Is Thy-1 expressed only by ganglion cells and their axons in the retina and optic nerve?

Summary The distribution of Thy-1 in the retina and optic nerve has been examined immunohistochemically, and compared to that of the astrocytic marker glial fibrillary acidic protein. The axons and cell bodies of ganglion cells were found to be Thy-1 positive as were processes within the inner plexiform layer. Transection of the optic nerve in the neonatal rat results in the rapid degeneration of the ganglion cells but some Thy-1 staining remains in the inner plexiform layer. We have estimated using an immunoassay of normal and optic nerve transected retinae that about 70% of the Thy-1 in the retina is on ganglion cells and their axons and the remainder is on cells which contribute processes to the inner plexiform layer, presumably amacrine, bipolar or Müller cells.In the optic nerve the Thy-1 was found to be limited to the fascicles of optic nerve fibres and the intrafascicular spaces, containing astrocytes and their processes, were not stained. Axotomy of the adult nerve, which produced axonal degeneration and astrocytic proliferation, led to a loss of over 95% of the Thy-1 from the nerve. We found no evidence that the astrocytes of the retina or optic nerve were Thy-1 positive in normal animals or during degeneration.     

The development of astrocytes and blood vessels in the postnatal rabbit retina

Summary Antibodies to glial fibrillary acidic protein (GFAP) have been used to study the shape and location of astrocytes in whole mount preparations of developing postnatal rabbit retina. At all developmental stages GFAP-positive astrocytes were detectable. At birth, they were few in number and only weakly labelled. With further development, their number as well as their labelling intensity increased. Following Nissl counterstaining it was observed that GFAP-positive astrocytes, always situated in the nerve fibre layer, are capable of cell division during about the first 4 postnatal weeks.GFAP-positive astrocytes were always confined to a wing-shaped area extending horizontally from both sides of the optic nerve head. It is suggested that astrocytes are not generated in the entire rabbit retina, which is in clear contrast to the second glial cell type of the rabbit retina, the Müller cell; and it has been concluded that the confinement of astrocytes to the medullary rays region in the adult rabbit is established during ontogenesis, and is not due to a secondary restriction of astrocytes to this region.Horizontal sections cut through entire rabbit retinae at various postnatal stages revealed that the first intraretinal blood vessels are not found before postnatal day 9. This is more than 1 week later than the first astrocytes are detectable. It is suggested that, at least in the rabbit, retinal astrocytes do not co-migrate with blood vessel endothelial cells from the optic disc into the retina, a hypothesis considered recently for the cat retina.It was, however, not possible to decide unequivocally if, in this material, astroglial progenitors are derived from retinal neuroepithelial cells or invade the retina from the optic nerve head.     

The structure of rabbit retinal Müller (glial) cells is adapted to the surrounding retinal layers

Summary Radial glial (Müller) cells of the rabbit retina were studied by various techniques including Golgi impregnation, scanning electron microscopy, horseradish peroxidase application, and staining of enzymatically isolated cells. This combination of methods produced detailed information on the specialized morphology of the Müller cells within the different topographical regions of the retina, and of the Müller cell processes within the various retinal layers. As a general rule, the retinal periphery contains short thick Müller cells with big endfeet, whereas the thick central retina is occupied by long slender cells with small endfeet. Independent of their location within the retina, Müller cell processes were found to be adapted to the structure of the surrounding retinal layers. Within the outer and inner nuclear layers, Müller cell processes (and somata) extend thin cytoplasmic bubbles ensheathing the neuronal somata, as do the velate astrocytes in the brain. In the plexiform layers, Müller cells extend many fine side branches between the neuropil, comparable to the protoplasmic astrocytes of the brain. In the thick myelinated nerve fibre layer of the central retina the Müller cell processes are rather smooth, similar to those of fibrous astrocytes. It is concluded that the neuronal microenvironment determines the morphology of a given glial process, or even of a part of a glial process running through a specialized neuronal compartment.     

Distribution of Müller cells in the turtle retina: an immunocytochemical study

Summary Müller cells are the major type of glial cell in the vertebrate retina, and appear to participate in important structural and metabolic functions. Although the morphological features of Müller cells have been extensively studied, their topographic distribution across the retina has not been previously reported. We have used a Müller cell-specific monoclonal antibody, 19–33, to study the distribution of Müller cells in turtle retina. The antibody was obtained during a search for cell type-specific monoclonal antibodies in the rat retina. Immunoblotting studies show that 19–33 reacts with a 58 KDa protein that is present in Müller cells. Immunocytochemical studies withen face sections of turtle retina show that the density of Müller cells is fairly uniform across the retina although there are small regional differences. We estimate that the mean Müller cell density is about 1600 cells mm^–2 of turtle retina and that each turtle retina contains about 54 000 Müller cells.     

