Cells are added to the archenteron during and following secondary invagination in the sea urchin Lytechinus variegatus.

In the present investigation, nuclei of endodermal cells, primary and secondary mesenchyme cells (PMCs and SMCs), and small micromere descendants (SMDs) of the sea urchin Lytechinus variegatus were counted and mapped at five developmental stages, ranging from primary invagination to pluteus larva. The archenteron and its derivatives were measured three dimensionally with STERECON analytical software. For the first time SMC production is included in the kinetic analysis of archenteron formation. While the archenteron lumen doubled in length during secondary invagination, the number of archenteron cells increased by at least 38% (over 50% when SMCs that emigrated from the tip of the archenteron were included). The volume of the archenteron epithelial wall plus the volume of 17 new SMCs increased by 40% over the equivalent volumes at the end of primary invagination. Because secondary invagination involves the addition of archenteron cells and an increase in volume of the archenteron epithelium, we conclude that secondary invagination is not accomplished simply by the rearrangement and reshaping of the primary archenteron cells. Both archenteron cell number and wall volume continued to increase at the same rates from the end of secondary invagination until the 27-h prism stage, although the lumen lengthened more slowly. SMCs were also produced at a constant rate from primary invagination until the prism stage. Because the production of both endodermal and mesodermal cells continues until the late prism stage, we conclude that gastrulation (defined as the establishment of the germ layers) also extends into the late prism stage.

The orientation of first cleavage in the sea urchin embryo, Lytechinus variegatus, does not specify the axes of bilateral symmetry.

One blastomere of the two-cell stage sea urchin embryo (Lytechinus variegatus) was labeled with an intracellular fluorescent lineage tracing stain to determine, from the lineage of that blastomere, the orientation of the first cleavage furrow with regard to the axes of bilateral symmetry in the gastrula and pluteus larva. Two methods were used to mark the blastomere: in the first, the lipophilic carbocyanine dye DiIC16 was microinjected directly into the blastomere after first cleavage was completed. In the second, caged (nonfluorescent) fluorescein-dextran was microinjected into the single-celled zygote and uncaged (made fluorescent) in one of the blastomeres at the two-cell stage using two-photon excitation microscopy (TPEM). This is the first use of TPEM for embryonic lineage tracing. In both methods the dye proved to be nontoxic and fluorescence was confined to lineally related cells. The results from both methods were similar and showed that the first cleavage furrow was variable in its orientation. Results were similar using animals obtained from different geographic locations. These results differ from those of McCain and McClay (Development, 1994, 120, 395-404), who reported that the median orientation was invariant in this species. The differences between the two studies are discussed. We conclude that first cleavage does not specify nor is it predictive of the bilateral axes in this species. The technique of TPEM is proffered as a powerful new tool that will enable the marking and tracing of embryonic cell lineages with less injury and more precision than current methods.

Preservation and visualization of the sea urchin embryo blastocoelic extracellular matrix.

Several methods were utilized to visualize the structure and orientation of the blastocoelic extracellular matrix (ECM) in Strongylocentrotus purpuratus embryos at the mesenchyme blastula stage. Rapid freezing in liquid propane cooled to LN2 temperatures followed by freeze substitution was used to preserve the ECM without shrinkage due to dehydration. Scanning, transmission, and light microscopy were employed to elucidate the ECMs' structure. The blastocoelic ECM consisted of parallel fibrillar sheets that were interconnected by finer filaments and oriented along the animal-vegetal axis. The ECM completely filled the blastocoelic cavity as viewed by scanning electron microscopy. The basal lamina could be distinguished from the blastocoelic ECM as a thin coat on the plasma membrane of epithelial cells; the ECM was in contact with this coat. In contrast, the blastocoelic ECM attached directly to the plasma membrane of primary mesenchyme cells (PMC) which did not possess a basal lamina. The blastocoelic ECM was isolated as an intact "bag" and probed in a hydrated state with Con A and alcian blue. Confocal microscopy confirmed that the entire blastocoel was filled with a fibrillar ECM. These approaches offer advantages for future studies of the ECMs of sea urchin embryos and their roles in gastrulation.

Characterization of sea urchin primary mesenchyme cells and spicules during biomineralization in vitro.

An in vitro culture system for primary mesenchyme cells of the sea urchin embryo has been used to study the cellular characteristics of skeletal spicule formation. As judged initially by light microscopy, these cells attached to plastic substrata, migrated and fused to form syncytia in which mineral deposits accumulated in the cell bodies and in specialized filopodial templates. Subsequent examination by scanning electron microscopy revealed that the cell bodies and the filopodia and lamellipodia formed spatial associations similar to those seen in the embryo and indicated that the spicule was surrounded by a membrane-limited sheath derived by fusion of the filopodia. The spicules were dissolved from living or fixed cells by a chelator of divalent cations or by lowering the pH of the medium. However, granular deposits found in the cell bodies appeared relatively refractory to such treatments, indicating that they were inaccessible to agents that dissolved the spicules. Use of rapid freezing and an anhydrous fixative to preserve the syncytia for transmission electron microscopy and X-ray microprobe analysis, indicated that electron-dense deposits in the cell bodies contain elements (Ca, Mg and S) common to the spicule. Examination of the spicule cavity after dissolution of the spicule mineral revealed openings in the filopodia-derived sheath, coated pits within the limiting membrane and a residual matrix that stained with ruthenium red. Concanavalin A--gold applied exogenously entered the spicule cavity and bound to matrix glycoproteins. Based on these observations, we conclude that components of the spicule initially are sequestered intracellularly and that spicule elongation occurs in an extracellular cavity. Ca2+ and associated glycoconjugates may be routed in this cavity via a secretory pathway.