Malcolm J. Jackson

Exercise-Induced Oxidative Stress: Cellular Mechanisms and Impact on Muscle Force Production

The first suggestion that physical exercise results in free radical-mediated damage to tissues appeared in 1978, and the past three decades have resulted in a large growth of knowledge regarding exercise and oxidative stress. Although the sources of oxidant production during exercise continue to be debated, it is now well established that both resting and contracting skeletal muscles produce reactive oxygen species and reactive nitrogen species. Importantly, intense and prolonged exercise can result in oxidative damage to both proteins and lipids in the contracting myocytes. Furthermore, oxidants can modulate a number of cell signaling pathways and regulate the expression of multiple genes in eukaryotic cells. This oxidant-mediated change in gene expression involves changes at transcriptional, mRNA stability, and signal transduction levels. Furthermore, numerous products associated with oxidant-modulated genes have been identified and include antioxidant enzymes, stress proteins, DNA repair proteins, and mitochondrial electron transport proteins. Interestingly, low and physiological levels of reactive oxygen species are required for normal force production in skeletal muscle, but high levels of reactive oxygen species promote contractile dysfunction resulting in muscle weakness and fatigue. Ongoing research continues to probe the mechanisms by which oxidants influence skeletal muscle contractile properties and to explore interventions capable of protecting muscle from oxidant-mediated dysfunction.

Electron spin resonance studies of intact mammalian skeletal muscle

Samples of skeletal muscle from mice, rats and man have been examined by conventional electron spin resonance techniques. One major free-radical signal with g value 2.0036-2.004 was detected in all intact muscle samples and homogenates at 77 K whereas this signal was not seen at room temperature. Other less prominant signals were also detected. Thirty minutes of excessive contractile activity of rat hind limb muscles was found to result in a leakage of intracellular creatine kinase enzyme into the blood plasma and also produced an average 70% increase in the amplitude of the major electron spin resonance signal. These data support the hypothesis that increased free-radical activity may play some role in muscle damage caused by extensive muscular activity.

Effect of Vitamin C Supplements on Antioxidant Defence and Stress Proteins in Human Lymphocytes and Skeletal Muscle

Oxidative stress induces adaptations in the expression of protective enzymes and heat shock proteins (HSPs) in a variety of tissues. We have examined the possibility that supplementation of subjects with the nutritional antioxidant, vitamin C, influences the ability of lymphocytes to express protective enzymes and HSPs following exposure to an exogenous oxidant and the response of skeletal muscle to the physiological oxidative stress that occurs during exercise in vivo. Our hypothesis was that an elevation of tissue vitamin C content would reduce oxidant‐induced expression of protective enzymes and HSP content. Lymphocytes from non‐supplemented subjects responded to hydrogen peroxide with increased activity of superoxide dismutase (SOD) and catalase, and HSP60 and HSP70 content over 48 h. Vitamin C supplementation at a dose of 500 mg day−1 for 8 weeks was found to increase the serum vitamin C concentration by ∼50 %. Lymphocytes from vitamin C‐supplemented subjects had increased baseline SOD and catalase activities and an elevated HSP60 content. The SOD and catalase activities and the HSP60 and HSP70 content of lymphocytes from supplemented subjects did not increase significantly in response to hydrogen peroxide. In non‐supplemented subjects, a single period of cycle ergometry was found to significantly increase the HSP70 content of the vastus lateralis. Following vitamin C supplementation, the HSP70 content of the muscle was increased at baseline with no further increase following exercise. We conclude that, in vitamin C‐supplemented subjects, adaptive responses to oxidants are attenuated, but that this may reflect an increased baseline expression of potential protective systems against oxidative stress (SOD, catalase and HSPs).

Overexpression of HSP70 in mouse skeletal muscle protects against muscle damage and age-related muscle dysfunction.

Ageing is associated with skeletal muscle atrophy, a deficit in force generation, an increased susceptibility to contraction‐induced injury, and a permanent force deficit following severe injury. Muscles of young mice adapt rapidly following exercise by an increase in the production of heat shock proteins (HSPs), whereas muscles of old mice show a severely diminished response. We hypothesized that overexpression of HSP70 in muscle throughout life would reduce age‐related changes in function. The maximum tetanic force of extensor digitorum longus (EDL) muscles of adult and old wild‐type (WT) and HSP70 overexpressor transgenic mice was determined. EDL muscles were subjected to damaging lengthening contractions and the ability to generate force was assessed for up to 28 days following the contractions. Overexpression of HSP70 in muscles of old transgenic mice prevented the specific force deficit observed in muscles of old WT mice. The complete recovery of muscles of old HSP70 transgenic mice by 14 days following the contraction protocol was in contrast to the 44% force deficit, which remained in muscles of old WT mice at 28 days following the protocol. These data indicate that a diminished production of HSP70 in muscles of old mammals has a major effect on age‐related functional deficits.

