Cellular basis of gastrulation in the sand dollar Scaphechinus mirabilis

The processes of gastrulation in the sand dollar Scaphechinus mirabilis are quite different from those in regular echinoids. In this study, we explored the cellular basis of gastrulation in this species with several methods. Cell-tracing experiments revealed that the prospective endodermal cells were convoluted throughout the invagination processes. Histological observation showed that the ectodermal layer remained thickened, and the vegetal cells retained an elongated shape until the last step of invagination. Further, most of the vegetal ectodermal cells were skewed or distorted. Wedge-shaped cells were common in the vegetal ectoderm, especially at the subequatorial region. In these embryos, unlike the embryos of regular echinoids, secondary mesenchyme cells did not seem to exert the force to pull up the archenteron toward the inner surface of the apical plate. In fact, the archenteron cells were not stretched along the axis of elongation and were in close contact with each other. Here we found that gastrulation was completely blocked when the embryos were attached to a glass dish coated with poly-L-lysine, in which the movement of the ectodermal layer was inhibited. These results suggest that a force generated by the thickened ectoderm, rather than rearrangement of the archenteron cells, may play a key role in the archenteron elongation in S. mirabilis embryos.     

T-brain homologue (HpTb) is involved in the archenteron induction signals of micromere descendant cells in the sea urchin embryo

Signals from micromere descendants play a crucial role in sea urchin development. In this study, we demonstrate that these micromere descendants express HpTb, a T-brain homolog of Hemicentrotus pulcherrimus. HpTb is expressed transiently from the hatched blastula stage through the mesenchyme blastula stage to the gastrula stage. By a combination of embryo microsurgery and antisense morpholino experiments, we show that HpTb is involved in the production of archenteron induction signals. However, HpTb is not involved in the production of signals responsible for the specification of secondary mesenchyme cells, the initial specification of primary mesenchyme cells, or the specification of endoderm. HpTb expression is controlled by nuclear localization of beta-catenin, suggesting that HpTb is in a downstream component of the Wnt signaling cascade. We also propose the possibility that HpTb is involved in the cascade responsible for the production of signals required for the spicule formation as well as signals from the vegetal hemisphere required for the differentiation of aboral ectoderm.     

Jun N‐terminal kinase activity is required for invagination but not differentiation of the sea urchin archenteron

Although sea urchin gastrulation is well described at the cellular level, our understanding of the molecular changes that trigger the coordinated cell movements involved is not complete. Jun N‐terminal kinase (JNK) is a component of the planar cell polarity pathway and is required for cell movements during embryonic development in several animal species. To study the role of JNK in sea urchin gastrulation, embryos were treated with JNK inhibitor SP600125 just prior to gastrulation. The inhibitor had a limited and specific effect, blocking invagination of the archenteron. Embryos treated with 2 μM SP600125 formed normal vegetal plates, but did not undergo invagination to form an archenteron. Other types of cell movements, specifically ingression of the skeletogenic mesenchyme, were not affected, although the development and pattern of the skeleton was abnormal in treated embryos. Pigment cells, derived from nonskeletogenic mesenchyme, were also present in SP600125‐treated embryos. Despite the lack of a visible archenteron in treated embryos, cells at the original vegetal plate expressed several molecular markers for endoderm differentiation. These results demonstrate that JNK activity is required for invagination of the archenteron but not its differentiation, indicating that in this case, morphogenesis and differentiation are under separate regulation. genesis 53:762–769, 2015. © 2015 Wiley Periodicals, Inc.     

