Orientation of chargerin II (A6L) in the ATP synthase of rat liver mitochondria determined with antibodies against peptides of the protein

Previous studies suggested that the hydrophobic protein chargerin II, which is encoded in the unidentified reading frame A6L of mitochondrial DNA (URFA6L), may have a key role in the energy transduction by mitochondrial ATP synthase because an antibody against chargerin II inhibited ATP synthesis and ATP-Pi exchange, in an energy-dependent fashion. In the present work, the orientation of chargerin II in Fo of the ATP synthase of rat liver mitochondria was examined using antibodies against peptides of chargerin II. Results showed that its N-terminal region (about 8 amino acid residues) was exposed on the surface of the C-side of Fo, but its C-terminal and charge-cluster regions were buried in Fo.     

Assaying ATP synthesis in cultured cells: A valuable tool for the diagnosis of patients with mitochondrial disorders

Mitochondrial ATP synthase plays a central role in cell function by synthesising most of the ATP in human tissues. In different cells, active regulation of mitochondrial ATP synthase in response to cellular energy demand has been demonstrated, as well as its alteration under several pathological conditions affecting oxidative phosphorylation (OXPHOS). Traditionally, detection of OXPHOS defects is based on the spectrophotometric measurement of respiratory chain complex activities in muscle biopsies. Considering the broad clinical spectrum of mitochondrial disorders, and the difficulty in arriving at a single diagnostic method, in this study we propose measurement of ATP synthesis in mitochondria from skin fibroblasts as an effective screening tool. In the light of our results this assessment emerges as a useful marker of impaired energy production in primary OXPHOS disorders of childhood and as a tool with the potential to drive further molecular genetic studies.     

Betanodavirus B2 Causes ATP Depletion-induced Cell Death via Mitochondrial Targeting and Complex II Inhibition in Vitro and in Vivo

The betanodavirus non-structural protein B2 is a newly discovered necrotic death factor with a still unknown role in regulation of mitochondrial function. In the present study, we examined protein B2-mediated inhibition of mitochondrial complex II activity, which results in ATP depletion and thereby in a bioenergetic crisis in vitro and in vivo. Expression of protein B2 was detected early at 24 h postinfection with red-spotted grouper nervous necrosis virus in the cytoplasm. Later B2 was found in mitochondria using enhanced yellow fluorescent protein (EYFP) and immuno-EM analysis. Furthermore, the B2 mitochondrial targeting signal peptide was analyzed by serial deletion and specific point mutation. The sequence of the B2 targeting signal peptide (⁴¹RTFVISAHAA⁵⁰) was identified and its presence correlated with loss of mitochondrial membrane potential in fish cells. Protein B2 also was found to dramatically inhibit complex II (succinate dehydrogenase) activity, which impairs ATP synthesis in fish GF-1 cells as well as human embryonic kidney 293T cells. Furthermore, when B2 was injected into zebrafish embryos at the one-cell stage to determine its cytotoxicity and ability to inhibit ATP synthesis, we found that B2 caused massive embryonic cell death and depleted ATP resulting in further embryonic death at 10 and 24 h post-fertilization. Taken together, our results indicate that betanodavirus protein B2-induced cell death is due to direct targeting of the mitochondrial matrix by a specific signal peptide that targets mitochondria and inhibits mitochondrial complex II activity thereby reducing ATP synthesis.     

Identification of subunit g of yeast mitochondrial F1F0-ATP synthase, a protein required for maximal activity of cytochrome c oxidase.

By means of a yeast genome database search, we have identified an open reading frame located on chromosome XVI of Saccharomyces cerevisiae that encodes a protein with 53% amino acid similarity to the 11.3-kDa subunit g of bovine mitochondrial F1F0-ATP synthase. We have designated this ORF ATP20, and its product subunit g. A null mutant strain, constructed by insertion of the HIS3 gene into the coding region of ATP20, retained oxidative phosphorylation function. Assembly of F1F0-ATP synthase in the atp20-null strain was not affected in the absence of subunit g and levels of oligomycin-sensitive ATP hydrolase activity in mitochondria were normal. Immunoprecipitation of F1F0-ATP synthase from mitochondrial lysates prepared from atp20-null cells expressing a variant of subunit g with a hexahistidine motif indicated that this polypeptide was associated with other well-characterized subunits of the yeast complex. Whilst mitochondria isolated from the atp20-null strain had the same oxidative phosphorylation efficiency (ATP : O) as that of the control strain, the atp20-null strain displayed approximately a 30% reduction in both respiratory capacity and ATP synthetic rate. The absence of subunit g also reduced the activity of cytochrome c oxidase, and altered the kinetic control of this complex as demonstrated by experiments titrating ATP synthetic activity with cyanide. These results indicate that subunit g is associated with F1F0-ATP synthase and is required for maximal levels of respiration, ATP synthesis and cytochrome c oxidase activity in yeast.     

