Association of ATP synthase alpha-chain with neurofibrillary degeneration in Alzheimer's disease.

Amyloid deposits and neurofibrillary tangles (NFT) are the two hallmarks that characterize Alzheimer's disease (AD). In order to find the molecular partners of these degenerating processes, we have developed antibodies against insoluble AD brain lesions. One clone, named AD46, detects only NFT. Biochemical and histochemistry analyses demonstrate that the labeled protein accumulating in the cytosol of Alzheimer degenerating neurons is the alpha-chain of the ATP synthase. The cytosolic accumulation of the alpha-chain of ATP synthase is observed even at early stages of neurofibrillary degenerating process. It is specifically observed in degenerating neurons, either alone or tightly associated with aggregates of tau proteins, suggesting that it is a new molecular event related to neurodegeneration. Overall, our results strongly suggest the implication of the alpha-chain of ATP synthase in neurofibrillary degeneration of AD that is illustrated by the cytosolic accumulation of this mitochondrial protein, which belongs to the mitochondrial respiratory system. This regulatory subunit of the respiratory complex V of mitochondria is thus a potential target for therapeutic and diagnostic strategies.

Identification of a nuclear gene (FMC1) required for the assembly/stability of yeast mitochondrial F(1)-ATPase in heat stress conditions.

We have identified a yeast nuclear gene (FMC1) that is required at elevated temperatures (37 degrees C) for the formation/stability of the F(1) sector of the mitochondrial ATP synthase. Western blot analysis showed that Fmc1p is a soluble protein located in the mitochondrial matrix. At elevated temperatures in yeast cells lacking Fmc1p, the alpha-F(1) and beta-F(1) proteins are synthesized, transported, and processed to their mature size. However, instead of being incorporated into a functional F(1) oligomer, they form large aggregates in the mitochondrial matrix. Identical perturbations were reported previously for yeast cells lacking either Atp12p or Atp11p, two specific assembly factors of the F(1) sector (Ackerman, S. H., and Tzagoloff, A. (1990) Proc. Natl. Acad. Sci. U. S. A. 87, 4986--4990), and we show that the absence of Fmc1p can be efficiently compensated for by increasing the expression of Atp12p. However, unlike Atp12p and Atp11p, Fmc1p is not required in normal growth conditions (28--30 degrees C). We propose that Fmc1p is required for the proper folding/stability or functioning of Atp12p in heat stress conditions.

Bovine coupling factor 6, with just 14.5% shared identity, replaces subunit h in the yeast ATP synthase.

The mammalian mitochondrial ATP synthase is composed of at least 16 polypeptides. With the exception of coupling factor F(6), there are likely yeast homologs for each of these polypeptides. There are no obvious yeast homologs of F(6), as predicted from primary sequence comparison of the putative peptides encoded by the open reading frames in the yeast genome. In this manuscript, we demonstrate that expression of bovine F(6) complements a null mutant in ATP14 gene in yeast Saccharomyces cerevisiae. Subunit h of the yeast ATP synthase is encoded by ATP14 and is just 14.5% identical to bovine F(6). Expression of bovine F(6) in an atp14 null mutant strain recovers oxidative phosphorylation, and the ATP synthase is active, although functioning with a lower efficiency than the wild type enzyme. Like subunit h, bovine F(6) is shown to interact mainly with subunit 4 (subunit b), a component of the second stalk of the enzyme. These data indicated the subunit h is the yeast homolog of mammalian coupling factor F(6).

Organisation of the yeast ATP synthase F(0):a study based on cysteine mutants, thiol modification and cross-linking reagents.

A topological study of the yeast ATP synthase membranous domain was undertaken by means of chemical modifications and cross-linking experiments on the wild-type complex and on mutated enzymes obtained by site-directed mutagenesis of genes encoding ATP synthase subunits. The modification by non-permeant maleimide reagents of the Cys-54 of mutated subunit 4 (subunit b), of the Cys-23 in the N-terminus of subunit 6 (subunit a) and of the Cys-91 in the C-terminus of mutated subunit f demonstrated their location in the mitochondrial intermembrane space. Near-neighbour relationships between subunits of the complex were demonstrated by means of homobifunctional and heterobifunctional reagents. Our data suggest interactions between the first transmembranous alpha-helix of subunit 6, the two hydrophobic segments of subunit 4 and the unique membrane-spanning segments of subunits i and f. The amino acid residue 174 of subunit 4 is close to both oscp and the beta-subunit, and the residue 209 is close to oscp. The dimerisation of subunit 4 in the membrane revealed that this component is located in the periphery of the enzyme and interacts with other ATP synthase complexes.

