The Blood Island is a Site of Formation of the Primary Embryo Thrombocyte in the Chick Blastoderm

Using the immunohistological technique we inquired at what developmental stage and in which site of chick blastoderm does the embryo thrombocyte (ET) begin to differentiate. An anti-ET antibody was raised against rabbits by injecting ETs isolated from blood of 10 day chick embryos. By applying the indirect staining method to smear preparations of blood collected from developing embryos it was confirmed that cytoplasm of the ET showed more intense staining than that of the erythroid cell and that the ET population could be distinguished from the erythrocyte population by this antibody. Cells showing the intense staining could be detected first in blood islands of the area opaca vasculosa of stage 9+ blastoderms. These embryo thromboblasts were found singly or in groups of a small number at dorsal periphery of cell clusters in the blood island. The electron microscopy revealed that embryo thromboblasts appeared in the same position in the stage 9+ blastoderm. At stage 10+ or later embryo thromboblasts were also present adhering to the vascular endothelium or free in the vessel lumen. We conclude that ETs start differentiating from primitive mesenchymal cells localized in the blood island of the area opaca vasculosa at stage 9 or earlier, migrate thereafter to vessel lumen, and enter the blood stream.     

Scanning electron microscopy of chick epiblast expansion on the vitelline membrane. Cell-substrate interactions

Cell-substrate interactions have been studied by examining migrating edge cells of the expanding chick extraembryonic epiblast on their normal substrate and in culture. Scanning electron microscopy shows that the outer face of the vitelline membrane is a random meshwork of fibrils (80 nm diam). The inner face, which is the normal substrate of epiblast expansion, is composed of a random branched system of fibers (400 nm diam) overlain by a network of fibrils (40 nm diam). The epiblast edge in situ has radially oriented filopodia (20 μm long, 200 nm diam.), frequently extending from broad lamellipodia. Blastoderms cultured on the inner face of unincubated vitelline membrane expand at a normal rate but display ruffles as well as filopodia and lamellipodia. When the blastoderm is cultured on the outer membrane face there is no expansion, but cells leave the edge and migrate across the membrane. In these cultures, ruffles are observed on the ventral epiblast face. Absence of the mass of yolk in culture appears to permit or provoke the observed ruffling. Comparison of dissociated epiblast edge cells and skin epithelial cells, cultured on glass and on the vitelline membrane inner face, indicates that epiblast cells remain flattened and display characteristic filopodia on both substrates, whereas skin cells display ruffles on the vitelline membrane but are flattened on glass. The mode of migration of epiblast edge cells seems to be more dependent on intrinsic factors than that of skin cells.     

Cell movements during epiboly and gastrulation in zebrafish

Beginning during the late blastula stage in zebrafish, cells located beneath a surface epithelial layer of the blastoderm undergo rearrangements that accompany major changes in shape of the embryo. We describe three distinctive kinds of cell rearrangements. (1) Radial cell intercalations during epiboly mix cells located deeply in the blastoderm among more superficial ones. These rearrangements thoroughly stir the positions of deep cells, as the blastoderm thins and spreads across the yolk cell. (2) Involution at or near the blastoderm margin occurs during gastrulation. This movement folds the blastoderm into two cellular layers, the epiblast and hypoblast, within a ring (the germ ring) around its entire circumference. Involuting cells move anteriorwards in the hypoblast relative to cells that remain in the epiblast; the movement shears the positions of cells that were neighbors before gastrulation. Involuting cells eventually form endoderm and mesoderm, in an anterior-posterior sequence according to the time of involution. The epiblast is equivalent to embryonic ectoderm. (3) Mediolateral cell intercalations in both the epiblast and hypoblast mediate convergence and extension movements towards the dorsal side of the gastrula. By this rearrangement, cells that were initially neighboring one another become dispersed along the anterior-posterior axis of the embryo. Epiboly, involution and convergent extension in zebrafish involve the same kinds of cellular rearrangements as in amphibians, and they occur during comparable stages of embryogenesis.     

