Efficiency Of Oxidative Phosphorylation Research Articles

Nitric Oxide as the Main Mediator of Adaptation to Physical Training

Intensive constitutive production of nitric oxide (NO) during physical training improves vasodilatation and heart function. However it reminds unclear how NO takes part in myocardial adaptation to workload, which accompanied with increased heart inflow and intra- cellular calcium content. Using isolated rat heart by Langendorf preparation we studied myo- cardial response to gradually increased left ventricular volume (Frank-Starling low) and in- creasing concentration of Ca 2+ in perfusion solution (from 1.7 mM to 12.5 mM) in trained and untrained rats. It was shown that 4 weeks swimming course improved heart function: heart rate was decreased; contractile activity (dP/dt max) and coronary flow were increased by 20% and 33% respectively. Equal volume of balloon stretching in left ventricle provoked greater con- traction in trained comparing to untrained hearts, demonstrating extended functional reserves of myocardium after swimming course. Furthermore, physical training significantly increased mitochondrial membrane potential (-176.5 ± 8.4 mV vs -156 ± 3.5 mV in control), that points to improved efficiency of oxidative phosphorylation. Heart contracture and increase of end diastolic pressure during calcium upload were much prevented in trained rat hearts. Mitochon- drial factor release due to opening of mitochondrial permeability transition (MPT) pore in trained heart was detected at higher concentration of calcium that reveals extended calcium capacity of mitochondria and lesser sensitivity of MPTP to its inductor - calcium. Pretreatment with NO synthesis inhibitor - L-NAME - in dose of 10 -4 M for 15 min abolished reaction of trained heart during Frank-Starling and calcium upload. Thus, heart adaptation to physical training and extend of functional reserves of heart are provided by endogenous NO production.

Uncoupling protein-2 attenuates glucose-stimulated insulin secretion in INS-1E insulinoma cells by lowering mitochondrial reactive oxygen species

Glucose-stimulated insulin secretion (GSIS) by pancreatic β cells is regulated by mitochondrial uncoupling protein-2 (UCP2), but opposing phenotypes, GSIS improvement and impairment, have been reported for different Ucp2-ablated mouse models. By measuring mitochondrial bioenergetics in attached INS-1E insulinoma cells with and without UCP2, we show that UCP2 contributes to proton leak and attenuates glucose-induced rises in both respiratory activity and the coupling efficiency of oxidative phosphorylation. Strikingly, the GSIS improvement seen upon UCP2 knockdown in INS-1E cells is annulled completely by the cell-permeative antioxidant MnTMPyP. Consistent with this observation, UCP2 lowers mitochondrial reactive oxygen species at high glucose levels. We conclude that UCP2 plays both regulatory and protective roles in β cells by acutely lowering GSIS and chronically preventing oxidative stress. Our findings thus provide a mechanistic explanation for the apparently discrepant findings in the field.

Tissue variation of mitochondrial oxidative phosphorylation efficiency in cold-acclimated ducklings.

We investigated the oxidative phosphorylation efficiency of liver and gastrocnemius muscle mitochondria in thermoneutral and cold-acclimated ducklings. The yield of oxidative phosphorylation was lower in muscle than in liver mitochondria, a difference that was associated with a higher proton conductance in muscle mitochondria. Cold exposure did not affect oxidative phosphorylation efficiency or basal proton leak in mitochondria. We conclude that the basal proton conductance of mitochondria may regulate mitochondrial oxidative phosphorylation efficiency, but is not an important contributor to thermogenic processes in cold-acclimated ducklings.

Functional argument for the existence of an avian nitric oxide synthase in muscle mitochondria: Effect of cold acclimation

We report the first evidence of a mitochondrial NO synthase (mtNOS) in bird skeletal muscle. In vitro, mtNOS activity stimulated by l-arginine reduced intermyofibrillar mitochondrial oxygen uptake and ATP synthesis rates, stimulated endogenous H2O2 generation, but had no effect on oxidative phosphorylation efficiency. Arginine-induced effects were fully reversed by l-NAME, a known NOS inhibitor. When ducklings were cold exposed for 4weeks, muscle mitochondria displayed an increased state 3 respiration, a reduced H2O2 generation but no significant alteration in mtNOS activity. We conclude that mtNOS is expressed in avian skeletal muscle.

"MitoTea": Geranium robertianum L. decoctions decrease blood glucose levels and improve liver mitochondrial oxidative phosphorylation in diabetic Goto-Kakizaki rats.

