Alterations in slow transport kinetics induced by estramustine phosphate, an agent binding to microtubule-associated proteins

Abstract

Estramustine phosphate (EP) disassembles microtubules by binding to microtubule-associated proteins (MAPs) rather than tubulin. In this study, EP-induced alterations of MAP integrity caused a unique form of axonal atrophy in rats. Initially, EP-induced axonal atrophy occurred in both proximal and distal axons of the sciatic nerve, characterized by an increase in neurofilament packing density, associated with a decrease in axonal area. In chronic exposure, distal axonal atrophy was associated with decreased numbers of microtubules, while the neurofilament number remained unaltered for the myelin spiral length. Continued exposure caused enlargement of proximal axons associated with an increase in neurofilament content. Correlative slow transport studies done at two different times, 7 and 14 days after [35S] methionine injection showed that EP retards the transport of cytoskeletal proteins migrating with both components of slow transport (SCa and SCb). However, there was a differential effect on SCb which showed progressive slowing along the nerve while the rate of SCa stayed relatively constant. In this model, the early occurring distal axonal atrophy can best be explained by reduced cytoskeletal components, particularly those traveling in SCb. Later in the course of intoxication, a relatively constant rate of SCa permitted continuous transport of neurofilament triplets, accounting for unaltered numbers of neurofilaments in distal axons with increased packing density. This model of axonal atrophy is unique because spacing of neurofilaments, not numbers determined axon size. Furthermore, EP-induced dissociation of the SCa and SCb kinetics suggests that MAPs play a role in the orderly, cohesive migration of slow transport components, essential for the normal organization of cytoskeleton.