Primary hypoblast development in the chick

Summary Scanning electron microscopy (SEM) indicates that the primary hypoblast forms beneath the area pellucida during the first 8 h of incubation mainly by establishment of contact among cells which move downward out of the epiblast. This movement, polyingression, begins posteriorly and continues antero-laterally during the period of primary hypoblast formation. Polyingression produces many pits and possibly a crescentic fold in the embryo upper surface with corresponding cell clusters and a ridge on the lower surface. Fixationin situ helps prevent formation of artifactual folds and wrinkles facilitating interpretation of the SEM images.Formation of intercellular adhesions which lead to development of an epithelial primary hypoblast proceeds in a posterior to anterior direction along with polyingression. This epithelialization begins with elaboration of numerous filamentous processes by cells as they arrive from the epiblast, and continues with ongoing input of cells, merging of cells and cell clusters, and cell flattening. We have also shown (Weinberger and Brick 1982) that proliferation of ingressing cells provides additional cells for hypoblast 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.     

Interaction of malignant MO4 cells with chick hypoblast in culture

Malignant MO4 mouse fibrosarcoma cells were confronted with fragments of hypoblast from stage 4 (Vakaet 1970) blastoderms in different dispositions either permitting or preventing contact of the hypoblast with the tissue culture plastic. Explantation of an MO4 cell aggregate on top of 24 h-old-hypoblast caused retraction of the hypoblast. Contact inhibition of ruffling in hypoblast cells at the inner margin, by MO4 cells migrating radially from the aggregate, prevented closure of the hole brought about by the initial retraction. Disintegration of hypoblast was not observed. Migration of MO4 cells during the first 24 h was faster from an aggregate explanted on top of hypoblast than from an aggregate explanted on tissue culture plastic. Hypoblast fragments explanted on top of confluent layers of MO4 cells attached and spread during the first 12 h. Later, the hypoblast progressively disintegrated. Here, MO4 cells accumulated underneath the hypoblast. We concluded 1) that the hypoblast attracted the MO4 cells by influencing their pattern of migration and 2) that contact with the artificial substrate allowed survival of hypoblast confronting malignant MO4 cells. Ultrastructural analysis suggested that formation of extracellular material played a major role in the interaction between the normal tissue and the malignant cells.     

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.     

Immunohistochemical analysis of the segregation process of the quail germ cell lineage

An antiserum against quail 7 day gonadal germ cells was found to react specifically with gonadal germ cells of both sexes. Transverse sections from a range of early quail developmental stages were submitted to the antibody PAP reaction. Blastodiscs from the earliest uterine stages (II to X E.G. & K) reacted very strongly, while the overall reaction gradually decreased in older blastoderms. At stage XIII both epiblast and hypoblast were weakly stained, but some large, PGC-like cells stained intensively. During gastrulation (PS formation) the reaction of the epiblast disappears quicker than that of the hypoblast. The newly formed mesoderm and entoderm do not react at all and the reaction gradually becomes limited mainly to the PGCs and somewhat to the primary hypoblast which is moving into the germinal crescent. The widely spread reaction at the early stages is thus gradually being restricted to the PGCs.     

Phagocytic capacity of invasive malignant cells in three-dimensional culture

To study the phagocytic capacity of invasive malignant cells, fragments of the hypoblast from chick blastoderms were confronted in three-dimensional culture with spheroidal aggregates of 1) malignant virally transformed C3H mouse cells (MO4), 2) HeLa cells and 3) embryonic chick heart cells. The hypoblast was used because it contains yolk, a marker that is absent in the confronting cells and that can be identified histologically and ultrastructurally. The confronting tissues were incubated on semi-solid agar-agar medium or in fluid medium on a gyrotory shaker. Cultures were followed for 1 to 7 days by stereomicroscopy, cinemicrophotography, light and transmission electron microscopy. Confrontation with MO4 cells of HeLa cells, known to be invasive in vitro, led to complete disappearance of the hypoblast. The fragments of hypoblast were well conserved when cultured alone or confronted with aggregates of chick heart cells. Degeneration of the hypoblast is shown at the area of contact with MO4-cell or HeLa-cell aggregates, in contrast to heart cells. Filopodia-like extensions from the MO4 or HeLa cells penetrate intercellularly, transcellularly and intracellularly into the hypoblast. Phagosomes, containing yolk and unidentified debris are observed in MO4 cells and in HeLa cells, but not in heart cells. These observations demonstrate the phagocytic capacity of invasive malignant cells.     

