A Role for the Planar Cell Polarity Pathway in Neuronal Positioning Along the AP Axis of C. elegans.

Abstract

We sought to investigate the role of the Planar Cell Polarity (PCP) pathway in neuronal positioning along the Anterior-Posterior (AP) axis of C. elegans, and chose the worm’s DD-type motor neurons as a model. The six DD neurons (DD1-DD6) are evenly spaced in the ventral nerve cord of wild type animals. Here we showed that mutations in core PCP genes caused DD neuron spacing and positioning defects. prkl-1 double mutant combinations with vang-1 and fmi-1 showed a suppression of the more severe prkl-1 single mutant defects, which was evidence of genetic interactions between these PCP components. We also conducted a candidate screen of Frizzled, Dishevelled, Wnt, and ROCK genes, and found that dsh-1/Dishevelled, mom-2/Wnt and let-502/ROCK also played roles in DD neuronal positioning. Both vang-1 and prkl-1 were found to function within the nervous system to guide DD neuronal positioning, and prkl-1 was further identified as playing a cell autonomous role. The origins of observed DD neuron anterior positioning defects were investigated during embryogenesis, in which 1.5 fold stage prkl-1(ok3182) embryos displayed delayed intercalation of the DD neurons. This represents a novel role for the PCP pathway in mediating DD neuronal intercalation.