Developmental and experimental changes in retinal glia cells: cell interactions and control of phenotype expression and stability

Jak/Stat signaling regulates the proliferation and neurogenic potential of Müller glia-derived progenitor cells in the avian retina

Müller glia are capable of de-differentiating and proliferating to become Müller glia-derived progenitor cells (MGPCs) with the ability to regenerate retinal neurons. One of the cell-signaling pathways that drives the reprogramming of Müller glia into MGPCs in the zebrafish retina is the Jak/Stat-pathway. However, nothing is known about the influence of Jak/Stat-signaling during the formation of MGPCs in the retinas of warm-blooded vertebrates. Accordingly, we examined whether Jak/Stat-signaling influences the formation of MGPCs and differentiation of progeny in the avian retina. We found that Jak/Stat-signaling is activated in Müller glia in response to NMDA-induced retinal damage or by CNTF or FGF2 in the absence of retinal damage. Inhibition of gp130, Jak2, or Stat3 suppressed the formation of proliferating MGPCs in NMDA-damaged and FGF2-treated retinas. Additionally, CNTF combined with FGF2 enhanced the formation of proliferating MGPCs in the absence of retinal damage. In contrast to the zebrafish model, where activation of gp130/Jak/Stat is sufficient to drive neural regeneration from MGPCs, signaling through gp130 inhibits the neurogenic potential of MGPCs and promotes glial differentiation. We conclude that gp130/Jak/Stat-signaling plays an important role in the network of pathways that drives the formation of proliferating MGPCs; however, this pathway inhibits the neural differentiation of the progeny.

Glucocorticoid receptors in the retina, Müller glia and the formation of Müller glia-derived progenitors

Identification of the signaling pathways that influence the reprogramming of Müller glia into neurogenic retinal progenitors is key to harnessing the potential of these cells to regenerate the retina. Glucocorticoid receptor (GCR) signaling is commonly associated with anti-inflammatory responses and GCR agonists are widely used to treat inflammatory diseases of the eye, even though the cellular targets and mechanisms of action in the retina are not well understood. We find that signaling through GCR has a significant impact upon the ability of Müller glia to become proliferating Müller glia-derived progenitor cells (MGPCs). The primary amino acid sequence and pattern of GCR expression in the retina is highly conserved across vertebrate species, including chickens, mice, guinea pigs, dogs and humans. In all of these species we find GCR expressed by the Müller glia. In the chick retina, we find that GCR is expressed by progenitors in the circumferential marginal zone (CMZ) and is upregulated by Müller glia in acutely damaged retinas. Activation of GCR signaling inhibits the formation of MGPCs and antagonizes FGF2/MAPK signaling in the Müller glia. By contrast, we find that inhibition of GCR signaling stimulates the formation of proliferating MGPCs in damaged retinas, and enhances the neuronal differentiation while diminishing glial differentiation. Given the conserved expression pattern of GCR in different vertebrate retinas, we propose that the functions and mechanisms of GCR signaling are highly conserved and are mediated through the Müller glia. We conclude that GCR signaling directly inhibits the formation of MGPCs, at least in part, by interfering with FGF2/MAPK signaling.

Effect of Rds abundance on cone outer segment morphogenesis, photoreceptor gene expression, and outer limiting membrane integrity

We examined the molecular, structural, and functional consequences on cone photoreceptors of the neural retinal leucine zipper knockout (Nrl(-/-)) mice when only one allele of retinal degeneration slow (Rds) is present (Rds(+/-)/Nrl(-/-)). Quantitative RT-PCR and immunoblot analysis were used to assess the expression levels of several phototransduction genes; electroretinography was used to assess quantitatively the retinal responsiveness to light; and immunohistochemistry and ultrastructural analysis were used to examine retinal protein distribution and morphology, respectively. In Rds/Nrl double-null mice, S-cones form dysmorphic outer segments that lack lamellae and fail to associate properly with the cone matrix sheath and the outer limiting membrane. In Rds(+/-)/Nrl(-/-) mice, cones form oversized and disorganized outer segment lamellae; although outer limiting membrane associations are maintained, normal interactions with cone matrix sheaths are not, and photoreceptor rosette formation is observed. These retinas produce significantly higher photopic a-wave and b-wave amplitudes than do those of Rds(-/-)/Nrl(-/-) mice, and the levels of several cone phototransduction genes are significantly increased coincidently with the presence of Rds and partial lamellae formation. Thus, as in rod photoreceptors, expression of only one Rds allele is unable to support normal outer segment morphogenesis in cones. However, cone lamellae assembly, albeit disorganized, concomitantly permits outer limiting membrane association, and this appears to be linked to photoreceptor rosette formation in the rodless (cone-only) Nrl(-/-) retina. In addition, photoreceptor gene expression alterations occur in parallel with changes in Rds levels.

Cytoskeletal and cell contact control of the glucocorticoid pathway

The cytoskeleton is a dynamic network that undergoes restructuring during a variety of cellular events including cell contact formation, cell invasion and the mitotic phase of the cell cycle. Here, we review the contribution of the cytoskeletal network to the inductive activity of glucocorticoids by focusing on the hormonal control of glutamine synthetase in the chick neural retina. Depolymerization of the cytoskeleton in cells of the intact retinal tissue inhibits the hormonal induction of glutamine synthetase, but does not alter the cellular amount of the glucocorticoid-receptor protein or the ability of the receptor molecules to translocate into the nucleus. Inhibition of glutamine synthetase induction occurs via a mechanism that involves elevation of c-Jun protein accumulation and repression of glucocorticoid-receptor transcriptional activity. Unlike growth factors and other c-Jun inducing stimuli that control the transcription of the c-Jun gene, depolymerization of the cytoskeleton elevates c-Jun accumulation by upregulating the translation of the c-Jun transcript. We postulate that the cytoskeletal-dependent increase in c-Jun accumulation is involved in cell contact control of both cell proliferation and transcriptional activity of the glucocorticoid-receptor protein.

Expression of spermidine/spermine N(1)-acetyltransferase in the Müller glial cells of the developing chick retina

A number of genes have been found to be asymmetrically expressed along the three axes of the retina: central-peripheral, dorsal-ventral, temporal-nasal. Some of the asymmetrically expressed genes have been shown to play a role in the establishment of boundaries required for guiding retinal axons to their correct targets in the brain. Asymmetric expression during development can also be a consequence of the different rates of differentiation along the three retinal axes. The authors have used a differential-display-PCR approach to identify genes asymmetrically expressed along the dorsal-ventral axis in the chick retina. One of the selected genes, spermidine/spermine N(1)-acetyltransferase (SSAT), was preferentially expressed in the dorsal-temporal quadrant of the developing retina. There was a sharp increase in retinal SSAT mRNA levels during the transition stage from proliferation (E7) to early differentiation (E10). SSAT mRNA was found in Müller glial cells and its distribution pattern in these cells closely followed the three differentiation axes of the developing retina, with a central-dorsal-temporal preference. The elevated levels of SSAT mRNA in Müller glial cells may reflect a requirement for acetylated spermine/spermidine or putrescine in the differentiating neuronal cells of the retina.

