Assembly of a functional F1 of the proton-translocating ATPase of Escherichia coli

Assembly of the F1 portion of the proton-translocating ATPase of Escherichia coli was examined in vivo. Analysis of strains lacking genes which specify the Fo polypeptides a, b, and c showed that the F1 subunits were able to assemble into a complex in the absence of the Fo subunits. In addition we have investigated the effects of mutations in the individual genes which specify the F1 polypeptides on the assembly process. Mutations of the uncA(alpha), uncG(gamma), or uncD(beta) genes result in a defective assembly of the F1 complex. In contrast, mutations in the uncH(delta) or uncC(epsilon) genes did not prevent assembly of the core alpha beta gamma complex. In these cases, however, the partial F1 complexes were incapable of restoring energy-linked functions to F1-depleted membranes.     

Proton leakiness caused by cloned genes for the F0 sector of the proton-translocating ATPase of Escherichia coli: requirement for F1 genes.

To study expression of uncG, the gene coding for the gamma subunit of the Escherichia coli proton-translocating ATPase, deletions were made in the intergenic region between uncA, the gene coding for the alpha subunit, and uncG. Two deletions which fused uncA and uncG coded for alpha-gamma fusion polypeptides which were synthesized well both in vitro and in vivo, demonstrating that uncG expression is normally controlled by nucleotides in the intergenic region. Multicopy plasmids carrying these fusion genes and the genes for the other subunits of the ATPase had a harmful effect on the growth of E. coli. The effect was overcome by N,N'-dicyclohexylcarbodiimide, indicating that the cells probably leaked protons. The deleterious effect was eliminated by making a nonpolar deletion in the upstream F0 gene uncB, or by cloning each of the uncA-uncG fusion genes onto a separate plasmid, removed from the F0 genes, thus demonstrating that the fusion genes were not primarily responsible for the proton permeability. A plasmid which carried F0 genes and the gene for the delta subunit caused deleterious proton leakiness in unc+ cells but not in cells from which the unc operon was deleted. The proton leakiness caused by these different plasmids was therefore due to the production of a leaky F0 proton channel and required the presence of F1 genes. The results support a model for ATPase assembly in which F1 genes or polypeptides are involved in the formation or opening of the F0 proton channel.     

Structural aspects of proton-pumping ATPases

ATP synthase is found in bacteria, chloroplasts and mitochondria. The simplest known example of such an enzyme is that in the eubacterium Escherichia coli; it is a membrane-bound assembly of eight different polypeptides assembled with a stoichiometry of alpha 3 beta 3 gamma 1 delta 1 epsilon 1 a1b2c10-12. The first five of these constitute a globular structure, F1-ATPase, which is bound to an intrinsic membrane domain, F0, an assembly of the three remaining subunits. ATP synthases driven by photosynthesis are slightly more complex. In chloroplasts, and probably in photosynthetic bacteria, they have nine subunits, all homologues of the components of the E. coli enzyme; the additional subunit is a duplicated and diverged relation of subunit b. The mammalian mitochondrial enzyme is more complex. It contains 14 different polypeptides, of which 13 have been characterized. Two membrane components, a (or ATPase-6) and A6L, are encoded in the mitochondrial genome in overlapping genes and the remaining subunits are nuclear gene products that are translated on cytoplasmic ribosomes and then imported into the organelle. The sequence of the proteins of ATP-synthase have provided information about amino acids that are important for its function. For example, amino acids contributing to nucleotide binding sites have been identified. Also, they provide the basis of models of secondary structure of membrane components that constitute the transmembrane proton channel. An understanding of the coupling of the transmembrane potential gradient for protons, delta mu H+, to ATP synthesis will probably require the determination of the structure of the entire membrane bound complex. Crystals have been obtained of the globular domain, F1-ATPase. They diffract to a resolution of 3-4 A and data collection is in progress. As a preliminary step towards crystallization of the entire complex, we have purified it from bovine mitochondria and reconstituted it into phospholipid vesicles.     

