Structure-activity relationships in the myotoxicity of ring-methylated p-phenylenediamines in rats and correlation with autoxidation rates in vitro

A number of N-methylated p-phenylenediamines are known to cause necrosis of skeletal and cardiac muscle in rats. The severity of the muscle damage induced by these compounds in vivo was found to be directly proportional to their autoxidation rates in vitro, suggesting that reactive species formed during oxidation may be involved in the initiation of this toxic effect. In the present study, the in vitro oxidation rates and in vivo toxicities of a number of ring-methylated p-phenylenediamines have been evaluated. 2,3,5,6-Tetramethyl p-phenylenediamine readily autoxidized at neutral pH. Hydrogen peroxide was formed in this reaction, while oxidation in the presence of glutathione or reduced pyridine nucleotides led to the production of both hydrogen peroxide and superoxide radical. Less highly methylated derivatives oxidized more slowly, with rates decreasing in the order 2,3,5,6-tetramethyl greater than 2,5-dimethyl greater than 2,6-dimethyl greater than 2-methyl. All these compounds were myotoxic in rats, with damage being largely confined to skeletal muscle. Toxicity was again proportional to oxidation rate. Myotoxicity appears to be a general property of certain substituted p-phenylenediamines and the structure-activity relationships identified may permit an estimate to be made of the potential toxicity of other compounds of this type.     

The interaction of flavonoids with mitochondria: effects on energetic processes

The study addressed aspects of energetics of isolated rat liver mitochondria exposed to the flavonoids quercetin, taxifolin, catechin and galangin, taking into account influences of the 2,3 double bond/3-OH group and 4-oxo function on the C-ring, and o-di-OH on the B-ring of their structures, as well as mitochondrial mechanisms potentially involved in cell necrosis and apoptosis. The major findings/hypothesis, were: The 2,3 double bond/3-OH group in conjugation with the 4-oxo function on the C-ring in the flavonoid structure seems favour the interaction of these compounds with the mitochondrial membrane, decreasing its fluidity either inhibiting the respiratory chain of mitochondria or causing uncoupling; while the o-di-OH on the B-ring seems favour the respiratory chain inhibition, the absence of this structure seems favour the uncoupling activity. The flavonoids not affecting the respiration of mitochondria, induced MPT. The ability of flavonoids to induce the release of mitochondria-accumulated Ca(2+) correlated well with their ability to affect mitochondrial respiration on the one hand, and their inability to induce MPT, on the other. The flavonoids causing substantial respiratory chain inhibition or mitochondrial uncoupling, quercetin and galangin, respectively, also decreased the mitochondrial ATP levels, thus suggesting an apparent higher potential for necrosis induction in relation to the flavonoids inducing MPT, taxifolin and cathechin, which did not decrease significantly the ATP levels, rather suggesting an apparent higher potential for apoptosis induction.     

Cardiac Metabolic Pathways Affected in the Mouse Model of Barth Syndrome

Cardiolipin (CL) is a mitochondrial phospholipid essential for electron transport chain (ETC) integrity. CL-deficiency in humans is caused by mutations in the tafazzin (Taz) gene and results in a multisystem pediatric disorder, Barth syndrome (BTHS). It has been reported that tafazzin deficiency destabilizes mitochondrial respiratory chain complexes and affects supercomplex assembly. The aim of this study was to investigate the impact of Taz-knockdown on the mitochondrial proteomic landscape and metabolic processes, such as stability of respiratory chain supercomplexes and their interactions with fatty acid oxidation enzymes in cardiac muscle. Proteomic analysis demonstrated reduction of several polypeptides of the mitochondrial respiratory chain, including Rieske and cytochrome c1 subunits of complex III, NADH dehydrogenase alpha subunit 5 of complex I and the catalytic core-forming subunit of F₀F₁-ATP synthase. Taz gene knockdown resulted in upregulation of enzymes of folate and amino acid metabolic pathways in heart mitochondria, demonstrating that Taz-deficiency causes substantive metabolic remodeling in cardiac muscle. Mitochondrial respiratory chain supercomplexes are destabilized in CL-depleted mitochondria from Taz knockdown hearts resulting in disruption of the interactions between ETC and the fatty acid oxidation enzymes, very long-chain acyl-CoA dehydrogenase and long-chain 3-hydroxyacyl-CoA dehydrogenase, potentially affecting the metabolic channeling of reducing equivalents between these two metabolic pathways. Mitochondria-bound myoglobin was significantly reduced in Taz-knockdown hearts, potentially disrupting intracellular oxygen delivery to the oxidative phosphorylation system. Our results identify the critical pathways affected by the Taz-deficiency in mitochondria and establish a future framework for development of therapeutic options for BTHS.     

