Distribution analysis of transferred donor cells in avian blastodermal chimeras.

Blastodermal chimeras were constructed by transferring quail cells to chick blastoderm. Contribution of donor cells to host were histologically analyzed utilizing an in situ cell marker. Of the embryos produced by injection of stage XI-XIII quail cells into stage XI-2 chick blastoderm, more than 50 percent were definite chimeras. The restriction on the spatial arrangement of donor cells was induced by varying the stage of host. Ectodermal chimerism was limited to the head region and no mesodermal chimerism was shown when the quail cells were injected into stage XI-XIII blastoderm. Mesodermal and ectodermal chimerisms were limited to the trunk, not to the head region, when the quail cells were injected into the stage XIV-2 blastoderm. In these chimeras, however, some of the injected quail cells formed ectopic epidermal cysts. Consequently, the stage XIV-2 blastoderm may become intolerant of the injected cells. Our results suggest that it is possible to obtain chimeras that have chimerism limited to a particular germ layer and region by varying the stage of donor cell injection. Injected quail cells contributed to endodermal tissues and primordial germ cells regardless of the injection site. The quail-chick blastodermal chimeras could be useful in the production of a transgenic chicken and in the investigation of immunological tolerance.     

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.     

Chick embryos can form teratomas from microinjected mouse embryonic stem cells

We examined whether chick embryos are a suitable experimental model for the evaluation of pluripotency of stem cells. Mouse embryonic stem cells (mESCs) expressing the reporter gene, LacZ or GFP were injected into the subgerminal cavity of blastoderms (freshly oviposited) or the marginal vein of chick embryos (2 days of incubation). Injected mESCs were efficiently incorporated into the body and extra‐embryonic tissues of chick embryos and formed small clusters. Increased donor cell numbers injected were positively associated with the efficiency of chimera production, but with lower viability. A single mESC injected into the blastoderm proliferated into 34.7 ± 3.8 cells in 3 days, implying that the chick embryo provides an optimal environment for the growth of xenogenic cells. In the embryo body, mESCs were interspersed as small clustered chimeras in various tissues. Teratomas were observed in the yolk sac and the brain with three germ layers. In the yolk sac, clusters of mESCs gradually increased in volume and exhibited varied morphology such as a water balloon‐like or dark‐red solid mass. However, mESCs in the brain developed into a large soft tissue mass of whitish color and showed a tendency to differentiate into ectodermal lineage cells, including primitive neural ectodermal and neuronal cells expressing the neurofilament protein. These results indicate that chick embryos are useful for the teratoma formation assays of mESCs and have a broad‐range potential as an experimental host model.     

Symmetry breaking and convergent extension in early chordate development

The initiation of axis, polarity, cell differentiation, and gastrulation in the very early chordate development is due to the breaking of radial symmetry. It is believed that this occurs by an external signal. We suggest instead spontaneous symmetry breaking through the agency of the Turing-Child field. Increased size or decreased diffusivity, both brought about by mitotic activity, cause the spontaneous loss of stability of the homogeneous state and the evolution of the metabolic pattern during development. The polar metabolic pattern is the cause of polar gene expression, polar morphogenesis (gastrulation), and polar mitotic activity. The Turing-Child theory explains not only the spontaneous formation of the invagination in gastrulation but also the coherent cell movement observed in convergence and extension during gastrulation and neurulation. The theory is demonstrated with respect to experimental observations on the early development of fish, amphibian, and the chick. The theory can explain a multitude of experimental details. For example, it explains the splayed polar progression of reduction in the fish blastoderm. Reduction starts on that side of the blastoderm margin, which will initiate invagination several hours later. It progresses toward the blastoderm center and somewhat laterally from this future "dorsal lip". This is precisely as predicted by a Turing-Child system in a circle. And for a fish like zebrafish with a blastoderm that is slightly oval, reduction is observed to progress along the long axis of the ellipse, which is what Turing-Child theory predicts. In general the shape and the chemical nature of the experimental patterns are the same as predicted by the Turing couple (cAMP, ATP). Embryological polarity and convergent extension are based on polar eigenfunction and saddle-shaped eigenfunction, respectively.     

