Histology of the ferret retina

The retina of the adult ferret, Mustelo furo, was studied with light and transmission electron microscopy to provide an anatomical basis for use of the ferret as a model for retinal research. The pigment epithelium is a simple cuboidal layer of cells characterized by a zone of basal folds, apical microvilli, and pigment granules at various stages of maturation. The distinction between rod and cone photoreceptor cells is based on their location, morphology, heterochromatin pattern and the electron density of their inner segments. The round, light-staining cone cell nuclei occupy the layer of perikarya along the apical border of the outer nuclear layer. The remainder of the outer nuclear layer consists of oblong, deeply-stained rod cell nuclei. Ribbon type synaptic complexes involving photoreceptor cell axons, horizontal cell processes, and bipolar cell dendrites characterize the outer plexiform layer. The inner nuclear layer is comprised of horizontal, bipolar, and amacrine cell perikarya as well as the perikarya of the Müller cells. The light-staining horizontal cell nuclei are prominent along the apical border of the inner nuclear layer. The light-staining amacrine cell nuclei form a more or less continuous layer along the basal border of the inner nuclear layer. Both conventional and ribbon-type synapses characterize the inner plexiform layer. The ganglion cells form a single cell layer. The optic fiber layer contains bundles of axons surrounded by Müller cell processes. Small blood vessels and capillaries are present in the basal portion of the retina throughout the region extending from the internal limiting membrane to the outer plexiform layer. The adult one-year-old retina is compared with the retina at the time of eye opening.     

Neuron-glia interactions in the rat retina infected by Borna disease virus

Summary.  Neuron-glia interactions in the Borna disease virus (BDV)-infected rat retina were investigated with emphasis on the ultrastructural characterization of degenerative alterations in the ganglion cell and photoreceptor layer. Immuno- and cytochemical techniques were applied to label microglia, macrophages and Müller (macroglial) cells. Four weeks after intracerebral infection of adult rats, the total thickness of the retina was considerably diminished, primarily due to the loss of photoreceptor segments and ganglion cells. A gradual reduction of both plexiform layers was also observed. There was a remarkable increase in the number of microglial cells, predominantly in the ganglion cell and the inner plexiform layers. Ultrastructural analysis confirmed that microglia, but also macrophages, were involved in phagocytosis accompanying severe neuronal degeneration in the ganglion cell and the photoreceptor layer. In contrast, Müller cells showed moderate morphological and cytochemical alterations, indicating that Müller cells play only a minor role in early stages of BDV-induced retinitis. Monitoring neuron-glia interactions in BDV-induced retinopathy, combined with the application of different protocols of immunosuppression effecting the BDV virus and/or the microglia, might help to establish specific strategies to suppress BDV-induced neuronal degeneration. Received October 21, 1998/Accepted June 23, 1999     

Müller glia and phagocytosis of cell debris in retinal tissue

Müller cells are the predominant glial cell type in the retina of vertebrates. They play a wide variety of roles in both the developing and the mature retina that have been widely reported in the literature. However, less attention has been paid to their role in phagocytosis of cell debris under physiological, pathological or experimental conditions. Müller glia have been shown to phagocytose apoptotic cell bodies originated during development of the visual system. They also engulf foreign molecules that are injected into the eye, cone outer segments and injured photoreceptors. Phagocytosis of photoreceptor cell debris in the light‐damaged teleost retina is primarily carried out by Müller cells. Once the microglial cells become activated and migrate to the photoreceptor cell layer, the phagocytic activity of Müller cells progressively decreases, suggesting a possible mechanism of communication between Müller cells and neighbouring microglia and photoreceptors. Additionally, it has been shown that phagocytic Müller cells acquire proliferating activity in the damaged teleost retina, suggesting that engulfment of apoptotic photoreceptor debris might stimulate the Müller glia to proliferate during the regenerative response. These findings highlight Müller glia phagocytosis as an underlying mechanism contributing to degeneration and regeneration under pathological conditions.     