Local cell interactions and the control of gastrulation in the sea urchin embryo

The sea urchin embryo is a good model system for studying the role of mechanical and cell-cell interactions during epithelial invagination, cell rearrangement and mesenchymal patterning in the gastrula. The mechanisms underlying the initial invagination of the archenteron have been surprisingly elusive; several possible mechanisms are discussed. In contrast to its initial invagination, the cellular basis for the elongation of the archenteron is better understood: both autonomous epithelial cell rearrangement and further rearrangement driven by secondary mesenchyme cells appear to be involved. Experiments indicate that patterning of freely migrating primary mesenchyme cells and secondary mesenchyme cells residing in the tip of the archenteron relies to a large extent on information resident in the ectoderm. Interactions between cells in the early embryo and later cell-cell interactions are both required for the establishment of ectodermal pattern information. Surprisingly, in the case of the oral ectoderm the fixation of pattern information does not occur until immediately prior to gastrulation.     

Oral/aboral ectoderm differentiation of the sea urchin embryo depends on a planar or secretory signal from the vegetal hemisphere

A monoclonal antibody that recognizes oral ectoderm and esophagus of sea urchin larvae was newly produced. Distribution of the antigen, named Hpoe, was examined by indirect immunofluorescence microscopy. Hpoe did not exist in eggs and appeared during the cleavage stage. In hatched blastulae, Hpoe was detected on the apical surface of all cells. As embryogenesis progressed, Hpoe disappeared from the primary mesenchyme, archenteron and aboral ectoderm. Hpoe reappeared in foregut at the prism stage and was restricted to the oral ectoderm and esophagus at the pluteus stage. Using this antigen as a molecular marker of oral/aboral ectoderm differentiation, the role of the vegetal hemisphere in ectoderm differentiation was examined. All animal hemispheres isolated from 16-cell stage embryos, mesenchyme blastulae, early gastrulae and mid gastrulae developed into epithelial balls and every cell expressed Hpoe. These epithelial balls failed in oral/aboral ectoderm differentiation. Twenty millimolar LiCI-treated whole embryos developed into exo-gastrulae but Hpoe restriction in ectoderm occurred in these exo-gastrulae. These results show that oral/aboral ectoderm differentiation requires an inductive interaction from the vegetal hemisphere and indicate that the inductive interaction depends on a planar or secretory signal, rather than the contact of the esophagus and ectoderm.     

Skeletogenic potential of induced secondary mesenchyme cells derived from the presumptive ectoderm in echinoid embryos

 During the normal development of echinoids, an animal cap consisting of 8 mesomeres in a 16-cell stage embryo differentiates exclusively into ectoderm. Micromeres in an embryo at the same stage differentiate into primary mesenchyme cells (PMC) and coelomic pouch constituents. An animal cap and a quartet of micromeres were isolated from a 16-cell stage embryo and recombined to make a chimeric embryo devoid of presumptive endoderm and secondary mesenchyme cells (SMC). The PMC in the chimeric embryo were completely removed at the mesenchyme blastula stage. The PMC-depleted chimeric embryos formed an archenteron derived from the mesomeres. Some secondary mesenchyme-like cells (induced SMC) were released from the archenteron tip. A considerable fraction of the induced SMC formed the typical mesenchyme pattern after migrating into the vegetal region, synthesized skeletogenic mesenchyme cell-surface protein (msp130) and produced the larval skeleton. These findings indicate that induced SMC derived from the presumptive ectoderm have the same nature as natural SMC in both the timing of their release and their skeletogenic potential expressed in the absence of PMC. Received: 14 November 1996 / Accepted: 30 December 1996     

