ATP synthase of yeast mitochondria. Characterization of subunit d and sequence analysis of the structural gene ATP7

Characterization of a highly diverged mitochondrial ATP synthase Fo subunit in Trypanosoma brucei

The mitochondrial F1Fo ATP synthase of the parasite Trypanosoma brucei has been previously studied in detail. This unusual enzyme switches direction in functionality during the life cycle of the parasite, acting as an ATP synthase in the insect stages, and as an ATPase to generate mitochondrial membrane potential in the mammalian bloodstream stages. Whereas the trypanosome F1 moiety is relatively highly conserved in structure and composition, the Fo subcomplex and the peripheral stalk have been shown to be more variable. Interestingly, a core subunit of the latter, the normally conserved subunit b, has been resistant to identification by sequence alignment or biochemical methods. Here, we identified a 17 kDa mitochondrial protein of the inner membrane, Tb927.8.3070, that is essential for normal growth, efficient oxidative phosphorylation, and membrane potential maintenance. Pull-down experiments and native PAGE analysis indicated that the protein is both associated with the F1Fo ATP synthase and integral to its assembly. In addition, its knockdown reduced the levels of Fo subunits, but not those of F1, and disturbed the cell cycle. Finally, analysis of structural homology using the HHpred algorithm showed that this protein has structural similarities to Fo subunit b of other species, indicating that this subunit may be a highly diverged form of the elusive subunit b.

Mitochondrial Targeting Involving Cholesterol-Rich Lipid Rafts in the Mechanism of Action of the Antitumor Ether Lipid and Alkylphospholipid Analog Edelfosine

The ether lipid edelfosine induces apoptosis selectively in tumor cells and is the prototypic molecule of a family of synthetic antitumor compounds collectively known as alkylphospholipid analogs. Cumulative evidence shows that edelfosine interacts with cholesterol-rich lipid rafts, endoplasmic reticulum (ER) and mitochondria. Edelfosine induces apoptosis in a number of hematological cancer cells by recruiting death receptors and downstream apoptotic signaling into lipid rafts, whereas it promotes apoptosis in solid tumor cells through an ER stress response. Edelfosine-induced apoptosis, mediated by lipid rafts and/or ER, requires the involvement of a mitochondrial-dependent step to eventually elicit cell death, leading to the loss of mitochondrial membrane potential, cytochrome c release and the triggering of cell death. The overexpression of Bcl-2 or Bcl-xL blocks edelfosine-induced apoptosis. Edelfosine induces the redistribution of lipid rafts from the plasma membrane to the mitochondria. The pro-apoptotic action of edelfosine on cancer cells is associated with the recruitment of F1FO-ATP synthase into cholesterol-rich lipid rafts. Specific inhibition of the FO sector of the F1FO-ATP synthase, which contains the membrane-embedded c-subunit ring that constitutes the mitochondrial permeability transcription pore, hinders edelfosine-induced cell death. Taking together, the evidence shown here suggests that the ether lipid edelfosine could modulate cell death in cancer cells by direct interaction with mitochondria, and the reorganization of raft-located mitochondrial proteins that critically modulate cell death or survival. Here, we summarize and discuss the involvement of mitochondria in the antitumor action of the ether lipid edelfosine, pointing out the mitochondrial targeting of this drug as a major therapeutic approach, which can be extrapolated to other alkylphospholipid analogs. We also discuss the involvement of cholesterol transport and cholesterol-rich lipid rafts in the interactions between the organelles as well as in the role of mitochondria in the regulation of apoptosis in cancer cells and cancer therapy.

The yeast protein Ubx4p contributes to mitochondrial respiration and lithium-galactose-mediated activation of the unfolded protein response

In the presence of galactose, lithium ions activate the unfolded protein response (UPR) by inhibiting phosphoglucomutase activity and causing the accumulation of galactose-related metabolites, including galactose-1-phosphate. These metabolites also accumulate in humans who have the disease classic galactosemia. Here, we demonstrate that Saccharomyces cerevisiae yeast strains harboring a deletion of UBX4, a gene encoding a partner of Cdc48p in the endoplasmic reticulum-associated degradation (ERAD) pathway, exhibit delayed UPR activation after lithium and galactose exposure because the deletion decreases galactose-1-phosphate levels. The delay in UPR activation did not occur in yeast strains in which key ERAD or proteasomal pathway genes had been disrupted, indicating that the ubx4Δ phenotype is ERAD-independent. We also observed that the ubx4Δ strain displays decreased oxygen consumption. The inhibition of mitochondrial respiration was sufficient to diminish galactose-1-phosphate levels and, consequently, affects UPR activation. Finally, we show that the deletion of the AMP-activated protein kinase ortholog-encoding gene SNF1 can restore the oxygen consumption rate in ubx4Δ strain, thereby reestablishing galactose metabolism, UPR activation, and cellular adaption to lithium-galactose challenge. Our results indicate a role for Ubx4p in yeast mitochondrial function and highlight that mitochondrial and endoplasmic reticulum functions are intertwined through galactose metabolism. These findings also shed new light on the mechanisms of lithium action and on the pathophysiology of galactosemia.

Ecm33 is a novel factor involved in efficient glucose uptake for nutrition-responsive TORC1 signaling in yeast

Glucose uptake is crucial for providing both an energy source and a signal that regulates cell proliferation. Therefore, it is important to clarify the mechanisms underlying glucose uptake and its transmission to intracellular signaling pathways. In this study, we searched for a novel regulatory factor involved in glucose-induced signaling by using Saccharomyces cerevisiae as a eukaryotic model. Requirement of the extracellular protein Ecm33 in efficient glucose uptake and full activation of the nutrient-responsive TOR kinase complex 1 (TORC1) signaling pathway is shown. Cells lacking Ecm33 elicit a series of starvation-induced pathways even in the presence of extracellular high glucose concentration. This results in delayed cell proliferation, reduced ATP, induction of autophagy, and dephosphorylation of the TORC1 substrates Atg13 and Sch9.

Mitochondria and lipid raft-located FOF1-ATP synthase as major therapeutic targets in the antileishmanial and anticancer activities of ether lipid edelfosine

Background

Leishmaniasis is the world’s second deadliest parasitic disease after malaria, and current treatment of the different forms of this disease is far from satisfactory. Alkylphospholipid analogs (APLs) are a family of anticancer drugs that show antileishmanial activity, including the first oral drug (miltefosine) for leishmaniasis and drugs in preclinical/clinical oncology trials, but their precise mechanism of action remains to be elucidated.

