A New Technique for Introducing Anti-Fibronectin Antibodies and Fibronectin-Related Synthetic Peptides into the Blastulae of the Sea Urchin, Clypeaster japonicus.

Migration of primary mesenchyme cells (PMCs) of the sea urchin, Clypeaster japonicus , was examined in vivo by introducing anti-fibronectin (FN) IgG, and FN-related synthetic peptides, Gly-Arg-Gly-Asp-Ser-Pro-Cys, Gly-Arg-Gly-Asp-Ser, and Arg-Gly-Asp-Ser (RGDS) into the blastocoel by a new technique. In this technique the embryos are treated with cytochalasin B (CB) and part of the presumptive PMCs (PPMCs) is removed, leaving a hole in the vegetal plate. Then macromolecules are introduced into the blastocoel through this hole. Their introduction was confirmed by introducing them with polystyrene beads as a marker. The hole closes soon after introduction of the materials, and so these materials remain in the blastocoel. After this treatment, blastulae had fewer PMCs, because of partial loss of PPMCs, but their morphogenesis proceeded normally. Introduction of anti-FN IgG or the synthetic peptides inhibited PMC migration in vivo , and this inhibition was associated with failure of the PMCs to form cell processes. These results indicate that sea urchin PMCs use the RGDS amino acid sequence in the FN molecule for migration in vivo .     

Micromere Differentiation in the Sea Urchin Embryo: Immunochemical Characterization of Primary Mesenchyme Cell-Specific Antigen and Its Biological Roles

Primary mesenchyme cell (PMC)-specific antigens in developing sea urchin embryos of five different species have been studied by using two different monoclonal antibodies, P4 and B2C2. Like B2C2 in Strongylocentrotus purpuratus (Anstrom et al. , 1987) P4 reacted with the N-linked carbohydrate in Strongylocentrotus intermedius embryo. Although both antibodies recognize the same group of glycoproteins in S. intermedius , P4 epitopes appeared earlier than B2C2 epitopes in Clypeaster japonicus embryo. PMCs of Anthocidaris crassispina blastulae raised in sulfate-deficient sea water were immuno-reactive with P4 but not with B2C2, although the embryos raised in normal sea water reacted with both antibodies at similar intensity. These results suggest that the epitopes of P4 and B2C2 are formed by glycosylation and sulfation, respectively. PMCs may display differential modification in their surface glycoprotein synthesis during differentiation. Furthermore, P4 inhibited cultured micromere descendant cells of Hemicentrotus pulcherrimus from attaching to the plastic dishes and forming spicules in vitro without detectable cytotoxic effect. P4-reactive glycoproteins may play important roles in cell-substrate interaction and spicule formation.     

Elevation of Cyclic AMP-Dependent Protein Kinase Activity during Migration of Primary Mesenchyme Cell in Sand Dollar Blastulae

Concetration of intracellular cyclic AMP (cAMP), and activities of adenylate cyclase and cAMP-dependent protein kinase were examined in swimming and mesenchyme blastulae and primary mesenchyme cells (PMCs) of the sand dollar, Clypeaster japonicus , respectively. In mesenchyme blastulae, the concentration of cAMP increased 45% from that in swimming blastulae. PMCs contained a concentration of cAMP 40% higher than that in whole embryos at the mesenchyme blastula stage. The activity of adenylate cyclase in mesenchyme blastulae was 100% higher than that in swimming blastulae. The activites of cAMP-dependent protein kinase in whole embryos at the above two developmental stages, on the other hand, were quite similar to each other. However, in PMCs the activity of the enzyme was conspicuously higher than that in these embryos, and it reached 190% higher than that in these embryos. Inhibition of cAMP-dependent protein kinase activity by a synthetic inhibitor, H8, caused severe inhibition of PMC migration but it did not exert any effect on PMC ingression. These results suggest that the cAMP-dependent protein kinase activity is involved in PMC migration, but not in PMC ingression.     

