Abstract
Charcot-Marie-Tooth (CMT) is the most common hereditary peripheral neuropathy with an incidence of 1:2,500. CMT2 clinical symptoms include distal muscle weakness and atrophy, sensory loss, toe and foot deformities, with some patients presenting with reduced nerve conduction velocity. Mutations in the neurofilament light chain (NEFL) gene result in a specific form of CMT2 disease, CMT2E. NEFL encodes the protein, NF-L, one of the core intermediate filament proteins that contribute to the maintenance and stability of the axonal cytoskeleton. To better understand the underlying biology of CMT2E disease and advance the development of therapeutics, we generated a Nefl (+/E397K) mouse model. While the Nefl (+/E397K) mutation is inherited in a dominant manner, we also characterized Nefl (E397K/E397K) mice to determine whether disease onset, progression or severity would be impacted. Consistent with CMT2E, lifespan was not altered in these novel mouse models. A longitudinal electrophysiology study demonstrated significant in vivo functional abnormalities as early as P21 in distal latency, compound muscle action potential (CMAP) amplitude and negative area. A significant reduction in the sciatic nerve axon area, diameter, and G-ratio was also present as early as P21. Evidence of axon sprouting was observed with disease progression. Through the twelve months measured, disease became more evident in all assessments. Collectively, these results demonstrate an early and robust in vivo electrophysiological phenotype and axonal pathology, making Nefl (+/E397K) and Nefl (E397K/E397K) mice ideal for the evaluation of therapeutic approaches.