The rabbit retina: a suitable mammalian tissue for obtaining astroglia-free Müller cell cultures

Optimization of a Method to Isolate and Culture Adult Porcine, Rats and Mice Müller Glia in Order to Study Retinal Diseases

Müller cells are the predominant glial elements in the retina, extending vertically across this structure, and they fulfill a wealth support roles that are critical for neurons. Alterations to the behavior and phenotype of Müller glia are often seen in animal models of retinal degeneration and in retinal tissue from patients with a variety of retinal disorders. Thus, elucidating the mechanisms underlying the development of retinal diseases would help better understand the cellular processes involved in such pathological changes. Studies into Müller cell activity in vitro have been hindered by the difficulty in obtaining pure cell populations and the tendency of these cells to rapidly differentiate in culture. Most protocols currently used to isolate Müller glia use neonatal or embryonic tissue but here, we report an optimized protocol that facilitates the reliable and straightforward isolation and culture of Müller cells from adult pigs, rats and mice. The protocol described here provides an efficient method for the rapid isolation of adult mammalian Müller cells, which represents a reliable platform to study therapeutic targets and to test the effects of drugs that might combat retinal diseases.

Uveal melanocytes, ocular pigment epithelium, and Müller cells in culture: in vitro toxicology

Uveal melanocytes and the ocular pigment epithelium are located in the middle and inner layers of the eye. Müller cells (a type of glial cell) are located in the neural retina. Melanocytes, retinal pigment epithelium (RPE), and Müller cells do not participate directly in the detection or transfer of visual information, but they have various functions that support the neural retina and are essential for the maintenance of vision. Methods for the isolation and cultivation of melanocytes, RPE, and Müller cells have been established by us and other investigators. These cultured cells can be used as in vitro model systems for studying the toxicology of visible light, ultraviolet (UV) radiation, drugs, and other potentially toxic agents. Toxic effects on these cells may give rise to altered retinal function and result in impaired vision. Both melanocytes and pigment epithelium contain melanin, which has the ability to bind organic amines and metal ions. This results in the accumulation of these substances in the eye. Melanin may protect cells from chemical stress by binding toxic chemicals; but in chronic exposure, increased and lengthy binding may cause damage to these cells. Two different types of melanin are found in the eye: eumelanin and pheomelanin, which may have photoprotective and phototoxic effects, respectively. Pigment epithelium contains mainly eumelanin, whereas melanocytes contain both eumelanin and pheomelanin. Melanin is an antioxidant and with age, the antioxidant properties may diminish to the point that it may even become a prooxidant. There are also other functions of pigment epithelium and uveal melanocytes not related to melanin and there are also several functions of Muller cells that play a role in the toxicological aspects of the eye. Cultured uveal melanocytes, pigment epithelial cells, and Müller cells can be used to study the toxicology of these cells in vitro.

Continuous observation of multipotential retinal progenitor cells in clonal density culture

All neural cell types in the vertebrate retina, except astrocytes, have been shown to develop from multipotential progenitor cells. It is not known, however, to what extent the progenitor cells are heterogeneous in their developmental potential or to what extent cell-cell interactions versus cell-autonomous factors influence the types of cells they become. To address these issues we developed a clonal-density cell culture system where mouse retinal progenitor cells can survive, divide, and differentiate. We followed the development of clones both by continuous time-lapse video microscopy and by daily microscopic observation. We show that even when cultured at clonal density in a homogeneous general environment, where they cannot contact cells outside their own clone, the retinal progenitor cells vary in proliferative capacity, cell cycle time, and in the cell types that they generate. In addition, we show that under these conditions single progenitor cells can generate both neurons and glia, in which case the neurons almost always develop before glial cells, as is the case in vivo.

