Identification of subunits a, b, and c1 from Acetobacterium woodii Na+-F1F0-ATPase. Subunits c1, c2, AND c3 constitute a mixed c-oligomer

The Na(+)-F(1)F(0)-ATPase operon of Acetobacterium woodii was recently shown to contain, among eleven atp genes, those genes that encode subunit a and b, a gene encoding a 16-kDa proteolipid (subunit c(1)), and two genes encoding 8-kDa proteolipids (subunits c(2) and c(3)). Because subunits a, b, and c(1) were not found in previous enzyme preparations, we re-determined the subunit composition of the enzyme. The genes were overproduced, and specific antibodies were raised. Western blots revealed that subunits a, b, and c(1) are produced and localized in the cytoplasmic membrane. Membrane protein complexes were solubilized by dodecylmaltoside and separated by blue native-polyacrylamide gel electrophoresis, and the ATPase subunits were resolved by SDS-polyacrylamide gel electrophoresis. N-terminal sequence analyses revealed the presence of subunits a, c(2), c(3), b, delta, alpha, gamma, beta, and epsilon. Biochemical and immunological analyses revealed that subunits c(1), c(2), and c(3) are all part of the c-oligomer, the first of a F(1)F(0)-ATPase that contains 8- and 16-kDa proteolipids.     

Molecular cloning of genes encoding major two subunits of a eubacterial V-type ATPase from Thermus thermophilus.

The atpAB genes which encode the alpha and beta subunits of membrane ATPase from a thermophilic eubacterium, Thermus thermophilus HB8, were cloned. The deduced amino-acid sequences of the alpha subunit (583 amino acids) and the beta subunit (478 amino acids) are only moderately similar to the alpha beta subunits of the F0F1-ATPases, while they are highly similar to the major two subunits of the V-type ATPases, a family of ATPases which have been so far found in eukaryotic endomembrane vacuolar vesicles and archaebacterial plasma membranes. Thus, T. thermophilus ATPase belongs to the V-type ATPase family, even though this bacterium is a eubacterium. The hypothesis that the differentiation of an ancestral ATPase into V-type and F0F1-ATPase occurred after the evolution of a primordial cell into archaebacteria and eubacteria should be modified accordingly.     

Recent developments on structural and functional aspects of the F1 sector of H+-linked ATPases

This review concerns the catalytic sector of F1 factor of the H+-dependent ATPases in mitochondria (MF1), bacteria (BF1) and chloroplasts (CF1). The three types of F1 have many similarities with respect to the structural parameters, subunit composition and catalytic mechanism. An alpha 3 beta 3 gamma delta epsilon stoichiometry is now accepted for MF1 and BF1; the alpha 2 beta 2 gamma 2 delta 2 epsilon 2 stoichiometry for CF1 remains as matter of debate. The major subunits alpha, beta and gamma are equivalent in MF1, BF1 and CF1; this is not the case for the minor subunits delta and epsilon. The delta subunit of MF1 corresponds to the epsilon subunit of BF1 and CF1, whereas the mitochondrial subunit equivalent to the delta subunit of BF1 and CF1 is probably the oligomycin sensitivity conferring protein (OSCP). The alpha beta gamma assembly is endowed with ATPase activity, beta being considered as the catalytic subunit and gamma as a proton gate. On the other hand, the delta and epsilon subunits of BF1 and CF1 most probably act as links between the F1 and F0 sectors of the ATPase complex. The natural mitochondrial ATPase inhibitor, which is a separate protein loosely attached to MF1, could have its counterpart in the epsilon subunit of BF1 and CF1. The generally accepted view that the catalytic subunit in the different F1 species is beta comes from a number of approaches, including chemical modification, specific photolabeling and, in the case of BF1, use of mutants. The alpha subunit also plays a central role in catalysis, since structural alteration of alpha by chemical modification or mutation results in loss of activity of the whole molecule of F1. The notion that the proton motive force generated by respiration is required for conformational changes of the F1 sector of the H+-ATPase complex has gained acceptance. During the course of ATP synthesis, conversion of bound ADP and Pi into bound ATP probably requires little energy input; only the release of the F1-bound ATP would consume energy. ADP and Pi most likely bind at one catalytic site of F1, while ATP is released at another site. This mechanism, which underlines the alternating cooperativity of subunits in F1, is supported by kinetic data and also by the demonstration of partial site reactivity in inactivation experiments performed with selective chemical modifiers. One obvious advantage of the alternating site mechanism is that the released ATP cannot bind to its original site.(ABSTRACT TRUNCATED AT 400 WORDS)     