Methodology/Principal findings

Here we show that the tumor cell apoptosis-inducer edelfosine was the most effective APL, as compared to miltefosine, perifosine and erucylphosphocholine, in killing Leishmania spp. promastigotes and amastigotes as well as tumor cells, as assessed by DNA breakdown determined by flow cytometry. In studies using animal models, we found that orally-administered edelfosine showed a potent in vivo antileishmanial activity and diminished macrophage pro-inflammatory responses. Edelfosine was also able to kill Leishmania axenic amastigotes. Edelfosine was taken up by host macrophages and killed intracellular Leishmania amastigotes in infected macrophages. Edelfosine accumulated in tumor cell mitochondria and Leishmania kinetoplast-mitochondrion, and led to mitochondrial transmembrane potential disruption, and to the successive breakdown of parasite mitochondrial and nuclear DNA. Ectopic expression of Bcl-X_L inhibited edelfosine-induced cell death in both Leishmania parasites and tumor cells. We found that the cytotoxic activity of edelfosine against Leishmania parasites and tumor cells was associated with a dramatic recruitment of F_OF₁-ATP synthase into lipid rafts following edelfosine treatment in both parasites and cancer cells. Raft disruption and specific F_OF₁-ATP synthase inhibition hindered edelfosine-induced cell death in both Leishmania parasites and tumor cells. Genetic deletion of F_OF₁-ATP synthase led to edelfosine drug resistance in Saccharomyces cerevisiae yeast.

Conclusions/Significance

The present study shows that the antileishmanial and anticancer actions of edelfosine share some common signaling processes, with mitochondria and raft-located F_OF₁-ATP synthase being critical in the killing process, thus identifying novel druggable targets for the treatment of leishmaniasis.

Leishmaniasis is a major health problem worldwide, and can result in loss of human life or a lifelong stigma because of bodily scars. According to World Health Organization, leishmaniasis is considered as an emerging and uncontrolled disease, and its current treatment is far from ideal, with only a few drugs available that could lead to drug resistance or cause serious side-effects. Here, we have found that mitochondria and raft-located F_OF₁-ATPase synthase are efficient druggable targets, through which an ether lipid named edelfosine exerts its antileishmanial action. Edelfosine effectively kills Leishmania spp. promastigotes and amastigotes. Our experimental animal models demonstrate that oral administration of edelfosine exerts a potent antileishmanial activity, while inhibits macrophage pro-inflammatory responses. Our results show that both Leishmania and tumor cells share mitochondria and raft-located F_OF₁-ATPase synthase as major druggable targets in leishmaniasis and cancer therapy. These data, showing a potent antileishmanial activity of edelfosine and unveiling its mechanism of action, together with the inhibition of the inflammatory responses elicited by macrophages, suggest that the ether lipid edelfosine is a promising oral drug for leishmaniasis, and highlight mitochondria and lipid raft-located F_OF₁-ATP synthase as major therapeutic targets for the treatment of this disease.

Testis-specific ATP synthase peripheral stalk subunits required for tissue-specific mitochondrial morphogenesis in Drosophila

Background

In Drosophila early post-meiotic spermatids, mitochondria undergo dramatic shaping into the Nebenkern, a spherical body with complex internal structure that contains two interwrapped giant mitochondrial derivatives. The purpose of this study was to elucidate genetic and molecular mechanisms underlying the shaping of this structure.

Results

The knotted onions (knon) gene encodes an unconventionally large testis-specific paralog of ATP synthase subunit d and is required for internal structure of the Nebenkern as well as its subsequent disassembly and elongation. Knon localizes to spermatid mitochondria and, when exogenously expressed in flight muscle, alters the ratio of ATP synthase complex dimers to monomers. By RNAi knockdown we uncovered mitochondrial shaping roles for other testis-expressed ATP synthase subunits.

Conclusions

We demonstrate the first known instance of a tissue-specific ATP synthase subunit affecting tissue-specific mitochondrial morphogenesis. Since ATP synthase dimerization is known to affect the degree of inner mitochondrial membrane curvature in other systems, the effect of Knon and other testis-specific paralogs of ATP synthase subunits may be to mediate differential membrane curvature within the Nebenkern.

Mitochondrial Efficiency-Dependent Viability of Saccharomyces cerevisiae Mutants Carrying Individual Electron Transport Chain Component Deletions

Mitochondria play a crucial role in eukaryotic cells; the mitochondrial electron transport chain (ETC) generates adenosine triphosphate (ATP), which serves as an energy source for numerous critical cellular activities. However, the ETC also generates deleterious reactive oxygen species (ROS) as a natural byproduct of oxidative phosphorylation. ROS are considered the major cause of aging because they damage proteins, lipids, and DNA by oxidation. We analyzed the chronological life span, growth phenotype, mitochondrial membrane potential (MMP), and intracellular ATP and mitochondrial superoxide levels of 33 single ETC component-deleted strains during the chronological aging process. Among the ETC mutant strains, 14 (sdh1Δ, sdh2Δ, sdh4Δ, cor1Δ, cyt1Δ, qcr7Δ, qcr8Δ, rip1Δ, cox6Δ, cox7Δ, cox9Δ, atp4Δ, atp7Δ, and atp17Δ) showed a significantly shorter life span. The deleted genes encode important elements of the ETC components succinate dehydrogenase (complex II) and cytochrome c oxidase (complex IV), and some of the deletions lead to structural instability of the membrane-F1F0-ATP synthase due to mutations in the stator stalk (complex V). These short-lived strains generated higher superoxide levels and produced lower ATP levels without alteration of MMP. In summary, ETC mutations decreased the life span of yeast due to impaired mitochondrial efficiency.