Differentiation and maturation of rabbit retinal oligodendrocyte precursor cells in vitro

The differentiation of oligodendrocytes from undifferentiated progenitor cells was studied in cultures obtained from the postnatal rabbit retina. 'Sandwich' cultures were established by turning the coverslips with adhering cells up-side down about 24 h after seeding. As a result O4-positive oligodendrocyte progenitors stop dividing and differentiate. Within 6 days in vitro they form extensive membranous sheets and acquire myelin associated glycoprotein (MAG), proteolipid protein (PLP), and myelin basic protein (MBP). O4-/MBP-positive oligodendrocytes and vimentin-positive/GFAP-negative Müller cells (a kind of modified astrocyte type in the retina), which are also present in these cultures, occupy distinct territories in vitro. When oligodendrocyte precursors were seeded onto a preformed Müller cell feeder layer they prefer to settle on the Müller cell free substrate poly-L-lysine, develop numerous processes but no membranous sheets and fail to acquire detectable amounts of MBP. In addition, culturing Müller cells and oligodendrocytes within the same medium, but without direct contact to each other, oligodendrocyte precursor cells fail to express MBP. The Müller cell factor(s) responsible for this interaction remains to be determined.

Effects of enhanced extracellular ammonia concentration on cultured mammalian retinal glial (Müller) cells

Müller (glial) cells of the neonatal rabbit retina were cultured as confluent monolayers and exposed to enhanced concentrations of ammonia (0.25, 0.5, 1, 3, 7, and 10 mM) in medium for various periods (30 min to 10 d). This caused, in a time- and dose-dependent manner, similar changes in the Müller cells as had previously been described in cultured astrocytes. The most conspicuous events were 1) an increasing size of cell nuclei, 2) an accumulation of phagocytotic vacuoles, and 3) a rearrangement of intermediate filaments. 4) A considerable number of cells died when higher ammonia concentrations were applied for more than 1 h. Simultaneous application of dibutyryl-cyclic adenosine monophosphate (dBcAMP) prevented almost completely both the increase in cell nucleus size and the changes of intermediate filaments, but only partly the early cell death of a subpopulation of cells, and the accumulation of phagocytotic vacuoles. Further changes evoked by enhanced ammonia concentration were 5) an accumulation of lipofuscin-like material ("fatty degeneration") revealed by lipophilic stain, 6) reduced immunoreactivity for cathepsin D, and increased immunoreactivity for 7) glial fibrillary acidic protein, 8) glutamine synthetase, and 9) bcl-2 protooncogene protein. These findings are discussed in respect to the possible underlying pathophysiological mechanisms.

Activation of P2-purinoreceptors triggered Ca2+ release from InsP3-sensitive internal stores in mammalian oligodendrocytes

1. The subcellular characteristics of an ATP-induced elevation of the cytoplasmic free calcium concentration ([Ca2+]i) were studied in cultured cells of the oligodendrocyte lineage obtained from mouse cortex and rabbit retina, as well as in oligodendrocytes from mouse corpus callosum slices, using laser scanning confocal microfluorometry. 2. With the stage- and lineage-specific antibodies O4 and O10, three developmental stages within the oligodendrocyte lineage were distinguished prior to Ca2+ recording. 3. Bath application of 1-100 microM ATP induced a transient increase of [Ca2+]i in late precursors and oligodendrocytes but not in early glial precursor cells from retinal and cortical cultures and from corpus callosum slices. This effect of ATP was observed in Ca(2+)-free extracellular solution, suggesting that the ATP-mediated elevation of [Ca2+]i is due to a Ca2+ liberation from intracellular stores. 4. In both late precursors and oligodendrocytes from retina, the amplitude of ATP-induced [Ca2+]i transients was significantly higher in processes as compared with the soma; in cortical cultures such an uneven response was only observed in oligodendrocytes, while in immature cells responses in soma and processes were of similar amplitude. 5. The rank order of potency for the purine and pyrimidine nucleotides was UTP > or = ATP > ADP >> AMP = adenosine = Me-ATP for retinal oligodendrocytes, and ADP > or = ATP >> UTP = AMP = adenosine = Me-ATP for cortical oligodendrocytes. The response to ATP and related nucleotides was blocked by suramin, indicating the involvement of a P2-purinoreceptor in the ATP-mediated [Ca2+]i response. 6. ATP-induced elevation of the cytosolic Ca2+ concentration was inhibited by incubating cells with thapsigargin (10 microM) and by intracellular administration of heparin (1 microM). These findings indicate that ATP triggers a release of Ca2+ ions from InsP3-sensitive internal stores. 7. The ATP receptors may play a role in neuron-glial signal transfer; ATP is released as neurotransmitter, but also under pathological conditions from damaged cells.

