The leader peptide of yeast Atp6p is required for efficient interaction with the Atp9p ring of the mitochondrial ATPase

Atp6p (subunit 6) of the Saccharomyces cerevisiae mitochondrial ATPase is synthesized with an N-terminal 10-amino acid presequence that is cleaved during assembly of the complex. This study has examined the role of the Atp6p presequence in the function and assembly of the ATPase complex. Two mutants were constructed in which the codons for amino acids 2-9 or 2-10 of the Atp6p precursor were deleted from the mitochondrial ATP6 gene. The concentration of Atp6p and ATPase complex was approximately 2 times less in the mutants. The lower concentration of ATPase complex in the leaderless mutants correlated with less Atp6p complexed with the Atp9p ring of the F0 sector and with accumulation of an Atp6p-Atp8p complex that aggregated into polymers destined for eventual proteolytic elimination. We propose that the presequence either targets Atp6p to the Atp9p or signals insertion of the Atp6p precursor into a microcompartment of the membrane for more efficient interaction with the Atp9p ring. Despite the ATPase deficiency, growth of the leaderless atp6 mutants on respiratory substrates and the efficiency of oxidative phosphorylation were similar to that of wild type, indicating that the mutations did not affect the proton permeability of mitochondria.     

The alpha-subunit of the mitochondrial F(1) ATPase interacts directly with the assembly factor Atp12p

The Atp12p protein of Saccharomyces cerevisiae is required for the assembly of the F(1) component of the mitochondrial F(1)F(0) ATP synthase. In this report, we show that the F(1) alpha-subunit co-precipitates and co-purifies with a tagged form of Atp12p adsorbed to affinity resins. Moreover, sedimentation analysis indicates that in the presence of the F(1) alpha-subunit, Atp12p behaves as a particle of higher mass than is observed in the absence of the alpha-subunit. Yeast two-hybrid screens confirm the direct association of Atp12p with the alpha-subunit and indicate that the binding site for the assembly factor lies in the nucleotide-binding domain of the alpha-subunit, between Asp133 and Leu322. These studies provide the basis for a model of F(1) assembly in which Atp12p is released from the alpha-subunit in exchange for a beta-subunit to form the interface that contains the non-catalytic adenine nucleotide-binding site.     

The assembly factor Atp11p binds to the beta-subunit of the mitochondrial F(1)-ATPase

Atp11p is a protein of Saccharomyces cerevisiae required for the assembly of the F(1) component of the mitochondrial F(1)F(0)-ATP synthase. This study presents evidence that Atp11p binds selectively to the beta-subunit of F(1). Under conditions in which avidin-Sepharose beads specifically adsorbed biotinylated Atp11p from yeast mitochondrial extracts, the F(1) beta-subunit coprecipitated with the tagged Atp11p protein. Binding interactions between Atp11p and the entire beta-subunit of F(1) or fragments of the beta-subunit were also revealed by a yeast two-hybrid screen: Atp11p bound to a region of the nucleotide-binding domain of the beta-subunit located between Gly(114) and Leu(318). Certain elements of this sequence that would be accessible to Atp11p in the free beta-subunit make contact with adjacent alpha-subunits in the assembled enzyme. This observation suggests that the alpha-subunits may exchange for bound Atp11p during the process of F(1) assembly.     

ATP10, a yeast nuclear gene required for the assembly of the mitochondrial F1-F0 complex

A yeast nuclear gene (ATP10) is reported whose product is essential for the assembly of a functional mitochondrial ATPase complex. Mutations in ATP10 induce a loss of rutamycin sensitivity in the mitochondrial ATPase but do not affect respiratory enzymes. This phenotype has been correlated with a defect in the F0 sector of the ATPase. The wild type ATP10 gene has been cloned by transformation of an atp 10 mutant with a yeast genomic library. The gene codes for a protein of Mr = 30,293. The primary structure of the ATP10 product is not related to any known subunit of the yeast or mammalian mitochondrial ATPase complexes. To further clarify the role of this new protein in the assembly of the ATPase, an antibody was prepared against a hybrid protein expressed from a trpE/ATP 10 fusion gene. The antibody recognizes a 30-kDa protein present in wild type mitochondria. The protein is associated with the mitochondrial membrane but does not co-fractionate either with F1 or with the rutamycin-sensitive F1-F0 complex. These data suggest that the ATP10 product is not a subunit of the ATPase complex but rather is required for the assembly of the F0 sector of the complex.     

