Comparison of the early chromatin reaction of the mouse thymocytes incubated with phytohemagglutinin and Concanavalin A

Summary The proventriculus, gizzard and pyloric antrum (region between the gizzard and the duodenum) of 18-day Black Australorp chick embryos and of chicks within 30 h of hatching have been studied by electron microscopy. D and EC cells, and putative G, D₁ and A-like cells were identified (terminology of Solcia et al., 1973) but no ECL cells. No endocrine cells of any kind were revealed in the gizzard.Supported by grants from the Senyte Research Comittee of the University of the Witwaterstrand, Johannesburg     

Origin of the iris sphincter muscle in chick embryo

The origin of the iridial sphincter muscle in chick embryo was investigated by means of immunohistochemistry. Desmin immunoreactive cells are shown in the mesenchymal stroma overlying the anterior epithelial layer of the iris in 4 1/2-day chick embryos. In 9-11-day chick embryos also some cells of the posterior epithelium near the pupillary margin, and of the iridial lamella show a slighter desmin-immunoreactivity. This finding agrees with a double origin of the iridial sphincter muscle: an early mesenchymal one and a later epithelial other.     

Microtubules and filaments in developing axons and optic stalk cells

Fibrous structures have been studied in the developing optic nerve of chick embryos. The first ganglion cell axons (3-day embryos) were of moderate size, with both neurofilaments and microtubules. Subsequently (4- and 5-day embryos), very small axons were also present. In thesc embryos and in the 4-day hatched chick, the density of microtubules fell within the same range for all but the very small axons, which tended to have more microtubules per unit area. Filaments similar to those previously thought to represent neurofilaments in other parts of the embryonic nervous system were present in the early optic stalk cells, calling into question the reliability of identifying early nerve cells on the basis of 'neurofilaments'.     

The possibility of lens formation in explants of the retina and pigment epithelium of the eye in chick embryos

Undissociated tissue explants of the retina and retinal pigment epithelium (RPE) of 3,5-, 4-, 5- and 8-day-old chick embryos were cultured in vitro. After 7 days in culture, lentoids were observed in explants of either retina or RPE from 3,5-, 4- and 5-day-old embryos. As demonstrated by immunohistochemistry, these lentoids contained specific chick lens proteins (alpha-, beta- and delta-crystallins). No crystallin-containing cells were found in eye tissue explants from 8-day-old embryos. However, when 5-bromo-deoxyuridine (25 microM) was introduced into the medium at the beginning of culturing (for 12 h), large eosinophilic cells containing alpha-, beta- and delta-crystallins were detected in retinal explants of the 8-day old embryos. Thus, retina and RPE of 3,5-5-day-old chick embryos are capable of lens differentiation after explantation in vitro without dissociation into individual cells. This capacity is lost during development.     

A developmental study of murine epidermal Langerhans cells

Prospective skin prior to invasion by neural crest cells was dissected from 10.5-day mouse embryos and cultivated in chick embryo hosts. The graft tissue was prepared for the demonstration of both mouse and chick cells, pigment cells, and Langerhans cells. Chick cells were not found in the graft mouse epidermis; however, ATPase-positive and osmium iodide-positive cells were present. Electron microscopic examination revealed that, in younger grafts, only indeterminate cells could be found among the keratinocytes. In older grafts, both indeterminate cells and Langerhans cells with granules were seen. The evidence affirms that epidermal Langerhans cells are not related to pigment cells.Based on the developmental nature of Birbeck (Langerhans) granules from the cytomembrane, it is proposed that the granule no longer be considered as specific to and characteristic of epidermal Langerhans cells. Rather, Langerhans cells should be defined as ATPase-positive, desmosome-free cells within stratified squamous, potentially keratinizing, epithelia. Thus epidermal, ATPase-positive indeterminate cells and such cells with Birbeck granules both should be considered as components of the Langerhans cell series.Normal chick skin does not show ATPase-positive cells. However, when 10.5-day mouse embryo ectoderm was inserted under the ectoderm of chick embryos, the resulting chimeric epidermis possessed ATPase-positive cells. It is proposed that epidermal Langerhans cells are of ectodermal origin.     