Determination and morphogenesis in the sea urchin embryo

The study of the sea urchin embryo has contributed importantly to our ideas about embryogenesis. This essay re-examines some issues where the concerns of classical experimental embryology and cell and molecular biology converge. The sea urchin egg has an inherent animal-vegetal polarity. An egg fragment that contains both animal and vegetal material will produce a fairly normal larva. However, it is not clear to what extent the oral-aboral axis is specified in embryos developing from meridional fragments. Newly available markers of the oral-aboral axis allow this issue to be settled. When equatorial halves, in which animal and vegetal hemispheres are separated, are allowed to develop, the animal half forms a ciliated hollow ball. The vegetal half, however, often forms a complete embryo. This result is not in accord with the double gradient model of animal and vegetal characteristics that has been used to interpret almost all defect, isolation and transplantation experiments using sea urchin embryos. The effects of agents used to animalize and vegetalize embryos are also due for re-examination. The classical animalizing agent, Zn2+, causes developmental arrest, not expression of animal characters. On the other hand, Li+, a vegetalizing agent, probably changes the determination of animal cells. The stability of these early determinative steps may be examined in dissociation-reaggregation experiments, but this technique has not been exploited extensively. The morphogenetic movements of primary mesenchyme are complex and involve a number of interactions. It is curious that primary mesenchyme is dispensable in skeleton formation since in embryos devoid of primary mesenchyme, the secondary mesenchyme cells will form skeletal elements. It is likely that during its differentiation the primary mesenchyme provides some of its own extracellular microenvironment in the form of collagen and proteoglycans. The detailed form of spicules made by primary mesenchyme is determined by cooperation between the epithelial body wall, the extracellular material and the inherent properties of primary mesenchyme cells. Gastrulation in sea urchins is a two-step process. The first invagination is a buckling, the mechanism of which is not understood. The secondary phase in which the archenteron elongates across the blastocoel is probably driven primarily by active cell repacking. The extracellular matrix is important for this repacking to occur, but the basis of the cellular-environmental interaction is not understood.(ABSTRACT TRUNCATED AT 400 WORDS)     

Ectoderm exerts the driving force for gastrulation in the sand dollar Scaphechinus mirabilis

How the ectodermal layer relates to the invagination processes was examined in the sand dollar Scaphechinus mirabilis. When the turgor pressure of blastocoele was increased, invagination was completely blocked. In contrast, an increase in turgor pressure did not affect elongation of the gut rudiment in the regular echinoid Hemicentrotus pulcherrimus. Rhodamine-phalloidin staining showed that the distribution of actin filaments was different between two species of embryos. In S. mirabilis gastrulating embryos, abundant actin filaments were seen at the basal cortex of ectoderm in addition to archenteron cells, while the intense signal was restricted to the archenteron in H. pulcherrimus. To investigate whether actin filaments contained in the ectodermal layer exert the force of invagination, a small part of the ectodermal layer was aspirated with a micropipette. If S. mirabilis embryos were aspirated from the onset of gastrulation, invagination did not occur at all, irrespective of the suction site. Even after the archenteron had invaginated to one-half of its full length, further elongation of the archenteron was severely blocked by suction of the lateral ectoderm. In contrast, suction of the ectodermal layer did not affect the elongation processes in H. pulcherrimus. These results strongly suggest that the ectodermal layer, especially in the vegetal half, exerts the driving force of invagination in S. mirabilis.     

Histological distribution of FR-1, a cyclic RGDS-peptide, binding sites during early embryogenesis, and isolation and initial characterization of FR-1 receptor in the sand dollar embryo

A fibronectin-related synthetic cyclic H-Cys-Arg-Gly-Asp-Ser-Pro-Ala-Ser-Ser-Cys-OH (RGDSPASS) peptide (FR-1) binding site in the embryo of the sand dollar Clypeaster japonicus was specified using dansyl-labeled FR-1 (Dns-FR-1) and horseradish peroxidase-labeled FR-1, and an FR-1 receptor was isolated using FR-1-affinity column chromatography. The FR-1 introduced to the blastocoel of blastulae inhibited primary mesenchyme cell (PMC) migration in mesenchyme blastulae, and complete gastrulation and spicule differentiation in gastrulae. The Dns-FR-1 bound to the entire basal side of the ectoderm in mesenchyme blastulae, and then restricted to the basal side of the ectoderm at the apical tuft region and the vegetal hemisphere in early gastrulae. The cytoplasm of the archenteron also bound to Dns-FR-1. In PMC, Dns-FR-1 bound to the nucleus and cytoplasmic reticular features. In unfertilized eggs, Dns-FR-1 bound to the entire cytoplasm, particularly to the oval-shaped granules and the nuclear envelope, but only to the cytoplasm after fertilization. Relative molecular mass ( Mr ) of the FR-1 -binding protein was 240 kDa under non-reducing conditions and 57 kDa under reducing conditions. The FR-1 receptor protein bound anti-sea urchin integrin (Spl) βL subunit antibodies raised against the embryos of Strongylocentrotus purpuratus . Immunohistochemistry showed that the antibody binding site was similar to the histochemical distribution of Dns-FR-1. However, Mr of the FR-1 receptor is distinctively larger than that of the Spl βL subunit.     