Thermus thermophilus membrane-associated ATPase. Indication of a eubacterial V-type ATPase

An ATPase with Mr of 360,000 was purified from plasma membranes of a thermophilic eubacterium Thermus thermophilus, and was characterized. ATP hydrolytic activity of the purified enzyme was extremely low, 0.07 mumol of Pi released mg-1 min-1, and it was stimulated up to 30-fold by bisulfite. The following properties of the enzyme indicate that it is not a usual F1-ATPase but that it belongs to the V-type ATPase family, another class of ATPases found in membranes of archaebacteria and eukaryotic endomembranes. Among its four kinds of subunits with approximate Mr values of 66,000 (alpha), 55,000 (beta), 30,000 (gamma), and 12,000 (delta), the alpha subunit had a similar molecular size to the catalytic subunits of the V-type ATPases but was significantly larger than the alpha subunit of F1-ATPases. ATP hydrolytic activity was not affected by azide, an inhibitor of F1-ATPases, but was inhibited by nitrate, an inhibitor of the V-type ATPase. N-terminal amino acid sequences determined for the purified alpha and beta subunits showed much higher similarity to those of the V-type ATPases than those of F1-ATPases. Thus the distribution of the V-type ATPase in the prokaryotic kingdom may not be restricted to archaebacteria.     

Structure-function relationships of the Escherichia coli ATP synthase probed by trypsin digestion

Trypsin cleavage has been used to probe structure-function relationships of the Escherichia coli ATP synthase (ECF1F0). Trypsin cleaved all five subunits, alpha, beta, gamma, delta, and epsilon, in isolated ECF1. Cleavage of the alpha subunit involved the removal of the N-terminal 15 residues, the beta subunit was cleaved near the C-terminus, the gamma subunit was cleaved near Ser202, and the delta and epsilon subunits appeared to be cleaved at several sites to yield small peptide fragments. Trypsin cleavage of ECF1 enhanced the ATPase activity between 6- and 8-fold in different preparations, in a time course that followed the cleavage of the epsilon subunit. This removal of the epsilon subunit increased multisite ATPase activity but not unisite ATPase activity, showing that the inhibitory role of the epsilon subunit is due to an effect on cooperativity. The detergent lauryldimethylamine oxide was found to increase multisite catalysis and also increase unisite catalysis more than 2-fold. Prolonged trypsin cleavage left a highly active ATPase containing only the alpha and beta subunits along with two fragments of the gamma subunit. All of the subunits of ECF1 were cleaved by trypsin in preparations of ECF1F0 at the same sites as in isolated ECF1. Two subunits, the beta and epsilon subunits, were cleaved at the same rate in ECF1F0 as in ECF1 alone. The alpha, gamma, and delta subunits were cleaved significantly more slowly in ECF1F0.(ABSTRACT TRUNCATED AT 250 WORDS)     

Coupling factor 1 from Escherichia coli lacking subunits delta and epsilon: preparation and specific binding to depleted membranes, mediated by subunits delta or epsilon

A procedure for the preparation of coupling factor 1 (F1) from Escherichia coli lacking subunits delta and epsilon is described. Using chloroform and dimethyl sulfoxide, we can isolate F1 containing only subunits alpha, beta, and gamma [F1(alpha beta gamma)] directly from membrane vesicles in 10-mg quantities. Pure and active subunits delta and epsilon were prepared from five-subunit F1 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. After addition of these subunits, F1(alpha beta gamma) is as active in reconstituting ATP-dependent transhydrogenase as five-subunit F1. The ATPase activity of F1 (alpha beta gamma) is inhibited by subunit epsilon in a 1:1 stoichiometry to the same extent (approximately equal to 90%) and with the same affinity (Ki = 0.2-0.8 nM) as reported earlier [Dunn, S.D. (1982) J. Biol. Chem. 257, 7354-7359]. In the presence of either delta or epsilon, F1(alpha beta gamma) binds to F1-depleted membrane vesicles and to liposomes containing the membrane sector (F0) of the ATP synthase to an extent commensurate with the F0 content. The binding ratios epsilon/F1 (alpha beta gamma) and probably also delta/F1 (alpha beta gamma) are close to unity. The specific, delta- or epsilon-deficient F1.F0 complexes presumably formed show ATPase activities sensitive to subunit epsilon but not to dicyclohexylcarbodiimide, and no energy-transfer capabilities. Binding studies at different pH values suggest that F1-F0 interactions in the presence of both subunits delta and epsilon are similar to a combination of those mediated by delta or epsilon alone.(ABSTRACT TRUNCATED AT 250 WORDS)     