A new method for isolating primary mesenchyme cells of the sea urchin embryo : Panning on wheat germ agglutinin-coated dishes

This paper describes a rapid and efficient way to isolate primary mesenchyme cells (PMCs) of the sea urchin embryo. The procedure involves three simple steps: Dissociation of mesenchyme blastulae in calcium-free artificial seawater. Incubation of the resulting cell suspension on dishes that have been coated with wheat germ agglutinin (WGA), to which the PMCs adhere more firmly than do other cell types. Gentle rinsing of the dishes to remove loosely attached cells, followed by more vigorous rinsing to remove PMCs. This panning procedure has been applied to embryos of three species of sea urchins, Lytechinus variegatus, L. pictus and Arbacia punctulata, and yields populations of PMCs that are 95-99% pure as determined by the proportion of cells that stain with fluorescein isothiocynate (FITC)-WGA and with a monoclonal antibody that binds specifically to PMCs. The yield of PMCs is 4-5 X 10(6) cells/100-mm dish, or 1-2 X 10(7) PMCs/ml of packed embryos. The principal advantages of this procedure are that it can be carried out rapidly and simply, and it yields pure populations of PMCs.     

Behavior of Primary Mesenchyme Cells In situ Associated with Ultrastructural Alteration of the Blastocoelic Material in the Sea Urchin, Anthocidaris crassispina

In the blastula of the sea urchin, Anthocidaris crassispina , a small number of primary mesenchyme cells (PMCs) ingressed from the blastocoel wall taking a bottle shape. The majority of the PMCs followed the first group of PMCs. These ingressed without taking the bottle shape, and became round within the blastocoel wall. After ingression, the PMCs migrated as single cells retaining their round cell contour. The average velocity of their migration was 13.3 μm/hr.
The blastocoel contained Alcian blue (pH 1.0)-positive material which changed its light microscopic configuration from being amorphous in the hatched and mesenchyme blastulae to being fibrous in the early gastrulae. Ultrastructurally, the blastocoelic material in the hatched blastulae was composed of 27 nm diameter granules. In the mesenchyme blastulae and the early gastrulae relatively long 15 nm diameter fibers were seen in addition to the 27 nm diameter granules. The 27 nm diameter granules bound the ruthenium red while the 15 nm diameter fibers did not. The 27 nm diameter granules formed aggregates in the hatched blastulae, and were bound to the 15 nm diameter fibers in the mesenchyme blastulae and early gastrulae to form a fibrous network which was observed by a light microscope.     

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.     

Behavior of pigment cells closely correlates the manner of gastrulation in sea urchin embryos

To know whether behavior of pigment cells correlates the process of gastrulation or not, gastrulating embryos of several species of regular echinoids (Anthocidaris crassispina, Mespilia globulus and Toxopneustes pileolus) and irregular echinoids (Clypeaster japonicus and Astriclypeus manni) were examined. In M. globulus and A. crassispina, the archenteron elongated stepwise like in well-known sea urchins. In the embryos of both species, fluorescent pigment cells left the archenteron tip and migrated into the blastocoel during gastrulation. In T. pileolus, C. japonicus and A. manni, on the other hand, the archenteron elongated at a constant rate throughout gastrulation. In these species, no pigment cell was observed at the archenteron tip during invagination processes; pigment cells began to migrate in the ectoderm from the vegetal pole side toward the apical plate without entering the blastocoel. These results clearly indicate that the behavior of pigment cells closely correlated the manner of gastrulation. Further, it was examined whether the archenteron cells are rearranged during invagination, by comparing the number of cells observed on cross sections of the archenteron at the early and late gastrula stages. The rearrangement was not conspicuous in A. crassispina and M. globulus, in which archenteron elongated stepwise. In contrast, the archenteron cells were remarkably rearranged in C. japonicus, alothough the archenteron elongated continuously. Thus, neither the behavior of pigment cells nor the manner of gastrulation matches the current taxonomic classification of echinoids.     

The effects of aphidicolin on morphogenesis and differentiation in the sea urchin embryo

Aphidicolin, an inhibitor of DNA polymerase alpha, blocks DNA synthesis and cell division in sea urchin embryos. The effects of this inhibition appear to be stage dependent. Blastulae treated with aphidicolin before the thickening of the vegetal plate undergo developmental arrest prior to gastrulation. The extent of inhibition of DNA synthesis varies from 60 to 93% in these embryos. However, when aphidicolin is added after the vegetal plate has thickened, development continues normally through pluteus formation, even though DNA synthesis is inhibited by greater than or equal to 90% and cell division has ceased. These observations indicate that, from the vegetal plate stage onward, morphogenesis and overt differentiation are independent of DNA synthesis and cell division.     

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.     

