Cell populations and morphogenetic movements underlying formation of the avian primitive streak and organizer

The cell populations and morphogenetic movements that contribute to the formation of the avian primitive streak and organizer-Hensen's node-are poorly understood. We labeled selected groups of cells with fluorescent dyes and then followed them over time during formation and progression of the primitive streak and formation of Hensen's node. We show that (1) the primitive streak arises from a localized population of epiblast cells spanning the caudal midline of Koller's sickle, with the mid-dorsal cells of the primitive streak arising from the midline of the epiblast overlying Koller's sickle and the deeper and more lateral primitive streak cells arising more laterally within the epiblast overlying the sickle, from an arch subtending about 30 degrees; (2) convergent extension movements of cells in the epiblast overlying Koller's sickle contribute to formation of the initial primitive streak; and (3) Hensen's node is derived from a mixture of cells originating both from the epiblast just rostral to the incipient (stage 2) primitive streak and later from the epiblast just rostral to the elongating (stage 3a/b) primitive streak, as well as from the rostral tip of the progressing streak itself. Collectively, these results provide new information on the formation of the avian primitive streak and organizer, increasing our understanding of these important events of early development of amniotes.     

Clonal analysis of epiblast fate during germ layer formation in the mouse embryo.

The fate of cells in the epiblast at prestreak and early primitive streak stages has been studied by injecting horseradish peroxidase (HRP) into single cells in situ of 6.7-day mouse embryos and identifying the labelled descendants at midstreak to neural plate stages after one day of culture. Ectoderm was composed of descendants of epiblast progenitors that had been located in the embryonic axis anterior to the primitive streak. Embryonic mesoderm was derived from all areas of the epiblast except the distal tip and the adjacent region anterior to it: the most anterior mesoderm cells originated posteriorly, traversing the primitive streak early; labelled cells in the posterior part of the streak at the neural plate stage were derived from extreme anterior axial and paraxial epiblast progenitors; head process cells were derived from epiblast at or near the anterior end of the primitive streak. Endoderm descendants were most frequently derived from a region that included, but extended beyond, the region producing the head process: descendants of epiblast were present in endoderm by the midstreak stage, as well as at later stages. Yolk sac and amnion mesoderm developed from posterolateral and posterior epiblast. The resulting fate map is essentially the same as those of the chick and urodele and indicates that, despite geometrical differences, topological fate relationships are conserved among these vertebrates. Clonal descendants were not necessarily confined to a single germ layer or to extraembryonic mesoderm, indicating that these lineages are not separated at the beginning of gastrulation. The embryonic axis lengthened up to the neural plate stage by (1) elongation of the primitive streak through progressive incorporation of the expanding lateral and initially more anterior regions of epiblast and, (2) expansion of the region of epiblast immediately cranial to the anterior end of the primitive streak. The population doubling time of labelled cells was 7.5 h; a calculated 43% were in, or had completed, a 4th cell cycle, and no statistically significant regional differences in the number of descendants were found. This clonal analysis also showed that (1) growth in the epiblast was noncoherent and in most regions anisotropic and directed towards the primitive streak and (2) the midline did not act as a barrier to clonal spread, either in the epiblast in the anterior half of the axis or in the primitive streak. These results taken together with the fate map indicate that, while individual cells in the epiblast sheet behave independently with respect to their neighbours, morphogenetic movement during germ layer formation is coordinated in the population as a whole.     

Primitive streak formation in mice is preceded by localized activation of Brachyury and Wnt3

The prevalent model for the generation of axial polarity in mouse embryos proposes that a radial to a linear transition in the expression of primitive streak markers precedes the formation of the primitive streak on one side of the epiblast. This model contrasts with the models of mesoderm formation in other vertebrates as it suggests that the primitive streak is initially established in a radial pattern rather than a localized region of the epiblast. Here, we examine the proposed correlation between the expression of Brachyury and Wnt3, two genes reported as expressed radially in the proximal epiblast, with the movements of proximal anterior epiblast cells at stages leading to the formation of the primitive streak. Our results reveal that neither Brachyury nor Wnt3 forms a ring of expression in the proximal epiblast as previously thought. In embryos dissected between 5.5 and 6.5 dpc, Brachyury is first expressed in the distal extra-embryonic ectoderm and subsequently on one side of the epiblast. Wnt3 expression is evident first in the posterior visceral endoderm of 5.5 dpc embryos and later in the posterior epiblast. Lineage analysis shows that the movements of the proximal epiblast do not restrict Brachyury expression to the posterior epiblast. Our data suggest a model whereby the localized expression of these genes in the posterior epiblast, and hence the formation of the primitive streak, is the result of local cell-cell interactions in the future posterior portion of the egg cylinder rather than regionalization of a radial pattern of expression in proximal epiblast cells.     

