Older Mice Show Decreased Regeneration of Neuromuscular Junctions Following Lengthening‐Contraction Injury

Abstract

Progressive muscle atrophy and loss of muscle strength associated with old age have been well documented. Although impairments in the ability of old mice to regenerate skeletal muscle following injury have been demonstrated, less is known about the way age modulates the regenerative response of motor neurons and the neuromuscular junctions (NMJ) of mice following contraction‐induced injury. The inability for NMJs to effectively regenerate following an injury could lead to the death of the denervated muscle fibers and therefore play a contributing role to age‐related sarcopenia. To investigate the relationship between age and NMJ regeneration following injury, extensor digitorum longus (EDL) muscles of adult (8‐9 months), middle‐aged (18‐19 months), and old mice (27‐28 months) were subjected to a protocol of repeated lengthening‐contractions that resulted in an acute force deficit of ~70%. After 28 days, muscles were evaluated for maximum force generating capacity, muscle mass, NMJ innervation, and endplate fragmentation. Cross sections of muscles taken at three days post injury showed extensive infiltration of mononuclear cells and widespread tissue disruption consistent with the induction of severe injury to the muscles. At 28 days, maximum isometric force recovered completely in adult mice, but was significantly reduced in middle aged and old mice when compared to muscles of adult mice. In each case, approximately 29% of fibers in the cross sections displayed containing central nuclei, whereas controls showed only 2.9%, indicating that the injured muscle fibers had undergone degeneration and regeneration. Analysis of the innervation of the NMJs in the regenerated muscles showed a moderate decrease in the number of fully innervated endplates in old mice as compared to adult and middle‐aged mice. When the architecture of the endplates in regenerated muscles was examined, the relative number of NMJs with intact postsynaptic structure varied little between the age groups, although control muscles of old mice showed an increase in the number of fragmented endplates compared with the adult and middle aged mice. Thus, the diminished ability of the skeletal muscle of old mice to recover following injury may be, in part, due to an age‐related decrease in the ability to adequately regenerate motor neurons and perhaps form NMJs in the injured muscle.