Characterizing immune-mediated neuronal microtubule destabilization and axonal transport defects in a mouse model of optic neuritis

Abstract

Abstract Multiple sclerosis (MS) is a central nervous system autoimmune disease that often presents with inflammation of the optic nerve, optic neuritis (ON). The mechanisms of neuronal damage in MS and ON are unknown. In vitro studies modeling MS neurodegeneration demonstrated that cytolytic lymphocytes drive microtubule destabilization in human induced pluripotent stem cell-derived spinal motor neurons. Microtubules are essential for axonal transport, a key function for neuron health. We hypothesize that immune-mediated neuronal microtubule destabilization drives development of ON through disruption of axonal transport. MOG35-55 T cell receptor transgenic mice were used as a model of ON. The non-invasive ophthalmologic technique optical coherence tomography (OCT) allows for confirmation of symptomatic ON. Using OCT, increasing severity of progressive ON was observed over 5 months. To examine transport efficiency, cholera toxin subunit B (CTB), an axonal transport tracer, was injected into the eyes of mice with ON. Optic nerves were collected and stained for β3-tubulin, a marker of microtubules, and imaged by immunofluorescence. Preliminary data found decreased β3-tubulin staining and markedly reduced CTB transport in the presence of immune cell infiltration in mice with ON. These data confirm that OCT can be used to monitor ON progression and provide evidence that immune-mediated neuronal microtubule destabilization causes axonal transport deficits that underly ON development.