Development of astrocytes in the lamina cribrosa sclerae of the mouse optic nerve,with special reference to myelin formation

In the mouse optic nerve, the optic nerve fiber layer in the retina, the optic papilla and the lamina cribrosa sclerae (LCS) just after penetrating the eyeball failed to generate myelin, whereas the optic nerve proper in the orbit was occupied by myelinated nerve fibers. The present study investigated development of the architecture of LCS, where the axons develop from unmyelinated to myelinated type, to elucidate how the initial part of axons was unmyelinated. At the LCS of the adult optic nerve, well developed astrocytes densely formed a cytoplasmic mesh-like frame through which unmyelinated fibers passed. The astrocytes here contained numerous and densely packed intermediate glial filaments and cell organelles. This framework formed by astrocytes appeared to be completed between 7 and 14 postnatal days before oligodendrocyte progenitors, migrated from the chiasm side, reached the proximal end of LCS, and began myelin formation. Thus the failure in myelin formation at the intraocular part and LCS possibly depended upon unsuccessful migration of oligodendrocytes beyond LCS constructed by specialized astrocytes, although other inhibitory factors for myelin formation, such as adhesion molecules distributed around LCS, may be unsolved.     

The serine racemase mRNA is expressed in both neurons and glial cells of the rat retina

D-Serine, an endogenous and obligatory coagonist for the glycine site of the N-methyl-D-aspartate receptor in mammals, is synthesized from L-serine by serine racemase. Serine racemase and D-serine have long been believed to occur predominantly in astrocytes, according to immunohistochemical studies. Recent studies have demonstrated, however, that both the mRNA and protein levels of serine racemase are considerably higher in neurons than in astrocytes in primary cultures of the rat brain and that the mRNA level of serine racemase predominates in neurons of the adult rat brain. Here we report the application of in situ hybridization based on tyramide signal amplification for the detection of serine racemase mRNA in sections of the adult rat retina and optic nerve head. The localization of serine racemase mRNA could be demonstrated in ganglion cells, amacrine cells, bipolar cells, horizontal cells, and Müller cells of the retina as well as in the astrocytes of the optic nerve head and the lamina cribrosa. This is the first study to demonstrate the exact localization of serine racemase mRNA at the cellular or tissue level in the retina and the optic nerve head. These results suggest that both the neuron- and glia-derived D-serine could modulate neurotransmission via the glycine site of the N-methyl-D-aspartate receptors in the retina.     

Immunolocalization of cellular retinol-, retinaldehyde- and retinoic acid-binding proteins in rat retina during pre- and postnatal development

Summary Cellular retinol-, retinaldehyde- and retinoic acid-binding proteins were localized in rat retina during pre- and postnatal development by indirect immunofluorescence. Cryostat tissue sections were prepared daily from embryonic day 11 until the day of birth (E11–22) and from postnatal days 1–32 (P1–32). Cellular retinaldehyde- and retinol-binding proteins were first detected in retinal pigment epithelium on E13 and E18, respectively, and in Müller cells at P1 and P15. Parallel studies showed that in adult retina cellular retinoic acid-binding protein is present in a subpopulation of GABAergic amacrine cells. During retinal differentiation, cellular retinoic acid-binding protein was first detected at E18 in cells sclerad to the developing inner plexiform layer, suggesting that this binding protein is expressed in amacrine cells very early during differentiation. During early ocular morphogenesis, cellular retinoic acid-binding protein was present in mesenchymal cells enveloping the eye (E12–15), in the neuroblastic layer of the retina (E13–15), in the nerve fibre layer (E14–15), and the developing optic nerve (E15). Our results suggest that retinoic acid, the natural ligand of cellular retinoic acid-binding protein, may be involved in neuronal differentiation in the inner retina. The studies further support a role for cellular retinoic acid-binding protein in mediating the effects of retinoic acid on developing neural crest cells and raise new questions about the role of cellular retinaldehyde-binding protein in the visual cycle and during development.     

