Electron microscopic studies on primary mesenchyme cell ingression and gastrulation in relation to vegetal pole cell behavior in sea urchin embryos

Early morphogenetic events of primary mesenchyme cell (PMC) ingression and gastrulation were examined by scanning and transmission electron microscopy, with special attention directed to changes in the shape of vegetal pole cells, the length of their microvilli, and interactions between microvilli and the hyaline layer (HL). Eight cells (vegetal pole cells) with elongated microvilli remained in the vegetal pole region while surrounding cells ingressed into the blastocoel to form the primary mesenchyme. These vegetal pole cells indented with the surrounding cells at the stage of gastrulation. The outer surface area with elongated microvilli of vegetal pole cells expanded at the stage of PMC ingression, but was considerably reduced at gastrulation. Microvilli on vegetal pole cells continued to adhere to the HL up to the stage of PMC ingression, but ceased to do so at the time of gastrulation. Thus, the area with separated HL, which is restricted to the region of the PMC released at the stage of PMC ingression, spreads almost entirely throughout the area of the indenting vegetal plate at gastrulation. The apical lamina, apparently consisting of fibrous material intertwinning the stalks of the microvilli, filled the space between the HL and ectodermal cells. The cells surrounding those of the vegetal pole and indenting with those at the stage of gastrulation appeared to behave in the same way as ingressing PMCs in both cell-shape and loss of adhesion of microvilli to HL. The role of vegetal pole cells in early morphogenetic events is discussed.     

Specification process of animal plate in the sea urchin embryo

The most animal part of the ciliated band of sea urchin larvae, the animal plate, is a specialized region in which elongated cells form long and non-beating cilia. To learn how this region is specified, animal halves were isolated from the early cleavage to pregastrulation stages. As is well known, the animal half that is isolated at the eight-cell stage develops into a 'dauerblastula', which forms long and non-beating cilia all around the surface. The region with long cilia, however, became restricted toward the animal pole when separation was delayed. If separated before primary mesenchyme ingression, even a small animal-pole-side fragment formed a normal-sized animal plate. Thus, the prospective animal plate region is gradually restricted by some signal from the vegetal hemisphere, and the specification process terminates before the mesenchyme blastula stage. It was also known that a normal-sized animal plate was formed in micromere-less embryos, indicating that the signal does not depend on micromeres or their descendants. Further, the animal-pole-side fragments were isolated from embryos in which the third cleavage plane was shifted toward the vegetal pole. They formed a normal-sized animal plate, containing more than 75% of the egg volume from the animal pole. This indicates that the egg cytoplasm delivered to veg₁ -lineage blastomeres plays an important role in the animal plate specification. Interestingly, the an1-less embryo formed long and non-beating cilia at its top region, but thickening did not occur. The cytoplasm near the animal pole might contain some factors necessary for the animal plate to become thick.     

The origin of skeleton forming cells in the sea urchin embryo

Summary In embryos of the modern sea urchin species, subclass Euechinoidea, primary mesenchyme cells are derived from the progeny of micromeres formed at the sixteen cell stage of embryogenesis. The micromeres reside within the vegetal plate epithelium and later ingress into the blastocoel as primary mesenchyme cells which form the larval skeleton. Embryos of Eucidaris tribuloides, a member of the primitive subclass Perischoechinoidea, exhibit several noteworthy differences from euechinoid primary mesenchyme cell lineage including variable numbers and sizes of micromeres, the absence of mesenchyme ingression, and the lack of any detectable primary mesenchyme although a larval skeleton forms. In the present study, the cell lineage of the spiculogenic mesenchyme has been studied in Eucidaris tribuloides and in the euechinoid Lytechinus pictus by microinjecting the fluorescent tracer, Lucifer Yellow, into individual blastomeres of the embryo. In addition, wheat germ agglutinin, a lectin which binds only to primary mesenchyme cells of the early euechinoid embryo, was injected into the blastocoel of embryos of both species in order to examine the distribution of cells which possess primary mesenchyme-specific cell surface markers. The results of these experiments demonstrate that the spiculogenic mesenchyme of both Lytechinus and Eucidaris arise from descendants of micromeres formed at the sixteen cell stage, although the temporal and spatial distribution of these mesenchyme cells varies considerably between species. Furthermore, the evidence obtained suggests that the information necessary for spicule formation is already segregated to the vegetal pole by the eight cell stage. The results also suggest that there are no gap junctions present between the blastomeres of the early sea urchin embryo.     