Intercellular contact in the unincubated chick embryo

Summary The unincubated chick blastoderm, which consists of a complete upper epithelial layer of one cell thickness (epiblast) and an incomplete lower layer (hypoblast), was examined with the electron microscope in order to define the types of cell contact present. The terminal contacts between the cells of the epiblast invariably involved several focal tight junctions, but only occasionally involved tight junctions. Desmosomes were not observed in these areas, but were encountered in various phases of development in the deeper contact regions between epiblast cells. This deeper region also showed sporadic focal tight junctions and frequent micropapillae. These micropapillae were also common on the surfaces of hypoblast cells. Intercellular spaces between epiblast and hypoblast cells and within the hypoblast were often wide, narrowing to occasional focal tight junctions. Tight junctions and desmosomes were not observed in association with hypoblast cells. Gap junctions were not observed in any region of the embryo.These observations are discussed in relation to the morphogenetic movements occurring in the forming hypoblast and also the influence of this layer on the subsequent development of the embryo. Comparisons are drawn between the contact morphology in the unincubated blastoderm and that in later stages of development.Supported by the Medical Research Council of Canada.     

The pluripotency of the extraembryonic mesodermal cells of the early chick blastoderm: effects of the AP and AOV environments

This study investigates the developmental potential of the extraembryonic mesodermal cells of the early chick blastoderm. [3H]Thymidine-labeled mesodermal fragments from the extraembryonic area pellucida (AP) and area opaca vasculosa (AOV) were transplanted into the AP or AOV of nonlabeled host blastoderms in culture, and their fate followed autoradiographically. All the homotopically transplanted mesodermal cells differentiated in accordance with their normal fates. However, not all the heterotopically transplanted mesodermal cells did so, for some of the stage 8 AP extraembryonic mesodermal cells (normally nonerythropoietic) gave rise to blood cells when transplanted into the AOV. We also observed that the stage 4-5 AOV mesoderm continues to migrate peripherally when heterotopically transplanted into the AP, at a time when the AP mesodermal cells are nonmigratory. In support of our premise that the stage 8-9 AP extraembryonic mesoderm has the potential to form blood, we observed a clear-cut production of hemoglobin when the latter mesoderm was co-cultured on coverslips with stage 4 AOV endoderm.     

FGF signalling through RAS/MAPK and PI3K pathways regulates cell movement and gene expression in the chicken primitive streak without affecting E-cadherin expression

Background  

FGF signalling regulates numerous aspects of early embryo development. During gastrulation in amniotes, epiblast cells undergo an epithelial to mesenchymal transition (EMT) in the primitive streak to form the mesoderm and endoderm. In mice lacking FGFR1, epiblast cells in the primitive streak fail to downregulate E-cadherin and undergo EMT, and cell migration is inhibited. This study investigated how FGF signalling regulates cell movement and gene expression in the primitive streak of chicken embryos.     

Formation of Embryo Thromboblasts in Chick Blastoderm: Morphology, Site of Production and Time of Emergence in the Blood

Thrombocytes in the blood of chick embryos (termed embryo thrombocytes by L ucas and J amroz ) have PAS-positive granules in their cytoplasm. Electron microscopic observations reveal that the embryo thrombocytes contain glycogen granules present singly or in clumps. The presence of these inclusions and other morphological characteristics were used as specific markers to distinguish embryo thrombocytes from primitive erythroid cells. These markers also made it possible to determine the time at which the immature thromboblasts first emerge in blood vessels, and the period of their continued presence in the circulation. In this way we found that thromboblasts were detectable in embryos as early as stage 10⁺ of H amburger and H amilton (after 35 hr incubation) and that the thromboblasts were present in the circulation until day 4 of incubation (stage 23). In ovo and in vitro culture of de-embryonated blastoderm demonstrated that thromboblasts were formed in the area opeca vasculosa. The present observations suggest that embryo thromboblasts are formed at the same time and in the same area as the primitive cells of erythroid line.     