Inductive properties of fibroblastic cell cultures derived from rat intestinal mucosa on epithelial differentiation

The present study represents a first attempt to elucidate the regulatory properties displayed by the non-epithelial portion of the intestinal mucosa, growing as fibroblasts in monolayer cultures. Thus, we compared the inductive action of 6-day suckling rat duodenal fibroblasts with that displayed by chick embryonic intestinal mesenchyme on the heterotypic cytodifferentiation of 5 1/2-day chick embryonic gizzard endoderm. The latter, isolated by 0.03% collagenase, was surrounded by intestinal intramucosal fibroblastic cell sheets. As control experiments, fibroblastic cells derived from the intestinal muscle or from 20-day fetal rat skin and lung were used. Every type of association was grafted into the coelomic cavity of 3-day chick embryos for 11 to 12 days, a system providing their vascularization and growth. The results clearly demonstrate that the mucosal fibroblastic cells of rat intestine were as potent as embryonic intestinal mesenchyme in inducing brush-border enzymes like sucrase and maltase, in conformity with an induced intestinal morphology. In contrast, the control fibroblastic cells were completely ineffective.     

Migratory and organogenetic capacities of muscle cells in bird embryos

Summary The migratory and organogenetic capacities of muscle cells at different stages of differentiation were tested in heterospecific chick/quail recombinants. Grafts containing muscle cells were taken from the premuscular masses from 4- to 5-day quail embryos, from the limb or trunk muscles of 12-day embryonic and 4-day post-natal quails, and from experimentally produced bispecific premuscular masses in which the myoblasts are of quail origin and the connective tissue cells of chick origin. Grafts were implanted into 2-day chick embryos in place of the somitic mesoderm at the limb level. Hosts were examined 4 to 7 days after operation.After implantation of a piece of premuscular mass, quail cells were found at and around the site of the graft in the truncal region and within the limb as far as the autopod. Quail cells participated predominantly in the trunk and limb musculature, which contained a number of quail myotubes and of bispecific quail/chick myotubes. Apart from skeletal muscles, quail cells contributed sporadically to nerve envelopes and blood vessel walls in the limb.When the graft was of bispecific constitution, quail nuclei in the limb and the trunk were found exclusively in monospecific and bispecific myotubes.After implantation of differentiated embryonic or post-natal muscle tissue, quail cells in the limb contributed only sporadically to nerve envelopes and blood vessel walls, while in the trunk they also participated in the formation of muscles and tendons.It is concluded that the myogenic cells in 4 to 5-day quail premuscular masses are still able to undergo an extensive migration into the limb buds and there participate in the formation of myotubes and anatomically normal muscles. They display developmental potentialities equivalent to those of the somitic myogenic stem cells. These capacities are lost in 12-day embryonic muscles.     

Positive inotropic action of acetylcholine on the heart ventricles of the chick embryo

Acetylcholine increased twitch tension in the whole ventricle or in ventricular strips from 2-10-day chick embryos. The effect of acetylcholine was mediated by muscarinic receptors, since it was prevented by atropine, but not by tubocurarine or propranolol. Prostigmine significantly increased the sensitivity to acetylcholine in the strips from 7-day embryos, being almost ineffective in the strips from 3-day embryos. The decrease in acetylcholine sensitivity in the developing chick embryo is presumably associated with the increase in cholinesterase activity of the myocardial tissue.     

Monoclonal antibodies specific to quail embryo tissues: their epitopes in the developing quail embryo and their application to identification of quail cells in quail-chick chimeras.

Quail-chick chimeras have been used extensively in the field of developmental biology. To detect quail cells more easily and to detect cellular processes of quail cells in quail-chick chimeras, we generated four monoclonal antibodies (MAb) specific to some quail tissues. MAb QCR1 recognizes blood vessels, blood cells, and cartilage cells, MAb QB1 recognizes quail blood vessels and blood cells, and MAb QB2 recognizes quail blood vessels, blood cells, and mesenchymal tissues. These antibodies bound to those tissues in 3-9-day quail embryos and did not bind to any tissues of 3-9-day chick embryos. MAb QSC1 is specific to the ventral half of spinal cord and thymus in 9-day quail embryo. No tissue in 9-day chick embryo reacted with this MAb. This antibody binds transiently to a small number of brain vesicle cells in developing chick embryo as well as in quail embryo. A preliminary application of two of these MAb, QCR1 and QSC1, on quail-chick chimeras of neural tube and somites is reported here.     