V-Type H+-ATPase/synthase from a thermophilic eubacterium, Thermus thermophilus. Subunit structure and operon

V-type ATPase (V(o)V(1)) capable of ATP-driven H(+) pumping and of H(+) gradient driven ATP synthesis was isolated from a thermophilic eubacterium, Thermus thermophilus. When the enzyme was analyzed by gel electrophoresis in the presence of sodium dodecyl sulfate, it showed eight polypeptide bands of which four were subunits of V(1). We also isolated the V(o)V(1) operon, containing nine genes in the order of atpG-I-L-E-X-F-A-B-D, which encoded proteins with molecular sizes of 13, 43, 10, 20, 35, 11, 64, 53, and 25 kDa, respectively. The last four genes were identified as those for V(1) subunits; atpA, B, D, and F encoded the A, B, gamma, and delta subunits, respectively. The first five genes, atpG-atpX, were identified as genes for the V(o) subunits. The product of atpL, the proteolipid subunit, lacked a 19-amino acid presequence and, unlike V-type ATPases, contained two membrane-spanning domains rather than four. The hydrophobic 43-kDa product of atpI is the smallest member so far found of the eukaryotic 100-kDa subunit family. Its electrophoretic band overlapped with the band of the A subunit. Therefore, all the gene products were found in our purified V(o)V(1). We isolated the A(3)B(3) subcomplex reconstituted from the isolated subunits and the A(3)B(3)gamma subcomplex from subunit-expressing Escherichia coli. Electron microscopic observation of these subcomplexes revealed that the gamma subunit of V(1) filled the central cavity of A(3)B(3) and might be central subunit, similar to the gamma subunit of F(1)-ATPase.     

Subunit analysis of latent and non-latent F1-ATPase from Micrococcus lysodeikticus (luteus)

Limited trypsin and chymotrypsin digestions were performed on the latent F1-ATPase from M. lysodeikticus, and subsequent analysis on SDS-polyacrylamide gels revealed subunit profiles with degraded alpha and delta subunits similar to those of ATPase preparations with spontaneously occurring lower degrees of latency. The ATPase obtained from M. lysodeikticus membranes after n-butanol extraction was also non-latent with similar SDS-gel patterns to the aforementioned ATPases. In addition, the sensitive technique of crossed immunoelectrophoresis was used to show that all of the above ATPases contained alpha, beta, gamma, delta and epsilon subunits but some of them were in degraded forms. Although the delta subunit was the first to be cleaved, the loss of latency can be attributed to the degradation of the alpha subunit.     

Monoclonal antibody modification of the ATPase activity of Escherichia coli F1 ATPase

Monoclonal antibodies (mAbs) have been made against each of the five subunits of ECF1 (alpha, beta, gamma, delta, and epsilon), and these have been used in topology studies and for examination of the role of individual subunits in the functioning of the enzyme. All of the mAbs obtained reacted with ECF1, while several failed to react with ECF1F0, including three mAbs against the gamma subunit (gamma II, gamma III, and gamma IV), one mAb against delta, and two mAbs against epsilon (epsilon I and epsilon II). These topology data are consistent with the gamma, delta, and epsilon subunits being located at the interface between the F1 and F0 parts of the complex. Two forms of ECF1 were used to study the effects of mAbs on the ATPase activity of the enzyme: ECF1 with the epsilon subunit tightly bound and acting to inhibit activity and ECF1* in which the delta and epsilon subunits had been removed by organic solvent treatment. ECF1* had an ATPase activity under standard conditions of 93 mumol of ATP hydrolyzed min-1 mg-1, cf. an activity of 7.5 units mg-1 for our standard ECF1 preparation and 64 units mg-1 for enzyme in which the epsilon subunit had been removed by trypsin treatment. The protease digestion of ECF1* reduced activity to 64 units mg-1 in a complicated process involving an inhibition of activity by cleavage of the alpha subunit, activation by cleavage of gamma, and inhibition with cleavage of the beta subunit. mAbs to the gamma subunit, gamma II and gamma III, activated ECF1 by 4.4- and 2.4-fold, respectively, by changing the affinity of the enzyme for the epsilon subunit, as evidenced by density gradient centrifugation experiments. The gamma-subunit mAbs did not alter the ATPase activity of ECF1*- or trypsin-treated enzyme. The alpha-subunit mAb (alpha I) activated ECF1 by a factor of 2.5-fold and ECF1F0 by 1.3-fold, but inhibited the ATPase activity of ECF1* by 30%.     

