Open-Loop Control of Oxidative Phosphorylation in Skeletal and Cardiac Muscle Mitochondria by Ca2+

In cardiac muscle, mitochondrial ATP synthesis is driven by demand for ATP through feedback from the products of ATP hydrolysis. However, in skeletal muscle at higher workloads there is an apparent contribution of open-loop stimulation of ATP synthesis. Open-loop control is defined as modulation of flux through a biochemical pathway by a moiety, which is not a reactant or a product of the biochemical reactions in the pathway. The role of calcium, which is known to stimulate the activity of mitochondrial dehydrogenases, as an open-loop controller, was investigated in isolated cardiac and skeletal muscle mitochondria. The kinetics of NADH synthesis and respiration, feedback from ATP hydrolysis products, and stimulation by calcium were characterized in isolated mitochondria to test the hypothesis that calcium has a stimulatory role in skeletal muscle mitochondria not apparent in cardiac mitochondria. A range of respiratory states were obtained in cardiac and skeletal muscle mitochondria utilizing physiologically relevant concentrations of pyruvate and malate, and flux of respiration, NAD(P)H fluorescence, and rhodamine 123 fluorescence were measured over a range of extra mitochondrial calcium concentrations. We found that under these conditions calcium stimulates NADH synthesis in skeletal muscle mitochondria but not in cardiac mitochondria.     

Effects of aging and caloric restriction on mitochondrial energy production in gastrocnemius muscle and heart

Mitochondria are chronically exposed to reactive oxygen intermediates. As a result, various tissues, including skeletal muscle and heart, are characterized by an age-associated increase in reactive oxidant-induced mitochondrial DNA (mtDNA) damage. It has been postulated that these alterations may result in a decline in the content and rate of production of ATP, which may affect tissue function, contribute to the aging process, and lead to several disease states. We show that with age, ATP content and production decreased by approximately 50% in isolated rat mitochondria from the gastrocnemius muscle; however, no decline was observed in heart mitochondria. The decline observed in skeletal muscle may be a factor in the process of sarcopenia, which increases in incidence with advancing age. Lifelong caloric restriction, which prolongs maximum life span in animals, did not attenuate the age-related decline in ATP content or rate of production in skeletal muscle and had no effect on the heart. 8-Oxo-7,8-dihydro-2'-deoxyguanosine in skeletal muscle mtDNA was unaffected by aging but decreased 30% with caloric restriction, suggesting that the mechanisms that decrease oxidative stress in these tissues with caloric restriction are independent from ATP availability. The generation of reactive oxygen species, as indicated by H2O2 production in isolated mitochondria, did not change significantly with age in skeletal muscle or in the heart. Caloric restriction tended to reduce the levels of H2O2 production in the muscle but not in the heart. These data are the first to show that an age-associated decline in ATP content and rate of ATP production is tissue specific, in that it occurs in skeletal muscle but not heart, and that mitochondrial ATP production was unaltered by caloric restriction in both tissues.     

Effect of insulin on dexamethasone-induced ultrastructural changes in skeletal and cardiac muscle

Glucocorticoids help animals respond to stressors but excessive glucocorticoids cause muscle atrophy, while insulin can promote anabolism and growth. In order to compare the glucocorticoids-induced ultrastructural changes between skeletal muscle and cardiac muscle, and investigate the preventive effects of insulin on the changes, eighteen male chicks with similar initial weight were randomly divided into three groups. The two test groups were respectively treated with high-dose dexamethasone alone or together with low-dose insulin by intraperitoneal injection, and the control group was treated with an equal volume of saline solution. The experiment lasted for ten days, and then the body weight, muscle size and ultrastructure in skeletal and cardiac muscles of twelve chicks were qualitatively or quantitatively analyzed. The results showed that high-dose dexamethasone induced obvious skeletal and cardiac muscle atrophy. The differences of ultrastructural changes between skeletal muscle and cardiac muscle (such as for the former or the latter, the intermyofibrillar-and-interfilamentary spaces reducing or enlarging, the mitochondria swelling seriously or enlarging lightly, the myofibril filaments compacting or loosing) suggested that dexamethasone induced skeletal and cardiac muscle atrophy by different mechanisms. Low-dose insulin did not affect the dexamethasone-induced decreases of body weight and skeletal muscle size, but alleviated lightly the dexamethasone-induced ultrastructural changes in skeletal muscle. Different from skeletal muscle, low-dose insulin almost resisted the dexamethasone-induced ultrastructural changes in cardiac muscle.     

