Lipid peroxide and antioxidant enzymes in muscle and nonmuscle of dystrophic mouse

The role of free radicals in the pathophysiology of muscular dystrophy

Null mutation of any one of several members of the dystrophin protein complex can cause progressive, and possibly fatal, muscle wasting. Although these muscular dystrophies arise from mutation of a single gene that is expressed primarily in muscle, the resulting pathology is complex and multisystemic, which shows a broader disruption of homeostasis than would be predicted by deletion of a single-gene product. Before the identification of the deficient proteins that underlie muscular dystrophies, such as Duchenne muscular dystrophy (DMD), oxidative stress was proposed as a major cause of the disease. Now, current knowledge supports the likelihood that interactions between the primary genetic defect and disruptions in the normal production of free radicals contribute to the pathophysiology of muscular dystrophies. In this review, we focus on the pathophysiology that results from dystrophin deficiency in humans with DMD and the mdx mouse model of DMD. Current evidence indicates three general routes through which free radical production can be disrupted in dystrophin deficiency to contribute to the ensuing pathology. First, constitutive differences in free radical production can disrupt signaling processes in muscle and other tissues and thereby exacerbate pathology. Second, tissue responses to the presence of pathology can cause a shift in free radical production that can promote cellular injury and dysfunction. Finally, behavioral differences in the affected individual can cause further changes in the production and stoichiometry of free radicals and thereby contribute to disease. Unfortunately, the complexity of the free radical-mediated processes that are perturbed in complex pathologies such as DMD will make it difficult to develop therapeutic approaches founded on systemic administration of antioxidants. More mechanistic knowledge of the specific disruptions of free radicals that underlie major features of muscular dystrophy is needed to develop more targeted and successful therapeutic approaches.

Molecular pathophysiology of myofiber injury in deficiencies of the dystrophin-glycoprotein complex

Duchenne muscular dystrophy is caused by mutations in the gene encoding dystrophin, a 427 kd protein normally found at the cytoplasmic face of the sarcolemma. In normal muscle, dystrophin is associated with a multimolecular glycoprotein complex. Primary mutations in the genes encoding members of this glycoprotein complex are also associated with muscular dystrophy. The dystrophin-glycoprotein complex provides a physical linkage between the internal cytoskeleton of myofibers and the extracellular matrix, but the precise functions of the dystrophin-glycoprotein complex remain uncertain. In this review, five potential pathogenetic mechanisms implicated in the initiation of myofiber injury in dystrophin-glycoprotein complex deficiencies are discussed: (1) mechanical weakening of the sarcolemma, (2) inappropriate calcium influx, (3) aberrant cell signaling, (4) increased oxidative stress, and (5) recurrent muscle ischemia. Particular emphasis is placed on the multifunctional nature of the dystrophin-glycoprotein complex and the fact that the above mechanisms are in no way mutually exclusive and may interact with one another to a significant degree.

The effects of fish oil and isoflavones on delayed onset muscle soreness

INTRODUCTION/PURPOSE

Fish oils (FO) have been shown to modulate the inflammatory response through alteration of the eicosanoid pathway. Isoflavones (ISO) appear to reduce the inflammatory pathway through their role as a tyrosine kinase inhibitor. Delayed onset muscle soreness (DOMS) develops after intense exercise and has been associated with an inflammatory response. Therefore, we hypothesized that physical parameters associated with DOMS could be decreased via the modulation of the inflammatory response by supplementing subjects with either FO or ISO.

METHODS

22 subjects were recruited and randomly assigned to one of three treatment groups: FO (1.8 g of omega-3 fatty acids x d(-1)), ISO (120 mg soy isolate x d(-1)), or placebo (PL) (Western fat blend and/or wheat flour). All treatment groups received 100-IU vitamin E x d(-1) to minimize lipid peroxidation of more highly unsaturated fatty acids. Subjects were supplemented 30 d before the exercise and during the week of testing and were instructed to refrain from unusual exercise. DOMS was induced by 50 maximal isokinetic eccentric elbow flexion contractions. Strength parameters, pain, arm circumference, and relaxed arm angle (RANG) were measured at 48, 72, and 168 h post exercise. Cortisol, creatine kinase (CK), interleukin-6 (IL-6), tumor necrosis factor (TNFalpha), malondialdehyde (MDA), and serum iron were measured before supplementation, after supplementation, and post exercise.

RESULTS

Significant decreases were observed in RANG and strength 48 h postexercise among all groups, and there were significant increases in pain and arm circumference. There were no significant changes among all groups from baseline at 168 h (7 d) post exercise. There were no significant treatment effects between groups for the physical parameters or for cortisol, CK, IL-6, TNFalpha, MDA, or serum iron.