Several chemical compounds found in plant products have proven to possess beneficial properties, being currently pointed out due to their pharmacological potential in type 2 diabetes mellitus complications. In this context, we studied the effect of Geranium robertianum L. (herb Robert) leaf decoctions in Goto-Kakizaki (GK) rats, a model of type 2 diabetes. Our results showed that oral administration of G. robertianum leaf decoctions over a period of four weeks lowered the plasma glucose levels in diabetic rats. Furthermore, the treatment with G. robertianum extracts improved liver mitochondrial respiratory parameters (state 3, state 4 and FCCP-stimulated respiration) and increased oxidative phosphorylation efficiency.

Supramolecular organizations in the aerobic respiratory chain of Escherichia coli

The organization of respiratory chain complexes in supercomplexes has been shown in the mitochondria of several eukaryotes and in the cell membranes of some bacteria. These supercomplexes are suggested to be important for oxidative phosphorylation efficiency and to prevent the formation of reactive oxygen species.Here we describe, for the first time, the identification of supramolecular organizations in the aerobic respiratory chain of Escherichia coli, including a trimer of succinate dehydrogenase. Furthermore, two heterooligomerizations have been shown: one resulting from the association of the NADH:quinone oxidoreductases NDH-1 and NDH-2, and another composed by the cytochrome bo3 quinol:oxygen reductase, cytochrome bd quinol:oxygen reductase and formate dehydrogenase (fdo). These results are supported by blue native-electrophoresis, mass spectrometry and kinetic data of wild type and mutant E . coli strains.

Mitochondrial uncoupling protein 2 in pancreatic β‐cells

Pancreatic β-cells have remarkable bioenergetics in which increased glucose supply upregulates the cytosolic ATP/ADP ratio and increases insulin secretion. This arrangement allows glucose-stimulated insulin secretion (GSIS) to be regulated by the coupling efficiency of oxidative phosphorylation. Uncoupling protein 2 (UCP2) modulates coupling efficiency and may regulate GSIS. Initial measurements of GSIS and glucose tolerance in Ucp2(-/-) mice supported this model, but recent studies show confounding effects of genetic background. Importantly, however, the enhancement of GSIS is robustly recapitulated with acute UCP2 knockdown in INS-1E insulinoma cells. UCP2 protein level in these cells is dynamically regulated, over at least a fourfold concentration range, by rapid proteolysis (half-life less than 1 h) opposing regulated gene transcription and mRNA translation. Degradation is catalysed by the cytosolic proteasome in an unprecedented pathway that is currently known to act only on UCP2 and UCP3. Evidence for proteasomal turnover of UCP2 includes sensitivity of degradation to classic proteasome inhibitors in cells, and reconstitution of degradation in vitro in mitochondria incubated with ubiquitin and the cytosolic 26S proteasome. These dynamic changes in UCP2 content may provide a fine level of control over GSIS in β-cells.

Efficiency of oxidative phosphorylation in liver mitochondria is decreased in a rat model of peritoneal carcinosis

Cancer cachexia is a dynamic process characterized by a negative energy balance induced by anorexia and hypermetabolism. The mechanisms leading to hypermetabolism are not totally elucidated. This study examines the efficiency of oxidative phosphorylation and energy wasting in liver mitochondria isolated from rats with cancer cachexia induced by peritoneal carcinosis (PC). PC was generated by an intraperitoneal injection of cancer cells (PROb) in BDIX rats. The efficiency of oxidative phosphorylation and energy wasting as well as the role played by reactive oxygen species (ROS) and cardiolipin (mitochondrial inner membrane phospholipid) in these processes were assessed in liver mitochondria of PC and pair-fed control rats. The efficiency of oxidative phosphorylation decreased (-26%) while energy wasting increased (+22%) in liver mitochondria from PC compared to control rats. The increased energy wasting was associated with a higher cardiolipin content (+55%, p<0.05; R(2)=0.64, p<0.05) and with a lower n-6/n-3 polyunsaturated fatty acid ratio in cardiolipin (-45%, p<0.05; R(2)=0.21, p<0.05) in PC rats. ROS production was increased by 12-fold in liver mitochondria from PC rats. The efficiency of ATP synthesis was reduced and energy wasting processes were increased in liver mitochondria of PC rats. This suggests that liver mitochondria from PC rats request more nutrients than liver mitochondria from control rats to maintain the same ATP production. These alterations were associated to the content and fatty acid composition of cardiolipin.