Development of the Basal Lamina and Its Role in Migration and Pattern Formation of Primary Mesenchyme Cells in Sea Urchin Embryos

The development and substructure of the basal lamina and its role in migration and pattern formation of primary mesenchyme cells (PMCs) in normal as well as Li⁺- and Zn⁺⁺-treated embryos of sea urchins were investigated by electron microscopy. Major findings were as follows. 1) Network fibrils appear along the basal surface of the blastular wall by the hatching blastula stage. The area covered with fibrils is restricted to the vegetal hemisphere at earlier stages, but extends to the animal hemisphere as development proceeds. 2) Nonfibrous fuzzy material embeds the fibrils to form a basal lamina, but in places the fibrils project from the basal lamina into the blastocoel. The major components of the fuzzy material were digested by glycosidase, which failed to digest the fibrous components. 3) The fibrils can be classified into two types, one Ca⁺⁺-independent and the other Ca⁺⁺-dependent. PMCs apparently utilize the Ca⁺⁺-indepndent fibrils as a substratum for locomotion. 4) After migration, PMCs accumulate in a specific region to form the PMC pattern. This is formed in the area of greatest concentration of Ca⁺⁺-independent fibrils. 5) PMCs in embryos treated with LiCl, in contrast to normal embryos, accumulate in the animal pole region where the Ca⁺⁺-independent fibrils are markedly concentrated.     

Lithium changes the ectodermal fate of individual frog blastomeres because it causes ectopic neural plate formation

Amphibian blastulae that are treated with lithium (Li) develop into embryos that consist almost exclusively of head structures. This dramatic change in embryogenesis may occur either because Li selectively kills trunk progenitors or because Li causes trunk progenitors to become head progenitors. To distinguish between these possibilities, we compared the fates of individual frog blastomeres between Li-treated embryos and normal embryos using lineage tracers. The results demonstrate that Li causes ventral midline cells, which normally populate large amounts of trunk, to produce many head structures, including the brain. Examination of fluorescently labeled clones in living Li-treated gastrulae shows that: (1) the ectodermal members of the clones migrate normally, and chordamesodermal involution begins normally; (2) the chordamesoderm's later involution is altered such that it is confined to the vegetal hemisphere; (3) accordingly, the neural plate forms in the vegetal hemisphere, circumscribing the blastopore, which normally gives rise to the cloaca; and (4) the ectodermal progeny of the ventral midline blastomeres that are near the blastopore populate the brain because they are induced by the stalled chordamesoderm to form part of the ectopic neural plate. These results demonstrate that Li, administered during a short developmental window at early cleavage stages, ultimately alters ectodermal fate because it changes the pattern of chordamesodermal involution during gastrulation, which in turn changes the site of neural plate formation.     

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.     

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.     

Primary mesenchyme cell patterning during the early stages following ingression

Sea urchin primary mesenchyme cells (PMCs) ingress into the blastocoel during an epithelial-to-mesenchymal transition (EMT), migrate along the blastocoelar wall for a period of time, and then settle into a subequatorial ring to form the larval skeleton. Fluorescent-marked blastomeres alone, or in combination with blastomere recombination, were used to track the position of PMCs during the early phases of this movement. Micromeres expressing Golgi-tethered GFP (galtase-GFP) were transplanted onto TRITC-stained hosts (in place of the endogenous micromere) to observe the progeny of a single micromere. Galtase-GFP as a Golgi marker is not transferred between PMCs when the syncytium forms. Thus, the position of cells can be followed relative to beginning position for longer periods than previously reported. The PMC progeny of a single micromere do not disperse upon ingression, but instead remain in a closely associated cluster. Generally, progeny of a single micromere remain in the quadrant of origin. In total, greater than approximately 94% of labeled PMCs remain within the local region of ingression. By contrast, when a transplanted micromere is placed at the vegetal plate after removing all 4 host micromeres, the resultant PMCs ingress and migrate into all 4 quadrants. Similarly, if 1 blastomere is injected at the 2-cell stage, and later the 2 unlabeled micromeres are removed at the 16-cell stage, the remaining PMCs ingress into all 4 quadrants of the vegetal plate. We conclude that the normal restriction of PMCs to a quadrant is due to mechanical constraint from other micromere-PMCs. If a labeled micromere is placed ectopically at the macromere/mesomere boundary, the PMC progeny ingress ectopically and migrate longitudinally along the animal-vegetal axis only. Injection of galtase-GFP into one blastomere at the 4-cell stage shows a 2-step pattern of localization. At late mesenchyme blastula and early gastrula stages, greater than 90% of GFP-expressing PMCs remain in the injected quadrant, while at mid- to late-gastrula stage and beyond, more PMCs are found outside the injected quadrant. The migration that sets up the asymmetry of the larval skeleton first occurs around mid- to late-gastrula stages, when some PMCs from an aboral quadrant migrate to the adjacent oral quadrant. In all, these data combined with previous data suggest that freshly ingressed PMCs migrate along a longitudinal path toward the animal pole and back toward the vegetal pole. Beginning at mid- to late-gastrula stage, PMCs utilize oral-aboral cues from the ectoderm for the first time. At this time, some aboral PMCs migrate into the adjacent oral quadrant to assist in the formation of the ventrolateral cluster.     

