Analysis of tissue flow patterns during primitive streak formation in the chick embryo

We have investigated the patterns of tissue flow underlying the formation of the primitive streak in the chick embryo. Analysis of time-lapse sequences of brightfield images to extract the tissue velocity field and of fluorescence images of small groups of DiI-labelled cells have shown that epiblast cells move in two large-scale counter-rotating streams, which merge at the site of streak formation. Despite the large-scale tissue flows, individual cells appear to move little relative to their neighbours. As the streak forms, it elongates in both the anterior and posterior directions. Inhibition of actin polymerisation via local application of the inhibitor latrunculin A immediately terminates anterior extension of the streak tip, but does not prevent posterior elongation. Inhibition of actin polymerisation at the base of the streak completely inhibits streak formation, implying that continuous movement of cells into the base of the forming streak is crucial for extension. Analysis of cycling cells in the early embryo shows that cell-cycle progression in the epiblast is quite uniform before the primitive streak forms then decreases in the central epiblast and incipient streak and increases at the boundary between the area pellucida and area opaca during elongation. The cell-cycle inhibitor aphidicolin, at concentrations that completely block cell-cycle progression, permits initial streak formation but arrests development during extension. Our analysis suggests that cell division maintains the cell-flow pattern that supplies the streak with cells from the lateral epiblast, which is critical for epiblast expansion in peripheral areas, but that division does not drive streak formation or the observed tissue flow.     

Nuclear beta-catenin and the development of bilateral symmetry in normal and LiCl-exposed chick embryos.

Studies in Xenopus laevis and zebrafish suggest a key role for beta-catenin in the specification of the axis of bilateral symmetry. In these organisms, nuclear beta-catenin demarcates the dorsalizing centers. We have asked whether beta-catenin plays a comparable role in the chick embryo and how it is adapted to the particular developmental constraints of chick development. The first nuclear localization of beta-catenin is observed in late intrauterine stages of development in the periphery of the blastoderm, the developing area opaca and marginal zone. Obviously, this early, radially symmetric domain does not predict the future organizing center of the embryo. During further development, cells containing nuclear beta-catenin spread under the epiblast and form the secondary hypoblast. The onset of hypoblast formation thus demarcates the first bilateral symmetry in nuclear beta-catenin distribution. Lithium chloride exposure also causes ectopic nuclear localization of beta-catenin in cells of the epiblast in the area pellucida. Embryos treated before primitive streak formation become completely radialized, as shown by the expression of molecular markers, CMIX and GSC. Lithium treatments performed during early or medium streak stages cause excessive development of the anterior primitive streak, node and notochord, and lead to a degeneration of prospective ventral and posterior structures, as shown by the expression of the molecular markers GSC, CNOT1, BMP2 and Ch-Tbx6L. In summary, we found that in spite of remarkable spatiotemporal differences, beta-catenin acts in the chick in a manner similar to that in fish and amphibia.     

The hypoblast of the chick embryo positions the primitive streak by antagonizing nodal signaling

The hypoblast (equivalent to the mouse anterior visceral endoderm) of the chick embryo plays a role in regulating embryonic polarity. Surprisingly, hypoblast removal causes multiple embryonic axes to form, suggesting that it emits an inhibitor of axis formation. We show that Cerberus (a multifunctional antagonist of Nodal, Wnt, and BMP signaling) is produced by the hypoblast and inhibits primitive streak formation. This activity is mimicked by Cerberus-Short (CerS), which only inhibits Nodal. Nodal misexpression can initiate an ectopic primitive streak, but only when the hypoblast is removed. We propose that, during normal development, the primitive streak forms only when the hypoblast is displaced away from the posterior margin by the endoblast, which lacks Cerberus.     

Early chick embryonic cells can form clones in agarose cultures

Early chick embryonic cells prior to the formation of the primitive streak, have been cultured in a two-layer soft-agarose system. Single, primary cells when grown in this system were capable of producing colonies ranging in size from 30 to 100 cells. The plating efficiency varied between 1 and 5% and the colonies remained viable for about 2 weeks. We believe this is the first report of normal, non-passaged cells which show anchorage-independent growth properties by forming colonies in a standard agarose culture in the absence of additional factors. The importance of being able to use normal monoclonal embryonic cell populations in studying early developmental processes is also discussed.     

