Publication

Motor terminal degeneration unaffected by activity changes in SOD1G93A mice; a possible role for glycolysis

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Last modified
  • 02/20/2025
Type of Material
Authors
    Dario Carrasco, Emory UniversityEdyta K. Bichler, Morehouse UniversityMark M. Rich, Wright State UniversityXueyong Wang, Wright State UniversityKevin L. Seburn, The Jackson LaboratoryMartin J. Pinter, Emory University
Language
  • English
Date
  • 2012-10
Publisher
  • Elsevier: 12 months
Publication Version
Copyright Statement
  • © 2012 Elsevier Inc. All rights reserved.
License
Final Published Version (URL)
Title of Journal or Parent Work
ISSN
  • 0969-9961
Volume
  • 48
Issue
  • 1
Start Page
  • 132
End Page
  • 140
Grant/Funding Information
  • This work was supported by NIH grant NS31621 (MJP).
Abstract
  • This study examined whether activity is a contributing factor to motor terminal degeneration in mice that overexpress the G93A mutation of the SOD1 enzyme found in humans with inherited motor neuron disease. Previously, we showed that overload of muscles accomplished by synergist denervation accelerated motor terminal degeneration in dogs with hereditary canine spinal muscular atrophy (HCSMA). In the present study, we found that SOD1 plantaris muscles overloaded for 2 months showed no differences of neuromuscular junction innervation status when compared with normally loaded, contralateral plantaris muscles. Complete elimination of motor terminal activity using blockade of sciatic nerve conduction with tetrodotoxin cuffs for 1 month also produced no change of plantaris innervation status. To assess possible effects of activity on motor terminal function, we examined the synaptic properties of SOD1 soleus neuromuscular junctions at a time when significant denervation of close synergists had occurred as a result of natural disease progression. When examined in glucose media, SOD1 soleus synaptic properties were similar to wildtype. When glycolysis was inhibited and ATP production limited to mitochondria, however, blocking of evoked synaptic transmission occurred and a large increase in the frequency of spontaneous mEPCs was observed. Similar effects were observed at neuromuscular junctions in muscle from dogs with inherited motor neuron disease (HCSMA), although significant defects of synaptic transmission exist at these neuromuscular junctions when examined in glucose media, as reported previously. These results suggest that glycolysis compensates for mitochondrial dysfunction at motor terminals of SOD1 mice and HCSMA dogs. This compensatory mechanism may help to support resting and activity-related metabolism in the presence of dysfunctional mitochondria and prolong the survival of SOD1 motor terminals.
Author Notes
  • Correspondence: Martin J. Pinter, Department of Physiology, Emory University School of Medicine, 615 Michael St., Atlanta, GA 30322; Voice: 404-727-3472; Fax: 404-727-2648; Email: mpinter@emory.edu
Keywords
Research Categories
  • Biology, Neuroscience

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