CONCLUSION

These data indicate FO or ISO, at the doses supplemented, were not effective in ameliorating DOMS with the above-cited protocol.

Appearance of cross linked proteins in human atheroma and rat pre-fibrotic liver detected by a new monoclonal antibody

A new monoclonal antibody against malondialdehyde (MDA)-treated low density lipoprotein (LDL) was raised using homogenate of human atheroma as immunogen. This antibody, DLH2, was obtained by selecting the clones which did not react to native LDL but did react to copper-induced oxidized LDL (OxLDL). DLH2 showed a greater reactivity to MDA-LDL than to OxLDL. When LDL was treated with various aldehyde containing reagents, treatment of LDL with glutaraldehyde or MDA greatly increased the reactivity to the antibody, while LDL treated with 2,4-hexadienal or 4-hydroxynonenal was not reactive. Among many proteins tested, high density lipoprotein, bovine serum albumin and hemoglobin showed significant reactivity to DLH2 after they were treated with MDA or glutaraldehyde. When low density and high density lipoproteins treated with MDA were subjected to immunoblot analysis, newly formed products larger than the original apolipoproteins were detected with the antibody, suggesting that this antibody recognizes aggregated proteins with divalent short chain cross linkers. The antigenic materials were shown by immunohistochemical analysis to be present in foamy macrophages in human atheromatous lesions. DLH2 antigen did not colocalize either with apolipoprotein B. Furthermore, we found a massive accumulation of the antigenic material in Kupffer cells in the liver of rats treated with alcohol and carbonyl iron, a model of hepatic fibrosis due to oxidative stress. These results suggest the presence of cross linked proteins in damaged tissues.

Examination of telomere lengths in muscle tissue casts doubt on replicative aging as cause of progression in Duchenne muscular dystrophy

The mean telomere length (TL) of somatic cells indicates their replicative age. In comparison with normal leukocytes (-0.03 kbp/y, 6.2 kbp at 80 y), we found advanced TL shortening in premature aging due to ataxia-telangiectasia or the Nijmegen chromosomal breakage syndrome. Duchenne muscular dystrophy (DMD) has been related to replicative senescence of satellite cells (SCs) caused by increased fiber turnover. Therefore, we determined TLs in DMD muscle. Because the regenerated fiber nuclei are produced by SCs. telomeres of both fiber and SC nuclei should be shortened. In DMD the SC number is increased. We determined that up to the age of 7 y the sum of fiber and SC nuclei should be large enough (73%) for the detection of TL shortening. Normal muscle fibers have negligible turnover rates, and, as expected, we did not find age-related TL shortening (10-83 y, n = 24, 8.3 +/- 0.5 kbp). Surprisingly, there was only slight TL shortening in patient muscles (DMD, 0.3-4.8 y, n = 4, 8.3 +/- 0.7 kbp; 5-7 y, n = 7, 7.9 +/- 0.4 kbp; limb-girdle muscular dystrophy 2C, 13 y, 7.6 kbp; Becker muscular dystrophy, 7 y, 8.5 kbp). Similarly, the peak positions of the telomere blots varied only slightly (DMD, 10.0 +/- 0.9 kbp; normal: 10.7 +/- 0.9 kbp). In accordance with our TL findings we derived less than 4 annual doublings per SC from published histologic data on DMD.

Wheat kernel ingestion protects from progression of muscle weakness in mdx mice, an animal model of Duchenne muscular dystrophy

A simple, reproducible test was used to quantify muscle weakness in mdx mice, an animal model of Duchenne muscular dystrophy. The effect of bedding on wheat kernels and of dietary supplementation of alpha-tocopherol on the progression of muscle weakness was investigated in mdx mice. When measured during the first 200 d of life, mdx mice developed muscle weakness, irrespective of bedding and diet. When kept on wood shavings and fed a conventional rodent diet, mdx mice showed progressive muscle weakness over the consecutive 200 d, and eventually showed a significant weight loss during the next 200-d observation period. Progression of muscle weakness and weight loss were almost completely prevented in mdx mice that were kept on wheat kernel bedding. In contrast, only incomplete maintenance of muscle strength and body weight was observed in mdx mice kept on wood shavings and fed the alpha-tocopherol-supplemented diet. It is concluded from these experiments that a component of wheat kernels other than alpha-tocopherol is essential to prevent the progression of muscle weakness in mdx mice.