Ingression of primary mesenchyme cells of the sea urchin embryo: a precisely timed epithelial mesenchymal transition

Epithelial-mesenchyme transitions (EMTs) are familiar to all scholars of development. Each animal system utilizes an EMT to produce mesenchyme cells. In vertebrates, for example, there are a number of EMTs that shape the embryo. Early, entry of epiblast cells into the primitive streak is followed by the emergence of mesoderm via an EMT process. The departure of neural crest cells from the margin of the neural folds is an EMT process, and the delamination of cells from the endomesoderm to form the supporting mesenchyme of the lung, liver, and pancreas are EMTs. EMTs are observed in Drosophila following invagination of the ventral furrow, and even in Cnidarians, which have only two germ layers, yet mesoglial and stem cells delaminate from the epithelia and occupy the matrix between the ectoderm and endoderm. This review will focus on a classic example of an EMT, which occurs in the sea urchin embryo. The primary mesenchyme cells (PMCs) ingress from the vegetal plate of this embryo precociously and in advance of archenteron invagination. Because ingression is precisely timed, the PMC lineage precisely known, and the embryo easily observed and manipulated, much has been learned about how the ingression of PMCs works in the sea urchin. Though the focus of this review is the sea urchin PMCs, there is evidence that all EMTs share many common features at both cellular and molecular levels, and many of these mechanisms are also shown to be involved in tumor progression, especially metastasizing carcinomas.     

Elongated Microvilli on Vegetal Pole Cells in Sea Urchin Embryos

The ultrastructure of cells in the vegetal pole region of sea urchin embryos during early development to the mesenchyme blastula stage was examined by scanning electron microscopy. Vegetal pole cells in the ectoderm with longer microvilli than those of neighboring cells were first detectable at the early blastula stage just before hatching. These cells with elongated microvilli remained in the central region of the vegetal plate when most vegetal plate cells ingressed into the blastocoel to form primary mesenchyme. When first detectable in the sea urchin, Anthocidaris crassispina , four vegetal pole cells had elongated microvilli, but at the time of primary mesenchyme cell ingression, the number of cells with elongated microvilli had increased to eight, apparently by cell division. These vegetal pole cells were wedge-shaped with a broad surface adhering to the hyaline layer at the time of primary mesenchyme cell ingression. SEM observation of the outer surface of embryos showed that the microvilli extended into the hyaline layer. The reinforced attachment of vegetal pole cells to the hyaline layer through their elongated microvilli may explain why these cells could remain at the vegetal pole when the surrounding cells ingressed into the blastocoel as primary mesenchyme cells.     

Behavior of pigment cells in gastrula-stage embryos of Hemicentrotus pulcherrimus and Scaphechinus mirabilis

The behavior of pigment cells in sea urchin embryos, especially at the gastrula stage, is not well understood, due to the lack of an appropriate method to detect pigment cells. We found that pigment cells emanated autofluorescence when they were fixed with formalin and irradiated with ultraviolet or green light. In Hemicentrotus pulcherrimus, fluorescent pigment cells became visible at the archenteron tip at the mid-gastrula stage. The cells detached from the archenteron slightly before the initiation of secondary invagination and migrated toward the apical plate. Most pigment cells entered the apical plate. This entry site seemed to be restricted, because pigment cells could not enter the ectoderm and remained in the blastocoele at the vegetal pole side when elongation of archenteron was blocked. Pigment cells that had entered the apical plate soon began to migrate in the aboral ectoderm toward the vegetal pole. In contrast, pigment cells of Scaphechinus mirabilis embryos were first detected in the vegetal plate before the onset of gastrulation. Without entering the blastocoele, these cells began to migrate preferentially in the aboral ectoderm toward the animal pole. When the archenteron tip reached the apical plate, pigment cells had already distributed throughout the aboral ectoderm. Thus, the behavior of pigment cells was quite different between H. pulcherrimus and S. mirabilis.     