Topology and function of "stalk" proteins in the bovine mitochondrial H+-ATPase

Proton translocating ATPases comprise a hydrophilic sector F1, a membrane sector F0, and, in the case of bovine mitochondria, a connecting "stalk" which is believed to contain the oligomycin sensitivity-conferring protein (OSCP) and coupling factor 6 (F6). The present study was undertaken to verify the accessibility of F6 and OSCP to trypsin and to examine the functional consequences of such treatment. Our data show that F1 binds equally to trypsin-treated F0 and untreated F0, but the former complexes exhibit cold lability and only partial sensitivity to oligomycin. Furthermore, these complexes fail to exhibit ATP-driven proton translocation or ATP-32Pi exchange activity. Trypsinization of F0 does not, however, inhibit passive proton conductance through the membrane sector but actually enhances it. Immunological data indicate extensive degradation of OSCP under conditions where F6 proteolysis is insignificant. Intact H+-ATPase complexes are relatively resistant to both the structural and functional effects of trypsin. We conclude that OSCP is predominantly an extrinsic protein which is shielded by F1 in the native membrane. F6 may also be an extrinsic protein but is shielded from trypsinization by OSCP and/or other F0 polypeptides. The exposed, trypsin-sensitive segments of OSCP are not required for passive proton conductance through F0 but may be required for ATP-driven reactions. We propose that bovine mitochondrial OSCP is a functional analogue of subunit b in the Escherichia coli H+-ATPase.     

All three subunits are required for the reconstitution of an active proton channel (F0) of Escherichia coli ATP synthase (F1F0).

The membrane-integrated, proton-translocating F0 portion of the ATP synthase (F1F0) from Escherichia coli is built up from three kinds of subunits a, b and c with the proposed stoichiometry of 1:2:10 +/- 1. We have dissociated the F0 complex by treatment with trichloroacetate (3 M) at pH 8.0, in the presence of deoxycholate (1%) and N-tetradecyl-N, N-dimethyl-3-ammonio-1-propanesulfonate (Zwittergent 3-14, 5%). The subunits were separated by gel filtration with trichloroacetate (1 M) included in the elution buffer. The homogeneity of the fractions was checked by rechromatography and SDS-gel electrophoresis. After integration into phospholipid vesicles each subunit alone as well as all possible combinations were tested for H+ translocating activity and binding of F1. A functional H+ channel could only be reconstituted by the combination a1b2c10 which corresponds to that of native F0.     

Cross-linking and labeling of the Escherichia coli F1F0-ATP synthase reveal a compact hydrophilic portion of F0 close to an F1 catalytic subunit

The subunit arrangement of the F0 sector of the Escherichia coli ATP synthase is examined using hydrophilic and hydrophobic (cleavable) cross-linking reagents and the water-soluble labeling reagent [35S] diazoniumbenzenesulfonate ( [35S]DABS). Cross-linking is performed on purified ATP synthase and inverted minicell membranes. ATP synthase incorporated into liposomes is labeled with [35S]DABS. Three cross-linked products involving the F0 subunits (a, b, and c) are observed with the purified ATP synthase in solution: a-b, b2, and c2 dimers. A cross-link between the F0 and F1 is detected and occurs between the a and beta subunits. A cross-linker independent association between the b and beta subunits is also evident, suggesting that the two subunits are close enough to form a disulfide bridge. A cross-linking reagent stable to reducing agents produces a b-beta dimer, as detected by immunoblotting with anti-beta serum. The c subunit does not cross-link with any F1 polypeptide. Minicell membranes containing ATP synthase polypeptides radioactively labeled in vivo similarly show b2 and c2 dimers after cross-linking. [35S]DABS labels the a and b, but not c, subunits, showing that the a and b, but not c, subunits possess hydrophilic domains. Thus, certain domains of subunits a and b extend from the membrane and are in close proximity to one another and the F1 catalytic subunit beta.     

