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.     

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.     

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.     

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.     

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.     

Becoming glial in the neural retina.

During development of the vertebrate neural retina, multipotent stem cells give rise to retinal neurons as well as to Müller cells, the principal glial population in the retina. Recent studies have shed light upon the extracellular and intracellular signaling pathways that regulate Müller glial cell genesis. Emerging evidence demonstrates that activation of the Notch signaling pathway can play a role in regulating Müller cell development as well as gliogenesis in other parts of the central nervous system. Cyclin dependent kinase (CDK) inhibitors of the Cip/Kip subfamily are cell cycle regulators that can regulate progenitor proliferation during retinal development, but also regulate the proliferation of Müller glia when they become activated in response to stress or injury. Surprisingly this class of proteins can also promote the development of Müller glia. In this review we discuss the role of both Notch and the CDK inhibitors in regulating Müller cell development.     

The peripapillary glia of the optic nerve head in the chicken retina

Abstract The eye of reptiles and birds is characterized by an avascular retina and a vascular convolute called conus papillaris in reptiles and pecten oculi in birds which arises from the papilla nervi optici (PNO) or optic nerve head into the vitreous. At least in birds, this central part of the retina is the site of a heterogeneous population of glial cells. Müller cells reside in the retina, astrocytes in the optic nerve, and pecteneal glial cells in the pecten. The latter are developmentally related to the pigment epithelial cells. In addition to these established types of cells, there is a population of glial cells lining the base of the pecten oculi. In the present study, we investigated both the morphology and the development of these glial cells of the PNO in a series of chicken embryos. These cells were called peripapillary glial cells. They were characterized by their morphology and by their spatiotemporal expression of antigens typical of glial cells (intermediate filaments and glutamine synthetase). They reside at the border between the retina and the optic nerve and at the innermost border of the ventricular cleft representing transitional forms among Müller cells, astrocytes, and pigment epithelial cells. The developmental data suggest a migration of the perikarya of the peripapillary glia in vitread direction, which may coincide with that of the pecteneal glia. Whereas the pecteneal glial cells differentiate morphologically from E16 on, the peripapillary glia retain characteristics of radial glia by spanning the distance from the vitreous to the ventricular cleft. Blood vessels only occurred in the optic nerve head and the pecten oculi. No capillaries were found in the retinal tissue, beyond the peripapillary glia, leading us to suggest that these cells may play a role in demarcating the outer limit of vascularization. The functional properties of these cells are unknown but were discussed to include prevention of vessel growth into the avascular retina and/or axonal guidance during development.     

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.     

Development of the neonatal rabbit retina in organ culture

Organ cultures from neonatal rabbit retinae grew well over periods of up to 2 weeks in vitro. Proliferation in vitro declined in parallel with the decline seen in vivo, although the rate of proliferation in the explants was slightly reduced. The proliferation of progenitor cells in vitro produced the same cell types produced postnatally in vivo. Postnatally generated cell clones, labeled by means of a retroviral vector, consisted mainly of rods and Müller cells. The layers of the retinae developed as in vivo; an outer plexiform layer occurreed after the first 2 days in vitro. Ultrastructurally, ribbon synapses (outer and inner plexiform layer) and conventional synapses (inner plexiform layer) were observed. The photoreceptor cells grew well-developed inner segments and cilia but no mature outer segments. The cultured retinae contained a well-developed, regular lattice of Müller cells expressing vimentin as in vivo. The neuron-to-Müller cell-ratios were essentially the same as in vivo, viz. about 15 to 16 neurons, among them about 10 to 11 (rod) photoreceptor cells per Müller cell. When the glia cell-specific toxin α-aminoadipic acid (αAAA) was applied, the pattern of vimentin-positive Müller cells became irregular, or even locally missing. In such cases, the tissue became disorganized as indicated by a local disappearance of the regular layering, and development of many rosettes. It is concluded that an intact lattice of Müller cells is necessary for the migration of young neurons, and for correct formation of retinal layers.     

