Abstract
Superoxide and nitric oxide are generated by skeletal muscle, and these species are increased by contractile activity. Mitochondria have long been assumed to play the primary role in generation of superoxide in muscle, but recent studies indicate that, during contractile activity, membrane-localized NADPH oxidase(s) rapidly generate(s) superoxide that plays a role in redox signaling. This process is important in upregulation of rapid and specific cytoprotective responses that aid maintenance of cell viability following contractile activity, but the overall extent to which redox signaling contributes to regulation of muscle metabolism and homeostasis following contractile activity is currently unclear, as is identification of key redox-sensitive protein targets involved in these processes. Reactive oxygen and nitrogen species have also been implicated in the loss of muscle mass and function that occurs with aging, although recent work has questioned whether oxidative damage plays a key role in these processes. A failure of redox signaling occurs in muscle during aging and may contribute to the age-related loss of muscle fibers. Whether such changes in redox signaling reflect primary age-related changes or are secondary to the fundamental mechanisms is unclear. For instance, denervated muscle fibers within muscles from aged rodents or humans appear to generate large amounts of mitochondrial hydrogen peroxide that could influence adjacent innervated fibers. Thus, in this instance, a “secondary” source of reactive oxygen species may be potentially generated as a result of a primary age-related pathology (loss of neurons), but, nevertheless, may contribute to loss of muscle mass and function during aging.
Highlights
THE EDITOR-IN-CHIEF OF THE Journal of Applied Physiology invited this review to accompany the presentation of the 2014 Edward F
It is well established that skeletal muscle fibers generate superoxide and nitric oxide (NO), and these parent molecules can be converted to several secondary reactive oxygen species (ROS) and reactive nitrogen species (RNS)
We have examined the potential contribution of mitochondrial and nonmitochondrial sources to the acute increase in superoxide seen during muscle contractions [69, 79] and concluded that NADPH oxidase effects predominated over mitochondria during the short contraction periods (10 –15 min) that were studied
Summary
Mitochondria were the main source of the ROS generated during contractile activity in muscle, but several recent publications disagree with this possibility [73]. Fibers isolated from neuronal NO synthase transgenic mice showed increased DAF-FM fluorescence and reduced DHE oxidation in resting muscle fibers These data appear to indicate that peroxynitrite is formed in muscle fibers as a consequence of lack of SOD1 in SOD1KO mice and may, contribute to fiber loss in this model. Relevant to consider whether increased mitochondrial ROS might play a secondary role in aging processes and be a consequence of more direct effects of aging Potential examples of this may be the increase in muscle mitochondrial ROS that appears to occur secondarily to other age-related changes in the SOD1KO mouse studies described above, and by the observation that experimental denervation leads to a very large sustained increase in muscle mitochondrial ROS generation [59]. Since the key ROS generated in mitochondria of the denervated fibers appears to be hydrogen peroxide or other peroxides, such species are membrane permeable and could diffuse to adjacent innervated fibers, leading to redox-related changes in oxidative damage and redox signaling
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