Changes in the Pattern of Intercellular Junctions during Early Embryogenesis of the Starfish, Asterias amurensis

Changes in the cellular adhesion pattern during the early embryogenesis of a starfish Asterias amurensis were examined using carboxyfluorescein (CF) dye as a probe. CF that was injected into one of the blastomeres at the 2- or 4-cell stage was in all cases restricted to the progeny cells of the CF-labelled blastomere. With the advancement of gastrulation, however, the injected dye was distributed not only to the progeny of the labelled blastomere, but also to cells that originated from non-injected blastomeres. At the beginning of mesenchyme cell release, the injected dye spread uniformly to most cells comprising the embryo. When one of the blastomeres situated in the vegetal hemisphere of an 8-cell embryo was labelled, the resulting embryo showed more intense fluorescence in the cells surrounding the archenteron than in the ectodermal layer, suggesting that the cells in ectodermal layer became associated more intimately or earlier than those surrounding the archenteron. Likewise, in double embryos formed by combining two denuded eggs, in which one egg had been labelled with CF, dye spread was observed when the ectodermal layer began to expand. The intercellular spread of CF dye in starfish embryo suggests that there is a dramatic change in the cellular adhesion pattern during the course of gastrulation.     

Oral-aboral patterning and gastrulation of sea urchin embryos depend on sulfated glycosaminoglycans

Glycosaminoglycans (GAGs) are a heavily sulfated component of the extracellular matrix (ECM) implicated in a variety of cell signaling events involved in patterning of embryos. Embryos of the sea urchin Strongylocentrotus purpuratus were exposed to several inhibitors that disrupt GAG function during development. Treatment with chlorate, a general inhibitor of sulfation that leads to undersulfated GAGs, reduced sulfation of the urchin blastocoelar ECM. It also prevented correct specification of the oral-aboral axis and mouth formation, resulting in a radialized phenotype characterized by the lack of an oral field, incomplete gastrulation and formation of multiple skeletal spicule rudiments. Oral markers were initially expressed in most of the prospective ectoderm of chlorate-treated early blastulae, but then declined as aboral markers became expressed throughout most of the ectoderm. Nodal expression in the presumptive oral field is necessary and sufficient to specify the oral-aboral axis in urchins. Several lines of evidence suggest a deregulation of Nodal signaling is involved in the radialization caused by chlorate: (1) Radial embryos resemble those in which Nodal expression was knocked down. (2) Chlorate disrupted localized nodal expression in oral ectoderm, even when applied after the oral-aboral axis is specified and expression of other oral markers is resistant to treatment. (3) Inhibition with SB-431542 of ALK-4/5/7 receptors that mediate Nodal signaling causes defects in ectodermal patterning similar to those caused by chlorate. (4) Intriguingly, treatment of embryos with a sub-threshold dose of SB-431542 rescued the radialization caused by low concentrations of chlorate. Our results indicate important roles for sulfated GAGs in Nodal signaling and oral-aboral axial patterning, and in the cellular processes necessary for archenteron extension and mouth formation during gastrulation. We propose that interaction of the Nodal ligand with sulfated GAGs limits its diffusion, and is required to specify an oral field in the urchin embryo and organize the oral-aboral axis.     

