Effect of hydrogen peroxide and dithiothreitol on contractile function of single skeletal muscle fibres from the mouse

Andrade, Francisco H.; Reid, Michael B.; Allen, David G.; Westerblad, Håkan

doi:10.1111/j.1469-7793.1998.565bn.x

Cited by 373 publications

(472 citation statements)

References 38 publications

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“…Several studies have shown that these reactive species contribute to skeletal muscle dysfunction through different mechanisms. Brotto and Nosek [42] demonstrated a decrease in calcium release from the sarcoplasmic reticulum, and Andrade et al [43] demonstrated reduced sensitivity to calcium in muscles exposed to hydrogen peroxide. In addition, moderate oxidative stress has been reported to induce protein oxidation, with a consequent increase in intracellular proteolysis [45][46][47].…”

Section: Discussionmentioning

confidence: 99%

Oxidative and proteolytic profiles of the right and left heart in a model of cancer-induced cardiac cachexia

et al. 2014

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Section: Discussionmentioning

confidence: 99%

Oxidative and proteolytic profiles of the right and left heart in a model of cancer-induced cardiac cachexia

et al. 2014

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“…The sensitivity of a particular target is defined by the intrinsic sensitivity of the molecule to oxidation–reduction and the local redox state,103 and evidence has shown that RONS produced by skeletal muscle can alter myofilament structure and function 187. Several myofilament proteins including actin, α‐actinin,151, 187 troponin C188 and myosin heavy chains189, 190, 191 are susceptible to RONS‐induced oxidative modifications, thus affecting Ca 2+ dynamics and Ca 2+ sensitivity192 and, inevitably, cross‐bridge kinetics,188 which may result in contractile dysfunction.…”

Section: Non‐enzymatic Key Antioxidants That Contribute To the Maintementioning

confidence: 99%

Redox homeostasis and age‐related deficits in neuromuscular integrity and function

Sakellariou

Lightfoot

Earl

et al. 2017

J cachexia sarcopenia muscle

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Skeletal muscle is a major site of metabolic activity and is the most abundant tissue in the human body. Age‐related muscle atrophy (sarcopenia) and weakness, characterized by progressive loss of lean muscle mass and function, is a major contributor to morbidity and has a profound effect on the quality of life of older people. With a continuously growing older population (estimated 2 billion of people aged >60 by 2050), demand for medical and social care due to functional deficits, associated with neuromuscular ageing, will inevitably increase. Despite the importance of this ‘epidemic’ problem, the primary biochemical and molecular mechanisms underlying age‐related deficits in neuromuscular integrity and function have not been fully determined. Skeletal muscle generates reactive oxygen and nitrogen species (RONS) from a variety of subcellular sources, and age‐associated oxidative damage has been suggested to be a major factor contributing to the initiation and progression of muscle atrophy inherent with ageing. RONS can modulate a variety of intracellular signal transduction processes, and disruption of these events over time due to altered redox control has been proposed as an underlying mechanism of ageing. The role of oxidants in ageing has been extensively examined in different model organisms that have undergone genetic manipulations with inconsistent findings. Transgenic and knockout rodent studies have provided insight into the function of RONS regulatory systems in neuromuscular ageing. This review summarizes almost 30 years of research in the field of redox homeostasis and muscle ageing, providing a detailed discussion of the experimental approaches that have been undertaken in murine models to examine the role of redox regulation in age‐related muscle atrophy and weakness.

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“…Of many intracellular ROS production mechanisms, the mitochondrion is the most prominent ROS generator wherein constitutive ROS production arises from leakage of a small percent of electrons from the electron transfer chain (ETC) [7,8]. In skeletal muscle, which requires high energy supply and contains abundant mitochondria, adequate amount of ROS modulates muscle contractility and glucose metabolism [9,10], while excessive ROS is responsible for muscle fatigue and insulin resistance [1,11,12].…”

Section: Introductionmentioning

confidence: 99%

Imaging superoxide flash and metabolism-coupled mitochondrial permeability transition in living animals

et al. 2011

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The mitochondrion is essential for energy metabolism and production of reactive oxygen species (ROS). In intact cells, respiratory mitochondria exhibit spontaneous "superoxide flashes", the quantal ROS-producing events consequential to transient mitochondrial permeability transition (tMPT). Here we perform the first in vivo imaging of mitochondrial superoxide flashes and tMPT activity in living mice expressing the superoxide biosensor mt-cpYFP, and demonstrate their coupling to whole-body glucose metabolism. Robust tMPT/superoxide flash activity occurred in skeletal muscle and sciatic nerve of anesthetized transgenic mice. In skeletal muscle, imaging tMPT/superoxide flashes revealed labyrinthine three-dimensional networks of mitochondria that operate synchronously. The tMPT/ superoxide flash activity surged in response to systemic glucose challenge or insulin stimulation, in an apparently frequency-modulated manner and involving also a shift in the gating mode of tMPT. Thus, in vivo imaging of tMPTdependent mitochondrial ROS signals and the discovery of the metabolism-tMPT-superoxide flash coupling mark important technological and conceptual advances for the study of mitochondrial function and ROS signaling in health and disease.

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Effect of hydrogen peroxide and dithiothreitol on contractile function of single skeletal muscle fibres from the mouse

Cited by 373 publications

References 38 publications

Oxidative and proteolytic profiles of the right and left heart in a model of cancer-induced cardiac cachexia

Oxidative and proteolytic profiles of the right and left heart in a model of cancer-induced cardiac cachexia

Redox homeostasis and age‐related deficits in neuromuscular integrity and function

Imaging superoxide flash and metabolism-coupled mitochondrial permeability transition in living animals

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