Antioxidants, reactive oxygen and nitrogen species, gene induction and mitochondrial function.

Redox-sensitive cell signalling Thiol groups and the regulation of gene expression Redox-sensitive signal transduction pathways Protein kinases Protein phosphatases Lipids and phospholipases Antioxidant (electrophile) response element Intracellular calcium signalling Transcription factors NF-?B AP-1 p53 Cellular responses to oxidative stress Cellular responses to change in redox state Proliferation Cell death Immune cell function Reactive oxygen and nitrogen species – good or bad? Reactive oxygen species and cell death Reactive oxygen species and inflammation Are specific reactive oxygen species and antioxidants involved in modulating cellular responses? Specific effects of dietary antioxidants in cell regulation Carotenoids Vitamin E Flavonoids Inducers of phase II enzymes Disease states affected Oxidants, antioxidants and mitochondria Introduction Mitochondrial generation of reactive oxygen and nitrogen species Mitochondria and apoptosis Mitochondria and antioxidant defences Key role of mitochondrial GSH in the defence against oxidative damage Mitochondrial oxidative damage Direct oxidative damage to the mitochondrial electron transport chain Nitric oxide and damage to mitochondria Effects of nutrients on mitochondria Caloric restriction and antioxidants Lipids Antioxidants Techniques and approaches Mitochondrial techniques cDNA microarray approaches Proteomics approaches Transgenic mice as tools in antioxidant research Gene knockout and over expression Transgenic reporter mice Conclusions Future research needs

Experimental skeletal muscle damage: the nature of the calcium‐activated degenerative processes

Abstract. The role of calcium‐activated degenerative processes in the efflux of enzyme from experimentally damaged mouse muscle has been studied using an isolated mouse soleus muscle preparation. Inhibition of mitochondrial activity with dinitrophenol or sodium cyanide was found to cause a large efflux of enzyme. This was largely prevented by withdrawal of the extracellular calcium suggesting that mitochondrial calcium overload does not play a major role in the damage leading to enzyme efflux.

Exercise and skeletal muscle ageing: cellular and molecular mechanisms

As we age, our skeletal muscle becomes smaller and weaker. In addition, the remaining muscle is more susceptible to damage, particularly following exercise, recovery from damage is severely impaired and muscle is unable to adapt rapidly following sequential periods of exercise. The mechanisms by which skeletal muscle damage occurs are poorly understood and the role that an increased production of free radical species plays in this damage is controversial. However, evidence is emerging which suggests that an increased production of free radicals may act as an activator of the adaptive response in skeletal muscle, resulting in the increased production of antioxidant enzymes and heat shock proteins (HSPs). The increased content of these proteins facilitates rapid remodelling of muscle and provides considerable protection against subsequent periods of damaging exercise. There is considerable evidence that the production of free radicals is modified during the ageing process. The aim of this review is to examine the possible effects of this modification on the ability of muscle cells to respond to stress and the functional effect that this may have on our muscles as we age.

Free radical generation by skeletal muscle of adult and old mice: effect of contractile activity

Oxidative modification of cellular components may contribute to tissue dysfunction during aging. In skeletal muscle, contractile activity increases the generation of reactive oxygen and nitrogen species (ROS). The question of whether contraction‐induced ROS generation is further increased in skeletal muscle of the elderly is important since this influences recommendations on their exercise participation. Three different approaches were used to examine whether aging influences contraction‐induced ROS generation. Hind limb muscles of adult and old mice underwent a 15‐min period of isometric contractions and we examined ROS generation by isolated skeletal muscle mitochondria, ROS release into the muscle extracellular fluid using microdialysis techniques, and the muscle glutathione and protein thiol contents. Resting skeletal muscle of old mice compared with adult mice showed increased ROS release from isolated mitochondria, but no changes in the extracellular levels of superoxide, nitric oxide, hydrogen peroxide, hydroxyl radical activity or muscle glutathione and protein thiol contents. Skeletal muscle mitochondria isolated from both adult and old mice after contractile activity showed significant increases in hydrogen peroxide release compared with pre‐contraction values. Contractions increased extracellular hydroxyl radical activity in adult and old mice, but had no significant effect on extracellular hydrogen peroxide or nitric oxide in either group. In adult mice only, contractile activity increased the skeletal muscle release of superoxide. A similar decrease in muscle glutathione and protein thiol contents was seen in adult and old mice following contractions. Thus, contractile activity increased skeletal muscle ROS generation in both adult and old mice with no evidence for an age‐related exacerbation of ROS generation.

