Acute effects of reactive oxygen and nitrogen species on the contractile function of skeletal muscle

Reactive oxygen and nitrogen species (ROS/RNS) are important for skeletal muscle function under both physiological and pathological conditions. ROS/RNS induce long‐term and acute effects and the latter are the focus of the present review. Upon repeated muscle activation both oxygen and nitrogen free radicals likely increase and acutely affect contractile function. Although fluorescent indicators often detect only modest increases in ROS during repeated activation, there are numerous studies showing that manipulations of ROS can affect muscle fatigue development and recovery. Exposure of intact muscle fibres to the oxidant hydrogen peroxide (H2O2) affects mainly the myofibrillar function, where an initial increase in Ca2+ sensitivity is followed by a decrease. Experiments on skinned fibres show that these effects can be attributed to H2O2 interacting with glutathione and myoglobin, respectively. The primary RNS, nitric oxide (NO•), may also acutely affect myofibrillar function and decrease the Ca2+ sensitivity. H2O2 can oxidize the sarcoplasmic reticulum Ca2+ release channels. This oxidation has a large stimulatory effect on Ca2+‐induced Ca2+ release of isolated channels, whereas it has little or no effect on the physiological, action potential‐induced Ca2+ release in skinned and intact muscle fibres. Thus, acute effects of ROS/RNS on muscle function are likely to be mediated by changes in myofibrillar Ca2+ sensitivity, which can contribute to the development of muscle fatigue or alternatively help counter it.

[1]  T. L. Dutka,et al.  Modulation of contractile apparatus Ca2+ sensitivity and disruption of excitation–contraction coupling by S‐nitrosoglutathione in rat muscle fibres , 2011, The Journal of physiology.

[2]  G. Lamb,et al.  Differential effects of peroxynitrite on contractile protein properties in fast- and slow-twitch skeletal muscle fibers of rat. , 2011, Journal of applied physiology.

[3]  C. Ward,et al.  Mitochondrial redox potential during contraction in single intact muscle fibers , 2010, Muscle & nerve.

[4]  E. Weitzberg,et al.  NO-synthase independent NO generation in mammals. , 2010, Biochemical and biophysical research communications.

[5]  H. Westerblad,et al.  Effects of HMGB1 on in vitro responses of isolated muscle fibers and functional aspects in skeletal muscles of idiopathic inflammatory myopathies , 2010, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[6]  Leonardo Nogueira,et al.  Myosin is reversibly inhibited by S-nitrosylation. , 2009, The Biochemical journal.

[7]  T. F. Reardon,et al.  Time to fatigue is increased in mouse muscle at 37°C; the role of iron and reactive oxygen species , 2009, The Journal of physiology.

[8]  H. Westerblad,et al.  High temperature does not alter fatigability in intact mouse skeletal muscle fibres , 2009, The Journal of physiology.

[9]  D. Allen,et al.  Iron injections in mice increase skeletal muscle iron content, induce oxidative stress and reduce exercise performance , 2009, Experimental physiology.

[10]  G. Posterino,et al.  Sequential effects of GSNO and H2O2 on the Ca2+ sensitivity of the contractile apparatus of fast- and slow-twitch skeletal muscle fibers from the rat. , 2009, American journal of physiology. Cell physiology.

[11]  S. Matecki,et al.  Hypernitrosylated ryanodine receptor/calcium release channels are leaky in dystrophic muscle , 2009, Nature Medicine.

[12]  H. Westerblad,et al.  Increased mitochondrial Ca2+ and decreased sarcoplasmic reticulum Ca2+ in mitochondrial myopathy. , 2009, Human molecular genetics.

[13]  B. MacIntosh,et al.  Staircase but not posttetanic potentiation in rat muscle after spinal cord hemisection , 2008, Muscle & nerve.

[14]  S. Powers,et al.  Exercise-induced oxidative stress: cellular mechanisms and impact on muscle force production. , 2008, Physiological reviews.

[15]  G. Lamb,et al.  Hydroxyl radical and glutathione interactions alter calcium sensitivity and maximum force of the contractile apparatus in rat skeletal muscle fibres , 2008, The Journal of physiology.

[16]  LeeAnn Higgins,et al.  Functional, structural, and chemical changes in myosin associated with hydrogen peroxide treatment of skeletal muscle fibers. , 2008, American journal of physiology. Cell physiology.

[17]  H. Westerblad,et al.  Reactive oxygen species and fatigue‐induced prolonged low‐frequency force depression in skeletal muscle fibres of rats, mice and SOD2 overexpressing mice , 2008, The Journal of physiology.

[18]  M. Jackson,et al.  Real‐time measurement of nitric oxide in single mature mouse skeletal muscle fibres during contractions , 2007, The Journal of physiology.