Cooperation and Competition between Adenylate Kinase,Nucleoside Diphosphokinase,Electron Transport,and ATP Synthase in Plant Mitochondria Studied by 31P-Nuclear Magnetic Resonance

Nucleotide metabolism in potato (Solanum tuberosum) mitochondria was studied using 31P-nuclear magnetic resonance spectroscopy and the O2 electrode. Immediately following the addition of ADP, ATP synthesis exceeded the rate of oxidative phosphorylation, fueled by succinate oxidation, due to mitochondrial adenylate kinase (AK) activity two to four times the maximum activity of ATP synthase. Only when the AK reaction approached equilibrium was oxidative phosphorylation the primary mechanism for net ATP synthesis. A pool of sequestered ATP in mitochondria enabled AK and ATP synthase to convert AMP to ATP in the presence of exogenous inorganic phosphate. During this conversion, AK activity can indirectly influence rates of oxidation of both succinate and NADH via changes in mitochondrial ATP. Mitochondrial nucleoside diphosphokinase, in cooperation with ATP synthase, was found to facilitate phosphorylation of nucleoside diphosphates other than ADP at rates similar to the maximum rate of oxidative phosphorylation. These results demonstrate that plant mitochondria contain all of the machinery necessary to rapidly regenerate nucleoside triphosphates from AMP and nucleoside diphosphates made during cellular biosynthesis and that AK activity can affect both the amount of ADP available to ATP synthase and the level of ATP regulating electron transport.     

Activation of ATP hydrolysis by an uncoupler in mutant mitochondria lacking an intrinsic ATPase inhibitor in yeast

An intrinsic ATPase inhibitor and 9-kDa protein are regulatory factors of mitochondrial ATP synthase in Saccharomyces cerevisiae. A gene encoding the ATPase inhibitor was isolated from a yeast genomic library with synthetic oligonucleotides as hybridization probes and was sequenced. The deduced amino acid sequence showed that the precursor protein contains an amino-terminal presequence of 22 amino acid residues. Mutant strains that did not contain the inhibitor and/or the 9-kDa protein were constructed by transformation of cells with their in vitro disrupted genes. The disruption of the chromosomal copy in recombinant cells was verified by Southern blot analysis, and the absence of the proteins in the mutant cells was confirmed by Western blot analysis. All the mutants could grow on a nonfermentable carbon source and the oxidative phosphorylation activities of their isolated mitochondria were the same as that of normal mitochondria. However, an uncoupler, carbonylcyanide-m-chlorophenylhydrazone, induced marked ATP hydrolysis in the inhibitor-deficient mitochondria, but not in normal mitochondria. These observations suggest that the ATPase inhibitor inhibits ATP hydrolysis by F1F0-ATPase only when the membrane potential is lost.     

Expression of the mammalian mitochondrial genome. Role for membrane potential in the production of mature translation products

Protein synthesis was investigated in isolated mitochondria under conditions which either inhibited electron transport or uncoupled oxidative phosphorylation. In a medium containing an exogenous source of ATP and oligomycin, an inhibitor of the ATP synthase complex, incorporation of [35S]methionine into proteins is stimulated in the presence of inhibitors of the electron transport chain; substituting uncouplers of oxidative phosphorylation for the latter leads, in contrast, to a decrease in the rate of incorporation of the labeled amino acid into mitochondrial translation products. Studies on the metabolic stability of mitochondrial translation products revealed that "mature" polypeptides made in isolated mitochondria are stable as indicated by the absence of degradation during a 50 min "chase" period. Under conditions which reduce or dissipate the membrane potential, 50-60% of the newly made polypeptides (pulse) are degraded within 50 min. The kinetics of the degradation process for individual mitochondrial gene products reveal that the largest proportion of polypeptides degraded to an acid-soluble form during the chase period are abnormal proteins, likely the result of premature chain termination. Emerging as a common denominator in these studies is a role for a transmembrane potential across the inner membrane in the production of mature "stable" mitochondrial gene products.     

