Involvement of P2 purinoceptors in the regulation ofdna synthesis in the neural retina of chick embryo

The activation of P2 purinoceptors induces Ca2+ mobilization in the early embryonic chick neural retina. This purinergic Ca2+ response declines parallel with the decrease in mitotic activity during retinal development. To investigate the role of P2 purinoceptors in the regulation of retinal cell proliferation, we studied the effects of the P2 purinoceptor antagonists suramin and pyridoxalphosphate-6-azophenyl-2',4'-disulphonic acid (PPADS), and of the agonist ATP on DNA synthesis in retinal organ cultures from embryonic day 3 (E3) chick. Suramin inhibited [3H]-thymidine incorporation in a dose-dependent manner (IC50: approximately 70 microM). PPADS also reduced [3H]-thymidine incorporation with maximum inhibition of 46% at 100 microM. Exogenous ATP enhanced [3H]-thymidine incorporation in a dose-dependent manner to maximally 200% of control (EC50: approximately 70 microM). In dissociated retinal cultures from E7 chick, both antagonists showed similar inhibitory effects on [3H]-thymidine incorporation without affecting cell viability. In line with these observations, the presence of extracellular ATP was demonstrated both in vitro and in vivo. In the medium of E3 retinal organ cultures, the concentration of ATP increased 25-fold within 1 h of incubation and this concentration was kept for at least 24 h. In the chick amniotic fluid, the ATP concentration was nearly 3 microM at E3 and declined to 0.15 microM at E7. The results indicate that P2 purinoceptors activated by autocrine or paracrine release of ATP are involved in the regulation of DNA synthesis in the neural retina at early embryonic stages.     

The cell recognition molecule, cognin, mediates choline acetyltransferase activity in embryonic chick retina.

Cell signaling and cell-cell interactions play an important role in neuronal differentiation in the embryonic CNS. Previous work (Hausman, R.E., Vivek Sagar, G.D. and Shah, B.H., Dev. Brain Res., 59 (1991) 31-37) had shown that cholinergic differentiation in the embryonic chick retina depends on insulin and neuron-neuron interactions. Here, we pursued the molecular nature of that dependence on cell interactions. The embryonic chick retina is known to contain several cell adhesion or recognition molecules. We asked if retina cognin, a 50 kDa cell surface-associated protein, played a role in controlling cholinergic differentiation in the developing chick retina. As previously, cholinergic differentiation was measured by two markers: choline acetyltransferase (ChAT) activity and high-affinity choline uptake. We used polyclonal antibody to cognin to determine if blocking cognin-mediated cell interactions would affect the normal embryonic increases in these cholinergic markers. We demonstrated a 40% inhibition of the normal developmental appearance of ChAT activity in retina neuronal cultures from early development, but no effect in cultures from more differentiated retina. The inhibition was selective for retina, since it was not seen in neural tissues like cerebrum and cerebellum that also express ChAT. In contrast to the effect of insulin, choline uptake was not affected by treatment with cognin antibody. Antibodies to two other cell recognition molecules present in the retina (Ng-CAM and N-cadherin) did not block the normal developmental appearance of ChAT. These results suggest that cognin-mediated interactions play a unique role in the control of one aspect of cholinergic differentiation in the developing chick retina.     

Opiate binding sites in the chick, rabbit and goldfish retina

The characteristics of opiate binding sites in the retina of the chick, rabbit and goldfish have been investigated. In the newly hatched chick retina, 131 fmol/mg of binding sites for [D-Ala2-D-Leu5]-[3H]enkephalin are present; competition studies with the delta selective peptide [D-Thr-Leu5]-enkephalin (DTLET) and the mu selective peptide morphiceptin show that all of the [D-Ala2-D-Leu5]-[3H]-enkephalin binding sites are of the delta subtype. Dihydro[3H]morphine binds poorly to the chick retina; 13.2 fmol/mg of this binding is displaceable by morphiceptin and corresponds to mu binding sites. Benzomorphan sites are defined as sites occupied by [3H]diprenorphine which is displaceable by low concentrations of ethylketocyclozacine but not by high concentrations of D-Ala2-D-Leu5-enkephalin and morphiceptin. At least 88 fmol/mg of benzomorphan sites are present in the chick retina. [3H]diprenorphine binding to the rabbit and fish retina was measured. The rabbit retina bound 60 fmol/mg, and the fish retina 42 fmol/mg of [3H]diprenorphine. These findings are discussed in the light of the studies on the localization and physiological effects of enkephalin in the retina.     

