Monensin inhibits the first cellular movements in early chick embryo

Summary In early chick blastoderm at stage XIII, the interaction of the hypoblast with the epiblast triggers on the epiblast the first extensive cellular migrations, which result in formation of the primitive streak, the source of the axial mesoderm. During this period, extracellular material (ECM) is secreted and assembled into an organized network in the extracellular spaces and is implicated in regulating the behaviour of the cells that contact it. The first cellular migrations and inductions are inhibited when early chick blastoderm is treated with the glycosylation-perturbing ionophore monensin. The difference in amount and in organization of ECM between monensin-treated embryos and control embryos is striking. Even blastoderms at stage X, which are essentially free of ECM, show extensive ECM after monensin treatment. Monensin produces a substantial change in the polypeptide pattern with the induction or marked accentuation of multiple charged species (isoforms) of polypeptides different from those present in the control embryos. The interference of monensin with the migration and induction mechanisms is permanent in embryos before the primitive streak (PS) stage, and it seems that the respective signals or the sensitivity of the epiblast/hypoblast cells to them must be very stage specific. Monensin-treated embryos probably secrete abnormal ECM that does not provide the proper conditions for the hypoblast to interact with the epiblast cells.     

N-glycosylated proteins interfere with the first cellular migrations in early chick embryo.

Cell adhesion and migration properties which are known to play a crucial role in developmental events seem to be modulated by variations in glycosylation of glycoproteins. In the chick embryo, the extracellular matrix (ECM) appears as a loose meshwork of fibrillar material in the space between the epiblast and the hypoblast shortly before the first major cell migrations start. Chick embryos treated with tunicamycin (TN), a specific inhibitor of N-linked glycosylation of proteins, show little or no ECM, diminished cell adhesion and a dramatic alteration in the architecture of the epiblast and of the hypoblast. The first major cell migrations which signal the onset of PS and gastrula formation are inhibited irreversibly in these embryos. Tunicamycin induces a substantial change in the labeling pattern with change in mobility of some polypeptides and with the induction or marked accentuation of multiple charged species (isoforms) of polypeptides different from these already present in the control blastoderm. The N-linked glycosylation of protein(s) that are synthesized during the interaction of the epiblast and of the hypoblast seem to play a critical role in cell adhesion and in the morphogenetic movements of gastrulation in the early chick embryo.     

Activation of epiblast gene expression by the hypoblast layer in the prestreak chick embryo

Axis formation is a highly regulated process in vertebrate embryos. In mammals, inductive interactions between an extra-embryonic layer, the visceral endoderm, and the embryonic layer before gastrulation are critical both for anterior neural patterning and normal primitive streak formation. The role(s) of the equivalent extra-embryonic endodermal layer in the chick, the hypoblast, is still less clear, and dramatic effects of hypoblast on embryonic gene expression have yet to be demonstrated. We present evidence that two genes later associated with the gastrula organizer (Gnot-1 and Gnot-2) are induced by hypoblast signals in prestreak embryos. The significance of this induction by hypoblast is discussed in terms of possible hypoblast functions and the regulation of axis formation in the early embryo. Several factors known to be expressed in hypoblast, and retinoic acid, synergistically induce Gnot-1 and Gnot-2 expression in blastoderm cell culture. The presence of retinoic acid in prestreak embryos has not yet been directly demonstrated, but exogenous retinoic acid appears to mimic the effects of hypoblast rotation on primitive streak extension, raising the possibility that retinoid signaling plays some role in the pregastrula embryo.     

A new method to transfect the hypoblast of the chick embryo reveals conservation of the regulation of an Otx2 enhancer between mouse and chick extraembryonic endoderm

Background

The mouse anterior visceral endoderm (AVE) and the chick hypoblast are thought to have homologous roles in the early stages of neural induction and primitive streak formation. In mouse, many regulatory elements directing gene expression to the AVE have been identified. However, there is no technique to introduce DNA into the chick hypoblast that would enable a comparison of their activity and this has hampered a direct comparison of the regulation of gene expression in the mouse and chick extraembryonic endoderm.