Differentiation of dissociated-reconstituted epiblasts of the chick under the influence of a normal hypoblast

Abstract. A cell suspension of chick epiblast cells cultured under defined conditions to form a flat disk, can differentiate and generate axial embryonic structures when covered with a primary hypoblast. Macroscopically identifiable axes developed in 26 out of 33 cases. In all cases axes developed in a direction consistent with the posteroanterior polarity of the normal hypoblast. Almost invariably the epiblast cells differentiated into ectoderm, neural plates or tubes, and endoderm. In some cases typical primitive streaks were found, sometimes accompanied by signs of axial mesoderm, whereas in other cases the primitive streaks seemed to regress. In the absence of a hypoblast no differentiation of neural tissue or any signs of axial development were observed.     

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.     

The dynamics of antigenic changes in the epiblast and hypoblast of the chick during the processes of hypoblast, primitive streak and head process formation, as revealed by immunofluorescence.

Antisera were prepared to epiblast, primary hypoblast, yolk, yolk entoderm, and extraembryonic yolk sac ectoderm and were submitted to various absorption procedures. The absorbed antisera were used in the indirect immunofluorescent method to stain microscopic sections of developing chick blastoderms at different developmental stages. The antigens revealed by the staining at the periods studied were divided into groups of persistent, nonspecific, and specific antigens. The epiblast does not appear to form or include specific antigens until stage XIII (full hypoblast). The primary hypoblast is the layer which during its formation acquires specificity by the inclusion of antigenic components through a cytoplasmic segregation and probably by one or two waves of appearance of primary hypoblast specific antigens. The inductive role of the hypoblast is discussed in relation to the above antigenic manifestations. The anti-hypoblast and anti-epiblast sera after absorption with yolk were found to be suitable reagents for the detection of morphogenetic movements.     

Transfer of extracellular matrix components between germ layers in chimaeric chicken-quail blastoderms

Summary A chemical basis for the transmission of signals during gastrulation has been investigated by using chimaeric embryos resulting from the combination of ³H-glucosamine-labelled and unlabelled hypoblast with epiblast taken from chicken and quail embryos at stage 3 of Vakaet (1970). The ability to distinguish chicken from quail cells on the basis of their different nuclear distribution of heterochromatin after Feulgen staining made it possible to determine the origin of the cells in the chimaerae. Tritiated quail hypoblast (after incubation of the embryo in the presence of ³H-glucosamine) was transplanted onto unlabelled chicken blastoderm deprived of its hypoblast. After culture of the chimaera for 5 h, the autoradiographic pattern shows silver grains not only over the graft, but also at the ventral surface of the epiblast of the host. Transfer of label may occur to mesoblast cells, but not between chicken and quail hypoblast cells. Chase experiments exclude the possibility that unprocessed, tritiated glucosamine is transferred. Chemical fixation of the host before transplantation of a labelled quail hypoblast also allows visualization of a transfer of macromolecules from hypoblast to the basement membrane of the epiblast, suggesting that an intervention of the epiblast cells in this process is not necessary. The morphology of the chimaeric embryos, as studied by scanning electron microscopy, suggests a direct deposition of these macromolecules by filopodia of the dorsal surface of the hypoblast. The possibility of diffusion of free macromolecules has been considered and can reasonably be discarded on the basis of several observations. The reverse experiment, in which unlabelled quail hypoblast and possibly some mesoblast have been combined with a tritiated host deprived of its hypoblast, also shows the transfer of label from the host to the cellular surface of the graft. A two-way exchange of glucosamine-containing molecules thus occurs in the blastoderm. It is hypothesized that: (1) low molecular weight compounds, macromolecular material, and/or catabolic products, are exchanged between the different germ layers during gastrulation; (2) the components of the extracellular matrix turn over and are continuously changing; (3) this transfer is a possible mechanism of transmission for developmental or inductive signals during embryonic development. The present results also demonstrate the participation of underlying tissue in the biosynthesis of basement membrane components of an epithelium.     