Shape diversity among chick retina Müller cells and their postnatal differentiation

It is currently believed that in each vertebrate species Müller cells in the central retina constitutes a fairly homogeneous population from the morphologic point of view and that particularly the chick Müller cell attains full shape differentiation at prenatal stages. However, in this study of the chick retina, from day 1 to day 55 of life, we show that there is a large variety of Müller cell shapes and that many of them complete shape differentiation postnatally. We used a cell dissociation method that preserves the whole shape of the Müller cells. Unstained living and unstained fixed cells were studied by phase-contrast microscopy, and fixed cells immunostained for intermediate filaments of the cytoskeleton were studied by fluorescence microscopy. Our results show that (1) Müller cell shapes vary in the origination of the hair of vitread processes, in the shape of the ventricular (outer or apical) process, in the presence or absence of an accessory process, as well as in the number and shape of processes leaving from the ventricular process at the level of the outer nuclear and outer plexiform layers (ONL/OPL); (2) during the first month of life, many Müller cells differentiate the portion of the ventricular process that traverses the ONL, most Müller cells differentiate the ONL/OPL processes, and all Müller cells differentiate the thin short lateral processes leaving from the vitread hair processes at the level of the inner plexiform layer (IPL). The number of cells differing in the shape of the ventricular process and that of cells with and without accessory process were estimated. The spatial relationship between the outer portion of the ventricular process of the Müller cell and the photoreceptor cells was also studied. Our results show that the branching of the ventricular process and the refinement of Müller cell shape is achieved without apparent participation of growth cones. We give a schematic view of how the branching of the ventricular process might take place and propose the size increase of photoreceptor soma as a factor responsible for this branching.

Distribution of the integrin beta 1 subunit on radial cells in the embryonic and adult avian retina

The distribution of the beta1 integrin subunit was investigated in the developing and adult chick retina at the light and electron microscopic levels, using two different monoclonal antibodies. Western blotting revealed a single band with a molecular weight of approximately 130 kDa in the retina and in a number of other tissues, indicating the specificity of the antibodies. In the retina, immunoreactivity was detected on radial cells spanning the entire width between the pigment epithelium and the vitreal border. These cells were undifferentiated neuroepithelial cells at early stages and radial Müller glial cells at later stages of development. At all stages, the beta1 subunit was concentrated at the vitreal border of the retina around the inner limiting membrane. Mechanical isolation of the inner limiting membrane, as well as immunoelectron microscopy, demonstrated that this immunoreactivity was due to a concentration of the beta1 subunit in the endfeet of neuroepithelial and Müller glial cells. Injection of collagenase into the vitreous of live embryos, a procedure that selectively removes the inner limiting membrane, but does not proteolytically degrade the integrin protein, resulted in a redistribution of the integrin immunoreactivity, demonstrating that the integrity of the basal lamina is required for the maintenance of the concentration of the beta1 subunit in the endfeet. These results suggest a role for the beta1 subunit-containing integrin heterodimers in the adhesion of neuroepithelial and Müller glial cells to extracellular matrix components of the inner limiting membrane, possibly stabilizing the radial morphology of these cells.

Regulation of the spatiotemporal pattern of expression of the glutamine synthetase gene

Glutamine synthetase, the enzyme that catalyzes the ATP-dependent conversion of glutamate and ammonia into glutamine, is expressed in a tissue-specific and developmentally controlled manner. The first part of this review focuses on its spatiotemporal pattern of expression, the factors that regulate its levels under (patho)physiological conditions, and its role in glutamine, glutamate, and ammonia metabolism in mammals. Glutamine synthetase protein stability is more than 10-fold reduced by its product glutamine and by covalent modifications. During late fetal development, translational efficiency increases more than 10-fold. Glutamine synthetase mRNA stability is negatively affected by cAMP, whereas glucocorticoids, growth hormone, insulin (all positive), and cAMP (negative) regulate its rate of transcription. The signal transduction pathways by which these factors may regulate the expression of glutamine synthetase are briefly discussed. The second part of the review focuses on the evolution, structure, and transcriptional regulation of the glutamine synthetase gene in rat and chicken. Two enhancers (at -6.5 and -2.5 kb) were identified in the upstream region and two enhancers (between +156 and +857 bp) in the first intron of the rat glutamine synthetase gene. In addition, sequence analysis suggests a regulatory role for regions in the 3' untranslated region of the gene. The immediate-upstream region of the chicken glutamine synthetase gene is responsible for its cell-specific expression, whereas the glucocorticoid-induced developmental appearance in the neural retina is governed by its far-upstream region.

Different cell surface areas of polarized radial glia having opposite effects on axonal outgrowth

During neuronal development neurites are likely to be specifically guided to their targets. Within the chicken retina, ganglion cell axons are extended exclusively into the optic fibre layer, but not into the outer retina. We investigated, whether radial glial cells having endfeet at the optic fibre layer and somata in the outer retina, might be involved in neurite guidance. In order to analyse distinct cell surface areas, endfeet and somata of these glial cells were purified. Glial endfeet were isolated from flat mounted retina by a specific detachment procedure. Glial somata were purified by negative selection using a monoclonal antibody/complement mediated cytolysis of all non-glial cells. Retinal tissue strips were explanted either onto pure glial endfeet or onto glial somata. As revealed by scanning and fluorescence microscopy, essentially no ganglion cell axons were evident on glial somata, whereas axonal outgrowth was abundant on glial endfeet. However, when glial somata were heat treated and employed thereafter as the substratum, axon extension was significantly increased. Time-lapse video recording studies indicated that purified cell membranes of glial somata but not of endfeet induced collapse of growth cones. Collapsing activity was destroyed by heat treatment of glial membranes. The collapsing activity of retinal glia was found to be specific for retinal ganglion cell neurites, because growth cones from dorsal root ganglia remained unaffected. Employing four different kinase inhibitors revealed that the investigated protein kinase types were unlikely to be involved in the collapse reaction. The data show for the first time that radial glial cells are functionally polarized having permissive endfeet and inhibitory somata with regard to outgrowing axons. This finding underscores the pivotal role of radial glia in structuring developing nervous systems.

Cloning, characterization and developmental expression of alpha2,8 sialyltransferase (GD3 synthase, ST8Sia I) gene in chick brain and retina

GD3 and GM2 synthases act on ganglioside GM3 at the branching point of the pathway of synthesis of gangliosides in which the "a", "b" and "c" families are produced. The relative activities of these enzymes are important for regulating the ganglioside composition of a given tissue. In the present work, we report the cloning and characterization of a chick GD3 synthase cDNA. The cloned cDNA directed the synthesis of a functionally active enzyme in transiently transfected CHO-K1 cells and was highly homologous to mammalian GD3 synthases. In Northern blot experiments the cDNA detected a single specific GD3 synthase mRNA of about 9.0 kb both in the chicken brain and retina. The abundance of the specific mRNA transcript declined steadily from E7-E9 to very low values around PN2. The levels of enzyme activities measured at the same developmental stages roughly followed the changes of specific mRNA levels in both tissues. In situ hybridization of embryonic neural retina cells in culture showed that both glial- and neuron-like cells expressed the specific GD3 synthase mRNA, although with different intensities. Results indicate that transcription and/or stability of the specific GD3 synthase mRNA constitute a level of control of the expression of GD3 synthase and indirectly of the ganglioside composition in the developing chicken central nervous system (CNS).

