Primary Invagination of the Vegetal Plate During Sea Urchin Gastrulation

The initial phase of echinoid gastrulation, primary invagination,involves an inpocketing of a monolayered epithelium. To gaininformation about the nature of the mechanical forces that areresponsible for primary invagination, several experimental approacheshave been taken, using the transparent embryos of the sea urchin,Lytechinus pictus, as the principal material. Vegetal platesisolated microsurgically well before the onset of gastrulationwill invaginate normally, demonstrating that the forces responsiblefor primary invagination are generated by the cells in the vegetal to of the embryo. As shown by serial reconstructions of L.pictus embryos, relatively few cells (about 100) take part inprimary invagination. Both the number of cells and the totalvolume of tissue in the wall of the archenteron increase withtime. Even so, it can be shown that very little movement ofcells over the lip of the blastopore takes place during primaryinvagination, and this process is best viewed as a simple inpocketingof the vegetal epithelium. The cells in the wall of the archenteronhave a distinctive shape; they are elongated along their apico-basalaxes and frequently have enlarged, rounded, basal ends. However,they do not undergo any dramatic changes in shape during primaryinvagination. In particular, there is only a slight decreasein the height of the cells (length along the apico-basal axis),a result that is inconsistent with the hypothesis that invaginationis due to cell rounding (Gustafson and Wolpert, 1967). Examinationof L. pictus and Strongylocentrotus purpuratus gastrulae bytransmission electron microscopy reveals that cells in the wallof the archenteron continue to be joined by typical junctionalcomplexes during primary invagination. In addition, the morphologyof the junctional complex at the gastrula stage is more elaboratethan previously described. Sparse bands of micronlaments areassociated with the plasma membrane at the level of the junctionalcomplexes in both endodermal and ectodermal cells. These andother relevant data on early echinoid gastrulation are discussedin relation to several possible mechanisms of epithelial morphogenesis.