Heterogeneous distribution of polysialylated neuronal-cell adhesion molecule during post-natal development and in the adult: an immunohistochemical study in the rat brain

A monoclonal antibody raised against the capsular polysaccharides of meningococcus B was used for immunohistochemical studies in the rat brain, with particular focus on the substantia nigra. This antibody recognizes polysialic acid residues specifically associated with the neuronal-cell adhesion molecule, and reacts with the highly sialylated embryonic neuronal-cell adhesion molecule, but not with the weakly sialylated adult form of the molecule. Immunoreactivity to this monoclonal antibody was intense and widespread in the brain of 1-10-day-old hooded rats. Immunolabeling was associated with cell membranes and present in the intersomata space. In sections from 16- and 25-day-old rats, marked heterogeneity in the level of immunostaining appeared among individual brain nuclei. Areas devoid of labeling with the anti-meningococcus antibody still expressed immunoreactivity to a polyclonal anti-neuronal-cell adhesion molecule antibody. This suggests that the loss of immunostaining with the monoclonal antibody did not correspond to a loss of expression of neuronal-cell adhesion molecule, but to a maturation from the embryonic to the adult form of the molecule, occurring at different rates in various brain regions. In 2-month-old rats, immunolabeling with the monoclonal antibody was still present in discrete brain areas, including the substantia nigra, suggesting that the presence of highly sialylated neuronal-cell adhesion molecule outlasts post-natal development in those brain regions. It is proposed that neuronal-cell adhesion molecule associated polysialic residues may play a role in neuronal plasticity in restricted areas of the adult brain.     

Evidence that migratory oligodendrocyte-type-2 astrocyte (O-2A) progenitor cells are kept out of the rat retina by a barrier at the eye-end of the optic nerve

Summary There is evidence that oligodendrocyte-type-2 astrocyte (O-2A) progenitor cells migrate along the developing rat optic nerve from the chiasm toward the eye before differentiating into oligodendrocytes that myelinate the retinal ganglion cell axons in the nerve. Why, then, do these progenitor cells not migrate into the eye, differentiate into oligodendrocytes and myelinate the nerve fibre layer of the retina? Myelination would opacify the neural retina and thereby severely impair vision. Here we provide evidence that there is a barrier at the eye-end of the rat optic nerve that prevents the migration of O-2A progenitor cells into the retina. Our findings in the rat support a previous hypothesis that such a barrier keeps myelin-forming glial cells out of the human retina.     

Immunohistochemical demonstration of glial fibrillary acidic protein in normal rat Müller glia and retinal astrocytes

The presence of glial fibrillary acidic protein (GFA)-positive Müller glia and retinal astrocytes were studied immunohistochemically in normal rat retina. Using GFA antiserum both Müller glia and separate star-shaped cells were observed in spread-preparations as well as cryostat sections. The retinal astrocytes were also visualized using two different monoclonal GFA antibodies. These cells were found to be located in the nerve fiber and ganglion cell layers. In contrast, Müller glia were not normally visualized with any of the monoclonal GFA antibodies but could be stained 4 days after an optic nerve crush. Our results demonstrate that normal rat Müller glia expresses GFA-like immunoreactivity.     

The ultrastructure of astrocytes, oligodendrocytes, and microglia in the optic nerve of urodele amphibians (A. punctatum, T. pyrrhogaster, T. viridescens)

Summary Recent ultrastructural studies which indicate a single type of glial cell in the amphibian optic nerve are contradicted by the results of the present investigation demonstrating three types of glial cells in the optic nerve of adult newtsT. viridescens andT. pyrrhogaster, and the neotenous salamanderA. punctatum. Well differentiated astrocytes, oligodendrocytes and microglia are the principal glial constituents with cytological characteristics corresponding to glial elements in the optic nerve of mammals. Immature astrocytes and oligodendrocytes are also present in the nerve indicating continuing production of cells from neuro-ectodermal precursors.Astrocytes constitute approximately 80% of the total. Processes of the large multipolar elements divide axons into bundles and extend to the pial surface to form the glia limitans. A distinct inter-species variability (6–17%) in oligodendrocytes is apparently related to differences in the incidence of myelinated axons. Microglia are the least numerous cellular element constituting only 2–6%. They arise, in part, from monocytic cells near the pial surface.     

