pp60c-src encoded by the proto-oncogene c-src is a product of sensory neurons

The advent of recombinant DNA technology has led to the identification in the DNA of normal animal cells of over 30 proto-oncogenes that are homologous to retroviral transforming genes. One of these encodes a protein kinase (pp60c-src) of unknown function, that is preferentially synthesized in brain and neural retina. Here the expression of pp60c-src in the peripheral nervous system was examined in sensory neurons from chick dorsal root ganglia with antisera raised against the transforming protein of Rous sarcoma virus (pp60v-src) expressed in Escherichia coli carrying the cloned v-src gene. This antiserum recognizes pp60c-src specifically in normal chicken cells. Western immunoblotting showed that dorsal root ganglia of stage 30 (day 6.5) chick embryos contained elevated levels of pp60c-src. Immunoperoxidase staining of neuron-enriched cultures prepared from chick dorsal root ganglia showed pp60c-src immunoreactivity in cells with neuronal morphology; flat, fibroblastic cells contained no detectable immunoreactivity. Indirect double immunofluorescence with pp60src antibodies and monoclonal antibodies against the 200-kD subunit of neurofilament protein confirmed that the cells expressing pp60c-src were neurons. Ninety-six percent of the neurofilament-positive cells were immunoreactive with pp60src antibodies, and conversely, all pp60c-src-positive cells were immunoreactive with neurofilament antibodies. pp60c-src immunofluorescence appeared to be distributed over the cell body, processes, and growth cones. These results clearly demonstrate that pp60c-src is a product of neurons and is expressed in sensory neurons in culture.     

Differential induction of interleukin-1beta and tumour necrosis factor-alpha may account for specific patterns of leukocyte recruitment in the brain

The mechanism of control of GAD expression by GABA and excitatory amino acids (EAAs) was studied in chick and rat retina cultures using immunohistochemical and PAGE-immunoblot detection of the enzyme, as well as by measuring enzyme activity. Aggregate cultures were prepared with retina cells obtained from chick embryos at embryonic days 8-9 (E8-E9). Organotypical cultures were also prepared with retinas from E14 chick embryos, post-hatched chicken and P21 rats. GABA (1-20 mM) fully prevented GAD expression in aggregate and organotypical cultures from chick embryo retinas. A substantial, but not complete, reduction of GAD was also observed in organotypical cultures of post-hatched chicken and P21 rats, in which both forms of the enzyme (GAD65 and 67) were affected. The GABA effect was not mimicked by THIP (100 microM), baclofen (100 microM) or CACA (300 microM), agonists of GABAa, b and c receptors, respectively. NNC-711, a potent inhibitor of GABA transporters, reduced by 50% the inhibition of GAD activity promoted by GABA. Aggregates exposed to GABA and treated with glutamate (5 mM) or kainate (100 microM) displayed an intense GAD-like immunoreactivity in many cell bodies, but not in neurite regions. Immunoblot analysis revealed that the increase in GAD-like immunoreactivity by EAA corresponded to a 67-kDa protein. However, GAD activity was not detected. Treatment of aggregates or retina homogenates with SNAP, a NO producing agent (but not its oxidized form), reduced GAD activity by more than 60% indicating that the lack of enzyme activity in GAD-like immunoreactive cells, could be due to NO production by EAA stimulation.     

Cell commitment and differentiation in explants of embryonic rat neural retina. Comparison with the developmental potential of dissociated retina