The Drosophila gene 2A5 complements the defect in mitochondrial F1-ATPase assembly in yeast lacking the molecular chaperone Atp11p.

Assembly of mitochondrial F1-ATPase in Saccharomyces cerevisiae requires the molecular chaperone, Atp11p. Database searches have identified protein sequences from Schizosaccharomyces pombe and two species of Drosophila that are homologous to S. cerevisiae Atp11p. A cDNA encoding the putative Atp11p from Drosophila yakuba was shown to complement the respiratory deficient phenotype of yeast harboring an atp11::HIS3 disruption allele. Furthermore, the product of this Drosophila gene was shown to interact with the S. cerevisiae F1 beta subunit in the yeast two-hybrid assay. These results indicate that Atp11p function is conserved in higher eukaryotes.     

Atp11p and Atp12p are assembly factors for the F(1)-ATPase in human mitochondria.

Atp11p and Atp12p were first described as proteins required for assembly of the F(1) component of the mitochondrial ATP synthase in Saccharomyces cerevisiae (Ackerman, S. H., and Tzagoloff, A. (1990) Proc. Natl. Acad. Sci. U. S. A. 87, 4986-4990). Here we report the isolation of the cDNAs and the characterization of the human genes for Atp11p and Atp12p and show that the human proteins function like their yeast counterparts. Human ATP11 spans 24 kilobase pairs in 9 exons and maps to 1p32.3-p33, while ATP12 contains > or =8 exons and localizes to 17p11.2. Both genes are broadly conserved in eukaryotes and are expressed in a wide range of tissues, which suggests that Atp11p and Atp12p are essential housekeeping proteins of human cells. The information reported herein will be useful in the evaluation of patients with ascertained deficiencies in the ATP synthase, in which the underlying biochemical defect is unknown and may reside in a protein that influences the assembly of the enzyme.     

Oxa1 directly interacts with Atp9 and mediates its assembly into the mitochondrial F1Fo-ATP synthase complex

The yeast Oxa1 protein is involved in the biogenesis of the mitochondrial oxidative phosphorylation (OXPHOS) machinery. The involvement of Oxa1 in the assembly of the cytochrome oxidase (COX) complex, where it facilitates the cotranslational membrane insertion of mitochondrially encoded COX subunits, is well documented. In this study we have addressed the role of Oxa1, and its sequence-related protein Cox18/Oxa2, in the biogenesis of the F(1)F(o)-ATP synthase complex. We demonstrate that Oxa1, but not Cox18/Oxa2, directly supports the assembly of the membrane embedded F(o)-sector of the ATP synthase. Oxa1 was found to physically interact with newly synthesized mitochondrially encoded Atp9 protein in a posttranslational manner and in a manner that is not dependent on the C-terminal, matrix-localized region of Oxa1. The stable manner of the Atp9-Oxa1 interaction is in contrast to the cotranslational and transient interaction previously observed for the mitochondrially encoded COX subunits with Oxa1. In the absence of Oxa1, Atp9 was observed to assemble into an oligomeric complex containing F(1)-subunits, but its further assembly with subunit 6 (Atp6) of the F(o)-sector was perturbed. We propose that by directly interacting with newly synthesized Atp9 in a posttranslational manner, Oxa1 is required to maintain the assembly competence of the Atp9-F(1)-subcomplex for its association with Atp6.     