Appearance of Primordial Germ Cells in Young Chick Blastoderms Cultured in vitro

Appearance of primordial germ cells (PGCs) in young chick blastoderms was investigated by the cultivation of only the epiblast or hypoblast. Presumptive PGCs exist in the epiblast before primitive-streak formation. They translocate gradually to the lower layer during early stages of primitive-streak formation, though substantial number of presumptive PGCs remain in the upper layer. The existing primary hypoblast under the epiblast is dispensable for the further differentiation of the PGCs.     

The marginal zone and its contribution to the hypoblast and primitive streak of the chick embryo

The marginal zone of the chick embryo has been shown to play an important role in the formation of the hypoblast and of the primitive streak. In this study, time-lapse filming, fate mapping, ablation and transplantation experiments were combined to study its contribution to these structures. It was found that the deep (endodermal) portion of the posterior marginal zone contributes to the hypoblast and to the junctional endoblast, while the epiblast portion of the same region contributes to the epiblast of the primitive streak and to the definitive (gut) endoderm derived from it. Within the deep part of the posterior marginal zone, a subpopulation of HNK-1-positive cells contributes to the hypoblast. Removal of the deep part of the marginal zone prevents regeneration of the hypoblast but not the formation of a primitive streak. Removal of both layers of the marginal zone leads to a primitive streak of abnormal morphology but mesendodermal cells nevertheless differentiate. These results show that the two main properties of the posterior marginal zone (contributing to the hypoblast and controlling the site of primitive streak formation) are separable, and reside in different germ layers. This conclusion does not support the idea that the influence of the posterior marginal zone on the development of axial structures is due to it being the source of secondary hypoblast cells.     

Organelle differentiation in the chick blastoderm during hypoblast formation

Summary The ultrastructure of the chick blastoderm was examined at three developmental stages, from an unincubated single-layered system through hypoblast advancement to full hypoblast formation.With the onset of incubation the nucleolus changes from a loose network of intermingled pars fibrosa and pars granulosa into a compact body with a definite matrix material.The endoplasmic reticulum, mitochondria, and Golgi complex increase in complexity and volume. In blastoderms with a fully developed hypoblast a special asymmetrical endoplasmic reticulum becomes abundant. These data are analysed in relation to similar structural differentiation of the nucleolus, endoplasmic reticulum, Golgi complex and mitochondria in the embryonic development of other vertebrate groups.The above changes in organelle structure are noted in both the epi- and the hypoblast, although these organelles become more abundant in the former. In the intermediate stage no differences are noted between epiblast cells underlined by hypoblast and those of the anterior single-layered region. The above changes in the epiblast must therefore be related to age and not to contact with the advancing hypoblast.Previous studies mentioned in the text seem to indicate that the inducing effect of the hypoblast on the epiblast is exerted after its complete formation and not during its advancement. Our results in the organelle differentiation during hypoblast formation are in accordance with this hypothesis.     

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.     

Gastrulation: Is It Analogous to Malignant Invasion

The process of gastrulation has often been compared with thatof malignant invasion. In this paper, the terms "malignant"and "invasion" are denned and the characteristics of malignantcells are discussed. One of the best examples of invasion duringgastrulation takes place during the formation of the endodermin the chick, when the definitive endoblast invades the hypoblast.Experiments are described in which the hypoblast is invadedby a) definitive endoblast, b) other normal embryonic cells,and c) three types of human malignant cells. It was found thatnot only does the hypoblast react differently to normal andmalignant cells, but that the cell interactions differ alsoaccording to the type of malignant cells. In particular, thereare differences in the behaviour of the cells and in the amountof extracellular material laid down between the hypoblast andmalignant cells. It is concluded that even within the limitsof this experiment, chick gastrulation is not wholly analogousto malignant invasion.     

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 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.     

Induction of gastrulation in the chick embryo

Interaction between the epiblast and the primary hypoblast in chick blastula results in induction of the primitive streak (PS) in the epiblast. Alpha-amanitin, a specific inhibitor of poly A-containing RNA synthesis, inhibits formation of the definitive PS. This inhibition is associated with qualitative changes in the pattern of protein synthesis in the hypoblast but not in the epiblast. The protein pattern of the component areas of the epiblast shows increase in some polypeptides after treatment with alpha-amanitin. By contrast, alpha-amanitin resulted in a decrease in synthesis of several polypeptides, which are either undetectable or weakly present in the hypoblast. The alpha-amanitin-sensitive translational products of the embryonic genome that are observed in the hypoblast may have specific functions in the control of PS induction and stabilization.