A study of the expansion of the chick area vasculosa

The radial expansion of the area vasculosa of the chick embryo was studied with regard to the location of the cells which generate the mesodermal movement. The expansion of stage 12 area vasculosae was shown to be autonomous from either continued blastoderm expansion or the continued presence of the embryo. Small glass rods were used as barriers to area vasculosa expansion. When placed peripheral to the terminal sinus, glass rods blocked the vascular expansion; however, when placed just central to the terminal sinus, glass rods had no effect on vascular expansion. In addition, removal of large amounts of tissue within the area vasculosa had no significant effect on vascular expansion. We conclude that the majority of the mesoderm within the boundaries of the terminal sinus plays no essential role in the expansion of the area vasculosa, and that the cells which generate the force for expansion are located at or very near the terminal sinus. A histological study of the area vasculosa and adjacent blastoderm was performed with light and electron microscopy. This survey showed that, as the terminal sinus and a group of mesenchymal cells just peripheral to it (“edge cells”) move out into the blastoderm, morphological changes occur in the epiblast overlying the terminal sinus and edge cells. Three major changes in the epiblast cell layer were observed: (1) The cells change from a squamous, monolayered arrangement to a cuboidal or columnar, bilayered arrangement; (2) the epiblast basal lamina is thrown into convoluted folds; (3) an electron-dense extracellular matrix becomes associated with both the epiblast basal lamina and mesenchymal edge cells. Histochemical staining (Alcian blue at pH 2.5 and 1.0 and two-step PAS) shows positive reactions at the epithelial-mesenchymal interface located just over the terminal sinus and edge cells. These results suggest that glycosaminoglycans are present in relatively large amounts at the advancing mesoderm edge.     

Cell population growth in chick blastoderms cultured in vitro

Primitive streak stage chick blastoderms were cultured in vitro up to 30 hr by New's technique. Chick blastoderms reaching stages 4 to 12 in vitro cultures and in ovo were harvested and homogenized to release cell nuclei. Fluorescent ethidium bromide-stained nuclei in homogenates were counted in Neubauer's chamber and the size of total blastoderm cell population was determined. Linear regression analysis revealed that both in ovo and in vitro chick blastoderm cell population grows in a biphasic manner with comparable cell population doubling times and the morphogenesis is not affected in vitro during the culture period.     

Neurite extension by peripheral and central nervous system neurons in response to substratum-bound fibronectin and laminin

Small groups of blastoderm cells were transplanted from wild-type donor embryos into genetically marked host embryos of the same age. Donor cells were injected either into an homologous or an ectopic region of the recipient, and both donor and recipient embryos were allowed to develop. Donor flies were examined for defects in external structures. Recipients were scored for patches of donor-type marked tissue derived from the injected cells. After ectopic transfer, the donor cells recovered in chimaeric recipients differentiated structures consistent with the donor site of cell removal. No apparent fate change was observed. In the rare cases when both individuals of a donor/host pair survived, a direct correspondence could be made between the deleted region in the donor and the chimaeric patch in the host. The results show that blastoderm cells are stably determined to within a segment.     

Expression of the zygotic genome in blastoderm stage embryos ofDrosophila: Analysis of a specific protein

Summary The synthesis of a protein which has been detected in blastoderm cells but not in pole cells (Gutzeit and Gehring 1979) has been studied further by means of two-dimensional gel electrophoresis. This protein could not be detected at the nuclear multiplication stage. The protein is translated from mRNA which is transcribed at the blastoderm stage since it is not synthesized in detectable amounts when embryos are injected with -amanitin prior to the blastoderm stage. Also the protein could not be detected when RNA from freshly laid eggs was translated in vitro. Embryos from females which are homozygous for the mutationmat (3) 1 form pole cells but no blastoderm cells (Rice and Garen 1975). Thesemat (3) 1 embryos, as we will call them in this report, express the protein if aged for a period of time sufficient for completion of blastoderm cell formation in control wild-type embryos.mat (3) 1 embryos and embryos injected with -amanitin show the same syndrome of visible developmental anomalies; however, the studied protein could only be detected inmat (3) 1 embryos but not in -amanitin injected embryos.Supported by the DFG, SFB 46     

Nucleolar ontogenesis in the uterine chick germ correlated with morphogenetic events

Nucleolar development in the cleaving chick germ up to the formation of the primary hypoblast was followed through a series of well-defined uterine and early incubated stages both by light and electron microscopy. Well-established criteria of nucleolar morphology were used for determining the developmental stage of onset of rRNA synthesis. By these criteria rRNA synthesis was first observed at midcleavage in uterine stage VII [1] germs. This could be correlated with the first morphogenetic event—the posterio-anteriorly orientated formation of the area pellucida which results in a bilaterally symmetrical blastoderm.     

Distribution of acid phosphatase in the chicken blastoderm]

The distribution of acid phosphatase in the chick blastoderm (stages 2--4 by HH) has been studied using cytochemistry. A marked increase of enzymatic activity all over the blastoderm was shown to coincide with the beginning of primitive streak formation. A part of the cells after their immigration are characterized by the fall of acid phosphatase activity. The percentage of such cells increases in the cranio-caudal direction of the definitive primitive streak. The patterns of yolk utilization upon the separation of individual embryonic rudiments are discussed.     