Decreased activities of ubiquinol:ferricytochrome c oxidoreductase (complex III) and ferrocytochrome c:oxygen oxidoreductase (complex IV) in liver mitochondria from rats with hydroxycobalamin[c-lactam]-induced methylmalonic aciduria.

Rats treated with hydroxycobalamin[c-lactam] (HCCL), a cobalamin analogue that induces methylmalonic aciduria, have increased hepatic mitochondrial content and increased oxidative metabolism of pyruvate and palmitate per hepatocyte. The present studies were undertaken to characterize oxidative metabolism in isolated liver mitochondria from rats treated with HCCL. After 5-6 weeks, state 3 oxidation rates for diverse substrates are reduced in mitochondria from HCCL-treated rats. Similar reductions of mitochondrial oxidation rates are obtained with dinitrophenol-uncoupled mitochondria excluding defective phosphorylation as a cause for the observed decrease in mitochondrial oxidation. The activities of mitochondrial oxidases are reduced in HCCL-treated rats and demonstrate a defect in complex IV. Investigation of the complexes of the respiratory chain reveals a 32% decrease of ubiquinol:ferricytochrome c oxidoreductase (complex III) activity and a 72% decrease of ferrocytochrome c:oxygen oxidoreductase (complex IV) activity in mitochondria from 5-6-week HCCL-treated rats as compared with controls. Liver mitochondria from HCCL-treated rats also demonstrate decreased cytochrome content per mg of mitochondrial protein (25% decrease of cytochrome b and 52% decrease of cytochrome a + a3 as compared with control rats). The HCCL-treated rat represents an animal model for the study of the consequences of respiratory chain defects in liver mitochondria.     

Defects in the mitochondrial energy metabolism outside the respiratory chain and the pyruvate dehydrogenase complex

Disturbances in substrate oxidations in muscle mitochondria from patients with a suspicion of a mitochondrial myopathy may arise from a deficiency of one or more of the complexes of the respiratory chain or of the pyruvate dehydrogenase complex. However, we found no clear-cut defect in a substantial part of such patients. In this report we discuss some of the other possibilities which could account for the disturbed substrate oxidation rates. Special attention will be paid to defects which are localized outside the respiratory chain, such as defects in post-respiratory chain enzymes, defects in transport mechanisms of the mitochondrial inner or outer membrane, deficiency of cofactors and deficiency of heat-shock protein. (Mol Cell Biochem 174: 243–247, 1997)     

Methoxyacetic acid and ethoxyacetic acid inhibit mitochondrial function in vitro

Ethylene glycol monomethyl ether (EGME) and ethylene glycol monoethyl ether (EGEE) have recently been shown to be potent reproductive toxicants in laboratory animals. The toxicity of these compounds is believed to be due to their metabolites, methoxyacetic acid (MAA) and ethoxyacetic acid (EAA). Since the primary targets of EGME and EGEE appear to be tissues with rapidly dividing cell systems and high rates of respiration and energy metabolism, the effects of these compounds and their proposed metabolites on mitochondria were investigated. At concentrations beginning at 3.85 mM, MAA and EAA inhibited state 3 respiration and the respiratory control ratio (RCR) in hepatic mitochondria with either succinate or citrate/malate as substrates. Cytochrome c oxidase activity was also inhibited by both metabolites at similar concentrations. The effects of MAA, the metabolite from the more potent compound, on testicular mitochondria were found to be comparable. Neither EGME or EGEE appeared to affect mitochondrial function at concentrations as high as 238 or 113 mM, respectively. These results support the hypothesis that the toxicity of EGME and EGEE are due to their metabolites, MAA and EAA, and that these metabolites may exert their effects, in part, on mitochondrial function.     