Fate maps of the primitive streak in chick and quail embryo: ingression timing of progenitor cells of each rostro-caudal axial level of somites

Developmental fates of cells emigrating from the primitive streak were traced by a fluorescent dye Dil both in chick and in quail embryos from the fully grown streak stage to 12-somite stage, focusing on the development of mesoderm and especially on the timing of ingression of each level of somitic mesoderm. The fate maps of the chick and quail streak were alike, although the chick streak was longer at all stages examined. The anterior part of the primitive streak predominantly produced somites. The thoracic and the lumbar somites were shown to begin to ingress at the 5 somite-stage and 10 somite-stage in a chick embryo, and 6 somite-stage and 9 somite-stage in a quail embryo, respectively. The posterior part of the streak served mainly as the origin of more lateral or extra embryonic mesoderm. As development proceeded, the fate of the posterior part of the streak changed from the lateral plate mesoderm to the tail bud mesoderm and then to extra embryonic, allantois mesoderm. The fate map of the primitive streak in chick and quail embryo presented here will serve as basic data for studies on mesoderm development with embryo manipulation, especially for transplantation experiments between chick and quail embryos.     

The enhancement of in vitro survival and chondrogenesis of limb bud cells by cartilage conditioned medium

Dissociated stage 21–28 chick embryo limb bud cells showed an increasing ability to produce cartilage colonies in vitro with in vivo maturation. In addition dissociated stage 21–28 chick embryo limb bud cells exposed to cartilage conditioned medium continuously or only for 48 hr prior to subculture showed an enhanced (as much as 15-fold) ability to form differentiated cartilage colonies. By this criterion, cells were more responsive to conditioned medium prior to stage 25. Conditioned medium from fibroblast cultures caused an inhibition of cartilage colony formation, suggesting that the effect is cell-type specific. Besides increasing cartilage colony formation by enhanced cell survival, the incorporation of S³⁵O₄ into isolated glycosaminoglycans is also stimulated when limb bud cells are exposed to cartilage conditioned medium. The results support a model for cell differentiation which involves the enhancement of a particular differentiated capacity by a diffusible cell-type-specific macromolecule.     

Visceral endoderm induces specification of cardiomyocytes in mice

The endoderm plays an inductive role in the formation of cardiomyocytes in many vertebrates. Here, we provide further evidence for this in the mouse and demonstrate enhanced cardiomyogenesis in mouse embryonic stem cells cultured in the presence of native visceral endoderm. Isolated mesoderm from late-primitive streak stage mouse embryos that still have an open proamniotic canal had a reduced capacity to form cardiomyocytes after 4 days in culture compared with mesoderm isolated from later stages but prior to cardiomyogenesis. Moreover, removal of the visceral endoderm but not the primitive streak reduced the formation of beating areas in embryo explants in culture. Coculture with the END2 cell line, which has visceral endoderm-like properties, restored the formation of beating areas. Immunohistochemical analysis showed that the expected candidate signaling pathways downstream of Wnts and bone morphogenetic proteins (BMPs) were active in the embryo at the appropriate time and place to be involved. Overall, the results show that, as in other vertebrates, the (visceral) endoderm plays an important role in the early events of mouse cardiomyogenesis.     

Induction and prevention of chondrocyte hypertrophy in culture

Primary chondrocytes from whole chick embryo sterna can be maintained in suspension culture stabilized with agarose for extended periods of time. In the absence of FBS, the cells remain viable only when seeded at high densities. They do not proliferate at a high rate but they deposit extracellular matrix with fibrils resembling those of authentic embryonic cartilage in their appearance and collagen composition. The cells exhibit many morphological and biochemical characteristics of resting chondrocytes and they do not produce collagen X, a marker for hypertrophic cartilage undergoing endochondral ossification. At low density, cells survive in culture without FBS when the media are conditioned by chondrocytes grown at high density. Thus, resting cartilage cells in agarose cultures can produce factors required for their own viability. Addition of FBS to the culture media leads to profound changes in the phenotype of chondrocytes seeded at low density. Cells form colonies at a high rate and assume properties of hypertrophic cells, including the synthesis of collagen X. They extensively deposit extracellular matrix resembling more closely that of adult rather than embryonic cartilage.     

