Microinjection in the chick blastoderm. An improved method to study the extracellular matrix in the living organism

A microinjection technique for the chick blastoderm is described. With a micropipette attached to a de Fonbrune micromanipulator, 25-45 nl of a reagent was injected into the entophyllic crescent of a chick blastoderm explanted in vitro according to New [7]. This procedure offers the advantage of eliminating the concentration variability which was observed after subblastodisc injection, and in contrast to the in ovo techniques, it allows one to stage the blastoderms properly. To check its applicability, testicular hyaluronidase was injected. On the basis of morphological and histochemical observations we ascertained that the experimental procedure itself did not interfere with the results. This method may provide a reliable experimental procedure with which to study the interactions between several macromolecules and the tissues during morphogenesis.     

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.     

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.     

Expression of Embryonic Haemoglobin in ts AEV-Transformed Embryonic Erythroid Cells During Temperature-Induced Differentiation

Cells prepared from 1-day-old chick blastoderms were infected with a temperature-sensitive mutant of avian erythroblastosis virus ( ts AEV). Clonal strains of transformed erythroblasts were isolated from the infected blastoderm cells. By shift to the nonpermissive temperature, these cells could be induced to differentiate into erythrocyte-like cells which expressed embryonic haemoglobins. Embryonic haemoglobins could not be detected in ts AEV-transformed erythroblasts from adult bone marrow when induced to differentiate under the same conditions. In contrast to normal primitive erythrocytes, ts AEV-infected embryonic erythroblasts differentiated in vitro expressed also adult haemoglobin. These results suggest an influence of the haematopoietic environment on the switch from embryonic to adult erythrocytes.     

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.     

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     

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.     

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.     

Cell Population Growth and Area Expansion in Early Chick Embryos During Normal and Abnormal Morphogenesis in vitro

The exponential growth and cell population during the early embryogenesis of chick, cultured in vitro correlates with a linear increase in the blastoderm area. To understand the relationship between these parameters and normal morphogenesis, we have used a known teratogen, trypan blue, as a probe. A method is developed in which each new embryonic structure is assigned a rank value of 1 and the total number of ranks allows quantification of development and establishment of a numerical relationship between the size of the cell population, blastoderm area and the morphological development. The teratogen inhibits cell population growth, morphogenetic movements and shaping of organ primordia, but not the epiboly and differentiation of cells which have already invaginated and positioned during primitive streak formation. In contrast, the cell population growth, but not the blastoderm area-expansion, is correlated with the extent of abnormal development. A graphic analysis of the rank order, log cell number and blastoderm area reveals that these three parameters coordinately regulate morphogenesis. It is suggested that head fold formation is the key event regulating the progress of early morphogenesis.     

Transient stimulation of glucose metabolism by insulin in the 1-day chick embryo

Effects of insulin upon glucose metabolism were investigated in chick embryos explanted in vitro during the first 30 h of incubation. Insulin stimulated the glucose consumption of the chick gastrula (18 h) and neurula (24 h), but had no effect on the late blastula (0 h:laying) and on the stage of six to eight somites (30 h). The increase in glucose consumption concerned both the embryonic area pellucida (AP) and extraembryonic area opaca (AO). AP responded to a greater extent (50%) and at a lower range of concentrations (0.1-1.0 ng/ml) than AO (30%; 1-100 ng/ml). Insulin had no effect on the oxygen consumption of blastoderms, whereas it stimulated the aerobic lactate production (approximately 70% of the additional glucose consumption was converted to lactate). The nanomolar range of stimulating concentrations suggests that insulin has a specific effect in the chick embryo, and that it could modulate glucose metabolism in ovo as well. The transient sensitivity of the embryo to insulin is discussed in relation to behavior of mesodermal cells.     