Blockade Of Prostaglandins And Nitric Oxide In-vivo Reduces State 3 Mitochondrial Respiration In Human Skeletal Muscle

Combined inhibition of nitric oxide (NO) and prostaglandins (PG) reduces skeletal muscle blood flow and oxygen delivery at rest and during exercise. It has recently been found that combined inhibition of NO and PG blockade reduces muscle oxygen uptake during exercise (Mortensen et al. 2007) suggesting a partial inhibition of aerobic metabolism or improved muscle efficiency of oxidative phosphorylation or actin-myosin cycling. PURPOSE: The purpose of this study was to examine in humans the independent and combined effect of NO and PG blockade with L-NMMA and Indomethacin (Indo) on mitochondrial respiration in muscle from biopsies of the vastus lateralis (VL) following knee extension (KE) exercise. METHODS: Mitochondrial respiration was measured ex-vivo by high resolution respirometry in saponin-permeabilized fibers following 6 min KE in control (CON, n=8), arterial infusion of LNMMA (n=4) and Indo (n=4) randomized in order, followed by combined inhibition of NO and PG (L-NMMA + Indo, n=8). RESULTS. ADP-stimulated state 3 respiration with substrates for complex I (glutamate, malate) was reduced 50% by Indo compared to CON. State 3 O2 flux with convergent electron input through both complex I and II with addition of succinate was equally reduced with Indo (20%) and L-NMMA + Indo (15%) compared to CON and LNMMA alone. Uncoupled O2 flux determined by titration of the ionophore FCCP was not increased above state 3 respiration with Indo suggesting tight coupling to oxidative phosphorylation. Graded titrations of L-NMMA into the respirometer in CON muscle reduced state 3 respiration by 12% only at a supra-physiological dose, while titration of Indo caused a linear reduction at all doses within and above the physiological range. CONCLUSION: The results indicate that inhibition of PG by indomethacin inhibits state 3 mitochondrial respiration primarily at complex I of the respiratory chain. This effect may in part explain the in-vivo reduction in muscle O2 uptake during exercise with double blockade of NO and PG, since blockade of NO by L-NMMA counteracts the inhibitory effect of Indo.

Energy metabolism in hypoxia: reinterpreting some features of muscle physiology on molecular grounds

An holistic approach for interpreting classical data on the adaptation of the animal and, particularly, of the human body to hypoxic stress was promoted by the discovery of HIF-1, the "master regulator" of cell hypoxic signaling. Mitochondrial production of ROS stabilizes the O(2)-regulated HIF-1α subunit of the HIF-1 dimer promoting transaction functions in a large number of potential target genes, activating transcription of sequences into RNA and, eventually, protein production. The aim of the present preliminary study is to assess whether adaptive changes in oxygen sensing and metabolic signaling, particularly in the control of energy turnover known to occur in cultured cells exposed to hypoxia, are detectable also in the muscles of animals and man. For the present analysis, data obtained from the proteome of the rat gastrocnemius and of the vastus lateralis muscle of humans together with functional measurements were compared with homologous data from hypoxic cultured cells. In particular, the following variables were assessed: (1) the role of stress response proteins in the maintenance of ROS homeostasis, (2) the activity of the PDK1 gene on the shunting of pyruvate away from the TCA cycle in rodents and in humans, (3) the COX-4/COX-2 ratio in hypoxic rodents, (4) the overall efficiency of oxidative phosphorylation in humans during exercise in hypoxia, (5) some features of muscle mitochondrial autophagy in humans undergoing subchronic and chronic altitude exposure. Despite the limited number of observations and the differences in the experimental approach, some initial interesting results were obtained encouraging to pursue this innovative effort.

Exploring mitochondrial evolution and metabolism organization principles by comparative analysis of metabolic networks

The endosymbiotic theory proposed that mitochondrial genomes are derived from an alpha-proteobacterium-like endosymbiont, which was concluded from sequence analysis. We rebuilt the metabolic networks of mitochondria and 22 relative species, and studied the evolution of mitochondrial metabolism at the level of enzyme content and network topology. Our phylogenetic results based on network alignment and motif identification supported the endosymbiotic theory from the point of view of systems biology for the first time. It was found that the mitochondrial metabolic network were much more compact than the relative species, probably related to the higher efficiency of oxidative phosphorylation of the specialized organelle, and the network is highly clustered around the TCA cycle. Moreover, the mitochondrial metabolic network exhibited high functional specificity to the modules. This work provided insight to the understanding of mitochondria evolution, and the organization principle of mitochondrial metabolic network at the network level.