Epidermal growth factor promotes chick embryonic angiogenesis

The response of the early extraembryonic vasculature to epidermal growth factor (EGF) was studied. Millipore filter discs containing 10ng-1 microgram of EGF were placed onto the advancing edge of the area vasculosa of 3-day chick embryos, and the effect examined macroscopically and histologically 24 hours after disc application. The capillary density at the site of application increased significantly, and the effect was seen to be dose-dependent; a similar but more marked response was observed in the vessel cross-sectional area per unit length. This change in vascularity was accompanied by tortuous folding of the mesoderm and endoderm (which normally lie parallel to the ectoderm in a trilaminar arrangement) into the yolk substance: this may indicate precocious development of all three layers (ectoderm, mesoderm and ectoderm) of the membrane, and the proliferative effects of EGF may not be confined to the vascular endothelium.     

Transitions between epithelial and mesenchymal states and the morphogenesis of the early mouse embryo

Multicellular organisms arise from the generation of different cell types and the organization of cells into tissues and organs. Cells of metazoa display two main phenotypes, the ancestral epithelial state and the recent mesenchymal derivative. Epithelial cells are usually stationary and reside in twodimensional sheets. By contrast mesenchymal cells are loosely packed and can move to new positions, thereby providing a vehicle for cell rearrangement, dispersal and novel cell-cell interactions. Transitions between epithelial and mesenchymal states drive key morphogenetic events in the early vertebrate embryo, including gastrulation, germ layer formation and somitogenesis. The cell behaviors and molecular mechanisms promoting transitions between these two states in the early mouse embryo are discussed in this review.Key words: mouse embryo, EMT, MET, morphogenesis, gastrulation, somitogenesis, epiblast, mesoderm, endoderm, primitive streak, paraxial mesoderm     

Structure of the endodermal epithelium of the chick yolk sac during early stages of development.

The structure of the areas pellucida and vasculosa of the early chick embryo (stages 11-29) was examined by light, transmission and scanning electron microscopy. The most striking feature of the endodermal cells of these areas is the presence of large intracellular yolk drops which are characteristic of the regions in which they are found; lipid-like homogeneous drops in the area pellucida, heterogeneously composed pleomorphic drops in the mid-region of the area vasculosa and granular drops at the periphery of the area vasculosa in the region of the sinus terminalis. On morphological criteria it is postulated that granular drops may arise by direct engulfment of extracellular yolk, but this does not appear to be true for pleomorphic or homogeneous drops. Since the apical junctions between endodermal cells across the yolk sac are tight, they seal off the extraembryonic compartment from the vitelline circulation and presumably prevent intercellular passage of the yolk constituents. Thus the endodermal epithelium must mediate the transport of nutrients from the yolk mass to the developing embryo. Endodermal cells exhibit a variation across the yolk sac in the presence and number of structures associated with uptake of extracellular materials. The mid-region of the area vasculosa appears to be the most endocytotically active region with an abundance of microvilli, bristle-coated pits and vesicles and apical canaliculi and vacuoles. There is a close association between the endoderm and vitelline blood vessels and this association is maintained, as the yolk sac develops, by the formation of small vessels juxtaposed between the vascular surface of the endoderm and the walls of the large vitelline vessels.     

BMP signaling in the epiblast is required for proper recruitment of the prospective paraxial mesoderm and development of the somites

Bmpr1a encodes the BMP type IA receptor for bone morphogenetic proteins (BMPs), including 2 and 4. Here, we use mosaic inactivation of Bmpr1a in the epiblast of the mouse embryo (Bmpr-MORE embryos) to assess functions of this gene in mesoderm development. Unlike Bmpr1a-null embryos, which fail to gastrulate, Bmpr-MORE embryos initiate gastrulation, but the recruitment of prospective paraxial mesoderm cells to the primitive streak is delayed. This delay causes a more proximal distribution of cells with paraxial mesoderm character within the primitive streak, resulting in a lateral expansion of somitic mesoderm to form multiple columns. Inhibition of FGF signaling restores the normal timing of recruitment of prospective paraxial mesoderm and partially rescues the development of somites. This suggests that BMP and FGF signaling function antagonistically during paraxial mesoderm development.     

