Glycoprotein differences among cells of the 14-day embryonic chick neural retina

In order to test the hypothesis that the progressive layering and differentiation of cell types during the development of the neural retina are associated with cell surface alterations we have separated distinct cell populations from the 14-day embryonic chick retina. Cells of these populations have been shown to differ in associative behavior and intramembrane particle content. We now report that these cells differ in cell surface glycoproteins. Proteins were labeled with two different extrinsic labels and one metabolic label. We used enzymatic transfer of galactose from UDP-gal to cellular acceptors, and borotritide reduction after galactose oxidation as extrinsic labels. Glucosamine incorporation was used as the metabolic label. In all these cases, we were able to identify bands on electrophoretic gels which were unique to individual populations.     

On the inhibition of camel retina acetylcholinesterase activity by cycloheximide in vitro

The kinetic parameters of inhibition of camel retinal acetylcholinesterase (AChE) activity by cycloheximide (CH) were investigated. For the control system, the Michaelis–Menten constant (K _m)for the hydrolysis of acetylthiocholine iodide was found to be 0.076 mmol/L and the V _max was 0.547 mol/min per mg protein. In contrast, these parameters were decreased in the CH-treated systems. Dixon and Lineweaver–Burk plots, and their secondary replots, indicated that the inhibition was of the linear mixed type, which seems to be a combination of partial competitive and pure noncompetitive inhibition. The values of K_i(slope) and K _I(intercept) were estimated to be 3.50 and 5.68 mmol/L, respectively. K _i was greater than K_i, indicating that CH has a greater binding affinity for the peripheral site than the active site.     

Freeze-fracturing and surface labelling of embryonic neural retina cells

Freeze-fracturing of dissociated and aggregating neural retina cells from 7-day chick embryos revealed on the inner faces (PF) of the cell membrane numerous particles 6–20 nm in size. In contrast, the PF faces of blebs and some of the lobopodia that project from the cell surface were practically devoid of such particles. However, the elongated filopodia that abound on these cells showed numerous particles on their PF faces. These regional differences in the distribution of particles on PF faces of these cells are interpreted as reflecting membrane activity that leads to the formation of blebs and lobopodia. The frequent presence of “pits” at the basis of blebs and lobopodia is described. It is suggested that the “pits” are associated with the formation of these membrane projections; they may represent anchoring sites for microfilaments and for microtubules involved in the dynamic structure of the cell surface. ConA-binding sites on these cells were studied by scanning electron microscopy, using labeling with hemocyanin. The distribution of these sites on different regions of the cell surface coincided with the regional differences in the distribution of the inner membrane particles.     

Scanning electron microscopy of aggregating embryonic neural retina cells.

Scanning electron microscopy of in vitro reaggregation of trypsin-dissociated neural retina cells from 10-day chick embryos revealed that filopodial projections participate in the assembly of the dispersed cells into clusters. Freshly dissociated cells displayed numerous elongated, randomly projecting filopodia. With the onset of cell reaggregation these filopodia bridged and connected distant cells becoming shorter as the cells came together and formed aggregates. In 24-h cell aggregates only short microvilli were seen, mostly on cell surfaces facing the periphery of the aggregate. Cells dissociated from retina tissue pre-treated with inhibitors of protein synthesis, or cells exposed to these inhibitors immediately after dissociation were mostly devoid of filopodial projections; such cells failed to re-aggregate histotypically. Thus, metabolic and biosynthetic processes are required for the changes in the cell periphery which result in formation or maintenance of filopodia, and which enable trypsin-dissociated cells to reform histotypic associations. Possible relationships between the formation of filopodia and histotypic reaggregation of cells is discussed.     

Galactosyltransferase activity of intact neural retinal cells from the embryonic chicken

Permeability of electrotonic junctions between isolated and reaggregated Fundulus blastomeres was evaluated with a new fluorescent dye, Lucifer yellow CH. The dye is readily shown to pass between coupled cells. It does not enter from the bathing medium, nor does it move between cells via the enlarged extracellular space sometimes seen between them. Thus, we conclude that passage is via a private pathway, presumably provided by the gap junctions described for this tissue. In contrast to previous findings, fluorescein (as the sodium salt, uranine) also passes between coupled Fundulus cells. Although it can enter from the bathing medium, it may be less concentrated in the space between a cell pair than in the uninjected cell. Again, passage via gap junctions is indicated. Molecular models demonstrate that Lucifer yellow and fluorescein are similar in size. Thus, similarity in ability to permeate junctional membranes is to be expected.     

