Absence of physiological Ca2+ transients is an initial trigger for mitochondrial dysfunction in skeletal muscle following denervation

Absence of physiological Ca2+ transients is an initial trigger for mitochondrial dysfunction in skeletal muscle following denervation

Abstract Background Motor neurons control muscle contraction by initiating action potentials in muscle. Denervation of muscle from motor neurons leads to muscle atrophy, which is linked to mitochondrial dysfunction. It is known that denervation promotes mitochondrial reactive oxygen species (ROS) pr...

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Main Authors: Chehade Karam, Jianxun Yi, Yajuan Xiao, Kamal Dhakal, Lin Zhang, Xuejun Li, Carlo Manno, Jiejia Xu, Kaitao Li, Heping Cheng, Jianjie Ma, Jingsong Zhou
Format: Article
Language:English
Published: BMC 2017-04-01
Series:Skeletal Muscle
Subjects:
E-C coupling
Calcium imaging
Calcium signaling
Calcium intracellular release
Denervation
Mitochondria
Online Access:http://link.springer.com/article/10.1186/s13395-017-0123-0
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spelling doaj-c627b64ab41a4880b38c587fb973f9f52020-11-24T22:01:42ZengBMCSkeletal Muscle2044-50402017-04-017111810.1186/s13395-017-0123-0Absence of physiological Ca2+ transients is an initial trigger for mitochondrial dysfunction in skeletal muscle following denervationChehade Karam0Jianxun Yi1Yajuan Xiao2Kamal Dhakal3Lin Zhang4Xuejun Li5Carlo Manno6Jiejia Xu7Kaitao Li8Heping Cheng9Jianjie Ma10Jingsong Zhou11Rush University School of MedicineRush University School of MedicineRush University School of MedicineKansas City University of Medicine and BioscienceRush University School of MedicineKansas City University of Medicine and BioscienceRush University School of MedicineInstitute of Molecular Medicine, Peking UniversityInstitute of Molecular Medicine, Peking UniversityInstitute of Molecular Medicine, Peking UniversityWexner Medical Center, The Ohio State UniversityRush University School of MedicineAbstract Background Motor neurons control muscle contraction by initiating action potentials in muscle. Denervation of muscle from motor neurons leads to muscle atrophy, which is linked to mitochondrial dysfunction. It is known that denervation promotes mitochondrial reactive oxygen species (ROS) production in muscle, whereas the initial cause of mitochondrial ROS production in denervated muscle remains elusive. Since denervation isolates muscle from motor neurons and deprives it from any electric stimulation, no action potentials are initiated, and therefore, no physiological Ca2+ transients are generated inside denervated muscle fibers. We tested whether loss of physiological Ca2+ transients is an initial cause leading to mitochondrial dysfunction in denervated skeletal muscle. Methods A transgenic mouse model expressing a mitochondrial targeted biosensor (mt-cpYFP) allowed a real-time measurement of the ROS-related mitochondrial metabolic function following denervation, termed “mitoflash.” Using live cell imaging, electrophysiological, pharmacological, and biochemical studies, we examined a potential molecular mechanism that initiates ROS-related mitochondrial dysfunction following denervation. Results We found that muscle fibers showed a fourfold increase in mitoflash activity 24 h after denervation. The denervation-induced mitoflash activity was likely associated with an increased activity of mitochondrial permeability transition pore (mPTP), as the mitoflash activity was attenuated by application of cyclosporine A. Electrical stimulation rapidly reduced mitoflash activity in both sham and denervated muscle fibers. We further demonstrated that the Ca2+ level inside mitochondria follows the time course of the cytosolic Ca2+ transient and that inhibition of mitochondrial Ca2+ uptake by Ru360 blocks the effect of electric stimulation on mitoflash activity. Conclusions The loss of cytosolic Ca2+ transients due to denervation results in the downstream absence of mitochondrial Ca2+ uptake. Our studies suggest that this could be an initial trigger for enhanced mPTP-related mitochondrial ROS generation in skeletal muscle.http://link.springer.com/article/10.1186/s13395-017-0123-0E-C couplingCalcium imagingCalcium signalingCalcium intracellular releaseDenervationMitochondria