ATPaseTb2, a unique membrane-bound FoF1-ATPase component, is essential in bloodstream and dyskinetoplastic trypanosomes

In the infectious stage of Trypanosoma brucei, an important parasite of humans and livestock, the mitochondrial (mt) membrane potential (Δψm) is uniquely maintained by the ATP hydrolytic activity and subsequent proton pumping of the essential FoF1-ATPase. Intriguingly, this multiprotein complex contains several trypanosome-specific subunits of unknown function. Here, we demonstrate that one of the largest novel subunits, ATPaseTb2, is membrane-bound and localizes with monomeric and multimeric assemblies of the FoF1-ATPase. Moreover, RNAi silencing of ATPaseTb2 quickly leads to a significant decrease of the Δψm that manifests as a decreased growth phenotype, indicating that the FoF1-ATPase is impaired. To further explore the function of this protein, we employed a trypanosoma strain that lacks mtDNA (dyskinetoplastic, Dk) and thus subunit a, an essential component of the proton pore in the membrane Fo-moiety. These Dk cells generate the Δψm by combining the hydrolytic activity of the matrix-facing F1-ATPase and the electrogenic exchange of ATP4- for ADP3- by the ATP/ADP carrier (AAC). Surprisingly, in addition to the expected presence of F1-ATPase, the monomeric and multimeric FoF1-ATPase complexes were identified. In fact, the immunoprecipitation of a F1-ATPase subunit demonstrated that ATPaseTb2 was a component of these complexes. Furthermore, RNAi studies established that the membrane-bound ATPaseTb2 subunit is essential for maintaining normal growth and the Δψm of Dk cells. Thus, even in the absence of subunit a, a portion of the FoF1-ATPase is assembled in Dk cells.

Identification of novel oxidized protein substrates and physiological partners of the mitochondrial ATP-dependent Lon-like protease Pim1

ATP-dependent proteases are currently emerging as key regulators of mitochondrial functions. Among these proteolytic systems, Pim1, a Lon-like serine protease in Saccharomyces cerevisiae, is involved in the control of selective protein turnover in the mitochondrial matrix. In the absence of Pim1, yeast cells have been shown to accumulate electron-dense inclusion bodies in the matrix space, to lose integrity of mitochondrial genome, and to be respiration-deficient. Because of the severity of phenotypes associated with the depletion of Pim1, this protease appears to be an essential component of the protein quality control machinery in mitochondria and to exert crucial functions during the biogenesis of this organelle. Nevertheless, its physiological substrates and partners are not fully characterized. Therefore, we used the combination of different proteomic techniques to assess the nature of oxidized protein substrates and physiological partners of Pim1 protease under non-repressing growth conditions. The results presented here supply evidence that Pim1-mediated proteolysis is required for elimination of oxidatively damaged proteins in mitochondria.

The F(0)F(1)-ATP synthase complex contains novel subunits and is essential for procyclic Trypanosoma brucei

The mitochondrial F₀F₁ ATP synthase is an essential multi-subunit protein complex in the vast majority of eukaryotes but little is known about its composition and role in Trypanosoma brucei, an early diverged eukaryotic pathogen. We purified the F₀F₁ ATP synthase by a combination of affinity purification, immunoprecipitation and blue-native gel electrophoresis and characterized its composition and function. We identified 22 proteins of which five are related to F₁ subunits, three to F₀ subunits, and 14 which have no obvious homology to proteins outside the kinetoplastids. RNAi silencing of expression of the F₁ α subunit or either of the two novel proteins showed that they are each essential for the viability of procyclic (insect stage) cells and are important for the structural integrity of the F₀F₁-ATP synthase complex. We also observed a dramatic decrease in ATP production by oxidative phosphorylation after silencing expression of each of these proteins while substrate phosphorylation was not severely affected. Our procyclic T. brucei cells were sensitive to the ATP synthase inhibitor oligomycin even in the presence of glucose contrary to earlier reports. Hence, the two novel proteins appear essential for the structural organization of the functional complex and regulation of mitochondrial energy generation in these organisms is more complicated than previously thought.

African trypanosomes (Trypanosoma brucei and related subspecies) are unicellular parasites that cause the devastating disease of African sleeping sickness in man and nagana in livestock. Both of these diseases are lethal, killing thousands of people each year and causing major economical complications in the developing world, thus affecting the lives of millions. Furthermore, available drugs are obsolete, difficult to administer and have many undesirable side-effects. Therefore, there is a reinvigorated effort to design new drugs against these parasites. From the pharmacological perspective, unique metabolic processes and protein complexes with singular structure, composition and essential function are of particular interest. One such remarkable protein complex is the mitochondrial F₀F₁-ATP synthase/ATPase. Here we show that F₀F₁-ATP synthase complex is essential for viability of procyclic T. brucei cells and it possesses unique and novel subunits. The three F₀F₁-ATP synthase subunits that were tested were shown to be crucial for the structural integrity of the F₀F₁-ATP synthase complex and its activities. The compositional and functional characterization of the F₀F₁-ATP synthase in T. brucei represents a major step towards deciphering the unique and essential properties of the respiratory chain of both an early diverged eukaryote and a lethal human parasite.

Assembly of F0 in Saccharomyces cerevisiae

Respiratory deficient mutants of Saccharomyces cerevisiae have been instrumental in identifying an increasing number of nuclear gene products that promote pre- and post-translational steps of the pathway responsible for biogenesis of the mitochondrial ATP synthase. In this article we have attempted to marshal current information about the functions of such accessory factors and the roles they play in expression and assembly of the mitochondrially encoded subunits of the ATP synthase. We also discuss evidence that the ATP synthase may be built up from three separate modules corresponding to the F1 ATPase, the stator and F0.

The structure and function of mitochondrial F1F0-ATP synthases

We review recent advances in understanding of the structure of the F(1)F(0)-ATP synthase of the mitochondrial inner membrane (mtATPase). A significant achievement has been the determination of the structure of the principal peripheral or stator stalk components bringing us closer to achieving the Holy Grail of a complete 3D structure for the complex. A major focus of the field in recent years has been to understand the physiological significance of dimers or other oligomer forms of mtATPase recoverable from membranes and their relationship to the structure of the cristae of the inner mitochondrial membrane. In addition, the association of mtATPase with other membrane proteins has been described and suggests that further levels of functional organization need to be considered. Many reports in recent years have concerned the location and function of ATP synthase complexes or its component subunits on the external surface of the plasma membrane. We consider whether the evidence supports complete complexes being located on the cell surface, the biogenesis of such complexes, and aspects of function especially related to the structure of mtATPase.