A thermodynamic approach to energy transduction in mitochondria

A model based on non-equilibrium thermodynamics has been extended for investigation of energy transduction in biological systems. Rate of free energy loss and efficiency of some mitochondria in energetic and thermogenic modes have been determined by means of this model. The theoretical results are in agreement with previous experimental ones indicating that the rate of free energy loss is greater in mitochondria with thermogenic function while the efficiency of oxidative phosphorylation appears to be less than energetic ones. Therefore, the model illustrates the principle that mitochondria with energetic role are able to store more energy in the form of adenosine triphosphate (ATP), while mitochondria with thermogenic function release more energy as heat and are thus less efficient in energy storage. Furthermore, the model introduces some thermodynamic criteria that can provide valuable information on whether the mitochondrion is functioning properly. After evaluation of some parameters for each mitochondrion, these criteria can be easily determined by means of the presented equations. Hence, the developed model can be widely used in medical, pharmaceutical, and biological studies.

Metabolic flux analysis of mitochondrial uncoupling in 3T3-L1 adipocytes.

BackgroundIncreasing energy expenditure at the cellular level offers an attractive option to limit adiposity and improve whole body energy balance. In vivo and in vitro observations have correlated mitochondrial uncoupling protein-1 (UCP1) expression with reduced white adipose tissue triglyceride (TG) content. The metabolic basis for this correlation remains unclear.Methodology/Principal FindingsThis study tested the hypothesis that mitochondrial uncoupling requires the cell to compensate for the decreased oxidation phosphorylation efficiency by up-regulating lactate production, thus redirecting carbon flux away from TG synthesis. Metabolic flux analysis was used to characterize the effects of non-lethal, long-term mitochondrial uncoupling (up to 18 days) on the pathways of intermediary metabolism in differentiating 3T3-L1 adipocytes. Uncoupling was induced by forced expression of UCP1 and chemical (FCCP) treatment. Chemical uncoupling significantly decreased TG content by ca. 35%. A reduction in the ATP level suggested diminished oxidative phosphorylation efficiency in the uncoupled adipocytes. Flux analysis estimated significant up-regulation of glycolysis and down-regulation of fatty acid synthesis, with chemical uncoupling exerting quantitatively larger effects.Conclusions/SignificanceThe results of this study support our hypothesis regarding uncoupling-induced redirection of carbon flux into glycolysis and lactate production, and suggest mitochondrial proton translocation as a potential target for controlling adipocyte lipid metabolism.

Response of mitochondrial fusion and fission protein gene expression to exercise in rat skeletal muscle

The purpose of this study was to investigate the changes in the gene expression of Mitofusion (Mfn) 1 and 2 and Fission 1 (Fis1) and mitochondrial energy metabolism in response to altered energy demand during prolonged exercise in rat skeletal muscle. Male Sprague–Dawley rats were subjected to an acute bout of treadmill running at various durations and killed immediately or during recovery. Mfn1/2 and Fis1 mRNA and protein contents, reactive oxygen species (ROS) generation, state 3 and state 4 respiration rates, trans-innermembrane potential and ATP synthase activity were measured in isolated muscle mitochondria. We found that (1) Mfn1/2 mRNA contents were progressively decreased during 150 min of exercise, along with decreased Mfn 1 protein levels. Fis1 mRNA and protein contents showed significant increases after 120–150 min of exercise. These changes persisted through the recovery period up to 24 h. (2) Mitochondrial ROS generation and state 4 respiration showed progressive increases up to 120 min, but dropped at 150 min of exercise. (3) State 3 respiration rate and respiratory control index were unchanged initially but decreased at 150 and 120 min of exercise, respectively, whereas ATP synthase activity was elevated at 45 min and returned to resting level thereafter. Our data suggested that the gene expression of mitochondrial fusion and fission proteins in skeletal muscle can respond rapidly to increased metabolic demand during prolonged exercise, which could significantly affect the efficiency of oxidative phosphorylation.

