Motoneurons In Zebrafish Research Articles

Lateral specification of cell fate during vertebrate development

Cells within equivalence groups interact via lateral specification to determine cell fates during development in Caenorhabditis elegans and other invertebrates. Populations of cells within the developing zebrafish have features similar to those of invertebrate equivalence groups. In a simple example, two identified zebrafish motoneurons behave as an equivalence pair in which one cell adopts a primary fate and interactions between the cells assign the other cell to a secondary fate. A more complicated situation exists for two initially equivalent populations of zebrafish neural crest cells. We consider whether mechanisms similar to those involved in fate specification within invertebrate equivalence groups also function furing fate specification in vertebrates.

Pathfinding by zebrafish motoneurons in the absence of normal pioneer axons.

Individually identified primary motoneurons of the zebrafish embryo pioneer cell-specific peripheral motor nerves. Later, the growth cones of secondary motoneurons extend along pathways pioneered by primary motor axons. To learn whether primary motor axons are required for pathway navigation by secondary motoneurons, we ablated primary motoneurons and examined subsequent pathfinding by the growth cones of secondary motoneurons. We found that ablation of the primary motoneuron that pioneers the ventral nerve delayed ventral nerve formation, but a normal-appearing nerve eventually formed. Therefore, the secondary motoneurons that extend axons in the ventral nerve were able to pioneer that pathway in the absence of the pathway-specific primary motoneuron. In contrast, in the absence of the primary motoneuron that normally pioneers the dorsal nerve, secondary motoneurons did not pioneer a nerve in the normal location, instead they formed dorsal nerves in an atypical position. This difference in the ability of these two groups of motoneurons to pioneer their normal pathways suggests that the guidance rules followed by their growth cones may be very different. Furthermore, the observation that the atypical dorsal nerves formed in a consistent incorrect location suggests that the growth cones of the secondary motoneurons that extend dorsally make hierarchical pathway choices.