The differentiation of presumptive neural retina following its isolation from rat embryos and growth in explant and monolayer culture has been studied to obtain information regarding the extent to which factors extrinsic and intrinsic to the retina participate in determining molecular and cytological differentiation. Explanted retinal epithelium retained the capacity for mitosis, as shown by [3H]thymidine incorporation, and from the undifferentiated neuroepithelium, retinal cell-types emerged and acquired a laminar organization resembling that in vivo. Characterization of rod photoreceptor cells at both the light and electron microscopic level showed that these cells exhibit differentiated structural features including inner segments, connecting cilia and membranous expansions suggestive of forming outer segments. Immunofluorescent labeling with an antibody to a synaptic vesicle protein, and electron microscopic identification of synaptic elements showed formation of synapses by the photoreceptor cells within the explant. Neurites extending from the explants exhibited growth on laminin, fibronectin and collagen substrates. Since the neurites immunolabeled with antibodies to the 140 kDa subunit of neurofilament and with antibodies to Thy-1, they could be identified as axons of ganglion cells. Antibodies to a variety of cell-type specific antigens showed that the cells expressed molecules associated with the fully differentiated cell. Furthermore, since our approach has been to explant embryonic retina at an age when the antigens are not yet expressed in vivo, the appearance of the antigens in culture represented de novo expression. In contrast, neural retinal cells in dissociated cultures did not exhibit de novo expression of differentiated molecular properties.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification and characterization of cell types in monolayer cultures of rat retina using monoclonal antibodies

This study describes the identification and differentiation of neonatal rat retinal cells in monolayer cultures. A panel of monoclonal antibodies was used as a molecular probe of both cell type and developmental stage. Previously described cell-type specific monoclonal antibodies were used to label rod photoreceptors, horizontal cells, amacrine cells or ganglion cells. Two new antibodies that react with rat retina are described. The first, RET-G7, reacts with a cytoplasmic antigen of Muller glia, astrocytes and some horizontal cells. The second, RET-B2, reacts with bipolar cells and photoreceptor inner segments. Two main findings are presented. The first is that each of the major subclasses of retinal neurons have been unambiguously identified in these cultures. The morphology of some subclasses was very characteristic. All photoreceptors, as defined by reactivity with antibody RET-P1, were small spherical cells with one or fewer processes. Horizontal cells, as defined by reactivity with antibody B-1, were large with a characteristic multipolar network of processes. Bipolar and amacrine cells, on the other hand, were of similar size and could only be distinguished on the basis of immunocytochemical labeling. The second finding is that while RET-B2 antigen appeared on bipolar and photoreceptor cells after about 5 days in culture, several Muller cell and photoreceptor antigens were not expressed in monolayer cultures. The results suggest that the expression of some molecules in culture is the result of properties intrinsic to the cells whereas expression of others depends upon extrinsic factors or cell interactions that may not be present in monolayer cultures.     

Differential expression of acetylcholinesterase molecular forms in neural retina and retinal pigmented epithelium during chick development

Neural retina (NR) and retinal pigmented epithelium (RPE) were used as a model for studying acetylcholinesterase (AChE) expression in neuronal and non-neuronal tissue during development. In chick embryo retina, increasing AChE activity appeared from day 7 to hatching, first in NR and then in RPE. NR contained 3 main AChE forms, 11.3S, 6.5S and 4.5S, resolved by sucrose density gradient centrifugation. An additional 19S form was exclusively detected in RPE whatever the extraction procedure followed. During differentiation, the proportions of AChE molecular form changed until they reached a steady state characteristics of mature neural retina, whereas in RPE, patterns of AChE molecular forms did not change significantly during development. Thus, 19S AChE appeared to be characteristic of non-neuronal retinal tissue. The expression of the AChE molecular forms in NR and RPE, and particularly the 19S form, was independent of the presence of the lens during retinal differentiation.     