Results

Here we describe a new method to introduce DNA into the chick hypoblast, using lipofectamine-mediated transfection. We show that the hypoblast can be easily transfected and that it starts to express a luciferase reporter within 2 hours of transfection. The validity of technique is tested by following the movement and fate of hypoblast cells, which reveals their translocation to the anterior germinal crescent. We then introduce a vector containing GFP driven by the mouse VEcis-Otx2 enhancer (which directs gene expression to the mouse AVE) and we detect activity in the hypoblast.

Conclusion

The new technique for delivering expression constructs to the chick hypoblast will enable studies on gene activity and regulation to be performed in this tissue, which has proved difficult to transfect by electroporation. Our findings also reveal that regulatory elements that direct gene expression to the mouse AVE are active in chick hypoblast, supporting the idea that these two tissues have homologous functions.     

Induction of the primitive streak in the chick blastoderm embryo: patterns of protein synthesis

Summary Induction of the primitive streak is correlated with specific qualitative and quantitative changes in protein synthesis in the component areas of chick blastoderm. Blastoderm embryos at the initial to intermediate primitive streak stage were labeled with L-[³⁵S] methionine. Radioactively labeled proteins separated by two-dimensional sodium dodecyl sulphate (SDS) polyacrylamide gel electrophoresis revealed differences in the number and density of spots among the component areas of the epiblast and hypoblast. Protein patterns of the area opaca, marginal zone and central area of the epiblast are very similar qualitatively but show distinct quantitative differences. A comparison between any of the component areas of the epiblast and the hypoblast in chick blastoderm embryos, however, reveals both qualitative and quantitative differences. A protein with a molecular weight of 30,000 unique to the component areas of the epiblast, and proteins with a molecular weight of 22,000 and 37,000 unique to the hypoblast are prominent and seem to be related to the initial appearance of the primitive streak.     

Anterior identity is established in chick epiblast by hypoblast and anterior definitive endoderm

Previous studies of head induction in the chick have failed to demonstrate a clear role for the hypoblast and anterior definitive endoderm (ADE) in patterning the overlying ectoderm, whereas data from both mouse and rabbit suggest patterning roles for anterior visceral endoderm (AVE) and ADE. Based on similarity of gene expression patterns, fate and a dual role in 'protecting' the prospective forebrain from caudalising influences of the organiser, the chick hypoblast has been suggested to be the homologue of the mouse anterior visceral endoderm. In support of this, when transplanted to chick embryos, the rabbit AVE induces anterior markers in the chick epiblast. To reevaluate the role of the hypoblast/ADE (lower layer) in patterning the chick ectoderm, we used rostral blastoderm isolates (RBIs) as an assay, that is, rostral regions of blastoderms transected at levels rostral to the node. RBIs are, therefore, free from the influences of Hensen's node and ingressing axial mesoderm - tissues that are able to induce Ganf, the earliest specific marker of anterior neural plate. We demonstrate, using such RBIs (or RBIs dissected to remove the lower layer with or without tissue replacement), that the hypoblast/ADE (lower layer) is required and sufficient for patterning anterior positional identity in the overlying ectoderm, leading to expression of Ganf in neuroectoderm. Our results suggest that patterning of anterior positional identity and specification of neural identity are separable events operating to pattern the rostral end of the early chick embryo. Based on this new evidence we propose a revised model for establishing anteroposterior polarity, neural specification and head patterning in the early chick that is consonant with that occurring in other vertebrates.     

Primitive streak-forming cells of the chick invaginate through a basement membrane

Summary Recently fibronectin was shown to appear in the development of the chick for the first time as a thin band on the epiblastic side facing the hypoblast just prior to primitive streak formation. It was thus suggested that fibronectin might be instrumental in the migration of cells that lead to axis formation during primitive streak formation. In the present work we have examined simultaneously for the presence of fibronectin and the specific basement membrane glycoprotein laminin during primitive streak formation using immunofluorescence methods. Laminin was found to be expressed between the epiblast and the hypoblast of stage XIII¹ chick blastoderms. During the immediately following process of streak formation the laminin was found to be continuously detectable throughout the area covered by the hypoblast, but disrupted on the streak area. Fibronectin was found to co-distribute with laminin in stage XIII and in the early primitive streak chick blastoderms. It is concluded that at stage XIII laminin and fibronectin form part of a basement membrane that is partially disrupted during the immediately following process of primitive streak formation in order to allow the migration of the streak-forming epiblastic cells during this morphogenetic process.     