Three cell recognition changes accompany the ingression of sea urchin primary mesenchyme cells

At gastrulation the primary mesenchyme cells of sea urchin embryos lose contact with the extracellular hyaline layer and with neighboring blastomeres as they pass through the basal lamina and enter the blastocoel. This delamination process was examined using a cell-binding assay to follow changes in affinities between mesenchyme cells and their three substrates: hyalin, early gastrula cells, and basal lamina. Sixteen-cell-stage micromeres (the precursors of primary mesenchyme cells), and mesenchyme cells obtained from mesenchyme-blastula-stage embryos were used in conjunction with micromeres raised in culture to intermediate ages. The micromeres exhibited an affinity for hyalin, but the affinity was lost at the time of mesenchyme ingression in vivo. Similarly, micromeres had an affinity for monolayers of gastrula cells but the older mesenchyme cells lost much of their cell-to-cell affinity. Presumptive ectoderm and endoderm cells tested against the gastrula monolayers showed no decrease in binding over the same time interval. When micromeres and primary mesenchyme cells were tested against basal lamina preparations, there was an increase in affinity that was associated with developmental time. Presumptive ectoderm and endoderm cells showed no change in affinity over the same interval. Binding measurements using isolated basal laminar components identified fibronectin as one molecule for which the wandering primary mesenchyme cells acquired a specific affinity. The data indicate that as the presumptive mesenchyme cells leave the vegetal plate of the embryo they lose affinities for hyalin and for neighboring cells, and gain an affinity for fibronectin associated with the basal lamina and extracellular matrix that lines the blastocoel.     

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.     

Microfilaments, cell shape changes, and the formation of primary mesenchyme in sea urchin embryos.

Primary mesenchyme formation in sea urchin embryos occurs when a subset of epithelial cells of the blastula move from the epithelial layer into the blastocoel. The role of microfilaments in producing the cell shape changes that characterize this process, referred to as ingression, was investigated in this study. f-Actin was localized by confocal microscopy using labeled phalloidin. The distribution of f-actin was observed before, during, and after ingression and was correlated with cellular movements. Prior to the onset of ingression, staining became intense in the apical region of putative primary mesenchyme and disappeared following the completion of mesenchyme formation. The apical end of these cells constricted coincidentally with the appearance of the intensified staining, indicating that f-actin may be involved in this constriction. In addition, papaverine, a smooth muscle cell relaxant that interferes with microfilament-based contraction, and that was shown in this study to inhibit cytokinesis, diminished apical constriction and delayed ingression. Despite this interference with apical constriction, the basal surface of ingressing cells protruded into the blastocoel. It is suggested that apical constriction, while not necessary for ingression, does contribute to the efficient production of mesenchyme and that protrusion of the basal surface results from changes that occur independent of apical constriction.     

Sea urchin primary mesenchyme cells: relation of cell polarity to the epithelial-mesenchymal transformation

In euechinoid sea urchin embryos, a subset of epithelial cells in the wall of the blastula become pulsatile, elongate, lose connections with their neighboring cells, and move into the blastocoel to form the primary mesenchyme cells. The Golgi apparatus and microtubule organizing center (MTOC) are located at the apical end of these epithelial cells. We show that as primary mesenchyme cells begin to move into the blastocoel, the Golgi apparatus and MTOC move to a new position adjacent to the apical side of the nucleus. They do not move to a position between the nucleus and the leading (i.e., basal) end of the cell as they do in cultured fibroblasts undergoing directed migration. In addition, we have inhibited the movement of membranous vesicles to the cell surface by incubating embryos in the ionophore monensin. We have used antibodies to msp130, a primary mesenchyme cell surface-specific glycoprotein, to demonstrate that monensin inhibits the movement of msp130-containing vesicles to the cell surface. Despite the inhibition of membrane shuttling by monensin, primary mesenchyme cells ingress on schedule and display normal cell-shape changes. We draw two conclusions from our data. First, the cellular elongation that characterizes ingression is not due to the local insertion of membrane at the leading (basal) end of the cell. Second, ingression does not depend upon establishment of the same cell polarity required for fibroblasts to carry out directed cell migration.     

