Effect of proximal axotomy on GAP-43 expression in cortical neurons in the mouse

Abstract

As an approach to understanding why central neurons fail to regenerate, we have studied the response to proximal axotomy of transcallosal neurons of the cerebral cortex of the mouse. Anatomical studies have indicated only very slight regenerative responses by this population of cortical neurons. To further examine the regenerative response of these cells, we have looked by in situ hybridization at the expression of GAP-43 mRNA following axotomy caused by a stab wound delivered within about 200 μm to 1.25 mm of the cell body. Axotomized transcallosal neurons were compared with near-by unaxotomized transcallosal neurons, as well as with distant unaxotomized cortical neurons in the contralateral hemisphere. All three populations of neurons had been pre-labeled with Fluoro-Gold to allow identification. No up-regulation of GAP-43 mRNA above background levels was detected for axotomized cortical neurons at 1, 3 or 7 days after injury. In contrast, increases in mean silver grain density of up to 8-fold were measured in axotomized spinal cord motor neurons used as positive controls. Thus, as a population, the transcallosal cortical pyramidal neurons did not show a significant regenerative response, as monitored by GAP-43 upregulation, even with very close axotomy. These results identify this population of neurons as among the least regenerative studied, and suggest that, on a molecular level, inherent neuronal properties play a role in the limited regenerative response to brain injury.