Exercise-induced mitophagy in skeletal muscle occurs in the absence of stabilization of Pink1 on mitochondria

Maintenance of mitochondrial quality is essential for skeletal muscle function and overall health. Exercise training elicits profound adaptations to mitochondria to improve mitochondrial quality in skeletal muscle. We have recently demonstrated that acute exercise promotes removal of damaged/dysfunctional mitochondria via mitophagy in skeletal muscle during recovery through the Ampk-Ulk1 signaling cascade. In this Extra View, we explore whether Pink1 is stabilized on mitochondria following exercise as the signal for mitophagy. We observed no discernable presence of Pink1 in isolated mitochondria from skeletal muscle at any time point following acute exercise, in contrast to clear evidence of stabilization of Pink1 on mitochondria in HeLa cells following treatment with the uncoupler carbonyl cyanide m-chlorophenyl hydrazone (CCCP). Taken together, we conclude that Pink1 is not involved in exercise-induced mitophagy in skeletal muscle.     

Optimal conditions for studies of amino acid incorporation in vitro by isolated skeletal muscle mitochondria

Optimal conditions for amino acid incorporation into protein in vitro by isolated skeletal muscle mitochondria were established. Maximum incorporation rates were obtained when atractylate and glutamate were added to the incubation medium in the absence of any exogenous adenine nucleotides. Under these conditions, the rate of amino acid incorporation was more than 5-fold greater than that observed with glutamate and ADP and nearly 12-fold greater than that observed with ATP and an ATP-regenerating system consisting of phosphoenolpyruvate and pyruvate kinase. The optimal concentrations of adenine nucleotides, glutamate, cofactors and the substrate leucine were determined for all three energy-providing systems. The inhibitors of protein synthesis, puromycin and chloramphenicol, completely blocked amino acid incorporation by isolated skeletal muscle in mitochondria, while cycloheximide had no effect. Analysis of the labeled mitochondrial proteins by sodium dodecylsulfate polyacrylamide gel electrophoresis revealed five labeled bands of molecular weights ranging from 38,000 to 10,000.Amino acid incorporation by skeletal muscle mitochondria isolated from diabetic rats was decreased over 60% as compared to mitochondria from controls when measured in the presence of glutamate and atractylate, ADP and glutamate or the ATP regenerating system. By contrast, amino acid incorporation by liver mitochondria isolated from diabetic rats did not differ significantly from control values when measured with four different energy sources.     

Impaired mitochondrial oxidative phosphorylation in skeletal muscle of the dystrophin-deficient mdx mouse

The mdx mouse, an animal model of the Duchenne muscular dystrophy, was used for the investigation of changes in mitochondrial function associated with dystrophin deficiency. Enzymatic analysis of skeletal muscle showed an approximately 50% decrease in the activity of all respiratory chain-linked enzymes in musculus quadriceps of adult mdx mice as compared with controls, while in cardiac muscle no difference was observed. The activities of cytosolic and mitochondrial matrix enzymes were not significantly different from the control values in both cardiac and skeletal muscles. In saponin-permeabilized skeletal muscle fibers of mdx mice the maximal rates of mitochondrial respiration were about two times lower than those of controls. These changes were also demonstrated on the level of isolated mitochondria. Mdx muscle mitochondria had only 60% of maximal respiration activities of control mice skeletal muscle mitochondria and contained only about 60% of hemoproteins of mitochondrial inner membrane. Similar findings were observed in a skeletal muscle biopsy of a Duchenne muscular dystrophy patient. These data strongly suggest that a specific decrease in the amount of all mitochondrial inner membrane enzymes, most probably as result of Ca²⁺ overload of muscle fibers, is the reason for the bioenergetic deficits in dystrophin-deficient skeletal muscle.     