Mitochondrial diseases and genetic defects of ATP synthase

ATP synthase is a key enzyme of mitochondrial energy conversion. In mammals, it produces most of cellular ATP. Alteration of ATP synthase biogenesis may cause two types of isolated defects: qualitative when the enzyme is structurally modified and does not function properly, and quantitative when it is present in insufficient amounts. In both cases the cellular energy provision is impaired, and diminished use of mitochondrial DeltamuH+ promotes ROS production by the mitochondrial respiratory chain. The primary genetic defects have so far been localized in mtDNA ATP6 gene and nuclear ATP12 gene, however, involvement of other nuclear genes is highly probable.

Caenorhabditis elegans MAI-1 protein, which is similar to mitochondrial ATPase inhibitor (IF1), can inhibit yeast F0F1-ATPase but cannot be transported to yeast mitochondria

In Caenorhabditis elegans, two proteins that are similar to mitochondrial ATPase inhibitor protein (IF(1)) have been found and named MAI-1 and MAI-2. In this study, we overexpressed and purified both the proteins and examined their properties. Circular dichroism spectra indicated that both the MAI-1 and MAI-2 predominantly consisted of beta- and random structure, and in contrast to mammalian IF(1), alpha-helixes were barely detected. Both MAI-1 and MAI-2 could inhibit yeast F(0)F(1)-ATPase, but the inhibition by MAI-1 was pH-independent. MAI-2-GFP fusion protein was transported to yeast mitochondria, but MAI-1-GFP was not. These results indicate that the MAI-2 is (C. elegans) IF(1). MAI-1 seems to be a cytosolic protein and may regulate cytosolic ATPase(s).

Gene expression profiling and phenotype analyses ofS. cerevisiaein response to changing copper reveals six genes with new roles in copper and iron metabolism

Exhaustive microarray time course analyses of Saccharomyces cerevisiae during copper starvation and copper excess reveal new aspects of metal-induced gene regulation. Aside from identifying targets of established copper- and iron-responsive transcription factors, we find that genes encoding mitochondrial proteins are downregulated and that copper-independent iron transport genes are preferentially upregulated, both during prolonged copper deprivation. The experiments also suggest the presence of a small regulatory iron pool that links copper and iron responses. One hundred twenty-eight genes with putative roles in metal metabolism were further investigated by several systematic phenotype screens. Of the novel phenotypes uncovered, hsp12-Δ and arn1-Δ display increased sensitivity to copper, cyc1-Δ and crr1-Δ show resistance to high copper, vma13-Δ exhibits increased sensitivity to iron deprivation, and pep12-Δ results in reduced growth in high copper and low iron. Besides revealing new components of eukaryotic metal trafficking pathways, the results underscore the previously determined intimate links between iron and copper metabolism and mitochondrial and vacuolar function in metal trafficking. The analyses further suggest that copper starvation can specifically lead to downregulation of respiratory function to preserve iron and copper for other cellular processes.

The molecular neighborhood of subunit 8 of yeast mitochondrial F1F0-ATP synthase probed by cysteine scanning mutagenesis and chemical modification

The detailed membrane topography and neighboring polypeptides of subunit 8 in yeast mitochondrial ATP synthase have been determined using a combination of cysteine scanning mutagenesis and chemical modification. 46 single cysteine substitution mutants encompassing the length of the subunit 8 protein were constructed by site-directed mutagenesis. Expression of each cysteine variant in yeast lacking endogenous subunit 8 restored respiratory phenotype to cells and had little measurable effect on ATP hydrolase function. The exposure of each introduced cysteine residue to the aqueous environment was assessed in isolated mitochondria using the fluorescent thiol-modifying probe fluorescein 5-maleimide. The first 14 and last 13 amino acids of subunit 8 were accessible to fluorescein 5-maleimide in osmotically lysed mitochondria and are thus extrinsic to the lipid bilayer, indicating a 21-amino acid transmembrane span. The C-terminal region of subunit 8 was partially occluded by other ATP synthase subunits, especially in a small region surrounding Val-40 that was demonstrated to play an important role in maintaining the stability of the F(1)-F(0) interaction. Cross-linking using heterobifunctional reagents revealed the proximity of subunit 8 to subunits b, d, and f in the matrix and to subunits b, f, and 6 in the intermembrane space. A disulfide bridge was also formed between subunit 8(F7C) or (M10C) and residue Cys-23 of subunit 6, demonstrating a close interaction between these two hydrophobic membrane subunits and confirming the location of the N termini of each in the intermembrane space. We conclude that subunit 8 is an integral component of the stator stalk of yeast mitochondrial F(1)F(0)-ATP synthase.

Genetic and biochemical basis for viability of yeast lacking mitochondrial genomes

Yme1p, an ATP-dependent protease localized in the mitochondrial inner membrane, is required for the growth of yeast lacking an intact mitochondrial genome. Specific dominant mutations in the genes encoding the alpha- and gamma-subunits of the mitochondrial F(1)F(0)-ATPase suppress the slow-growth phenotype of yeast that simultaneously lack Yme1p and mitochondrial DNA. F(1)F(0)-ATPase activity is reduced in yeast lacking Yme1p and is restored in yme1 strains bearing suppressing mutations in F(1)-ATPase structural genes. Mitochondria isolated from yme1 yeast generated a membrane potential upon the addition of succinate, but unlike mitochondria isolated either from wild-type yeast or from yeast bearing yme1 and a suppressing mutation, were unable to generate a membrane potential upon the addition of ATP. Nuclear-encoded F(0) subunits accumulate in yme1 yeast lacking mitochondrial DNA; however, deletion of genes encoding those subunits did not suppress the requirement of yme1 yeast for intact mitochondrial DNA. In contrast, deletion of INH1, which encodes an inhibitor of the F(1)F(0)-ATPase, partially suppressed the growth defect of yme1 yeast lacking mitochondrial DNA. We conclude that Yme1p is in part responsible for assuring sufficient F(1)F(0)-ATPase activity to generate a membrane potential in mitochondria lacking mitochondrial DNA and propose that Yme1p accomplishes this by catalyzing the turnover of protein inhibitors of the F(1)F(0)-ATPase.