Subcellular heterogeneity of voltage-gated Ca2+ channels in cells of the oligodendrocyte lineage

We studied the distribution of voltage-gated Ca2+ channels in cells of the oligodendrocyte lineage from retinal and cortical cultures. Influx of Ca2+ via voltage-gated channels was activated by membrane depolarization with elevated extracellular K+ concentration ([K+]e) and local, subcellular increases in cytosolic free Ca2+ concentration ([Ca2+]in) could be monitored with a fluometric system connected to a laser scanning confocal microscope. In glial precursor cells from both retina and cortex, small depolarizations (with 10 or 20 mM K+) activated Ca2+ transients in processes indicating the presence of low-voltage-activated Ca2+ channels. Larger depolarizations (with 50 mM K+) additionally activated high-voltage-activated Ca2+ channels in the soma. An uneven distribution of Ca2+ channels was also observed in the mature oligodendrocytes; Ca2+ transients in processes were considerably larger. Recovery of Ca2+ levels after the voltage-induced influx was achieved by the activity of the plasmalemmal Ca2+ pump, while mitochondria played a minor role to restore Ca2+ levels after an influx through voltage-operated channels. During the development of white matter tracts, cells of the oligodendrocyte lineage contact axons to form myelin. Neuronal activity is accompanied by increases in [K+]e; this may lead to Ca2+ changes in the processes and the Ca2+ increases might be a signal for the glial precursor cell to start myelin formation.

Growth factor effects on the proliferation of different retinal glial cells in vitro

Vascularized mammalian retinae contain two distinct neuroglial cells types, radially oriented Müller cells and astrocytes, which are located in the nerve fiber layer. These cell types derive from different precursor cells and proliferate during ontogenesis at distinct schedules. The aim of the present study was to disclose whether growth factors, which are known to interfere with the development of neuroglial cells in the central nervous system, like basic and acidic fibroblast growth factor (aFGF and bFGF), epidermal growth factor (EGF) and platelet-derived growth factor, have similar or distinct effects on the proliferative capacity of retinal astrocytes and Müller cells. These questions were tested by applying growth factors to cultured astrocytes and Müller cells from early postnatal rabbit retina. Proliferating cells were identified by double labeling experiments combining cell type specific markers with bromodeoxyuridine immunocytochemistry and [3H]thymidine incorporation experiments, respectively. In addition, we used the anatomical advantage of the rabbit retina. Its peripheral part is astroglial cell-free. Cultures prepared from this part of the retina (P-cultures) contain Müller cells, microglial cells and neurons, while cultures from the 'central part', the medullary rays (MR) region contain, in addition, astrocytes and oligodendrocytes. Our studies show that Müller cell proliferation is stimulated by EGF in a dose dependent manner, while astrocyte proliferation is stimulated by aFGF and bFGF. The proliferation of O4-positive glial precursor cells is stimulated by aFGF, bFGF and platelet-derived growth factor, but not by EGF. Microglial cells, which are a minor population in these cultures, do not respond to either of these factors.