Selective detection of UCP 3 expression in skeletal muscle: effect of thyroid status and temperature acclimation

A novel peptide antibody to UCP 3 is characterized which is sensitive and discriminatory for UCP 3 over UCP 2, UCP 1 and other mitochondrial transporters. The peptide antibody detects UCP 3 expression in E. coli, COS cells and yeast expression systems. The peptide antibody detects a single ∼33 kDa protein band in mitochondria from isolated rat skeletal muscle, mouse and rat brown adipose tissue, and in whole muscle groups (soleus and extensor digitorum longus) from mice. No 33 kDa band is detectable in isolated mitochondria from liver, heart, brain, kidney and lungs of rats, or gastrocnemius mitochondria from UCP 3 knock-out mice. From our data, we conclude that the peptide antibody is detecting UCP 3 in skeletal muscle, skeletal muscle mitochondria and brown adipose tissue mitochondria. It is also noteworthy that the peptide antibody can detect human, mouse and rat forms of UCP 3. Using the UCP 3 peptide antibody, we confirm and quantify the increased (2.8-fold) UCP 3 expression observed in skeletal muscle mitochondria isolated from 48-h-starved rats. We show that UCP 3 expression is increased (1.6-fold) in skeletal muscle of rats acclimated over 8 weeks to 8 °C and that UCP 3 expression is decreased (1.4-fold) in rats acclimated to 30 °C. Furthermore, UCP 3 expression is increased (2.3-fold) in skeletal muscle from hyperthyroid rats compared to euthyroid controls. In addition, we show that UCP 3 expression is only coincident with the mitochondrial fraction of skeletal muscle homogenates and not peroxisomal, nuclear or cytosolic and microsomal fractions.     

Selective detection of UCP 3 expression in skeletal muscle: effect of thyroid status and temperature acclimation

A novel peptide antibody to UCP 3 is characterized which is sensitive and discriminatory for UCP 3 over UCP 2, UCP 1 and other mitochondrial transporters. The peptide antibody detects UCP 3 expression in E. coli, COS cells and yeast expression systems. The peptide antibody detects a single approximately 33 kDa protein band in mitochondria from isolated rat skeletal muscle, mouse and rat brown adipose tissue, and in whole muscle groups (soleus and extensor digitorum longus) from mice. No 33 kDa band is detectable in isolated mitochondria from liver, heart, brain, kidney and lungs of rats, or gastrocnemius mitochondria from UCP 3 knock-out mice. From our data, we conclude that the peptide antibody is detecting UCP 3 in skeletal muscle, skeletal muscle mitochondria and brown adipose tissue mitochondria. It is also noteworthy that the peptide antibody can detect human, mouse and rat forms of UCP 3. Using the UCP 3 peptide antibody, we confirm and quantify the increased (2.8-fold) UCP 3 expression observed in skeletal muscle mitochondria isolated from 48-h-starved rats. We show that UCP 3 expression is increased (1.6-fold) in skeletal muscle of rats acclimated over 8 weeks to 8 degrees C and that UCP 3 expression is decreased (1.4-fold) in rats acclimated to 30 degrees C. Furthermore, UCP 3 expression is increased (2.3-fold) in skeletal muscle from hyperthyroid rats compared to euthyroid controls. In addition, we show that UCP 3 expression is only coincident with the mitochondrial fraction of skeletal muscle homogenates and not peroxisomal, nuclear or cytosolic and microsomal fractions.     