Impaired substrate utilization in mitochondria from strain 129 dystrophic mice

Mitochondria from skeletal muscle, heart and liver of strain 129/ReJ-dy dystrophic mice and their littermate controls were characterized with respect to their respiratory and phosphorylating activities. Skeletal muscle mitochondria from dystrophic mice showed significantly lower state 3 respiratory rates than controls with both pyruvate + malate and succinate as substrates (P < 0.01). ADP/O and Ca²⁺/O ratios were found to be normal. A decreased rate of NADH oxidation (0.01 <P < 0.05) by sonicated mitochondrial suspensions from dystrophic mice was also seen. High respiratory rates with ascorbate + phenazine methosulfate as substrates indicated that cytochrome oxidase was not rate limiting in the oxidation of either pyruvate + malate or succinate. Skeletal muscle mitochondria from dystrophic mice showed no deficiency in any of the cytochromes or coenzyme Q. Mg²⁺-stimulated ATPase activity was higher in dystrophic muscle mitochondria than in controls, but basal and oligomycin-insensitive activities were virtually identical to those of controls. A significant reduction in the intramitochondrial NAD⁺ content (0.01 <P < 0.02) was seen in dystrophic skeletal muscle as compared to controls. Heart mitochondria from dystrophic mice showed similar, though less extensive abnormalities while liver mitochondria were essentially normal. We concluded from these results that skeletal muscle mitochondria from strain 129 dystrophic mice possess impairments in substrate utilization which may result from (1) an abnormality in the transfer of electrons on the substrate side of coenzyme Q in the case of succinate oxidation; (2) a defect on the path of electron flow from NADH to cytochrome c, and (3) a deficiency of NAD⁺ in the case of NAD⁺-linked substrates.     

硒对大鼠心、肝、肌、胰、肺和肾脏细胞线粒体~(45)Ca摄取的影响

用低硒饲料和该饲料补硒分别喂大鼠,对比观察硒对动物心、肝,肌、胰、肺和肾脏线粗体~(45)Ca摄取及心肌线粒体呼吸的影响。结果表明硒非常显著地刺激此六脏器细胞线粒体钙摄取,其中,对心、肝、肌的刺激强大而稳定;对胰、肺,在温育过程中逐渐增强;对肾则稍差。硒还非常显著地刺激心肌线粒体呼吸功能。提示硒对维持整体线粒体钙运转及心肌线粒体呼吸功能具重要作用。     

Oxidative phosphorylation in human muscle in patients with ocular myopathy and after general anaesthesia

The fuel preference of human muscle mitochondria has been given. Substrates which are oxidized with low velocity cannot be used to detect defects in oxidative phosphorylation. After general anaesthesia, the oxygen uptake with the different substrates is much lower than after local analgesia. The latter was therefore used in the subsequent study. In 15 out of 18 patients with ocular myopathy, defects in oxidative phosphorylation could be detected in isolated muscle mitochondria prepared from freshly biopsied tissue. Measurement of the activity of segments of the respiratory chain in homogenate from frozen muscle showed no, or minor defects. In two of these patients showing exercise intolerance, decreased oxidation of NAD(+)-linked substrates and apparently normal mitochondrial DNA, further study revealed deficiency of pyruvate dehydrogenase in a girl with ptosis and a high Km of complex I for NADH in a man. Both patients responded to vitamin therapy.     