Skeletogenesis by transfated secondary mesenchyme cells is dependent on extracellular matrix-ectoderm interactions in Paracentrotus lividus sea urchin embryos

In the sea urchin embryo, primary mesenchyme cells (PMCs) are committed early in development to direct skeletogenesis, provided that a permissive signal is conveyed from adjacent ectoderm cells. We showed that inhibition of extracellular matrix (ECM)-ectoderm cells interaction, by monoclonal antibodies (mAb) to Pl-nectin, causes an impairment of skeletogenesis and reduced expression of Pl-SM30, a spicule-specific matrix protein. When PMCs are experimentally removed, some secondary mesenchyme cells (SMCs) switch to skeletogenic fate. Here, for the first time we studied SMC transfating in PMC-less embryos of Paracentrotus lividus. We observed the appearance of skeletogenic cells within 10 h of PMCs removal, as shown by binding of wheat germ agglutinin (WGA) to cell surface molecules unique to PMCs. Interestingly, the number of WGA-positive cells, expressing also msp130, another PMC-specific marker, doubled with respect to that of PMCs present in normal embryos, though the number of SM30-expressing cells remained constant. In addition, we investigated the ability of SMCs to direct skeletogenesis in embryos exposed to mAbs to Pl-nectin after removal of PMCs. We found that, although phenotypic SMC transfating occurred, spicule development, as well as Pl-SM30-expression was strongly inhibited. These results demonstrate that ectoderm inductive signals are necessary for transfated SMCs to express genes needed for skeletogenesis.     

Brachyury homolog (HpTa) is involved in the formation of archenteron and secondary mesenchyme cell differentiation in the sea urchin embryo

Sea urchin Brachyury homolog (HpTa) is expressed exclusively in the vegetal plate and secondary mesenchyme cells in the embryos of sea urchin Hemicentrotus pulcherrimus. In order to gain insights into the role of HpTa during sea urchin development, we designed experiments to perturb the embryo by inducing ectopic overexpression of HpTa by injecting fertilized eggs with HpTa mRNA. The overexpression of HpTa resulted in suppression of the formation of vegetal plate and secondary mesenchyme cells. We assume that the interaction of HpTa with unknown factors is required for the activation of the HpTa target genes, and that the excess amount of HpTa proteins produced from injected HpTa mRNA depletes the co-factors. In consequence, the target genes of HpTa would be repressed by the overexpression of HpTa. We suggest that HpTa is involved in the formation of the vegetal plate and the differentiation of secondary mesenchyme cells.     

Cell movements during the initial phase of gastrulation in the sea urchin embryo.

The morphogenetic processes responsible for the initial phase of gastrulation in sea urchin embryos are not known. Here we report observations of the size and position of clones of cells derived from horseradish peroxidase (HRP)-injected mesomeres and macromeres. The displacement of these clones during the initial phase of gastrulation suggests that involution is a mechanism involved in primary invagination. Experiments with embryos marked with vital dyes indicate that movements occur only during a brief phase coincident with the invagination of the vegetal plate. Counts of cells derived from HRP-injected mesomeres and macromeres suggest it unlikely that localized growth in the vegetal plate is involved in gastrulation. An analysis of changes in cell shape during the initial phase of gastrulation indicates that there is a stage-dependent shift from cells being columnar to having their apices skewed toward the vegetal plate and an increase in the proportion of cells having basal processes during gastrulation. When embryos are grown in the presence of monoclonal antibodies to the apical lamina or monovalent fragments of these antibodies, the initial phase of gastrulation is delayed and they form partial exogastrulae. Analysis of embryos marked with HRP indicate that the antibody treatments interfere with the cellular movements observed in untreated embryos. We conclude that directed movements of cells within the blastoderm, probably employing tractoring on components of the hyaline layer, cause the buckling of the vegetal plate and displacement of presumptive endoderm cells seen during the initial phase of gastrulation.