体外诱导鸡胚胎生殖细胞分化为神经干细胞

本研究探讨体外诱导鸡胚胎生殖细胞(EGCs)分化为神经干细胞(NSCs)的可能性.EGCs经类胚体(EB)阶段,以维生素A酸(RA)等进行诱导,在NSCs选择性培养基中筛培养扩增7 d,观察形态变化;采用RT-PCR法检测nestin基因表达及免疫细胞化学法检测nestin等NSCs特异性标志物,并对其扩增及分化能力进行观察.结果显示:EGCs经初级诱导,NSCs选择性培养基筛选培养7 d后,形成大量神经球样结构,可扩增传代;绝大部分神经球样结构呈nestin抗原阳性,表达nestin基因,且可分化为神经上皮样及少突胶质细胞.研究结果表明:RA等诱导的EGCs,经选择性培养基筛选培养可获得NSCs,有望为眼部神经变性疾病的治疗提供新的技术参考.     

The cytoprotective properties of prostaglandin E2 against the toxic effects of actinomycin C on embryonic neural retina cells.

Prostaglandins (PGs) have been shown to cytoprotect various tissue types against the toxic effects of many chemicals. The mechanism of this protection is poorly understood, but the involvement of cAMP is often implied. Only one previous study examined nervous tissue and PG protection. The present study was designed to determine if PGE2 affords cytoprotection to a more specific nervous tissue (embryonic neural retina) from the toxicity of actinomycin C (AMC) using a trypan blue exclusion assay. The lowest concentration of PGE2 (2 x 10(-5)M) had no effect, but as the concentration increased (3 x 10(-5)M and 5 x 10(-5)M), PGE2 did afford protection against AMC in a dose dependent fashion. Theophylline treated cells were not protected, suggesting that cAMP may not be the primary mechanism of protection.     

Lectin-mediated stimulation of DNA synthesis in cultures of embryonic neural retina cells

Plant lectins and other agents which are mitogenic for lymphocytes and fibroblasts were tested for their effects on DNA synthesis in primary monolayer cultures of neural retina cells from 10-day chick embryos. Concanavalin A (ConA), phytohemagglutinin (PHA), wheat germ agglutinin (WGA), and anti-retina cell antiserum significantly stimulated [³H]TdR incorporation; the maximum increase was reached 15 h after exposure of the cultures to these agents. Cells stimulated by ConA to synthesize DNA subsequently divided. The divalent succinyl derivative of ConA had a considerably lesser effect than the native tetramer, suggesting that cross-linking of cell surface components may be an important aspect of the changes that lead to the stimulation of DNA synthesis in these cells.Using [¹²⁵I]ConA, the average number of ConA-binding sites per 10-day retina cell was estimated to be 1.7 × 10⁶ (under the culture conditions employed); binding of the lectin to 25–50% of these sites was sufficient to elicit the maximal stimulation of DNA synthesis. Continuous association of the lectin with the cell surface for up to 8 h was essential for the maximal effect, since removal of the lectin from the cell surface (with α-methyl mannose) prior to this time reduced or prevented the stimulation of DNA synthesis.The stimulation by ConA of DNA synthesis in these cultures was dependent on the cell density and was reduced or absent at lower than optimal densities. Examination of this effect suggested that the frequency of intercellular contacts or specific cell associations play a role in the responsiveness of these cells to stimulation of DNA synthesis by ConA.     