Regionalisation of the mouse embryonic ectoderm: allocation of prospective ectodermal tissues during gastrulation

The regionalisation of cell fate in the embryonic ectoderm was studied by analyzing the distribution of graft-derived cells in the chimaeric embryo following grafting of wheat germ agglutinin--gold-labelled cells and culturing primitive-streak-stage mouse embryos. Embryonic ectoderm in the anterior region of the egg cylinder contributes to the neuroectoderm of the prosencephalon and mesencephalon. Cells in the distal lateral region give rise to the neuroectoderm of the rhombencephalon and the spinal cord. Embryonic ectoderm at the archenteron and adjacent to the middle region of the primitive streak contributes to the neuroepithelium of the spinal cord. The proximal-lateral ectoderm and the ectodermal cells adjacent to the posterior region of the primitive streak produce the surface ectoderm, the epidermal placodes and the cranial neural crest cells. Some labelled cells grafted to the anterior midline are found in the oral ectodermal lining, whereas cells from the archenteron are found in the notochord. With respect to mesodermal tissues, ectoderm at the archenteron and the distal-lateral region of the egg cylinder gives rise to rhombencephalic somitomeres, and the embryonic ectoderm adjacent to the primitive streak contributes to the somitic mesoderm and the lateral mesoderm. Based upon results of this and other grafting studies, a map of prospective ectodermal tissues in the embryonic ectoderm of the full-streak-stage mouse embryo is constructed.     

Regulative specification of ectoderm in skeleton disrupted sea urchin embryos treated with monoclonal antibody to Pl-nectin

Pl-nectin is a glycoprotein first discovered in the extracellular matrix (ECM) of Paracentrotus lividus sea urchin embryo, apically located on ectoderm and endoderm cells. The molecule has been described as functioning as an adhesive substrate for embryonic cells and its contact to ectoderm cells is essential for correct skeletogenesis. The present study was undertaken to elucidate the biochemical characteristics of Pl-nectin and to extend knowledge on its in vivo biological function. Here it is shown that the binding of mesenchyme blastula cells to Pl-nectin-coated substrates was calcium dependent, and reached its optimum at 10 mM Ca2+. Perturbation studies using monoclonal antibody (McAb) to Pl-nectin, which prevent ectoderm cell-Pl-nectin contact, show that dorsoventral axis formation and ectoderm differentiation were retarded. At later stages, embryos recovered and, even if growth and patterning of the skeleton was greatly affected, the establishment of dorsoventral asymmetry was reached. Similarly, the expression of specific ectoderm and endoderm territorial markers was achieved, although occurring with some delay. Endoderm differentiation and patterning was not obviously affected. These results suggest that both endoderm and ectoderm cells have regulative capacities and differentiation of territories is restored after a lag period. On the contrary, failure of inductive differentiation of the skeleton cannot be rescued, even though the ectoderm has recovered.     

Probable Contribution of Protein Phosphorylation by Protein Kinase C to Spicule Formation in Sea Urchin Embryos

The formation of spicules and development of pluteus arms in sea urchin embryos were strongly blocked by H-7 (1-(5-isoquinolinesulfonyl)-2-methylpiperazine dihydrochloride) but were not affected by HA1004 ( N -(2-guanidinoethyl)-5-isoquinolinesulfonamide hydrochloride). Archenteron formation occurred normally in the presence of these compounds. Late gastrulae (28 hr after fertilization) were exposed to ³²Pi for 30 min at 20°C, and then dissociated and their primary mesenchyme cells with spicules, embryo-wall cells and archenteron cells were separated. Then, the radioactivities in the protein fractions of these separated cells were measured. Results showed that culture of embryos with H-7 strongly inhibited ³²p incorporation into proteins in primary mesenchyme cells but caused little inhibition of its incorporations in embryo-wall cells and archenteron cells. The effective concentrations of H-7 for inhibition of ³²p incorporation were within the range that blocked spicule formation and growth of pluteus arms in embryos. HA1004 only slightly inhibited ³²p incorporation into protein in mesenchyme cells, embryo-wall cells and archenteron cells of embryos exposed to ³²Pi. Protein kinase C activity was detectable only in isolated primary mesenchyme cells associated with spicule structures. These suggest that phosphorylation of proteins by protein kinase C contributes to the formation of spicule structures.