In utero development and maturation of the retina of a non-primate mammal: A light and electron microscopic study of the guinea pig

Summary A light and electron microscopic examination of retinogenesis in the fetal guinea pig has revealed an early development of synapses and photoreceptor cells. Differentiation of the neural retina begins around day 23 of gestation. By 34 days the retina reaches its maximum thickness. It differentiates an inner plexiform layer in which vesicle-containing processes and primitive synapses are evident. Synaptic ribbons are found in processes of this layer by 43–45 days of gestation. An outer plexiform layer develops within the neuroblast layer at 40 days of gestation; from its first appearance the outer plexiform layer contains synapses complete with synaptic ribbons. Receptor terminals of the , paranuclear and type are present well before birth. Photoreceptor cells form inner segments by 40 days; the formation of outer segments is indicated by 45 days but not widespread until 49 days. The retina appears mature by day 51–57. It is clear that the primate is not unique in the early differentiation of its retinal synapses relative to the time of maturation of its photoreceptor cells. The potential functional capacities of precocious retinae, and the mechanisms of synapse development are discussed.Supported by Grants from the Medical Research Council.     

Localization of glial aquaporin-4 and Kir4.1 in the light-injured murine retina

Excessive light causes damage to photoreceptor and pigment epithelial cells, and a local edema in the outer retina. Since Müller glial cells normally mediate the osmohomeostasis in the inner retina (mainly via channel-mediated transport of potassium and water), we determined whether retinal light injury causes an alteration in the retinal localization of glial water (aquaporin-4) and potassium (Kir4.1) channels, and in the potassium conductance of Müller cells. Mice were treated with bright white light (intensity, 15,000lx) for 2h. Light treatment results in Müller cell gliosis as indicated by the enhanced staining of the glial fibrillary acidic protein and an increase in the cell membrane area reflecting cellular hypertrophy. In light-injured retinas, the immunostaining of the photoreceptor water channel aquaporin-1 disappeared along with the degeneration of the outer retina, and the outer nuclear layer contained large spherical bodies representing photoreceptor nuclei which were fused together. The immunostainings of the aquaporin-4 and Kir4.1 proteins were increased in the outer retina after light treatment. Since the amplitude of the potassium currents of Müller cells remained largely unaltered, the increase in the Kir4.1 immunostaining is supposed to be caused by a redistribution of the channel protein. The data indicate that Müller glial cells respond to excessive light with an alteration in the localization of Kir4.1 and aquaporin-4 proteins; this alteration is thought to be a response to the edema in the outer retina and may support the resolution of edema.     

Neuronal and glial cell types revealed by NADPH-diaphorase histochemistry in the retina of a teleost fish, the grass goby (Zosterisessor ophiocephalus, Perciformes, Gobiidae)

The grass goby is a mud-burrowing fish with a rich retinal vasculature appropriate to its hypoxic habitat. NADPH-diaphorase histochemistry was performed on retinal sections and wholemounts to reveal cells that contain nitric oxide synthase and so may be presumed to synthesise nitric oxide, a gaseous intercellular messenger with many roles including vasodilation. Structures that were consistently stained by this method included cone ellipsoids, horizontal cells, Müller cells and their processes, large displaced ganglion cells in the inner nuclear layer (identified by their axons), large interstitial ganglion cells in the inner plexiform layer, and capillary endothelial cells. In wholemounts, horizontal cells were seen to form a regular pattern, contacting each other at their dendritic terminals. Some cells in the ganglion cell layer were weakly stained, but stained bipolar and amacrine cells were not seen. The diaphorase-positive large ganglion cells all formed large, sparsely branched dendritic trees, arborizing near the scleral border of the inner plexiform layer. The displaced and interstitial cells seemed to belong to distinct morphological types, the interstitial cells having smaller somata and trees. Analysis of their spatial distributions in one representative retina confirmed this: the displaced cells formed a highly regular mosaic with a mean spacing (nearest-neighbour distance) of 303 µm, whereas the interstitial cells formed a separate mosaic, almost as regular but with a smaller mean spacing of 193 µm, rising to 217 µm in a sample that excluded the area retinae temporalis. Spatial correlogram analysis showed that these two mosaics were spatially independent. Nitric oxide probably has many roles in the retina. The presence of its synthetic enzyme in Müller cells, which communicate with retinal blood vessels, is consistent with a role in the control of retinal blood flow. Its function in large, mosaic-forming retinal ganglion cells is unknown.     