ATP25, a new nuclear gene of Saccharomyces cerevisiae required for expression and assembly of the Atp9p subunit of mitochondrial ATPase

We report a new nuclear gene, designated ATP25 (reading frame YMR098C on chromosome XIII), required for expression of Atp9p (subunit 9) of the Saccharomyces cerevisiae mitochondrial proton translocating ATPase. Mutations in ATP25 elicit a deficit of ATP9 mRNA and of its translation product, thereby preventing assembly of functional F(0). Unlike Atp9p, the other mitochondrial gene products, including ATPase subunits Atp6p and Atp8p, are synthesized normally in atp25 mutants. Northern analysis of mitochondrial RNAs in an atp25 temperature-sensitive mutant confirmed that Atp25p is required for stability of the ATP9 mRNA. Atp25p is a mitochondrial inner membrane protein with a predicted mass of 70 kDa. The primary translation product of ATP25 is cleaved in vivo after residue 292 to yield a 35-kDa C-terminal polypeptide. The C-terminal half of Atp25p is sufficient to stabilize the ATP9 mRNA and restore synthesis of Atp9p. Growth on respiratory substrates, however, depends on both halves of Atp25p, indicating that the N-terminal half has another function, which we propose to be oligomerization of Atp9p into a proper size ring structure.     

Yeast cells depleted in Atp14p fail to assemble Atp6p within the ATP synthase and exhibit altered mitochondrial cristae morphology

Within the yeast mitochondrial ATP synthase, subunit h is a small nuclear encoded protein belonging to the so-called "peripheral stalk" that connects the enzyme catalytic F(1) component to the mitochondrial inner membrane. This study examines the role of subunit h in ATP synthase function and assembly using a regulatable, doxycycline-repressible subunit h gene to overcome the strong instability of the mtDNA previously observed in strains lacking the native subunit h gene. Yeast cells expressing less than 3% of subunit h, but still containing intact mitochondrial genomes, grew poorly on respiratory substrates because of a major impairment of ATP synthesis originating from the ATP synthase, whereas the respiratory chain complexes were not affected. The lack of ATP synthesis in the subunit h-depleted (deltah) mitochondria was attributed to defects in the assembly/stability of the ATP synthase. A main feature of deltah-mitochondria was a very low content (<6%) in the mitochondrially encoded Atp6p subunit, an essential component of the enzyme proton channel, which was in large part because of a slowing down in translation. Interestingly, depletion of subunit h resulted in dramatic changes in mitochondrial cristae morphology, which further supports the existence of a link between the ATP synthase and the folding/biogenesis of the inner mitochondrial membrane.     

Correspondence of minor subunits of plant mitochondrial F1ATPase to F1F0ATPase subunits of other organisms

In addition to two major alpha- and beta-subunits, the soluble oligomycin-insensitive F1ATPase purified from sweet potato root mitochondria contains four different minor subunits of gamma (Mr = 35,500), delta (Mr = 27,000), delta' (Mr = 23,000), and epsilon (Mr = 12,000) (Iwasaki, Y., and Asashi, T. (1983) Arch. Biochem. Biophys. 227, 164-173). Among these minor subunits, the delta-subunit specifically cross-reacted with an antibody against the delta-subunit of maize mitochondrial F1 which contains only three minor gamma-, delta- and epsilon-subunits like F1ATPases from other organisms, indicating that the delta'-subunit is an extra subunit of sweet potato F1 which is absent in the maize F1. All of the four minor subunits of sweet potato F1 were purified and their N-terminal amino acid sequences of 30-36 residues were determined. The N-terminal sequence of gamma-subunit was homologous to those of the gamma-subunits of bacterial F1 and mammalian mitochondrial F1. The N-terminal sequence of the delta-subunit was homologous to those of the delta-subunits of bacterial F1, chloroplast CF1, and oligomycin sensitivity conferring protein of bovine mitochondrial F1F0. A sequence homology was also observed between the sweet potato epsilon-subunit and the epsilon-subunit of bovine mitochondrial F1. The N-terminal sequence of the delta'-subunit did not show any significant sequence homology to known protein sequences. These subunit correspondences place plant mitochondrial F1 at an unique position in the evolution of F1ATPase.     