Specific transcellular carbocyanine-labelling of rat retinal microglia during injury-induced neuronal degeneration

The present work employed a new technique for labelling phagocytizing microglia in the axotomized retinal of adult rats. Transection axotomy was performed within the intraorbital segment of the optic nerve, and the fast-transported, vital fluorescent carbocyanine dyes DiI and 4Di-10ASP were deposited at the ocular stump of the nerve in order to retrogradely prelabel the ganglion cells which were destined to die. Optic nerve transection resulted in progressive degradation of ganglion cell axons, perikarya and dendrites within the retina and in release of fluorescent material which was then incorporated into cells identified as microglia but not into other cells of the retina. Incorporation of labelled material into microglia occurred only when the ganglion cells degenerated and not when the non-lesioned ganglion cells were labelled from the superior colliculus. Double-staining of microglia with both dyes helped to compare the pattern of labelling for each dye. After progression of ganglion cell degeneration, microglia displayed a staggered, bilaminated distribution within the ganglion cell layer and within the inner plexiform layer. Fluorescent microglia were not found within the deeper layers of the retina indicating that transneuronal degeneration and subsequent labelling of microglial cells do not occur. The results show that one major function of microglia within the ganglion cell and inner plexiform layers of the lesioned retina is to remove debris produced after degradation of neurons.     

大鼠视神经切断后视网膜双极细胞PKC-α和recoverin的表达

为了探讨视神经切断后视网膜内部是否存在突触可塑性改变,本实验采用大鼠视神经切断模型,通过免疫组织化学方法检测视神经切断后视网膜双极细胞PKC-α和recoverin的表达变化。结果显示:正常视网膜中,PKC-α和recoverin阳性产物主要见于视网膜内核层、内网层及节细胞层,另外外核层也可见少量recoverin阳性细胞。视神经切断后3d,大鼠视网膜内网层高倍镜下可见PKC-α和recoverin免疫阳性终末的数量开始增加,14d时增至最高,21d、28d呈现逐渐减少的趋势。本研究结果提示视神经切断后视网膜双极细胞与节细胞之间的突触可能存在早期增生,后期溃变的可塑性变化。     

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.     

Somatostatin-like immunoreactive material in associational ganglion cells of human retina

The retinal ganglion cell is classically viewed as the output cell of the retina, sending a single axon via the optic nerve to synapse in visual relay nuclei of the brain. However, some ganglion cells, termed associational ganglion cells, have axons which do not leave the retina and presumably serve intraretinal communication. Using high-affinity and specific monoclonal antibodies to somatostatin-14 and the avidin-biotin-peroxidase immunohistochemical procedure, somatostatin-immunoreactive associational ganglion cells are specifically stained in human retinas obtained at necropsy. These cells are more numerous in the inferior than the superior retina; they have dendrites which ramify in the inner plexiform layer; and they have sparsely branching axons, many of which can be traced over 1 cm. These axons do not enter the optic nerve. They follow remarkably straight courses at the border of the inner plexiform layer and ganglion cell layer and thereby form a gridwork of fibers covering the entire retinal area. These observations verify the existence of associational ganglion cells in the human and establish somatostatin as a neurotransmitter or neuromodulator candidate for these neurons. The morphology of these cells suggests that they are involved in long-distance interactions within the 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.     

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     

Non-NMDA receptors in frog retina: an immunocytochemical study

Glutamate is one of the main neurotransmitters in the retina. Its effects are mediated by a large number of ionotropic and metabotropic membrane receptors. The distribution of ionotropic AMPA receptor subunits GluR1-4, kainate receptor subunits GluR5-7 and KA2, delta receptors 1-2, as well as the metabotropic receptor mGluR6 were studied in the frog retina. Indirect immunofluorescence was used to localize the different receptor subunits. Results showed that all subunits, with the exception of GluR1 and GluR5, are widely distributed in the retina. They are mainly located in both plexiform layers: the outer (OPL) and the inner one (IPL), where punctate labelling, a sign of synaptic localization, is observed. The metabotropic receptor mGluR6 is localised only in the OPL. The AMPA receptor subunit GluR4 is localised on the glial Müller cells of the retina. The vast majority of the subunits possess specific patterns of labelling that indicate that they are involved with different retinal functions. The significance of the AMPA receptors and involvement of glia in modulation of synaptic transmission are discussed.     