Adenine nucleotide translocase is involved in a mitochondrial coupling defect in MFN2-related Charcot–Marie–Tooth type 2A disease

Charcot-Marie-Tooth type 2A disease (CMT2A), a dominantly inherited peripheral neuropathy, is caused by mutations in MFN2, a mitochondrial fusion protein. Having previously demonstrated a mitochondrial coupling defect in CMT2A patients' fibroblasts, we here investigate mitochondrial oxygen consumption and the expression of adenine nucleotide translocase (ANT) and uncoupling proteins from eight other patients with the disease. The mitochondrial uncoupling was associated with a higher respiratory rate, essentially involving complex II proteins. Furthermore, a twofold increase in the expression of ANT led to the reduced efficiency of oxidative phosphorylation in CMT2A cells, suggesting that MFN2 plays a role in controlling ATP/ADP exchanges.

Mitochondrial Dysfunction Contributes to Impaired Insulin Secretion in INS-1 Cells with Dominant-negative Mutations of HNF-1α and in HNF-1α-deficient Islets

Maturity Onset Diabetes of the Young-type 3 (MODY-3) has been linked to mutations in the transcription factor hepatic nuclear factor (HNF)-1alpha, resulting in deficiency in glucose-stimulated insulin secretion. In INS-1 cells overexpressing doxycycline-inducible HNF-1alpha dominant-negative (DN-) gene mutations, and islets from Hnf-1alpha knock-out mice, insulin secretion was impaired in response to glucose (15 mm) and other nutrient secretagogues. Decreased rates of insulin secretion in response to glutamine plus leucine and to methyl pyruvate, but not potassium depolarization, indicate defects specific to mitochondrial metabolism. To identify the biochemical mechanisms responsible for impaired insulin secretion, we used (31)P NMR measured mitochondrial ATP synthesis (distinct from glycolytic ATP synthesis) together with oxygen consumption measurements to determine the efficiency of mitochondrial oxidative phosphorylation. Mitochondrial uncoupling was significantly higher in DN-HNF-1alpha cells, such that rates of ATP synthesis were decreased by approximately one-half in response to the secretagogues glucose, glutamine plus leucine, or pyruvate. In addition to closure of the ATP-sensitive K(+) channels with mitochondrial ATP synthesis, mitochondrial production of second messengers through increased anaplerotic flux has been shown to be critical for coupling metabolism to insulin secretion. (13)C-Isotopomer analysis and tandem mass spectrometry measurement of Krebs cycle intermediates revealed a negative impact of DN-HNF-1alpha and Hnf-1alpha knock-out on mitochondrial second messenger production with glucose but not amino acids. Taken together, these results indicate that, in addition to reduced glycolytic flux, uncoupling of mitochondrial oxidative phosphorylation contributes to impaired nutrient-stimulated insulin secretion with either mutations or loss of HNF-1alpha.

Metabolic impact of redox cofactor perturbations in Saccharomyces cerevisiae

Redox cofactors play a pivotal role in coupling catabolism with anabolism and energy generation during metabolism. There exists a delicate balance in the intracellular level of these cofactors to ascertain an optimal metabolic output. Therefore, cofactors are emerging to be attractive targets to induce widespread changes in metabolism. We present a detailed analysis of the impact of perturbations in redox cofactors in the cytosol or mitochondria on glucose and energy metabolism in Saccharomyces cerevisiae to aid metabolic engineering decisions that involve cofactor engineering. We enhanced NADH oxidation by introducing NADH oxidase or alternative oxidase, its ATP-mediated conversion to NADPH using NADH kinase as well as the interconversion of NADH and NADPH independent of ATP by the soluble, non-proton-translocating bacterial transhydrogenase. Decreasing cytosolic NADH level lowered glycerol production, while decreasing mitochondrial NADH lowered ethanol production. However, when these reactions were coupled with NADPH production, the metabolic changes were more moderated. The direct consequence of these perturbations could be seen in the shift of the intracellular concentrations of the cofactors. The changes in product profile and intracellular metabolite levels were closely linked to the ATP requirement for biomass synthesis and the efficiency of oxidative phosphorylation, as estimated from a simple stoichiometric model. The results presented here will provide valuable insights for a quantitative understanding and prediction of cellular response to redox-based perturbations for metabolic engineering applications.