K(+)-, hypoosmolarity-, and NH4(+)-induced taurine release from cultured rabbit Müller cells: role of Na+ and Cl- ions and relation to cell volume changes

The release of preloaded radiolabeled taurine (TAU) from cultured rabbit Müller cells [14-21 days in vitro (DIV)] was measured before and after treatment with the following stimuli: 1) isoosmotic 65 mM KCl; 2) a medium made hypoosmotic by uncompensated lowering of Na+ by 40-100 mM; and 3) NH4Cl ranging from 0.25 to 5 mM. The same stimuli were tested for their effect on the cell volume by the 3-O-methyl-D-glucose (OMG) uptake method of Kletzien et al. (Anal Biochem 68:537, 1975). Hypoosmotic media and 65 mM KCl stimulated TAU release, and the release was well correlated with the increase of cell volume. The stimulatory effect of 65 mM KCl was abolished by isotonic removal of Cl- or Na+, and omission of either ion markedly enhanced the basal release of TAU. The results are roughly consistent with the characteristics of the swelling-induced TAU release reported for cultured astrocytes and neurons of various CNS regions, and also for freshly isolated, nondissociated retina. Taken together, the results are indicative of a significant role of TAU release from Müller cells, in the osmosensory response of the retina. Ammonium chloride stimulated TAU release in a dose-dependent manner, a significant stimulation being already observed at 0.5 mM, a concentration that is frequently measured in brain during acute hyperammonemia. The effect of NH4Cl was strictly chloride dependent at 0.5-2 mM, but partly Cl- independent at 5 mM. The Kletzien's method did not appear to be well suited for measuring cell volume in the presence of ammonium ions.(ABSTRACT TRUNCATED AT 250 WORDS)

The role of Müller cells in the formation of the blood-retinal barrier

We have compared the ability of Müller cells and astrocytes to induce the formation of barrier properties in blood vessels. Müller cells cultured from the rabbit retina, and astrocytes and meningeal cells cultured from the rat cerebral cortex, were injected into the anterior chamber of the rat eye, where they formed aggregates on the iris. We have examined the barrier properties of the vessels in those aggregates and, for comparison, the barrier properties of vessels in the retina, ciliary processes and iris. Two tracers were perfused intravascularly to test barrier properties. The movement of Evans Blue was assessed by light microscopy, and the movement of horseradish peroxidase by light and electron microscopy. Our results indicate that Müller cells share the ability of astrocytes to induce the formation of barrier properties by vascular endothelial cells, and we suggest that Müller cells play a major role in the formation of barrier properties in retinal vessels.

What do retinal müller (glial) cells do for their neuronal 'small siblings'?

Müller (radial glial) cells are the predominant glia of the vertebrate retina. They arise, together with rod photoreceptor cells, bipolar cells, and a subset of amacrine cells, from common precursor cells during a late proliferative phase. One Müller cell and a species-specific number of such neurons seem to form a columnar unit within the retinal tissue. In contrast, 'extracolumnar neurons' (ganglion cells, cone photoreceptor cells, horizontal cells, and another subset of amacrine cells) are born and start differentiation before most Müller cells are generated. It may be essential for such neurons to develop metabolic capacities sufficient to support their own survival, whereas late-born ('columnar') neurons seem to depend on a nursing function of their 'sisterly' Müller cell. Thus, out of the cell types within a retinal column it is exclusively the Müller cell that possesses the enzymes for glycogen metabolism. We present evidence that Müller cells express functional insulin receptors. Furthermore, isolated Müller cells rapidly hydrolyse glycogen when they are exposed to an elevated extracellular K+ ion concentration, a signal that is involved in the regulation of neuronal-glial metabolic cooperation in the brain. Müller cells are also thought to be essential for rapid and effective retinal K+ homeostasis. We present patch-clamp measurements on Müller cells of various vertebrate species that all demonstrate inwardly rectifying K+ channels; this type of channel is well-suited to mediate spatial buffering currents. A mathematical model is presented that allows estimation of Müller cell-mediated K+ currents. A simulation analysis shows that these currents greatly limit lateral spread of excitation beyond the borders of light-stimulated retinal columns, and thus help to maintain visual acuity.