Müller细胞反应性胶质化在急性高眼压致大鼠视网膜损伤中作用

 目的 观察Müller细胞反应性胶质化在急性高眼压(AOH)大鼠视网膜中变化及其抑制对视网膜损伤的影响。方法 建立大鼠AOH青光眼模型,分为正常对照(Ctrl)、AOH和AOH+玻璃体内注射胶质毒素α-氨基己二酸(AAA)后再灌注1、3和5d组,以及单纯AAA和AOH+PBS对照组。TUNEL染色检测细胞凋亡,GFAP免疫荧光染色反应Müller细胞反应性胶质化程度,Thy-1染色标记视网膜神经节细胞(RGCs)。结果 AOH可致大鼠视网膜内丛状层和内核层明显变薄、神经节细胞层内细胞排列紊乱和数量减少,并诱发Müller细胞反应性胶质化(GFAP表达增加)。同时,AAA抑制Müller细胞反应性胶质化可明显缓解AOH所致RGCs丢失和凋亡发生。结论 Müller细胞反应性胶质化参与AOH所致视网膜损伤,抑制其反应性胶质化可能是改善高眼压性青光眼视网膜病变的一种有效治疗方法。     

高血压大鼠视网膜溶酶体酶组织化学研究

目的：探讨溶酶体酶在高血压视网膜网变发生过程中的作用。方法：应用光镜定量酶组织化学方法对ＷＫＹ大鼠和自发性高血压大鼠视网膜原酸性磷酸的分布和活性变化进行定量观察。结果：视网膜各层酸性磷酸酶活性岂强到弱依次是（Ｆ检验，Ｐ〈０．０５）；（１）色素上皮层；（２）视杆维层内节和外网层（两层间活性无显著性差异）；（３）内网层；（４）节细胞层和神经纤维层，（５）外核层和内核层（两层间活性无显著性差异）杆锥层外     

Momordica charantia (bitter melon) attenuates high-fat diet-associated oxidative stress and neuroinflammation

Purpose

Microglia and Müller cells are prominent participants in retinal responses to injury and disease that shape eventual tissue adaptation or damage. This investigation examined how microglia and Müller cells interact with each other following initial microglial activation.

Methods

Mouse Müller cells were cultured alone, or co-cultured with activated or unactivated retinal microglia, and their morphological, molecular, and functional responses were evaluated. Müller cell-feedback signaling to microglia was studied using Müller cell-conditioned media. Corroborative in vivo analyses of retinal microglia-Müller cell interactions in the mouse retina were also performed.

Results

Our results demonstrate that Müller cells exposed to activated microglia, relative to those cultured alone or with unactivated microglia, exhibit marked alterations in cell morphology and gene expression that differed from those seen in chronic gliosis. These Müller cells demonstrated in vitro (1) an upregulation of growth factors such as GDNF and LIF, and provide neuroprotection to photoreceptor cells, (2) increased pro-inflammatory factor production, which in turn increased microglial activation in a positive feedback loop, and (3) upregulated chemokine and adhesion protein expression, which allowed Müller cells to attract and adhere to microglia. In vivo activation of microglia by intravitreal injection of lipopolysaccharide (LPS) also induced increased Müller cell-microglia adhesion, indicating that activated microglia may translocate intraretinally in a radial direction using Müller cell processes as an adhesive scaffold.

Conclusion

Our findings demonstrate that activated microglia are able to influence Müller cells directly, and initiate a program of bidirectional microglia-Müller cell signaling that can mediate adaptive responses within the retina following injury. In the acute aftermath following initial microglia activation, Müller cell responses may serve to augment initial inflammatory responses across retinal lamina and to guide the intraretinal mobilization of migratory microglia using chemotactic cues and adhesive cell contacts. Understanding adaptive microglia-Müller cell interactions in injury responses can help discover therapeutic cellular targets for intervention in retinal disease.