Skeletal muscle denervation investigations: selecting an experimental control wisely
Files
Published version
Date
2019-03-01
Authors
Liu, Haiming
Thompson, LaDora V.
Version
Published version
OA Version
Citation
Haiming Liu, LaDora V. Thompson. 2019. "Skeletal muscle denervation investigations: selecting an experimental control wisely.." Am J Physiol Cell Physiol, Volume 316, Issue 3, pp. C456 - C461. https://doi.org/10.1152/ajpcell.00441.2018
Abstract
Unilateral denervation is widely used for studies investigating mechanisms of muscle atrophy. The "contralateral-innervated muscle" is a commonly used experimental control in denervation studies. It is not clear whether denervation unilaterally alters the proteolytic system in the contralateral-innervated muscles. Therefore, the objectives of this rapid report are 1) to determine whether unilateral denervation has an effect on the proteolytic system in contralateral-innervated control muscles and 2) to identify the changes in proteasome properties in denervated muscles after 7- and 14-day tibial nerve transection with either the contralateral-innervated muscles or intact muscles from nonsurgical mice used as the experimental control. In the contralateral-innervated muscles after 7 and 14 days of nerve transection, the proteasome activities and content are significantly increased compared with muscles from nonsurgical mice. When the nonsurgical mice are used as the experimental control, a robust increase in proteasome properties is found in the denervated muscles. This robust increase in proteasome properties is eliminated when the contralateral-innervated muscles are the experimental control. In conclusion, there is a crossover effect from unilateral denervation on proteolytic parameters. As a result, the crossover effect on contralateral-innervated muscles must be considered when an experimental control is selected in a denervation study.
Description
License
Copyright © 2019 the American Physiological Society. Licensed under Creative Commons Attribution CC-BY 4.0 : © the American Physiological Society.