Dual mutations reveal interactions between components of oxidative phosphorylation in Kluyveromyces lactis

Loss of mtDNA or mitochondrial protein synthesis cannot be tolerated by wild-type Kluyveromyces lactis. The mitochondrial function responsible for rho(0)-lethality has been identified by disruption of nuclear genes encoding electron transport and F(0)-ATP synthase components of oxidative phosphorylation. Sporulation of diploid strains heterozygous for disruptions in genes for the two components of oxidative phosphorylation results in the formation of nonviable spores inferred to contain both disruptions. Lethality of spores is thought to result from absence of a transmembrane potential, Delta Psi, across the mitochondrial inner membrane due to lack of proton pumping by the electron transport chain or reversal of F(1)F(0)-ATP synthase. Synergistic lethality, caused by disruption of nuclear genes, or rho(0)-lethality can be suppressed by the atp2.1 mutation in the beta-subunit of F(1)-ATPase. Suppression is viewed as occurring by an increased hydrolysis of ATP by mutant F(1), allowing sufficient electrogenic exchange by the translocase of ADP in the matrix for ATP in the cytosol to maintain Delta Psi. In addition, lethality of haploid strains with a disruption of AAC encoding the ADP/ATP translocase can be suppressed by atp2.1. In this case suppression is considered to occur by mutant F(1) acting in the forward direction to partially uncouple ATP production, thereby stimulating respiration and relieving detrimental hyperpolarization of the inner membrane. Participation of the ADP/ATP translocase in suppression of rho(0)-lethality is supported by the observation that disruption of AAC abolishes suppressor activity of atp2.1.

Topology and proximity relationships of yeast mitochondrial ATP synthase subunit 8 determined by unique introduced cysteine residues

We have used site-directed chemical labelling to demonstrate the membrane topology and to identify neighbouring subunits of subunit 8 (Y8) in yeast mitochondrial ATP synthase (mtATPase). Unique cysteine residues were introduced at the N or C-terminus of Y8 by site-directed mutagenesis. Expression and targeting to mitochondria in vivo of each of these variants in a yeast Y8 null mutant was able to restore activity to an otherwise nonfunctional ATP synthase complex. The position of each introduced cysteine relative to the inner mitochondrial membrane was probed with thiol-specific nonpermeant and permeant reagents in both intact and lysed mitochondria. The data indicate that the N-terminus of Y8 is located in the intermembrane space of mitochondria whereas the C-terminus is located within the mitochondrial matrix. The proximity of Y8 to other proteins of mtATPase was tested using heterobifunctional cross-linking reagents, each with one thiol-specific reactive group and one nonspecific, photoactivatible reactive group. These experiments revealed the proximity of the C-terminal domain of Y8 to subunits d and f, and that of the N-terminal domain to subunit f. It is concluded that Y8 possesses a single transmembrane domain which extends across the inner membrane of intact mitochondria. As subunit d is a likely component of the stator stalk of mitochondrial ATP synthase, we propose, on the basis of the observed cross-links, that Y8 may also be part of the stator stalk.

A single amino acid change in subunit 6 of the yeast mitochondrial ATPase suppresses a null mutation in ATP10

In an earlier study, the ATP10 gene of Saccharomyces cerevisiae was shown to code for an inner membrane protein required for assembly of the F(0) sector of the mitochondrial ATPase complex (Ackerman, S., and Tzagoloff, A. (1990) J. Biol. Chem. 265, 9952-9959). To gain additional insights into the function of Atp10p, we have analyzed a revertant of an atp10 null mutant that displays partial recovery of oligomycin-sensitive ATPase and of respiratory competence. The suppressor mutation in the revertant has been mapped to the OLI2 locus in mitochondrial DNA and shown to be a single base change in the C-terminal coding region of the gene. The mutation results in the substitution of a valine for an alanine at residue 249 of subunit 6 of the ATPase. The ability of the subunit 6 mutation to compensate for the absence of Atp10p implies a functional interaction between the two proteins. Such an interaction is consistent with evidence indicating that the C-terminal region with the site of the mutation and the extramembrane domain of Atp10p are both on the matrix side of the inner membrane. Subunit 6 has been purified from the parental wild type strain, from the atp10 null mutant, and from the revertant. The N-terminal sequences of the three proteins indicated that they all start at Ser(11), the normal processing site of the subunit 6 precursor. Mass spectral analysis of the wild type and mutants subunit 6 failed to reveal any substantive difference of the wild type and mutant proteins when the mass of the latter was corrected for Ala --> Val mutation. These data argue against a role of Atp10p in post-translational modification of subunit 6. Although post-translational modification of another ATPase subunit interacting with subunit 6 cannot be excluded, a more likely function for Atp10p is that it acts as a subunit 6 chaperone during F(0) assembly.

Maintenance and integrity of the mitochondrial genome: a plethora of nuclear genes in the budding yeast

Instability of the mitochondrial genome (mtDNA) is a general problem from yeasts to humans. However, its genetic control is not well documented except in the yeast Saccharomyces cerevisiae. From the discovery, 50 years ago, of the petite mutants by Ephrussi and his coworkers, it has been shown that more than 100 nuclear genes directly or indirectly influence the fate of the rho(+) mtDNA. It is not surprising that mutations in genes involved in mtDNA metabolism (replication, repair, and recombination) can cause a complete loss of mtDNA (rho(0) petites) and/or lead to truncated forms (rho(-)) of this genome. However, most loss-of-function mutations which increase yeast mtDNA instability act indirectly: they lie in genes controlling functions as diverse as mitochondrial translation, ATP synthase, iron homeostasis, fatty acid metabolism, mitochondrial morphology, and so on. In a few cases it has been shown that gene overexpression increases the levels of petite mutants. Mutations in other genes are lethal in the absence of a functional mtDNA and thus convert this petite-positive yeast into a petite-negative form: petite cells cannot be recovered in these genetic contexts. Most of the data are explained if one assumes that the maintenance of the rho(+) genome depends on a centromere-like structure dispensable for the maintenance of rho(-) mtDNA and/or the function of mitochondrially encoded ATP synthase subunits, especially ATP6. In fact, the real challenge for the next 50 years will be to assemble the pieces of this puzzle by using yeast and to use complementary models, especially in strict aerobes.