Modulation of retinal differentiation by oncogenes: effect of the v-src gene on expression of choline acetyltransferase and glutamine synthetase.

Expression of the protooncogene c-src in chick neural retina is developmentally regulated and associated with neural differentiation. In the present study, chick neural retina (NR) cell cultures from 7 day embryos were exposed to the exogenous src oncogene, the c-src counterpart, to establish the effect of expression of v-src on specific retinal cellular differentiation. NR cells from 7 day chick embryos were placed in monolayer or rotation culture and infected with Rous sarcoma virus (RSV) containing a single transforming gene. Other cultures were infected with a transforming defective mutant of RSV which still possesses mitogenic activity for NR cells. While control cultures showed typical neuronal and Muller cell morphologies at the light and electron microscopic level, NR cells infected with RSV exhibited dramatic morphological alterations in monolayer culture and cell aggregates. However, the mutant src gene induced mitosis without accompanying transforming properties. When aggregate cultures were treated with hydrocortisone to induce glutamine synthetase (GS) expression in Muller cells, control cultures showed the typical immunofluorescence pattern of GS staining, while RSV infected cultures showed no GS fluorescence. Cultures infected with mutant RSV showed some staining for GS. In contrast, choline acetyltransferase activity was shown to increase in both monolayer and aggregate cultures of retinal cells following v-src expression. These data indicate that the presence of excess v-src in differentiating cultures of NR inhibits the expression of some neural specific enzymes and enhances the presence of other specific proteins. Moreover, continually growing cultures of oncogene-altered retinal cells may be useful as models to study gene expression in development of the nervous system.     

Initial cholinergic differentiation in embryonic chick retina is responsive to insulin and cell-cell interactions

Previous work [Kyriakis et al., Proc. Natl. Acad. Sci. U.S.A., 84 (1987) 7463-7467] had shown that insulin, when added during a window of binding from embryonic days 9-11, stimulates the normal developmental increase in choline acetyltransferase (ChAT) activity (a marker for cholinergic differentiation) in cultured embryonic chick retinal neurons. Here, we investigated the effect of insulin and IGF 1 on embryonic chick retinal neurons at the stage of development (embryonic day 6) when ChAT activity is first expressed. We investigated insulin peptide effects in retinal tissue developing in vitro as well as in cultures of retinal cells. We show that insulin also stimulated the initial embryonic increase in ChAT activity but had no stimulatory effect on glutamic acid decarboxylase activity (a marker for GABAergic differentiation), an enzyme whose activity also increases developmentally in the same retinal neurons. In fact, insulin inhibited the expression of GAD activity in the retina. The insulin-mediated increase in ChAT activity was independent of normal cell-cell interactions but could not replace them. Insulin also stimulated choline uptake but only after a two day delay, suggesting that the normal program for cholinergic differentiation in the chick retina was induced by insulin. IGF 1 did not have any effect on either cholinergic or GABAergic differentiation. We conclude that cholinergic differentiation in chick embryo retinal neurons is dependent on both insulin- and cell contact-mediated signals.     

Ca2+ mobilization and capacitative Ca2+ entry regulate DNA synthesis in cultured chick retinal neuroepithelial cells.

Release of Ca2+ from intracellular Ca2+ stores (Ca2+ mobilization) and capacitative Ca2+ entry have been shown to be inducible in neuroepithelial cells of the early embryonic chick retina. Both types of Ca2+ responses decline parallel with retinal progenitor cell proliferation. To investigate their potential role in the regulation of neuroepithelial cell proliferation, we studied the effects of 2,5-di-tert-butylhydroquinone (DBHQ), an inhibitor of the Ca2+ pump of intracellular Ca2+ stores, and of SK&F 96365, an inhibitor of capacitative Ca2+ entry, on DNA synthesis in retinal organ cultures from embryonic day 3 (E3) chicks and in dissociated cultures from E7 and E9 chick retinae. We demonstrate that both antagonists inhibit [3H]-thymidine incorporation in a dose-dependent manner without affecting cell viability or morphology. The inhibition of [3H]-thymidine incorporation by SK&F 96365 occurred in the same concentration range (IC50: approximately 4 microM) as the blockade of capacitative Ca2+ entry in the E3 retinal organ culture. At a concentration of 5 microM SK&F 96365. DNA synthesis was reduced by 71, 40 and 32% in the E3, E7 and E9 cultures, respectively. Application of DBHQ at concentrations which led to depletion of intracellular Ca2+ stores also inhibited [3H]-thymidine incorporation with IC50 values of 20-30 microM in the different cultures. Our results suggest the involvement of Ca2+ mobilization and capacitative Ca2+ entry in the regulation of DNA synthesis in the developing neural retina.     