Mitochondrial sensitivity to AZT

The possibility of tissue-specific effects regarding mitochondrial sensitivity to AZT was evaluated in this study. When mitochondria isolated from liver, kidney, skeletal and cardiac muscle were oxidizing glutamate, a dose-dependent inhibition by AZT of state 3 respiration was observed; using succinate as substrate the inhibition occurred only in skeletal and cardiac muscle mitochondria. The same results were obtained with FCCP-uncoupled mitochondria. NADH oxidase of intact and disrupted mitochondria, isolated from all four tissues was strongly inhibited. Succinate oxidase activity was inhibited by AZT only in intact mitochondria from skeletal and cardiac muscles, suggesting the involvement of succinate transport systems. Similarly, inhibition by the drug of the hydrolytic activity of H⁺-ATPase was observed only in mitochondria of these tissues. These effects taken together, indicate a tissue/carrier-specific inhibition in vitro, although its precise mechanism requires further research. © 1998 John Wiley & Sons, Ltd.     

Effects of thyroidectomy of the rat on the structure and functions of skeletal muscle mitochondria]

Mitochondria used in the present study were isolated from skeletal muscle of normal and thyroidectomized rats. The preparations were controlled by electron microscopy. It was not possible to find any morphological change induced by thyroidectomy, nevertheless, some difference appeared in the cytochrome contents which were slightly decreased. Oxygen consumption rates of thyroidectomized rat mitochondria were decreased when the particles were maintained in states 3 and 4 in the presence of various substrates, but the P/O ratios were not modified. The activities of mitochondrial enzymes were in general slightly affected by thyroidectomy except for glycerol-1-phosphate cytochrome c reductase and NADH rotenone sensitive cytochrome c reductase which were decreased and for glutamate dehydrogenase activity which was increased. The tRNA nucleotidyltransferase activity found in the mitochondrial matrix was not influenced by the absence of thyroid secretion. Normal rat muscle mitochondria incorporate 14C-leucine with an artificial ATP-generating system or with a respiratory substrate. The amino acid incorporation was decreased by thyroidectomy. Muscle mitochondria analyzed by polyacrylamide gel electrophoresis contained more than 30 protein components with MW ranging from 10.000 to 135.000. Thyroidectomy lowered the amount of a fraction of about 54.000 MW. It is not impossible that all the data observed in the absence of thyroid secretion are in relation with changes induced in the mitochondrial genome as previously shown in mitochondria isolated from liver or thyroidectomized rats.     

The effects of palmitic acid on skeletal muscle mitochondria of cold and warm acclimated rats.

The effects of palmitic acid on skeletal muscle mitochondria isolated from the hind limb muscle of cold and warm acclimated rats were studied. At higher concentrations of the fatty acid, a greater depression of both ADP/O and RCR (respiratory control ratio) was observed in the cold acclimated group. Initial ADP/O and RCC however, were higher in the cold acclimated group. The enhanced sensitivity of skeletal muscle mitochondria of the cold acclimated rat is discussed.     

‘Idealized’ State 4 and State 3 in Mitochondria vs. Rest and Work in Skeletal Muscle

A computer model of oxidative phosphorylation (OXPHOS) in skeletal muscle is used to compare state 3, intermediate state and state 4 in mitochondria with rest and work in skeletal muscle. ‘Idealized’ state 4 and 3 in relation to various ‘experimental’ states 4 and 3 are defined. Theoretical simulations show, in accordance with experimental data, that oxygen consumption (V’O₂), ADP and P_i are higher, while ATP/ADP and Δp are lower in rest than in state 4, because of the presence of basal ATP consuming reactions in the former. It is postulated that moderate and intensive work in skeletal muscle is very different from state 3 in isolated mitochondria. V’O₂, ATP/ADP, Δp and the control of ATP usage over V’O₂ are much higher, while ADP and Pi are much lower in the former. The slope of the phenomenological V’O₂-ADP relationship is much steeper during the rest-work transition than during the state 4-state 3 transition. The work state in intact muscle is much more similar to intermediate state than to state 3 in isolated mitochondria in terms of ADP, ATP/ADP, Δp and metabolic control pattern, but not in terms of V’O₂. The huge differences between intact muscle and isolated mitochondria are proposed to be caused by the presence of the each-step activation (ESA) mechanism of the regulation of OXPHOS in intact skeletal muscle. Generally, the present study suggests that isolated mitochondria (at least in the absence of Ca²⁺) cannot serve as a good model of OXPHOS regulation in intact skeletal muscle.     

