Migration-Directing Liquid Properties of Embryonic Amphibian Tissues

Deep ectoderm, mesoderm and endoderm excised from gastrulatingamphibian embryos spontaneously undergo liquid-like movementsin organ culture. Cell populations of these tissues on nonadhesivesubstrata will round up into spheres, spread over one anotherand segregate (sort out) from one another just as immiscibleliquid droplets do. In ordinary liquids, movements like theseare controlled by surface tensions; perhaps surface tensionsalso control the similar movements of liquid-like tissues. Onenecessary condition for tissue surface tension analysis is thatthe tissue must be able (just as ordinary liquids are able)to spontaneously relax internal stretching forces (shear stresses).When cellular aggregates of the germ layers were deformed bygentle compression between parallel glass plates, cells withinthe aggregates were initially stretched. However, the cellssoon returned to their original undistorted shapes. Thus, cellstretching forces were gradually relaxed by cell rearrangements.The in vitro spreading movements of the deep germ layers implythat the surface tension of ectoderm should be greater thanthe surface tension of mesoderm which should be greater thanthe surface tension of endoderm. Quantitative measurements oftissue surface tensions made by parallel plate compression confirmprecisely that relationship. Furthermore, the surface tensionsof these tissues remain constant regardless of the amount ofaggregate flattening—another necessary condition for validsurface tension measurements. These results demonstrate thatamphibian deep germ layers possess fundamental liquid propertieswhich are sufficient to direct their liquid-like rearrangementsin organ culture. Furthermore, I also report that one of theseproperties, surface tension, displays a preliminary correlationwith density of cell surface charge (assessed by electrophoreticmobility) and with the onset of in vivo mesodermal involution.