Modification of glutamine synthetase expression by mammalian Müller (glial) cells in retinal organ cultures

One of the key enzymes in glial-neuronal transmitter recycling is glutamine synthetase (GS). In the retina, GS is exclusively expressed by glial (Müller) cells where it serves to convert neuron-released active transmitter substances (glutamate and GABA) into glutamine. Experiments on avian retinae have shown that GS expression is developmentally regulated by glucocorticoid hormones and, to a lesser extent, by a non-hormonal control mechanism(s). Much less is known about GS regulation in mammalian retinae, although either increases or decreases of GS immunoreactivity have been observed in Müller cells in different forms of retinal pathologies. We studied GS expression in postnatal rabbit retinae both in vivo and explanted as wholemounts in vitro, using immunocytochemistry and Western immunoblotting. GS expression was detectable in vivo from the fourth postnatal day, and increased rapidly within the first weeks of life. Levels were lower in vitro than in vivo by an order of magnitude, and could be significantly stimulated (> 60-110%) in vitro by application of hydrocortisone, conditioned medium from cultured retinal pigment epithelium and glutamate or ammonia, but not GABA. It is concluded that GS expression in mammalian Müller cells is dependent on systemic control by glucocorticoid hormones, as observed in birds, but environmental (activity-dependent) factors may play a more important role in mammals.

Contribution of glial metabolism to neuronal damage caused by partial inhibition of energy metabolism in retina

Glial cells are relatively resistant to energy impairment, although little is known of the extent to which glial metabolism is affected during partial energy impairment and how this influences neurons. Fluorocitrate has been shown to be a glial specific metabolic inhibitor. Its selective effect on chick retinal Müller cells was verified by measuring incorporation of radiolabel from 3H-acetate and U-14C-glucose into glutamate and glutamine following exposure of isolated embryonic day 15-18 chick retina to 20 microm fluorocitrate. Fluorocitrate significantly reduced the incorporation of radiolabel from acetate and glucose into glutamine, with less effect on incorporation of label from acetate into glutamate and no reduction of label from glucose into glutamate. The relative specific activity (RSA; ratio of glutamine to glutamate) increased between embryonic day 15 and 18 consistent with the increase in glutamine synthetase activity that occurs in Müller cells at this time in chick retinal development. As with previous findings, mild energy stress produced by inhibiting glycolysis with the general inhibitor iodoacetate (IOA) for up to 45 min, caused acute neuronal damage that was predominately NMDA receptor mediated and occurred in the absence of a net efflux of excitatory amino acids. Acute NMDA-mediated toxicity in this preparation is characterized by the selective damage to amacrine and ganglion cells and quantitatively, by GABA release into the medium. When IOA was combined with fluorocitrate, acute toxicity was potentiated and temporally accelerated. Acute damage was first noted at 15 min, occurred throughout all retinal layers and was accompanied by an overflow of excitatory amino acids at 30 and 45 min. Blocking NMDA receptors with MK-801 during IOA plus fluorocitrate exposure attenuated the rise in excitatory amino acids and prevented the swelling in neuronal, but not Müller cells. Following incorporation of radiolabel from acetate and glucose into glutamate and glutamine after different times of exposure to IOA showed that while the effects of incorporation of label from glucose were immediate, glutamine synthesis from acetate was preserved for a longer period of time. These findings suggest that during a partial energy impairment, neuronal metabolism is affected to a greater extent than is glial metabolism. Glial cells may play a protective role in this situation, and can delay the onset of acute neuronal damage.

The bovine guanylate cyclase GC-E gene and 5' flanking region

The gene encoding the bovine guanylate cyclase isoform E (GC-E) was isolated as a single 18 kb genomic clone and shown to have 20 exons and 19 introns. Comparison of the structure of the GC-E gene with structures of other membrane guanylate cyclase genes indicates that the GC-E is most closely related to the subfamily of sensory guanylate cyclases. Comparison of the GC-E structure with that of the more distantly related guanylate cyclase isoform A (GC-A) gene shows the most divergence in the extracellular and C-terminal regions, but general conservation of introns and exons in the intracellular kinase-like and catalytic domains. RT-PCR from several bovine tissues shows that GC-E is expressed only in the retina. Consistent with this pattern of expression, elements for the retinal-specific transcription factors RET-1, RET-2 and Talpha-1 are located in the 5' flanking promoter region.

Steroid hormone receptors activate transcription in glial cells of intact retina but not in primary cultures of retinal glial cells

We have compared the steroid responsiveness of Müller glial cells of intact embryonic chicken retina with that of primary cultures derived from Müller glia. Appropriately constructed fusion genes were found to be highly glucocorticoid inducible after their cotransfection with an expression vector encoding the human glucocorticoid receptor (GR) into intact embryonic d-10 (E10) or E5.5 retina. Dramatically attenuated inductions were obtained after contransfection of Müller cell primary cultures. The progesterone receptor (PR) was also demonstrated to function in intact retina, but not in Müller cell primary cultures. An immunochemical assay was utilized to confirm that a glucocorticoid-responsive, beta-galactosidase-encoding fusion gene was specifically induced in Müller cells after its transfection into intact retina. Thus, in contrast to Müller cells in intact retina, Müller cells in primary culture have lost the capacity to achieve transcriptional activation by steroid receptors. We postulate that coordinate expression of the GR, and other more general factors required for steroid inducibility, is lost by dispersion and primary culture of retinal Müller glial cells.

Hormonal and non-hormonal regulation of glutamine synthetase in the developing neural retina

Two isoforms of the glucocorticoid receptor, with apparent molecular mass of 90 and 95 kDa, are expressed in embryonic chicken neural retina. The 95-kDa receptor represents a hyperphosphorylated form of the 90-kDa receptor. Activation of the glucocorticoid receptor by cortisol results in a dose-dependent increase in receptor phosphorylation, translocation of receptor molecules into the nucleus and a decline in the total amount of the receptor. Activation of the glucocorticoid receptor can also be observed in the developing retinal tissue in ovo. At late embryonic ages, when the systemic level of glucocorticoids increases, a substantial quantity of receptor molecules becomes translocated into the nucleus, the relative level of the 95-kDa isoform increases, and the total amount of receptor declines. Activation of the receptor molecules in ovo correlates directly with an increase in transcription of the glucocorticoid-inducible gene, glutamine synthetase. The close correlation between the increase in systemic glucocorticoids, activation of glucocorticoid receptor molecules and induction of glutamine synthetase gene transcription suggests that glucocorticoids are directly involved in the developmental control of glutamine synthetase expression. Long-term organ culturing of embryonic retinal tissue in the absence of hormone results in an increase in glutamine synthetase expression. This increase, which is only 5 to 10% of that observed in ovo, is not mediated by activated receptor molecules and represents a mechanism for non-hormonal regulation of glutamine synthetase.

A transcriptional enhancer of the glutamine synthetase gene that is selective for retinal Müller glial cells

This article demonstrates that the chicken glutamine synthetase (GS) promoter contains cis-acting elements that direct transcription to retinal Müller glial cells. The transient assay system developed to identify these elements involved electroporation of intact retinal tissue with GS-beta-galactosidase fusion genes followed by preparation of primary cultures and histochemical assay of cells expressing beta-galactosidase. Plasmids containing beta-galactosidase under transcriptional control by two different viral promoters are expressed primarily in neuronal cells after transfection of intact embryonic d 12 retina. In sharp contrast, expression is primarily in Müller glia after transfection with a GS-beta-galactosidase fusion gene. Although GS is glucocorticoid inducible, steroid hormone is not required to achieve Müller cell-selective expression of the GS-beta-galactosidase fusion gene. Deletion studies indicate that multiple cis-acting elements located between nucleotides-436 and -61 relative to the GS transcription start site contribute to produce Müller cell selectivity. Moreover, these upstream elements enhance expression of a heterologous promoter in Müller cells not neurons. These results indicate that an enhancer located between 61 and 436 nucleotides upstream of the transcription start site contributes to Müller cell-selective expression of the GS gene in the retina.