Metabolism of 4-hydroxyaminoquinoline-1-oxide and its binding to DNA in chick embryos

The metabolic pathway of 4-hydroxyaminoquinoline-1-oxide (4HAQO) and its binding to DNA was studied in 2-day chick embryos administered [G-3H]4HAQO in a shell-less culture. The 4HAQO rapidly metabolized into non-carcinogenic compounds and 1 h after administration only very small amounts of free 4HAQO could be detected in the embryo cells. The amount of DNA-bound 4HAQO in the embryo cells reached a maximum 2 h after administration, then began to decrease. The maximum extent (mu mol/mol P of nucleotide) was 18.2, equivalent to 1 molecule of 4HAQO-purine adducts per 2.8 X 10(4) base pairs of DNA. It was possible to detect removal of 4HAQO-purine adducts from DNA in chick embryo cells in a shell-less culture. A dose-response relationship for the killing effect of 4HAQO on 2-day embryos was observed in the range of 0.24-24 nmol 4HAQO per embryo. The practicality of the present method of administration of 4HAQO for 'flash administration' of compounds to chick embryo and the advantages of the shell-less culture method which provides access for biochemical and developmental studies of chick embryos were also discussed.     

Immunologic detection of retina cognin on the surface of embryonic cells

The retina cell-aggregating glycoprotein, referred to as the retina cognin, has been demonstrated to be located at the surface of embryonic neural retina cells. The term cognin is used to indicate its postulated role in the mechanism of mutual recognition and morphogenetic association of embryonic cells. Antiserum was prepared to the highly purified retina cognin derived from isolated cell membranes of chick embryo retina, and it was used to detect the cognin on cells from chick embryos by means of complement-mediated cell lysis. Retina cells (from 10-day embryos) freshly dissociated with trypsin showed little—if any—lysis by the cognin antiserum; this is consistent with the sensitivity of the cognin to trypsin. However, the cells became susceptible to immunolysis after a period of incubation at 37 °C, which indicates regeneration of the cognin at the cell surface during the recovery period. This regeneration required protein synthesis. Immunofluorescence tests showed binding of the antiserum to the surface of the recovered cells, thereby further demonstrating the surface location of the cognin. The presence, availability or ability to regenerate the cognin, as assayed here, declined sharply with the embryonic age of the cells. Addition of exogenous cognin to freshly trypsin-dissociated retina cells (from 10-day embryos) markedly increased their susceptibility to immunolysis by the cognin antiserum, which indicates that the added cognin becomes associated with the surface of these cells. In contrast, addition of retina cognin to cells freshly trypsinized from 10-day embryo optic tectum and cerebrum, or from 14-day retina did not increase their susceptibility to immunolysis by the cognin antiserum. These results are consistent with earlier findings that enhancement of cell aggregation by the retina cognin is tissue-specific and stage-specific. Cells from non-neural tissues of the chick embryo were not lysed by the retina cognin antiserum. However, neural tissues, such as optic tectum, were found to contain cells which showed surface cross-reaction with the retina cognin antiserum.     

Development of the enteric nervous system in chick embryonic duodenum in terms of the distribution of tubulin

An immunohistochemical method that uses anti-tubulin was utilized to observe the development of the enteric nervous system in chick embryonic duodenum. Neural crest cells, and enteric neuroblasts, or enteric ganglia, which derive from neural crest cells were clearly shown as sharp immunoreactive regions of tubulin. The distributions of enteric neuroblasts and enteric ganglia in chick duodena were in agreement with results of previous reports in which different techniques were used. The initial stage at which cells of neural crest origin were present in the duodenal walls (4-day-old embryos) was earlier than the initial stage (about 6-day-old embryos) reported earlier. This was verified by transmission electron microscopy. Also, the tubulin that is a component of the enteric nervous system was shown to be stable at a low temperature. This tubulin-immunostaining method provides a useful histochemical technique with which to study the development of the enteric ganglion and the function of tubulin as a component of the enteric nervous system.     

