Effect of Changes in Neurofilament Content on Caliber of Small Axons: The ,B,fl-lminodipropionitrile Model

The structural role of neurofilaments in the normal axon and the consequences of altered axonal transport of neurofilaments have been extensively studied in large axons. These studies suggest that neurofilament numbers and interneurofilament spacing are major determinants of axonal crosssectional area. In contrast, in small axons and dendrites, microtubules and membranous organelles appear to be the most closely correlated with size and shape of the cell process. In this study we have examined the effect of impairment in neurofilament transport on small axons, typical of most CNS pathways. Neurofilament transport was impaired by administration of &3’-iminodipropionitrile (IDPN), resulting in proximal accumulation and distal depletion of neurofilaments. The evolution of these changes was studied in the optic nerves of guinea pigs treated with IDPN, 1-35 weeks following intoxication. The effect of this redistribution of neurofilaments on cross-sectional area of small axons was evaluated using quantitative ultrastructural methods. Our results show that with the alteration in neurofilament transport seen with IDPN intoxication, there is a wide spectrum of neurofilament densities, ranging from a B-fold increase above normal in the proximal axon, to a B-fold decrease below normal in the distal axon. Although the optic nerve fibers enlarge with the increase in neurofilament content, they do not atrophy significantly with the continued loss of neurofilaments. We conclude that factors other than neurofilament content are capable of maintaining size and shape of these small axons. Candidate organelles include microtubules and membranous organelles and possibly other axonal elements.