Protein tyrosine phosphatases expressed in developing brain and retinal Müller glia

Regulation of protein function through tyrosine phosphorylation is critical to many developmental processes involving cell-cell communication. A number of protein tyrosine phosphatases (PTPs) have been identified in the early postnatal and mature central nervous system (CNS), but the PTPs expressed during its development have not been well characterized. Using a polymerase chain reaction with degenerate primers, we analyzed PTPs expressed in fetal (E18) rat brain and Müller glia cultures from embryonic chick retina, two systems in which cell-to-cell contacts are numerous. Fetal rat brain expressed four known receptor-like PTPs (PTP delta, LAR, LAR-PTP2, LRP (PTP alpha)) and the non-receptor phosphatase PTP1B. Müller glia exhibited a distinct but overlapping pattern of expression: four known receptor PTPs (PTP alpha, PTP gamma, PTP delta, PTP zeta) and PTP1B. In addition, two novel PTPs, termed MG-PTP1 and 2 (Müller glia PTP 1 and 2) were identified in Müller glia cDNA. MG-PTP1 was related to, but distinct from PTP delta, while MG-PTP2 was related to, but distinct from the cytosolic T-cell phosphatase. These results demonstrate that a distinct but overlapping set of PTPs is expressed in the developing brain and retinal Müller glia, including two novel PTPs that may participate in neural cell communication.

Selective regeneration of photoreceptors in goldfish retina

Previous work has shown that the neural retina in adult goldfish can regenerate. Following retinal damage elicited by surgical or cytotoxic lesions, missing neurons are replaced by foci of proliferating neuroepithelial cells, which previous studies have suggested are derived from rod precursors. In the intact retina, rod precursors proliferate but produce only new rods. The regenerative responses observed previously have involved replacement of neurons in all retinal layers; selective regeneration of specific neuronal types (except for rod photoreceptors) has not been reported. In the experiments described here, we specifically destroyed either cones alone or cones and rods with an argon laser, and we found that both types of photoreceptors regenerated within a few weeks. The amount of cone regeneration varied in proportion to the degree of rod loss. This is the first demonstration of selective regeneration of a specific class of neuron (i.e., cones) in a region of central nervous tissue where developmental production of that class of neuron has ceased. Selective regeneration may be limited to photoreceptors, however, because when dopaminergic neurons in the inner retina were ablated with intraocular injections of 6-hydroxydopamine, in combination with laser lesions that destroyed photoreceptors, the dopaminergic neurons did not regenerate, but the photoreceptors did. These data support previous studies which showed that substantial cell loss is required to trigger regeneration of inner retinal neurons, including dopaminergic neurons. New observations here bring into question the presumption that rod precursors are the only source of neuronal progenitors during the regenerative response. Finally, a model is presented which suggests a possible mechanism for regulating the phenotypic fate of retinal progenitor cells during retinal regeneration.

Developmental changes in the expression and compartmentalization of the glucocorticoid receptor in embryonic retina

Inducibility by glucocorticoids of the glutamine synthetase gene in chicken embryo retina and the transcriptional activity of the glucocorticoid receptor (GR) greatly increase between embryonic days 6 and 10 (E6, E10), although the level of GR does not markedly change during that time. This apparent discrepancy was investigated by examining the pattern of GR expression in undifferentiated E6 retina and in E10 retina, which consists mostly of differentiated cells. Two GR isoforms, 90 and 95 kDa, were found to be expressed at both of these ages at a similar total level but in different proportions: in E6 retina the level of the 90-kDa isoform was higher, whereas in E10 retina the 95-kDa receptor was higher. However, following treatment of the retinas with cortisol, the 95-kDa isoform became the predominant receptor at both ages. Immunohistochemical analysis revealed that the cellular localization of GR markedly changed in the course of development: in the undifferentiated E6 retina GR was expressed in virtually all cells, whereas in the more differentiated E10 and E12 retina, GR was detected only in Müller glia cells. The latter represent approximately 20% of the cells in this tissue and are the only cells in which glucocorticoid hormone induces the glutamine synthetase gene. We suggest that the compartmentalization of GR in Müller glia is a major aspect of the mechanism that modulates receptor activity during retina development and results in the temporal increase in the inducibility of glutamine synthetase and its specific localization in Müller glia cells.

A developmentally regulated basic-leucine zipper-like gene and its expression in embryonic retina and lens

Transcriptional regulators play important roles in the control of key developmental events. We have identified sw3-3, a likely candidate for such a function, in tissues of the eye and other neural organs. It encodes a basic-leucine zipper-like protein, in which two leucine zipper motifs flank a basic domain. The latter contains helix-disturbing amino acids such as glycine and proline, at positions occupied by conserved asparagine and alanine residues (respectively) in "conventional" basic-leucine zipper proteins. sw3-3 is widely expressed at early embryonic stages in the lens, retina, and other neural tissues and is down-regulated thereafter with a spatial and temporal pattern that correlates with the cessation of mitotic activity and the onset of cell migration and differentiation.

Induction of c-fos by excitatory amino acids in developing chick retina is affected by changes in cellular interactions

Cell contact is important for normal maturation of chicken retinal Müller cells. In order to gain a better understanding as to how this occurs, we examined the ability of retinal cells with altered cell contacts to respond to an environmental stimulus. The response of Müller cells cultured under conditions which alter cell contacts was measured by activating intracellular signaling systems leading to induction of the early-inducible gene c-fos. Chicken retinal cells were cultured as explants, reaggregates, and monolayers and exposed to extracellular stimuli in the form of the excitatory amino acids D,L-alpha aminoadipic acid (AAA) and N-methyl-D,L-aspartic acid (NMDA). Each culture was exposed to 1.25 mM AAA, 2.5 mM AAA, 50 microM NMDA, or 100 microM NMDA. Toxicity was assessed histologically and by immunocytochemical labeling of Müller cells after 2 days of exposure. Activation of c-fos was determined by Western blot analysis for Fos protein after 30, 60, and 120 minutes of exposure. Exposure to AAA led to a loss of Müller cells in explant and reaggregate cultures; however, Müller cells in monolayer culture were not susceptible to AAA at either dose. NMDA was toxic to a specific population of neurons under all three culture conditions. Fos protein expression paralleled the histologic findings. Fos protein was significantly elevated after exposure to either dose of AAA in explant and reaggregate cultures but not in monolayer cultures.(ABSTRACT TRUNCATED AT 250 WORDS)

Retinal FABP principally localizes to neurons and not to glial cells

The presence of fatty acid-binding protein (FABP) in the embryonic chick retina may be linked to the demand for polyunsaturated fatty acids in this developing neural tissue. There is a decline in the overall level of FABP as the retina matures, suggesting a role for FABP in cellular differentiation. However, this pattern is not present in the chick brain, indicating a unique function for FABP in the retina. Immunohistochemical staining of paraffin sections of chick retina from embryonic day 21 revealed immunopositive photoreceptor inner segments, outer nuclear layer, 'radial processes' in the inner nuclear layer, a subpopulation of cells in the ganglion cell layer, and inner limiting membrane. This pattern suggested that FABP positive cells were photoreceptors, Müller (glial) cells, and possibly ganglion cells. Staining of sections for glutamine synthetase, an enzyme specific for Müller cells, was similar but not identical to the pattern observed with FABP; thus identification of these cells as FABP-positive was not conclusive. However, in retinal cells dissociated from day E14 embryos and cultured for one week, staining with FABP was more intense in the neurons than in the 'flat' cells (presumed to be derived from the Müller cells). Retinal FABP thus appears to be localized predominantly in neurons, and may serve to sequester fatty acids in preparation for neurite outgrowth as the retinal cells differentiate.

