Lack of Sod1 induces disruption of innervation accompanied by Schwann cell proliferation in skeletal muscle

The neuromuscular junction (NMJ) is an excitatory synapse that constitutes the primary site of communication between the nervous system and skeletal muscle and therefore any degenerative changes at the NMJ have the potential to impair muscle function. The primary cellular components of the NMJ are the motor neuron, the muscle fiber and terminal Schwann cells (tSC) that surround the NMJ. The importance of redox homeostasis for the maintenance of NMJ integrity is supported by work from our group showing degenerative changes at NMJs in mice lacking copper zinc superoxide dismutase (CuZnSOD; Sod1 -/- ) as early as 4 months of age. Prior work from others suggests that tSCs contribute trophic support for the NMJ and facilitate motor unit remodeling, but changes in tSC structure and function under conditions of elevated oxidative stress have not been thoroughly explored. Using in vitro assays, we previously showed that primary Schwann cells treated with a sublethal dose of the reactive oxygen species inducing agent Paraquat (PQ) resulted in increased Schwann cell number, ki67+ staining, and gene expression of trophic factors and the critical NMJ organizing protein Agrin. Furthermore, differentiated C2C12 myotubes treated with conditioned media from PQ treated Schwann cell cultures showed increased number of acetylcholine receptor (AChR) plaques. The goal of the current study was to characterize NMJs in young Sod1 -/- mice (2-months) to determine the early effects of elevated oxidative stress on NMJ structure in vivo with a specific focus on tSCs. We hypothesized that loss of Sod1 would lead to aberrant tSC and NMJ structure associated with decreased muscle function. We assessed maximum isometric force, NMJ morphology, and number of Schwann cells in gastrocnemius muscles of WT (n = 3) and Sod1 -/- (n = 3) mice. In Sod1 -/- mice, muscle force was reduced by 26% ( p = 2e-4) with nerve stimulation compared to direct muscle stimulation, and overlap between motor nerve terminals and AChRs was reduced by nearly 60% compared to WT controls. Post-synaptic AChR area was increased by 37% in Sod1 -/- mice, and tSC area and numbers per NMJ were increased by 60% and 155%, respectively in Sod1 -/- mice. Finally, Schwann cells proximal to NMJs showed increased Ki67+ labeling in Sod1 -/- mice compared to WT mice. This analysis demonstrates that early changes in both pre- and post-synaptic NMJ components and reduced neurotransmission due to loss of Sod1 are associated with marked increases in tSC proliferation. Our data implicate a protective role of muscle-resident Schwann cells in preserving NMJ integrity in response to alterations in redox homeostasis that may be mediated in part through activation and proliferation of these cells. These findings indicate that further investigation of the dynamics between Schwann cells and NMJ function is important to increase understanding of neuromuscular degenerativeconditions that involve altered redox homeostasis such as sarcopenia. Supported by the University of Michigan Medical School Office of Research, the American Physiological Society, and NIH AR069620. This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.