Changes in the expression of the carbohydrate epitope HNK-1 associated with mesoderm induction in the chick embryo

We report that a monoclonal antibody, HNK-1, identifies specific regions and cell types during primitive streak formation in the chick blastoderm. Immunohistochemical studies show that the cells of the forming hypoblast are HNK-1 positive from the earliest time at which they can be identified. Some cells of the margin of the blastoderm are also positive. The mesoderm cells of the primitive streak stain strongly with the antibody from the time of their initial appearance. In the epiblast, some cells are positive and some negative at pre-primitive-streak stages, but as the primitive streak develops a gradient of staining intensity is seen within the upper layer, increasing towards the primitive streak. At later stages of development, the notochord and the mesenchyme of the headfold are positive, while the rest of the mesoderm (lateral plate) no longer expresses HNK-1 immunoreactivity. This antibody therefore reveals changes associated with mesodermal induction: before induction, it recognizes the 'inducing' tissue (the hypoblast) and reveals a mosaic pattern in the responding tissue (the epiblast); after primitive streak formation, the mesoderm of the primitive streak that results from the inductive interactions expresses the epitope strongly. Affinity purification of HNK-1-related proteins in various tissues was carried out, followed by SDS-PAGE to identify them. The hypoblast, mesoderm and epiblast of gastrulating chick embryos have some HNK-1-related proteins in common, while others are unique to specific tissues. Attempts have been made to identify these proteins using Western blots and antibodies known to recognize HNK-1-related molecules, but none of the antibodies used identify the bands unique to any of the tissues studied. We conclude that these proteins may be novel members of the HNK-1/L2 family, and that they may have a role in cell interactions during early development.     

Fibronectin in the area opaca of the young chick embryo

Summary Distribution of fibronectin-like immunoreactivity was studied in the area opaca of the young chick embryo (stages 4–6 HH) by use of the immunofluorescence and protein A-coupled to colloidal gold techniques. Fibronectin, associated to the basement membrane, formed a fibrillar network, the pattern of which changed from the centre to the periphery of the area opaca. At the ultrastructural level, differences in fibronectin distribution were found between non-moving and moving cells. The epithelial-like cells presented fibronectin staining exclusively on their basal side. Actively migrating cells (edge and mesodermal cells) showed immunoreactive material localized around their entire surface and within the cytoplasm. The fibronectin distribution is discussed in relation to three important phenomena taking place during the early growth of the area opaca: (i) anchorage and migration of the edge cells, (ii) modification of cell shape in relation to mechanical tension, and (iii) expansion of the area vasculosa.     

Organization of the migrating chick epiblast edge: attachment sites, cytoskeleton, and early developmental changes

The radial expansion of the chick extraembryonic epiblast on the inner side of the vitelline membrane in yolk sac formation provides a useful system for study of adhesion and migration of an epithelial cell sheet. A band of specialized cells at the epiblast edge adheres by its dorsal side to the overlying vitelline membrane. The attached edge was examined by scanning electron microscopy. The attachment region (av 0.06 mm wide) extends from the advancing edge to a transitional ridge. The ridge appears to be an area of adhesion and de-adhesion. The attached surface is smooth with small surface projections and filopodia. These become more numerous and prominent with cold treatment. Epiblast cells display a filopodial/lamellipodial mode of migration in vivo and in vitro. The distribution of 4- to 7-nm microfilaments in edge cells is examined using transmission electron microscopy of whole cells. Decoration with heavy meromyosin shows that these components of the cytoskeleton contain actin. Treatment of intact blastoderms and dissociated edge cells with cytochalasin B and cold suggests that microfilaments rather than microtubules are primarily responsible for edge cell morphology. Early blastoderm cells which have not initiated migration respond to cytochalasin B, cold, and colcemid in the same way as migrating edge cells. This suggests that the differentiative change that produces the rapidly migrating edge cells does not involve a shift in the relative contribution of microtubules and microfilaments to the cytoskeleton.     