Protein kinase A activation of glucocorticoid-mediated signaling in the developing retina

This report establishes that increasing the activity of cyclic AMP-dependent protein kinase (protein kinase A; PKA) potentiates glucocorticoid-mediated signaling in embryonic day 5.5 (E5.5) chicken retina. Expression of a glutamine synthetase-chloramphenicol acetyltransferase (CAT) fusion gene is not induced by treatment with glucocorticoid hormone in transfected E5.5 retina. However, treatment of the retina with forskolin, an activator of adenyl cyclase, or cotransfection with an expression vector encoding PKA is sufficient to render the fusion gene hormonally responsive. Similar results are obtained after forskolin treatment of E5.5 retina that have been transfected with a plasmid that contains the CAT reporter gene under transcriptional control by the thymidine kinase promoter and a 46-nucleotide enhancer with two glucocorticoid response elements (GREs). In contrast, forskolin augments but is not required to achieve glucocorticoid-inducible CAT gene expression in E5.5 retina transfected with a plasmid that contains the reporter driven by a minimal promoter with six juxtaposed GREs. Based on these results, we postulate that E5.5 retina contain glucocorticoid receptors whose signal transduction properties are enhanced by PKA. Unlike the transiently expressed glutamine synthetase fusion gene, however, activation of PKA does not render the endogenous glutamine synthetase gene glucocorticoid-inducible. Thus, its expression appears to be subject to an additional level of control in the developing retina.

5A11 antigen is a cell recognition molecule which is involved in neuronal-glial interactions in avian neural retina

In continuing efforts to identify cell-surface molecules involved in cell-cell interactions in the developing avian retina, we identified a monoclonal antibody, the 5A11 antibody, which possessed the ability to interfere with contact-dependent glial cell maturation in vitro. We sought to determine the molecular and biochemical identity of the glycoprotein recognized by this antibody, and using additional criteria, establish whether the 5A11 antigen is indeed a cell-recognition molecule in the developing retina. Immunohistochemical analyses demonstrate that in the hatchling chick retina and in live cultures of embryonic retina cells, the 5A11 antigen is predominantly associated with Müller glial cells whereas little is observed on neuronal elements. Microsequencing of the major component isolated by immunoaffinity chromatography identifies the HT7 antigen (Seulberger et al.: EMBO Journal 9:2151-2158, 1990), a unique member of the immunoglobulin super gene family (IGSF), as a homologous if not identical protein to the 5A11 antigen. The HT7 antibody, furthermore, recognizes affinity purified 5A11 antigen, and both the HT7 antibody and additional probes generated against the 5A11 antigen recognize a major polypeptide of 45.5 kDa and a minor band of 69 kDa on Western blots of membrane preparations from neural retina. To verify that the 5A11 antigen mediates cell-cell recognition events in the developing neural retina, we examined the consequences of adding antibody to monolayer cultures of dissociated embryonic retina cells and to dissociated retina cells in rotation-mediated suspension culture. Addition of the 5A11 antibody to monolayer cultures results in alteration in the development of the stereotypic arrangement of neurons and glia characterized by a reduction in the number and complexity of neural extensions upon the glial-derived flat cells. Similarly, addition of antibodies generated against the 5A11 antigen to dissociated cells in rotation cultures significantly reduces retina cell reaggregation as monitored by computer-assisted image analysis of cell aggregate size. These data and the identification of the 5A11 antigen as a member of the IGSF establish a role for the 5A11 antigen as a novel recognition molecule in the developing neural retina.

Developmental control of glucocorticoid receptor transcriptional activity in embryonic retina

In chicken embryo retina, competence for induction of the glutamine synthetase [L-glutamate:ammonia ligase (ADP-forming); EC 6.3.1.2] gene by glucocorticoid hormones increases progressively with development; this competence is minimal in 6-day retina (E6) and high by day 10 (E10). Because the level of glucocorticoid receptors (GRs) in the retina does not increase during that time, we investigated whether the transcriptional activity of GR increased between days 6 and 10 of development. The glucocorticoid-inducible chloramphenicol acetyltransferase (CAT) constructs 2GRE-37TK and p delta G46TCO, which contain glucocorticoid-responsive elements attached to a TATA box and to the thymidine kinase promoter, respectively, were transfected into E6 and E10 retinas, and their inducibility was examined. CAT expression could be induced in the transfected E10 retina but was not induced in the transfected E6 retina. However, induction was obtained also in E6 retina after cotransfection with a GR expression vector. Noninducible CAT constructs (pRSV-CAT, pSV2CAT, and pBLCAT2) were expressed at both ages at similar levels. The CAT construct pGS2.1CAT, which is controlled by the upstream sequence of the chicken glutamine synthetase gene, could be induced in E10 retina but was not induced in E6 retina; however, cotransfection with the GR expression vector resulted in induction of pGS2.1CAT also in E6 retina. We interpret these results as showing that the transcriptional activity of GR in embryonic retina is developmentally controlled and suggest that its increase is causally implicated in the development of competence for glutamine synthetase induction.

Peanut agglutinin binding glycoproteins in the chick retina: their presence in Müller glia cells

The histological and cellular distribution and some biochemical characteristics of components that bind peanut agglutinin (PNA), a lectin that recognizes preferentially terminal galactose-beta (1-3) N-acetyl galactosamine disaccharide residues of glycoconjugates, were studied in chick retinal tissue and in dissociated retinal cells after their differentiation in culture. In sections of retinal tissue from animals 7 days after hatching (Rp7), in addition to the inner and outer segments of the photoreceptor layer, the plexiform and optic fiber layers were stained with rhodamine-labeled PNA, indicating that, besides photoreceptor cells, other cellular types contribute to the PNA staining. We present evidence indicating that at least part of this staining is provided by Müller glia cells. In cultures of dissociated cells from retinas at embryonic day 7 (R7), photoreceptor-like cells and flat Müller glia-derived cells but not neurons were stained with rhodamine-labeled PNA. Furthermore, Müller glia cells isolated from Rp7 were also brightly stained with PNA. Western blot assays of extracts from R7 showed the presence of PNA binding glycoproteins of 31-33 kDa and a component that migrates at the dye front. In addition to the components detected in R7, extracts from R14 and Rp7 showed the presence of a major PNA binding glycoprotein of 175 kDa and a minor glycoprotein of 220 kDa. Extracts from the photoreceptor layer contain the 175 and 220 kDa glycoproteins, indicating their association with photoreceptor cells. The 31-33 kDa components were detected in extracts from the remnant inner retina, suggesting their association with the Müller glia cells. Supporting this view, these components and not those of 175 and 220 kDa were detected in cell cultures enriched in flat Müller glia-derived cells. Only the 31-33 kDa components and the component that migrates at the dye front were detected in extracts from cell cultures enriched in photoreceptor-like cells, suggesting the need of some environmental element for the expression of the 175 and 220 kDa components in the differentiated photoreceptor cells.