The cholinergic system in the early development of chickens. 1. Choline acetyltransferase and acetylcholinesterase as the key regulators of acetylcholine metabolism

Acetylcholine esterase (AChE, EC 3.1.1.7) and choline acetyltransferase (CAT, EC 2.3.1.6) activities were studied in the early chick embryos. Gastrulation is accompanied by a sharp increase in the AChE activity which was most pronounced in anterior hypoblast. Three molecular of AChE (4.7, 6.8 and 10.9 S) were identified in the extract of chick embryos using a sucrose density gradient centrifugation. The CAT activity remained unchanged during gastrulation but increased twice at the end of gastrulation.     

The sorting-out of thymidine-labelled chick hypoblast cells in mixed epiblast--hypoblast aggregates.

Tritium-labelled disaggregated chick hypoblast cells were mixed with non-labelled epiblast cells and vice-versa. The mixtures were allowed to aggregate in a gyratory shaker and were transferred on to a solid culture medium for further incubation. The aggregates were fixed after various incubation times, sectioned and examined for sorting-out. There was already a tendency to sort out after 10 h of incubation, a process which was completed after 25 h. The hypoblast cells formed a continuous layer adjacent to the vitelline membrane, while the epiblast cells moved out to form the upper external layer. The position of the two layers was normal as far as the substrate and external environment are concerned, and reversed in relation to their relative position to the vitelline membrane. The hypoblast cells tended to migrate to the margins of the aggregate. The latter phenomenon seems to parallel the migration of hypoblast cells towards the extra-embryonal area during the formation of the primitive streak.     

The Sorting-out of Thymidine-labelled Chick Hypoblast Cells in Mixed Epiblast–Hypoblast Aggregates

Tritium-labelled disaggregated chick hypoblast cells were mixed with non-labelled epiblast cells and vice-versa . The mixtures were allowed to aggregate in a gyratory shaker and were transferred on to a solid culture medium for further incubation. The aggregates were fixed after various incubation times, sectioned and examined for sorting-out. There was already a tendency to sort out after 10 h of incubation, a process which was completed after 25 h. The hypoblast cells formed a continuous layer adjacent to the vitelline membrane, while the epiblast cells moved out to form the upper external layer. The position of the two layers was normal as far as the substrate and external environment are concerned, and reversed in relation to their relative position to the vitelline membrane. The hypoblast cells tended to migrate to the margins of the aggregate. The latter phenomenon seems to parallel the migration of hypoblast cells towards the extra-embryonal area during the formation of the primitive streak.     

Involvement of fibronectin during epiboly and gastrulation in embryos of the common carp,Cyprinus carpio

Summary The present report firstly describes a pilot study in which, during early development of embryos of the common carp, Cyprinus carpio, the cellular adhesion to fibronectin (FN) was blocked by administration of GRGDS peptide (which binds to the FN-receptor). As this treatment resulted in developmental aberrations, suggesting a functional role for FN, the major part of the work was focussed on the distribution of reactivity of anti-FN antibodies during epiboly and gastrulation. GRGDS treatment had a concentration dependent effect on development. Incubation of embryos in 1.5 mg/ml from the 32-cell stage onwards caused a retardation of epiboly, which did not proceed beyond 60%. The embryos did not show involution, as was confirmed by histological study. These preliminary results suggest that FN is involved in both epiboly and gastrulation of carp embryos. During cleavage, no specific extracellular binding of anti-FN antiserum could be observed. However, binding to a number of cell membranes took place from early epiboly onwards. After the onset of gastrulation, we observed a gradually increasing number of the deepest epiblast cells, showing immunostaining on part of their surface, facing the yolk syncytial layer (YSL) or the involuted cells. During early epiboly, anti-FN binding was restricted to areas in front of the migratory hypoblast cells. Later on, binding was found at the border of hypoblast and epiblast cells. At 100% epiboly, some contact areas of epiblast and hypoblast showed a discontinuous lining of reactivity, whilst other areas appeared devoid of anti-FN binding sites. The results indicate that FN is involved in the migration and guidance of hypoblast cells during gastrulation in carp. Correspondence to: P. Gevers     

The roles of FGF and MAP kinase signaling in the segregation of the epiblast and hypoblast cell lineages in bovine and human embryos