The second stalk of Escherichia coli ATP synthase

Two stalks link the F(1) and F(0) sectors of ATP synthase. The central stalk contains the gamma and epsilon subunits and is thought to function in rotational catalysis as a rotor driving conformational changes in the catalytic alpha(3)beta(3) complex. The two b subunits and the delta subunit associate to form b(2)delta, a second, peripheral stalk extending from the membrane up the side of alpha(3)beta(3) and binding to the N-terminal regions of the alpha subunits, which are approx. 125 A from the membrane. This second stalk is essential for binding F(1) to F(0) and is believed to function as a stator during rotational catalysis. In vitro, b(2)delta is a highly extended complex held together by weak interactions. Recent work has identified the domains of b which are essential for dimerization and for interaction with delta. Disulphide cross-linking studies imply that the second stalk is a permanent structure which remains associated with one alpha subunit or alphabeta pair. However, the weak interactions between the polypeptides in b(2)delta pose a challenge for the proposed stator function.     

F1F0-ATPase from Escherichia coli with mutant F0 subunits. Partial purification and immunoprecipitation of F1F0 complexes

Previously identified mutations in subunits a and b of the F0 sector of the F1F0-ATPase from Escherichia coli are further characterized by isolating detergent-solubilized, partially purified F1F0 complexes from cells bearing these mutations. The composition of the various F1F0 complexes was judged by quantitating the amount of each subunit present in the detergent-solubilized preparations. The composition of the F0 sectors containing altered polypeptides was determined by quantitating the F0 subunits that were immunoprecipitated by antibodies directed against the F1 portion. In this way, the relative amounts of F0 subunits (a, b, c) which survived the isolation procedure bound to F1 were determined for each mutation. This analysis indicates that both missense mutations in subunit a (aser206----leu and ahis245----tyr) resulted in the isolation of F1F0 complexes with normal subunit composition. The nonsense mutation in subunit a (atyr235----end) resulted in isolation of a complex containing the b and c subunits. The bgly131----asp mutation in the b subunit results in an F0 complex which does not assemble or survive the isolation. The isolated F1F0 complex containing the mutation bgly9----asp in the b subunit was defective in two regards: first, a reduction in F1 content relative to F0 and second, the absence of the a subunit. Immunoprecipitations of this preparation demonstrated that F1 interacts with both c and mutant b subunits. A strain carrying the mutation, bgly9----asp, and the compensating suppressor mutation apro240----leu (previously shown to be partially unc+) yielded an F1F0 ++ complex that remained partially defective in F1 binding to F0 but normal in the subunit composition of the F0 sector. The assembly, structure, and function of the F1F0-ATPase is discussed.     

Role of the delta subunit in enhancing proton conduction through the F0 of the Escherichia coli F1F0 ATPase.

We studied the effect of the delta subunit of the Escherichia coli F1 ATPase on the proton permeability of the F0 proton channel synthesized and assembled in vivo. Membranes isolated from an unc deletion strain carrying a plasmid containing the genes for the F0 subunits and the delta subunit were significantly more permeable to protons than membranes isolated from the same strain carrying a plasmid containing the genes for the F0 subunits alone. This increased proton permeability could be blocked by treatment with either dicyclohexyl-carbodiimide or purified F1, both of which block proton conduction through the F0. After reconstitution with purified F1 in vitro, both membrane preparations could couple proton pumping to ATP hydrolysis. These results demonstrate that an interaction between the delta subunit and the F0 during synthesis and assembly produces a significant change in the proton permeability of the F0 proton channel.     

Labeling of the ATP synthase of Escherichia coli from the head-group region of the lipid bilayer

The isolated and membrane-bound forms of the adenosinetriphosphatase of Escherichia coli (ECF1 and ECF1F0, respectively) have been reacted with two lysine-specific reagents, sodium hexadecyl 4-[3H]formylphenyl phosphate (HFPP) and sodium methyl 4-[3H]formylphenyl phosphate (MFPP), and with the photoreactive reagent 1,2-[3H]dipalmitoyl-sn-glycerol 3-[[[(4-azido-2-nitrophenyl)amino]ethyl]-phosphate] (arylazidoPE). HFPP and arylazidoPE are amphipathic molecules, inserting by their hexadecyl moieties (one and two chains, respectively) into the lipid bilayer, with the reactive groups intercalated among the phospholipid head groups. MFPP is the water-soluble analogue of HFPP. The labeling patterns of ECF1F0 obtained with HFPP and arylazidoPE were very similar; in both cases the a and b subunits of the F0 part were the most heavily labeled polypeptides of the complex. Models of subunit a, arranged in six transmembrane helices, place most of the lysines in the head-group region, available for reaction with HFPP. Subunits alpha and beta of the ECF1 part were very poorly labeled in comparison to the a and b subunits, together incorporating only 4% as much HFPP and 7.5% as much arylazidoPE as the two F0 subunits together on a protein mass basis. Trypsin cleavage studies localized any labeling of the alpha subunit by arylazidoPE to the N-terminal 15 residues of this polypeptide. When MFPP was used, the alpha and beta subunits were very much more reacted than the F0 subunits. This implies that most of the mass of the alpha and beta subunits in ECF1F0 is above the membrane and not in contact with the bilayer surface.(ABSTRACT TRUNCATED AT 250 WORDS)     