High levels of aldehyde dehydrogenase transcripts in the undifferentiated chick retina

A cDNA clone corresponding to chicken aldehyde dehydrogenase (ALDH) mRNA was isolated from a library representing the polyadenylated RNAs expressed in the retina of day 3.5 chick embryos. The profile of ALDH RNA expression was examined in different tissues as well as at different stages of development in the chick embryo. A notable feature of this analysis was the high level of ALDH transcripts found in the undifferentiated cells of the retina. A 20-fold decrease in ALDH RNA levels was observed upon retinal differentiation, in contrast to the kidney, liver and gut where tissue maturation was accompanied by an increase in ALDH mRNA levels. The observations reported here suggest an important role for the ALDH enzyme in retinal development. One possibility is that retinal, the aldehyde form of vitamin A, serves as a substrate for ALDH in the developing retina, resulting in the formation of retinoic acid which has been implicated in various differentiation processes.

Developmental expression of the glial fibrillary acidic protein (GFAP) gene in the mouse retina

1. In the nervous system, Glial fibrillary acidic protein (GFAP) is a well-known, cell type-specific marker for astrocytes. 2. In the mammalian retina, Muller cells, the major class of retinal glia, do not express GFAP or contain only low amounts of this protein. In retinas with photoreceptor degeneration, however, high levels of GFAP are found. It is possible that GFAP synthesis in these retinas could result from "dedifferentiation" of Muller cells as a consequence of disruption of normal neuron-glia interactions. 3. We have carried out immunocytochemical and in situ hybridization studies to examine whether GFAP or its mRNA is expressed by retinal cells early in embryonic development. 4. Our results show that GFAP-containing cells, which are probably astrocytes, are found only in the ganglion cell and nerve fiber layers and that these cells appear after postnatal day-1 (P-1) and continue to form until P-10. 5. Astrocyte formation starts from the optic disc and moves toward the periphery of the retina at a rate of approximately 160-200 microns per day. 6. An unexpected result from these studies is that GFAP mRNA levels are high in the first week of birth and decline rapidly as the animal develops. 7. Finally, we did not find either GFAP or GFAP mRNA in retinal cells other than astrocytes during normal development.

Expression of v-src in embryonic neural retina alters cell adhesion, inhibits histogenesis, and prevents induction of glutamine synthetase

Using Rous sarcoma virus as the vector, v-src or c-src genes were introduced into 6-day chicken embryo retina tissue in organ culture and their effects on retina development were investigated. Overexpression of c-src in many of the cells had no noticeable effect on retina development. In contrast, infection with v-src resulted in abnormal histogenesis and inhibition of differentiation. Although only a portion of the cells in infected tissue expressed the oncogene and displayed the transformation phenotype, the other cells were also hindered from becoming normally positioned and organized. Therefore, presence of oncogene-transformed cells within the tissue hindered organization and development of adjacent nontransformed cells. Failure of normal cell relationships impeded induction by cortisol of glutamine synthetase in Muller glia, which requires contact associations of the glia cells with neurons. The transformed cells tended to assemble into chaotic clusters, suggesting that their adhesiveness and contact affinities had become altered. This was confirmed by aggregation experiments with dissociated cells which showed that adhesiveness of transformed cells was greatly reduced and that they had lost the ability to cohere with nontransformed cells. In binary mixtures of transformed and nontransformed cells, the two sorted out into separate aggregates. Transformed cells formed loose clusters devoid of tissue architecture; aggregates of nontransformed cells became organized into retinotypic structures, and glutamine synthetase was inducible. Our findings suggest that the mechanisms of cell adhesion and cell affinities are a key target of v-src activity in infected cells and that modification of the cell surface may be a leading factor in other cellular changes characteristic of the v-src transformation phenotype.

Expression of v-src in embryonic neural retina alters cell adhesion, inhibits histogenesis, and prevents induction of glutamine synthetase

Using Rous sarcoma virus as the vector, v-src or c-src genes were introduced into 6-day chicken embryo retina tissue in organ culture and their effects on retina development were investigated. Overexpression of c-src in many of the cells had no noticeable effect on retina development. In contrast, infection with v-src resulted in abnormal histogenesis and inhibition of differentiation. Although only a portion of the cells in infected tissue expressed the oncogene and displayed the transformation phenotype, the other cells were also hindered from becoming normally positioned and organized. Therefore, presence of oncogene-transformed cells within the tissue hindered organization and development of adjacent nontransformed cells. Failure of normal cell relationships impeded induction by cortisol of glutamine synthetase in Muller glia, which requires contact associations of the glia cells with neurons. The transformed cells tended to assemble into chaotic clusters, suggesting that their adhesiveness and contact affinities had become altered. This was confirmed by aggregation experiments with dissociated cells which showed that adhesiveness of transformed cells was greatly reduced and that they had lost the ability to cohere with nontransformed cells. In binary mixtures of transformed and nontransformed cells, the two sorted out into separate aggregates. Transformed cells formed loose clusters devoid of tissue architecture; aggregates of nontransformed cells became organized into retinotypic structures, and glutamine synthetase was inducible. Our findings suggest that the mechanisms of cell adhesion and cell affinities are a key target of v-src activity in infected cells and that modification of the cell surface may be a leading factor in other cellular changes characteristic of the v-src transformation phenotype.

Emergence of flat cells from glia in stationary cultures of embryonic chick neural retina

When embryonic retina is dissociated into a single cell suspension and maintained in stationary culture, a population of flat cells is found on the culture dish. We have carried out a morphologic and immunologic study of the emergence of this population in vitro. Ten- and fourteen-day-old chick embryo retinas were dissociated with trypsin, seeded on glass cover slips for various times, and prepared for scanning electron microscopy (SEM) and immunofluorescence (IF) for Vimentin, an intermediate filament protein. SEM indicates that the characteristic flat cell morphology is initiated in some cells in as little as 30 min after the start of the culture. Not all of the cells that attach flatten. As incubation proceeds, small clusters of cells that had formed in suspension attach to the substrate, and flat cells emerge from them. The flattened cells are positive for Vimentin by IF within 10 min of attachment. The percent of fluorescent cells found on the substrate is constant during the time in culture. This suggests that flat cells do not attach first, followed by neural cells, but that the neural cells and flat cells attach to the dish at the same rate. When aggregates that had formed in suspension attach to the substrate, they are anchored by flat cells that migrate out of the aggregate. Since Vimentin appears in the cultured cells within 10 min, it is unlikely that it has been newly synthesized. Thus, the same cells that contained Vimentin in the retina now express it as flat cells. This supports the hypothesis that flat cells derive from the same cells in the retina that give rise to Müller cells. We have also observed the emergence of a population of cells with short (0.5 micron) microvilli that appear within 8 h of culture. They seem to be a distinct subpopulation of the cells on the upper portion of attached clusters.