Insights into ATP synthase assembly and function through the molecular genetic manipulation of subunits of the yeast mitochondrial enzyme complex

Development of an increasingly detailed understanding of the eucaryotic mitochondrial ATP synthase requires a detailed knowledge of the stoichiometry, structure and function of F(0) sector subunits in the contexts of the proton channel and the stator stalk. Still to be resolved are the precise locations and roles of other supernumerary subunits present in mitochondrial ATP synthase complexes, but not found in the bacterial or chloroplast enzymes. The highly developed system of molecular genetic manipulation available in the yeast Saccharomyces cerevisiae, a unicellular eucaryote, permits testing for gene function based on the effects of gene disruption or deletion. In addition, the genes encoding ATP synthase subunits can be manipulated to introduce specific amino acids at desired positions within a subunit, or to add epitope or affinity tags at the C-terminus, enabling questions of stoichiometry, structure and function to be addressed. Newly emerging technologies, such as fusions of subunits with GFP are being applied to probe the dynamic interactions within mitochondrial ATP synthase, between ATP synthase complexes, and between ATP synthase and other mitochondrial enzyme complexes.

Mutant residues suppressing rho(0)-lethality in Kluyveromyces lactis occur at contact sites between subunits of F(1)-ATPase

Characterisation of 35 Kluyveromyces lactis strains lacking mitochondrial DNA has shown that mutations suppressing rho(0)-lethality are limited to the ATP1, 2 and 3 genes coding for the alpha-, beta- and gamma- subunits of mitochondrial F(1)-ATPase. All atp mutations reduce growth on glucose and three alleles, atp1-2, 1-3 and atp3-1, produce a respiratory deficient phenotype that indicates a drop in efficiency of the F(1)F(0)-ATP synthase complex. ATPase activity is needed for suppression as a double mutant containing an atp allele, together with a mutation abolishing catalytic activity, does not suppress rho(0)-lethality. Positioning of the seven amino acids subject to mutation on the bovine F(1)-ATPase structure shows that two residues are found in a membrane proximal region while five amino acids occur at a region suggested to be a molecular bearing. The intriguing juxtaposition of mutable amino acids to other residues subject to change suggests that mutations affect subunit interactions and alter the properties of F(1) in a manner yet to be determined. An explanation for suppressor activity of atp mutations is discussed in the context of a possible role for F(1)-ATPase in the maintenance of mitochondrial inner membrane potential.

The petite mutation in yeasts: 50 years on

Fifty years ago it was reported that baker's yeast, Saccharomyces cerevisiae, can form "petite colonie" mutants when treated with the DNA-targeting drug acriflavin. To mark the jubilee of studies on cytoplasmic inheritance, a review of the early work will be presented together with some observations on current developments. The primary emphasis is to address the questions of how loss of mtDNA leads to lethality (rho 0-lethality) in petite-negative yeasts and how S. cerevisiae tolerates elimination of mtDNA. Recent investigation have revealed that rho 0-lethality can be suppressed by specific mutations in the alpha, beta, and gamma subunits of the mitochondrial F1-ATPase of the petite-negative yeast Kluyveromyces lactis and by the nuclear ptp alleles in Schizosaccharomyces pombe. In contrast, inactivation of genes coding for F1-ATPase alpha and beta subunits and disruption of AAC2, PGS1/PEL1, and YME1 genes in S. cerevisiae convert this petite-positive yeast into a petite-negative form. Studies on nuclear genes affecting dependence on mtDNA have provided important insight into the functions provided by the mitochondrial genome and the maintenance of structural and functional integrity of the mitochondrial inner membrane.

Structure/function of the beta-barrel domain of F1-ATPase in the yeast Saccharomyces cerevisiae

The first 90 amino acids of the alpha- and beta-subunits of mitochondrial F1-ATPase are folded into beta-barrel domains and were postulated to be important for stabilizing the enzyme (Abrahams, J. P., Leslie, A. G., Lutter, R., and Walker, J. E. (1994) Nature 370, 621-628). The role of the domains was studied by making chimeric enzymes, replacing the domains from the yeast Saccharomyces cerevisiae enzyme with the corresponding domains from the enzyme of the thermophilic bacterium Bacillus PS3. The enzymes containing the chimeric alpha-, beta-, or alpha- and beta-subunits were not functional. However, gain-of-function mutations were obtained from the strain containing the enzyme with the chimeric PS3/yeast beta-subunit. The gain-of-function mutations were all in codons encoding the beta-barrel domain of the beta-subunit, and the residues appear to map out a region of subunit-subunit interactions. Gain-of-function mutations were also obtained that provided functional expression of the chimeric PS3/yeast alpha- and beta-subunits together. Biochemical analysis of this active chimeric enzyme indicated that it was not significantly more thermostable or labile than the wild type. The results of this study indicate that the beta-barrel domains form critical contacts (distinct from those between the alpha- and beta-subunits) that are important for the assembly of the ATP synthase.

Quantitation and origin of the mitochondrial membrane potential in human cells lacking mitochondrial DNA

Mammalian mitochondrial DNA (mtDNA) encodes 13 polypeptide components of oxidative phosphorylation complexes. Consequently, cells that lack mtDNA (termed rho degrees cells) cannot maintain a membrane potential by proton pumping. However, most mitochondrial proteins are encoded by nuclear DNA and are still imported into mitochondria in rho degrees cells by a mechanism that requires a membrane potential. This membrane potential is thought to arise from the electrogenic exchange of ATP4- for ADP3- by the adenine nucleotide carrier. An intramitochondrial ATPase, probably an incomplete FoF1-ATP synthase lacking the two subunits encoded by mtDNA, is also essential to ensure sufficient charge flux to maintain the potential. However, there are considerable uncertainties about the magnitude of this membrane potential, the nature of the intramitochondrial ATPase and the ATP flux required to maintain the potential. Here we have investigated these factors in intact and digitonin-permeabilized mammalian rho degrees cells. The adenine nucleotide carrier and ATP were essential, but not sufficient to generate a membrane potential in rho degrees cells and an incomplete FoF1-ATP synthase was also required. The maximum value of this potential was approximately 110 mV in permeabilized cells and approximately 67 mV in intact cells. The membrane potential was eliminated by inhibitors of the adenine nucleotide carrier and by azide, an inhibitor of the incomplete FoF1-ATP synthase, but not by oligomycin. This potential is sufficient to import nuclear-encoded proteins but approximately 65 mV lower than that in 143B cells containing fully functional mitochondria. Subfractionation of rho degrees mitochondria showed that the azide-sensitive ATPase activity was membrane associated. Further analysis by blue native polyacrylamide gel electrophoresis (BN/PAGE) followed by activity staining or immunoblotting, showed that this ATPase activity was an incomplete FoF1-ATPase loosely associated with the membrane. Maintenance of this membrane potential consumed about 13% of the ATP produced by glycolysis. This work has clarified the role of the adenine nucleotide carrier and an incomplete FoF1-ATP synthase in maintaining the mitochondrial membrane potential in rho degrees cells.