Endogenous patterns of BMP signaling during early chick development

Bone morphogenetic proteins (BMPs) are members of the transforming growth factor beta superfamily signaling molecules that play important roles in a wide variety of developmental processes. In this study, we have used an antibody specific for the phosphorylated and activated form of Smad1 to examine endogenous patterns of BMP signaling in chick embryos during early development. We find complex spatial and temporal distributions of BMP signaling that elucidate how BMPs may function in multiple patterning events in the early chick embryo. In the pregastrula embryo, we find that BMP signaling is initially ubiquitous and is extinguished in the epiblast at the onset of primitive streak formation. At the head process stage, BMP signaling is inactivated in prospective neural plate, while it is strongly activated at the neural plate border, a region which is populated by cells that will give rise to neural crest. During later development, we find a dynamic spatiotemporal activation of BMP signaling along the rostrocaudal axis, in the dorsal neural tube, in the notochord, and in the somites during their maturation process. We discuss the implication of our results for endogenous functions of BMP signaling during chick development.     

Developmental patterning of the carbohydrate antigen FC10.2 during early embryogenesis in the chick

An oligosaccharide antigen (FC10.2), formerly described only in mammalian cells and secreted glycoproteins, has been detected and found to display striking temporal and spatial patterning in the chick during early embryonic development. This antigen is expressed on type 1 chains, which are isomers of oligosaccharides of the poly-N-acetyllactosamine series (type 2 chains). Immunoreactivities before and after neuraminidase treatment of serial sections of chick embryos during the first 17 stages of development indicate that the FC10.2 structure occurs predominantly in the sialylated form (S-FC10.2). The FC10.2 and S-FC10.2 antigens are prominent markers of the primordial germ cells, being strongly expressed by these cells from the pre-primitive streak stage onwards. S-FC10.2 is also a clear marker of the pronephric duct from its first appearance. Initially present over the entire apical surface of the ectoderm, antigenicity diminishes in an antero-posterior direction as neurulation proceeds. A unique pattern for a carbohydrate antigen is displayed by cells of the primitive streak; antigenicity is lost with de-epithelialisation and ingression, but is regained in a pericellular distribution on the mesoderm cells that emerge from the primitive streak. Thereafter, successive changes in expression and distribution of FC10.2 and S-FC10.2 are features of mesodermal tissues, particularly during somitogenesis. These antigens are prominent components of the extracellular matrix around the notochord and sclerotome cells. They are also prominent posteriorly in the subectodermal region, ceasing abruptly at the lateral limits of the embryo proper. Although no absolute correlations can yet be made, several features of the distribution of these antigens suggest that they may be integral components of, or ligands for, cell adhesion molecules.     

Post-hatching development of the porcine and bovine embryo--defining criteria for expected development in vivo and in vitro

Particular attention has been paid to the pre-hatching period of embryonic development although blastocyst development is a poor indicator of embryo viability. Post-hatching embryonic development in vitro would allow for establishment of more accurate tools for evaluating developmental potential without the need for transfer to recipient animals. Such a system would require (1) definition of milestones of expected post-hatching embryonic development in vivo; and (2) development of adequate culture systems. We propose a stereomicroscopical staging system for post-hatching embryos defining the following stages: (1) Expanded hatched blastocyst stage where the embryo presents an inner cell mass (ICM) covered by trophoblast. (2) Pre-streak stage 1 where the embryonic disc is formed. (3) Pre-streak stage 2 where a crescent-shaped thickening of the caudal portion of the embryonic disk appears. (4) Primitive streak stage where the primitive streak has developed as an axis of cell ingression of cells for meso- and endoderm formation. (5) Neural groove stage where the neural groove is developing from the rostral pole of the embryo along with a proportional shortening of the primitive streak; and (6) Somite stage(s) where paraxial mesoderm gradually condensates to form somites. Post-hatching development of bovine embryos in vitro is compromised and although hatching occurs and elongation can be physically provoked by culture in agarose tunnels, the embryonic disk characterizing the pre-streak stage 1 is never established. Thus, particular focus should be placed on establishing culture conditions that support at least some of the above-mentioned critical phases of development that in vivo occur within the initial two (pig) to three (cattle) weeks.     

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.     

Evidence that plasminogen activator is not involved in basement membrane penetration at avian gastrulation

We have used the method of radial caseinolysis in agarose to assay for the presence of plasminogen activator in the primitive streak cells of the early chick embryo. These cells are undergoing an epithelial-mesenchymal transformation in the process of the differentiation of mesoderm cells from the ectoderm. In the primitive streak, the epithelial cells, after penetrating the basement membrane, ingress and invade the underlying tissue space as fibroblast-like mesenchyme cells. In contrast to some other early embryonic invasionary and migratory events, we find no evidence for the participation of plasminogen activator in this process.     