Signalling of sphingosine-1-phosphate in Müller glial cells via the S1P/EDG-family of G-protein-coupled receptors

Signalling of sphingosine-1-phosphate (S1P) via G-protein-coupled receptors of the Endothelial Differentiation Gene family differentially regulates cellular processes such as migration, proliferation and morphogenesis in a variety of cell types. Proliferation and migration of retinal Müller glial cells are involved in pathological events such as proliferative vitreoretinopathy and proliferative diabetic retinopathy. Investigation of possible functional roles of S1P receptors might thus open new insights into Müller cell pathophysiology. Here we show that cultured Müller cells from the guinea pig retina respond to application of S1P with an increase in the intracellular calcium content in a concentration-dependent manner (EC₅₀ 11 nM). This calcium increase consists of two components; an initial fast peak and a slow plateau component. The initial transient is caused by a release of calcium from intracellular stores and is suppressed by U-73122, a selective phospholipase C inhibitor. The slow plateau component is caused by a calcium influx. These results suggest that the S1P-induced calcium response in Müller cells partially involves signalling via G-protein-coupled receptors. Moreover, S1P slightly induced Müller cell migration but no proliferation. Thus, the data indicate that Müller cells might be involved in S1P signalling in the retina.     

Ischemia-reperfusion alters the immunolocalization of glial aquaporins in rat retina

Glial cells control the retinal osmohomeostasis, in part via mediation of water fluxes through aquaporin (AQP) water channels. By using immunohistochemical staining, we investigated whether ischemia-reperfusion of the rat retina causes alterations in the distribution of AQP1 and AQP4 proteins. Transient ischemia was induced in retinas of Long–Evans rats by elevation of the intraocular pressure for 60 min. In control retinas, immunoreactive AQP1 was expressed in the outer retina and by distinct amacrine cells, and AQP4 was expressed by glial cells (Müller cells and astrocytes) predominantly in the inner retina. After ischemia, retinal glial cells in the nerve fiber/ganglion cell layers strongly expressed AQP1. The perivascular staining around the superficial vessels altered from AQP4 in control retinas to AQP1 in postischemic retinas. The data suggest that the glial cell-mediated water transport in the retina is altered after ischemia especially at the superficial vessel plexus.     

Msx1 expression in the adult mouse brain: characterization of populations of beta-galactosidase-positive cells in the hippocampus and fimbria

We have analyzed Msx1 expression in the mature mouse brain using in situ hybridization and beta-galactosidase activity in Msx1(nLacZ) mice. The study revealed that Msx1 is strongly expressed in the circumventricular organs, such as the subcommissural organ and choroid plexus, and in some epithelia, such as that of the dorsal, but not the ventral part of the third ventricle. Immunohistochemical analysis revealed that the Msx1-expressing cells of the hippocampus and fimbria are astrocytes, oligodendrocytes or immature oligodendrocytes. In contrast, no co-expression was detected in these structures using several neuronal markers. These results were confirmed, using transmission electron microscopy, by the presence of 5-bromo-3-indolyl-beta-D-galactopyranosideprecipitates in astrocytes and oligodendrocytes in both sites. Moreover, using an anti-glial fibrillary acidic protein antibody (GFAP), our study reveals two populations of astrocytes in the adult hippocampus and other areas, such as the fimbria, namely Msx1+/GFAP+ and Msx1-/GFAP+. Beta-galactosidase activity was also observed in endothelial cells of hippocampal fissure blood vessels. We also observed co-localization of polysialic acid neural cell adhesion molecule, a marker of the polysialylated form of the neural cell adhesion molecule, in Msx1-expressing cells in the fimbria. These cells may be precursors of glial cells and originate from the epithelium of the fimbria. The present study indicates, in the mature mouse brain, that Msx1 may be linked to secretory activity in circumventricular organs, and to glial proliferation and differentiation in the hippocampus and fimbria, and presumably also in other cerebral areas. We suggest that Msx1 could be associated with brain homeostasis and blood-brain barrier function.     

Reticulon3 expression in rat optic and olfactory systems

Reticulon3 (RTN3), which belongs to a reticulon family, is first isolated from the retina, but little is known about its function. We investigated the distribution of RTN3 in rat retina and olfactory bulb by immunohistochemistry. In the retina, Müller cells highly expressed RTN3. The expression level of RTN3 in the optic nerve was high in the embryo, but low in the adult. In the olfactory system, RTN3 was highly expressed in the olfactory nerve both in developmental and adult stages. Further, RTN3 was co-localized with synaptophysin in tubulovesicular structures in the developing axon of cultured cortical neurons. These results suggest that RTN3 may play an important role in the developing axons and also in some glial cells such as Müller cells.     