Endogenous skeletal muscle antioxidants

Skeletal muscle is susceptible to oxidative deterioration due to a combination of lipid oxidation catalysts and membrane lipid systems that are high in unsaturated fatty acids. To prevent or delay oxidation reactions, several endogenous antioxidant systems are found in muscle tissue. These include alpha-tocopherol, histidine-containing dipeptides, and antioxidant enzymes such as glutathione peroxidase, superoxide dismutase, and catalase. The contribution of alpha-tocopherol to the oxidative stability of skeletal muscle is largely influenced by diet. Dietary supplementation of tocopherol has been shown to increase muscle alpha-tocopherol concentrations and inhibit both lipid oxidation and color deterioration. Dietary selenium supplementation has also been shown to increase the oxidative stability of muscle presumably by increasing the activity of glutathione peroxidase. The oxidative stability of skeletal muscle is also influenced by the histidine-containing dipeptides, carnosine and anserine. Whereas carnosine and anserine are affected by diet less than alpha-tocopherol and glutathione peroxidase, their concentrations vary widely with species and muscle type. In pigs, beef, and turkey muscle, carnosine concentrations are greater than anserine, while the opposite is true in rabbit, salmon, and chicken muscle. Anserine and carnosine are found in greater concentrations in muscle high in white fibers, with chicken white muscle containing over fivefold more anserine and carnosine than red muscle. Anserine and carnosine are thought to inhibit lipid oxidation by a combination of free radical scavenging and metal chelation.

Elevation of the level of thiobarbituric acid-reactive products in hindleg skeletal muscle of dystrophic mice, but non-elevation in tongue muscle

In order to understand the pathogenesis of mouse muscular dystrophy, we investigated the levels of the thiobarbituric acid-reactive substances (TBARS), H2O2 and NADPH oxidase activity, which were relative to the acceleration of oxidative conditions, in tongue and hindleg skeletal muscles from C57BL/6J-dy mice. The TBARS content (702 nmol/g protein) in skeletal muscles from 2-months-old dystrophic mice was increased significantly over that (384 nmol/g protein) in muscles from age-matched normal mice. The H2O2 concentration in dystrophic skeletal muscles was 30% higher than that in normal ones. Microsomal NADPH oxidase activity which was related to the production of superoxide anions, was similar between dystrophic muscles (4.66 nmol/10 min/mg protein) and normal muscles (4.11 nmol/10 min/mg protein). These results indicate that oxidation is accelerated in the dystrophic muscles. However, the TBARS content in the tongues of dystrophic mice was identical to that of normal mice. This finding supports our bone-muscle growth imbalance hypothesis for the pathogenesis of mouse muscular dystrophy.

Concentration of lipid peroxide in serum lipoproteins of insulin-dependent diabetic children

Lipids, apolipoproteins and lipid peroxide were measured in the sera of 29 children with insulin-dependent diabetes mellitus. Ten non-diabetic children served as controls. High-density lipoprotein (HDL) was separated by heparin-MnCl2 precipitation. Lipid peroxides in HDL and non-HDL fractions were estimated by fluorimetric measurement of thiobarbituric acid-reactive substances. The patients were normolipidemic, and their HDL-cholesterol was increased. Apo A1 level in the patients was similar to that in the controls, while levels of apo A2 and apo B were decreased in the patients. Concentrations of lipid peroxides in the whole serum and non-HDL were unaltered, while that in the HDL was higher in the patients than in the controls. Hemoglobin AIc in the patients correlated with the triglyceride and urinary excretion rate of N-acetylglucosaminidase (NAG). The NAG correlated with the triglycerides. The triglycerides correlated with the atherogenic index, apo B and total cholesterol. The lipid peroxides in the non HDL correlated with the triglyceride, atherogenic index, and NAG. That in the HDL correlated with the HDL-cholesterol, apo A1 and endogenous creatinine clearance, and inversely with the atherogenic index and apo B. Lipid peroxides in HDL and non-HDL appeared to play different physiological roles from each other, and they have provided evidence suggesting that diabetic microvascular injury is mediated by reactive oxygen species.