Characterization of a membrane-associated ATPase from Methanococcus voltae, a methanogenic member of the Archaea.

A membrane-associated ATPase with an M(r) of approximately 510,000 and containing subunits with M(r)s of 80,000 (alpha), 55,000 (beta), and 25,000 (gamma) was isolated from the methanogen Methanococcus voltae. Enzymatic activity was not affected by vanadate or azide, inhibitors of P- and F1-ATPase, respectively, but was inhibited by nitrate and bafilomycin A1, inhibitors of V1-type ATPases. Since dicyclohexylcarbodiimide inhibited the enzyme when it was present in membranes but not after the ATPase was solubilized, we suggest the presence of membrane-associated component analogous to the F0 and V0 components of both F-type and V-type ATPases. N-terminal amino acid sequence analysis of the alpha subunit showed a higher similarity to ATPases of the V-type family than to those of the F-type family.     

Assembly of a functional F0 of the proton-translocating ATPase of Escherichia coli

We have investigated both structural and functional assembly of the F0 portion of the Escherichia coli proton-translocating ATPase in vivo. Fractionation of E. coli minicells containing plasmids which code for parts of the unc operon shows that each of the F0 peptides a, b, and c insert into the cytoplasmic membrane independent of each other and without the polypeptides which form the F1 portion of the complex alpha, beta, gamma, delta, and epsilon. Assays of membrane energization indicate that, while formation of a functional proton channel requires the presence of all three F0 polypeptides a, b and c, they are not sufficient. Synthesis of both the alpha and beta subunits of the F1 are required for formation of a functional proton channel.     

The epsilon subunit of bacterial and chloroplast F(1)F(0) ATPases. Structure, arrangement, and role of the epsilon subunit in energy coupling within the complex

Recent studies show that the epsilon subunit of bacterial and chloroplast F(1)F(0) ATPases is a component of the central stalk that links the F(1) and F(0) parts. This subunit interacts with alpha, beta and gamma subunits of F(1) and the c subunit ring of F(0). Along with the gamma subunit, epsilon is a part of the rotor that couples events at the three catalytic sites sequentially with proton translocation through the F(0) part. Structural data on the epsilon subunit when separated from the complex and in situ are reviewed, and the functioning of this polypeptide in coupling within the ATP synthase is considered.     

Isolation of genes encoding the Neurospora vacuolar ATPase. Analysis of vma-1 encoding the 67-kDa subunit reveals homology to other ATPases

The vacuolar membrane of Neurospora crassa contains a H+-translocating ATPase composed of at least three subunits with approximate molecular weights of 70,000, 60,000, and 15,000. Both genomic and cDNA clones encoding the largest subunit, which appears to contain the active site of the enzyme, have been isolated and sequenced. The gene for this subunit, designated vma-1, contains six small introns (60-131 base pairs) and encodes a hydrophilic protein of 607 amino acids, Mr 67,121. Within the sequence is a putative nucleotide-binding region, consistent with the proposal that this subunit contains the site of ATP hydrolysis. This 67-kDa polypeptide shows high homology (62% identical residues overall and 84% in the middle of the protein) to the analogous polypeptide of a higher plant vacuolar ATPase. The hypothesis that the vacuolar ATPase is related to F0F1 ATPases is strongly supported by the finding of considerable homology between the 67-kDa subunit of the Neurospora vacuolar ATPase and both the alpha and beta subunits of F0F1 ATPases.     