Hepatotoxicity due to mitochondrial dysfunction

Mitochondria are involved in fatty acid β-oxidation, the tricarboxylic acid cycle, and oxidative phosphorylation, which provide most of the cell energy. Mitochondria are also the main source of reactive oxygen species in the cell and are involved in cell demise through opening of the mitochondrial permeability transition pore. It was therefore to be expected that mitochondrial dysfunction could be a major mechanism of drug-induced liver disease. Microvesicular steatosis (which may cause liver failure, coma, and death) is the consequence of severe impairment of mitochondrial β-oxidation. Endogenous compounds (such as cytokines or female sex hormones) or xenobiotics (including toxins such as ethanol and drugs such as aspirin, valproic acid, ibuprofen, or zidovudine) can inhibit β-oxidation directly or through a primary effect on the mitochondrial genome or the respiratory chain itself. In some patients, infections and cytokines, or inborn errors of β-oxidation enzymes or the mitochondrial genome, may favor the appearance of drug-induced microvesicular steatosis. Nonalcoholic steatohepatitis may develop under conditions causing prolonged, microvesicular, and/or macrovacuolar steatosis. In this condition, chronic impairment of mitochondrial β-oxidation (causing steatosis) and the respiratory chain (increasing the production of ROS) lead to lipid peroxidation, which, in turn, may cause the diverse lesions of steatohepatitis, namely, necrosis, inflammation, Mallory's bodies, and fibrosis. Finally, mitochondria are involved in several forms of drug-induced cytolytic hepatitis, through inhibition or uncoupling of respiration or through a drug-induced or reactive metabolite-induced mitochondrial permeability transition. The latter effect commits hepatocytes to either apoptosis or necrosis, depending on the number of organelles that have undergone the permeability transition. This revised version was published online in July 2006 with corrections to the Cover Date.     

Inhibition of acetyl-carnitine oxidation in rat brown-adipose-tissue mitochondria by erucoyl-carnitine is due to sequestration of CoA

The cause underlying the inhibitory effect of erucoyl-carnitine on acetyl-carnitine oxidation in rat brown-adipose-tissue mitochondria was investigated. The inhibition was shown to be of a noncompetitive nature, with an I50 of about 10 microM erucoyl-carnitine. Erucoyl-carnitine did not inhibit the respiratory chain or the citric acid cycle to a significant degree. Incubation of mitochondria with erucoyl-carnitine led to about 2/3 of all CoA being sequestered in the form of acid-insoluble esters (probably erucoyl-CoA). This sequestration had an apparent Km of about 10 microM. Erucoyl-carnitine also inhibited pyruvate oxidation with an I50 of about 10 microM. When added at this concentration, it also inhibited the oxidation of a wide variety of acyl-carnitines by about 50%, despite very different oxidation rates of these different acyl-carnitines. It was concluded that the inhibitory effect of erucoyl-carnitine on all CoA-dependent substrates could be adequately explained by the suggestion that erucoyl sequesters a significant fraction of mitochondrial matrix CoA as slowly metabolizable erucoyl-CoA esters. Possible physiological effects of this sequestration for brown adipose tissue thermogenesis are discussed.     

Acute effect of fatty acids on metabolism and mitochondrial coupling in skeletal muscle

Acute effects of free fatty acids (FFA) were investigated on: (1) glucose oxidation, and UCP-2 and -3 mRNA and protein levels in 1 h incubated rat soleus and extensor digitorium longus (EDL) muscles, (2) mitochondrial membrane potential in cultured skeletal muscle cells, (3) respiratory activity and transmembrane electrical potential in mitochondria isolated from rat skeletal muscle, and (4) oxygen consumption by anesthetized rats. Long-chain FFA increased both basal and insulin-stimulated glucose oxidation in incubated rat soleus and EDL muscles and reduced mitochondrial membrane potential in C2C12 myotubes and rat skeletal muscle cells. Caprylic, palmitic, oleic, and linoleic acid increased O₂ consumption and decreased electrical membrane potential in isolated mitochondria from rat skeletal muscles. FFA did not alter UCP-2 and -3 mRNA and protein levels in rat soleus and EDL muscles. Palmitic acid increased oxygen consumption by anesthetized rats. These results suggest that long-chain FFA acutely lead to mitochondrial uncoupling in skeletal muscle.     

