Antioxidant treatment of hindlimb-unloaded mouse counteracts fiber type transition but not atrophy of disused muscles

Desaphy, Jean-François; Pierno, Sabata; Liantonio, Antonella; Giannuzzi, Viviana; Digennaro, Claudio; Dinardo, Maria Maddalena; Camerino, Giulia Maria; Ricciuti, Patrizia; Brocca, Lorenza; Pellegrino, Maria Antonietta; Bottinelli, Roberto; Camerino, Diana Conte

doi:10.1016/j.phrs.2010.01.012

Cited by 70 publications

(99 citation statements)

References 42 publications

(88 reference statements)

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“…The slow twitch muscle soleus is promptly responding to unloading, while fast twitch muscles represent a less intensive response, but previous findings show that TA, GAS, and EDL can also be affected (19,20). Here, in the study, TA and GAS underwent diverse alterations following unloading.…”

Section: Compared With Ta Gas Was Preferentially Affected To Atrophymentioning

confidence: 54%

“…The antigrativity soleus was considered preferentially affected and was clearly demonstrated as dysfunction of mitochondrial biogenesis following unloading (17,18). The fast-twitch muscles-EDL, GAS, and TA also respond to unloading in mouse or rat (19,20). Especially, GAS exhibited the specific dysfunction of mitochondrial respiration and TA showed distinct electromyogram following unloading (21,22).…”

Section: Introductionmentioning

confidence: 99%

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Depressed mitochondrial biogenesis and dynamic remodeling in mouse tibialis anterior and gastrocnemius induced by 4‐week hindlimb unloading

et al. 2012

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SummaryMitochondrial dynamics is highly involved in muscle atrophy, the slow twitch muscle as soleus, preferentially affected by hindlimb unloading (HU), was well characterized by mitochondrial dysfunction in biogenesis. However, the fast twitch muscles like tibialis anterior (TA) and gastrocnemius (GAS), which are the most massive parts of the hindlimb muscles, are less elucidated on mitochondrial adaptations responding to HU. To investigate the mitochondrial dynamic responses and the involved molecules mediating atrophy in TA and GAS, we studied a 4-week HU mouse model. We found GAS was preferentially affected to atrophy by unloading compared with TA. Furthermore, the depressed mitochondrial biogenesis occurred, accounting for mitochondrial loss in GAS by unloading. PGC-1a, as well as its transcriptional/post-translational modification regulators, such as p-CREB, SIRT1, and p-AMPK, were consistently reduced in response to unloading in GAS. Molecules relevant to autophagy, mitochondrial fusion, and fission, were compromised following unloading both in TA and GAS. These results suggested that TA exhibited resistance to unloading induced muscle atrophy while GAS presented significant mitochondrial loss, which might be due to the mitochondrial biogenesis suppressed by the inactivation of PGC-1a. However, both in TA and GAS muscles, a similar sedentary mitochondrial dynamics of mitochondrial fusion and fission was induced by unloading though TA exhibited little muscle atrophy. IUBMBIUBMB Life, 64(11): 901-910, 2012

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Section: Compared With Ta Gas Was Preferentially Affected To Atrophymentioning

confidence: 54%

Section: Introductionmentioning

confidence: 99%

Depressed mitochondrial biogenesis and dynamic remodeling in mouse tibialis anterior and gastrocnemius induced by 4‐week hindlimb unloading

et al. 2012

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“…The role of ROS and oxidative stress in disuse atrophy is further supported by work showing that mitochondria-targeting antioxidants administered to mice attenuate immobilisation atrophy (Min et al, 2011). However, results from other studies have failed to show any attenuation of disuse atrophy with antioxidant administration Desaphy et al, 2010). This disparity in results is likely due to differences in the specific antioxidants used, the ratio of the magnitude of oxidative stress (threshold level) to the magnitude of the administered antioxidant, the particular muscle tested, different conditions of disuse and combinations thereof.…”

Section: Introductionmentioning

confidence: 93%

Each to their own: skeletal muscles of different function use different biochemical strategies during aestivation at high temperature