DNA-dependent RNA polymerase of thermoacidophilic archaebacteria

Among 979 non-glycerol growers of the yeast Schizosaccharomyces pombe, 40 strains were found to be deficient in the mitochondrial ATPase activity. Three of them exhibited an alteration in either the alpha or beta subunits of the F1ATPase. The alpha subunit was not immunodetected in the A23/13 mutant. The beta subunit was not immuno-detected in the B59/1 mutant. The existence of these two mutants shows that the alpha and beta subunits can be present independently of each other in the inner mitochondrial membrane. The beta subunit of the mutant F25/28 had a slower electrophoretic mobility than that of the wild-type beta subunit. This phenotype indicates abnormal processing or specific modification of the beta subunit. All mutants showed reduced activities of the NADH-cytochrome c reductase and of the cytochrome oxidase and a decreased synthesis of cytochrome aa3 and cytochrome b. This pleiotropic phenotype appears to result from specific modifications in the mitochondrial protein synthesis. The mitochondrial synthesis of four polypeptides (three cytochrome oxidase and one cytochrome b subunits) was markedly decreased or absent while three new polypeptides (Mr = 54000, 20000 and 15000) were detected in all the mutants analysed. This observation suggests that a functional F1ATPase is necessary for the correct synthesis and/or assembly of the mitochondrially made components of the cytochrome oxidase and cytochrome b complexes.     

Mechanically driven proton conduction in single delta-free F0F1-ATPase

In order to observe mechanically driven proton flux in F(0)F(1)-ATPase coupled with artificial driven rotation on F(1) simultaneously, a double channel observation system was established. An artificial delta-free F(0)F(1)-ATPase was constructed with alpha(3), beta(3), epsilon, gamma, and c(n) subunits as rotator and a, b(2) as stator. The chromatophore was immobilized on the glass surface through biotin-streptavidin-biotin system, and the magnetic bead was attached to the beta subunit of delta-free F(0)F(1)-ATPase. The mechanically driven proton flux was indicated by the fluorescence intensity change of fluorescein reference standard (F1300) and recorded by a cooled digital CCD camera. The mechanochemical coupling stoichiometry between F(0) and F(1) is about 4.15 +/- 0.2H(+)/rev when the magnetic field rotated at 0.33 Hz (rps).     

F1F0 ATP synthase subunit c is a substrate of the novel YidC pathway for membrane protein biogenesis

The Escherichia coli YidC protein belongs to the Oxa1 family of membrane proteins that have been suggested to facilitate the insertion and assembly of membrane proteins either in cooperation with the Sec translocase or as a separate entity. Recently, we have shown that depletion of YidC causes a specific defect in the functional assembly of F1F0 ATP synthase and cytochrome o oxidase. We now demonstrate that the insertion of in vitro-synthesized F1F0 ATP synthase subunit c (F0c) into inner membrane vesicles requires YidC. Insertion is independent of the proton motive force, and proteoliposomes containing only YidC catalyze the membrane insertion of F0c in its native transmembrane topology whereupon it assembles into large oligomers. Co-reconstituted SecYEG has no significant effect on the insertion efficiency. Remarkably, signal recognition particle and its membrane-bound receptor FtsY are not required for the membrane insertion of F0c. In conclusion, a novel membrane protein insertion pathway in E. coli is described in which YidC plays an exclusive role.     