YidC-mediated membrane insertion of assembly mutants of subunit c of the F1F0 ATPase

YidC is a member of the OxaI family of membrane proteins that has been implicated in the membrane insertion of inner membrane proteins in Escherichia coli. We have recently demonstrated that proteoliposomes containing only YidC support both the stable membrane insertion and the oligomerization of the c subunit of the F(1)F(0) ATP synthase (F(0)c). Here we have shown that two mutants of F(0)c unable to form a functional F(1)F(0) ATPase interact with YidC, require YidC for membrane insertion, but fail to oligomerize. These data show that oligomerization is not essential for the stable YidC-dependent membrane insertion of F(0)c consistent with a function of YidC as a membrane protein insertase.     

ATP4, the structural gene for yeast F0F1 ATPase subunit 4

A plasmid containing the gene coding for the Saccharomyces cerevisiae F0F1 ATPase subunit 4 was isolated from a yeast genomic DNA library using the oligonucleotide probe procedure. The gene and the surrounding regions were cloned into M13 tg 130 and M13 tg 131 phage vectors. A 732-base-pair open reading frame encoding a 244-amino-acid polypeptide is described. The nucleotide sequence predicts that subunit 4 is probably derived from a precursor protein with a hydrophilic and basic 35-amino-acid leader sequence. Mature subunit 4 contains 209 amino acid residues and the predicted molecular mass is 23250 Da. This subunit presents amphiphilic behaviour with two distinct domains. A high alpha-helix content of 77% was predicted from the sequence. Subunit 4 shows homology with the b subunit of Escherichia coli ATP synthase.     

Effects of naturally occurring polyols and urea on mitochondrial F0F1ATPase

We show that urea inhibits the ATPase activity of MgATP submitochondrial particles (MgATP-SMP) with Ki = 0.7 M, probably as a result of direct interaction with the structure of F0F1-ATPase. Counteracting compounds (sorbitol, mannitol or inositol), despite slightly (10-20%) inhibiting the ATPase activity, also protect the F0F1-ATPase against denaturation by urea. However, this protection was only observed at low urea concentrations (less than 1.5 M), and in the presence of three polyols, the Ki for urea shift from 0.7 M to 1.2 M. Urea also increases the initial activation rate of latent MgATP-SMP in a dose-dependent-manner. However, when the particles (0.5 mg/ml) were preincubated in the presence of 1 M, 2 M or 3 M urea, a decrease in the activation level occurred after 1 h, 30 and 10 min, respectively. At high MgATP-SMP concentration (3 mg/ml) a decrease in activation was observed after 2 h, 1 h and 20 min, respectively. These data indicate that the effect of urea on the activation of MgATP-SMP depends on time, urea and protein concentrations. It was also observed that polyols suppress the activation of latent MgATP-SMP in a dose-dependent manner, and protect the particles against urea denaturation during activation. We suppose that a decrease in membrane mobility promoted by interactions of polyols with phospholipids around the F0F1-ATPase may also increase the compactation of protein structure, explaining the inhibition of natural inhibitor protein of ATPase (IF1) release and the activation of the enzyme.     

Nuclear genes encoding the yeast mitochondrial ATPase complex. Analysis of ATP1 coding the F1-ATPase alpha-subunit and its assembly

Mitochondria prepared from the yeast nuclear pet mutant N9-84 lack a detectable F1-ATPase activity. Genetic complementation of this mutant with a pool of yeast genomic DNA in the yeast Escherichia coli shuttle vector YEp13 restored its growth on a nonfermentable carbon source. Mitochondria prepared from the transformed host contained an 8-fold higher than normal level of the F1 alpha-subunit and restored ATPase activity to 50% that of the wild-type strain. Deletion and nucleotide sequence analysis of the complementing DNA on the plasmid revealed a coding sequence designated ATP1 for a protein of 544 amino acids which exhibits 60 and 54% direct protein sequence homology with the proton-translocating ATPase alpha-subunits from tobacco chloroplast and E. coli, respectively. In vitro expression and mitochondrial import experiments using this ATP1 sequence showed that additional amino-terminal sequences not present in the comparable plant and bacterial subunits function as transient sequences for import.     

