Secondary mesenchyme of the sea urchin embryo: ontogeny of blastocoelar cells.

Secondary mesenchyme in sea urchin embryos is released into the blastocoel after primary mesenchyme, and although these cells have been recognized for some time, we lack knowledge about many fundamental aspects of their origin and fate. Here we documented the ontogeny of one of the principal, and least well-known, types of cells derived from secondary mesenchyme. The blastocoelar cells arise from mesenchyme released from the tip of the archenteron following the initial phase of gastrulation. The cells migrate with their cell bodies suspended in the blastocoel, rather than being apposed to the basal lamina like primary mesenchyme. The cells extend numerous fine filopodia to form a network of cytoplasmic processes around the gut, along the skeletal rods, and within the larval arms. Once the network is formed, the cells maintain their positions, although they actively translocate vesicles and cytoplasm along their filopodia. Cell counts indicate there is an initial recruitment of cells during gastrulation, followed by a more gradual increase in cell number after the larva begins to feed. Lineage studies in which 16-cell-stage macromeres were injected with horseradish peroxidase indicate that almost all of the macromere-derived mesenchyme forms pigment cells and blastocoelar cells. We propose that blastocoelar cells are a distinct subset of secondary mesenchyme that forms fibroblast-like cells in the blastocoel of sea urchin embryos.     

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.     

Isolation,culture, and differentiation of echinoid primary mesenchyme cells

Summary Methods are described for isolation and culture of primary mesenchyme cells from echinoid embryos. Ninety-five percentpure primary mesenchyme cells were isolated from early gastrulae ofStrongylocentrotus purpuratus, exploiting the biological segregation of these cells within the blastocoel. When cultured, more than 90% of the isolated cells reached the differentiated state, spicule formation, in synchrony with in vivo controls. Isolated primary mesenchyme cells were cultured with and without various cellular and acellular components of normal embryos in order to study the potential involvement of these components in the morphogenesis of the primary mesenchyme. Our data indicate that: 1. primary mesenchyme cells lack the ability to form the annular pattern of the primary mesenchymal ring autonomously; 2. they autonomously produce spicules of a characteristic morphology that differs from that of embryonic spicules; 3. morphogenesis of the primary mesenchyme is not affected by association with embryonic basal lamina, blastocoel matrix, or loosely aggregated epithelial cells, or by close confinement of each set of primary mesenchyme cells within the blastocoelar space; and 4. reaggregated, tightly associated epithelial cells can promote normal primary mesenchyme ring formation, and modify the primary mesenchyme-intrinsic spicule pattern to produce more normal spicule forms.     

Isolation and characterization of an endodermally derived, proteoglycan-like extracellular matrix molecule that may be involved in larval starfish digestive tract morphogenesis

A monoclonal antibody, anti-Pisaster matrix-1 (anti-PM1) has been developed against an extracellular matrix antigen, Pisaster matrix-1 (PM1) found in embryos and larvae of the starfish Pisaster ochraceus . Pisaster matrix-1 was first observed in endodermal cells of the early gastrula, and shortly thereafter it was secreted into the blastocoel where it accumulated steadily during gastrulation. During the late gastrula stage it also appeared in the extracellular matrix (ECM) of the gut lumen. Immunogold electron microscopy with anti-PM1 revealed that PM1 was found in condensations of ECM associated with blastocoel matrix fibers, in the trans Golgi network, in Golgi-associated vesicles in endoderm and mesenchyme cells and throughout the ECM lining the digestive tract of late gastrula and bipinnaria larvae. When blastula or early gastrula stage embryos were grown in the presence of the PM1 antibody, archenteron elongation, bending and mouth formation failed to occur. Pisaster matrix-1 stained with alcian blue and its assembly could be disrupted with the common inhibitor of O-linked glycosaminoglycan assembly, β-xyloside but not by tunicamycin. It was not sensitive to enzymes that degrade vertebrate proteoglycans. Pisaster matrix-1 is a large (600 kDa) proteoglycan-like glycosaminoglycan, secreted exclusively by endodermal and/or endodermally derived cells that may be necessary for morphogenesis of the mouth and digestive tract of Pisaster ochraceus embryos/larvae.     

