CONTROL OF NEURAL CREST CELL DISPERSION IN THE TRUNK OF THE AVIAN EMBRYO

Many hypotheses have been advanced to explain the orientation and directional migration of neural crest cells. These include positive and negative chemotaxis, haptotaxis, galvanotaxis, and contact inhibition. To test directly the factors that may control the directional dispersion of the neural crest, I have employed a variety of grafting techniques in living embryos. In addition, time-lapse video microscopy has been used to study neural crest cells in tissue culture. Trunk neural crest cells normally disperse from their origin at the dorsal neural tube along two extracellular pathways. One pathway extends laterally between the ectoderm and somites. When either pigmented neural crest cells or neural crest cells isolated from 24-hr cultures are grafted into the space lateral to the somites, they migrate: (1) medially toward the neural tube in the space between the ectoderm and somites and (2) ventrally along intersomitic blood vessels. Once the grafted cells contact the posterior cardinal vein and dorsal aorta they migrate along both blood vessels for several somite lengths in the anterior-posterior axis. Neural crest cells grafted lateral to the somites do not immediately move laterally into the somatic mesoderm of the body wall or the limb. Dispersion of neural crest cells into the mesoderm occurs only after blood vessels and nerves have first invaded, which the grafted cells then follow. The other neural crest pathway extends ventrally alongside the neural tube in the intersomitic space. When neural crest cells were grafted to a ventral position, between the notochord and dorsal aorta, in this intersomitic pathway at the axial level of the last somite, the grafted cells migrate rapidly within 2 hr in two directions: (1) dorsally, in the intersomitic space, until the grafted cells contact the ventrally moving stream of the host neural crest and (2) laterally, along the dorsal aorta and endoderm. All of the above experiments indicate that neither a preestablished chemotactic nor adhesive (haptotactic) gradient exists in the embryo since the grafted neural crest cells will move in the reverse direction along these pathways toward the dorsal neural tube. For the same reason, these experiments also show that dispersal of the neural crest is not directed passively by other environmental controls, since the cells can clearly move counter to their usual pathway and against such putative passive mechanisms. Although the dispersion of grafted neural crest cells becomes channeled by blood vessels and structures such as the somites and neural tube, their initial radial pattern suggests that dispersal is driven by contact among the cells. Tissue culture studies demonstrate that neural crest cells display contact paralysis when two lamellipodia touch each other. The best explanation for the dispersal of the neural crest in the embryo, therefore, is contact inhibition.