Progenitor cells of the definitive erythroid series in the chick embryo

Chick embryos, developing in ovo, were treated with methyllabeled tritiated thymidine at 3 days. Definitive erythroid cells isolated from such embryos at 6 days had incorporated tritiated thymidine into nuclear DNA. Progenitor cells for the definitive erythroid cell series appear, therefore, to exist in the embryo prior to the initiation of definitive erythropoiesis and are capable of DNA synthesis.     

Separation of primitive and definitive erythroid cells of the chick embryo

The primitive and definitive erythroid cells of the chick embryo are separated preparatively by means of velocity sedimentation at unit gravity in BSA gradients. Analyses of the hemoglobins contained by the fractionated cells show a segregation of different hemoglobins between the primitive and definitive cells. Studies of the incorporation of [³H]leucine show that the fractionated cells are normal with respect to their protein synthetic activities and that their relative rates of incorporation are markedly different.     

Chromatin of primitive erythroid cells from the chick embryo

Differentiation of primitive erythroid cells derived from the yolk sac of the chick embryo is accompanied by changes in the morphology of and in the physicochemical properties of the nucleus. Microfluorimetry of individual nuclei stained with acridine orange was performed on thermally denatured cells. Measurements were made at 530 nm (green fluorescence) and 590 nm (redfluorescence). The ratio of these two measurements was used to monitor the susceptibility of chromatin to thermal denaturation. Differences were found (a) between mature erythrocytes and dividing erythroblasts, and (b) between dividing erythroblasts from successive cell generations of the erythroid series. There were differential characteristics of AO binding during thermal denaturation as signified by F₅₃₀ and F₅₉₀ measurements. The temperature at which the increase of the ratio (F₅₉₀/F₅₃₀) was 50% of its maximum was approximately 70° C for erythroblasts from the fifth generation (day 4), 80–85° C for the sixth generation (day 5), and 85–90° C for the nondividing erythrocytes (day 8). Interpretation of these differences may be complicated by changes in the sensitivity of nuclear proteins to the interactive effects of 0.15 M NaCl and thermal denaturation.     

Effect of steroids on definitive localization of primordial germ cells in the chick embryo.

It has been suggested that PGCs are attracted to developing gonads by a chemotactic-like agent secreted by the gonads and that this agent might be steroidal in nature. This study was undertaken to ascertain whether specific exogenous steroid hormones exert an influence on germ cell colonization of the gonads, by enhancing, inhibiting or otherwise interfering with it. Testosterone cypionate in cottonseed oil, crystalline testosterone propionate, estrone in aqueous suspension and crystalline estradiol-17beta were adminstered to chick embryos at 33 hours incubation. Normally developed embryos, those receiving cottonseed oil (vehicle for testosterone cypionate) and those receiving cholesterol served as controls. A decrease in the number of germ cells in the gonadal area at five days of incubation occurred in all groups receiving the androgens and estrogens. However, in only one group (that receiving testosterone cypionate) was this decrease found to be significant. The mean number of germ cells found in the cottonseed oil controls and the cholesterol controls closely paralleled that of the normally developed controls. Normal asymmetry in the distribution of the germ cells favoring the left side in the chick was not affected in any of the groups; however, the percentage distribution of the germ cells between the right and left gonads at this early stage appeared to be affected.     

Early development of the chick embryo

The ultrastructure of the early chick embryo was investigated, using scanning (SEM) and transmission electron microscopy (TEM). Eggs were obtained from the shell gland by injecting hens intravenously with a synthetic prostaglandin or arginine vasopressin. Embryos were examined during late cleavage (stages IV–VI, Eyal-Giladi and Kochav, '76), formation of the area pellucida (stages VII–XI), and formation of the hypoblast (stages X–XIV). SEM highlighted the reduction in cell number at the underside of the embryo during formation of the area pellucida although it became apparent that the thickness of the embryo is not reduced to a single layer of cells at stage X. In addition, blastomeres at the perimeter of embryos (stages V–VI) project filopodial extensions onto a smooth membrane that separates the sub-embryonic cavity from the yolk. During hypoblast formation, epiblast cells generate stellate projections at their basal aspect, thus providing a meshwork for the advancing secondary hypoblast cells. By stage XII the epiblast was one cell thick and reminiscent of a columnar epithelium when viewed transversely. Cells of the deep portion of the posterior marginal zone were distinguished morphologically in the stage XII embryo by their many cell surface projections and ruffled appearance. Blastomeres at the perimeter of stage V–VI embryos projected filopodial extensions onto a smooth membrane which separates the sub-embryonic cavity from the yolk. This membrane is presumed to be confluent with the cytolemma. Evidence is presented demonstrating the presence of intracellular membrane-bound droplets which are hypothesised to contain sub-embryonic fluid. © 1993 Wiley-Liss, Inc.     

Hemoglobin synthesis in isolated erythroid colonies from the chick embryo.

