Michela Aucello scite author profile

The antioxidant enzyme superoxide dismutase 1 (SOD1) is a critical player of the antioxidative defense whose activity is altered in several chronic diseases, including amyotrophic lateral sclerosis. However, how oxidative insult affects muscle homeostasis remains unclear. This study addresses the role of oxidative stress on muscle homeostasis and function by the generation of a transgenic mouse model expressing a mutant SOD1 gene (SOD1(G93A)) selectively in skeletal muscle. Transgenic mice developed progressive muscle atrophy, associated with a significant reduction in muscle strength, alterations in the contractile apparatus, and mitochondrial dysfunction. The analysis of molecular pathways associated with muscle atrophy revealed that accumulation of oxidative stress served as signaling molecules to initiate autophagy, one of the major intracellular degradation mechanisms. These data demonstrate that skeletal muscle is a primary target of SOD1(G93A) -mediated toxicity and disclose the molecular mechanism whereby oxidative stress triggers muscle atrophy.

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Impact of ageing on muscle cell regeneration

Carosio

Berardinelli

Aucello

et al. 2011

Ageing Research Reviews

122

115

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Skeletal Muscle Is a Primary Target of SOD1G93A-Mediated Toxicity

Dobrowolny¹,

Aucello²,

Rizzuto³

et al. 2009

Cell Metabolism

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Muscle atrophy induced by SOD1G93A expression does not involve the activation of caspase in the absence of denervation

2011

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BackgroundThe most remarkable feature of skeletal muscle is the capacity to adapt its morphological, biochemical and molecular properties in response to several factors. Nonetheless, under pathological conditions, skeletal muscle loses its adaptability, leading to atrophy or wasting. Several signals might function as physiopathological triggers of muscle atrophy. However, the specific mechanisms underlying the atrophic phenotype under different pathological conditions remain to be fully elucidated. In this paper, we address the involvement of caspases in the induction of muscle atrophy in experimental models of amyotrophic lateral sclerosis (ALS) expressing the mutant SOD1G93A transgene either locally or ubiquitously.ResultsWe demonstrate that SOD1G93A-mediated muscle atrophy is independent from caspase activity. In particular, the expression of SOD1G93A promotes a reduction of the phosphatidylinositol 3-kinase/Akt pathway associated with activation of forkhead box O3. In contrast, the activation of caspases occurs later and is causally linked to motor neuron degeneration, which is associated with exacerbation of the atrophic phenotype and a shift in fiber-type composition.ConclusionThis study suggests that muscle atrophy induced by the toxic effect of SOD1G93A is independent from the activation of apoptotic markers and that caspase-mediated apoptosis is a process activated upon muscle denervation.

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Localized accumulation of oxidative stress causes muscle atrophy through activation of an autophagic pathway

Aucello¹,

Dobrowolny²,

Musarò³

2009

Autophagy

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Local expression of mIgf-1 modulates ubiquitin, caspase and CDK5 expression in skeletal muscle of an ALS mouse model

Dobrowolny¹,

Aucello²,

Molinaro³

et al. 2008

Neurological Research

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Postmitotic Expression of SOD1^G93AGene Affects the Identity of Myogenic Cells and Inhibits Myoblasts Differentiation

Martini

Dobrowolny

Aucello

et al. 2015

Mediators of Inflammation

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To determine the role of mutant SOD1 gene (SOD1G93A) on muscle cell differentiation, we derived C2C12 muscle cell lines carrying a stably transfected SOD1G93A gene under the control of a myosin light chain (MLC) promoter-enhancer cassette. Expression of MLC/SOD1G93A in C2C12 cells resulted in dramatic inhibition of myoblast differentiation. Transfected SOD1G93A gene expression in postmitotic skeletal myocytes downregulated the expression of relevant markers of committed and differentiated myoblasts such as MyoD, Myogenin, MRF4, and the muscle specific miRNA expression. The inhibitory effects of SOD1G93A gene on myogenic program perturbed Akt/p70 and MAPK signaling pathways which promote differentiation cascade. Of note, the inhibition of the myogenic program, by transfected SOD1G93A gene expression, impinged also the identity of myogenic cells. Expression of MLC/SOD1G93A in C2C12 myogenic cells promoted a fibro-adipogenic progenitors (FAPs) phenotype, upregulating HDAC4 protein and preventing the myogenic commitment complex BAF60C-SWI/SNF. We thus identified potential molecular mediators of the inhibitory effects of SOD1G93A on myogenic program and disclosed potential signaling, activated by SOD1G93A, that affect the identity of the myogenic cell population.

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Michela Aucello

Skeletal Muscle Is a Primary Target of SOD1G93A-Mediated Toxicity

Impact of ageing on muscle cell regeneration

Skeletal Muscle Is a Primary Target of SOD1G93A-Mediated Toxicity

Muscle atrophy induced by SOD1G93A expression does not involve the activation of caspase in the absence of denervation

Localized accumulation of oxidative stress causes muscle atrophy through activation of an autophagic pathway

Local expression of mIgf-1 modulates ubiquitin, caspase and CDK5 expression in skeletal muscle of an ALS mouse model

Postmitotic Expression of SOD1^G93AGene Affects the Identity of Myogenic Cells and Inhibits Myoblasts Differentiation

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Michela Aucello

Skeletal Muscle Is a Primary Target of SOD1G93A-Mediated Toxicity

Impact of ageing on muscle cell regeneration

Skeletal Muscle Is a Primary Target of SOD1G93A-Mediated Toxicity

Muscle atrophy induced by SOD1G93A expression does not involve the activation of caspase in the absence of denervation

Localized accumulation of oxidative stress causes muscle atrophy through activation of an autophagic pathway

Local expression of mIgf-1 modulates ubiquitin, caspase and CDK5 expression in skeletal muscle of an ALS mouse model

Postmitotic Expression of SOD1G93AGene Affects the Identity of Myogenic Cells and Inhibits Myoblasts Differentiation

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Postmitotic Expression of SOD1^G93AGene Affects the Identity of Myogenic Cells and Inhibits Myoblasts Differentiation