Inhibition of cell migration in sea urchin embryos by beta-D-xyloside

This investigation examines the effect of exogenous xylosides on primary mesenchyme cell behavior in Strongylocentrotus purpuratus embryos. In confirmation of studies in some other species the addition of 2 mM p-nitrophenyl-beta-D-xylopyranoside blocks the migration but not the initial ingression of primary mesenchyme cells. The blastocoel matrix of treated embryos appears deficient in a 15- to 30-nm-diameter granular component that is observed extensively on the basal lamina and on filopodia of migrating primary mesenchyme cells in untreated embryos. Other blastocoel components appear unaffected by ultrastructural criteria. The incorporation of 35SO4(2-) per embryo into ethanol precipitates of isolated blastocoel matrices was reduced significantly after xyloside treatment but the distribution of 35SO4(2-) after polyacrylamide gel electrophoresis or the glycosaminoglycan composition was unaffected. Chromatography on Sepharose CL-2B demonstrates a reduction in size of sulfated components of the blastocoel. While over 60% of the 35S-labeled material from the blastocoel of normal mesenchyme blastulae is voided from a Sepharose CL-2B column run in a dissociative solvent, only 10% from xyloside treated embryos is voided. Instead, there is a large included peak with Kav of 0.33. This material is acid soluble but cetylpyridinium chloride precipitable. It apparently consists largely of free glycosaminoglycan chains. Based on analysis of chondroitinase ABC digestion products this material consists of 41% chondroitin-6-sulfate and 58% dermatan sulfate. These results are consistent with a role in cell migration for intact chondroitin sulfate/dermatan sulfate proteoglycans in the sea urchin blastocoel matrix.     

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.     

Specification and differentiation processes of secondary mesenchyme-derived cells in embryos of the sea urchin Hemicentrotus pulcherrimus

Four types of mesoderm cells (pigment cells, blastocoelar cells, coelomic pouch cells and circumesophageal muscle cells) are derived from secondary mesenchyme cells (SMC) in sea urchin embryos. To gain information on the specification and differentiation processes of SMC-derived cells, we studied the exact number and division cycles of each type of cell in Hemicentrotus pulcherrimus. Numbers of blastocoelar cells, coelomic pouch cells and circumesophageal muscle fibers were 18.0 +/- 2.0 (36 h post-fertilization (h.p.f.)), 23.0 +/- 2.5 (36 h.p.f.) and 9.5 +/- 1.3 (60 h.p.f.), respectively, whereas the number of pigment cells ranged from 40 to 60. From the diameters of blastocoelar cells and coelomic pouch cells, the numbers of division cycles were elucidated; these two types of cells had undertaken 11 rounds of cell division by the prism stage, somewhat earlier than pigment cells. To determine the relationship among the four types of cells, we tried to alter the number of pigment cells with chemical treatment and found that CH3COONa increased pigment cells without affecting embryo morphology. Interestingly, the number of blastocoelar cells became smaller in CH3COONa-treated embryos. In contrast, blastocoelar cells were markedly increased with NiCl2 treatment, whereas the number of pigment cells was markedly decreased. The number of coelomic pouch cells and circumesophageal muscle fibers was not affected with these treatments, indicating that coelomic pouch and muscle cells are specified independently of, or at much later stages, than pigment and blastocoelar cells.     

Fibronectin-binding acid polysaccharide in the sea urchin embryo

Summary A novel fibronectin-binding acid polysaccharide (FAPS) was isolated from embryos of the sea urchin. Binding of FAPS to fibronectin was quantitatively measured at physiological pH and ionic strength by two different assay systems. Immunofluorescent studies revealed that FAPS is localized in the extracellular matrix surrounding the mesenchyme cells and primitive gut of middle gastrula. Sea urchin fibronectin was also detected in the extracellular matrix surrounding mesenchyme cells and the cells surrounding the blastopore. When a monoclonal antibody to FAPS (anti-FAPS) was microinjected into the blastocoel, more than one pair of triradiate spicular rudiments was formed and the malformation of spicules was induced. Armless and deformed larvae were also induced by anti-FAPS. FAPS may regulate the number, length, position and direction of spicules. These results implicate the extracellular matrix of the blastocoel in the complex process of differentiation of mesenchyme and the formation of spicules.     