Binding of receptor-hydrocortisone complexes to isolated nuclei from embryonic neural retina cells

Hydrocortisone (HC) induces glutamine synthetase in the embryonic chick neural retina. The binding of cytoplasmic receptor-hydrocortisone (R-HC) complexes to isolated retina nuclei has been studied in a cell-free system. Optimal conditions, specificity and quantitative aspects of binding were determined. The isolated nuclei retained binding specificity for the R-HC complex prepared from retina cytosol. Free HC, estradiol-receptor complexes from retina cytosol and HC-receptor complexes from mouse brain cytosol or from chick serum did not bind to the nuclei. Assuming monovalency of the binding sites, the number of nuclear acceptor sites per retina cell for the R-HC complex was estimated to be in the range of 1500. These sites were resistant to RNAse but sensitive to DNAse.     

Histogenesis and dependent glutamine synthetase inducibility in embryonic neural retina. Irreversible inhibition of differentiation by 5-bromodeoxyuridine

Young, mitotically active neural retinas from 7-day chick embryos were cultured with 5-bromodeoxyuridine (BrdU) for 8 hr or more. After this treatment, they failed to differentiate beyond the stage at which they were explanted; there was no histogenesis or increase in glutamine synthetase (GS) inducibility in intact tissues or in aggregates of dissociated cells. Normally GS can be induced in the retina with hydrocortisone as the cells cease to be mitotically active and begin showing histological organization after day 7. This inhibition by BrdU was irreversible even in the presence of excess thymidine. Overall incorporation of ¹⁴C-amino acids into protein was only slightly inhibited, and the ability of cells from treated tissue to aggregate and sort out from nonneural cell types was unaffected. Control cultures without BrdU showed considerable histogenesis and a parallel increase in enzyme inducibility. Postmitotic 10-day retinas appeared to be unaffected by BrdU. The incorporation rates of both tritiated BrdU and thymidine (dT) into DNA were 14× higher in 7- than in 10-day retinas. Simultaneous addition of excess unlabeled dT with either of the labeled nucleosides reduced their incorporation and reduced the inhibitory action of BrdU on differentiation.It is concluded that BrdU irreversibly inhibits the differentiation of retina cell surface properties involved in histogenesis and dependent cytodifferentiation without affecting already differentiated properties of the cell surface. The results support the hypothesis that histogenesis is directed by genes affecting specific cell surface properties.     

The cytoprotective properties of prostaglandin E2 against the toxic effects of actinomycin C on embryonic neural retina cells

Prostaglandins (PGs) have been shown to cytoprotect various tissue types against the toxic effects of many chemicals. The mechanism of this protection is poorly understood, but the involvement of cAMP is often implied. Only one previous study examined nervous tissue and PG protection. The present study was designed to determine if PGE₂ affords cytoprotection to a more specific nervous tissue (embryonic neural retina) from the toxicity of actinomycin C (AMC) using a trypan blue exclusion assay. The lowest concentration of PGE₂ (2 × 10⁻⁵M) had no effect, but as the concentration increased (3 × 10⁻⁵M and 5 × 10⁻⁵M), PGE₂ did afford protection against AMC in a dose dependent fashion. Theophylline treated cells were not protected, suggesting that cAMP may not be the primary mechanism of protection.     

pp60c-src expression in transdifferentiating cultures of embryonic chick neural retina cells

Chick embryo neural retinal cells transdifferentiate extensively into lens cells when cultured in Eagle's MEM containing horse and fetal calf sera (FHMEM). Such cultures express elevated levels of pp60c-src-associated tyrosine kinase activity relative to parallel cultures prevented from transdifferentiating by the addition of supplementary glucose (FHGMEM) or replacement of MEM by medium 199 (F199). Northern blotting and in vitro translation studies suggest that c-src mRNA levels are only slightly higher in late transdifferentiating (FHMEM) cultures as compared to parallel blocked (FHGMEM or F199) cultures. By immunocytochemical staining, we show that pp60c-src protein is largely localized in cell groups undergoing conversion into lens (i.e. expressing delta crystallin) in late FHMEM cultures. Initial studies of pp60c-src in chick lens tissues during development indicate that higher kinase activity is found in the epithelial cells relative to mature lens fibres. Thus pp60c-src may be expressed both during the differentiation of lens cells in vivo and during the transdifferentiation of neural retina cells into lens in vitro.     

Spontaneous and lectin-induced redistribution of cell surface receptors on embryonic chick neural retina cells.