Increasing mitochondrial substrate-level phosphorylation can rescue respiratory growth of an ATP synthase-deficient yeast

In a previous study we have identified Fmc1p, a mitochondrial protein involved in the assembly/stability of the yeast F0F1-ATP synthase at elevated temperatures. The deltafmc1 mutant was shown to exhibit a severe phenotype of very slow growth on respiratory substrates at 37 degrees C. We have isolated ODC1 as a multicopy suppressor of the fmc1 deletion restoring a good respiratory growth. Odc1p expression level was estimated to be at least 10 times higher in mitochondria isolated from the deltafmc1/ODC1 transformant as compared with wild type mitochondria. Interestingly, ODC1 encodes an oxodicarboxylate carrier, which transports alpha-ketoglutarate and alpha-ketoadipate or any other transported tricarboxylic acid cycle intermediate in a counter-exchange through the inner mitochondrial membrane. We show that the suppression of the respiratory-growth-deficient fmc1 by the overexpressed Odc1p was not due to a restored stable ATP synthase. Instead, the rescuing mechanism involves an increase in the flux of tricarboxylic acid cycle intermediate from the cytosol into the mitochondria, leading to an increase in the alpha-ketoglutarate oxidative decarboxylation, resulting in an increase in mitochondrial substrate-level-dependent ATP synthesis. This mechanism of metabolic bypass of a defective ATP synthase unravels the physiological importance of intramitochondrial substrate-level phosphorylations. This unexpected result might be of interest for the development of therapeutic solutions in pathologies associated with defects in the oxidative phosphorylation system.     

Direct protein sequencing of wheat mitochondrial ATP synthase subunit 9 confirms RNA editing in plants

RNA editing, a process that results in the production of RNA molecules having a nucleotide sequence different from that of the initial DNA template, has been demonstrated in several organisms using different biochemical pathways. Very recently RNA editing was described in plant mitochondria following the discovery that the sequence of certain wheat and Oenothera cDNAs is different from the nucleotide sequence of the corresponding genes. The main conversion observed was C to U, leading to amino acid changes in the deduced protein sequence when these modifications occurred in an open reading frame. In this communication we show the first attempt to isolate and sequence a protein encoded by a plant mitochondrial gene. Subunit 9 of the wheat mitochondrial ATP synthase complex was purified to apparent homogeneity and the sequence of the first 32 amino acid residues was determined. We have observed that at position 7 leucine was obtained by protein sequencing, instead of the serine predicted from the previously determined genomic sequence. Also we found phenylalanine at position 28 instead of a leucine residue. Both amino acid conversions, UCA (serine) to UUA (leucine) and CUC (leucine) to UUC (phenylalanine), imply a C to U change. Thus our results seem to confirm, at the protein level, the RNA editing process in plant mitochondria.     

Harpin-induced hypersensitive cell death is associated with altered mitochondrial functions in tobacco cells

Mitochondria play important roles in animal apoptosis and are implicated in salicylic acid (SA)-induced plant resistance to viral pathogens. In a previous study, we demonstrated that SA induces rapid inhibition of mitochondrial electron transport and oxidative phosphorylation in tobacco cells. In the present study, we report that plant programmed cell death induced during pathogen elicitor-induced hypersensitive response (HR) is also associated with altered mitochondrial functions. Harpin, an HR elicitor produced by Erwinia amylovora, induced inhibition of ATP synthesis in tobacco cell cultures. Inhibition of ATP synthesis occurred almost immediately after incubation with harpin and preceded hypersensitive cell death induced by the elicitor. Diphenylene iodonium, an inhibitor of the oxidative burst, did not block harpin-induced inhibition of ATP synthesis or cell death, suggesting that oxidative burst was not the direct cause for these two harpin-induced processes. Unlike SA, harpin had no significant effect on total respiratory O2 uptake of treated cells. However, respiration of harpin-treated tobacco cells became very sensitive to the alternative oxidase inhibitors salicyl-hydroxamic acid and n-propyl gallate. Thus, harpin treatment resulted in reduced capacity of mitochondrial cytochrome pathway electron transport, which could lead to the observed inhibition of ATP synthesis. Given the recently demonstrated roles of mitochondria in apoptosis, this rapid inhibition of mitochondrial functions may play a role in harpin-induced hypersensitive cell death.     