ULTRASTRUCTURAL BASES FOR METABOLICALLY LINKED MECHANICAL ACTIVITY IN MITOCHONDRIA : I. Reversible Ultrastructural Changes with Change in Metabolic Steady State in Isolated Liver Mitochondria

By means of a new "quick-sampling" method, micropellets of mouse liver mitochondria were rapidly prepared for electron microscopy during the recording of steady state metabolism. Reversible ultrastructural changes were found to accompany change in metabolic steady states. The most dramatic reversible ultrastructural change occurs when ADP is added to systems in which only phosphate acceptor is deficient, i.e., during the State IV to State III transition as defined by Chance and Williams. After 15 min in State IV, mitochondria display an "orthodox" ultrastructural appearance as is usually observed after fixation within intact tissue. On transition to State III, a dramatic change in the manner of folding of the inner membrane takes place. In addition, the electron opacity of the matrix increases as the volume of the matrix decreases, but total mitochondrial volume does not appear to change during this transition. This conformation is called "condensed." Isolated mitochondria were found to oscillate between the orthodox and condensed conformations during reversible transitions between State III and State IV. Various significant ultrastructural changes in mitochondria also occur during transitions in other functional states, e.g., when substrate or substrate and acceptor is made limiting. Internal structural flexibility is discussed with respect to structural and functional integrity of isolated mitochondria. Reversible changes in the manner of folding of the inner membrane and in the manner of packing of small granules in the matrix as respiration is activated by ADP represent an ultrastructural basis for metabolically linked mechanical activity in tightly coupled mitochondria.     

Stereologic studies on mitochondrial configuration in mitochondria of immobilized mice muscle

The effect of long-term (3 weeks) immobilization on mice skeletal (m. gastrocnemius) and heart muscles was investigated. Morphometric determinations were carried out for analysis surface and volume parameters in mitochondria. The ultrastructural visual evaluation of mitochondria showed that there are no difference between control and experimental groups. Morphometric data obtained from stereological analysis were shown that mitochondria in immobilized skeletal and heart muscles represent tendency of transformation to low-energy states (condensed state). Based upon data obtained in this study we recommend that these changes in mitochondria there are reversible.     

The effect of diabetes on protein synthesis and the respiratory chain of rat skeletal muscle and kidney mitochondria