Acute effect of fatty acids on metabolism and mitochondrial coupling in skeletal muscle

Acute effects of free fatty acids (FFA) were investigated on: (1) glucose oxidation, and UCP-2 and -3 mRNA and protein levels in 1 h incubated rat soleus and extensor digitorium longus (EDL) muscles, (2) mitochondrial membrane potential in cultured skeletal muscle cells, (3) respiratory activity and transmembrane electrical potential in mitochondria isolated from rat skeletal muscle, and (4) oxygen consumption by anesthetized rats. Long-chain FFA increased both basal and insulin-stimulated glucose oxidation in incubated rat soleus and EDL muscles and reduced mitochondrial membrane potential in C2C12 myotubes and rat skeletal muscle cells. Caprylic, palmitic, oleic, and linoleic acid increased O(2) consumption and decreased electrical membrane potential in isolated mitochondria from rat skeletal muscles. FFA did not alter UCP-2 and -3 mRNA and protein levels in rat soleus and EDL muscles. Palmitic acid increased oxygen consumption by anesthetized rats. These results suggest that long-chain FFA acutely lead to mitochondrial uncoupling in skeletal muscle.     

Influence of oxidative processes in mitochondria on contractility of the frog Rana temporaria heart muscle. Effects of cadmium

The inotropic Cd2+ action on frog heart is studied with taking into account its toxic effects upon mitochondria. Cd2+ at concentrations of 1, 10, and 20 microM is established to decrease dosedependently (21.3, 50.3, and 72.0%, respectively) the muscle contraction amplitude; this is explained by its competitive action on the potential-controlled Ca2(+)-channels of the L-type (Ca 1.2). In parallel experiments on isolated rat heart mitochondria (RHM) it was shown that Cd2+ at concentrations of 15 and 25 microM produces swelling of non-energized and energized mitochondria in isotonic (with KNO2 and NH4NO3) and hypoosmotic (with 25 mM CH3COOK) media. Study of oxidative processes in RHM by polarographic method has shown 20 microM Cd2+ to disturb activity of respiratory mitochondrial chain. The rate of endogenous respiration of isolated mitochondria in the medium with Cd2+ in the presence of malate and succinate was approximately 5 times lower than in control. In experimental preparations, addition into the medium of DNP-uncoupler of oxidation and phosphorylation did not cause an increase of the oxygen consumption rate. Thus, the obtained data indicate that a decrease in the cardiac muscle contractility caused by Cd2+ is due not only to its direct blocking action on Ca2(+)-channels, but also is mediated by toxic effect on rat heart mitochondria, which was manifested as an increase in ion permeability of the inner mitochondrial membrane (IMM), acceleration of the energy-dependent K+ transport into the matrix of mitochondria, and inhibition of their respiratory chain.     

Characterisation of oxidative phosphorylation in skeletal muscle mitochondria subpopulations in pig: a study using top-down elasticity analysis

In skeletal muscle, two mitochondrial populations are present which, on the basis of their localisation, are termed intermyofibrillar and subsarcolemmal mitochondria (IMF and SS, respectively). These two populations have different biochemical characteristics and show different responses to physiological stimuli. In this paper, we characterise the oxidative phosphorylation of SS and IMF using 'top-down' elasticity analysis. We excluded the possibility that their different characteristics can be attributed to a different degree of breakage of the two types of mitochondria due to the different isolation procedures used in their preparation. The higher respiration rate and higher respiratory control ratio shown by IMF compared with those shown by SS are principally due to the higher activities of the reactions involved in substrate oxidation as confirmed by the measurement of cytochrome oxidase activity. There is no difference in the leak of protons across the inner mitochondrial membrane between IMF and SS; a faster rate of ATP synthesis and turnover is driven by the lower membrane potential in SS compared with in IMF.     