Focal adhesion kinase (FAK) expression and phosphorylation in sea urchin embryos

We have cloned three cDNA isoforms of focal adhesion kinase (FAK) from the sea urchin, Lytechinus variegatus. The sea urchin FAK is more closely related to FAK from other deuterostomes than from invertebrate protostomes or to cell adhesion kinase beta (CAKbeta/Pyk2/FAK2). FAK is expressed in all cells of sea urchin embryos by the 120-cell stage and strongly in blastulae. Phospho-FAK concentrates on basal surfaces of epithelial cells in early blastulae and occurs in syncytial cables of primary mesenchyme cells (PMC). Inhibition of FAK by constructs of FAK-related non-kinase delays blastocoel expansion and early PMC ingression. These results suggest that FAK has roles in cell adhesion and in the shape and integrity of the epithelial cells in sea urchin embryos.     

Acid mucopolysaccharide metabolism, the cell surface, and primary mesenchyme cell activity in the sea urchin embryo

The relationship between ³⁵SO₄ incorporation into acid mucopolysaccharides and the appearance and activity of the primary mesenchyme cells has been studied in the sea urchin, Lytechinus pictus. The ratio of the uptake of ³⁵SO₄ to its incorporation into cetylpyridinium chloride precipitable material varies over a wide range during early development, with the smallest ratio, therefore the greatest sulfation activity, being found at the early mesenchyme blastula stage. The types of mucopolysaccharides produced have not been identified, but are heterogeneous. At the mesenchyme blastula stage nearly 90% of the polysaccharides produced become sulfated. When embryos develop in sulfate-free sea water to the mesenchyme blastula stage there is a 70% decrease in the incorporation of ³H-acetate into polysaccharides and a 13-fold decrease in the ratio of sulfated to nonsulfated polysaccharides produced. Embryos raised in sulfate-free sea water develop normally to the mesenchyme blastula stage at which time there is an accumulation in the blastocoel of primary mesenchyme cells that do not migrate. The surface of the primary mesenchyme cells of sulfate-deficient embryos has a smooth appearance in the scanning electron microscope, while the surface of these cells in control embryos is rough, possibly reflecting the presence of an extracellular coat. It is suggested that there is a correlation between sulfated polysaccharide synthesis, cell surface morphology and cell movement.     

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.     

Occurrence of Fibronectin on the Primary Mesenchyme Cell Surface During Migration in the Sea Urchin Embryo

The distribution of fibronectin in situ in the sea urchin embryo was examined by using indirect immunofluorescence with an antibody raised against human plasma fibronectin. Fibronectin was detected on the surfaces of primary mesenchyme cells in the mid-mesenchyme blastula stage, when these cells are migratory. However, it was not detected on these cells at the early mesenchyme blastula or early gastrula stages. Also, it was not detected in the blastocoel nor on the basal surface of the blastular wall. The migration of the primary mesenchyme cells is therefore correlated with a stage-dependent occurrence of cell surface-associated fibronectin.     

Occurrence of fibronectin on the primary mesenchyme cell surface during migration in the sea urchin embryo

The distribution of fibronectin in situ in the sea urchin embryo was examined by using indirect immunofluorescence with an antibody raised against human plasma fibronectin. Fibronectin was detected on the surfaces of primary mesenchyme cells in the mid-mesenchyme blastula stage, when these cells are migratory. However, it was not detected on these cells at the early mesenchyme blastula or early gastrula stages. Also, it was not detected in the blastocoel nor on the basal surface of the blastular wall. The migration of the primary mesenchyme cells is therefore correlated with a stage-dependent occurrence of cell surface-associated fibronectin.     