[19]  H. Westerblad,et al.  Effects of Palmitate on Ca2+ Handling in Adult Control and ob/ob Cardiomyocytes , 2007, Diabetes.

[20]  C. Hidalgo,et al.  A Transverse Tubule NADPH Oxidase Activity Stimulates Calcium Release from Isolated Triads via Ryanodine Receptor Type 1 S -Glutathionylation* , 2006, Journal of Biological Chemistry.

[21]  S. Simão,et al.  Inhibition of skeletal muscle S1-myosin ATPase by peroxynitrite. , 2006, Biochemistry.

[22]  C. Barclay Modelling diffusive O2 supply to isolated preparations of mammalian skeletal and cardiac muscle , 2005, Journal of Muscle Research & Cell Motility.

[23]  G. Salama,et al.  Effects of pO2 on the activation of skeletal muscle ryanodine receptors by NO: a cautionary note. , 2005, Cell calcium.

[24]  V. Jacquemond,et al.  Nitric oxide synthase inhibition affects sarcoplasmic reticulum Ca2+ release in skeletal muscle fibres from mouse , 2005, The Journal of physiology.

[25]  D. Allen,et al.  Reactive oxygen species reduce myofibrillar Ca2+ sensitivity in fatiguing mouse skeletal muscle at 37°C , 2005 .

[26]  B. Allard,et al.  Control of intracellular calcium in the presence of nitric oxide donors in isolated skeletal muscle fibres from mouse , 2004, The Journal of physiology.

[27]  J. Stamler,et al.  Concerted regulation of skeletal muscle contractility by oxygen tension and endogenous nitric oxide , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[28]  S. Hamilton,et al.  S-Glutathionylation Decreases Mg2+ Inhibition and S-Nitrosylation Enhances Ca2+ Activation of RyR1 Channels* , 2003, Journal of Biological Chemistry.

[29]  G. Lamb,et al.  Effects of oxidation and cytosolic redox conditions on excitation–contraction coupling in rat skeletal muscle , 2003, The Journal of physiology.

[30]  G. Lamb,et al.  Effects of oxidation and reduction on contractile function in skeletal muscle fibres of the rat , 2003, The Journal of physiology.

[31]  M. Brand,et al.  Topology of Superoxide Production from Different Sites in the Mitochondrial Electron Transport Chain* , 2002, The Journal of Biological Chemistry.

[32]  H. Westerblad,et al.  Contractile response of skeletal muscle to low peroxide concentrations: myofibrillar calcium sensitivity as a likely target for redox-modulation. , 2001, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[33]  J. Stamler,et al.  The Skeletal Muscle Calcium Release Channel Coupled O2 Sensor and NO Signaling Functions , 2000, Cell.

[34]  B. MacIntosh,et al.  Coexistence of potentiation and fatigue in skeletal muscle. , 2000, Brazilian journal of medical and biological research = Revista brasileira de pesquisas medicas e biologicas.

[35]  E. Homsher,et al.  Regulation of contraction in striated muscle. , 2000, Physiological reviews.

[36]  D. Allen,et al.  Effect of nitric oxide on single skeletal muscle fibres from the mouse , 1998, The Journal of physiology.

[37]  D. Allen,et al.  Effect of hydrogen peroxide and dithiothreitol on contractile function of single skeletal muscle fibres from the mouse , 1998, The Journal of physiology.

[38]  C. Hidalgo,et al.  Sulfhydryl oxidation modifies the calcium dependence of ryanodine-sensitive calcium channels of excitable cells. , 1998, Biophysical journal.

[39]  G. Sieck,et al.  Skeletal muscle force and actomyosin ATPase activity reduced by nitric oxide donor. , 1997, Journal of applied physiology.

[40]  J. Nadler,et al.  Nitric oxide release is present from incubated skeletal muscle preparations. , 1994, Journal of applied physiology.

[41]  L. Ji,et al.  Glutathione and antioxidant enzymes in skeletal muscle: effects of fiber type and exercise intensity. , 1992, Journal of applied physiology.

[42]  M. Reid,et al.  Reactive oxygen in skeletal muscle. I. Intracellular oxidant kinetics and fatigue in vitro. , 1992, Journal of applied physiology.

[43]  D. Allen,et al.  Changes of myoplasmic calcium concentration during fatigue in single mouse muscle fibers , 1991, The Journal of general physiology.

[44]  B Chance,et al.  Hydroperoxide metabolism in mammalian organs. , 1979, Physiological reviews.

[45]  D. Allen,et al.  Skeletal muscle fatigue: cellular mechanisms. , 2008, Physiological reviews.

[46]  G. Lamb,et al.  Excitation–contraction coupling and fatigue mechanisms in skeletal muscle: studies with mechanically skinned fibres , 2004, Journal of Muscle Research & Cell Motility.