Expression of aquaporin-1 immunoreactivity by photoreceptor cells in the mouse retina

Aquaporin water channels play a crucial role in the maintenance of ionic and osmotic homeostasis in the neural tissue. In the sensory retina, aquaporin-4 is expressed by Müller glial cells, predominantly in the inner retina, while aquaporin-1 is expressed mainly in the outer retina. However, it is unknown whether aquaporin-1 expression occurs in Müller cells or photoreceptor cells. By using immunohistochemical staining of retinal slices from rds mice, we show that the immunoreactivity for aquaporin-1 disappears along with the photoreceptor cell degeneration. In suspensions of dissociated retinal cells from control mice, photoreceptor cells expressed aquaporin-1 immunoreactivity while Müller cells were largely devoid of staining. The data suggest that photoreceptor cells, but not Müller cells, express aquaporin-1 in the murine retina.     

Neuronal and glial cell types revealed by NADPH-diaphorase histochemistry in the retina of a teleost fish, the grass goby ( Zosterisessor ophiocephalus , Perciformes, Gobiidae)

The grass goby is a mud-burrowing fish with a rich retinal vasculature appropriate to its hypoxic habitat. NADPH-diaphorase histochemistry was performed on retinal sections and wholemounts to reveal cells that contain nitric oxide synthase and so may be presumed to synthesise nitric oxide, a gaseous intercellular messenger with many roles including vasodilation. Structures that were consistently stained by this method included cone ellipsoids, horizontal cells, Müller cells and their processes, large displaced ganglion cells in the inner nuclear layer (identified by their axons), large interstitial ganglion cells in the inner plexiform layer, and capillary endothelial cells. In wholemounts, horizontal cells were seen to form a regular pattern, contacting each other at their dendritic terminals. Some cells in the ganglion cell layer were weakly stained, but stained bipolar and amacrine cells were not seen. The diaphorase-positive large ganglion cells all formed large, sparsely branched dendritic trees, arborizing near the scleral border of the inner plexiform layer. The displaced and interstitial cells seemed to belong to distinct morphological types, the interstitial cells having smaller somata and trees. Analysis of their spatial distributions in one representative retina confirmed this: the displaced cells formed a highly regular mosaic with a mean spacing (nearest-neighbour distance) of 303 μm, whereas the interstitial cells formed a separate mosaic, almost as regular but with a smaller mean spacing of 193 μm, rising to 217 μm in a sample that excluded the area retinae temporalis. Spatial correlogram analysis showed that these two mosaics were spatially independent. Nitric oxide probably has many roles in the retina. The presence of its synthetic enzyme in Müller cells, which communicate with retinal blood vessels, is consistent with a role in the control of retinal blood flow. Its function in large, mosaic-forming retinal ganglion cells is unknown. Accepted: 29 April 1999     

An ultramicroscopic study on the distribution of Müller cell processes in the outer retinal layers of the zebrafish

The zebrafish, Brachydanio rerio, is a good model for studying the development of various organs. We have assayed the distribution pattern of Müller cell processes in zebrafish retinas by electron microscopy. In the outer nuclear (ON) layer, multiple layers of Müller cell processes were present along both sides of the large pyramidal endings of the synaptic terminals. We found that the inner segments (ISs) of the zebrafish photoreceptors (PRs), including the cones, double cones and rods, were arranged in different planes, and that the Müller cell processes formed multilayered sheaths around virtually all PR compartments except their outer segments. Thus, Müller cell processes beyond the outer limiting membrane (OLM) are more easily observed in zebrafish retina than in the retinas of other species. To our knowledge, this is the first study to show the exact ultrastructural distribution of Müller cell processes around the OLM and the PR layer in zebrafish retina.     

Intermediate filament complement of the normal and gliotic canine retina.