Hemopoietic colonies on the chorioallantoic membrane of the chick embryo: Induction by embryonic,adherent, non-hemopoietic spleen cells

Granulocytic and erythrocytic colonies developed on the chick embryo chorioallantoic membrane (CAM) following the inoculation of chick embryo spleen cells. Dose response and kinetic experiments showed that the colonies were derived from cell aggregates present in the inoculum. Dissociation and reaggregation studies of the CAM colony-inducing cells (CAM-CIC) indicated that these cells must be present as aggregates in order to form colonies. Results from the morphology and cell marker experiments suggested that the colony-inducing aggregates (CAM-CIA) attract and support the differentiation of primitive host hemopoietic cells. The physical characteristics of the CAM-CIC, which are different from those of the hemopoietic progenitor cells, indicated that they represent a stromal cell population of the chick embryo spleen. Further evidence supporting this notion was provided by the radiation studies which showed that the colony-inducing ability of the CAM-CIC is radioresistant. The above characteristics of the CAM-CIC strongly suggest that they represent the stromal cells of the chick embryo spleen which influence hemopoiesis.     

Limited left-right cell migration across the midline of the gastrulating avian embryo

During avian development the earliest phase in which the avian embryo expresses axial features of a left-right axis is at the primitive streak stage. Until the stage of definitive primitive streak (streak 4 H&H), the axis seems to possess morphological bilateral symmetry. Morphological asymmetry begins only during the next few hours of incubation, with development of overt morphological and molecular asymmetry within Hensen's node (stage 5 H&H). In this report, we present an experimental study aimed at following the pattern of cell movements during primitive streak formation and gastrulation of specific left-right regions from earlier stages of the avian embryo. To determine the origin of cells contributing to each side of the primitive streak, we applied the dye Lysinated-Rodamine-Dextran (LRD) to one half, either left or right, of the pre-streak blastoderm (stages X–XIII, EG&K). We tried to estimate the relative cell contribution to primitive streak formation, and to the three germ layers evolving during gastrulation in the context of the left-right axis. Moreover, we asked whether the midline serves as a border, that is, as a physiological barrier preventing cell passing during gastrulation. Our results demonstrate that on each side of the axis, either the right or the left, most of the cells originate from the same half of a pre-streak blastoderm, populate the same half of the PS and contribute to tissues largely confined to that particular side. However, along the primitive streak, a few cells were detected on the opposite side of the midline. Moreover, variation in the number of cells crossing the midline at specific regions along the primitive streak was found. Most crossing cells were located near the mid rostrocaudal extent of the primitive streak, from 25–85% of its length. At the posterior end of the primitive streak, fewer crossing cells were detected. At the anterior region of the PS, that is, within Hensen's node, cells do not cross the midline. These results suggest that differences occur in the process of ingression along the rostrocaudal extent of the PS. Dev. Genet. 23:175–184, 1998. © 1998 Wiley-Liss, Inc.     

Cell movement during chick primitive streak formation

Gastrulation in amniotes begins with extensive re-arrangements of cells in the epiblast resulting in the formation of the primitive streak. We have developed a transfection method that enables us to transfect randomly distributed epiblast cells in the Stage XI-XIII chick blastoderms with GFP fusion proteins. This allows us to use time-lapse microscopy for detailed analysis of the movements and proliferation of epiblast cells during streak formation. Cells in the posterior two thirds of the embryo move in two striking counter-rotating flows that meet at the site of streak formation at the posterior end of the embryo. Cells divide during this rotational movement with a cell cycle time of 6-7 h. Daughter cells remain together, forming small clusters and as result of the flow patterns line up in the streak. Expression of the cyclin-dependent kinase inhibitor, P21/Waf inhibits cell division and severely limits embryo growth, but does not inhibit streak formation or associated flows. To investigate the role off cell-cell intercalation in streak formation we have inhibited the Wnt planar-polarity signalling pathway by expression of a dominant negative Wnt11 and a Dishevelled mutant Xdd1. Both treatments do not result in an inhibition of streak formation, but both severely affect extension of the embryo in later development. Likewise inhibition of myosin II which as been shown to drive cell-cell intercalation during Drosophila germ band extension, has no effect on streak formation, but also effectively blocks elongation after regression has started. These experiments make it unlikely that streak formation involves known cell-cell intercalation mechanisms. Expression of a dominant negative FGFR1c receptor construct as well as the soluble extracellular domain of the FGFR1c receptor both effectively block the cell movements associated with streak formation and mesoderm differentiation, showing the importance of FGF signalling in these processes.     