Role of Vma21p in assembly and transport of the yeast vacuolar ATPase

The Saccharomyces cerevisiae vacuolar H+-ATPase (V-ATPase) is a multisubunit complex composed of a peripheral membrane sector (V1) responsible for ATP hydrolysis and an integral membrane sector (V0) required for proton translocation. Biogenesis of V0 requires an endoplasmic reticulum (ER)-localized accessory factor, Vma21p. We found that in vma21Delta cells, the major proteolipid subunit of V0 failed to interact with the 100-kDa V0 subunit, Vph1p, indicating that Vma21p is necessary for V0 assembly. Immunoprecipitation of Vma21p from wild-type membranes resulted in coimmunoprecipitation of all five V0 subunits. Analysis of vmaDelta strains showed that binding of V0 subunits to Vma21p was mediated by the proteolipid subunit Vma11p. Although Vma21p/proteolipid interactions were independent of Vph1p, Vma21p/Vph1p association was dependent on all other V0 subunits, indicating that assembly of V0 occurs in a defined sequence, with Vph1p recruitment into a Vma21p/proteolipid/Vma6p complex representing the final step. An in vitro assay for ER export was used to demonstrate preferential packaging of the fully assembled Vma21p/proteolipid/Vma6p/Vph1p complex into COPII-coated transport vesicles. Pulse-chase experiments showed that the interaction between Vma21p and V0 was transient and that Vma21p/V0 dissociation was concomitant with V0/V1 assembly. Blocking ER export in vivo stabilized the interaction between Vma21p and V0 and abrogated assembly of V0/V1. Although a Vma21p mutant lacking an ER-retrieval signal remained associated with V0 in the vacuole, this interaction did not affect the assembly of vacuolar V0/V1 complexes. We conclude that Vma21p is not involved in regulating the interaction between V0 and V1 sectors, but that it has a crucial role in coordinating the assembly of V0 subunits and in escorting the assembled V0 complex into ER-derived transport vesicles.     

Phospholipid-dependent assembly of mitochondrial ATPase complex

1. Phosphatidylcholines of different acyl-chain composition and a preparation of ATPase complex depleted of phospholipids have been employed in order to evaluate the contribution of lipid bilayer to the assembly of this multi-subunit component of mitochondrial membrane. 2. At the minimal requirement for bilayer assembly (dinonanoylphosphatidylcholine, mixtures of lysophosphatidylcholine and phosphatidylcholine), fragments with oligomycin-insensitive ATPase activity are reconstituted. Conformational changes with dislocation of ATPase complex subunits may explain these results. 3. At increased strength of acyl-chain interaction (dilauroylphosphatidylcholine and higher homologues), the damage to the ATPase complex is prevented but this is not sufficient to achieve functional restoration. Bilayers with a tendency to coalesce and fuse aggregate in large amounts with the complex and yield low ATPase reactivation. Bilayers of high stability yield complexes with physiological content of phospholipids and efficient ATPase activity. Transition between these two possibilities is found at sixteen carbon acyl-chains. Only at this chain length does the cholate dialysis procedure of reconstitution become feasible. 4. It is concluded that a minimum of 16 carbon atoms in each chain are required to organize a bilayer structurable to maintain the ATPase complex conformation and to sustain the transmembrane position of the whole assembly.     