Neurotrophic factor for serotonergic neurons prevents degeneration of grafted raphe neurons in the cerebellum.

[³H]SCH 23390 binds stereospecifically and with high affinity to D₁ dopaminergic receptors in the developing chick retina. Autoradiographic experiments revealed that in retinas from 3-day-old chicken and embryos with 12, 14 and 16 days of development, specific labeling of [³H]SCH 23390 was mainly observed over the plexiform layers of the tissue, showing that dopaminergic D₁ receptors are localized in retina cell neurites since the initial stages of neurite formation. The total number of [³H]SCH 23390 binding sites increased 5-fold during the differentiation of the retina, while the dopamine-dependent cyclic adenosine monophosphate (AMP) accumulation was significantly decreased. Consequently, the ratio between dopamine-dependent cyclic AMP accumulation and [³H]SCH 23390 binding sites decreased 10-fold as retina differentiated, indicating that a significant portion of D₁ receptors in retinas from adult chicken are not effectively coupled to adenylate cyclase molecules.     

Coincident expression and distribution of melanotransferrin and transferrin receptor in human brain capillary endothelium

One method of iron transport across the blood brain barrier (BBB) involves the transferrin receptor (TR), which is localized to the specialized brain capillary endothelium [7]. The melanotransferrin (MTf) molecule, also called p97, has been widely described as a melanoma specific molecule, however, its expression in brain tissues has not been addressed. MTf has a high level of sequence homology to transferrin (Tf) and lactoferrin, but is unusual because it predominantly occurs as a membrane bound, glycosylphosphatidylinositol (GPI) anchored molecule, but can also occur as a soluble form. We have recently demonstrated that GPI-anchored MTf provides a novel route for cellular iron uptake which is independent of Tf and its receptor [10]. Here we consider whether MTf may have a role in the transport of iron across the BBB. The distributions of MTf, Tf and the TR were studied immunohistochemically in human brain tissues. The distributions of MTf and TR were remarkably similar, and quite different from that of Tf. In all brain tissues examined, MTf and the TR were highly localized to capillary endothelium, while Tf itself was mainly localized to glial cells. These data suggest that MTf may play a role in iron transport within the human brain.     

High affinity binding of transferrin in cultures of embryonic neurons from the chick retina.

Immunohistochemical and autoradiographic analysis of neuronal cultures from embryonic day 8 (E8) and day 11 (E11) chick retina indicate that transferrin receptors and binding sites are present on soma and neurites. Cultures maintained in the presence of transferrin expressed elevated transferrin binding due to an increase in the number of transferrin receptors. Cultures from E11 neural retina exhibited a decrease in transferrin binding when compared to E8 cultures. This appears to be due to a decrease in the number of binding sites. Neurons maintained in a transferrin-free medium supplemented with 0.4 microM of iron sulfate generally expressed slight increases in transferrin binding.     

Immunocytochemical and Biochemical Evidence for Aromatase in Neurons of the Retina, Optic Tectum and Retinotectal Pathways in Goldfish

Using an animal model in which neural aromatase is apparently overexpressed (the goldfish, Carassius auratus) and an antihuman placental antibody which specifically crossreacts with goldfish brain aromatase, aromatase-immunoreactive neuronal cell bodies and fibers have been localized within the retina. These include a subset of horizontal cells, bipolar cells, and amacrine cells of the inner nuclear layer, some fibers of the outer and inner synaptic layers and certain cells of the ganglion cell layer; photoreceptors were never labeled. Some ganglion cell projections to the brain via the optic nerve and optic tract were aromatase-positive, as were small neurons of the stratum periventriculare (SPV) and fibers of two other strata of the optic tectum. Aromatase activity, as measured by [³H]estrogen formation from [³H]androgen by tissue homogenates and cell cultures, confirmed the presence of aromatase in retina and in brain regions containing the optic tectum. This localization of the rate-limiting enzyme in estrogen biosynthesis suggests that neuroestrogen derived from circulating androgen may modulate transmission and integration of visual information important for reproduction in this species.     