Patterns of cells and extracellular material of the sea urchin Lytechinus variegatus (Echinodermata; Echinoidea) embryo,from hatched blastula to late gastrula

Scanning electron microscopy of six stages of Lytechinus variegatus embryos from hatching through gastrulation reveals changes in the shapes of the ectodermal cells and morphological changes in the extracellular material (ECM) in relation to the locations and migratory activities of mesenchyme cells. The classical optical patterns in the blastular wall (Okazaki patterns) are due to differential orientations of the cells, which bend and extend sheet-like lamellipodia over adjoining cells toward the eventual location of the primary mesenchymal ring. The blastocoelic surfaces of the blastomeres become covered with a thin basal lamina (BL) composed of fibers and nonfibrous material. During primary mesenchyme cell (PMC) ingression, a web-like ECM is located in the blastocoel overlying the amassed PMCs. This ECM becomes sparse in migratory mesenchyme blastulae, and is confined to the animal hemisphere. Localized regions of intertwining basal cell processes in the blastular wall are also present during PMC migration. While a distinct BL is present during early and midgastrulation, blastocoelic ECM is absent. Late gastrulae, on the other hand, have an abundance of blastocoelic ECM concentrated near secondary mesenchyme cell protrusive activity. ECM appearing at both the early mesenchyme and late gastrula stages are probably remnants of degraded BL and intercellular matrix preserved by fixation for SEM. Thus, early mesenchyme ECM is formed of BL material whose degradation is necessary for entry of PMCs into the blastocoel. Late gastrula ECM is apparently a degradation product of BL and intercellular material whose destruction is required for fusion of the gut with oral ectoderm in formation of the mouth.     

Ultrastructure and synthesis of the extracellular matrix of Pisaster ochraceus embryos preserved by freeze substitution

When asteroid embryos cryoprotected with propylene glycol are rapidly frozen in liquid propane and freeze substituted with ethanol, preservation of the cells and extracellular matrix (ECM) is excellent. The basal lamina, although thicker and less well defined than in conventionally fixed embryos, demonstrates a region of decreased density just below the cells that corresponds to the lamina lucida and a lamina densa. The former region is often occupied by fibrous material. In addition, as was previously described in conventionally fixed tissues, the basal lamina of the ectoderm is generally thicker and more substantial than that of the endoderm, reinforcing an earlier suggestion that the structure of the basal lamina is different in different regions of the embryo. The ECM of the blastocoel consists of thin “twig-like” elements that form a loose meshwork evenly distributed throughout the blastocoel. Bundles of 20 nm fibers, located within the meshwork, are oriented parallel to the base of the cells of the stomodeum. In the long axis of the embryo, similar fibers are present in the dorsal aspect of the animal between the stomach and the ectoderm and radiate out from the esophagus crossing the region between it and the ectoderm. Immunocytochemical work with three different monoclonal antibodies shows that glycoprotein molecules, synthesized in the Golgi apparatus, are also secreted here and form part of the matrix structure. The results suggest that the blastocoel is filled with a gel-like material reinforced with bundles of 20-nm fibers. The manner in which the observed arrangement could contribute to the development and maintainence of the shape of the embryo is discussed. J Morphol 232:133–153, 1997. © 1997 Wiley-Liss, Inc.     

Extracellular matrix of sea urchin and other marine invertebrate embryos

The extracellular matrix surrounding the sea urchin embryo (outer ECM) contains fibers and granules of various sizes which are organized in recognizable patterns as shown by ultrastructural studies, particularly stereoimaging techniques. The use of the ruthenium red method for retaining and staining the ECM, with modifications of the Luft (Anatomical Record 171:347-368, 1971) method for invertebrate embryos, allows for the clarification of certain structures, particularly fiber compaction in the interzonal region, and microvillus-associated bodies. The inner ECM in the sea urchin embryo includes the basal lamina and blastocoel matrix. Stereoimages show that the fibers which are loosely distributed in the blastocoel matrix become compacted around the periphery of the blastocoel to form the basal lamina. The ruthenium red method was also used on a number of marine invertebrate embryos and larvae, representing different phyla, to facilitate comparisons between their surface coats. The similarities observed in the specimens shown suggest that ECMs are widely found on marine invertebrate eggs, embryos, and larvae, and that they resemble vertebrate ECMs and may, therefore, have similar functions.     