Intermediate filament expression of various cell types in the adult canine normal and gliotic retina was determined by an immunoperoxidase method of using monoclonal antibodies on aldehyde-fixed tissues. In the normal retina, vimentin was present in astrocytes in the nerve fibre layer, horizontal cell processes, and Müller cell fibres from the internal limiting membrane to the outer nuclear layer. Neurofilamentous axons were noted in the nerve fibre, inner plexiform layer, and outer plexiform layer, although the degree of staining intensity varied among the three molecular weight neurofilament antisera used. Glial fibrillary acidic protein (GFAP) staining was confined to the nerve fibre and ganglion cell layer; this was interpreted as representing fibrous astrocytes. Astrocyte density varied according to retinal topography with an increased number around retinal blood vessels and in the peripapillary retina. Quantitative, but not qualitative differences in staining for vimentin and the neurofilaments were noted in degenerative, gliotic retinas. In common with several other mammalian species previously studied, the canine Müller cells accumulate or express GFAP under pathological conditions involving a gliotic response.     

Distribution of monocarboxylate transporters MCT1 and MCT2 in rat retina.

Transport of lactic acid and other monocarboxylates such as pyruvate and the ketone bodies through cellular membranes is facilitated by specific transport proteins. We used chicken polyclonal antibodies to the monocarboxylate transporters-1 and -2 to determine their cellular and subcellular distributions in rat retina, and we compared these distributions to those of the glucose transporters-1 and -3. Monocarboxylate transporter-1 was most highly expressed by the apical processes of retinal pigment epithelium that surround the outer segments of the photoreceptor cells. In contrast to glucose transporter-1, monocarboxylate transporter-1 was not detected on the basal membranes of pigment epithelium. The luminal and abluminal endothelial plasma membranes in retina also exhibited heavy labeling by antibody to monocarboxylate transporter-1. In addition, this transporter was associated with the Müller cell microvilli, the plasma membranes of the rod inner segments, and all retinal layers between the inner and external limiting membranes. Monocarboxylate transporter-2 was found to be abundantly expressed on the inner (basal) plasma membrane of Müller cells and by glial cell processes surrounding retinal microvessels. This transporter was also present in the plexiform and nuclear layers but was not detected beyond the external limiting membrane. Recent studies have shown that lactic acid transport is of particular importance at endothelial and epithelial barriers where membranes of adjoining cells are linked by tight junctions. Our results suggest that monocarboxylate transporter-1 functions to transport lactate between the retina and the blood, both at the retinal endothelium and the pigment epithelium. The location of monocarboxylate transporter-2 on glial foot processes surrounding retinal vessels suggests that this transporter is also important in blood-retinal lactate exchange. In addition, the abundance of these transporters in Müller cells and synaptic (plexiform) layers suggests that they function in lactate exchange between neurons and glia, supporting the notion that lactate plays a key role in neural metabolism.     

Retinal degeneration in experimental Creutzfeldt-Jakob disease

Mice with experimental Creutzfeldt-Jakob disease (CJD) develop a progressive retinal degeneration after a prolonged incubation period. Sections of the eyes stained with hematoxylin and eosin revealed pathologic changes in the optic nerve and a marked degeneration of photoreceptor cell inner and outer segment areas. Both peripheral and central retina, normally 10 cells thick, were reduced to one photoreceptor cell or less in thickness. Ultrastructural analysis revealed total loss of outer segment and most inner segment elements. Only Müller cell microvilli and macrophages remained in the subretinal space. Macrophages were also visible in the remnant photoreceptor cell layer. The inner nuclear layer and pigment epithelial cell layers appeared normal. Müller cell hypertrophy was evident but was not accompanied by spongiform vacuolation. Several of the degenerative changes of the eye in mice with experimental Creutzfeldt-Jakob disease differ from those observed for scrapie in rodents. The pathologic similarities between the retinal degenerations occurring in mice with experimental Creutzfeldt-Jakob disease and those found in some forms of human retinal degeneration are provocative. These similarities raise the question whether or not other retinal degenerative diseases might be caused by infectious agents such as prions or slow viruses.     