Avian pluripotent stem cells

Pluripotent embryonic stem cells are undifferentiated cells capable of proliferation and self-renewal and have the capacity to differentiate into all somatic cell types and the germ line. They provide an in vitro model of early embryonic differentiation and are a useful means for targeted manipulation of the genome. Pluripotent stem cells in the chick have been derived from stage X blastoderms and 5.5 day gonadal primordial germ cells (PGCs). Blastoderm-derived embryonic stem cells (ESCs) have the capacity for in vitro differentiation into embryoid bodies and derivatives of the three primary germ layers. When grafted onto the chorioallantoic membrane, the ESCs formed a variety of differentiated cell types and attempted to organize into complex structures. In addition, when injected into the unincubated stage X blastoderm, the ESCs can be found in numerous somatic tissues and the germ line. The potential give rise to somatic and germ line chimeras is highly dependent upon the culture conditions and decreases with passage. Likewise, PGC-derived embryonic germ cells (EGCs) can give rise to simple embryoid bodies and can undergo some differentiation in vitro. Interestingly, chicken EG cells contribute to somatic lineages when injected into the stage X blastoderm, but only germ line chimeras have resulted from EGCs injected into the vasculature of the stage 16 embryo. To date, no lines of transgenic chickens have been generated using ESCs or EGCs. Nevertheless, progress towards the culture of avian pluripotent stem cells has been significant. In the future, the answers to fundamental questions regarding segregation of the avian germ line and the molecular basis of pluripotency should foster the full use of avian pluripotent stem cells.     

Wound healing in the primitive deep layer of the young chick blastoderm.

Wound healing in the primitive deep layer of stage 4 chick blastoderms was studied in vitro by cinemicrophotography of living cultures and by photomicroscopy, scanning- and transmission electron microscopy after fixation. Experimental wounds with an average diameter of 0.3 mm healed completely within 2 to 4 h through migration of the cells at their rims. Healing occurred in mesenchyme-free areas, providing us with a purely epithelial reaction. The rim cells of the primitive deep layer formed extensions at their free flank, described as fila, filopodia, lamellae and lamellipodia. They were already present in blastoderms fixed at the earliest after the intervention. This reaction was ascribed to the elimination of a normal fellow cell at the side of the rim cell facing the defect. Movement of the rim cell ceased upon meeting another cell with the same polarity. At this moment lamellipodia disappeared as suddenly as they had formed, and the number of fila and filopodia decreased. We believe that the chick blastoderm's primitive deep layer might be appropriate for analysis of the factors governing primary epithelial wound healing.     

In the absence of Rauber's sickle material,no blood islands are formed in the avian blastoderm

Using the quail-chick chimera technique, we followed the fate of Rauber's sickle cells in older whole blastoderms (cultured for approximately 2 days): after removal of the autochthonous Rauber's sickle from an unincubated chicken blastoderm, a quail Rauber's sickle was grafted isotopically and isochronically in its place. In transverse sections through these chimeras, the grafted quail Rauber's sickle cells were seen to have transformed into a broad row or ridge of quail junctional endoblast cells extending at the inner border of the area containing blood islands. After unilateral removal of the junctional endoblast from an intermediate streak chicken blastoderm (Stage 3; Hamburger and Hamilton [1951] J Morphol 88:49-92), we observed during further in vitro culture that at the operated side, in the area previously occupied by this junctional endoblast, blood islands no longer developed. If after such a unilateral removal of the chicken junctional endoblast quail junctional endoblast was apposed in its place, then blood islands reappeared in the operated area. The intimate contact between the apposed quail junctional endoblast and the recently formed blood islands, derived from peripherally migrating mesoderm, was very obvious on sections through such chimeras. We further demonstrate that Rauber's sickle vs. junctional endoblast is indispensable for the anlage of blood islands in avian blastoderms. Indeed, in the absence of Rauber's sickle material no blood islands develop (even when mesoderm is present after ingression of the upper layer via a primitive streak) in the isolated central region of the area centralis of unincubated chicken blastoderms after culture in vitro. Also, no junctional endoblast and no sickle canal appear in these explants. By contrast, if a Rauber's sickle fragment is placed on such an isolated central blastoderm region, then blood islands develop. These blood islands start to develop from peripherally migrating mesoderm in the neighborhood of the Rauber's sickle-derived junctional endoblast.     

