Aging alters mechanisms underlying voluntary movements in spinal motor neurons of mice, primates, and humans
Ryan W. Castro, … , Robert E. Settlage, Gregorio Valdez
Ryan W. Castro, … , Robert E. Settlage, Gregorio Valdez
Published May 8, 2023
Citation Information: JCI Insight. 2023;8(9):e168448. https://doi.org/10.1172/jci.insight.168448.
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Research Article Aging Neuroscience

Aging alters mechanisms underlying voluntary movements in spinal motor neurons of mice, primates, and humans

Abstract

Spinal motor neurons have been implicated in the loss of motor function that occurs with advancing age. However, the cellular and molecular mechanisms that impair the function of these neurons during aging remain unknown. Here, we show that motor neurons do not die in old female and male mice, rhesus monkeys, and humans. Instead, these neurons selectively and progressively shed excitatory synaptic inputs throughout the soma and dendritic arbor during aging. Thus, aged motor neurons contain a motor circuitry with a reduced ratio of excitatory to inhibitory synapses that may be responsible for the diminished ability to activate motor neurons to commence movements. An examination of the motor neuron translatome (ribosomal transcripts) in male and female mice reveals genes and molecular pathways with roles in glia-mediated synaptic pruning, inflammation, axonal regeneration, and oxidative stress that are upregulated in aged motor neurons. Some of these genes and pathways are also found altered in motor neurons affected with amyotrophic lateral sclerosis (ALS) and responding to axotomy, demonstrating that aged motor neurons are under significant stress. Our findings show mechanisms altered in aged motor neurons that could serve as therapeutic targets to preserve motor function during aging.

Authors

Ryan W. Castro, Mikayla C. Lopes, Robert E. Settlage, Gregorio Valdez

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Figure 1

Motor neuron numbers and sizes are stable in aged spinal cords.

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Motor neuron numbers and sizes are stable in aged spinal cords. (A–D) Re...
(AD) Representative images of α-motor neurons in young adult (top row) and aged (bottom row) mouse spinal cords. (A and B) NeuN and VAChT IHC in males. (C and D) Transgenic tdTomato labeled motor neurons in Chat-Cre;tdTomato males. (E) Motor neuron density in lumbar spinal cord of male mice based on multiple methods of α-motor neuron labeling, including NeuN and VAChT IHC, ChT IHC, Chat in situ hybridization, and transgenic tdTomato expression in Chat-Cre;tdTomato mice. (F) Cross-sectional area (CSA) of α-motor neuron soma based on NeuN and VAChT IHC, ChT IHC, and Chat-Cre;tdTomato labeling in male mouse lumbar spinal cord. (G) Distribution of α-motor neuron CSAs in male mouse lumbar spinal cord. (H) Volume of tdTomato-labeled α-motor neurons in male Chat-Cre;tdTomato lumbar spinal cord. Unpaired, 2-sided t test used for all comparisons except G, where a Kolmogorov-Smirnov test was used. *P < 0.05 versus young. All values except G presented as mean ± SEM; n = 3. Scale bar: 20 μm.