High resolution respirometry of permeabilized skeletal muscle fibers in the diagnosis of neuromuscular disorders

High resolution respirometry in combination with the skinned fiber technique offers the possibility to study mitochondrial function routinely in small amounts of human muscle. During a period of 2 years, we investigated mitochondrial function in skeletal muscle tissue of 13 patients (average age = 5.8 years). In all of them, an open muscle biopsy was performed for diagnosis of their neuromuscular disorder. Mitochondrial oxidation rates were measured with a highly sensitive respirometer. Multiple substrate-inhibitor titration was applied for investigation of mitochondrial function. About 50 mg fibers were sufficient to obtain maximal respiratory rates for seven different substrates (pyruvate/malate, glutamate/malate, octanoylcarnitine/malate, palmitoylcarnitine /malate, succinate, durochinol and ascorbate/TMPD). Decreased respiration rates with reference to the wet weight of the permeabilized fiber could immediately be detected during the course of measurements.In 4 patients with mitochondrial encephalomyopathy (MEM) the respiration pattern indicated a specific mitochondrial enzyme defect, which was confirmed in every patient by measurements of the individual enzymes (one patient with PDHC deficiency, one with complex I deficiency and two patients with combined complex I and IV deficiency). In the 6 patients with spinal muscular atrophy (SMA) oxidation rates were found to be decreased to 23 ± 5% of controls. The normalized respiration pattern was comparable to that of the controls indicating a decreased content of mitochondria in SMA muscle with normal functional properties. Also in the 3 patients with Duchenne muscular dystrophy (DMD) decreased oxidation rates (42 ± 5%) were detected. In addition a low RCI (1.2) indicated a loose coupling of oxidative phosphorylation in the mitochondria of these patients.It is concluded that investigation of mitochondrial function in saponin skinned muscle fibers using high resolution respirometry in combination with multiple substrate titration offers a valuable tool for evaluation of mitochondrial alterations in muscle biopsies of children suffering from neuromuscular disorders. (Mol Cell Biochem 174: 71–78, 1997)     

Functional studies on in situ-like mitochondria isolated in the presence of polyvinyl pyrrolidone

Mitochondria isolated and maintained in sucrose mannitol medium show a large intermembrane space and a condensed matrix unlike the appearance of in situ mitochondria. Mitochondria resembling in situ organelles are obtained when the isolation medium is supplemented with certain macromolecules such as polyvinyl pyrrolidone. We found that the in situ appearance was acquired also by the conventionally isolated mitochondria when they were exposed to 2% polyvinyl pyrrolidone supplemented medium. Paradoxically, however, these in situ looking mitochondria proved functionally inferior in that their brief incubation without substrates led to a marked loss of their ability to respire with subsequently added substrates such as pyruvate, acylcarnitines or glutamate. The oxidation of succinate was, however, not so affected. This phenomenon was shared by heart and skeletal muscle mitochondria of different animal species but not by rat liver mitochondria. The inhibition of respiration could not be related to the failure to oxidize NADH, to the tieing up of mitochondrial free CoASH, or to the increased matrix space of mitochondria that was observed in the presence of polyvinyl pyrrolidone. The polyvinyl pyrrolidone-exposed mitochondria regained their respiratory ability on being freed from polyvinyl pyrrolidone. The same phenomenon was seen also when the medium contained 2% albumin or 20% Ficoll.     

Arachidonic acid causes cell death through the mitochondrial permeability transition. Implications for tumor necrosis factor-alpha aopototic signaling

We have investigated the effects of arachidonic and palmitic acids in isolated rat liver mitochondria and in rat hepatoma MH1C1 cells. We show that both compounds induce the mitochondrial permeability transition (PT). At variance from palmitic acid, however, arachidonic acid causes a PT at concentrations that do not cause PT-independent depolarization or respiratory inhibition, suggesting a specific effect on the PT pore. When added to intact MH1C1 cells, arachidonic acid but not palmitic acid caused a mitochondrial PT in situ that was accompanied by cytochrome c release and rapidly followed by cell death. All these effects of arachidonic acid could be prevented by cyclosporin A but not by the phospholipase A(2) inhibitor aristolochic acid. In contrast, tumor necrosis factor alpha caused phospholipid hydrolysis, induction of the PT, cytochrome c release, and cell death that could be inhibited by both cyclosporin A and aristolochic acid. These findings suggest that arachidonic acid produced by cytosolic phospholipase A(2) may be a mediator of tumor necrosis factor alpha cytotoxicity in situ through induction of the mitochondrial PT.     