At the blastocyst stage of mammalian pre-implantation development, three distinct cell lineages have formed: trophectoderm, hypoblast (primitive endoderm) and epiblast. The inability to derive embryonic stem (ES) cell lines in a variety of species suggests divergence between species in the cell signaling pathways involved in early lineage specification. In mouse, segregation of the primitive endoderm lineage from the pluripotent epiblast lineage depends on FGF/MAP kinase signaling, but it is unknown whether this is conserved between species. Here we examined segregation of the hypoblast and epiblast lineages in bovine and human embryos through modulation of FGF/MAP kinase signaling pathways in cultured embryos. Bovine embryos stimulated with FGF4 and heparin form inner cell masses (ICMs) composed entirely of hypoblast cells and no epiblast cells. Inhibition of MEK in bovine embryos results in ICMs with increased epiblast precursors and decreased hypoblast precursors. The hypoblast precursor population was not fully ablated upon MEK inhibition, indicating that other factors are involved in hypoblast differentiation. Surprisingly, inhibition of FGF signaling upstream of MEK had no effects on epiblast and hypoblast precursor numbers in bovine development, suggesting that GATA6 expression is not dependent on FGF signaling. By contrast, in human embryos, inhibition of MEK did not significantly alter epiblast or hypoblast precursor numbers despite the ability of the MEK inhibitor to potently inhibit ERK phosphorylation in human ES cells. These findings demonstrate intrinsic differences in early mammalian development in the role of the FGF/MAP kinase signaling pathways in governing hypoblast versus epiblast lineage choices.     

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.     

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.     

Hypoblast cells of chick pre-streak stage embryos invaded basement membrane analogues in vitro: Implications for hypoblast layer formation

In early chick blastodermal morphogenesis, the hypoblast layer is organized beneath the epiblast and induces an axial structure. However, the origin of hypoblast cells and the mechanism of hypoblast layer formation are poorly understood. We hypothesized that the hypoblast layer is formed by an invasive process across the basement membrane of the juxtaposing epiblast, and tested the idea in vitro . Primary and secondary hypoblast cells from embryos at various pre-streak stages were dissociated into single cells and cultured on reconstituted basement membrane gel, laminin gel or fibronectin gel in the culture medium with or without serum for 24–48 h. As a result, we found that after 24 h of serum-supplemented culture, up to 35% of the hypoblast cells dissolved the gel and made holes on it. Similarly, up to 36% of the hypoblast cells showed invasiveness after 48 h in the serum-free culture. Furthermore, it was observed that Koller's sickle cells, which are regarded to be the progenitors of secondary hypoblast cells, penetrated those gels on which they were seeded. The posterior epiblast cells covering Koller's sickle were also invasive. These results suggest that the presumptive primary hypoblast cells that are known to mingle with epiblast cells invade through the basement membrane to form the hypoblast layer. Furthermore, the present results imply that invasion through the basement membrane may be involved in the formation of Koller's sickle, the anlage of secondary hypoblast.     

An electron-microscopical analysis of embryonic chick tissues explanted in culture

Summary Three types of tissue (hypoblast, germ wall and epiblast) were dissected from early chick embryos and explanted on Falcon plastic dishes. After they had settled and spread, the explants were fixed, usually within 18–24 h after explantation, and sections were cut through the tissue and the Falcon dish. The closeness of the cells to the substrate varied even within the same explant, but the epiblast tended to be closer to the substrate than did the hypoblast or germ wall. Plaques were present in all three tissues in regions where the cell processes contacted the substrate. Extensive desmosomes were visible in the epiblast explants, small desmosomes were present in the germ wall explants, but desmosomes were never seen in hypoblast explants. These differences in cell/substrate and cell/cell morphology are discussed in relation to the different behavioural characteristics of the three tissues. Some mixed cultures were also examined by electron microscopy. When the epiblast was confronted with either hypoblast or germ wall, it underlapped them at the region of contact.     

Fibronectin expression during the processes leading to axis formation in the chick embryo

Fibronectin expression was studied and found not to be present during the shedding process of stage VII chick embryos which indicates that fibronectin is not relevant during the implementation of the gravity-determined process of symmetrization. Fibronectin was detected, however, at the later stage XIII just prior to streak formation as a thin fluorescent sheet on the epiblastic side facing the hypoblast suggesting that it might be involved in the specific interactions that occur between epiblast and hypoblast and that lead to axis formation. Cultures of either epiblastic or hypoblastic chick cells indicate that both types of cells are capable of autonomous expression of fibronectin under in vitro conditions.     