Transferrin, carbonic anhydrase C and ferritin in dissociated murine brain cell cultures

It is shown here that transferrin (Tf), the iron transport protein and carbonic anhydrase C (CA C) are specifically located within oligodendrocytes in murine brain cell cultures. Ferritin (F), the major iron storage protein, was demonstrated in oligodendrocytes, as well as in astrocytes and microglial cells and was more prominent in the former. CA C and Tf were seen first after 6-7 days in culture. CA C and F positivity increased rapidly and at day 20, 80-85% of galactocerebroside + oligodendrocytes were positive for both proteins. Only a small number of oligodendrocytes was Tf+ up to day 14, after which their numbers increased rapidly until day 20, when 67% of the oligodendrocytes were Tf+. Because of the presence of Tf and F in oligodendrocytes it is suggested that these cells may play an important role in the metabolism of iron within the central nervous system.     

Role of nitric oxide in photoreceptor survival in embryonic chick retinal cell culture

The presence of nitric oxide synthase (NOS) in chick retina during development has allowed us to study the role of nitric oxide (NO) during retinal differentiation in dissociated chick retinal cell culture from embryonic day 6. We have demonstrated the presence of nicotinamide adenine dinucleotide phosphate diaphorase staining in these cultures after 3 days in vitro (Div), with a maximal intensity after 8 Div, corresponding to embryonic day 14. Immunohistochemistry studies confirmed the presence of the two isoforms of NOS, NOS-I and -III, in dissociated retinal cell cultures at 8 Div. Addition of NG-monomethyl-L-arginine, a NOS inhibitor, to retinal cell cultures prevented NO production but did not modify the appearance and the survival of ganglion and amacrine cells. However, immunohistochemical analysis with distinct markers for photoreceptor cells (rods and cones) showed that inhibition of endogenous NOS in retinal cell cultures prevented the developmental decrease of rod number between 5 and 8 Div, thus supporting the hypothesis that NO may be involved in the cell death of rods during the development of the retina.     

Changes in ganglioside profile in chick embryo retina: Studies on tissue and cell cultures

The developmental profile of gangliosides in the neural retina of the chick embryo is characterized by a progressive decrease in the concentration of GD3 complex from a high level on day 6; by a continuous increase in GD1a concentration; and by less striking increases in GD1b and GT1b concentrations during the growth phase; GM1 increases in the post-mitotic retina. Gangliosides were analyzed by thin layer chromatography and by densitometry of the TLC plates. (Ganglioside nomenclature is according to Svennerholm.³⁷)We have examined comparatively ganglioside changes in organ cultures of retina tissue from 6 day embryos (R³⁶), in cell aggregates and in primary monolayer cultures of R²⁶ cells, all maintained for 6 days in vitro. In all cases, the pattern of ganglioside changes was qualitatively similar to that in the retina in vivo. These results suggest that, unlike some other aspects of retina differentiation, the progression of ganglioside changes in the 6–12 day embryonic retina is not critically dependent on histotypic cell organization or on specific contact-dependent cell interactions; these changes appear to be largely preprogrammed in the cells at some earlier phase of development.     

Conditioned media derived from glial cell lines promote survival and differentiation of dopaminergic neurons in vitro: role of mesencephalic glia.

Neuronal differentiation is influenced by extracellular factors; however, only a few such factors have been identified for central neurons. To address this issue, we have screened media conditioned (CM) by several glial cell lines for neurotrophic effects on dopaminergic neurons in dissociated cell cultures of the E14.5 rat mesencephalon grown in serum-free conditions. To establish culture conditions under which dopaminergic cell survival depends on the exogenous support from neurotrophic factors, cell suspensions were seeded at varying densities and the number of tyrosine hydroxylase-immunoreactive (TH-IR) neurons was determined. This number was maximal at plating densities greater than 175,000 cells/cm2 and was 10-fold lower at the plating density of 80,000 cells/cm2. Cell density had only a minimal effect on [3H]dopamine uptake per TH-IR neuron. Treatment of cultures plated at 80,000 cells/cm2 with CM derived from the glial cell line, B49, the neural retina glial cell line, R33, and the Schwannoma cell line JS1, increased the number of surviving TH-IR neurons 160-330%. These effects were dose dependent and heat sensitive. All CM stimulated neurite elongation of TH-IR neurons, while only the B49-CM increased [3H]dopamine uptake. The neurotrophic effects of these media were not confined to dopaminergic neurons but increased overall neuronal density in culture by 50-100%. Moreover, all three CM were mitogenic for mesencephalic glia as demonstrated by glial fibrillary acidic protein (GFAP)-immunocytochemistry in combination with [3H]thymidine-autoradiography. By contrast, medium conditioned by the pheochromocytoma cell line, PC12, did not increase the number of astrocytes or promote the survival of dopaminergic neurons. Inhibition of glial proliferation reduced the neurotrophic effects of the B49-, R33-, and JS1-CM by 40-80%. These observations suggest that the glial cell lines B49, R33, and JS1 secrete factors that promote the survival of dopaminergic neurons and induce proliferation of glial precursors. The partial decrease of the survival-promoting effects of these CM on dopaminergic neurons in glial-free mesencephalic cultures further suggests that the observed neurotrophic effects result from the combined action of cell line-derived substances directly on neurons and indirectly via effects on mesencephalic astrocytes or astrocyte precursors.     