Regionalisation of cell fate and morphogenetic movement of the mesoderm during mouse gastrulation

The developmental fate of cells in the epiblast of early-primitive-streak-stage mouse embryos was assessed by studying the pattern of tissue colonisation displayed by lac Z-expressing cells grafted orthotopically to nontransgenic embryos. Results of these fate-mapping experiments revealed that the lateral and posterior epiblast contain cells that will give rise predominantly to mesodermal derivatives. The various mesodermal populations are distributed in overlapping domains in the lateral and posterior epiblast, with the embryonic mesoderm such as heart, lateral, and paraxial mesoderm occupying a more distal position than the extraembryonic mesoderm. Heterotopic grafting of presumptive mesodermal cells results in the grafted cells adopting the fate appropriate to the new site, reflecting a plasticity of cell fate determination before ingression. The first wave of epiblast cells that ingress through the primitive streak are those giving rise to extraembryonic mesoderm. Cells that will form the mesoderm of the yolk sac and the amnion make up a major part of the mesodermal layer of the midprimitive-streak-stage embryo. Cells that are destined for embryonic mesoderm are still found within the epiblast, but some have been recruited to the distal portion of the mesoderm. By the late-primitive-streak-stage, the mesodermal layer contains only the precursors of embryonic mesoderm. This suggests that there has been a progressive displacement of the midstreak mesoderm to extraembryonic sites, which is reminiscent of that occurring in the overlying endodermal tissue. The regionalisation of cell fate in the late-primitive-streak mesoderm bears the same spatial relationship as their ancestors in the epiblast prior to cell ingression. This implies that both the position of the cells in the proximal-distal axis and their proximity to the primitive streak are major determinants for the patterning of the embryonic mesoderm. © 1995 Wiley-Liss, Inc.     

Low proliferative and high migratory activity in the area of Brachyury expressing mesoderm progenitor cells in the gastrulating rabbit embryo

General mechanisms initiating the gastrulation process in early animal development are still elusive, not least because embryonic morphology differs widely among species. The rabbit embryo is revived here as a model to study vertebrate gastrulation, because its relatively simple morphology at the appropriate stages makes interspecific differences and similarities particularly obvious between mammals and birds. Three approaches that centre on mesoderm specification as a key event at the start of gastrulation were chosen. (1) A cDNA fragment encoding 212 amino acids of the rabbit Brachyury gene was cloned by RT-PCR and used as a molecular marker for mesoderm progenitors. Whole-mount in situ hybridisation revealed single Brachyury-expressing cells in the epiblast at 6.2 days post conception, i.e. several hours before the first ingressing mesoderm cells can be detected histologically. With the anterior marginal crescent as a landmark, these mesoderm progenitors are shown to lie in a posterior quadrant of the embryonic disc, which we call the posterior gastrula extension (PGE), for reasons established during the following functional analysis. (2) Vital dye (DiI) labelling in vitro suggests that epiblast cells arrive in the PGE from anterior parts of the embryonic disc and then move within this area in a complex pattern of posterior, centripetal and anterior directions to form the primitive streak. (3) BrdU labelling shows that proliferation is reduced in the PGE, while the remaining anterior part of the embryonic disc contains several areas of increased proliferation. These results reveal similarities with the chick with respect to Brachyury expression and cellular migration. They differ, however, in that local differences in proliferation are not seen in the pre-streak avian embryo. Rather, rabbit epiblast cells start mesoderm differentiation in a way similar to Drosophila, where a transient downregulation of proliferation initiates mesoderm differentiation and, hence, gastrulation.     