In vivo model of muscle pain: Quantification of intramuscular chemical, electrical, and pressure changes associated with saline-induced muscle pain in humans

Abstract Intramuscular injection of hypertonic saline is a good model to study human muscle pain (Kellgren 1938). The present study concerns the intramuscular (i.m.) pain mediators in saline‐induced muscle pain. In experiment 1, the diffusion of infused hypertonic and isotonic saline (0.5 ml) in m. tibialis anterior was illustrated by magnetic resonance imaging (MRI) in one subject. In experiment 2, six volunteers received four sequential infusions (0.5 ml given at 5 min intervals) of isotonic saline and thereafter four sequential infusions (0.5 ml given at 5 min intervals) of hypertonic saline into m. tibialis anterior. The isotonic and hypertonic saline infusions were computer‐controlled and separated by 20 min. The muscle pain intensity was assessed by continuous recordings on a visual analogue scale (VAS). One microdialysis probe was inserted 1 cm from the infusion needle in m. tibialis anterior and another probe in the other m. tibialis anterior. Concentrations of the i.m. sodium, potassium, magnesium, and prostaglandin E2 (PGE2) were assessed from the dialysates. Intramuscular electromyography (EMG) and pressure were assessed in the area of the infused saline. In experiment 1, the infusion of hypertonic and isotonic saline created a visible saline‐pool on the MRI scans. These saline‐pool volumes were stable and not correlated to the pain scores. In experiment 2, infusion of isotonic saline produced little pain compared to infusion of hypertonic saline. Maximal pain was reported after the first infusion of hypertonic saline and thereafter the pain gradually decreased with subsequent infusions of hypertonic saline. During infusion of hypertonic saline the i.m. sodium and potassium concentrations increased significantly, i.m. magnesium concentration tended to be increased, and the i.m. PGE2 concentration tended to be decreased although these changes were not significant. The i.m. EMG was smaller during and after infusions of hypertonic saline compared with isotonic saline. The i.m. pressure was not different during the infusions of hypertonic and isotonic saline but was increased between the infusions of hypertonic saline. This study has shown that i.m. infusion of hypertonic saline produced a saline‐pool, causing the i.m. pressure to increase. Possibly, pain activation and cessation are related to increased intramuscular sodium and potassium content respectively.

Effect of lifelong overexpression of HSP70 in skeletal muscle on age-related oxidative stress and adaptation after nondamaging contractile activity

Skeletal muscle aging is characterized by atrophy, a deficit in specific force generation, increased susceptibility to injury, and incomplete recovery after severe injury. The ability of muscles of old mice to produce heat shock proteins (HSPs) in response to stress is severely diminished. Studies in our laboratory using HSP70 overexpressor mice demonstrated that lifelong overexpression of HSP70 in skeletal muscle provided protection against damage and facilitated successful recovery after damage in muscles of old mice. The mechanisms by which HSP70 provides this protection are unclear. Aging is associated with the accumulation of oxidation products, and it has been proposed that this may play a major role in age‐related muscle dysfunction. Muscles of old wild‐type (WT) mice demonstrated increased lipid peroxidation, decreased glutathione content, increased catalase and superoxide dismutase (SOD) activities, and an inability to activate nuclear factor (NF)‐κB after contractions in comparison with adult WT mice. In contrast, levels of lipid peroxidation, glutathione content, and the activities of catalase and SOD in muscles of old HSP70 overexpressor mice were similar to adult mice and these muscles also maintained the ability to activate NF‐κB after contractions. These data provide an explanation for the preservation of muscle function in old HSP70 overexpressor mice.—Broome, C. S., Kayani, A. C., Palomero, J., Dillmann, W. H., Mestril, R., Jackson, M. J., McArdle, A. Effect of lifelong overexpression of HSP70 in skeletal muscle on age‐related oxidative stress and adaptation after nondamaging contractile activity. FASEB J. 20, E855–E860 (2006)