The mobility of plant lectin receptors in the plane of the membrane is examined for cells prepared from embryonic chick neural retinas by a variety of procedures. Cells liberated from the intact tissue by trypsin treatment followed by mechanical dissociation are able to redistribute their receptors into 'caps' both spontaneously and in the presence of a multivalent lectin. These cells, dispersed by trypsinization, upon repair in culture for a suitable period of time lose their ability to redistribute lectin receptors. Cells dispersed by mechanical means without prior trypsin treatment are unable to undergo 'cap' formation. In addition, cells within intact tissues are also unable to redistribute their lectin receptors into 'caps.' Based on these observations we propose that within solid tissues which have assumed their characteristic architecture, cell surfaces are immobilized, and that this phenomenon may be a critical parameter in determining the potential of a cell to undergo morphogenetic rearrangements.     

Induction of epithelio-mesenchymal transformation of quail embryonic neural cells by inhibition of atypical protein kinase-C

Epithelio-mesenchymal transition, which involves the re-organisation of cell-cell adhesion molecules and the actin cytoskeleton, can be induced in embryonic neural epithelium in vitro by protein kinase-C inhibitors. A non-inhibitory analogue, BIM V, and potent inhibitors of other kinases are not active. This suggests a central role for C-kinases, although the powerful specific C-kinase inhibitors BIM I and Ro 31-8220 show lower than expected activity. Co-inhibition by several kinases is unlikely to account for this, since no potentiation occurs when these are combined with potent inhibitors of other kinases. BIM I and Ro 31-8220 strongly inhibit only conventional calcium-regulated C-kinases; this and the lack of effect of TMB-8, which inhibits calcium release, suggests that novel and/or atypical isoforms are involved. Various potentiators and activators of conventional and novel C-kinases have no obvious effect alone and fail to reduce the effect of staurosporine, suggesting that atypical C-kinases are critical. The presence of C-kinase isoforms in the E2 embryonic neural tissues has been probed on Western blots, revealing immunoreactivity for the atypical isoforms 1 (or 5) and + and the !, %, l and 7 isoforms. Immunofluorecent localisation on sections of embryos has shown the widespread distribution of conventional and novel isoforms but only the atypical isoforms 5 and + are enriched at the apical margins of the neural and other epithelia; they overlap with the cell-cell adhesion molecule N-cadherin and with F-actin. Thus, epithelio-mesenchymal transition in the embryonic neural epithelium in vitro is induced by inhibiting protein kinase activity, probably via an atypical protein kinase-C; atypical protein kinase-C isoforms are present in the tissue at the appropriate developmental stage and subcellular site in cells capable of epithelio-mesenchymal transition.     

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

Summary 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 (0.5μm) 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. This research was supported in part by grant EY-04892 and RR-0715 from the National Institutes of Health, Bethesda, MD, and a grant from the W.W. Smith Foundations     

A requirement for trypsin-sensitive cell-surface components for cell-cell interactions of embryonic neural retina cells

A quantitative assay was used to measure the rate of collection of a population of embryonic neural retina cells to the surface of cell aggregates. The rate of collection of freshly trysinized cells was limited in the initial stages by the rate of replacement of trypsin-sensitive cell- surface components. When cells were preincubated, or "recovered," and then added to cell aggregates, collection occurred at a linear rate and was independent of protein and glycoprotein synthesis. The adhesion of recovered cells was temperature and energy dependent, and was reversibly inhibited by cytochalasin B. Colchicine had little effect on collection of recovered cells. Antiserum directed against recovered cell membranes was shown to bind to recovered cells by indirect immunofluorescence. The antiserum also was shown to inhibit collection of recovered cells to aggregates, suggesting that at least some of the antigens identified might be involved in the adhesion process. The inhibitory effect of the antiserum was dose dependent . Freshly trypsinized cells absorbed neither the immunofluorescence activity nor the adhesion-inhibiting activity. Recovered cells absorbed away both activities. In specificity studies, dorsal neural retina cells adhered to aggregates of ventral optic tectum in preference to aggregates of dorsal optic tectum. The adhesive specificity of the dorsal retina cells was less sensitive to trypsin than the adhesive specificity of ventral retina cells which adhered preferentially to dorsal tectal aggregates only after a period of recovery.