Development of the basal lamina and extracellular materials in the early chick embryo

Summary Chick embryos at developmental stages up to primitive streak formation were fixed in a mixture of tannic acid and glutaraldehyde. A basal lamina was present in the unincubated embryo and consisted of a lucent lamina interna and a lamina densa. At the primitive streak stage the lamina densa showed a periodicity of stained elements. Densely stained materials were present on the cell surfaces lining the cavity between the epiblast and endoblast, and on the mesoderm cells within this cavity. Considerable amounts of extracellular material were observed in the cavity. Hyaluronidase treatment removed the cell surface and extracellular material, indicating that hyaluronic acid is a major component. This enzyme disrupted the basal lamina, leaving a fibrillar remnant with no periodic structure. It is therefore suggested that the dense periodicities consist of glycosaminoglycan built on an enzyme-resistant framework which is probably collagen. Enzyme-resistant fibrils, presumably collagen precursors, are present elsewhere within the tissue spaces.     

Mutations in half baked/E-cadherin block cell behaviors that are necessary for teleost epiboly

Epiboly, the spreading of the blastoderm over the large yolk cell, is the first morphogenetic movement of the teleost embryo. Examining this movement as a paradigm of vertebrate morphogenesis, we have focused on the epiboly arrest mutant half baked (hab), which segregates as a recessive lethal, including alleles expressing zygotic-maternal dominant (ZMD) effects. Here we show that hab is a mutation in the zebrafish homolog of the adhesion protein E-cadherin. Whereas exclusively recessive alleles of hab produce truncated proteins, dominant alleles all contain transversions in highly conserved amino acids of the extracellular domains, suggesting these alleles produce dominant-negative effects. Antisense oligonucleotides that create specific splicing defects in the hab mRNA phenocopy the recessive phenotypes and, surprisingly, some of the ZMD phenotypes as well. In situ analyses show that during late epiboly hab is expressed in a radial gradient in the non axial epiblast, from high concentrations in the exterior layer of the epiblast to low concentrations in the interior layer of the epiblast. During epiboly, using an asymmetric variant of radial intercalation, epiblast cells from the interior layer sequentially move into the exterior layer and become restricted to that layer; there they participate in subtle cell shape changes that further expand the blastoderm. In hab mutants, when cells intercalate into the exterior layer, they tend to neither change cell shape nor become restricted, and many of these cells 'de-intercalate' and move back into the interior layer. Cell transplantation showed all these defects to be cell-autonomous. Hence, as for the expansion of the mammalian trophoblast at a similar developmental stage, hab/E-cadherin is necessary for the cell rearrangements that spread the teleost blastoderm over the yolk.     

Shaping and bending of the avian neural plate as analysed with a fluorescent-histochemical marker

Shaping and bending of the neural plate are cardinal events of neurulation. These processes are initiated in avian embryos shortly after the onset of gastrulation and concluded concomitantly with the completion of gastrulation. The epiblast undergoes extensive morphogenetic movements during gastrulation and neurulation, but the directions, distances, rates, mechanisms and roles of such rearrangements are largely unknown. To begin to understand these morphogenetic movements, we have mapped regional displacements of the epiblast by injecting a fluorescent-histochemical marker into selected prenodal, nodal and postnodal levels of the blastoderm. Lateral epiblast regions (600 microns lateral to the midline and consisting primarily of surface epithelium) are displaced craniomedially, medial regions (300 microns lateral to the midline and consisting of neural plate and preingressed mesoderm) predominantly medially, and midline regions (consisting of neural plate and primitive streak) predominantly caudally. Displacements within the avian neural plate parallel those previously described for the amphibian neural plate. Furthermore, similar tissue displacements occur within the prenodal and postnodal levels of the avian epiblast despite the fact that neurulation is occurring in the former and gastrulation in the latter. Finally, our results show that ectodermal rudiments contained within a single cross-sectional level of the embryo are a composite of cells derived from multiple craniocaudal and mediolateral levels. Thus, regional tissue displacements are important events to consider in the analysis of the early morphogenesis of axial and paraxial organ rudiments derived from the epiblast.