Experimental reversal of polarity in chick embryo epiblast sheets in vitro

The dorso-ventral polarity of cells within sheets of epiblast from early chick embryos can be experimentally reversed by applying low voltages across them in experimental chambers. The induced reversal is stable and affects the position of histochemically and ultrastructurally demonstrable markers.     

MyoD-positive epiblast cells regulate skeletal muscle differentiation in the embryo

MyoD mRNA is expressed in a subpopulation of cells within the embryonic epiblast. Most of these cells are incorporated into somites and synthesize Noggin. Ablation of MyoD-positive cells in the epiblast subsequently results in the herniation of organs through the ventral body wall, a decrease in the expression of Noggin, MyoD, Myf5, and myosin in the somites and limbs, and an increase in Pax-3-positive myogenic precursors. The addition of Noggin lateral to the somites compensates for the loss of MyoD-positive epiblast cells. Skeletal muscle stem cells that arise in the epiblast are utilized in the somites to promote muscle differentiation by serving as a source of Noggin.     

Tracking morphogenetic tissue deformations in the early chick embryo

Embryonic epithelia undergo complex deformations (e.g. bending, twisting, folding, and stretching) to form the primitive organs of the early embryo. Tracking fiducial markers on the surfaces of these cellular sheets is a well-established method for estimating morphogenetic quantities such as growth, contraction, and shear. However, not all surface labeling techniques are readily adaptable to conventional imaging modalities and possess different advantages and limitations. Here, we describe two labeling methods and illustrate the utility of each technique. In the first method, hundreds of fluorescent labels are applied simultaneously to the embryo using magnetic iron particles. These labels are then used to quantity 2-D tissue deformations during morphogenesis. In the second method, polystyrene microspheres are used as contrast agents in non-invasive optical coherence tomography (OCT) imaging to track 3-D tissue deformations. These techniques have been successfully implemented in our lab to study the physical mechanisms of early head fold, heart, and brain development, and should be adaptable to a wide range morphogenetic processes.     

Cytochemical study of the ovary cells in the chick embryo

In the present work, cytochemical studies of mucosubstances, 3-beta-hydroxysteroid dehydrogenase and lipids in the different cellular types of chick embryo female gonads were performed, at 7, 11, 15, and 19 days of embryonal development. Oocytes from the cortical zone of the left ovary were characterized by the presence of a juxtanuclear cytoplasmic cap, which was basophilic, PAS positive, alcianophilic and acidophilic and was related to Balbiani's vitelline body. These staining characteristics either decreased or disappeared from 15 days in oocytes of the normal left ovary medulla as well as in oocytes of the atrophic right ovary.     

Protein synthesis in epiblast versus hypoblast during the critical stages of induction and growth of the primitive streak in the chick embryo.

In the chick the inducing power of the hypoblast for primitive streak was assumed to reach its maximum at the beginning of the primitive streak stage and to last until its completion. It was therefore of interest to trace the protein synthetic activity of the epiblast and hypoblast during five successive developmental stages and to correlate them with the known morphogenetic events.The investigation was done along two lines: 1) A quantitative survey was made of the uptake of tritiated phenylalanine into epiblasts versus hypoblasts and their incorporation into trichloroacetic acid-precipitable protein. 2) Incorporation of label into protein was followed by a comparative investigation of the electropherograms of epiblast versus hypoblast at the different stages.The quantitative survey has shown an almost uniform and rather low incorporation of label into protein in the hypoblast layer with a very short period of doubled activity between full hypoblast and initial primitive streak (p.s.). During this period the inductive capacity of the hypoblast for primitive streak was supposed to reach its maximal value.The qualitative survey indicated different patterns of incorporation in the two layers studied. Of special interest are two peaks (III and IV) which appear in the hypoblast previous to p.s. formation at the time of its augmented synthetic activity which also coincides with the onset of its inductive capacity. At later stages two similar peaks appear in the epiblast. It is suggested that a protein included in the above peaks might represent the inductor of the primitive streak.     

Early origins of definitive erythroid cells in the chick embryo

The early maturation stages of definitive erythroid cells are observed in the embryonic circulation of the chick yolk sac at 4.5--5 days of incubation. Light and electron microscope observation of the mesoderm of the yold sac membrane indicate that individual presumptive precursors of the definitive-line are present as early as 2 days of incubation and give rise to sequestered populations of immature erythroblasts within sinusoids during the period of 2.5-6 days incubation. Such isolated populations of definitive-line erythroblasts eventually connect with the established capillary circulation of yolk sac membrane but a large proportion of the erythroblasts temporarily remain associated with the endothelium prior to free circulation.     

Endogenous nuclease activity in chick embryo lens cells

The temporal and spatial sequence of nuclear disappearance during the terminal differentiation of lens fiber cells could be due to an impairment of the DNA repair pathways or to the appearance of an active DNA degradation process. The results presented here favor the second hypothesis. A single-stranded DNA nuclease activity and a double-stranded DNA nuclease activity have been found in chick embryo fiber cells. Moreover, there is a good correspondence between the variations of the nuclease activity and the stages of differentiation of the different samples analyzed.     

Correlation between the expression of the HNK-1 epitope and cellular invasiveness in prestreak epiblast cells of chick embryos

During avian gastrulation, certain cells present in the epiblast layer ingress through the basement membrane sealing the basal surface of themselves. Previously we reported that chick prestreak epiblast cells show two different behavioral phenotypes upon reconstituted basement membrane and laminin gel in vitro. Half of the dissociated epiblast cells invade the gel substratum after one-day of culture, whereas the others attach to the gel but do not invade. It is expected that such heterogeneity in the behavior of the epiblast cells reflects some mechanism that sorts the cells into those that will ingress into the blastocoelic cavity and those that will remain in the epiblast layer. To test this hypothesis, we dissociated chick prestreak epiblast cells into single cells, cultured them on the laminin gel, and then stained them with anti-HNK-1 antibody. This antibody binds to an epitope present on half of the prestreak epiblast cells which are thought to differentiate into presumptive mesoendodermal cells. We found that 80% of the invasive epiblast cells were HNK-1-positive whereas 77% of the non-invasive cells were HNK-1 negative. In the case of invasive cells, the edges of the proteolytic holes made by the invasive cells were often stained. These results suggest that the cells expressing the HNK-1 carbohydrate chain are preferentially invasive, and this induces selective ingression of the carrier cells for mesoendodermal differentiation in vivo.     

Concanavalin A-binding by cells of the early chick embryo

The surfaces of cells from the early embryo of the chick were examined using electron microscope techniques for the visualization of concanavalin A-binding sites. Horseradish peroxidase and Ferritin labelled concanavalin A were used to determine the distribution of the binding sites. All surfaces of the epiblast and hypoblast layers which were accessible to concanavalin A showed the presence of binding sites in stage 1 embryos. The ventral surface of the epiblast showed a high lectin affinity which may reflect the development of a basal lamina on this surface. The individual hypoblast cells at this stage showed a non-uniform distribution of binding sites, having a greater affinity on the dorsal surface than the ventral. By the time of primitive streak formation (stage 4-5) the dorsal surface of the epiblast displayed increased binding sites, while the frequency of sites on the ventral surface of the endoblast was reduced. The latter may reflect a change from one cell population to another, which occurs in the lower layer of the embryo at this time. No consistent correlation could be drawn between changes in motility of cells actually invaginating through the primitive streak and changes in affinity for concanavalin A. An overall increase in affinity of the dorsal surface of the epiblast was revealed by Ferritin and may reflect the changes in surface structure occurring in readiness for the morphogenetic migrations of gastrulation.     

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.     

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.