Behaviour of dissociated hypoblast cells on the basal lamina and on extracellular fibrils in the gastrulating chicken embryo.

The spreading behaviour of dissociated hypoblast cells on and besides a band of aligned fibrils associated with the basal lamina of the epiblast was investigated by the use of scanning electron microscopy. A horse-shaped band of aligned fibrils, first demonstrated by Wakely and England (1979), is present during the gastrulation stages of chicken embryos on the ventral side of the epiblast at the cranial and lateral borders of the area pellucida. The basal lamina of the area pellucida situated inside the fibrillar band enables the spreading and probably the locomotion of dissociated cells, which appeared as polarized cells. Numerous cells were also found on the fibrillar band, and these cells lacked distinct lamellae and a polarized shape. Extensions of the cells contacted the extracellular fibrils and, at these sites of contact, the pattern of the fibrils was frequently deformed. From these observations and from previous results emerged the concept that spreading and locomotion of dissociated hypoblast cells, as well as single mesoblast cells and healing hypoblast epithelium, are inhibited by the band of extracellular fibrils, which acts as a physical barrier. The cell biological basis of the mechanism by which extracellular fibrils associated with the basal lamina arrest the migration of hypoblast and mesoblast cells, but guide the migration of primordial germ cells, is discussed.     

Interaction of three human malignant cell lines with chick hypoblast in culture

The hypoblast (lower layer) was dissected from young chick blastoderms and explanted in vitro, where it formed an epitheloid sheet. Cells from the following malignant lines were explanted on top of the sheet both as aggregates and as cell suspensions: Hu456 human bladder carcinoma, SAOS-2 human osteosarcoma, LICR(LOND)-HN-4 laryngeal carcinoma. The interaction of the malignant cells with the hypoblast was studied by time lapse cinephotography, light microscopy, and transmission electron microscopy. All malignant cells penetrated through the hypoblast, so that a gradually enlarging hole formed in it. Apart from this common pattern of behaviour, the three types of malignant cells differed in their interactions with the hypoblast in the following ways. 1) Both the Hu456 and to a lesser extent the SAOS-2 cells brought about an initial retraction of the hypoblast so that a temporary cell-free space was formed. No such retraction occurred in response to the LICR-(LOND)-HN-4 cells. 2) Each of the three types of malignant cells migrated for some distance beneath the hypoblast, and in this area of underlap, there were differences in the amount and disposition of extracellular material. Thus, there was more extracellular material between the hypoblast and underlying SAOS-2 cells than between the hypoblast and underlying Hu456 cells, whilst there was no extracellular material between the hypoblast and underlying LICR(LOND)-HN-4 cells. Indeed, the hypoblast and LICR(LOND)-HN-4 cells often shared desmosomes. 3) When explanted as aggregates on hypoblast Hu456 and SAOS-2 cells left the corona and migrated as solitary cells underneath the hypoblast in contrast with control aggregates explanted on plastic. These cells which had migrated beneath the hypoblast were flatter than their corresponding control cells which had spread on the plastic substrate. The flatter cells appeared to have been using the extracellular materials as a substrate, rather than the plastic. Such differences in the migratory behaviour between experimental and control cultures were not observed with LICR(LOND)-HN-4 cells.     

On the Origin of Primordial Germ Cells in the Chick Embryo

An attempt was made to re-examine the location of the primordial germ cells (PGCs) in very young chick embryos. Freshly laid blastoderms, prior to hypoblast formation, of a known anterio-posterior axis, were transversely bisected and each half was separately grown in vitro. Both anterior and posterior halves were shown to be fertile and each was shown to contain roughly the same amount of PGCs as a normal control embryo. It has been concluded that in the chick as well as in the duck there is no concentration of cells containing germinal plasm in the posterior part of the blastoderm.
Two other possibilities should be investigated:
1. A concentric arrangement of cells containing germinal plasm. 2. The absence of a germinal plasm and a relatively late appearance of PGCs as a result of induction.