Lectin uptake and incorporation into the calcitic spicule of sea urchin embryos.

Primary mesenchyme cells (PMCs) are skeletogenenic cells that produce a calcareous endoskeleton in developing sea urchin larvae. The PMCs fuse to form a cavity in which spicule matrix proteins and calcium are secreted forming the mineralized spicule. In this study, living sea urchin embryos were stained with fluorescently conjugated wheat germ agglutinin, a lectin that preferentially binds to PMCs, and the redistribution of this fluorescent tag was examined during sea urchin development. Initially, fluorescence was associated primarily with the surface of PMCs. Subsequently, the fluorescent label redistributed to intracellular vesicles in the PMCs. As the larval skeleton developed, intracellular granular staining diminished and fluorescence appeared in the spicules. Spicules that were cleaned to remove membranous material associated with the surface exhibited bright fluorescence, which indicated that fluorescently labelled lectin had been incorporated into the spicule matrix. The results provide evidence for a cellular pathway in which material is taken up at the cell surface, sequestered in intracellular vesicles and then incorporated into the developing spicule.

Septate junctions mediate the barrier to paracellular permeability in sea urchin embryos.

In sea urchin embryos, blastula formation occurs between the seventh and tenth cleavage and is associated with changes in the permeability properties of the epithelium although the structures responsible for mediating these changes are not known. Tight junctions regulate the barrier to paracellular permeability in chordate epithelia; however, the sea urchin blastula epithelium lacks tight junctions and instead possesses septate junctions. Septate junctions are unique to non-chordate invertebrate cell layers and have a characteristic ladder-like appearance whereby adjacent cells are connected by septa. To determine the function of septate junctions in sea urchin embryos, the permeability characteristics of the embryonic sea urchin epithelia were assessed. First, the developmental stage at which a barrier to paracellular permeability arises was examined and found to be in place after the eighth cleavage division. The mature blastula epithelium is impermeable to macromolecules; however, brief depletion of divalent cations renders the epithelium permeable. The ability of the blastula epithelium to recover from depletion of divalent cations and re-establish a barrier to paracellular permeability using fluorescently labelled lectins was also examined. Finally, septate junction structure was examined in embryos in which the permeability status of the epithelium was known. The results provide evidence that septate junctions mediate the barrier to paracellular permeability in sea urchin embryos.

Localization of cortical granule lectin ligand in Xenopus laevis egg jelly.

The block to polyspermy in Xenopus laevis involves an interaction between a cortical granule lectin, released at fertilization, and a ligand located in the egg extracellular matrix. The egg extracellular matrix in X. laevis consists of a vitelline envelope and three distinct jelly layers, designated J1, J2 and J3. To localize cortical granule lectin ligand in the egg extracellular matrix, we used enzyme-linked lectin assays that showed that cortical granule lectin ligands were absent in J2, J3 and the vitelline envelope. Cortical granule lectin bound to a ligand(s) in J1 in a galactose-dependent fashion. In addition, we separated egg jelly macromolecules electrophoretically and, in conjunction with western blotting, have shown that J1 contains two major, high molecular weight ligands for cortical granule ligand. Finally, using confocal microscopy, we demonstrated that the ligand(s) for cortical granule lectin occupies a 20-30 µm thick band in a region of J1 just proximal to the vitelline envelope.