Formation of the avian primitive streak from spatially restricted blastoderm: evidence for polarized cell division in the elongating streak

Gastrulation in the amniote begins with the formation of a primitive streak through which precursors of definitive mesoderm and endoderm ingress and migrate to their embryonic destinations. This organizing center for amniote gastrulation is induced by signal(s) from the posterior margin of the blastodisc. The mode of action of these inductive signal(s) remains unresolved, since various origins and developmental pathways of the primitive streak have been proposed. In the present study, the fate of chicken blastodermal cells was traced for the first time in ovo from prestreak stages XI-XII through HH stage 3, when the primitive streak is initially established and prior to the migration of mesoderm. Using replication-defective retrovirus-mediated gene transfer and vital dye labeling, precursor cells of the stage 3 primitive streak were mapped predominantly to a specific region where the embryonic midline crosses the posterior margin of the epiblast. No significant contribution to the early primitive streak was seen from the anterolateral epiblast. Instead, the precursor cells generated daughter cells that underwent a polarized cell division oriented perpendicular to the anteroposterior embryonic axis. The resulting daughter cell population was arranged in a longitudinal array extending the complete length of the primitive streak. Furthermore, expression of cVg1, a posterior margin-derived signal, at the anterior marginal zone induced adjacent epiblast cells, but not those lateral to or distant from the signal, to form an ectopic primitive streak. The cVg1-induced epiblast cells also exhibited polarized cell divisions during ectopic primitive streak formation. These results suggest that blastoderm cells located immediately anterior to the posterior marginal zone, which secretes an inductive signal, undergo spatially directed cytokineses during early primitive streak formation.     

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.     

Nodal signal is required for morphogenetic movements of epiblast layer in the pre-streak chick blastoderm

During axis formation in amniotes, posterior and lateral epiblast cells in the area pellucida undergo a counter-rotating movement along the midline to form primitive streak (Polonaise movements). Using chick blastoderms, we investigated the signaling involved in this cellular movement in epithelial-epiblast. In cultured posterior blastoderm explants from stage X to XI embryos, either Lefty1 or Cerberus-S inhibited initial migration of the explants on chamber slides. In vivo analysis showed that inhibition of Nodal signaling by Lefty1 affected the movement of DiI-marked epiblast cells prior to the formation of primitive streak. In Lefty1-treated embryos without a primitive streak, Brachyury expression showed a patchy distribution. However, SU5402 did not affect the movement of DiI-marked epiblast cells. Multi-cellular rosette, which is thought to be involved in epithelial morphogenesis, was found predominantly in the posterior half of the epiblast, and Lefty1 inhibited the formation of rosettes. Three-dimensional reconstruction showed two types of rosette, one with a protruding cell, the other with a ventral hollow. Our results suggest that Nodal signaling may have a pivotal role in the morphogenetic movements of epithelial epiblast including Polonaise movements and formation of multi-cellular rosette.     

Analysis of extraembryonic mesodermal structure formation in the absence of morphological primitive streak

During mouse gastrulation, the primitive streak is formed on the posterior side of the embryo. Cells migrate out of the primitive streak to form the future mesoderm and endoderm. Fate mapping studies revealed a group of cell migrate through the proximal end of the primitive streak and give rise to the extraembryonic mesoderm tissues such as the yolk sac blood islands and allantois. However, it is not clear whether the formation of a morphological primitive streak is required for the development of these extraembryonic mesodermal tissues. Loss of the Cripto gene in mice dramatically reduces, but does not completely abolish, Nodal activity leading to the absence of a morphological primitive streak. However, embryonic erythrocytes are still formed and assembled into the blood islands. In addition, Cripto mutant embryos form allantoic buds. However, Drap1 mutant embryos have excessive Nodal activity in the epiblast cells before gastrulation and form an expanded primitive streak, but no yolk sac blood islands or allantoic bud formation. Lefty2 embryos also have elevated levels of Nodal activity in the primitive streak during gastrulation, and undergo normal blood island and allantois formation. We therefore speculate that low level of Nodal activity disrupts the formation of morphological primitive streak on the posterior side, but still allows the formation of primitive streak cells on the proximal side, which give rise to the extraembryonic mesodermal tissues formation. Excessive Nodal activity in the epiblast at pre‐gastrulation stage, but not in the primitive streak cells during gastrulation, disrupts extraembryonic mesoderm development.     