Peroxisomal oxidases in various tissues of diabetic rats

The effect of diabetes mellitus induced by streptozotocin on the activities of peroxisomal oxidases and H2O2-metabolizing enzymes, and lipid peroxidation in various rat tissues were investigated. Peroxisomal acyl-CoA oxidase, D-amino acid oxidase and L-alpha-hydroxyacid oxidase were measured by a sensitive spectrophotometric method using dichlorofluorescein/peroxidase as the detector of H2O2. Acyl-CoA oxidase activity was increased most markedly in the heart of diabetic rats, less markedly in the liver, and tended to be increased in the kidneys. The activities of other peroxisomal oxidases were much lower than that of acyl-CoA oxidase in the liver and kidneys, and were undetectable in the heart. Catalase activity was decreased in the liver and kidneys of diabetics, and was increased in the heart. Glutathione peroxidase activity was increased more markedly in the kidneys of the diabetics, and less markedly in the heart than in the liver. Lipid peroxide level was higher in the kidneys of the diabetics than in the controls, unchanged in the heart, and was lower in the liver of the diabetics than in the controls. Thus, peroxisomal beta-oxidation and the H2O2 production coupled with that, were activated in various tissues of diabetic rats, presumably as a part of the overall increase in lipid oxidation. However, they did not appear to contribute to the enhanced oxidative stress induced by diabetes mellitus.

Antioxidant enzymes and lipoperoxide in blood in patients with Kawasaki disease. Comparison with the changes in acute infections

Increased production of active oxygen species from activated neutrophils is postulated to contribute to endothelial damage in Kawasaki disease, leading to the formation of coronary aneurysms. To determine whether an altered oxidant-antioxidant balance exists in acute phase of Kawasaki disease, antioxidant enzymes in peripheral blood cells and plasma lipid peroxide were measured in patients. The two isoenzymes of intracellular superoxide dismutase were assayed by specific radioimmunoassays. Lipid peroxide in plasma and manganese superoxide dismutase in both polymorphs and lymphocytes were increased in the acute phase of Kawasaki disease. The erythrocyte glutathione peroxidase and catalase were also increased. On the other hand, copper zinc superoxide dismutase in polymorphs, lymphocytes and erythrocytes was unaltered. Acute infections did not appear to modify the levels of either antioxidant enzymes or lipid peroxide in blood. These results suggest that increased oxidative stress in Kawasaki disease evokes a reactive increase in antioxidant enzymes, and that this response in the defense system is related to the reversible nature of the tissue damage in most patients with Kawasaki disease.

Oxidative muscular injury and its relevance to hyperthyroidism

In experimental hyperthyroidism, acceleration of lipid peroxidation occurs in heart and slow-oxidative muscles, suggesting the contribution of reactive oxygen species to the muscular injury caused by thyroid hormones. This article reviews various models of oxidative muscular injury and considers the relevance of the accompanying metabolic derangements to thyrotoxic myopathy and cardiomyopathy, which are the major complications of hyperthyroidism. The muscular injury models in which reactive oxygen species are supposed to play a role are ischemia/reperfusion syndrome, exercise-induced myopathy, heart and skeletal muscle diseases related to the nutritional deficiency of selenium and vitamin E and related disorders, and genetic muscular dystrophies. These models provide evidence that mitochondrial function and the glutathione-dependent antioxidant system are important for the maintenance of the structural and functional integrity of muscular tissues. Thyroid hormones have a profound effect on mitochondrial oxidative activity, synthesis and degradation of proteins and vitamin E, the sensitivity of the tissues to catecholamine, the differentiation of muscle fibers, and the levels of antioxidant enzymes. The large volume of circumstantial evidence presented here indicates that hyperthyroid muscular tissues undergo several biochemical changes that predispose them to free radical-mediated injury.

Antioxidant enzymes and lipoperoxide in blood in uremic children and adolescents

To determine whether oxidant-antioxidant balance is altered in chronic renal failure, antioxidant enzymes and lipid peroxide in peripheral blood cells and lipid peroxide in plasma were measured. Nine children and adolescents maintained on hemodialysis (HD), 9 on continuous ambulatory peritoneal dialysis (CAPD), and 14 controls were studied. Lipid peroxide was assayed fluorimetrically as thiobarbituric acid-reactive substances, superoxide dismutases by radioimmunoassays. Both manganese and copper-zinc superoxide dismutases in lymphocytes and monocytes in the HD and CAPD patients, and manganese superoxide dismutase in polymorphs in the HD patients were higher than in the controls. Copper-zinc superoxide dismutase, glutathione peroxidase, and catalase in erythrocytes were unaltered. The lipid peroxide level in plasma in the dialyzed patients was increased, whereas those in polymorphs and lymphocytes were unaltered. Triglyceride and total cholesterol in plasma in the dialyzed patients were also increased. The plasma lipid peroxide in the patients correlated with the triglyceride and total cholesterol level. This is the first study in which manganese superoxide dismutase is measured in nucleated cells of the patients with chronic renal failure. The present results suggest that increased superoxide dismutases protect against oxidative stress induced by chronic renal failure in nucleated cells but in neither erythrocytes nor plasma.