Growth hormone localization in the neural retina and retinal pigmented epithelium of embryonic chicks

It is well-established that growth hormone (GH) is present in the brain, spinal cord, and peripheral nerves of embryonic chicks, prior to the differentiation of pituitary somatotrophs, but its presence and distribution in retinal tissues is controversial. The possible presence of GH and GH mRNA in retinal tissues of early embryos has therefore been further evaluated. A 466-bp fragment of the pituitary GH cDNA, derived from a portion of exon 3 and spanning exons 4 and 5, was amplified by RT-PCR from reverse-transcribed mRNA from the pituitary glands of juvenile chicks and from the whole eye, neural retina, and retinal pigmented epithelium (RPE) of embryonic-day (ED) 9 chick embryos. In ED 9 embryos, GH immunoreactivity was demonstrated in the choroid and neural retina, in which it was particularly abundant in a layer of cells with the location and morphological appearance of retinal ganglion cells. GH immunoreactivity was also present in tissue sections of the RPE that were bleached to remove the melanin pigment. The intense GH staining in the RPE of ED 9 embryos was also revealed using a fluorescein-labeled GH antibody and confocal microscopy. At the ultrastructural level, GH detected by immunogold electron microscopy was present in the cytoplasm of RPE and neural retinal cells of ED 9 embryos. Although not associated with secretory granules, GH in the RPE was particularly associated with the membranes of the melanin granules. These results demonstrate that the neural retina and RPE are extrapituitary sites of GH production in early chick embryos, prior to the differentiation of the pituitary gland.     

Novel organotypic culture model of adult mammalian neurosensory retina in co-culture with retinal pigment epithelium

PURPOSE: The purpose of this study was to assess survival of adult mammalian neurosensory retina cultured in contact with the layer of a choroid-retinal pigment epithelium (RPE) explant. METHODS: The entire adult porcine neurosensory retina and RPE-choroid layer were placed in tissue culture by juxtaposing both tissues in their original orientation. Culture of the neurosensory retina alone and freshly prepared retina were used as control. After 3 days in culture retinal explants were fixed and processed for immunohistochemistry and TUNEL technique. RESULTS: We observed limited nuclei loss and significant reduction in apoptotic cells in nuclear cell layers (GCL, INL, and ONL) and decreased Muller cell hypertrophy in retina-RPE cultures compared to retinal cultures alone. In addition, cultures were characterized by reduced upregulation of GFAP, vimentin as well as S100 and increased glutamine synthetase expression. CONCLUSIONS: As any tissue culture model, retinal tissue culture is a short-term system and since degenerative processes begin quite early it may be a good model to investigate degenerative processes in the retina. However, our model of culture of retina adjacent to the RPE-choroid layer improves the maintenance of neural retina as evidenced by reduced apoptosis in nuclear cell layers (GCL, INL, and ONL) and reduced gliosis as indicated by the diminished expression of glial-specific proteins and increased glutamine synthetase compared to cultures of retina alone. Thus the retina-RPE-choroid culture system can enable the evaluation of interactions between RPE and neural retina, the role of signaling molecules as well the effect of pharmaceuticals on retinal biology.     

Induction of glutamine synthetase in embryonic neural retina: its suppression by the gliatoxic agent alpha-aminoadipic acid

Competence for cortisol-mediated induction of glutamine synthetase (GS) is a differentiation marker of embryonic neural retina. Earlier work has indicated that the induction and accumulation of GS is localized in the Müller glia cells. This localization was presently confirmed by the finding that the gliatoxin D,L-alpha-amino-adipic acid (AAA) reduces responsiveness to GS induction by 60--90% due to preferential damage to Müller cells. The tests were performed on organ cultures of retina tissue from chick embryos, and on retina cell aggregates in which there is tissue reconstruction. The presence of GS-inducible Müller cells was monitored by immuno-staining of tissue sections with anti-GS antiserum. Reduction of GS inducibility due to pretreatment with AAA resulted in virtual absence of cells that immunostained for GS. The preferential toxicity of AAA for Müller cells was also demonstrated by cell viability tests; it was further corroborated by the finding that treatment with AAA greatly reduced the level of carbonic anhydrase activity, another enzyme localized predominantly in Müller cells, but did not affect gamma-aminobutyric acid transaminase and choline acetyl transferase, neuronal enzymes. Susceptibility of Müller cells to AAA was found to increase with embryonic development of the retina. We suggest that acquisition of susceptibility for AAA represents another differentiation marker of embryonic Müller cells.     