The effects of streptozotocin-induced diabetes mellitus upon mitochondria from rat skeletal muscle and kidney were examined. The rate of amino acid incorporation in vitro by isolated skeletal muscle mitochondria from diabetic animals was decreased by 50–60% from control values. Treatment of diabetic animals with insulin lowered blood glucose levels to control values and restored the rate of muscle mitochondrial protein synthesis in vitro to control levels. The rates of skeletal muscle mitochondrial protein synthesis were also decreased 23–27% by a 2-day fast. Comparison of the translation products synthesized by isolated muscle mitochondria from control and diabetic rats by dodecyl sulfate polyacrylamide-gel electrophoresis revealed a uniform decrease in the synthesis of all polypeptides. Aurintricarboxylic acid and pactamycin, inhibitors of chain initiation, blocked protein synthesis to a greater extent in muscle mitochondria from control as compared to diabetic animals suggesting that mitochondria from diabetics are unable to initiate protein synthesis at a rate comparable to control. Phenotypic changes observed in diabetic muscle mitochondria included a 36% decrease in the content of cytochromes aa₃ and a 27% decrease in cytochrome b, both established as containing mitochondrial translation products in lower eucaryotes. State 3 respiration with glutamate as substrate decreased by 27% and uncoupler-stimulated respiration decreased by 23% in the diabetic mitochondria. By contrast, the specific activities of NADH and succinate dehydrogenases, established as products of cytoplasmic protein synthesis in lower eucaryotes, were not decreased in skeletal muscle mitochondria from the diabetic animals. These results suggest that the considerable muscular atrophy observed in diabetics may involve decreases in both cytoplasmic and mitochondrial protein synthesis, the latter reflected in profound changes in the respiratory chain. By contrast, comparison of kidney mitochondria from control and diabetic rats revealed no differences in the rates of protein synthesis in vitro, nor in the mitochondrial translation products, which corresponded closely to liver and skeletal muscle translation products. Similarly, the mitochondrial content of cytochromes b, c + c₁, and aa₃, the specific activity of succinate dehydrogenase, the rate of state 3 respiration, and the recovery of mitochondria from kidney homogenates did not differ in control and diabetic animals. Kidney mitochondria are thus like liver mitochondria in being relatively unaffected by insulin deprivation.     

Early morphological remodeling of neuromuscular junction in a murine model of diabetes.

Although skeletal muscle weakness is documented in diabetes, the time course for its development is not established. The present study examined the dorsiflexor muscle from animals that had been diabetic for 2 wk. Adult male c57BL mice were injected once with streptozotocin (STZ) to induce diabetes (60 mg/kg ip). Two weeks later, resting membrane potential and miniature end-plate potentials were recorded, and electron microscopy was utilized for ultrastructural evaluations. After STZ-induced diabetes, both resting membrane potential and miniature end-plate potentials were reduced. Nerve terminals showed less synaptic vesicles and had degenerated mitochondria. Furthermore, in the intramuscular nerves, disorganization of microtubules and neurofilaments was evidenced. Myelin-like figures were present in intramuscular nerves, neuromuscular junctions, and muscle fibers. At the muscle level, mitochondria were swollen, with disorganization of their cristae, disruption of T tubules, and myofibers with more deposition of glycogen granules. The present results revealed early STZ-induced nerve and muscle alterations. Observed ultrastructural modifications resemble those of motoneuron disorders and aging processes. These changes are possibly related to alterations in Ca(2+) mobilization across muscle membrane. Other mechanisms such as free radical-mediated actions may also be implicated in STZ-induced effects on skeletal muscle.     

Regulation of UCP1 and UCP3 in arctic ground squirrels and relation with mitochondrial proton leak.

Uncoupling protein (UCP) 1 (UCP1) catalyzes a proton leak in brown adipose tissue (BAT) mitochondria that results in nonshivering thermogenesis (NST), but the extent to which UCP homologs mediate NST in other tissues is controversial. To clarify the role of UCP3 in mediating NST in a hibernating species, we measured Ucp3 expression in skeletal muscle of arctic ground squirrels in one of three activity states (not hibernating, not hibernating and fasted for 48 h, or hibernating) and housed at 5 degrees C or -10 degrees C. We then compared Ucp3 mRNA levels in skeletal muscle with Ucp1 mRNA and UCP1 protein levels in BAT in the same animals. Ucp1 mRNA and UCP1 protein levels were increased on cold exposure and decreased with fasting, with the highest UCP1 levels in thermogenic hibernators. In contrast, Ucp3 mRNA levels were not affected by temperature but were increased 10-fold during fasting and >3-fold during hibernation. UCP3 protein levels were increased nearly fivefold in skeletal muscle mitochondria isolated from fasted squirrels compared with nonhibernators, but proton leak kinetics in the presence of BSA were unchanged. Proton leak in BAT mitochondria also did not differ between fed and fasted animals but did show classical inhibition by the purine nucleotide GDP. Levels of nonesterified fatty acids were highest during hibernation, and tissue temperatures during hibernation were related to Ucp1, but not Ucp3, expression. Taken together, these results do not support a role for UCP3 as a physiologically relevant mediator of NST in muscle.     