Bioenergetic and structural consequences of allotopic expression of subunit 8 of yeast mitochondrial ATP synthase. The hydrophobic character of residues 23 and 24 is essential for maximal activity and structural stability of the enzyme complex

Subunit 8 (Y8), a mitochondrially encoded subunit of the F0 sector of the F1F0-ATP synthase is essential for oxidative phosphorylation. We have previously introduced the technique of allotopic expression to study the structure/function of Y8, whereby an artificial Y8 gene is expressed in the nucleus of cells lacking a functional mitochondrial Y8, thus generating assembly of a functional F1F0-ATPase complex. In this paper we show that when a gene encoding an essentially unmodified version of Y8 is allotopically expressed, ATP synthesis and hydrolysis rates, as well as efficiency of oxidative phosphorylation, were similar to those of the parental wild-type strain in which Y8 is naturally expressed in mitochondria. We then tested the requirement for the hydrophobicity of the central domain (residues 14-32), which possibly represents a transmembrane stem, by introducing adjacent negative charges at different positions of Y8. One of the variants thus generated, which carries the double substitution Leu23-->Asp, Leu24-->Asp, when expressed in a strain lacking endogenous Y8, gave rise to cells which grew very slowly by oxidative phosphorylation. Measurement of bioenergetic parameters showed two major defects in these cells relative to control cells allotopically expressing unmodified Y8. First, the activity of the F1F0-ATP synthase was significantly decreased. ATP synthesis and state 3 of respiration were reduced by approximately 30-40%. ATP hydrolysis was reduced by approximately 30% and was almost insensitive to the F0 inhibitor oligomycin. Second, the physical coupling between the two sectors of the enzyme, as well as the stability of the F1 sector itself, were affected as shown by decreased recovery of F0 sector [8, 9, b, oligomycin sensitivity-conferring protein (OSCP), d, h and f] and F1 sector (alpha, gamma, delta) subunits in immunoprecipitates of ATP synthase. This study indicates that Y8 not only performs an important role in the structure of the mitochondrial complex but also in its activity. We conclude that the hydrophobic character of amino acids 23 and 24 in the middle of the putative transmembrane stem of Y8 is essential for coupling proton transport through F0 to ATP synthesis on F1.

Single copies of subunits d, oligomycin-sensitivity conferring protein, and b are present in the Saccharomyces cerevisiae mitochondrial ATP synthase

In the mitochondrial ATP synthase (mtATPase) of the yeast Saccharomyces cerevisiae, the stoichiometry of subunits d, oligomycin-sensitivity conferring protein (OSCP), and b is poorly defined. We have investigated the stoichiometry of these subunits by the application of hexahistidine affinity purification technology. We have previously demonstrated that intact mtATPase complexes incorporating a Hex6-tagged subunit can be isolated via Ni2+-nitrilotriacetic acid affinity chromatography (Bateson, M., Devenish, R. J., Nagley, P., and Prescott, M. (1996) Anal. Biochem. 238, 14-18). Strains were constructed in which Hex6-tagged versions of subunits d, OSCP, and b were coexpressed with the corresponding wild-type subunit. This coexpression resulted in a mixed population of mtATPase complexes containing untagged wild-type and Hex6-tagged subunits. The stoichiometry of each subunit was then assessed by determining whether or not the untagged wild-type subunit could be recovered from Ni2+-nitrilotriacetic acid purifications as an integral component of those complexes absorbed by virtue of the Hex6-tagged subunit. As only the Hex6-tagged subunit was recovered from such purifications, we demonstrate that the stoichiometry of subunits d, OSCP, and b in yeast is 1 in each case.

ATP synthase of yeast mitochondria. Isolation of subunit j and disruption of the ATP18 gene

The subunit composition of the mitochondrial ATP synthase from Saccharomyces cerevisiae was analyzed using blue native gel electrophoresis and high resolution SDS-polyacrylamide gel electrophoresis. We report here the identification of a novel subunit of molecular mass of 6,687 Da, termed subunit j (Su j). An open reading frame of 127 base pairs (ATP18), which encodes for Su j, was identified on chromosome XIII. Su j does not display sequence similarity to ATP synthase subunits from other organisms. Data base searches, however, identified a potential homolog from Schizosaccharomyces pombe with 51% identity to Su j of S. cerevisiae. Su j, a small protein of 59 amino acid residues, has the characteristics of an integral inner membrane protein with a single transmembrane segment. Deletion of the ATP18 gene encoding Su j led to a strain (Deltasu j) completely deficient in oligomycin-sensitive ATPase activity and unable to grow on nonfermentable carbon sources. The presence of Su j is required for the stable expression of subunits 6 and f of the F0 membrane sector. In the absence of Su j, spontaneously arising rho- cells were observed that lacked also ubiquinol-cytochrome c reductase and cytochrome c oxidase activities. We conclude that Su j is a novel and essential subunit of yeast ATP synthase.

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.

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.

Functional F1-ATPase essential in maintaining growth and membrane potential of human mitochondrial DNA-depleted rho degrees cells

F1-ATPase assembly has been studied in human rho degrees cells devoid of mitochondrial DNA (mtDNA). Since, in these cells, oxidative phosphorylation cannot provide ATP, their growth relies on glycolysis. Despite the absence of the mtDNA-coded F0 subunits 6 and 8, rho degrees cells possessed normal levels of F1-ATPase alpha and beta subunits. This F1-ATPase was functional and azide- or aurovertin-sensitive but oligomycin-insensitive. In addition, aurovertin decreased cell growth in rho degrees cells and also reduced their mitochondrial membrane potential, as measured by rhodamine 123 fluorescence. Therefore, a functional F1-ATPase was important to maintain the mitochondrial membrane potential and the growth of these rho degrees cells. Bongkrekic acid, a specific adenine nucleotide translocator (ANT) inhibitor, also reduced rho degrees cell growth and mitochondrial membrane potential. In conclusion, rho degrees cells need both a functional F1-ATPase and a functional ANT to maintain their mitochondrial membrane potential, which is necessary for their growth. ATP hydrolysis catalyzed by F1 must provide ADP3- at a sufficient rate to maintain a rapid exchange with the glycolytic ATP4- by ANT, this electrogenic exchange inducing a mitochondrial membrane potential efficient enough to sustain cell growth. However, since the effects of bongkrekic acid and of aurovertin were additive, other electrogenic pumps should cooperate with this pathway.