Effects of serotonin and serotonin antagonists on chick embryogenesis

Summary Serotonin and some selected substances known to interfere with its formation (diethyldithiocarbamate) and function (Catron^®, 5-methyltryptamine, promethazine) were tested for their ability to affect chick embryo morphogenesis during the first 48 h of development. To detect possible differences in sensitivity between the successive morphogenetic events taking place during this period, the treatment was begun at successively more advanced stages corresponding to embryo ages of between 4 and 30 h incubation. In all cases, the treatment was terminated at an embryo age of 48 h incubation. The treatment was performed both in ovo and in vitro.With some exceptions, the substances induced malformations of the same characteristic types. The developmental processes subjected to disturbances included blastoderm expansion, primitive streak formation, neurulation with brain formation, and somitogenesis. At the cellular level, the malformations can be traced to delayed yolk degradation, impaired formation and function of microvilli, and impaired ability of the embryo cells to change shape.All of the tested chemicals can be expected to interfere with intracellular levels of serotonin. They obviously interfered with decomposition of the yolk granules, recognized centres for intracellular serotonin formation and we therefore conclude that the observed morphogenetical disturbances are ultimately due to impairment of the endogenous serotonin formation. We suggest that, in morphogenesis, serotonin primarily promotes the activity of microtubules and microfilaments.     

PTEN抑制胚胎原肠胚形成期EMT的过程

PTEN(Phosphatase and tensin homolog)是一种重要的抑癌基因,具有非常广泛的生物学活性,例如在细胞的生长发育、迁移、凋亡和信号传导等均发挥重要作用。PTEN基因表达始于在胚胎早期的上胚层,而后主要出现在神经外胚层和胚胎中胚层结构,表明PTEN可能参与胚胎早期发育过程的细胞迁移、增殖和分化。文章主要应用在体改变早期胚胎PTEN的表达水平来观察其对上胚层至中胚层细胞转换—EMT(Epithe-lial-mesenchymal transition)的作用。首先,原位杂交结果提示,内源性PTEN表达在原条以及之后的中胚层细胞结构如体节等。在体PTEN转染实验,体外培养至HH3期的鸡胚胎,转染Wt PTEN-GFP或移植Wt PTEN-GFP原条组织至未转染的同时期的宿主胚胎相同部位后,观察到PTEN转染细胞大都由上胚层迁移至原条并滞留于原条,不再参与中胚层细胞形成。移植实验也得到相似结果,发现在Wt PTEN-GFP阳性原条组织移植后很少细胞迁移出原条。另外在原肠胚期PTEN siRNA降调胚胎一侧PTEN基因后,降调侧中胚层细胞数明显少于正常侧。上述研究结果均提示PTEN基因在胚胎原肠胚期三胚层形成过程中可能具有抑制EMT的作用。     

Hypoblast controls mesoderm generation and axial patterning in the gastrulating rabbit embryo

Gastrulation in higher vertebrate species classically commences with the generation of mesoderm cells in the primitive streak by epithelio-mesenchymal transformation of epiblast cells. However, the primitive streak also marks, with its longitudinal orientation in the posterior part of the conceptus, the anterior-posterior (or head-tail) axis of the embryo. Results obtained in chick and mouse suggest that signals secreted by the hypoblast (or visceral endoderm), the extraembryonic tissue covering the epiblast ventrally, antagonise the mesoderm induction cascade in the anterior part of the epiblast and thereby restrict streak development to the posterior pole (and possibly initiate head development anteriorly). In this paper we took advantage of the disc-shape morphology of the rabbit gastrula for defining the expression compartments of the signalling molecules Cerberus and Dickkopf at pre-gastrulation and early gastrulation stages in a mammal other than the mouse. The two molecules are expressed in novel expression compartments in a complementary fashion both in the hypoblast and in the emerging primitive streak. In loss-of-function experiments, carried out in a New-type culturing system, hypoblast was removed prior to culture at defined stages before and at the beginning of gastrulation. The epiblast shows a stage-dependent and topographically restricted susceptibility to express Brachyury, a T-box gene pivotal for mesoderm formation, and to transform into (histologically proven) mesoderm. These results confirm for the mammalian embryo that the anterior-posterior axis of the conceptus is formed first as a molecular prepattern in the hypoblast and then irrevocably fixed, under the control of signals secreted from the hypoblast, by epithelio-mesenchymal transformation (primitive streak formation) in the epiblast.Edited by D. Tautz