Effects of follistatin and BMP4 proteins on early dorso-ventral patterning in chick

In Xenopus and zebrafish certain bone morphognetic proteins (BMPs), and proteins that antagonise these by preventing their interaction with receptors, constitute a morphogen system in primary dorso-ventral patterning. This system may be directly involved in the parallel processes, within mesoderm and ectoderm, whereby the boundaries of the dorsal (paraxial) mesoderm and the neural plate are established. The bird blastoderm, amenable to grafting techniques and to direct exposure to specific proteins, has provided an opportunity to explore the phylogenetic conservation of such antagonistic system. We have grafted the gastrular organiser (node) into hosts, testing the effects of prior exposure of either grafted or host tissue to Follistatin (a known antagonist of TGFbeta superfamily ligands including BMP4) or to BMP4 protein. Strong, converse effects are seen from the two agents, the most consistent being on the sizes of new dorsalised areas (second neural plates) induced in host epiblast. Follistatin also enhances extension movements due to grafts, though without clear effect upon the rostro-caudal completeness of new patterns. Neural induction in chick epiblast by grafted mouse nodes are also more extensive, after their pre-incubation in Follistatin. Follistatin potentiates other, unknown but distinctive signals coming from the node, being unable to convert other non-inducing pieces of blastoderm into organisers on grafting. Pre-incubation of early blastoderms in BMP4 has such profound effects on normal dorsal axial development that host responsiveness of these blastoderms as hosts to node grafts is difficult to assess. Follistatin has no such overt effect on host development, but greatly enhances the competence of host epiblast to grafts of untreated nodes. Early chick BMP4 and BMP7 expressions are consistent with the proposed roles, though Follistatin is probably an experimental tool only in the present study.     

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.     

Growth-factor-related proteins that are inducers in early amphibian development may mediate similar steps in amniote (bird) embryogenesis

Xenopus and murine activin A homologues (XTC-MIF and WEHI-MIF) and Xenopus and bovine basic fibroblast growth factor (bFGFs) are potent inducers of mesodermal and endodermal pathways of development in amphibian blastular animal cap cells. Porcine transforming growth factor beta 2 (TGF beta 2) is a weaker inducer in the same assay but human platelet-derived growth factor (PDGF) is inactive. We have assayed these factors for evidence of homologous effects in bird development. Unlike amphibians, bird embryos never exhibit a clean segregation of a cell layer that has a uniform specification when uninduced, and can be cultured in isolation as an assay after exposure to soluble factors. We have therefore performed less direct experiments, of three types. We have briefly cultured early chick epiblast cells with and without factors and then assayed their capacity to attach and spread upon fibronectin, in comparison with young streak and substreak hypoblast cells. We have asked whether similar microculture with factors alters the ability of quail epiblast cells to disrupt morphogenesis, and to integrate into the structure, of host chick blastoderms into which they are seeded. Finally, whole early chick blastoderms have been preincubated with or without factors for a brief period before setting them up to develop in vitro under circumstances usually permitting successful formation of axial pattern. Strong effects of the activin-like factors, of bFGF and of TGF beta 2 were seen in all three procedures, while PDGF was essentially inactive. In epiblast cells, effective factors at picomolar concentrations induced stable spreading upon fibronectin, and a capacity to adhere and spread upon basal epiblast surface and prevent morphogenesis in host blastoderms. Preincubation of whole early blastoderms with these factors led to characteristic deviation from normal development over the subsequent 24 h. We therefore suggest that peptides from the particular families that are active as inducers in amphibian blastula ectoderm may mediate homologous or closely related steps in respecification throughout vertebrates.     

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.     

Primordial germ cells of the young chick blastoderm originate from the central zone of the area pellucida irrespective of the embryo-forming process

Early chick blastoderms (stages X-XII) were divided by a circular cut into two fragments. In one experimental group, the area opaca was separated from the marginal zone and the central disc of the area pellucida, while in another group the area opaca plus marginal zone were separated from the central disc. Other blastoderms of equivalent stages were each cut into three strips of equal size (either perpendicular or parallel to the axis of symmetry). The fragments were isolated and incubated for 43-48 h after which they were PAS-stained, whole-mounted and checked for the presence of primordial germ cells (PGCs). The results showed that most of the PGCs originated from the central disc and not from the periphery of the area pellucida and that they segregated from this zone even if no embryonic axis developed in the explant. In such cases, the PGCs were found to be dispersed throughout the entire explant, usually in association with forming blood islands. When an axis did develop in the explant, the PGCs were found to be concentrated around its anterior end, in a pattern resembling the germinal crescent. No indication of a quantitative regulation of PGCs was found in the explants and the sum of PGCs, calculated for the complementary fragments of a blastoderm, matched the range of numbers in control blastoderms. Our results suggest that PGCs may already be determined as early as stage X and that their further differentiation is independent of the embryo-forming process.     

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.