Young

Cramp

Franklin

2012

Journal of Experimental Biology

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SUMMARYPreservation of muscle morphology depends on a continuing regulatory balance between molecules that protect and molecules that damage muscle structural integrity. Excessive disruption of the biochemical balance that favours reactive oxygen species (ROS) in disused muscles may lead to oxidative stress, which in turn is associated with increased atrophic or apoptotic signalling and/or oxidative damage to the muscle and thus muscle disuse atrophy. Increases in the rate of oxygen consumption likely increase the overall generation of ROS in vivo. Temperature-induced increases in oxygen consumption rate occur in some muscles of ectotherms undergoing prolonged muscular disuse during aestivation. In the green-striped burrowing frog, Cyclorana alboguttata, both large jumping and small non-jumping muscles undergo atrophy seemingly commensurate with their rate of oxygen consumption during aestivation. However, because the extent of atrophy in these muscles is not enhanced at higher temperatures, despite a temperature-sensitive rate of oxygen consumption in the jumping muscle, we proposed that muscles are protected by biochemical means that, when mobilised at higher temperatures, inhibit atrophy. We proposed that the biochemical response to temperature would be muscle-specific. We examined the effect of temperature on the antioxidant and heat shock protein systems and determined the extent of oxidative damage to lipids and proteins in two functionally different skeletal muscles, the gastrocnemius (jumping muscle) and the iliofibularis (non-jumping muscle), by aestivating frogs at 24 and 30°C for 6months. We assayed small molecule antioxidant capacity, mitochondrial and cytosolic superoxide dismutase activities and Hsp70 concentrations to show that protective mechanisms in disused muscles are differentially regulated with respect to both temperature and aestivation. High aestivation temperature results in an antioxidant response in the metabolically temperaturesensitive jumping muscle. We assayed lipid peroxidation and protein oxidation to show that oxidative damage is apparent during aestivation and its pattern is muscle-specific, but unaffected by temperature. Consideration is given to how the complex responses of muscle biochemistry inform the different strategies muscles may use in regulating their oxidative environment during extended disuse and disuse at high temperature.

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“…For instance, hindlimb unloading of rodents, a model of muscle disuse, induce a slow-to-fast transition of postural muscles, i.e. increased expression of fast isoforms of myosin heavy chain (MHC) and increase of resting gCl in soleus muscle [40]. A coordinated expression existed among MHC isoforms, metabolic enzymes and isoforms of other myofibrillar and non-myofibrillar proteins [41][42][43].…”

Section: Myofibrillar Proteinsmentioning

confidence: 99%

Statin or fibrate chronic treatment modifies the proteomic profile of rat skeletal muscle

Camerino

Pellegrino

Brocca

et al. 2011

Biochemical Pharmacology

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Statins and fibrates can cause myopathy. To further understand the causes of the damage we performed a proteome analysis in fast-twitch skeletal muscle of rats chronically treated with different hypolipidemic drugs. The proteomic maps were obtained from extensor digitorum longus (EDL) muscles of rats treated for 2-months with 10mg/kg atorvastatin, 20mg/kg fluvastatin, 60mg/kg fenofibrate and control rats. The proteins differentially expressed were identified by mass spectrometry and further analysed by immunoblot analysis. We found a significant modification in 40 out of 417 total spots analysed in atorvastatin treated rats, 15 out of 436 total spots in fluvastatin treated rats and 21 out of 439 total spots in fenofibrate treated rats in comparison to controls. All treatments induced a general tendency to a down-regulation of protein expression; in particular, atorvastatin affected the protein pattern more extensively with respect to the other treatments.Energy production systems, both oxidative and glycolytic enzymes and creatine kinase, were downregulated following atorvastatin administration, whereas fenofibrate determined mostly alterations in glycolytic enzymes and creatine kinase, oxidative enzymes being relatively spared. Additionally, all treatments resulted in some modifications of proteins involved in cellular defenses against oxidative stress, such as heat shock proteins, and of myofibrillar proteins. These results were confirmed by immunoblot analysis. In conclusions, the proteomic analysis showed that either statin or fibrate administration can modify the expression of proteins essential for skeletal muscle function suggesting potential mechanisms for statin myopathy.

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Antioxidant treatment of hindlimb-unloaded mouse counteracts fiber type transition but not atrophy of disused muscles

Cited by 70 publications

References 42 publications

Depressed mitochondrial biogenesis and dynamic remodeling in mouse tibialis anterior and gastrocnemius induced by 4‐week hindlimb unloading

Depressed mitochondrial biogenesis and dynamic remodeling in mouse tibialis anterior and gastrocnemius induced by 4‐week hindlimb unloading

Each to their own: skeletal muscles of different function use different biochemical strategies during aestivation at high temperature

Statin or fibrate chronic treatment modifies the proteomic profile of rat skeletal muscle

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