Mitochondria in exercise-induced oxidative stress

In recent years it has been suggested that reactive oxygen species (ROS) are involved in the damage to muscle and other tissues induced by acute exercise. Despite the small availability of direct evidence for ROS production during exercise, there is an abundance of literature providing indirect support that oxidative stress occurs during exercise. The electron transport associated with the mitochondrial respiratory chain is considered the major process leading to ROS production at rest and during exercise. It is widely assumed that during exercise the increased electron flow through the mitochondrial electron transport chain leads to an increased rate of ROS production. On the other hand, results obtained by in vitro experiments indicate that mitochondrial ROS production is lower in state 3 (ADP-stimulated) than in state 4 (basal) respiration. It is possible, however, that factors, such as temperature, that are modified in vivo during intense physical activity induce changes (uncoupling associated with loss of cytochrome oxidase activity) leading to increased ROS production. The mitochondrial respiratory chain could also be a potential source of ROS in tissues, such as liver, kidney and nonworking muscles, that during exercise undergo partial ischemia because of reduced blood supply. Sufficient oxygen is available to interact with the increasingly reduced respiratory chain and enhance the ROS generation. At the cessation of exercise, blood flow to hypoxic tissues resumes leading to their reoxygenation. This mimics the ischemia-reperfusion phenomenon, which is known to cause excessive production of free radicals. Apart from a theoretical rise in ROS, there is little evidence that exercise-induced oxidative stress is due to its increased mitochondrial generation. On the other hand, if mitochondrial production of ROS supplies a remarkable contribution to exercise-induced oxidative stress, mitochondria should be a primary target of oxidative damage. Unfortunately, there are controversial reports concerning the exercise effects on structural and functional characteristics of mitochondria. However, the isolation of mitochondrial fractions by differential centrifugation has shown that the amount of damaged mitochondria, recovered in the lightest fraction, is remarkably increased by long-lasting exercise.     

Abnormalities of mitochondrial functioning can partly explain the metabolic disorders encountered in sarcopenic gastrocnemius

Aging triggers several abnormalities in muscle glycolytic fibers including increased proteolysis, reactive oxygen species (ROS) production and apoptosis. Since the mitochondria are the main site of substrate oxidation, ROS production and programmed cell death, we tried to know whether the cellular disorders encountered in sarcopenia are due to abnormal mitochondrial functioning. Gastrocnemius mitochondria were extracted from adult (6 months) and aged (21 months) male Wistar rats. Respiration parameters, opening of the permeability transition pore and ROS production, with either glutamate (amino acid metabolism) or pyruvate (glucose metabolism) as a respiration substrate, were evaluated at different matrix calcium concentrations. Pyruvate dehydrogenase and respiratory complex activities as well as their contents measured by Western blotting analysis were determined. Furthermore, the fatty acid profile of mitochondrial phospholipids was also measured. At physiological calcium concentration, state III respiration rate was lowered by aging in pyruvate conditions (-22%), but not with glutamate. The reduction of pyruvate oxidation resulted from a calcium-dependent inactivation of the pyruvate dehydrogenase system and could provide for the well-known proteolysis encountered during sarcopenia. Matrix calcium loading and aging increased ROS production. They also reduced the oxidative phosphorylation. This was associated with lower calcium retention capacities, suggesting that sarcopenic fibers are more prone to programmed cell death. Aging was also associated with a reduced mitochondrial superoxide dismutase activity, which does not intervene in toxic ROS overproduction but could explain the lower calcium retention capacities. Despite a lower content, cytochrome c oxidase displayed an increased activity associated with an increased n-6/n-3 polyunsaturated fatty acid ratio of mitochondrial phospholipids. In conclusion, we propose that mitochondria obtained from aged muscle fibers display several functional abnormalities explaining the increased proteolysis, ROS overproduction and vulnerability to apoptosis exhibited by sarcopenic muscle. These changes appear to be related to modifications of the fatty acid profile of mitochondrial lipids.