ATP synthase complex from bovine heart mitochondria. Subunit arrangement as revealed by nearest neighbor analysis and susceptibility to trypsin

The nearest neighbor relationships of bovine mitochondrial H(+)-ATPase subunits were investigated by the chemical cross-linking approach using the homobifunctional cleavable reagents dithiobis(succinimidyl propionate) and disuccinimidyl tartrate. Cross-linked proteins were resolved by one- and two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Individual subunits were detected by silver staining or by Western blotting and staining with subunit-specific antisera. Products larger than 80,000 daltons were not analyzed. Interactions between F1 subunits included cross-links between gamma and delta as well as gamma and epsilon subunits. Among F0 subunit interactions were observed cross-links of (i) coupling factor 6 (F6) with 8-, 20-, and 24-kDa proteins, (ii) oligomycin sensitivity-conferring protein (OSCP) with 24-kDa protein, and (iii) 20-kDa protein with 24-kDa protein. In addition, several cross-links among subunits involving F1 and F0 sectors were detected. These included cross-links between F6 and alpha, F6 and gamma, OSCP and alpha/beta, and 24-kDa protein and alpha/beta. Thus, OSCP, F6, and the 24-kDa protein were found to form cross-links with both F1 and F0 subunits. The surface accessibility of F0 subunits was investigated by subjecting aliquots of F0 to trypsin treatment. Our data demonstrated that the rate of degradation was in the order OSCP greater than 24-kDa protein greater than or equal to F6 greater than subunit 6. The degradation of subunits of F0 was prevented in intact or reconstituted F1-F0. Based on our present and previously published observations, a model of H(+)-ATPase has been proposed wherein OSCP, F6, and the 24-kDa protein are placed in the stalk region and the alpha and beta subunits of F1-ATPase have been extended down to the membrane surface to enclose the stalk segment.     

The epsilon subunit of Escherichia coli coupling factor 1 is required for its binding to the cytoplasmic membrane.

The coupling factor, F1-ATPase of Escherichia coli (ECF1) contains five different subunits, alpha, beta, gamma, delta, and epsilon. Properties of delta-deficient ECF1 have previously been described. F1-ATPase containing only the alpha, beta, and gamma subunits was prepared from E. coli by passage of delta-deficient ECF1 through an affinity column containing immobilized antibodies to the epsilon subunit. The delta, epsilon-deficient enzyme has normal ATPase activity but cannot bind to ECF1-depleted membrane vesicles. Both the delta and epsilon subunits are required for the binding of delta, epsilon-deficient ECF1 to membranes and the restoration of oxidative phosphorylation. Either delta or epsilon will bind to the deficient enzyme to form a four-subunit complex. Neither four-subunit enzyme binds to depleted membranes. The epsilon subunit, does, however, slightly improve the binding affinity between delta and delta-deficient enzyme suggesting a possible interaction between the two subunits. Neither subunit binds to trypsin-treated ECF1, which contains only the alpha and beta subunits. A role for gamma in the binding of epsilon to F1 is suggested. epsilon does not bind to ECF1-depleted membranes. Therefore, the in vitro reconstitution of depleted membranes requires an initial complex formation between epsilon and the rest of ECF1 prior to membrane attachment. Reconstitution experiments indicate that only one epsilon is required per functional ECF1 molecule.     

Complementation in vitro of mutant and wild-type ATPase of Escherichia coli using isolated subunits.

1. The inactive ATPases of four different mutant strains of Escherichia coli have been purified to homogeneity. 2. Molecular weights, subunit patterns in sodium dodecylsulfate electrophoresis and immunological properties of mutant and wild-type proteins are identical. The mutant enzymes compete with the wild-type enzyme for the binding sites on the membrane. 3. On freezing and thawing in salt solutions, the ATPase is split into subunits IA (alpha, gamma, epsilon), IB (delta; alpha, gamma, epsilon), and II (beta). By complementation in vitro of the isolated subunits, it is shown that subcomplex IA (alpha, gamma, epsilon) is altered in the mutant strains described here.     

Role of the subunits of the energy-transducing adenosine triphosphatase from Micrococcus lysodeikticus membranes studied by proteolytic digestion and immunological approaches.