GD3 ganglioside is prevalent in fully differentiated neurons from rat retina

Adult mammalian retinas contain unusually high amounts of GD3, a ganglioside of the lactosylceramide series. In this respect, they differ from adult avian retina and other regions of the adult avian and mammalian brain, where GD3 is a minor ganglioside and gangliosides of the gangliotetraosylceramide series (GM1, GD1a, GD1b, GT1b) are the predominant ones. We compare here the ganglioside patterns of rat, human, horse, and guinea pig retinas, which are known to differ in the degree of vascularization and astrocytic cell content. All these retinas showed a prevalence of pathway "b" gangliosides over pathway "a" gangliosides but showed no correlation between GD3 content and the degree of vascularization and astrocytic cell content. Immunostaining of rat retina sections showed the presence of GD3 in the inner and outer plexiform layers and also in the ganglion cell and inner nuclear layers. About 60% of the cells dissociated from rat retina showed immuno-colocalization of GD3 and the neuronal marker class III beta tubulin isotype or cholera toxin binding. All morphologically identifiable glial Muller cells coexpress GD3 and gangliotetraosylgangliosides. GD3 was a minor ganglioside among these axonally transported by ganglion cells in rats and guinea pigs, suggesting that it is either not synthesized by ganglion cells or, if so, it is restricted to the cell soma and/or dendritic tree. Our results demonstrate that, unlike neurons from avian retina and other regions of avian and mammalian brain, neurons from mammalian retina not only contain gangliosides of the gangliotetraosylceramide series but also keep a prevalence of gangliosides of the lactosylceramide series (GD3) when they are fully differentiated.

Glucocorticoid-inducible expression of a glutamine synthetase-CAT-encoding fusion plasmid after transfection of intact chicken retinal explant cultures

In this communication we demonstrate that gene transfer methodology can be applied to study gene expression in intact retinal explant cultures. The appropriate enzyme activity is observed in extracts obtained after electroporation of embryonic day-10 chicken retina with plasmids containing the chloramphenicol acetyltransferase-encoding or beta-galactosidase-encoding reporter genes under transcriptional control by the Rous sarcoma virus long terminal repeat. Similar results are obtained using Ca.phosphate-mediated gene transfer. Moreover, it has been previously established that glucocorticoid hormones stimulate transcription of glutamine synthetase (Glns) mRNA in embryonic retina. We report here that, based on the results of gene transfer experiments with chimeric plasmids containing 5'-flanking DNA derived from the cloned chicken Glns-encoding gene (Glns), essential glucocorticoid response elements reside between approx. 1.3 kb and 2.5 kb upstream from the Glns transcription start point. These data show that transfection of explant cultures can provide a useful approach to the study of gene expression in complex systems.

Coexpression of lactosyl and gangliotetraosyl gangliosides in rat cerebellar radial glial cells in culture

The expression of gangliosides of the lactosylceramide (LC) and of the gangliotetraosylceramide (GTC) series on the surface of cells from rat embryonic cerebellar tissue was investigated by double-color indirect immunofluorescence. GD3 was assumed to be representative of LC and was detected using a specific monoclonal antibody. GM1 was assumed to be representative of GTC and was detected using the binding of cholera toxin followed by the binding of cholera toxin antibodies. The expression of polysialosylated GTC (polysialosyl-GTC) was detected using the cholera toxin-cholera toxin antibody experimental approach after conversion of polysialosyl-GTC to GM1 by treatment of the cells with neuraminidase. To distinguish the major neural cell types present in the cultures the expression of the following cell type-specific markers was investigated: neuron-specific enolase and microtubule-associated protein-2 (MAP-2) as probes for neuronal cells and the intermediate filament protein glial fibrillar acidic protein (GFAP) as a probe for astroglial cells. More than 80% of cells dissociated from cerebellar tissue of 15-day-old rat embryos (E15) are positive for the expression of GD3 and about 50% for the expression of GM1 and polysialosyl-GTC, but most are negative for the expression of neuron-specific enolase, MAP-2, and GFAP. After culturing for 4 days (E15 + 4) most cells that show characteristics of neuronal cells are positive for the expression of polysialosyl-GTC and "inactivate" the expression of GD3. Most cells with characteristics of radial and stellate glial cells are also positive for the expression of polysialosyl-GTC, but unlike neuron-like cells, they do not "inactivate" the expression of GD3.

Carbonic anhydrase activity in mammalian retina. Developmental aspects in altricial and precocial species

Carbonic anhydrase activity has been studied during retina development in 2 mammalian species, guinea pig and rat, which differ for birth time and gestational period as being precocial and altricial respectively. For both species, the definitive pattern of enzyme distribution corresponds to the localization of the reaction product in the Müller glial cells at the level of nucleus, perikaryon, lateral processes, and end-feet. Only in the rat retina, staining has been observed also in some amacrine cells. The results of either in situ or extra situm investigations showed that, according to tissue maturity, in the precocial species, the definitive expression of carbonic anhydrase is reached at birth time. In the altricial species, on the contrary, maturity is very delayed and may be recognized at only the 12th d of postnatal life. Present findings confirm that carbonic anhydrase is a marker for the maturity of the retinal glial cells.

Response of Müller cells following experimental lensectomy-vitrectomy

We used morphological, biochemical and immunohistochemical methods to assess the response of Müller cells after experimental lensectomy-vitrectomy in rabbits. We observed widened intercellular spaces between the Müller cells and nerve fibers of ganglion cells, and increased electron opacity in the Müller cells of eyes injected with silicone oil. No apparent morphological changes were detected in the Müller cells of air-injected eyes. The specific and total activities of Müller cell-marker enzymes (glucose 6-phosphatase and glutamine synthetase) showed an initial increase, followed by a decrease. Glial fibrillary acidic protein immunoreactivity was not found in the Müller cells of the normal rabbit retina but was exhibited after surgery. Our results showed that markers of Müller cells associated with glycogenolysis and/or gluconeogenesis, glutamate-glutamine cycle and cytoskeletal protein metabolism were affected by the experimental lensectomy-vitrectomy.

Synthesis and secretion of interphotoreceptor retinoid-binding protein (IRBP) by isolated normal and rd mouse retinal photoreceptor neurons in culture

Cultures of dissociated retinal neurons and photoreceptors from homozygous wild-type, heterozygous rd/+ and homozygous rd/rd retinas have been used to investigate the capacity of isolated photoreceptor cells to synthesize and secrete the interphotoreceptor retinoid-binding protein (IRBP). Retinal cells were dissociated on postnatal day 2 and grown in chemically defined medium in the absence of glial and pigmented epithelial cells. Expression of IRBP immunoreactive materials in these cultures was cell type-specific and developmentally regulated. Thus increasing numbers of rod photoreceptor cells showed immunoreactivity during the first week in culture, whereas nonphotoreceptor cell types remained consistently negative. Photoreceptor immunoreactivity could be detected in permeated (detergent-treated) as well as in unpermeated preparations, the latter suggesting that some IRBP is associated with the photoreceptor cell surface. These materials appeared to be loosely bound to the photoreceptors, since they disappeared when the cultures were exposed for 6 hr to IRBP-free medium but not when they were exposed to IRBP-containing medium. IRBP synthesis and secretion could be demonstrated by analyzing either cell extracts or conditioned medium by "slot blot" and Western blot techniques using affinity purified antibodies against bovine IRBP as well as by fluorographic analysis after metabolic labeling of the cultures with 35S-methionine. Comparisons of cultures from the different genotypes showed many similarities, including the abundance of IRBP-immunoreactive photoreceptors in 7 day cultures. However, immunochemical analysis showed lower conditioned medium/cell extract IRBP ratios in rd/rd cultures, an observation consistent with previous reports suggesting that IRBP secretion may be deficient in rd/rd photoreceptor cells.