Absence of the mitochondrial AAA protease Yme1p restores F0-ATPase subunit accumulation in an oxa1 deletion mutant of Saccharomyces cerevisiae.

The nuclear gene OXA1 encodes a protein located within the mitochondrial inner membrane that is required for the biogenesis of both cytochrome c oxidase (Cox) and ATPase. In the absence of Oxa1p, the translocation of the mitochondrially encoded subunit Cox2p to the intermembrane space (also referred to as export) is prevented, and it has been proposed that Oxa1p could be a component of a general mitochondrial export machinery. We have examined the role of Oxa1p in light of its relationships with two mitochondrial proteases, the matrix protease Afg3p-Rca1p and the intermembrane space protease Yme1p, by analyzing the assembly and activity of the Cox and ATPase complexes in Deltaoxa1, Deltaoxa1Deltaafg3, and Deltaoxa1Deltayme1 mutants. We show that membrane subunits of both complexes are specifically degraded in the absence of Oxa1p. Neither Afg3p nor Yme1p is responsible for the degradation of Cox subunits. However, the F(0) subunits Atp4p, Atp6p, and Atp17p are stabilized in the Deltaoxa1Deltayme1 double mutant, and oligomycin-sensitive ATPase activity is restored, showing that the increased stability of the ATPase subunits allows significant translocation and assembly to occur even in the absence of Oxa1p. These results suggest that Oxa1p is not essential for the export of ATPase subunits. In addition, although respiratory function is dispensable in Saccharomyces cerevisiae, we show that the simultaneous inactivation of AFG3 and YME1 is lethal and that the essential function does not reside in their protease activity.

Environmental study of subunit i, a F(o) component of the yeast ATP synthase.

The topology of subunit i, a component of the yeast F(o)F(1)-ATP synthase, was determined by the use of cysteine-substituted mutants. The N(in)-C(out) orientation of this intrinsic subunit was confirmed by chemical modification of unique cysteine residues with 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid. Near-neighbor relationships between subunit i and subunits 6, f, g, and d were demonstrated by cross-link formation following sulfhydryl oxidation or reaction with homobifunctional and heterobifunctional reagents. Our data suggest interactions between the unique membrane-spanning segment of subunit i and the first transmembranous alpha-helix of subunit 6 and a stoichiometry of 1 subunit i per complex. Cross-linked products between mutant subunits i and proteins loosely bound to the F(o)F(1)-ATP synthase suggest that subunit i is located at the periphery of the enzyme and interacts with proteins of the inner mitochondrial membrane that are not involved in the structure of the yeast ATP synthase.

The Saccharomyces cerevisiae ATP synthase.

The ATP synthase of the yeast Saccharomyces cerevisiae is composed of 20 different subunits whose primary structure is known. The organization of proteins that constitute the membranous domain is now under investigation. Cysteine insertions combined with the use of nonpermeant maleimide reagents and cross-linking reagents showing different lengths and specificity contribute to the knowledge of the location of the N- and C-termini of the subunits involved in the stator of the enzyme and their organization. This review summarizes data on yeast ATP synthase obtained in our laboratory since 1980.

The second stalk of the yeast ATP synthase complex: identification of subunits showing cross-links with known positions of subunit 4 (subunit b).