The preservation of in vivo phosphorylated and activated uncoupling protein 3 (UCP3) in isolated skeletal muscle mitochondria following administration of 3,4-methylenedioxymethamphetamine (MDMA aka ecstasy) to rats/mice

Previous researchers have demonstrated that 3,4-methylenedioxymethamphetamine (MDMA) induced hyperthermia, in skeletal muscle of animals, is uncoupling protein 3 (UCP3) dependent. In light of our investigations that in vivo phosphorylation of UCP1 is augmented under conditions of cold-acclimation, we set out to investigate whether (a) UCP3 was phosphorylated in vivo and (b) whether in vivo phosphorylation of UCP3 resulted in increased proton leak following MDMA administration to animals. Our data demonstrate that MDMA treatment (but not PBS treatment) of animals results in both in vivo serine and tyrosine phosphorylation of UCP3 in skeletal muscle mitochondria, isolated in the presence of phosphatase inhibitors to preserve in vivo phosphorylation. In addition, proton leak is only increased in skeletal muscle mitochondria isolated from MDMA treated animals (in the presence of phosphatase inhibitors) and the increased proton leak is due to phosphorylated UCP3. UCP3 abundance in skeletal muscle mitochondria is unaffected by MDMA administration. Preservation of UCP3 phosphorylation and increased proton leak is lost when skeletal muscle mitochondria are isolated in the absence of phosphatase inhibitors. We conclude that MDMA treatment of animals increases proton leak in skeletal muscle mitochondria by activating UCP3 through in vivo covalent modification of UCP3 by phosphorylation. Furthermore, we deduce that the MDMA induced hyperthermia in skeletal muscle is due to increased proton leak in vivo as a result of activation of UCP3 through phosphorylation.     

High‐fat diet affects skeletal muscle mitochondria comparable to pressure overload‐induced heart failure

In heart failure, high‐fat diet (HFD) may exert beneficial effects on cardiac mitochondria and contractility. Skeletal muscle mitochondrial dysfunction in heart failure is associated with myopathy. However, it is not clear if HFD affects skeletal muscle mitochondria in heart failure as well. To induce heart failure, we used pressure overload (PO) in rats fed normal chow or HFD. Interfibrillar mitochondria (IFM) and subsarcolemmal mitochondria (SSM) from gastrocnemius were isolated and functionally characterized. With PO heart failure, maximal respiratory capacity was impaired in IFM but increased in SSM of gastrocnemius. Unexpectedly, HFD affected mitochondria comparably to PO. In combination, PO and HFD showed additive effects on mitochondrial subpopulations which were reflected by isolated complex activities. While PO impaired diastolic as well as systolic cardiac function and increased glucose tolerance, HFD did not affect cardiac function but decreased glucose tolerance. We conclude that HFD and PO heart failure have comparable effects leading to more severe impairment of IFM. Glucose tolerance seems not causally related to skeletal muscle mitochondrial dysfunction. The additive effects of HFD and PO may suggest accelerated skeletal muscle mitochondrial dysfunction when heart failure is accompanied with a diet containing high fat.     

Isolation of two ATPase inhibitor proteins from mitochondria of rat skeletal muscle

An ATPase inhibitor protein was isolated from mitochondria of rat skeletal muscle by alkaline extraction and then was purified, It differed in definitive ways from the ATPase inhibitor protein isolated previously by Ca²⁺-stripping of submitochondrial particles of rat skeletal muscle. The two ATPase inhibitor proteins were shown to be present together in intact mitochondria.