collection DOAJ
language English
format Article
sources DOAJ
author Chehade Karam
Jianxun Yi
Yajuan Xiao
Kamal Dhakal
Lin Zhang
Xuejun Li
Carlo Manno
Jiejia Xu
Kaitao Li
Heping Cheng
Jianjie Ma
Jingsong Zhou
spellingShingle Chehade Karam
Jianxun Yi
Yajuan Xiao
Kamal Dhakal
Lin Zhang
Xuejun Li
Carlo Manno
Jiejia Xu
Kaitao Li
Heping Cheng
Jianjie Ma
Jingsong Zhou
Absence of physiological Ca2+ transients is an initial trigger for mitochondrial dysfunction in skeletal muscle following denervation
Skeletal Muscle
E-C coupling
Calcium imaging
Calcium signaling
Calcium intracellular release
Denervation
Mitochondria
author_facet Chehade Karam
Jianxun Yi
Yajuan Xiao
Kamal Dhakal
Lin Zhang
Xuejun Li
Carlo Manno
Jiejia Xu
Kaitao Li
Heping Cheng
Jianjie Ma
Jingsong Zhou
author_sort Chehade Karam
title Absence of physiological Ca2+ transients is an initial trigger for mitochondrial dysfunction in skeletal muscle following denervation
title_short Absence of physiological Ca2+ transients is an initial trigger for mitochondrial dysfunction in skeletal muscle following denervation
title_full Absence of physiological Ca2+ transients is an initial trigger for mitochondrial dysfunction in skeletal muscle following denervation
title_fullStr Absence of physiological Ca2+ transients is an initial trigger for mitochondrial dysfunction in skeletal muscle following denervation
title_full_unstemmed Absence of physiological Ca2+ transients is an initial trigger for mitochondrial dysfunction in skeletal muscle following denervation
title_sort absence of physiological ca2+ transients is an initial trigger for mitochondrial dysfunction in skeletal muscle following denervation
publisher BMC
series Skeletal Muscle
issn 2044-5040
publishDate 2017-04-01
description Abstract Background Motor neurons control muscle contraction by initiating action potentials in muscle. Denervation of muscle from motor neurons leads to muscle atrophy, which is linked to mitochondrial dysfunction. It is known that denervation promotes mitochondrial reactive oxygen species (ROS) production in muscle, whereas the initial cause of mitochondrial ROS production in denervated muscle remains elusive. Since denervation isolates muscle from motor neurons and deprives it from any electric stimulation, no action potentials are initiated, and therefore, no physiological Ca2+ transients are generated inside denervated muscle fibers. We tested whether loss of physiological Ca2+ transients is an initial cause leading to mitochondrial dysfunction in denervated skeletal muscle. Methods A transgenic mouse model expressing a mitochondrial targeted biosensor (mt-cpYFP) allowed a real-time measurement of the ROS-related mitochondrial metabolic function following denervation, termed “mitoflash.” Using live cell imaging, electrophysiological, pharmacological, and biochemical studies, we examined a potential molecular mechanism that initiates ROS-related mitochondrial dysfunction following denervation. Results We found that muscle fibers showed a fourfold increase in mitoflash activity 24 h after denervation. The denervation-induced mitoflash activity was likely associated with an increased activity of mitochondrial permeability transition pore (mPTP), as the mitoflash activity was attenuated by application of cyclosporine A. Electrical stimulation rapidly reduced mitoflash activity in both sham and denervated muscle fibers. We further demonstrated that the Ca2+ level inside mitochondria follows the time course of the cytosolic Ca2+ transient and that inhibition of mitochondrial Ca2+ uptake by Ru360 blocks the effect of electric stimulation on mitoflash activity. Conclusions The loss of cytosolic Ca2+ transients due to denervation results in the downstream absence of mitochondrial Ca2+ uptake. Our studies suggest that this could be an initial trigger for enhanced mPTP-related mitochondrial ROS generation in skeletal muscle.
topic E-C coupling
Calcium imaging
Calcium signaling
Calcium intracellular release
Denervation
Mitochondria
url http://link.springer.com/article/10.1186/s13395-017-0123-0
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