Transport of the yeast ATP synthase beta-subunit into mitochondria. Effects of amino acid substitutions on targeting.

We have isolated the yeast ATP2 gene encoding the beta-subunit of mitochondrial ATP synthase and determined its nucleotide sequence. A fusion between the N-terminal 15 amino acid residues of beta-subunit and the mouse cytosolic protein dihydrofolate reductase (DHFR) was transcribed and translated in vitro and found to be transported into isolated yeast mitochondria. A fusion with the first 35 amino acid residues of beta-subunit attached to DHFR was not only transported but also proteolytically processed by a mitochondrial protease. Amino acid substitutions were introduced into the N-terminal presequence of the beta-subunit by bisulphite mutagenesis of the corresponding DNA. The effects of these mutations on mitochondrial targeting were assessed by transport experiments in vitro using DHFR fusion proteins. All of the mutants, harbourin from one to six amino acid substitutions in the first 14 residues of the presequence, were transported into mitochondria, though at least one of them (I8) was transported and proteolytically processed at a much reduced rate. The I8 mutant beta-subunit also exhibited poor transport and processing in vivo, and expression of this mutant polypeptide failed to complement the glycerol- phenotype of a yeast ATP2 mutant. More remarkably, the expression of I8 beta-subunit induced a more general growth defect in yeast, possibly due to interference with the transport of other, essential, mitochondrial proteins.     

The sequence of the major protein stored in ovine ceroid lipofuscinosis is identical with that of the dicyclohexylcarbodiimide-reactive proteolipid of mitochondrial ATP synthase.

The ceroid lipofuscinoses are a group of neurodegenerative lysosomal storage diseases of children and animals that are recessively inherited. In diseased individuals fluorescent storage bodies accumulate in a wide variety of cells, including neurons. Previous studies of these bodies isolated from tissues of affected sheep confirmed that the storage occurs in lysosomes, and showed that the storage body is mostly made of a single protein with an apparent molecular mass of 3500 Da with an N-terminal amino acid sequence that is the same as residues 1-40 of the c-subunit (or dicyclohexylcarbodi-imide-reactive proteolipid) of mitochondrial ATP synthase. In the present work we have shown by direct analysis that the stored protein is identical in sequence with the entire c-subunit of mitochondrial ATP synthase, a very hydrophobic protein of 75 amino acid residues. As far as can be detected by the Edman degradation, the stored protein appears not to have been subject to any post-translational modification other than the correct removal of the mitochondrial import sequences that have been shown in other experiments to be present at the N-terminal of its two different precursors. No other protein accumulates in the storage bodies to any significant extent. Taken with studies of the cDNAs for the c-subunit in normal and diseased sheep, these results indicate that the material that is stored in lysosomes of diseased animals has probably entered mitochondria and has been subjected to the proteolytic processing that is associated with mitochondrial import. This implies that the defect that leads to the lysosomal accumulation concerns the degradative pathway of the c-subunit of ATP synthase. An alternative, but less likely, hypothesis is that for some unknown reason the precursors of subunit c are being directly mis-targeted to lysosomes, where they become processed to yield a protein identical with the protein that is normally found in the mitochondrial ATP synthase assembly, and which then accumulates.     

Factor B is essential for ATP synthesis by mitochondria

Factor B is a water-soluble protein, which is required for the coupled activity of the mitochondrial ATP synthase complex. Specific removal of factor B from well-coupled bovine heart submitochondrial particles (SMP) results in uncoupling and the loss of ATP-driven membrane potential formation and reverse electron transfer from succinate to NAD. Addition of recombinant human factor B (molecular mass 20,341 Da) to factor B-depleted SMP (AE-SMP) restores these properties [G.I. Belogrudov, and Y. Hatefi, (2002) J. Biol. Chem. 277, 6097-6103]. This paper shows that extraction and purification of ATP synthase complex (complex V) from bovine heart mitochondria results in extensive loss of factor B. Addition of recombinant human factor B to AE-SMP completely restores the lost oxidative phosphorylation and ATP-32P(i) exchange activities of the particles and increases the ATP-32P(i) exchange activity of complex V by 2.5-fold. These results further indicate that factor B is an essential component of the mammalian ATP synthase complex.     