Glutamine Synthetase is Expressed by Primary Sensory Neurons from Chick Embryos In Vitro but not In Vivo: Influence of Skeletal Muscle Extract

Glutamine synthetase (GS) catalyses the ATP-dependent formation of glutamine from glutamate and ammonia. To determine whether dorsal root ganglion (DRG) cells from chick embryos express the enzyme in vivo or in vitro, GS was detected by immunocytochemical reaction either in vibratome sections of DRG or in dissociated DRG cell cultures. The immunocytochemical detection of GS showed that in vivo the DRG taken from chick embryos at day 10 (E10), E14, E18 or from chickens after hatching were free of any GS-positive ganglion cells; in contrast, in neuron-enriched cultures of DRG cells grown in vitro at E10, virtually all the neuronal cells (98.6 +/- 1.0%) express GS at 3, 5 or 7 days of culture. In mixed DRG cell cultures, only 83.6+/-4.6% of the neurons displayed a GS-immunoreactivity. In both culture conditions, neither the presence of horse serum nor the age of the culture appeared to affect the percentage of neurons which displayed a GS-immunoreactivity. After [3H]glutamine uptake, radioautographs revealed that only 80% of the neurons were labelled in neuron-enriched DRG cell cultures while 96% of the neurons were radioactive in mixed DRG cell cultures. Furthermore the most heavily [3H]glutamine-labelled neurons were exclusively found in mixed DRG cell cultures. Combination of both immunocytochemical detection of GS and radioautography after [3H]glutamine uptake showed that strongly GS-immunostained neurons corresponded to poorly radioactive ones and vice versa. When skeletal muscle extract (ME) was added to DRG cell cultures, the number of GS-positive neurons was reduced to 77.5 +/- 2.5% in neuron-enriched cultures or to 43.6 +/- 3.8% in mixed DRG cell cultures; in both types of culture, the intensity of the neuronal immunostaining was depressed. Furthermore, combined action of ME and non-neuronal cells potentiates the enzyme repression exerted separately by ME or non-neuronal cells. Since GS-immunoreactivity is expressed in DRG cells grown in vitro, but not in vivo, it is suggested that microenvironmental factors influence the expression of GS. More specifically, the repression of GS by primary sensory neurons grown in vitro may be strongly induced by soluble factors present in skeletal muscle, and to a lesser extent in brain, and potentiated by non-neuronal cells.     

Heterogeneity Among Neuroepithelial Cells in the Chick Retina Revealed by Immunostaining with Monoclonal Antibody PM1

Neuroepithelial cells appear as a homogeneous population of cells in the cell cycle that seem to behave as pluripotent neural precursors. The study of the intrinsic heterogeneity and subtle developmental changes among neuroepithelial cells has been hindered by the lack of specific markers. To address that study, a panel of monoclonal antibodies was produced against early developing chick retina. The monoclonal antibody precursor marker 1 (PM1) labels most, if not all, of the early neuroepithelial cells in embryonic day 4 retinal sections. This pattern is transient since the labelling becomes restricted to the peripheral retina as development proceeds and eventually disappears from the neuroepithelial cells. However, apparently in parallel, the differentiating retinal ganglion cells become PM1-positive. The expression of the PM1 antigen, a 73 × 10³ M _r protein, as shown by western blotting, also decreases with development. In addition, a chick retina dissociated-cell culture system, where retinal neuroepithelial cells actively proliferate and undergo differentiation under defined conditions, in combination with monoclonal antibody PM1, allowed us to characterize and quantify the proliferating and differentiating neuroepithelial cells. Interestingly, the fraction of total neuroepithelial cells that are stained with PM1 sharply decreases as retinal development proceeds, in correlation with the staining pattern in sections from matched stages. These data thus reveal that the pluripotent neural precursors in the chick retina already represent an intrinsically heterogeneous population, and that this population changes with development.     