Migration of chick blastoderm under the vitelline membrane: the role of fibronectin

In the earliest stages of its development the chick blastoderm is a flattened disc at the surface of the yolk. It gradually increases in diameter, partially because the cells are rapidly proliferating, but also because the cells at the periphery (the margin of overgrowth) are migrating in a centrifugal direction. These cells utilize the inner surface of the vitelline membrane as their substratum. In the normal blastoderm, these cells at the edge of the spreading blastoderm are the only cells which are attached to the vitelline membrane. This investigation is concerned with the possible role played by fibronectin in the interaction between these migrating cells and the vitelline membrane. Chick blastoderms, explanted by the New (1955) technique have been treated with synthetic peptides that mimic the adhesive recognition signal of the fibronectin molecule. The pentapeptide GRGDS (containing the specific RGD cell adhesion sequence) caused the edge cells of the blastoderm to detach within minutes, and the expansion of the blastoderm was inhibited for about 4 hr. After this period there was gradual recovery and the cells reattached and spreading resumed. Examination of the margin of the blastoderm by scanning electron microscopy showed that cell processes were lost soon after treatment with GRGDS but concomitant with reattachment and the resumption of spreading, the cell processes reformed. The pentapeptide GRDGS (with the amino acids G and D inverted) produced a brief inhibition of spreading, but after an hour these blastoderms spread at the same rate as controls. Immunocytochemical staining with anti-fibronectin demonstrated that fibronectin was not only present at the interface of the edge cells and the vitelline membrane, but also between the epiblast and the hypoblast. These results indicate that tissue movement during blastoderm spreading is dependent upon fibronectin and that the specific RGD amino acid sequence, and presumably the VLA/integrin family of receptors, is involved in this embryonic morphogenetic movement.     

Further studies on the role of sulfhydryl groups in the morphogenesis of the chick embryo

Summary The teratogenic effects on chick embryos of chloroacetophenone, a specific sulfhydryl reagent, are known to be reversible by cysteine and glutathione. Dithiothreitol (Cleland's reagent) and thiomalic acid cannot ameliorate the -SH block syndrome. While cysteine and glutathione can elicit differentiation of axial structures in the post-nodal pieces of the chick blastoderm, dithiothreitol and thiomalic acid cannot do so. This finding seems to suggest that the naturally occurring thiols, cysteine and glutathione, play an important role in the primary organizer action.This work was supported by a grant from the Indian Council of Medical Research. The author wishes to express his thanks to Miss N. Tripura Sundari for technical assistance. The Cleland's reagent used in this study was a gift from Dr. D. E. S. Truman of the University of Edinburgh.     

Hepten inhibitors of the endogenous galactose binding lectins and anti-lectin antibodies inhibit primitive streak formation in the early chick embryo

The early chick blastoderm expresses two endogenous galactose-bindinglectins of 14 kDa and 16 kDa. We have studied the effect thelectin hapten inhibitors thiodigalactoside and the syntheticneoglycoprotein lactosyl-bovine serum albumin as well as polyclonalanti-lectin antibodies on the development of early chick embryoscultured in a defined medium. Controls consisted of maltose,maltosyl bovine serum albumin and rabbit IgG. Embryos treatedat the onset of cell migration during early gastrulation underwentblastoderm retraction with decrease in surface area. In addition,they exhibited a lack of demarcation between the presumptiveembryonic area (area pellucida) and the presumptive extraembryonicarea (area opaca). These blastoderms also lacked a primitivestreak, that is, the structure that forms in the area pellucidaduring gastrulation as cell migrate to form the endodermal andmesodermal layers of the embryo. Embryos treated at later stagesof gastrulation showed development similar to that of controlsin that they were able to undergo early organogenesis. The resultssuggest that lectin mediated mechanisms are essential for themigratory movements of early gastrulation and that, at lategastrulation, other mechanisms exist in the embryo to compensatefor lectin function. blastoderm chick embryo galectin     

Lithium Chloride and Trypan Blue Induce Abnormal Morphogenesis by Suppressing Cell Population Growth

Full primitive streak stage chick embryos were cultured in vitro for 20 hrs and monitored every 4 hr for morphology, cell number and blastoderm area. In normal embryos, the cell population growth is exponential and correlates directly with Increasing morphological rank. The chick blastoderm area expands in two waves, one immediately after gastrulation and another after 16 hr in culture, while cell population growth is predominant between 4–16 hr. Trypan blue and LiCI inhibit cell population growth, epiboly and shaping of organ primordia. Both teratogens induce a similar spectrum of abnormalities although the severity of abnormal development is greater with LiCl for the given dose. In most abnormal embryos the cell population size and blastoderm area are inhibited most, which is detectable already after 12 hr of culture. We have established that the cell population growth, morphogenesis and area expansion constitute a parametric hierarchy with the cell population growth as the most independent parameter in regulating normal morphogenesis.     