Prebursal stem cells in the intraembryonic mesenchyme of the chick embryo at 7 days of incubation.

Cyclophosphamide-treated 18-day-old chick embryos were transplanted with cells from 7-day intraembryonic mesenchyme; the recipients and donors were identical at the major histocompatibility locus. At the age of 35 days, the cell recipients were studied to determine the reconstitution capacity of the transplanted cells. The transplantation resulted in a complete restoration of IgM and IgG class antibody production against human gammaglobulin and Brucella abortus, and of microscopic morphology of the bursa of Fabricius and of the germinal center formation in the spleen. These findings demonstrate that 7-day intraembryonic mesenchyme of the chick embryo harbor prebursal stem cells. These findings confirm our previous observations in the yolk sac-embryo chimeras indicating that lymphoid stem cells originate in the intraembryonic hematopoietic sites.     

Appearance of brush-border antigens and sucrase in the allantoic endoderm cultured in recombination with digestive-tract mesenchymes

Summary Allantoic endoderm of 3.5-day chick embryos was cultured in recombination with digestive-tract mesenchymes of 6-day chick embryos, and the differentiation of the endoderm was studied, with special attention being given to the appearance of brush-border (BB) antigens and sucrase. Irrespective of the origin of the associated digestive-tract mesenchymes, the allantoic endoderm differentiated into a columnar epithelium, expressing BB antigens and sucrase, and also into a BB antigen-negative pseudostratified or stratified epithelium of cuboidal or columnar cells with PAS or alcian blue staining in the apical portion or a BB antigen-negative stratified squamous epithelium. These results suggest that 3.5-day allantoic endoderm has the potency to differentiate into intestinal and cloacal epithelium.     

Changes in lectin-induced deoxyribonucleic acid synthesis in cultures of chick-embryo fibroblasts at various stages of development

Concanavalin A and Robinia pseudoacacia lectin decreased [(3)H]thymidine incorporation into acid-insoluble material of fibroblasts cultured from 6-10-day chick embryos. In contrast, these lectins stimulated [(3)H]thymidine incorporation in cells from 16-day embryos. These effects are due to neither [(3)H]thymidine permeability modification nor toxicity of the lectins. The specificity of lectin action was proved by blocking experiments with alpha-methyl mannopyranoside and with anti-(Robinia lectin) serum.     

Inaccessibility of certain Ricinus lectin binding sites due to the increase in hyaluronic acid during chick embryo development

Abstract. Chick embryo fibre-blasts constitute a useful model for investigating cell surface differentiation using Ricinus lectin as a marker. Fibroblasts from 8-day chick embryos had two classes of Ricinus lectin binding sites, whereas those from 16-day embryos displayed only one class. Hyaluronidase treatment of fibroblasts from 8-day embryos had no effect on their capacity to bind Ricinus lectin;.however after this treatment, 16-day cells resembled 8-day cells since the former also exhibited two classes of lectin-binding sites. Treatment with hyaluronidase released 2–5 times more hyaluronic acid from the older cells than from the younger cells. The same hyaluronidase treatment did not change the number of 8-day cells detached by trypsin from the substrate, but increased the number of detached 16-day cells.
These observations suggest (i) that the greater adhesiveness to the substrate of the 16-day cells might be due to the presence on the cell surface of a larger amount of glycosaminoglycans at 16 days than at 8 days, and (ii) that the increased accumulation of hyaluronic acid on the cell surface might be involved in an alteration in the cell membrane during differentiation.     

Cell growth and thymidine incorporation changes induced by Dolichos lectin in embryo fibroblasts at various stages of differentiation.