Developmental changes in glycoproteins of the chick nervous system

Temporal changes have been noted previously in retinal glycoproteins that bind to wheat germ agglutinin by a technique in which the denatured glycoproteins are first separated according to size by polyacrylamide gel electrophoresis, and are then localized on the gel using [¹²⁵I]lectin¹⁵. As reported here this technique will also detect differences between dorsal and ventral halves of the neural retina from 8-day chick embryos, and using other lectins will detect temporal changes in the glycoprotein pattern of the optic tectum. Some of the glycoproteins detected by wheat germ agglutinin in the neural retina appear to be represented on the surface of the retinal cells since: (a) the temporal changes in retinal glycoproteins can also be observed in a plasma membrane enriched fraction prepared from neural retina cells; and (b) antibodies prepared in mice against various size categories of wheat germ lectin binding glycoproteins bind to intact retinal cells.     

Glutamine synthetase and energy metabolism enzymes in cultivated chick neurons and astrocytes: modulation by serum and hydrocortisone

Primary cultures of astroglial cells and of neurons obtained from chick embryos were grown in culture medium with and without serum added. The expression of glutamine synthetase (GS) in the cultured nerve cells was investigated immunocytochemically and biochemically. The cellular localization of GS in cerebellar tissue sections and in cerebral cortex of chick embryos was investigated by immunohistochemical staining. In tissue sections the enzyme is only present in astrocytes and their processes; neurons and their structures do not express the enzyme. In contrast, in pure neuronal primary cultures, a high level of GS was detected by biochemical and immunochemical methods. Thus, our results clearly indicate the presence of GS in pure neuronal cell cultures and its absence in this type of cells in vivo. Removal of serum from the culture medium enhanced GS levels in primary astrocyte cultures, but was without effect on GS activity in neurons. Addition of calf serum to the culture medium induces a two-fold increase of cellular lactate dehydrogenase (LDH) activity in neurons by increasing specifically the M subunit containing isoenzymes. The sensitivity of chick astroglial cells and neurons toward the GS inducing effect of hydrocortisone and modulation of its effect by serum was also investigated. Differences in the sensitivity of the two types of nerve cells in culture toward the GS inducing effect of hydrocortisone, and the effect of serum could be demonstrated.     

Generation of retinal ganglion cells is modulated by caspase-dependent programmed cell death

Programmed cell death occurs during both early and late neural development. The mechanisms for the regulation and execution of the early cell death as well as its developmental role are still not fully understood. In this work we have studied the early programmed cell death in the retinal neuroepithelium. Apoptotic cells were selectively located around the optic nerve head in the retinal neuroepithelium of 2- to 6-day-old chick embryos. TUNEL-positive cells and cells which were immunostained for activated caspase-3 showed overlapping distributions suggesting that caspase-3 is involved in the early retinal cell death. Caspase-3 involvement in early retinal cell death was also demonstrated by in vivo treatment with caspase inhibitors z-DEVD-fmk and Boc-D-fmk. After 6 h of treatment, the number of TUNEL-positive cells was reduced by 50%. Sustained treatments (20 h) resulted in a slight widening in the central part of the neural retina but the retinal ganglion cell axons maintained their organization and navigation towards the optic fissure. The most prominent result after inhibition of cell death was an increase in the number of retinal ganglion cells which also produced an enlargement of the ganglion cell layer and an increased number of ganglion cell axons. In conclusion, our results show that caspase-dependent programmed cell death occurs in the embryonic chick retina and that it plays a role to modulate the generation of retinal ganglion cells.     

Normal development and precocious induction of glutamine synthetase in the neural retina of the quail embryo

The developmental pattern of glutamine synthetase (GS) in the neural retina of the quail embryo is described and correlated with retina growth and differentiation. We show that GS in the quail retina can be precociously induced by cortisol, and that the enzyme is localized in Müller glia cells. The results are compared with the development and induction of GS in chick retina.