Functional properties of retinal Müller cells following transplantation to the anterior eye chamber

Two types of glial cells occur in the retina, Müller cells and astrocytes. These cells share several structural features such as extending endfeet onto blood vessels of the retina. Retinal vessels express a tight blood-retinal barrier which is comparable to the blood-brain barrier (BBB) of the CNS. While astrocytes have been implicated in the induction of the BBB, the role of Müller cells in the blood-retinal barrier is unknown. To determine if Müller cells are capable of influencing vascular permeability, we have prepared Müller cells that are free of astrocytes and transplanted them to a peripheral target, the anterior eye chamber. Müller cells were identified 2 weeks to 3 months after injection and were predominantly localized within the connective tissue of the ciliary body. The Müller cells occurred as dense clusters of cells closely associated with ciliary blood vessels. The ciliary vessels adjacent to Müller cells were freely permeable to circulating horseradish peroxidase (HRP), suggesting that Müller cells did not induce tight barrier properties from these leaky peripheral vessels. In contrast, cortical astrocytes injected into the anterior eye chamber preferentially formed a monolayer on the anterior surface of the iris, a region known to contain blood vessels that are impermeable to circulating tracers (e.g., Raviola, Exp Eye Res [Suppl] 25:27, 1977). Müller cells were rarely associated with the iris and the few cells that were present were located deep within the iris stroma rather than on the surface. The behaviour of guinea pig Müller cells transplanted to the anterior eye chamber contrasts sharply with that of cortical astrocytes in terms of: 1) the ocular compartment to which Müller cells migrate; 2) the tissue invasiveness of the cells; and 3) the degree of permeability of blood vessels adjacent to transplanted cells. The results of this study emphasize the functional distinctness of the two types of retinal glia and suggest that Müller cells from guinea pig retina may not be active in modifying the permeability properties of peripheral blood vessels, a function that has been suggested for astrocytes.

Excitatory amino acid receptors in primary cultures of glial cells from the retina

Binding of 3H-L-aspartate to membranes from retinal glial cells in primary culture was characterized. Binding kinetics showed a saturable, reversible binding to three populations of sites with KB = 40, 200, and 1,300 nM. The first two were present at 1 day in vitro (DIV), whereas the latter two were observed at 12 DIV. The possibility of the 40 nM site being neuronal cannot be discarded, since some neurons are present at 1 DIV. In 12 DIV cultures, the presence or absence of sodium determined two different pharmacological patterns, comparable to those described for electrogenic glutamate transport in Müller cells, and QA metabotropic receptors in astrocytes, respectively. Results suggest that, as has been shown for some receptors in nerve tissue, the properties of glial cell receptors undergo age-dependent changes. In turn, this could be related to changes in the function of neurotransmitter substances during development.

Adult rat retinal glia in vitro: effects of in vivo crush-activation on glia proliferation and permissiveness for regenerating retinal ganglion cell axons

The effects of optic nerve crush on adult rat retinal glia activation were studied in vitro. In adult rats the optic nerves were crushed and the corresponding retinae were explained 5 to 7 days later and cultured in vitro. The glial response of retinae with precrushed optic nerves was compared to the glial response of retinae without prior optic nerve crush. As a consequence of crush-axotomy more glial cells migrated out from retinal explants and covered significantly larger areas of the substratum than glia from noncrushed retinae. Migration of immunohistochemically distinguishable Vimentin-positive Müller cells and glial fibrillary acidic protein-positive astrocytes could be observed in both types of cultures. Astrocytes as well as Müller cells incorporated bromodeoxyuridine after explantation. In noncrushed retinal explants Thy 1.1-immunopositive flat cells were much more frequent and the relative proportion of glial cells was much lower than in crush-activated cultures. In a second set of experiments the ability of adult rat retinal glia to support retinal ganglion cell regeneration was examined. Normal retinal explants (without optic nerve crush) which usually do not substantially regenerate axons were cultured on retinal glia from normal and crush-activated explants. Both glia preparations supported axon growth from retinal explants after 3 days in vitro. Neuritic growth was significantly better when retinal explants from normal adult rats were cultured on crush-activated retinal glia as compared to glia derived from noncrushed retinae. It is concluded that activated adult rat retinal glia, unlike adult glia found in other brain regions, support adult rat retinal ganglion cell regeneration in vitro.

