Exercise preconditioning diminishes skeletal muscle atrophy after hindlimb suspension in mice

Theilen, Nicholas T.; Jeremić, Nevena; Weber, Gregory J.; Tyagi, Suresh C.

doi:10.1152/japplphysiol.00137.2018

Cited by 29 publications

(41 citation statements)

References 56 publications

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“…When comparing the results of this meta‐analysis to other models of skeletal muscle atrophy, we found that a 7‐day hind limb suspension resulted in a comparable decrease in soleus (27.1%) and gastrocnemius muscle (21.5%) weight to body weight ratio in wildtype mice . Moreover, evidence shows that the network of interacting signalling pathways that we found to be involved in doxorubicin‐induced skeletal muscle atrophy, also share common pathways with disuse atrophy .…”

Section: Discussionmentioning

confidence: 57%

Doxorubicin‐induced skeletal muscle atrophy: Elucidating the underlying molecular pathways

et al. 2019

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Aim Loss of skeletal muscle mass is a common clinical finding in cancer patients. The purpose of this meta‐analysis and systematic review was to quantify the effect of doxorubicin on skeletal muscle and report on the proposed molecular pathways possibly leading to doxorubicin‐induced muscle atrophy in both human and animal models. Methods A systematic search of the literature was conducted in PubMed, EMBASE, Web of Science and CENTRAL databases. The internal validity of included studies was assessed using SYRCLE’s risk of bias tool. Results Twenty eligible articles were identified. No human studies were identified as being eligible for inclusion. Doxorubicin significantly reduced skeletal muscle weight (ie EDL, TA, gastrocnemius and soleus) by 14% (95% CI: 9.9; 19.3) and muscle fibre cross‐sectional area by 17% (95% CI: 9.0; 26.0) when compared to vehicle controls. Parallel to negative changes in muscle mass, muscle strength was even more decreased in response to doxorubicin administration. This review suggests that mitochondrial dysfunction plays a central role in doxorubicin‐induced skeletal muscle atrophy. The increased production of ROS plays a key role within this process. Furthermore, doxorubicin activated all major proteolytic systems (ie calpains, the ubiquitin‐proteasome pathway and autophagy) in the skeletal muscle. Although each of these proteolytic pathways contributes to doxorubicin‐induced muscle atrophy, the activation of the ubiquitin‐proteasome pathway is hypothesized to play a key role. Finally, a limited number of studies found that doxorubicin decreases protein synthesis by a disruption in the insulin signalling pathway. Conclusion The results of the meta‐analysis show that doxorubicin induces skeletal muscle atrophy in preclinical models. This effect may be explained by various interacting molecular pathways. Results from preclinical studies provide a robust setting to investigate a possible dose‐response, separate the effects of doxorubicin from tumour‐induced atrophy and to examine underlying molecular pathways. More research is needed to confirm the proposed signalling pathways in humans, paving the way for potential therapeutic approaches.

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Section: Discussionmentioning

confidence: 57%

Doxorubicin‐induced skeletal muscle atrophy: Elucidating the underlying molecular pathways

et al. 2019

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“…Muscle mass is determined by the balance between muscle protein synthesis and degradation which control the accretion or loss of muscle mass (Figure ) . The primary mechanism for disuse atrophy seems to be the reduction in muscle protein synthesis in mice, rats and humans . Muscle protein synthesis is stimulated by the activation of mammalian target of rapamycin (mTOR) pathway, a key regulator of translation initiation and its downstream targets S6 kinase‐1 (S6K1) and 4E binding protein 1 (4E‐BP1).…”

Section: Methodsmentioning

confidence: 99%

Muscle unloading: A comparison between spaceflight and ground‐based models

2019

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Prolonged unloading of skeletal muscle, a common outcome of events such as spaceflight, bed rest and hindlimb unloading, can result in extensive metabolic, structural and functional changes in muscle fibres. With advancement in investigations of cellular and molecular mechanisms, understanding of disuse muscle atrophy has significantly increased. However, substantial gaps exist in our understanding of the processes dictating muscle plasticity during unloading, which prevent us from developing effective interventions to combat muscle loss. This review aims to update the status of knowledge and underlying mechanisms leading to cellular and molecular changes in skeletal muscle during unloading. We have also discussed advances in the understanding of contractile dysfunction during spaceflights and in ground‐based models of muscle unloading. Additionally, we have elaborated on potential therapeutic interventions that show promising results in boosting muscle mass and strength during mechanical unloading. Finally, we have identified key gaps in our knowledge as well as possible research direction for the future.

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“…The mechanisms involved in the production of the beneficial effects of preconditioning in skeletal muscle are not yet clear, although it has recently been shown to decrease skeletal muscle atrophy induced by the discharge of the hind limbs (HU) and the mechanism that can participate it is through HDAC4/Gadd45α [23]. Although, interestingly, the mechanisms of physical training to reduce muscle atrophy are associated with the biogenesis, function and redox balance of mitochondria, the same mechanism involved in preconditioning [24]. The redox mechanism seems to be common in preconditioning processes regardless of white tissue, probably not the only shared mechanism, but certainly unlike the cardiac muscle, in skeletal muscle hypertrophy represents a greater capacity for energy regulation.…”

Section: About Skeletal Musclementioning

confidence: 99%

Ischemic Preconditioning in Cardiac and Skeletal Muscle Induced by Exercise

Sampieri-Cabrera¹,

Lopez‐Toledo²,

Aceves-Hernández³

et al. 2020

Cardiorespiratory Fitness

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Since it was discovered, ischemic preconditioning (IPC) has motivated research groups around the world to develop preconditioning protocols capable of protecting tissues against prolonged insults. In 31 years of study, promising results have been obtained on the beneficial role of the CPI and the mechanisms involved in its regulation. Also, different preconditioning protocols that have obtained results similar to the classic CPI have been developed, among which is the exercise-induced preconditioning (EP), that has been proven to protect the heart against an insult, mitigate the atrophy of the heart muscle and increase physical performance in athletes and/or athletes.

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Exercise preconditioning diminishes skeletal muscle atrophy after hindlimb suspension in mice

Cited by 29 publications

References 56 publications

Doxorubicin‐induced skeletal muscle atrophy: Elucidating the underlying molecular pathways

Doxorubicin‐induced skeletal muscle atrophy: Elucidating the underlying molecular pathways

Muscle unloading: A comparison between spaceflight and ground‐based models

Ischemic Preconditioning in Cardiac and Skeletal Muscle Induced by Exercise

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