Transient expression of an intermediate filament-associated protein (IFAPa-400) during in vivo and in vitro differentiation of chick embryonic cells derived from neuroectoderm

The expression of an intermediate filament (IF) associated protein (IFAPa-400) and IF proteins was investigated during chick neurogenesis. Using immunoblots and indirect immunofluorescence we have found that IFAPa-400 was strongly expressed during the early events of nervous tissue ontogenesis and disappeared thereafter. IFAPa-400 was elevated in the brain and retina until ED 10 and until hatching in the cerebellum. This protein was shown to be transiently expressed in the Müller glia of the developing retina. In the brain, IFAPa-400 decreased as development proceeded in a way similar to vimentin but the latter remained elevated in the retina and the cerebellum radial glia (Müller and Bergmann cells). In all tissues examined, GFAP was detected long after the disappearance of IFAPa-400. In dorsal root ganglion cell cultures, IFAPa-400 and vimentin were absent from mature neurons but were coexpressed into supportive cells. In trunk neural crest cell cultures, IFAPa-400 and vimentin were present in all cells after one day but IFAPa-400 became undetectable after a few days of culture in differentiated melanocytes and catecholaminergic neurons. The transient expression of this giant cytoskeletal protein in non-differentiated cells deriving from the neuroectoderm could reflect a structural change which precedes overt cytodifferentiation.     

Infection of human neural cell aggregate cultures with a clinical isolate of cytomegalovirus.

Human neural cell aggregate cultures were prepared from dissociated fetal brain tissue and maintained in rotation culture. After 35 days in culture, aggregates had the histologic appearance of dense, immature, neural cells in a tightly packed neuropil. Electron microscopy revealed ultrastructural features suggestive of immature neurons and neuroglia. In addition, neuron-specific enolase and glial fibrillary acidic protein associated with radial glial cells were detected within the aggregates by immunoperoxidase staining. When infected with a laboratory-adapted strain of cytomegalovirus (CMV), [AD169], cells containing large, bizarre, nuclei and CMV-induced intranuclear inclusion bodies were dispersed throughout the aggregates at 16 days postinfection. In situ hybridization using a CMV-specific DNA probe and electron microscopy confirmed the presence of virus sequences as well as virus particles at histologic sites of cytopathology. In sharp contrast, aggregate cultures infected with a CMV strain recovered from the retina of an acquired immune deficiency syndrome (AIDS) patient with CMV retinitis and encephalitis displayed distinct foci of cytopathology at 23 days postinfection, a pattern not observed in CMV [AD169]-infected aggregates. Our findings suggest that human neural cell aggregates represent a a promising multicellular non-neoplastic culture system in which to study the replication of human neurotropic viruses within neural tissue.     

Myelin basic protein and transferrin characterize different subpopulations of oligodendrocytes in rat primary glial cultures

The iron transport glycoprotein, transferrin (Tf), localizes exclusively in oligodendrocytes in brain tissue sections. Previously, we showed that Tf is also expressed in oligodendrocytes in primary cultures established from newborn rat brains. Its developmental appearance precedes that of galactocerebroside (GC). In this study, Tf expression in primary brain cell cultures was investigated over a 4-week period in relation to GC and myelin basic protein (MBP), respectively, early and late markers of oligodendrocyte development. From 9 days in vitro and thereafter, all Tf+ cells were also found to be GC+. With increasing age the number of Tf+ cells decreased while the number of MBP+ cells increased. However, less than 10% of oligodendrocytes co-expressed Tf and MBP at any age. MBP+ cells were largely found in cell clusters which increased in size and number with age in culture. Interestingly, Tf+ cells were located around the clusters of MBP+ cells which displayed elaborate branched processes. The transient expression of Tf in oligodendrocytes which become MBP+, suggests a role for Tf in the early stages of myelinogenesis. The results also demonstrate the existence of three phenotypically distinct populations of oligodendrocytes. A new model of developmental and functional subpopulations of oligodendrocytes is proposed.     