Knockdown of DAPIT (diabetes-associated protein in insulin-sensitive tissue) results in loss of ATP synthase in mitochondria

It was found recently that a diabetes-associated protein in insulin-sensitive tissue (DAPIT) is associated with mitochondrial ATP synthase. Here, we report that the suppressed expression of DAPIT in DAPIT-knockdown HeLa cells causes loss of the population of ATP synthase in mitochondria. Consequently, DAPIT-knockdown cells show smaller mitochondrial ATP synthesis activity, slower growth in normal medium, and poorer viability in glucose-free medium than the control cells. The mRNA levels of α- and β-subunits of ATP synthase remain unchanged by DAPIT knockdown. These results indicate a critical role of DAPIT in maintaining the ATP synthase population in mitochondria and raise an intriguing possibility of active role of DAPIT in cellular energy metabolism.     

Amino acid sequence of a new mitochondrially synthesized proteolipid of the ATP synthase of Saccharomyces cerevisiae.

The purification and the amino acid sequence of a proteolipid translated on ribosomes in yeast mitochondria is reported. This protein, which is a subunit of the ATP synthase, was purified by extraction with chloroform/methanol (2/1) and subsequent chromatography on phosphocellulose and reverse phase h.p.l.c. A mol. wt. of 5500 was estimated by chromatography on Bio-Gel P-30 in 80% formic acid. The complete amino acid sequence of this protein was determined by automated solid phase Edman degradation of the whole protein and of fragments obtained after cleavage with cyanogen bromide. The sequence analysis indicates a length of 48 amino acid residues. The calculated mol. wt. of 5870 corresponds to the value found by gel chromatography. This polypeptide contains three basic residues and no negatively charged side chain. The three basic residues are clustered at the C terminus. The primary structure of this protein is in full agreement with the predicted amino acid sequence of the putative polypeptide encoded by the mitochondrial aap1 gene recently discovered in Saccharomyces cerevisiae. Moreover, this protein shows 50% homology with the amino acid sequence of a putative polypeptide encoded by an unidentified reading frame also discovered near the mitochondrial ATPase subunit 6 gene in Aspergillus nidulans.     

Mitochondrial ATP synthasome. Cristae-enriched membranes and a multiwell detergent screening assay yield dispersed single complexes containing the ATP synthase and carriers for Pi and ADP/ATP

The terminal step of ATP synthesis in intact mitochondria is catalyzed by the ATP synthase (F(0)F(1)) that works in close synchrony with the P(i) and ADP/ATP carriers. Each carrier consists of only a single polypeptide chain in dimeric form, while the ATP synthase is highly complex consisting in animals of 17 known subunit types and more than 30 total subunits. Although structures at high resolution have been obtained for the water-soluble F(1) part of the ATP synthase consisting of only five subunit types, such structures have not been obtained for either the complete ATP synthase or the P(i) and ADP/ATP carriers. Here, we report that all three proteins are localized in highly purified cristae-like vesicles obtained by extensive subfractionation of the mitochondrial inner membrane. Moreover, using a multiwell detergent screening assay, 4 nonionic detergents out of 80 tested were found to disperse these cristae-like vesicles into single soluble complexes or "ATP synthasomes" that contain the ATP synthase in association with the P(i) and ADP/ATP carriers. These studies offer new mechanistic insights into the terminal steps of oxidative phosphorylation in mitochondria and set the stage for future structural efforts designed to visualize in atomic detail the entire complex involved. They also provide evidence that the cristae are a subcompartment of the inner membrane.     

Oxidative phosphorylation in a hybrid system containing bovine heart membranes and pea mitochondrial F1-ATPase

Purified pea mitochondrial F1-ATPase reconstituted oxidative phosphorylation in both partially and completely F1-depleted bovine heart mitochondrial membranes. The isolated plant enzyme exhibited high rates of ATP synthesis when combined with bovine heart membranes, suggesting great evolutionary conservation of the ATP synthase complex in mitochondria.     