In vivo and in vitro expression of gangliosides in chick retina Müeller cells

The expression of gangliosides of the lactosylceramide (LC) and of the gangliotetraosylceramide (GTC) series on the surface of cells from the chick neural retina was investigated by double-color indirect immunofluorescence. GD3 was assumed to be representative of LC and was detected using a specific monoclonal antibody. GM1 was assumed to be representative of GTC and was detected using the binding of cholera toxin followed by the binding of cholera toxin antibodies. The expression of polysialosylated GTC (polysialosyl-GTC) was detected using the cholera toxin-cholera toxin antibody experimental approach, after conversion of polysialosyl-GTC to GM1 by treatment of the cells with neuraminidase. In retinas from 6-day-old embryos (R6), most cells (approximately 80%) expressed GD3 but not GTC. After culturing for 7 days, (R6+7), the expression of GTC was found confined to neuron-like cells; flat cells derived from Müller cells expressed GD3 but were negative for GTC expression. On the other hand, postmitotic Müller cells obtained from 13-day-old embryo (R13) or 1-day-old hatched chick retina (RP1) expressed GD3, GM1, and polysialosyl-GTC but were unable to maintain the expression of these GTCs when kept in culture for several days. According to these results, retinal cells can be defined on the basis of their ganglioside expression as follows: (a) retinoblasts, by the expression of GD3; (b) postmitotic neuronal cells, by the expression of GTC; and (c) postmitotic Müller cells, by the expression of GD3 and GTC.(ABSTRACT TRUNCATED AT 250 WORDS)

Cell type expression mediated by cell cycle events, and signaled by mitogens and growth inhibitors

It is initially pointed out that the majority of factors that induce cell type expression in mature precursor cells are either mitogens or growth inhibitors. On the basis of available data, a theoretical model of regulation of cell type expression for each group of factors is proposed. In model A the mitogen affects the expression of cell type through the positive control of cell cycle progression, while in model B the growth inhibitor induces the negative control of cell cycle progression, which in its turn causes the cell type expression. In connection with those two models, various systems of cell type expression are classified into three groups. In model A systems, the cell lineage has an option of autotypic and allotypic cell types. The former is expressed in the absence of added mitogen, and the latter is expressed in its presence. In model B systems the cell lineage-specific cell type is expressed by the negative cell cycle control induced by the growth inhibitor. In model A-B systems both mitogen and inhibitor are needed in tandem for the expression of a cell type. The second major point made is that the expression of cell type follows the negative control of cell cycle progression even in model A systems. However, in this system the control occurs spontaneously. This suggests that the negative control is essential for cell type expression in all systems, and directly precedes the expression. In contrast, the positive control induced by exogenous mitogen is not required in the expression in model B systems or in that of autotypic cell types in model A systems. The third point is that on the basis of the hypothesis of replication-transcription coupling, proposed by Sauer and colleagues, it is speculated that the pattern of early-replicating genes may be functioning as the potential gene transcription pattern for cell type expression in precursor cells. If this pattern is perpetuated through cell generations, the original cell type specificity of the precursor cell lineage should be maintained. If this pattern is modified by the positive control of cell cycle progression in model A systems, the potential transcriptional pattern for the allotypic pathway may emerge. Furthermore, it is proposed that the realization of the potential pattern may depend on a signal, informing the completion of the negative control of cell cycle progression. Thus in all cell lineages, when the negative cell cycle control is completed, chromatin receives this signal, and the potential transcription pattern is converted into cell type differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)

An immunocytochemical comparison of Müller cells and astrocytes in the cat retina

Immunocytochemical localization, at the light and electron microscopic levels, of five different known glial proteins was used to compare Müller cells with astrocytes in the adult cat retina. Retina from two different areas of the eye was examined. A region of retina on the border of the optic nerve was used because of its large population of astrocytes, and a region away from the optic nerve was used to examine Müller cells (astrocytes are sparse in this region). Antibodies to cellular retinaldehyde binding protein and glutamine synthetase labeled the Müller cells but not the astrocytes, while labeling with anti-carbonic anhydrase C, anti-alpha crystallin and anti-glial fibrillary acidic protein was found in both Müller cells and astrocytes.

Cell contacts are required for induction by cortisol of glutamine synthetase gene transcription in the retina

In embryonic neural retina the enzyme glutamine synthetase [GS; L-glutamate:ammonia ligase (ADP-forming), EC 6.3.1.2] is a glia-specific differentiation marker inducible with cortisol. We show that cortisol elicits GS mRNA accumulation by stimulating transcription of the GS gene and that this stimulation requires cell contacts: in dissociated and separated retina cells GS gene transcription was not induced; when the separated cells were reassembled into multicellular aggregates, restoring cell contacts, accumulation of GS mRNA was again inducible. In cells dissociated from retina tissue that had been preinduced with cortisol, GS gene transcription rapidly declined, despite continued hormone availability. In the separated cells transcription of the histone H3.3 gene and accumulation of carbonic anhydrase II mRNA were unaffected; therefore, cell separation selectively precluded induction of the GS gene. These findings provide direct evidence for the regulatory role of cell contacts in hormonal control of gene transcription.

Tetanus toxin binding to isolated and cultured rat retinal glial cells

The presence of immunocytochemically detectable membrane receptors for tetanus toxin, supposedly composed of higher gangliosides, is widely accepted as a marker of neuronal cells. We now demonstrate that Müller cells, a unique glial cell type of the vertebrate retina, possess specific tetanus toxin (TT)-binding sites. Single cell suspensions were prepared from adult rat retina by a gentle dissociation method, and the Müller cells, unequivocally identified by their morphology, could be immunocytochemically double-labeled by antisera to vimentin and to TT. The expression of complex gangliosides by identified Müller cells was also demonstrated by immunofluorescence labeling with the monoclonal antibody A2B5. Using the double-immunolabeling method for the identification of Müller cells we show that specific tetanus toxin binding is acquired by these cells during postnatal maturation both in vivo and in vitro. In vivo the percentage of tetanus toxin-positive Müller cells increases from 0% in 4-day-old animals to 10% on postnatal day 8, reaching the adult level of about 95-100% around day 30. In retinal monolayer cultures prepared from newborn rats, the majority (65%) of vimentin-positive non-neuronal cells became TT-positive during a 2-week culture period, indicating that this population of non-neuronal cells represents differentiating Müller cells. Again, comparable results were obtained with A2B5, supporting the conclusion that Müllerian glia expresses surface molecules, which are normally regarded as neuronal markers.

Developmentally regulated primary glucocorticoid hormone induction of chick retinal glutamine synthetase mRNA

We have characterized the glucocorticoid hormone induction of glutamine synthetase mRNA in embryonic chick retinal organ cultures by quantitative dot hybridization using a cDNA clone derived from chick retinal RNA. Hydrocortisone (Kapp = 3-4 nM) and dexamethasone (Kapp = 1-2 nM) produce an approximate 30-fold increase in glutamine synthetase mRNA after incubation of organ cultures derived from embryonic day 12 retinae with either hormone for 3 hr. Progesterone is a poor inducer. The glucocorticoid-mediated rise is rapid (t1/2 = 2-3 hr) and occurs in the presence of either of the protein synthesis inhibitors cycloheximide or puromycin, indicating that the induction is a primary or direct response to the hormone. However, the magnitude of the hormonal response observed in culture increases markedly during retinal development. These observations, coupled with the previously reported absence of a hormonal induction in embryonic liver, raise the possibility of a synergistic mechanism, involving tissue-specific regulatory molecules in addition to the glucocorticoid hormone receptor, to explain the retinal-specific primary glucocorticoid hormone induction of glutamine synthetase mRNA.