Axis formation in half blastoderms of the chick: Stage at separation and the relative positions of fused halves influence axis development

The blastoderm of the avian embryo acts during the early stages of development as an integrative system programmed to form a single embryonic axis. Isolated parts of the blastoderm are known to each form an axis, owing to the system's properties. In the work reported here, the regulative capability of the right and left halves of chick blastoderms to form an embryonic axis was examined systematically at different stages. This revealed a progressive change in the developing blastoderm. After early separation, the axis in each half will form at some distance from the blastoderm's original midline, while with late separation the axis will form next to the original midline and may even lack one row of somites at the medial rim. Since development stops in culture after about 2 days, axis development after early separation ceases before somites are formed, whereas after late separation somites and brain vesicles can develop. In addition, an attempt was made to learn whether the two halves of blastoderm, when shifted along the midline and then reunited in staggered fashion, act as a single or two separate embryonic fields. When reunion of the right and left halves was achieved so that the posterior end of one half was adjoining the posterior area pellucida region of the other half, a single embryonic axis developed. When, on the other hand, the shift was larger so that the posterior end was fused to the central area pellucida of the other half, two separated embryonic axes developed.     

The development of cystic embryoid bodies in vitro from clonal teratocarcinoma stem cells

Previous findings on exogenous RNA-induced heart muscle differentiation in the non-heartforming cultured explants of the chick blastoderm, the postnodal pieces, were reexamined. Some of the changes that characterized the transition in the host tissues were: (i) the formation of highly ordered myofibrils; (ii) the appearance of characteristic cytoplasmic glycogen particles; (iii) a 2.5- and 3.5-fold increase in actin and myosin-like polypetides respectively; (iv) an increase in acetylcholinesterase activity; and (v) the acquisition of spontaneous and rhythmic pulsations. These specific changes appeared only in those explants that received a poly(A)-containing RNA fraction obtained from the 16-day-old chick embryonic heart. Neither synthetic polynucleotides nor a variety of RNA from several sources could replace the RNA from chick embryonic heart as an inducer of heart muscle differentiation.     

The occurrence of microtubules in the pre-streak chick embryo

Summary Arrays of well developed microtubules were demonstrated in the cells of the pre-streak chick blastoderm. The microtubules occurring subjacent to the lateral plasma membrane of the epiblast cells were arranged parallel to the longitudinal axis of the cell. Those occurring more deeply in these and the hypoblast cells were distributed in a more random fashion. This is the earliest stage in the development of any vertebrate in which microtubules have been described. It is suggested that the presence of microtubules at this stage is related to the separation of the hypoblast cells from the epiblast cells.     

The effects of microinjection of rhodamine-phalloidin on mitosis and cytokinesis in early stage Drosophila embryos

Rhodamine-phalloidin was microinjected into early stage Drosophila embryos, which were then allowed to develop for various times, fixed, and examined by fluorescence microscopy. A gradient of effects was seen. Close to the site of injection an area of diffuse bright fluorescence was found which included lumps and long strands of fluorescent material. Around this region particular cytoplasmic domains showed a denser F-actin distribution. These domains included the nuclear islands of the preblastoderm, the cortical caps of the syncytial blastoderm, and the contractile ring network which forms during cellularization of the blastoderm. It is proposed that these domains are regions of preferential actin polymerization under the appropriate cellular conditions and that the injected phalloidin causes incorporation of additional polymer into existing structures. Further away the pattern of phalloidin staining corresponded to that found with fixed material. In contrast to the domains of apparent additional F-actin polymerization a reduction of actin incorporated into small aggregates was found, both in syncytial blastoderm stages and during cellularization. This occurred in regions where additional actin had been incorporated into adjacent actin-rich structures. A storage role for the aggregates, which are depleted when F-actin is polymerized, is proposed. Both mitosis and cytokinesis were found to be slowed but the inhibition was only transient. However, most embryos died without differentiating. Rarely, differentiated tissues formed and the musculature was strongly stained by rh-phalloidin. When embryos were injected immediately prior to the start of cellularization cytokinesis was inhibited only locally and continued normally elsewhere. This finding argues against the hypothesis that contraction of an actomyosin network over the whole surface is the only force involved in the cellularization of the blastoderm and that local factors, e.g., plasmalemma extension, must be involved.