Characterization and expression of two matrix metalloproteinase genes during sea urchin development

Matrix metalloproteinases (MMPs) play an essential role in a variety of processes in development that require extracellular matrix remodeling and degradation. In this study, we characterize two MMPs from the sea urchin Strongylocentrotus purpuratus. These clones can both be identified as MMPs based on the presence of conserved domains such as the cysteine switch, zinc-binding, and hemopexin domains. In addition, both of these genes contain consensus furin cleavage sites and putative transmembrane domains, classifying them as membrane-type MMPs. We have named these clones SpMMP14 and SpMMP16 based on the vertebrate MMPs with which they share the greatest similarity. SpMMP14 is expressed in all cells from the egg to mesenchyme blastula stage embryo. Expression of this gene is strongest in the animal and vegetal poles early in gastrulation and in the animal pole only later in gastrulation. SpMMP16 is expressed at low levels in eggs. Expression of SpMMP16 becomes more pronounced in the vegetal pole region at the blastula and mesenchyme blastula stages and becomes confined to vegetal pole descendants, such as pigment cells, later in development. In the future, we hope to learn more about the possible functions of these genes in sea urchin development.     

Ontogeny and characterization of mesenchyme antigens of the sea urchin embryo

A monoclonal antibody, Sp12, binds to cortical granules, the hyaline layer, and skeletogenic, chromogenic, and blastocoelar mesenchyme of sea urchin eggs and embryos. Adult urchins also express Sp12 antigens in the dermal layer of the test and spines. Antigen is expressed on the surface of primary mesenchyme cells after they have entered the blastocoel, and by two secondary mesenchyme derivatives--the blastocoelar cells after they have been released from the tip of the archenteron, and the pigment cells in prism stage embryos. Immunogold localizations show antigen on the surfaces of mesenchyme, within membrane bounded vesicles, and associated with the Golgi apparatus. Western blots of antigens immunoprecipitated from seven developmental stages reveal twelve antigens ranging in Mr from 35 k to 240 k. Most of these antigens appear, disappear or change Mr over the first five days of development. Characterizations of this complex array of antigens show that the epitope recognized by Sp12 is eliminated by proteolytic enzymes and endoglycosidase F, while immunoreactivity is only reduced by periodate oxidation. As well, calcium magnesium free seawater extracts a subset of antigens different from that retained by crude membrane preparations. It is proposed that the mesenchyme of sea urchin embryos produces a family of developmentally regulated cell surface and extracellular matrix glycoproteins which all exhibit a carbohydrate epitope recognized by Sp12.     

A method of microinjection: delivering monoclonal antibody 1223 into sea urchin embryos.

In this paper, a simpler method of microinjecting sea urchin embryos without using the conventional microinjection chamber designed by Kiehart is reported. A trough was made on a surface of 0.6% agarose gel dissolved in artificial sea water. Approximately fifty hatched embryos could be loaded in the trough and, consequently, swimming embryos were trapped in the trough. Monoclonal antibody (mAB) 1223 which blocks spiculogenesis in vitro was delivered into the blastocoels of sea urchin embryos to test whether this antibody inhibits spiculogenesis in vivo and also, whether this new technique is effective for the microinjection of the sea urchin embryos. The embryos were injected with mAB1223 at the hatched blastula, early mesenchyme blastula and early gastrula stages, and 63%, 90% and 97% of the embryos did not form spicules at the late gastrula stage, respectively. Therefore, mAB1223 was shown to also block spiculogenesis in vivo. From the fact that spiculogenesis occurred at a lower rate when mAB1223 was injected at the hatched blastula stage than at later stages, it may be speculated that endogenous proteases degraded the injected antibodies. Using this technique, extracellular events in the blastocoel or the function of certain molecules expressed in blastocoel can be easily investigated in vivo.