Cognin distribution during differentiation of embryonic chick retinal cells in vitro

Differentiation of individual retina neurons is closely linked to development of retina function. This differentiation may be intrinsic to the cell or determined by the position of the cell within the developing tissue. Retina cognin, a cell-cell recognition protein, which may itself mediate position-dependent cell interactions in vivo exhibits a characteristic change in distribution during embryonic chick development. Cognin is progressively lost from the outer retina in a manner which appears position-dependent. We asked if this change in cognin distribution was actually position-dependent or intrinsic to the retina cells. Neural retina cells from 8-day-old chick embryos were cultured in vitro. Continued differentiation of the cultured cells was demonstrated by neurite outgrowth and characteristic increases in choline acetyltransferase and glutamic acid decarboxylase activity. In such cultures, the characteristic developmentally related disappearance of retina cognin occurred as in vivo. This indicated that this aspect of retina neuronal differentiation was independent of position within the tissue and likely intrinsic to individual cells after 8 days of embryonic development.     

Differential ontogenesis of D1 and D2 dopaminergic receptors in the chick embryo retina

The differentiation of D1 and D2 dopamine receptors was investigated during the ontogenesis of the chick embryo retina. Our results reveal an interesting complexity in dopaminergic differentiation, with one major receptor system developing before synapses and another one developing after. The dopamine-dependent increase of chick retina cAMP level differentiates early during retina ontogeny. By the embryonic day 10-11 10(-4) M dopamine and ADTN elicit a 13-fold increase in cAMP content of the retina. However, [3H]spiperone (D2 ligand) binds very little to crude membrane preparation of retinas from embryos in the same developmental stage (12-13 fmol/mg protein). High specific binding of [3H]spiperone is only detected after the embryonic day 17-18, attaining 80 to 100 fmol of specific spiperone binding sites in the retinas from post-hatched animals. Apomorphine also promotes the accumulation of cAMP of retinas from early embryonic stages. However, it is only 20-30% as effective as ADTN or dopamine. In addition, while the dopamine responsiveness of the tissue decreases sharply during its ontogeny, the apomorphine effect remains practically constant throughout this period. Both dopamine and apomorphine are equally effective in eliciting cAMP accumulation of retinas from post-hatched animals. Moreover, apomorphine is a potent inhibitor of dopamine-induced cAMP level of the embryonic tissue. The results presented here indicate that D1 and D2 receptors differentiate independently from each other, and that apomorphine elevates retina cAMP levels via a subclass of D1 receptors that does not desensitize significantly during retina development.     

Role of the cell recognition molecule, cognin, in GABAergic differentiation in chick retina

Previous work showed that GABAergic differentiation in developing chick retina depends on insulin and cell interactions. Here, we investigated whether it depended on cell signaling mediated by retina cognin, a 50 kDa cell recognition molecule. Cognin mediates cell adhesion in vitro and occurs on retinal neurons that become both GABAergic and cholinergic. We investigated two markers of GABAergic differentiation: glutamate decarboxylase (GAD) activity and high-affinity GABA uptake. Both increase during differentiation of retinal neurons in culture and can be easily measured. We blocked cognin-mediated cell signaling with cognin antibody and found a reduction of the developmental increase in GAD activity in cultures of retinal neurons from 7 and 11 day chick embryos. There was no reduction of high-affinity GABA uptake. This suggested that cognin-mediated signaling was necessary for the normal developmental increase in GAD but not for high-affinity GABA uptake. These results contrasted with our previous observations on cholinergic differentiation in cultured retinal neurons. We found that cognin antibody blocked the normal developmental increase in choline acetyltransferase (ChAT) only if the cells were exposed before embryonic day 7. Thus, while both GAD and ChAT activity appear to be controlled by cell signaling involving cognin, the periods of developmental sensitivity for the two differentiation markers are different. Antibodies to other adhesion molecules, Ng-CAM, and N-cadherin, did not similarly affect GAD activity. Antibodies to laminin at a 10-fold higher concentration inhibited GAD activity only in early embryonic retina. Tests for protein synthesis and “housekeeping” enzyme activity demonstrated that the cognin antibody effect was selective for neuronal differentiation pathways. Thus, GABAergic differentiation in developing retina is sensitive to cell signaling mediated in part by cognin.