Regeneration of axons in the optic nerve of the adult Browman-Wyse (BW) mutant rat

Summary We have studied the regeneration of axons in the optic nerves of the BW rat in which both oligodendrocytes and CNS myelin are absent from a variable length of the proximal (retinal) end of the nerve. In the optic nerves of some of these animals, Schwann cells are present. Axons failed to regenerate in the exclusively astrocytic environment of the unmyelinated segment of BW optic nerves but readily regrew in the presence of Schwann cells even across the junctional zone and into the myelin debris filled distal segment. In the latter animals, the essential condition for regeneration was that the lesion was sited in a region of the nerve in which Schwann cells were resident. Regenerating fibres appeared to be sequestered within Schwann cell tubes although fibres traversed the neuropil intervening between the ends of discontinuous bundles of Schwann cell tubes, in both the proximal unmyelinated and myelin debris laden distal segments of the BW optic nerve. Regenerating axons never grew beyond the distal point of termination of the tubes. These observations demonstrate that central myelin is not an absolute requirement for regenerative failure, and that important contributing factors might include inhibition of astrocytes and/or absence of trophic factors. Regeneration presumably occurs in the BW optic nerve because trophic molecules are provided by resident Schwann cells, even in the presence of central myelin, oligodendrocytes and astrocytes. All the above experimental BW animals also have Schwann cells in their retinae which myelinate retinal ganglion cell axons in the fibre layer. Control animals comprised normal Long Evans Hooded rats, BW rats in which both retina and optic nerve were normal, and BW rats with Schwann cells in the retina but with normal, i.e. CNS myelinated, optic nerves. Regeneration was not observed in any of the control groups, demonstrating that, although the presence of Schwann cells in the retina may enhance the survival of retinal ganglion cells after crush, concomitant regrowth of axons cut in the optic nerve does not take place.     

The origin and development of retinal astrocytes in the mouse

Summary Astrocytes, a class of glia which appear in the mammalian retina late in development, have been postulated either to originatein situ from Müller cells or extra-retinally from the optic stalk epithelium, only subsequently invading the eye. The site of origin and the developmental characteristics of retinal astrocytes were examined in the mouse, a species not previously studied for this purpose. Sections of normal eyes and stalks at different ages were examined. Cells positive for glial fibrillary acidic protein (GFAP) were first observed at post-conceptional day 17 at the optic disc end of the stalk. From this site, the GFAP-positive cells migrated into and across the retina at a rate of 290 m per day, reaching its edge by post-conceptional day 28. While migrating across the retina, the astrocytes progressively increased in size and morphological complexity, observations confirmed by measurement of their fractal dimension. Over the same period, a wave of differentiation swept along the stalk in the cranial direction. Further evidence that retinal astrocytes are born outside the retina emerged when foetal hemiretinae with or without optic stalks were explanted to the chorioallantoic membrane of the chick. When examined one to twelve days later, no expiant cultured without the optic stalk contained GFAP-positive astrocytes, while expiants with the stalk left attached contained relatively normal numbers of astrocytes. We observed, using fluorescence confocal microscopy, that retinal astrocytes in the mouse as in the rat, associate predominantly with blood vessels, not axonal bundles. It was of interest to determine whether this class of glia is essential to the normal cytoarchitectural development of the neural retina. Morphological analysis of the expiants revealed no observable differences in cytoarchitecture or in the timing of developmental events between retinae maturing with or without astrocytes. It was therefore concluded that astrocytes may not be essential to the normal structural development of the murine retina.     

Retinal pigment epithelium melanin granules are phagocytozed by Müller glial cells in experimental retinal detachment

The ability of retinal Müller glial cells to perform phagocytosis in vivo is studied in a rabbit model of experimental retinal detachment where pigment epithelial cells are occasionally detached together with the neural retina. While macrophages and/or microglial cells phagocytoze most of the cellular debris at the sclerad surface of the detached retinae, some Müller cells accumulate melanin granules. The granules are virtually intact at the ultrastructural level, and are surrounded by a membrane. They are often located close to the sclerad end of the cells, but some are distributed throughout the outer stem process up to the soma. It is concluded that rabbit Müller cells in vivo are capable of phagocytosis and of transporting the phagocytozed material within their cytoplasm.