Diethylstilbestrol. A novel F0-directed probe of the mitochondrial proton ATPase

At low concentrations, diethylstilbestrol (DES) is shown to be a potent F0-directed inhibitor of the F0F1-ATPase of rat liver mitochondria. In analogy to other F0-directed inhibitors, DES inhibits both the ATPase and ATP-dependent proton-translocation activities of the purified and membrane bound enzyme. When added at low concentrations with dicyclohexylcarbodiimide (DCCD), a covalent inhibitor, DES acts synergistically to inhibit ATPase activity of the complex. At higher concentrations, DES restores DCCD-inhibited ATPase activity. However, there is no restoration of ATP-dependent proton translocation. Under these conditions DCCD remains covalently bound to the F0F1-ATPase complex and F1 remains bound to Fo. Significantly, when the F0F1-ATPase is inhibited by the Fo-directed inhibitor venturicidin rather than DCCD, DES is also able to restore ATPase activity. In contrast, DES is unable to restore ATPase activity to F0F1 preparations inhibited by the Fo-directed inhibitors oligomycin or tricyclohexyltin. However, combinations of [DES + DCCD] or [DES + venturicidin] can restore ATPase activity to F0F1 preparations inhibited by either oligomycin or tricyclohexyltin. Results presented here indicate that the F0 moiety of the rat liver mitochondrial proton ATPase contains a distinct binding site for DES. In addition, they suggest that at saturating concentrations simultaneous occupancy of the DES binding site and sites for either DCCD or venturicidin promote "uncoupled" ATP hydrolysis.     

Effect of the delta subunit on assembly and proton permeability of the F0 proton channel of Escherichia coli F1F0 ATPase.

During the assembly of the Escherichia coli proton-translocating ATPase, the subunits of F1 interact with F0 to increase the proton permeability of the transmembrane proton channel. We tested the involvement of the delta subunit in this process by partially and completely deleting uncH (delta subunit) from a plasmid carrying the genes for the F0 subunits and delta and testing the effects of those F0 plasmids on the growth of unc+ and unc mutant E. coli strains. We found that the delta subunit was required for inhibition of growth of unc+ cells. We also tested membranes isolated from unc-deleted cells containing F0 plasmids for F1-binding ability. In unc-deleted cells, these plasmids produced F0 in amounts comparable to those found in normal unc+ E. coli cells, while having only small effects on cell growth. These studies demonstrate that the delta subunit plays an important role in opening the F0 proton channel but that it does not serve as a temporary plug of F0 during assembly, as had been previously speculated (S. Pati and W. S. A. Brusilow, J. Biol. Chem. 264:2640-2644, 1989).     

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.     

Ethanol-elicited alterations in the oligomycin sensitivity and structural stability of the mitochondrial F0 . F1 ATPase

Liver mitochondria from rats fed ethanol chronically demonstrated a 35% decrease in mitochondrial ATPase activity. Moreover, the ATPase activity was inhibited only 61% by addition of oligomycin. Treatment of mitochondria from ethanol-fed rats with the detergent, Lubrol-WX, caused the release of 36% of the F1 from the resulting inner membrane particles. In comparison, only 5% of the F1 was dissociated when control mitochondria were subjected to the Lubrol treatment. However, when the units of ATPase activity from the supernatant and particles obtained after Lubrol treatment were added together, their sums were equivalent in preparations from control and ethanol-fed animals. Moreover, polyacrylamide gel electrophoresis analyses indicated equal amounts of the alpha + beta subunits of F1 in mitochondria from control and ethanol-fed rats. Reconstitution experiments with urea particles and F1 prepared from both control and ethanol mitochondria revealed a decrease in oligomycin sensitivity which could be attributed to an alteration in the functioning of either the oligomycin sensitivity conferring protein or a membrane sector subunit that interacts with oligomycin. Analysis by reconstitution also demonstrated that there were no ethanol-elicited alterations in the properties of the F1 portion of the ATP synthase complex. These observations indicate that the activity of the ATP synthase complex is altered significantly by ethanol-elicited changes in the functioning of those polypeptides involved in modulating both oligomycin sensitivity and the association of F1 with membrane sector subunits.