The assembly of yeast mitochondrial ATP synthase: subunit depletion in vivo suggests ordered assembly of the stalk subunits b, OSCP and d

The abundance in vivo of each of three subunits b, OSCP and d, components of the stalk region of the yeast mitochondrial ATP synthase complex, was manipulated by a controlled depletion strategy. Western blots of whole cell lysates were used to study the effect of depletion of each of these subunits on the cellular levels of other subunits of the enzyme complex. A hierarchy of subunit stability was determined and interpreted to indicate the order of assembly of these three subunits of the stalk region. Thus, subunit b is assembled first, followed by OSCP and then by subunit d.

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.

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.

ATP synthase of yeast mitochondria. Isolation of the F1 delta subunit, sequence and disruption of the structural gene

The delta-subunit was isolated from the purified yeast F1. Partial protein sequences were determined by direct methods. From this information, degenerated primers were constructed. A part of the ATP delta gene was amplified by polymerase chain reaction from yeast genomic DNA. From the amplified DNA sequence, a nondegenerated oligonucleotide probe was constructed to isolate a 2.6-kbp BamHI-EcoRI DNA fragment bearing the whole gene. A 1036-bp DraI fragment was sequenced. A 480-bp open reading frame encoding a 160-amino-acid polypeptide is described. The deduced amino acid sequence is 22 amino acids longer than the mature protein, which is 138 amino acids long with a mass of 14,555 Da. The delta-subunit of Saccharomyces cerevisiae is 21%, 35%, 52% identical and 66%, 61% and 92% similar to the epsilon-subunit of Escherichia coli and the delta-subunits of beef heart and Neurospora crassa, respectively. A null mutant was constructed. The mutation was recessive and dramatically affected mitochondrial DNA stability since the transformed cells were 100% cytoplasmic petite. The double mutant (rho-, ATP delta::URA3) displayed low or no ATPase activity with an unstable catalytic sector, since a polyclonal antibody directed against the beta subunit did not coprecipitate the alpha subunit.

The role of the stalk in the coupling mechanism of F1F0-ATPases

The extrinsic and intrinsic membrane sectors of F1F0-ATPases are linked by a slender stalk 40-50 A in length. The stalk transmits the energy produced by oxidative or photosynthetic phosphorylation from the intrinsic sector, F0, to the catalytic sites in the extrinsic F1 sector. How this is achieved is unknown, but long-range conformational changes linked to transmembrane proton transport may be involved. In bacterial and chloroplast F1F0-ATPases, the stalk is probably a composite of subunits delta and epsilon, part of the gamma-subunit, and the extrinsic membrane domains of 2 subunits (identical or non-identical according to the species) that are bound to the membrane by their N-terminal regions. The stalk in the bovine mitochondrial enzyme appears to be more complex, and the gamma, delta, epsilon, OSCP, F6, b and d subunits all contribute to it. A bovine stalk complex has been assembled in vitro from bacterially expressed OSCP, F6, b and d, both in the presence and in the absence of F1-ATPase. One molecule of each of these subunits is present in the assembled complex, as there is also in each native F1F0-ATPase assembly. Providing that suitable crystals can be obtained, the stalk complex and the F1.stalk complex may permit the high resolution structure of bovine F1-ATPase to be extended into the stalk domain.

Sequencing and analysis of 51.6 kilobases on the left arm of chromosome XI from Saccharomyces cerevisiae reveals 23 open reading frames including the FAS1 gene

We have sequenced two segments containing a total of 51.6 kb of the left arm from chromosome XI of Saccharomyces cerevisiae. The first segment of 38.5 kb contains 18 open reading frames (ORFs) of more than 100 amino acid residues. Five ORFs encode known yeast genes, including the fatty acid synthase gene (FAS1). Three new yeast genes were discovered with homologies to non-yeast genes and ten new genes without homologies to any known sequences. The second segment of 13 kb contains five ORFs with two known yeast genes and three unknown genes. The sequences from cosmid pUKG041 were obtained entirely with the walking primer strategy resulting in a very low overall sequence redundancy of 2.8 and an average reading length of 443 bases.

The C-terminal region of subunit 4 (subunit b) is essential for assembly of the F0 portion of yeast mitochondrial ATP synthase

The role of the C-terminal part of yeast ATP synthase subunit 4 (subunit b) in the assembly of the whole enzyme was studied by using nonsense mutants generated by site-directed mutagenesis. The removal of at least the last 10 amino-acid residues promoted mutants which were unable to grow with glycerol or lactate as carbon source. These mutants were devoid of subunit 4 and of another F0 subunit, the mitochondrially encoded subunit 6. The removal of the last eight amino-acid residues promoted a temperature-sensitive mutant (PVY161). At 37 degrees C this strain showed the same phenotype as above. When grown at permissive temperature (30 degrees C) with lactate as carbon source, PVY161 and the wild-type strain both displayed the same generation time and growth yield. Furthermore, the two strains showed identical cellular respiration rates at 30 degrees C and 37 degrees C. However, in vitro the ATP hydrolysis of PVY161 mitochondria exhibited a low sensitivity to F0 inhibitors, while ATP synthesis displayed the same oligomycin sensitivity as wild-type mitochondria. It is concluded that, in this mutant, the assembly of the truncated subunit 4 in PVY161 ATP synthase is thermosensitive and that, once a functional F0 is formed, it is stable. On the other hand, the removal of the last eight amino-acid residues promoted in vitro a proton leak between the site of action of oligomycin and F1.

cDNA cloning for and preparation of antibodies against subunit d of H(+)-ATP synthase in rat mitochondria

The cDNA for subunit d of rat mitochondrial H(+)-ATP synthase was cloned from a brain cDNA library. The protein contains internally repeat structures that have sequences similar to those of other ATP-related proteins. The antibodies raised against the protein A-subunit d fusion protein expressed in E. coli specifically recognized only the protein in the mitochondria. The Na2 CO3 fractionation followed by immunoblotting analyses suggest that at least a part of the protein is inserted into the membrane.