Formation of the chick primitive streak as studied in computer simulations

We have used a computer simulation system to examine formation of the chick primitive streak and to test the proposal (Wei and Mikawa Development 127 (2000) 87) that oriented cell division could account for primitive streak elongation. We find that this proposal is inadequate to explain elongation of the streak. In contrast, a correctly patterned model streak can be generated if two putative mechanisms are operative. First, a subpopulation of precursor cells that is known to contribute to the streak is assigned a specific, but simple, movement pattern. Second, additional cells within the epiblast are allowed to incorporate into the streak based on near-neighbor relations. In this model, the streak is cast as a steady-state system with continuous recruitment of neighboring epiblast cells, egress of cells into deeper layers and an internal pattern of cell movement. The model accurately portrays elongation and maintenance of a robust streak, changes in the composition of the streak and defects in the streak after experimental manipulation.     

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.     

Otx2 is required for visceral endoderm movement and for the restriction of posterior signals in the epiblast of the mouse embryo

Genetic and embryological experiments have demonstrated an essential role for the visceral endoderm in the formation of the forebrain; however, the precise molecular and cellular mechanisms of this requirement are poorly understood. We have performed lineage tracing in combination with molecular marker studies to follow morphogenetic movements and cell fates before and during gastrulation in embryos mutant for the homeobox gene Otx2. Our results show, first, that Otx2 is not required for proliferation of the visceral endoderm, but is essential for anteriorly directed morphogenetic movement. Second, molecules that are normally expressed in the anterior visceral endoderm, such as Lefty1 and Mdkk1, are not expressed in Otx2 mutants. These secreted proteins have been reported to antagonise, respectively, the activities of Nodal and Wnt signals, which have a role in regulating primitive streak formation. The visceral endoderm defects of the Otx2 mutants are associated with abnormal expression of primitive streak markers in the epiblast, suggesting that anterior epiblast cells acquire primitive streak characteristics. Taken together, our data support a model whereby Otx2 functions in the anterior visceral endoderm to influence the ability of the adjacent epiblast cells to differentiate into anterior neurectoderm, indirectly, by preventing them from coming under the influence of posterior signals that regulate primitive streak formation.     

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 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     

Epithelial and basement membrane responses to chick embryo primitive streak grafts

Chick embryo primitive streak grafts, placed beneath the epiblast of host embryos, tend to result in the formation of either a neural plate in response to anterior streak grafts, or in de-epithelialization in response to posterior grafts. Ultrastructural and immunocytochemical examination shows that both reactions are preceded by basement membrane disruption and early removal of fibronectin therefrom. This disruption does not occur in response to non-streak grafts. It is suggested that the disruption, evoked by primitive streak cells, is a prerequisite first step, allowing direct graft-epiblast cell contact. This contact elicits a specific cytoskeletal reaction determining the epiblast response.     

Invasion and migration of a single chick pre-streak stage epiblast cell in vitro: Its implication to the primitive streak formation

To investigate the contribution of the epiblast cell behavior to the primitive streak formation, we examined the motility of a single epiblast cell from pre-streak stage embryo in vitro . On the substratum that was evenly coated with laminin gel, epiblast cells attached well to the gel and one or a few very long and broad cellular processes protruded from their spherical cell bodies; however, they hardly locomoted on it. Unexpectedly, after overnight culture, half of the single cells dissolved the laminin gel beneath them to make well-like holes, and invaded in the holes. On the substratum lined parallel with the fibrous laminin gels supplemented with fibronectin, they locomoted actively in accordance with the alignment. That is, they were subjected to contact guidance. In locomotion they looked like snails, extending one or a few long and broad processes in a forward direction from the spherical cell bodies. However, on the substratum lined with laminin or fibronectin only, they did not locomote actively. Individual chick pre-streak epiblast cells had already been committed to invade, and their migratory nature existed in each cell, even though they were isolated from the epithelial sheet. The implication of these findings on the cellular basis of primitive streak formation will be discussed.     