Computational Analysis of Cardiac Energetics during Ischemia and Reperfusion in Buffer‐Perfused Rabbit Hearts

To determine the mechanisms by which nucleotide concentrations change in the heart during ischemia and reperfusion, data from Kroll et al. [Am. J. Physiol. 272:H2567‐2576, 1997] were analyzed using a computational model of cardiac energy metabolism and metabolite transport. In the experiments of Kroll et al., rabbit hearts were subjected to 10 minutes of perfusion at basal conditions; then 45 minutes of ischemia with 95% flow reduction; and then reperfusion. Phosphate metabolite concentrations were measured by 31P‐Magnetic Resonance Spectroscopy (31P‐MRS) and oxygen flux by arterial‐venous differences in oxygen tension during the ischemia reperfusion protocol. Data were analyzed by integrating open adenosine kinetics into a previously developed computational model [Wu et al., J. Physiol. 586:4193‐4208, 2008]. Our analyses find that during ischemia/anoxia the heart actively down‐regulates ATP hydrolysis rate in the cytoplasm, while inhibiting mitochondrial ATP consumption. Down‐regulation of mitochondria ATP consumption during anoxia may be associated with inhibition of F1Fo‐ATPase reversal or reduction of mitochondrial proton leak. During the reperfusion period, the mitochondrial ATP synthesis capacity is largely restored, while mitochondrial proton leak is significantly magnified resulting in a slightly impaired efficiency of mitochondrial oxidative phosphorylation. The loss of adenosine nucleotides during ischemia does not limit the mitochondrial oxidative capacity during reperfusion.

Variety-specific response of wheat (Triticum aestivum L.) leaf mitochondria to drought stress

The main objective of the present work was to examine leaf respiratory responses to dehydration and subsequent recovery in three varieties of winter wheat (Triticum aestivum L.) known to differ in their level of drought tolerance. Under dehydration, both total respiration and salicylhydroxamic acid (SHAM)-resistant cytochrome (Cyt) pathway respiration by leaf segments decreased significantly compared with well-watered plants. This decrease was more pronounced in the drought-sensitive Sadovo and Prelom genotypes. In contrast, the KCN-resistant SHAM-sensitive alternative (Alt) pathway became increasingly engaged, and accounted for about 80% of the total respiration. In the drought-tolerant Katya variety, increased contribution of the Alt pathway was accompanied by a slight decrease in Cyt pathway activity. Respiration of isolated leaf mitochondria also showed a variety-specific drought response. Mitochondria from drought-sensitive genotypes had low oxidative phosphorylation efficiency after dehydration and rewatering, whereas the drought-tolerant Katya mitochondria showed higher phosphorylation rates. Morphometric analysis of leaf ultrastructure revealed that mitochondria occupied approximately 7% of the cell area in control plants. Under dehydration, in the drought-sensitive varieties this area was reduced to about 2.0%, whereas in Katya it was around 6.0%. The results are discussed in terms of possible mechanisms underlying variety-specific mitochondrial responses to dehydration.

Biochemical consequences in yeast of the human mitochondrial DNA 8993T > C mutation in the ATPase6 gene found in NARP/MILS patients

We have created and analyzed the properties of a yeast model of the human mitochondrial DNA T8993C mutation that has been associated with maternally-inherited Leigh syndrome and/or with neurogenic muscle weakness, ataxia and retinitis pigmentosa. This mutation changes a highly conserved leucine to proline in the Atp6p subunit of the ATP synthase, at position 156 in the human protein, position 183 in yeast. In vitro the yeast T8993C mitochondria showed a 40–50% decrease in the rate of ATP synthesis. The ATP-driven translocation of protons across the inner mitochondrial membrane was normal in the mutant and fully sensitive to oligomycin, an inhibitor of the ATP synthase proton channel. However under conditions of maximal ATP hydrolytic activity, using non-osmotically protected mitochondria, the mutant ATPase activity was poorly inhibited by oligomycin (by 40% versus 85% in wild type cells). These anomalies were attributed by BN-PAGE and mitochondrial protein synthesis analyses to a less efficient incorporation of Atp6p within the ATP synthase. Interestingly, the cytochrome c oxidase content was selectively decreased by 40–50% in T8993C yeast, apparently due to a reduced synthesis of its mitochondrially encoded Cox1p subunit. This observation further supports the existence of a control of cytochrome c oxidase expression by the ATP synthase in yeast mitochondria. Despite the ATPase deficiency, growth of the atp6-L183P mutant on respiratory substrates and the efficiency of oxidative phosphorylation were similar to that of wild type, indicating that the mutation did not affect the proton permeability of the mitochondrial inner membrane.