A component of the stator of the yeast ATP synthase (subunit 4 or b) showed many cross-linked products with the homobifunctional reagent dithiobis[succinimidyl propionate], which reacts with the amino group of lysine residues. The positions in subunit 4 that were involved in the cross-linkings were determined by using cysteine-generated mutants constructed by site-directed mutagenesis of ATP4. Cross-linking experiments with the heterobifunctional reagent p-azidophenacyl bromide, which has a spacer arm of 9 A, were performed with mitochondria and crude Triton X-100 extracts containing the solubilized enzyme. Substitution of lysine residues by cysteine residues in the hydrophilic C-terminal part of subunit 4 allowed cross-links with subunit h from C98 and with subunit d from C141, C143, and C151. OSCP was cross-linked from C174 and C209. A cross-linked product, 4+beta, was also obtained from C174. It is concluded that the C-terminus of subunit 4 is distant from the membrane surface and close to F(1) and OSCP. The N-terminal part of subunit 4 is close to subunit g, as demonstrated by the identification of a cross-linked product involving subunit g and the cysteine residues 7 or 14 of subunit 4.

Subunit f of the yeast mitochondrial ATP synthase: topological and functional studies.

Modified versions of subunit f were produced by mutagenesis of the ATP17 gene of Saccharomyces cerevisiae. A version of subunit f devoid of the last 28 amino acid residues including the unique transmembranous domain complemented the oxidative phosphorylation of the null mutant. However, a two-fold decrease in the specific ATP synthase activity was measured and attributed to a decrease in the stability of the mutant ATP synthase complex as shown by the low oligomycin-sensitive ATPase activity at alkaline pH. The modification or not by nonpermeant maleimide reagents of cysteine residues introduced at the N and C termini of subunit f indicated a Nin-Cout orientation. From the C terminus of subunit f it was possible to cross-link subunit 4 (also called subunit b), which is another component of the F0 sector and which also displays a short hydrophilic segment exposed to the intermembrane space.

Activation and deactivation of F0F1-ATPase in yeast mitochondria.

The regulation of membrane-bound proton F0F1 ATPase by the protonmotive force and nucleotides was studied in yeast mitochondria. Activation occurred in whole mitochondria and the ATPase activity was measured just after disrupting the membranes with Triton X-100. Deactivation occurred either in whole mitochondria uncoupled with FCCP, or in disrupted membranes. No effect of Triton X-100 on the ATPase was observed, except a slow reactivation observed only in the absence of MgADP. Both AMPPNP and ATP increased the ATPase deactivation rate, thus indicating that occupancy of nucleotidic sites by ATP is more decisive than catalytic turnover for this process. ADP was found to stimulate the energy-dependent ATPase activation. ATPase deactivated at the same rate in uncoupled and disrupted mitochondria This suggests that deactivation is not controlled by rebinding of some soluble factor, like IF1, but rather by the conversion of the F1.IF1 complex into an inactive form.

Isolation of supernumerary yeast ATP synthase subunits e and i. Characterization of subunit i and disruption of its structural gene ATP18.

Two subunits of the yeast ATP synthase have been isolated. Subunit e was found loosely associated to the complex. Triton X-100 at a 1% concentration removed this subunit from the ATP synthase. The N-terminal sequencing of subunit i has been performed. The data are in agreement with the sequence of the predicted product of a DNA fragment of Saccharomyces cerevisiae chromosome XIII. The ATP18 gene encodes subunit i, which is 59 amino acids long and corresponds to a calculated mass of 6687 Da. Its pI is 9.73. It is an amphiphilic protein having a hydrophobic N-terminal part and a hydrophilic C-terminal part. It is not apparently related to any subunit described in other ATP synthases. The null mutant showed low growth on nonfermentable medium. Mutant mitochondria display a low ADP/O ratio and a decrease with time in proton pumping after ATP addition. Subunit i is associated with the complex; it is not a structural component of the enzyme but rather is involved in the oxidative phosphorylations. Similar amounts of ATP synthase were measured for wild-type and null mutant mitochondria. Because 2-fold less specific ATPase activity was measured for the null mutant than for the wild-type mitochondria, we make the hypothesis that the observed decrease in the turnover of the mutant enzyme could be linked to a proton translocation defect through F0.

Evidence of a subunit 4 (subunit b) dimer in favor of the proximity of ATP synthase complexes in yeast inner mitochondrial membrane.