Primary cultures derived from mechanically dissociated definitive streak chick blastoderms were grown in a warm air stream on the stage of inverted phase microscope, through which in vitro erythroid development could be observed. Proerythroid cells divide three or four times in 48 hr to give rise to erythroid colonies ranging from 10 to 1000 cells, depending on the size of the blastoderm fragments from which they were derived.Erythroid cell development follows a similar course in cultures grown in a carbon dioxide incubator. Colonies consisting of about 50 cells, derived from blastoderm fragments containing 5 to 10 cells, were isolated and labeled with [³H]leucine, and their labeled hemoglobins were analyzed by isoelectric focusing. Both early hemoglobins (E,M,P,P′, and P″) and late hemoglobins (A and D) are made in colonies derived from single blastoderm fragments. The ratio of late to early hemoglobins is about 1.7 in all colonies analyzed. The implications of this finding for the clonal model of erythroid development are discussed.     

Epiblast and primitive-streak origins of the endoderm in the gastrulating chick embryo

Gastrulation is characterized by the extensive movements of cells. Fate mapping is used to follow such cell movements as they occur over time, and prospective fate maps have been constructed for several stages of the model organisms used in modern studies in developmental biology. In chick embryos, detailed fate maps have been constructed for both prospective mesodermal and ectodermal cells. However, the origin and displacement of the prospective endodermal cells during crucial periods in gastrulation remain unclear. This study had three aims. First, we determined the primitive-streak origin of the endoderm using supravital fluorescent markers, and followed the movement of the prospective endodermal cells as they dispersed to generate the definitive endodermal layer. We show that between stages 3a/b and 4, the intraembryonic definitive endoderm receives contributions mainly from the rostral half of the primitive streak, and that endodermal movements parallel those of ingressing adjacent mesodermal subdivisions. Second, the question of the epiblast origin of the endodermal layer was addressed by precisely labeling epiblast cells in a region known to give rise to prospective somitic cells, and following their movement as they underwent ingression through the primitive streak. We show that the epiblast clearly contributes prospective endodermal cells to the primitive streak, and subsequently to definitive endoderm of the area pellucida. Finally, the relationship between the hypoblast and the definitive endoderm was defined by following labeled rostral primitive-streak cells over a short period of time as they contributed to the definitive endoderm, and combining this with in situ hybridization with a riboprobe for Crescent, a marker of the hypoblast. We show that as the definitive endodermal layer is laid down, there is cell-cell intercalation at its interface with the displaced hypoblast cells. These data were used to construct detailed prospective fate maps of the endoderm in the chick embryo, delineating the origins and migrations of endodermal cells in various rostrocaudal levels of the primitive streak during key periods in early development.     

Haemoglobin biosynthesis site in rabbit embryo erythroid cells

Properly metabolized globin synthesis and iron uptake are indispensable for erythroid cell differentiation and maturation. Mitochondrial participation is crucial in the process of haeme synthesis for cytochromes and haemoglobin. We studied the final biosynthesis site of haemoglobin using an ultrastructural approach, with erythroid cells obtained from rabbit embryos, in order to compare these results with those of animals treated with saponine or phenylhydrazine. Our results are similar to those obtained in assays with adult mammals, birds, amphibians, reptiles and fish, after induction of haemolytic anaemia. Therefore, the treatment did not interfere with the process studied, confirming our previous findings. Immunoelectron microscopy showed no labelling of mitochondria or other cellular organelles supposedly involved in the final biosynthesis of haemoglobin molecules, suggesting instead that it occurs free in the cytoplasm immediately after the liberation of haeme from the mitochondria, by electrostatic attraction between haeme and globin chains.     

Evidences that hemoglobin switch in the chick embryo depends on erythroid cell line substitution

Chemical identifications of various hemoglobin types were performed on unfractionated erythroid cells derived from chicken embryos at 5 and 7 days of development and on purified primitive and definitive cells. Proteins were pulse-labelled in primitive erythroid cells at various times of culture to identify those actually synthesized. The data show that primitive cells contain and synthesize only embryonic hemoglobins at all stages of maturation and definitive cells contain adult and minor embryonic hemoglobins, but no major embryonic hemoglobins, not even in trace amounts. These results support a model for hemoglobin switch in the chicken embryo based on cell line substitution.     

Early development of the primitive cranial vault in the chick embryo.

The calcified tissues involved in the early morphogenesis of the cranial vault were studied by microradiographic analysis and histological techniques in 12 chick embryos on the 9th, 12th, and 14th days of incubation. On the 9th day, the frontal, parietal, and squamosal bones are comprised of a thin lamina of chondroid tissue deposited at a short distance from the fibers of the dura mater. Woven bone formation takes place in the calvarial mesenchyme only after the 12th day of incubation and occurs mainly on the external side of the chondroid primordium. The present data obviously indicate that the primitive desmocranium of the chick embryo, which is usually known to be formed by intramembranous ossification, consists first of chondroid tissue. This tissue represents thus the initial modality of skeletogenic differentiation within the cephalic mesenchyme of the cranial vault.