Stochastic rotational catalysis of proton pumping F-ATPase

F-ATPases synthesize ATP from ADP and phosphate coupled with an electrochemical proton gradient in bacterial or mitochondrial membranes and can hydrolyse ATP to form the gradient. F-ATPases consist of a catalytic F1 and proton channel F0 formed from the alpha3beta3gammadelta and ab2c10 subunit complexes, respectively. The rotation of gammaepsilonc10 couples catalyses and proton transport. Consistent with the threefold symmetry of the alpha3beta3 catalytic hexamer, 120 degrees stepped revolution has been observed, each step being divided into two substeps. The ATP-dependent revolution exhibited stochastic fluctuation and was driven by conformation transmission of the beta subunit (phosphate-binding P-loop/alpha-helix B/loop/beta-sheet4). Recent results regarding mechanically driven ATP synthesis finally proved the role of rotation in energy coupling.     

In vitro membrane association of the F0 polypeptides of the Escherichia coli proton translocating ATPase.

The F0 polypeptides a, b, and c of the H+-translocating ATPase associated with membranes when synthesized in vitro. This association occurred when the membranes were present either cotranslationally or post-translationally. In addition, the F0 polypeptides associated with liposomes. The membrane association seemed to be an insertion process since there was protection of polypeptides a and c from proteolysis. The in vitro insertion of the F0 polypeptides a, b, and c was independent of the synthesis of each polypeptide and of the F1 polypeptides.     

Observation of calcium-dependent unidirectional rotational motion in recombinant photosynthetic F1-ATPase molecules

ATP hydrolysis and synthesis by the F(0)F(1)-ATP synthase are coupled to proton translocation across the membrane in the presence of magnesium. Calcium is known, however, to disrupt this coupling in the photosynthetic enzyme in a unique way: it does not support ATP synthesis, and CaATP hydrolysis is decoupled from any proton translocation, but the membrane does not become leaky to protons. Understanding the molecular basis of these calcium-dependent effects can shed light on the as yet unclear mechanism of coupling between proton transport and rotational catalysis. We show here, using an actin filament gamma-rotation assay, that CaATP is capable of sustaining rotational motion in a highly active hybrid photosynthetic F(1)-ATPase consisting of alpha and beta subunits from Rhodospirillum rubrum and gamma subunit from spinach chloroplasts (alpha(R)(3)beta(R)(3)gamma(C)). The rotation was found to be similar to that induced by MgATP in Escherichia coli F(1)-ATPase molecules. Our results suggest a possible long range pathway that enables the bound CaATP to induce full rotational motion of gamma but might block transmission of this rotational motion into proton translocation by the F(0) part of the ATP synthase.     

Identification and partial characterization of a novel bipartite protein antigen associated with the outer membrane of Escherichia coli.

A study by crossed immunoelectrophoresis performed in conjunction with precipitate excision and polypeptide analysis identified a new antigen complex in the envelope of Escherichia coli ML308-225. This antigen corresponds to antigen 43 in the crossed immunoelectrophoresis profile of membrane vesicles (P. Owen and H. R. Kaback, Proc. Natl. Acad. Sci. USA 75:3148-3152, 1978). Immunoprecipitation experiments conducted with specific antiserum revealed that the complex was expressed on the cell surface and that it contained, in equal stoichiometry, two chemically distinct polypeptides termed alpha and beta (Mrs of 60,000 and 53,000, respectively). The beta polypeptide was heat modifiable, displaying an apparent Mr of 37,000 when solubilized at temperatures below 70 degrees C. Analysis of fractions obtained following cell disruption, isopycnic centrifugation, and detergent extraction indicated that both alpha and beta polypeptides were components of the outer membrane. The two polypeptides were not linked by disulfide bonds, and neither was peptidoglycan associated. The complex contained no detectable lipopolysaccharide, enzyme activity, fatty acyl groups, or other cofactors. Neither correlated with E. coli proteins of similar molecular weight which had previously been shown to be associated with the outer membrane. Antibodies were raised to individual alpha and beta polypeptides. Each of these sera was shown to be subunit specific when tested against denatured membrane proteins. In contrast, each immunoglobulin preparation coprecipitated both alpha and beta polypeptides when tested against undenatured proteins derived from Triton X-100-treated membranes. The results reveal the presence of a novel bipartite protein antigen in the outer membrane of E. coli.