Expression of the repulsive guidance molecule RGM and its receptor neogenin after spinal cord injury in sea lamprey.

The sea lamprey recovers normal-appearing locomotion after spinal cord transection and its spinal axons regenerate selectively in their correct paths. However, among identified reticulospinal neurons some are consistently bad regenerators and only about 50% of severed reticulospinal axons regenerate through the site of injury. We previously suggested (Shifman, M. I., and Selzer, M. E., 2000a. Expression of netrin receptor UNC-5 in lamprey brain; modulation by spinal cord transection. Neurorehabilitation and Neural Repair 14, 49-58; Shifman, M. I., and Selzer, M. E., 2000b. In situ hybridization in wholemounted lamprey spinal cord: localization of netrin mRNA expression. Journal of Neuroscience Methods 104, 19-25) that selective chemorepulsion might explain why some neurons are bad regenerators and others not. To explore the role of additional chemorepulsive axonal guidance molecules during regeneration, we examined the expression of the repulsive guidance molecule (RGM) and its receptor neogenin by in situ hybridization and quantitative PCR. RGM mRNA was expressed in the spinal cord, primarily in neurons of the lateral gray matter and in dorsal cells. Following spinal cord transection, RGM message was downregulated in neurons close (within 10 mm) to the transection at 2 and 4 weeks, although it was upregulated in reactive microglia at 2 weeks post-transection. Neogenin mRNA expression was unchanged in the brainstem after spinal cord transection, and among the identified reticulospinal neurons, was detected only in "bad regenerators", neurons that are known to regenerate well never expressed neogenin. The downregulation of RGM expression in neurons near the transection may increase the probability that regenerating axons will regenerate through the site of injury and entered caudal spinal cord.