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.     

5-Bromodeoxyuridine inhibition of the epiblast competence for primitive streak formation in the young chick blastoderm

The competence of stage XIII chick epiblast which under the influence of an inductive hypoblast is directed to form a normal primitive streak, is affected by 5-bromodeoxyuridine (BUdR). The BUdR-treated epiblast forms an atypical primitive streak and no axial mesoderm. However, a nonorganized mesenchymal layer is formed between the epiblast and the hypoblast, and atypical neural tissue in the epiblast. BUdR interferes neither with hypoblast formation nor with its inductivity even when blastoderms are treated with BUdR as early as uterine stage VIII and later.     

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

Background  

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

Control of early anterior-posterior patterning in the mouse embryo by TGF-beta signalling

Prior to gastrulation the mouse embryo exists as a symmetrical cylinder consisting of three tissue layers. Positioning of the future anterior-posterior axis of the embryo occurs through coordinated cell movements that rotate a pre-existing proximal-distal (P-D) axis. Overt axis formation becomes evident when a discrete population of proximal epiblast cells become induced to form mesoderm, initiating primitive streak formation and marking the posterior side of the embryo. Over the next 12-24 h the primitive streak gradually elongates along the posterior side of the epiblast to reach the distal tip. The most anterior streak cells comprise the 'organizer' region and include the precursors of the so-called 'axial mesendoderm', namely the anterior definitive endoderm and prechordal plate mesoderm, as well as those cells that give rise to the morphologically patent node. Signalling pathways controlled by the transforming growth factor-beta ligand nodal are involved in orchestrating the process of axis formation. Embryos lacking nodal activity arrest development before gastrulation, reflecting an essential role for nodal in establishing P-D polarity by generating and maintaining the molecular pattern within the epiblast, extraembryonic ectoderm and the visceral endoderm. Using a genetic strategy to manipulate temporal and spatial domains of nodal expression reveals that the nodal pathway is also instrumental in controlling both the morphogenetic movements required for orientation of the final axis and for specification of the axial mesendoderm progenitors.     

Gastrulation in the mouse: the role of the homeobox gene goosecoid.

Mouse goosecoid is a homeobox gene expressed briefly during early gastrulation. Its mRNA accumulates as a patch on the side of the epiblast at the site where the primitive streak is first formed. goosecoid-expressing cells are then found at the anterior end of the developing primitive streak, and finally in the anteriormost mesoderm at the tip of the early mouse gastrula, a region that gives rise to the head process. Treatment of early mouse embryos with activin results in goosecoid mRNA accumulation in the entire epiblast, suggesting that a localized signal induces goosecoid expression during development. Transplantation experiments indicate that the tip of the murine early gastrula is the equivalent of the organizer of the amphibian gastrula.     

Protein synthesis in epiblast versus hypoblast during the critical stages of induction and growth of the primitive streak in the chick embryo.

In the chick the inducing power of the hypoblast for primitive streak was assumed to reach its maximum at the beginning of the primitive streak stage and to last until its completion. It was therefore of interest to trace the protein synthetic activity of the epiblast and hypoblast during five successive developmental stages and to correlate them with the known morphogenetic events.The investigation was done along two lines: 1) A quantitative survey was made of the uptake of tritiated phenylalanine into epiblasts versus hypoblasts and their incorporation into trichloroacetic acid-precipitable protein. 2) Incorporation of label into protein was followed by a comparative investigation of the electropherograms of epiblast versus hypoblast at the different stages.The quantitative survey has shown an almost uniform and rather low incorporation of label into protein in the hypoblast layer with a very short period of doubled activity between full hypoblast and initial primitive streak (p.s.). During this period the inductive capacity of the hypoblast for primitive streak was supposed to reach its maximal value.The qualitative survey indicated different patterns of incorporation in the two layers studied. Of special interest are two peaks (III and IV) which appear in the hypoblast previous to p.s. formation at the time of its augmented synthetic activity which also coincides with the onset of its inductive capacity. At later stages two similar peaks appear in the epiblast. It is suggested that a protein included in the above peaks might represent the inductor of the primitive streak.