Closer look at lactose-mediated support of retinal morphogenesis

We have previously shown in intact isolated eye rudiments from Xenopus laevis that lactose, but not mannose, permits the formation of organized photoreceptor outer segments in the absence of the retinal pigment epithelium (RPE). The purpose of this study was to determine, using electron microscopic analysis, the key ultrastructural differences between healthy retinas, lactose-protected retinas, and retinas that developed aberrantly to reveal which subcellular structures were exclusively present in healthy retinas. Filamentous actin was also localized in retinas to determine its distribution under the various conditions. In healthy retinas, calycal processes extending approximately three-fourths of the length of the outer segment surrounded highly organized photoreceptor outer segments. Adherens junctions were localized between adjacent photoreceptors and Müller cells at the outer limiting membrane. In addition, Müller cells possessed apical processes that extended for a short distance beyond the adherens junctions. These fine cytoarchitectural details were missing in retinas that completed differentiation in the absence of the RPE; both calycal and apical processes were no longer present and adherens junctions were sparsely intermittent. Müller cells appeared atrophic. Similarly, mannose promoted none of the fine cytoarchitectural details of the retina. Lactose, however, supported the formation of the proper subcellular cytoarchitecture of both photoreceptor and Müller cells. These results suggest that these subcellular structures may be fundamental for the proper assembly and stability of organized outer segments and are necessary to allow for normal cytogenesis of the outer retina.     

Dopamine- and adenosine-3':5'-monophosphate (cAMP)-regulated phosphoprotein of Mr 32,000 (DARPP-32) in the retina of cat, monkey and human.

The cellular localization of a dopamine- and cAMP-regulated phosphoprotein of Mr 32,000 (DARPP-32) was investigated in cat, monkey and human retina by immunohistochemistry. In cat, DARPP-32-immunoreactive cell bodies identified as Müller cells were demonstrated in the inner nuclear layer (INL) with processes closely surrounding the cell soma of photoreceptors in the outer nuclear layer. Some DARPP-32-IR cells were also seen in the nerve fiber layer (NFL) sending processes to the inner plexiform layer. In monkey and human retina, DARPP-32-IR cell bodies were also demonstrated in the INL, with few cells located in the NFL.     

Microelectrode study of spreading depression (SD) in frog retina-Müller cell activity and [K+] during SD--.

By means of K+ microelectrodes, K+ potentials and [K+] were studied in frog retinas conditioned for SD by CL--free Ringer's. A marked increase in [K+]o was observed during SD, the increase being maximal in the inner plexiform layer (up to 50 mM or more) and subsiding towards the distal retina. The extracellular K+ potential change during SD and also the graded K+ potential changes produced locally by iontophoretic injection of SD-stimulant chemicals resembled the membrane potential changes in Müller cells under the same conditions, suggesting that the Müller cells act as K+ electrodes. In retinas conditioned by Cl--free Ringer's Müller cells were swollen. This allowed intracellular recording with K+ electrodes in Müller cells to reveal that upon SD the Müller cells immediately start to cleanse the extracellular space of excess K+ which is probably a product of pathologically enhanced synaptic activity in the inner plexiform layer. The mechanism of SDP, the field potential change associated with SD, is discussed from a proposed model.     

Growth of postnatal rat retina in vitro. Development of neurotransmitter systems

In this study, we demonstrate that explanted neonatal rat retina can be maintained in culture for periods up to 3 weeks. The cultured retinas displayed a distinct layering that was almost identical to litter-matched retinas of the same age, but the majority of the ganglion cells did not survive and photoreceptor outer segments did not develop properly. Distinct synaptophysin immunoreactivity was expressed in both the inner and outer plexiform layers of cultured retina and the pattern mimicked that one observed in vivo. After 2-3 weeks in vitro, the inner retina expressed immunoreactivities to various components of the cholinergic and nitrergic transmitter systems, including nitric oxide activated cyclic GMP immunoreactivity. The investigated cell populations displayed similar distribution patterns as in situ, but morphological differences appeared in vitro. Such differences were mainly observed as irregularities in the arborization patterns in the inner part of the inner plexiform layer. We suggest that these discrepancies may arise as a result of reduced ganglion cell survival. Our observations demonstrate that some neurotransmitter systems develop in vitro and their neural circuitry appears similar to the in vivo situation. The presence of synapses, receptor proteins and transmitter substances implies that neural communication can occur in cultured retinas.     