We report here the effect of Dolichos lectin on chick embryo fibroblasts from embryos between 6th and 16th day of development. There is evidence that Dolichos lectin decreases cell number and proportion of cells incorporating tritium labelled thymidine in case of chick embryo fibroblasts of 6th, 8th and 10th day of development. Dolichos lectin stimulated the proliferation of 16-day old embryo cells. No effect was noticed on 12-day embryo cells at different concentrations of Dolichos lectin used. This lectin is specifically inhibited by N-acetyl-D-galactosamine and anti-Dolichos lectin serum. The difference in response by cells during different stages of embryonic development could perhaps be explained as some regulatory changes occurring on the cell surface.     

Do Peanut Agglutinin Receptors on Somites Control the Behavior of Neural Cells?

Peanut agglutinin (PNA) receptors are expressed in the caudal halves of sclerotomes in chick embryos after 3 days of incubation (stages 19–20 of Hamburger & Hamilton). The neural crest cells forming dorsal root ganglia (DRG) and motor nerves appear to avoid PNA positive regions and concentrate into rostral halves of sclerotomes. To investigate the role of PNA receptors in gangliogenesis and nerve growth, we examined PNA binding ability in quail sclerotomes and in chick-quail chimeric embryos made by transplanting quail somites to chick embryos, comparing the development of DRG, motor nerves and sclerotomes. PNA did not bind to any part of the somites of 4.5-day quail embryos, although dorsal root ganglia and motor nerves appeared only in the rostral halves of sclerotomes as in chick embryos. Moreover, in spite of no PNA binding ability of the transplanted quail somite in 4.5-day chick-quail chimeric embryos, DRG and motor nerves derived from chick tissues appeared only in the rostral halves of the sclerotomes derived from these somites. Thus, both quail and chick neural crest cells and motor nerves recognized the difference between the rostral and caudal halves of sclerotomes of quail embryos in the absence of PNA binding ability, indicating that PNA binding site on somite cells does not support the selective neural crest migration and nerve growth.     

Inaccessibility of certain Ricinus lectin binding sites due to the increase in hyaluronic acid during chick embryo development

Chick embryo fibroblasts constitute a useful model for investigating cell surface differentiation using Ricinus lectin as a marker. Fibroblasts from 8-day chick embryos had two classes of Ricinus lectin binding sites, whereas those from 16-day embryos displayed only one class. Hyaluronidase treatment of fibroblasts from 8-day embryos had no effect on their capacity to bind Ricinus lectin; however after this treatment, 16-day cells resembled 8-day cells since the former also exhibited two classes of lectin-binding sites. Treatment with hyaluronidase released 2-5 times more hyaluronic acid from the older cells than from the younger cells. The same hyaluronidase treatment did not change the number of 8-day cells detached by trypsin from the substrate, but increased the number of detached 16-day cells. These observations suggest (i) that the greater adhesiveness to the substrate of the 16-day cells might be due to the presence on the cell surface of a larger amount of glycosaminoglycans at 16 days than at 8 days, and (ii) that the increased accumulation of hyaluronic acid on the cell surface might be involved in an alteration in the cell membrane during differentiation.     

Changes in protein glycosylation during chick embryo development

To investigate the molecular changes in cell-surface glycoproteins during chick embryo development, fibroblasts from 8- and 16-day embryos were extensively digested by pronase after (i) metabolic labeling with radioactive precursors and (ii) external labeling. Two main classes of glycopeptide pronase digestion product were distinguished by Sephadex G-50 column chromatography. The large material excluded was mostly composed of glycosaminoglycans. The small retarded glycopeptides underwent age-related modifications. Those in the 8-day cells were mainly N-linked, whereas 16-day cells contained both O- and N-linked glycopeptides. The evolution of high-mannose chains in younger cells to complex-type chains in the older cells is suggested by (i) the decrease in the mannose-to-galactose and mannose-to-N-acetylglucosamine ratio with embryo development, and (ii) the fact that endo-β-N-acetylglucosaminidase H treatment released more oligomannosyls from younger than from older embryo cell glycopeptides. Small glycopeptides were also more highly sialylated in 16-day cells than in 8-day cells. The present results provide the first biochemical evidence that both quantitative and qualitative modifications occur in cell-surface glycoconjugates during the late stages of chick embryo development.