Development of inhibition by ephrin-A5 on outgrowth of embryonic spinal motor neurites

Abstract

The spinal motor pool maps systematically onto the surface of muscles. This map is detectable in rat embryonic muscles, and is partially restored after reinnervation. Recent evidence shows that either overexpression or deletion of the ephrin-A5 gene significantly disrupts the map, suggesting that ephrin-A5 plays a critical role in the formation of this topography. Several studies have demonstrated that ephrin-A5 is a repulsive molecule in the nervous system, including the neuromuscular system. To examine the development of sensitivity of ventral spinal axons to this inhibitory ligand, slices of E11 to E15 embryonic rat spinal cords were cocultured with membranes derived from ephrin-A5-expressing cell lines. We detected a progressive expression of inhibition by ephrin-A5 between E11 and E15. By E15, rostral and caudal spinal neurites showed clear differences in responsiveness to the ephrin-A5 ligand. Further, we found that at this age caudal neurites are more sensitive to changes of ephrin-A5 concentration along a gradient. In addition, growth cones of caudal, more than rostral, neurites tended to assume a collapsed shape in the presence of the ligand. These results demonstrate a progressive development of sensitivity to ephrin-A5, and suggest a divergence in this sensitivity between rostral and caudal spinal cord neurites. These results provide further insight into how subtle rostrocaudal differences in the development of sensitivity to ephrin-A5 may explain, in part, neuromuscular topography.