An energy-transducing adenosine triphosphatase (ATPase, EC 3.6.1.3) that contains an extra polypeptide (delta) as well as three intrinsic subunits (alpha, beta, gamma) was purified from Micrococcus lysodeikticus membranes. The apparent subunit stoichiometry of this soluble ATPase complex is alpha 3 beta 3 gamma delta. The functional role of the subunits was studied by correlating subunit sensitivity to trypsin and effect of antibodies raised against holo-ATPase and its alpha, beta and gamma subunits with changes in ATPase activity and ATPase rebinding to membranes. A form of the ATPase with the subunit proportions 1.67(alpha):3.00(beta:0.17(gamma) was isolated after trypsin treatment of purified ATPase. This form has more than twice the specific activity of native enzyme. Other forms with less relative proportion of alpha subunits and absence of gamma subunit are not active. Of the antisera to subunits, only anti-(beta-subunit) serum shows a slight inhibitory effect on ATPase activity, but its combination with either anti-(alpha-subunit) or anti-(gamma-subunit) serum increases the effect. The results suggest that beta subunit is required for full ATPase activity, although a minor proportion of alpha and perhaps gamma subunit(s) is also required, probably to impart an active conformation to the protein. The additional polypeptide not hitherto described in Micrococcus lysodeikticus ATPase had a molecular weight of 20 000 and was found to be involved in ATPase binding to membranes. This 20 000-dalton component can be equated with the delta subunit of other energy-transducing ATPases and its association with the (alpha, beta, gamma) M. lysodeikticus ATPase complex appears to be dependent on bivalent cations. The present results do not preclude the possibility that the gamma subunit also plays a role in ATPase binding, in which, however, the major subunits do not seem to play a role.     

Reconstitution of adenosine triphosphatase of thermophilic bacterium from purified individual subunits.

1. Five subunits (alpha, beta, gamma, delta, and epsilon) of an ATPase from a thermophilic bacterium PS3 were purified in the presence of 8 M urea by ion exchange chromatography. Then the ATPase activity was reconstituted by mixing the subunit solutions and incubating them at 20-45 degrees, at pH 6.3 to 7.0. 2. Mixtures containing beta + gamma or alpha + beta + delta regained ATP-hydrolyzing activity, but mixtures of alpha + beta and beta + delta did not. Combinations not including beta were all inactive. 3. The ATPase activity reconstituted from alpha + beta + delta was thermolabile and insensitive to NaN3, whereas the activities obtained from mixtures containing beta and gamma were thermostable and sensitive to NaN3, like the native ATPase. 4. The assemblies containing both beta and gamma subunits had the same mobility as the native ATPase molecule on gel electrophoresis, those without the gamma subunit moved more rapidly toward the anode. 5. Subunits epsilon and delta did not inhibit the ATPase activity of either the assembly (alpha + beta + gamma) or the native ATPase.     

Large-scale purification and characterization of the five subunits of F1-ATPase from pig heart mitochondria.

A large-scale purification procedure was developed to isolate the five subunits of F1-ATPase from pig heart mitochondria. The previously described procedure (Williams, N. and Pedersen, P.L. (1986) Methods Enzymol. 126, 484-489) to dissociate the rat liver F1-ATPase by cold treatment followed by warming at 37 degrees C has been adapted for the pig heart enzyme. Removal of endogenous nucleotides from that enzyme before dissociation led to the efficient separation of the alpha and gamma subunits from beta, delta and epsilon subunits. The beta subunit was purified in the hundred-milligram range by anion-exchange chromatography in the absence of any denaturing agent. This subunit was free from any bound nucleotide and almost no ATPase and adenylate kinase-like activities were detected. The delta and epsilon subunits were purified by reversed-phase chromatography (RP-HPLC) in the milligram range. As recently reported (Penin, F., Deléage, G., Gagliardi, D., Roux, B. and Gautheron, D.C. (1990) Biochemistry 29, 9358-9364), these purified subunits kept biophysical features of folded proteins and their ability to reconstitute the tight delta epsilon complex. The alpha and gamma subunits remained poorly soluble and required dissociation by 8 M guanidinium chloride prior to their purification by RP-HPLC. In addition, characterizations of the five subunits by IEF and SDS-polyacrylamide gel electrophoresis are reported, as well as ultraviolet spectra and solubility properties of the beta, delta and epsilon subunits.