led to the development of a cystic cavity surrounded by astrocytes and CSPG. Müller cells expressed GFAP but not CSPG in the lesioned retina. CONCLUSION: Successful regrowth of ganglion cells through a retinal lesion may be partly the result of the scarcity of astrocytes in the retina, which results in minimal gliosis, or of their apparent inability to express inhibitory molecules.     

Simultaneous expression of keratin and glial fibrillary acidic protein by the same cells in epiretinal membranes.

The identification of cells comprising epiretinal membranes is difficult because of the phenotypic changes that occur. Examination of intermediate filament protein content by immunocytochemical analysis can help to identify some cells with altered ultrastructure but is not always definitive because altered expression of intermediate filament proteins can also occur. To examine this issue further, the authors utilized a postembedding immunocytochemical technique with epiretinal membranes in which they were able to double label for keratin, a useful marker for identifying retinal pigment epithelial cells, and glial fibrillary acidic protein (GFAP), a useful marker for identifying glial cells. Nine of ten idiopathic epiretinal membranes contained cells that labeled for GFAP and not keratin. Two of these membranes also contained cells that labeled only for keratin and one membrane contained cells that simultaneously labeled for both GFAP and keratin. Other types of epiretinal membranes had an equal participation by cells that expressed only GFAP or keratin (12 of 17 membranes contained cells positive for keratin; 13 of 17 contained cells positive for GFAP). Ten of 17 nonidiopathic membranes contained cells simultaneously expressing GFAP and keratin, although they comprised only a minor subpopulation of the total number of cells present. These findings demonstrate that keratin and GFAP are not mutually exclusive intermediate filament proteins in cells of epiretinal membranes and that, although each may provide a helpful adjunct for cell type identification, neither is an absolutely specific marker.     

Immunohistochemical demonstration of neuronal and astrocytic differentiation in retinoblastoma

Sections of 51 surgically enucleated eyes from cases of retinoblastomas were examined immunohistochemically to delineate patterns of cellular differentiation. Employing the avidin-biotin immunoperoxidase technique, antibodies were used against glial fibrillary acidic protein (GFAP), S-100 protein and neuron specific enolase (NSE). Areas of uninvolved retina and/or optic nerve were used as built-in positive control. Most of the tumors showed GFAP and S-100 protein-positive perivascular glial cells that were interpreted as reactive astrocytes. In three well-differentiated retinoblastomas, glial cells were found to be interspersed randomly among tumor cells and not associated with blood vessels. These glial cells were interpreted as neoplastic based on their distribution pattern and cytologic features. In about half of the tumors, the retinoblastoma cells stained positively for NSE, indicating their neuronal tumor cells that stained positively for NSE but failed to show any evidence of photoreceptor differentiation. Based on these observations and similar differentiation patterns described in other primitive neuroectodermal tumors of the brain, it is suggested that retinoblastoma cells can differentiate not only into photoreceptor cells but also along other neuronal cell lines and rarely into glial cells.     

Immunohistochemical evidence of neuronal and glial differentiation in retinoblastoma.

BACKGROUND--The study sought to investigate the histogenesis of retinoblastoma. METHODS--One hundred specimens of retinoblastomas were examined along with those of 18 astrocytic gliomas and 15 medulloblastomas to compare similarities of glial differentiation in retinoblastoma and the two types of brain tumour. Employing avidin-biotin immunoperoxidase technique, antibodies were applied against neuron specific enolase (NSE), glial fibrillary acidic protein (GFAP), and S-100 protein (S-100). RESULTS--Most rosettes and fleurettes, and some undifferentiated cells in retinoblastomas were NSE positive, but GFAP and S-100 negative. GFAP and S-100 positive cells in retinoblastomas were detected mostly in well differentiated glial cells which were interpreted as reactive or non-neoplastic cells. Some of the GFAP and S-100 positive cells in retinoblastomas were defined as tumour cells that resembled neoplastic astrocytes in astrocytic gliomas and medulloblastomas. CONCLUSION--Retinoblastoma may arise from primitive bipotential or multipotential cells capable of neuronal and glial differentiation.     

全反式维甲酸对视网膜母细胞瘤细胞增殖和分化影响的实验研究

目的 观察全反式维甲酸(ATRA)对视网膜母细胞瘤SO-Rb 50细胞生长及分化的作用.方法 为实验研究.将不同浓度的ATRA作用于SO-Rb 50细胞,绘制生长曲线;MTT法检测ATRA的IC50值;流式细胞仪测定用药前后的细胞周期;用药前及用药后20 d观察活体细胞和HE染色后的细胞形态;免疫组织化学法检测神经元特异性烯醇化酶(NSE)、波形蛋白(Vimentin)、神经胶质纤维酸性蛋白(GFAP)的表达情况.结果 0、1×10-7、1×10-6、1×10-5mol/L的ATRA作用于SO-Rb 50细胞后细胞生长曲线随药物浓度增加而逐渐变得低平;ATRA作用于细胞的IC50值约为14.05 μmol/L;用1×10=3mol/L的ATRA作用细胞后,G0/G1期细胞从用药前的56.5%升至用药后的66.6%～81.O%,S期细胞则从33.1%降至22.3%～15.9%.细胞在包被0.25%多聚赖氨酸溶液的载玻片上可贴壁牛长,用药后细胞生长集落明显减小,20 d后部分细胞呈椭圆形或梭形,胞核与胞质比值减小,并伸出细长或较短的突起;用药前NSE、Vimentin、GFAP染色分别旱中等阳性、强阳性和弱阳性;用药20 d后三者染色分别呈强阳性、强阳性和中等阳性.结论 ATRA对SO-Rb 50细胞的生长有明显抑制作用,使细胞停滞于细胞周期的G0/G1期.ATRA可诱导SO-Rb 50细胞向神经元和胶质细胞方向分化.(中华眼科杂志,2008,44:549-553)     

Rabbit retinal Müller cells undergo antigenic changes in response to experimentally induced proliferative vitreoretinopathy.

Experimental proliferative vitreoretinopathy (PVR) was induced in the rabbit eye by injecting mitotically active Müller cells into the vitreal chamber. Two weeks after the initiation of PVR, the retina and the epiretinal membrane that formed were examined to ascertain the antigenic expression of Müller cells in the retina and in the epiretinal membrane. Examination of various regions of the retina from the experimental PVR eye demonstrated that vimentin, glial fibrillary acidic protein (GFAP), cellular retinaldehyde binding protein (CRALBP), and beta-amyloid precursor protein (beta-APP), which were present in the Müller cells of the retina from the control eye, increased their expression, while the antigenicity of glutamine synthetase (GS), did not change; these proteins were also present in the cells contained within the experimentally induced epiretinal membrane. Alpha smooth muscle actin (alpha-SMA), a cytoskeletal protein that is associated with migration and tractional forces in many cell types, was not only present in the cells embedded within the epiretinal membrane, but was also present in the Müller cells underlying the epiretinal membrane. However, Müller cells that were in the inferior portion of the retina, where epiretinal membrane pathology was absent, did not express alpha-SMA. Although this protein is not normally found in Müller cells, they do express it de novo when they are maintained in culture. This suggests that a localized mechanism associated with epiretinal membrane formation induces the expression of alpha-SMA in Müller cells while the increased expression of GFAP, beta-APP, vimentin, and CRALBP are probably regulated via a more general mechanism.