Fatty liver and insulin resistance in obese Zucker rats: no role for mitochondrial dysfunction

The relationship between insulin resistance and mitochondrial function is of increasing interest. Studies looking for such interactions are usually made in muscle and only a few studies have been done in liver, which is known to be a crucial partner in whole body insulin action. Recent studies have revealed a similar mechanism to that of muscle for fat-induced insulin resistance in liver. However, the exact mechanism of lipid metabolites accumulation in liver leading to insulin resistance is far from being elucidated. One of the hypothetical mechanisms for liver steatosis development is an impairment of mitochondrial function. We examined mitochondrial function in fatty liver and insulin resistance state using isolated mitochondria from obese Zucker rats. We determined the relationship between ATP synthesis and oxygen consumption as well as the relationship between mitochondrial membrane potential and oxygen consumption. In order to evaluate the quantity of mitochondria and the oxidative capacity we measured citrate synthase and cytochrome c oxidase activities. Results showed that despite significant fatty liver and hyperinsulinemia, isolated liver mitochondria from obese Zucker rats display no difference in oxygen consumption, ATP synthesis, and membrane potential compared with lean Zucker rats. There was no difference in citrate synthase and cytochrome c oxidase activities between obese and lean Zucker rats in isolated mitochondria as well as in liver homogenate, indicating a similar relative amount of hepatic mitochondria and a similar oxidative capacity. Adiponectin, which is involved in bioenergetic homeostasis, was increased two-fold in obese Zucker rats despite insulin resistance. In conclusion, isolated liver mitochondria from lean and obese insulin-resistant Zucker rats showed strictly the same mitochondrial function. It remains to be elucidated whether adiponectin increase is involved in these results.     

Atp11p and Atp12p are chaperones for F(1)-ATPase biogenesis in mitochondria

The bioenergetic needs of aerobic cells are met principally through the action of the F(1)F(0) ATP synthase, which catalyzes ATP synthesis during oxidative phosphorylation. The catalytic unit of the enzyme (F(1)) is a multimeric protein of the subunit composition alpha(3)beta(3)(gamma)(delta) epsilon. Our work, which employs the yeast Saccharomyces cerevisiae as a model system for studies of mitochondrial function, has provided evidence that assembly of the mitochondrial alpha and beta subunits into the F(1) oligomer requires two molecular chaperone proteins called Atp11p and Atp12p. Comprehensive knowledge of Atp11p and Atp12p activities in mitochondria bears relevance to human physiology and disease as these chaperone actions are now known to exist in mitochondria of human cells.     

Attenuation of cardiac mitochondrial dysfunction by melatonin in septic mice

The existence of an inducible mitochondrial nitric oxide synthase has been recently related to the nitrosative/oxidative damage and mitochondrial dysfunction that occurs during endotoxemia. Melatonin inhibits both inducible nitric oxide synthase and inducible mitochondrial nitric oxide synthase activities, a finding related to the antiseptic properties of the indoleamine. Hence, we examined the changes in inducible nitric oxide synthase/inducible mitochondrial nitric oxide synthase expression and activity, bioenergetics and oxidative stress in heart mitochondria following cecal ligation and puncture-induced sepsis in wild-type (iNOS(+/+)) and inducible nitric oxide synthase-deficient (iNOS(-/-)) mice. We also evaluated whether melatonin reduces the expression of inducible nitric oxide synthase/inducible mitochondrial nitric oxide synthase, and whether this inhibition improves mitochondrial function in this experimental paradigm. The results show that cecal ligation and puncture induced an increase of inducible mitochondrial nitric oxide synthase in iNOS(+/+) mice that was accompanied by oxidative stress, respiratory chain impairment, and reduced ATP production, although the ATPase activity remained unchanged. Real-time PCR analysis showed that induction of inducible nitric oxide synthase during sepsis was related to the increase of inducible mitochondrial nitric oxide synthase activity, as both inducible nitric oxide synthase and inducible mitochondrial nitric oxide synthase were absent in iNOS(-/-) mice. The induction of inducible mitochondrial nitric oxide synthase was associated with mitochondrial dysfunction, because heart mitochondria from iNOS(-/-) mice were unaffected during sepsis. Melatonin treatment blunted sepsis-induced inducible nitric oxide synthase/inducible mitochondrial nitric oxide synthase isoforms, prevented the impairment of mitochondrial homeostasis under sepsis, and restored ATP production. These properties of melatonin should be considered in clinical sepsis.