Yeast mitochondria having either the D54C or E55C mutations in subunit 4 (subunit b), which is a component of the ATP synthase stator, displayed a spontaneous disulfide bridge between two subunits 4. This dimer was not soluble upon Triton X-100 extraction either at concentrations which extract the yeast ATP synthase or at higher concentrations. Increasing detergent concentrations led to a lack of the oligomycin-sensitive ATPase activity, thus showing an uncoupling between the two sectors of the mutated enzymes due to the dissociation of the subunit 4 dimer from the mutant enzyme. There is only one subunit 4 (subunit b) per eukaryotic ATP synthase. As a consequence, the results are interpreted as the proximity of ATP synthase complexes within the inner mitochondrial membrane.

The Mitochondrial F0F1-ATPase proton pump is required for function of the proapoptotic protein Bax in yeast and mammalian cells.

The proapoptotic mammalian protein Bax associates with mitochondrial membranes and confers a lethal phenotype when expressed in yeast. By generating Bax-resistant mutant yeast and using classical complementation cloning methods, subunits of the mitochondrial F0F1-ATPase proton pump were determined to be critical for Bax-mediated killing in S. cerevisiae. A pharmacological inhibitor of the proton pump, oligomycin, also partially abrogated the cytotoxic actions of Bax in yeast. In mammalian cells, oligomycin also inhibited Bax-induced apoptosis and activation of cell death proteases. The findings imply that an intact F0F1-ATPase in the inner membrane of mitochondria is necessary for optimal function of Bax in both yeast and mammalian cells.

Topography of the yeast ATP synthase F0 sector by using cysteine substitution mutants. Cross-linkings between subunits 4, 6, and f.

The arrangement of the N-terminal part of subunit 4 (subunit b) has been studied by the use of mutants containing cysteine residues in a loop connecting the two N-terminal postulated membrane-spanning segments. Labelling of the mutated subunit 4 by the fluorescent probe N-(7-(dimethylamino)-4-methyl-3-coumarinyl)maleimide revealed that the sulfhydryl groups were modified upon incubation of intact mitochondria. In addition, the nonpermeant sulfhydryl reagent 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid prevented the 3-(N-maleimidylpropionyl)biocytin labeling of subunit 4D54C, thus showing a location of this residue in the intermembrane space. Cross-linking experiments revealed the proximity of subunits 4 and f. In addition a disulfide bridge between subunit 4D54C and subunit 6 was evidenced, thus demonstrating near-neighbor relationships of the two subunits and a location of the N-terminal part of the mitochondrially-encoded subunit 6 in the intermembrane space.

Topography of the yeast ATP synthase F0 sector.

The interaction between the hydrophilic C-terminal part of subunit 4 (subunit b) and OSCP, which are two components of the connecting stalk of the yeast ATP synthase, was shown after reconstitution of the two over-expressed proteins and by the two-hybrid method. The organization of a part of the F0 sector was studied by the use of mutants containing cysteine residues in a loop connecting the two N-terminal postulated membrane-spanning segments. Labelling of the mutated subunits 4 by a maleimide fluorescent probe revealed that the sulfhydryl groups were modified upon incubation of intact mitochondria. In addition, non-permeant maleimide reagents labeled subunit 4D54C, thus showing a location of this residue in the intermembrane space. Cross-linking experiments revealed the proximity of subunits 4 and f. In addition, a disulfide bridge between subunit 4D54C and subunit 6 was evidenced, thus demonstrating near-neighbor relationships of the two subunits and a location of the N-terminal part of the mitochondrially-encoded subunit 6 in the intermembrane space.

The subunit f of mitochondrial yeast ATP synthase--characterization of the protein and disruption of the structural gene ATP17.

The subunit f of the yeast F1F0ATP synthase has been isolated from the purified enzyme. Amino acid composition, protein and peptide sequencing were performed. The data are in agreement with the sequence of the predicted product of the gene D9481.21 identified on the Saccharomyces cerevisiae chromosome IV. A 303-bp open reading frame encoding a 101-amino acid polypeptide is described. The deduced amino acid sequence from the ATP17 gene is 6 amino acids longer than the mature protein, which displays a molecular mass of 10567 Da. The protein is basic with a short hydrophobic segment located in the C-terminal part of the subunit. Subunit f remained associated with other F0 subunits upon sodium bromide treatment of the whole enzyme. A null mutant was constructed. The disrupted strain was unable to grow on glycerol medium and the mutation was recessive; rho- cells arose spontaneously. The null mutant mitochondria were devoid of oligomycin-sensitive ATPase, but still contained an active F1, while the subunits f, 6 and 8 were absent.