Early postnatal Müller cell death leads to retinal but not optic nerve degeneration in NSE-Hu-Bcl-2 transgenic mice

Topographically localized over-expression of the human Bcl-2 protein in retinal glial Müller cells of a transgenic mice (line 71) leads to early postnatal apoptotic Müller cell death and retinal degeneration. Morphological, immunohistological and confocal laser microscopic examination of transgenic and wild-type retinas were achieved on paraffin retinal sections, postnatally. Apoptosis occurs two to three days earlier in the internal nuclear layer of transgenic retinae, than in wild-type littermates. In parallel there was a progressive disappearance of transgenic Hu-Bcl-2 over-expression, as well as of the Müller cell markers, cellular retinaldehyde-binding protein and glutamine synthetase. This phenomenon led to retinal dysplasia, photoreceptor apoptosis and then retinal degeneration and proliferation of the retinal pigment epithelium. The optic nerve, however, remains intact. Two complementary observations confirm the pro-apoptotic action of Bcl-2 over-expression in Müller cells: (i) in the peri-papillary and peripheral regions where the transgene Bcl-2 is not expressed, cellular retinaldehyde-binding protein or glutamine synthetase immunostaining persist and Müller glia do not die; and (ii) the retina conserves a normal organisation in these two regions inspite of total retinal degeneration elsewhere.We conclude that retinal dysplasia and degeneration are linked to primary Müller cell disruption. Besides its generally accepted anti-apoptotic function, over-expression of Bcl-2 also exerts a pro-apoptotic action, at least in immature Müller glia. One may suppose that Bcl-2 translocation resulting in its over-expression in retinal Müller cells could be a putative mechanism for early retinal degeneration.     

Immunohistochemical features of cells in peripheral microcystoid retinal degeneration

Peripheral microcystoid retinal degeneration (PMD) is an age-related, benign condition in which the peripheral retina develops small holes and undergoes cystic degeneration. This paper demonstrates neuronal alterations in PMD, as studied by immunohistochemistry in postmortem donor eyes (age: 76–89 years; N = 6 donors). In all cases, the degeneration was located in the inferior temporal quadrant, creating holes in the far peripheral retina. There was thinning of the inner retinal layers and the outer plexiform layer (OPL) was patchy or inconspicuous. As a response, Müller cell processes showed increased vimentin immunoreactivity. None of the retinas examined expressed glial fibrillary acidic protein. Cone photoreceptor cells were significantly altered: compared to the adjoining cones that were short, those located in the cystoid retina underwent significant elongation of their inner segments, evident from calbindin immunolabeling, to maintain synaptic contacts with the remnant OPL. The latter consisted of small photoreceptor terminals and scanty processes from shrunken bipolar cells. Besides, cones and ganglion cells undergo oxidative stress, they showed immunoreactivity to 4-hydroxy 2-nonenal and nitrotyrosine. The level of superoxide dismutase-2 was relatively low in the PMD region than in adjacent area, suggesting that the former suffers from oxidative stress.     

Glucagon-like immunoreactivity in mouse and rat retina

Mouse and rat retinae were examined by the peroxidase-anti-peroxidase technique of immunocytochemistry using an antiserum against glucagon. The immunoreactivity was found in the cells of the ganglion cell layer and inner nuclear layer, including Müller cells. These observations may indicate that glucagon or a similar peptide is important in neuromodulation and/or metabolism of retinal cells.     

Development of normal retinal organization depends on Sonic hedgehog signaling from ganglion cells

The adult retina is organized into three cellular layers--an outer photoreceptor, a middle interneuron and an inner retinal ganglion cell (RGC) layer. Although the retinal pigment epithelium (RPE) and Müller cells are important in the establishment and maintenance of this organization, the signals involved are unknown. Here we show that Sonic hedgehog signaling from RGCs is required for the normal laminar organization in the vertebrate retina.