An extracellular fibrillar matrix in gastrulating sea urchin embryos

Fine structural studies of fractured developing sea urchin embryos revealed the existence of a voluminous, fibrillar, extracellular matrix composed of fine filaments, twisting fibers and granules lining the blastocoel of midgastrula embryos. Glycine disaggregated embryos also exhibited this material. The fibrillar matrix is closely associated with the basal lamina of the ectodermal cells of the embryo and histochemical studies suggest it is composed mostly of sulfated glycosaminoglycans. The position of the matrix within the blastocoel as well as its organized association with embryonic cell surfaces is consistent with the hypothesis that it plays a major role in guiding the invaginating archenteron during gastrulation.     

Fibronectin and laminin in the extracellular matrix and basement membrane of sea urchin embryos

Fibronectin and laminin have been found in the extracellular matrix and in the basement membrane of sea urchin embryos during early development. These glycoproteins are also found on the cell surfaces of the outer epithelial layer and on the secondary mesenchyme cells within the blastocoel. The similarity of functions of the extracellular matrix and basement membrane is discussed, as is the similarity of their molecular components. These observations suggest the possibility that fibronectin and laminin form a continuous matrix surrounding the cells which links the outer ECM (hyaline layer) to the inner ECM (basement membrane). Such a network could coordinate the various activities of the embryo during early morphogenesis.     

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.     

Regional Ultrastructural Differences in Basal Laminae Isolated from the Starfish Pisaster ochraceus

The ultrastructure of different regions of the basal laminae isolated from 5-1/2-6 day-old embryos of the starfish, Pisaster ochraceus , has been described after fixation in the presence of anionic dyes. Isolated basal laminae from all regions of the embryo exhibit a lamina lucida and lamina densa. No lamina fibroreticularis is present. Instead, a coarse meshwork of thick densely stained and thinner intermediately stained fibers is embedded in the lamina densa and extends into the blastocoel forming the extracellular matrix. The coarse meshwork associated with the ectodermal basal lamina consists primarily of thick densely stained fibers with a small number of intermediate ones while that associated with the endodermal one contains much less densely stained material. These structures were morphologically identical to those found in control embryos. Examination of different regions of the endodermal basal lamina shows that the amount of dense material varies from region to region. These differences in dense material may reflect biochemical differences, particularly of proteoglycans, which could provide positional information to migrating mesenchyme cells.     

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.     

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)     

Study of larval and adult skeletogenic cells in developing sea urchin larvae

The larval skeleton of sea urchin embryos is formed by primary mesenchyme cells (PMCs). Thereafter, the larvae start feeding and additional arms develop. An adult rudiment that contains spines, tube feet, tests, and other parts of the adult body is formed in the eight-armed larva. The cellular mechanism of the later skeletogenesis and the lineage of the adult skeletogenic cells are not known. In this study, the morphogenesis of larval and adult skeletons during larval development of the sea urchin Hemicentrotus pulcherrimus was investigated by immunostaining cells with PMC-specific monoclonal antibodies, which are useful markers of skeletogenic cells. All spicules and the associated cells in the later larvae were stained with the antibodies. We could observe the initiation of skeletal morphogenesis at each developmental stage and visualize the cellular basis of skeleton formation in whole-mount embryos that possessed an intact morphology. There were some similarities between PMCs and the later skeletogenic cells. Both had a rounded shape with some filopodia, and the antigen expression started just before overt spicule formation. In the later-stage embryos, cells with filopodia and faint antigen expression were observed migrating in the blastocoel or aggregating in the presumptive location of new skeletogenesis.