Response of Müller cells to growth factors alters with time in culture

We have developed an explant culture technique, using the retinae of newborn guinea pigs, that reliably yields cultures of Müller cells showing uniform morphology and phenotype. Since the guinea pig retina is avascular and lacks astrocytes, Müller cells are the only glial cell-type and the only vimentin-positive population present. Virtually all passaged cells (greater than 98%) contain vimentin-positive intermediate filaments and no glial fibrillary acidic protein (GFAP) has been detected using a range of GFAP antibodies known to label astrocytes in the guinea pig optic nerve. Most vimentin-positive cells were also labeled with an antibody to carbonic anhydrase II, an enzyme which in the retina is specific for Müller cells. Proliferating Müller cells were identified within the inner nuclear layer of retinal fragments as early as 2 days in culture using bromodeoxyuridine (BrdU) and vimentin double labeling. Cultured Müller cells change their growth characteristics with successive passaging. The length of the cell cycle increases from 25.4 h for cells at first passage, to 66.7 h for cells at fourth passage. Altered responses to mitogens were also observed with passaging. First-passage cultures responded to basic fibroblast growth factor (bFGF) but not to several other factors tested including interleukin-2 (IL-2). In contrast, older cultures were highly responsive to IL-2 but showed a minimal response to bFGF. The altered responsiveness to mitogens observed in vitro may be relevant to changes in growth control of Müller cells in the developing and mature retina. The guinea pig retina provides an ideal mammalian tissue for generating Müller cell cultures that are free of astrocytes, endothelial cells, and pericytes, the most frequent contaminants of retinal glial cultures. The monolayers obtained show a high degree of homogeneity and are well suited for studies of Müller cell function.

In vitro differentiation of human retinoblastoma cells into neuronal phenotypes

In order to characterize the cell type(s) of origin of human retinoblastoma cells by immunophenotyping, primary cells from seven retinoblastomas and of the corresponding cell lines (RBL lines), as well as four retinoblastoma (RB) lines established by other groups, were compared with rat and human retina cells, and with the adenovirus E1A-transformed human retinoblast cell line HER-Xho1-CC2. Analyses using monoclonal antibodies (Mabs) RB13-2 and RB21-7, originally raised against prenatal rat brain cells and recognizing neural cell surface antigens expressed in a developmental-stage-dependent manner, and three cell-type-specific Mabs (Q211, M501, Mab directed against vimentin) developed by other groups, gave the following results: (i) Retinoblastomas consist of cells expressing differentiated neuronal phenotypes during cultivation in vitro; (ii) All of the newly established RBL lines express neuronal phenotypes; and (iii) Cell lines such as Y79, which have been propagated in vitro for extended periods, do not express antigens specific for the neuronal pathway and cannot, therefore, be considered phenotypically representative of retinoblastoma cells.

Rabbit retinal Müller cells in cell culture show gap and tight junctions which they do not express in situ

Retinae of early postnatal rabbits were enzymatically dissociated and explanted in a culture system. The prospective myelinated region was discarded in order to avoid the presence of astrocytic or mesenchymal cells. After about 14 days in vitro (DIV), outgrowing glial (Müller) cells formed what light optically appeared to be confluent monolayers but by electron microscopy was shown to consist of flat epithelioid cells which overlapped considerably by extension of cytoplasmic tongues. Applying the freeze-fracture technique, apposed membranes of these cells were demonstrated to express infrequently but consistently both gap and tight junctions. This kind of junctions has never been observed on the membrane of rabbit Müller cells in situ. In comparison with Müller cell membranes in situ, the density of intramembrane particles was considerably reduced. Orthogonal arrays of particles which are characteristic elements of Müller cells in situ were not detected. Our results suggest that in homogeneous cell culture, Müller cells form some kind of epithelium-like specialized intercellular junctions. This situation resembles that of closely related glial cell types which form homogeneous layers in situ as e.g. retinal pigment epithelium cells expressing tight junctions, and marginal astrocytes being coupled by extensive gap junctions.