The absence of the mitochondrial ATP synthase delta subunit promotes a slow growth phenotype of rho- yeast cells by a lack of assembly of the catalytic sector F1.

In the yeast Saccharomyces cerevisiae, inactivation of the gene encoding the delta subunit of the ATP synthase led to a lack of assembly of the catalytic sector. In addition a slow-growth phenotype was observed on fermentable medium. This alteration appears in strains lacking intact mitochondrial DNA and showing a defect in the assembly of the catalytic sector, such as the yeast strain inactivated in the gene encoding the epsilon subunit. In rho mitochondria having an intact F1, the ion movement resulting from the exchange of ADP formed in the organelle and ATP entering the mitochondrial compartment led to a mitochondrial transmembranous potential delta psi that was sensitive to carboxyactractyloside. This ion movement was dramatically decreased in rho mitochondria lacking the delta subunit and thus the F1 sector, whereas a cell devoid of delta subunit and complemented with a plasmid harboring the ATPdelta gene displayed an assembled F1, a normal generation time and a fully restored mitochondrial potential. This result could be linked to the involvement of the membrane potential delta psi which is indispensible for mitochondrial biogenesis.

ATP synthase of yeast mitochondria. Isolation of the subunit h and disruption of the ATP14 gene.

A new subunit of the yeast ATP synthase (termed subunit h) has been isolated. Amino acid composition and N-terminal sequencing were determined by chemical methods. These data were in agreement with the sequence of the hypothetical protein L8003.20 whose primary structure was deduced from DNA sequencing of the yeast chromosome XII. The amino acid sequence encoded by ATP14 gene is 32 amino acids longer than the mature protein, which contains 92 amino acids corresponding to a calculated mass of 10,408 Da. The protein is hydrophilic and acidic with a calculated pHi of 4.08. It is not apparently related to any subunit described in other ATP synthases. A null mutant was constructed. The mutation was recessive and the mutant strain was unable to grow on glycerol medium. A high percentage of rho- cells arose spontaneously. The mutant mitochondria had no detectable oligomycin-sensitive ATPase activity, but still contained ATPase activity with a catalytic sector dissociated from the membranous components. The mutant mitochondria did not contain subunit h, and the mitochondrially encoded hydrophobic subunit 6 was not present.

The inhibition of phosphoenolpyruvate carboxykinase following in vivo chronic phenobarbital treatment in the rat is due to a post-translational event.

Chronic treatment of rats with phenobarbital has been reported to decrease gluconeogenesis in rat hepatocytes by a 50% inhibition of phosphoenolpyruvate (P-pyruvate) carboxykinase activity [Argaud, D., Halimi, S., Catelloni, F. & Leverve, X. (1991) Biochem. J. 280, 663-669]. Contrary to the current knowledge of P-pyruvate carboxykinase regulation, we failed to find a diminution of either P-pyruvate carboxykinase protein (by using a polyclonal antibody) or P-pyruvate carboxykinase mRNA, in the liver of rats treated with phenobarbital for 2 weeks. Kinetic studies of P-pyruvate carboxykinase activity, measured by either carboxylation of P-pyruvate or decarboxylation of oxaloacetate, revealed a decrease in both V(max) and Km after phenobarbital treatment, whereas the nutritional state affected only the V(max), as expected. Assessment of P-pyruvate carboxykinase specificity was confirmed by the full inhibition of the enzyme with its specific inhibitor 3-mercaptopicolinate in the micromolar range. P-Pyruvate carboxykinase, purified either by ammonium sulfate fractionation or by immunoprecipitation, exhibited a similar decrease in affinity after phenobarbital treatment. Although the molecular mass does not appear to be altered, the pH sensitivity to 3-mercaptopicolinate inhibition and the enzyme recovery after immunoprecipitation both seemed to be affected. This leads us to propose that the effect of chronic phenobarbital treatment on P-pyruvate carboxykinase activity is not the result of transcriptional regulation but is exerted at the post-translational level.