The membrane-associated ATPase from Sulfolobus acidocaldarius is distantly related to F1-ATPase as assessed from the primary structure of its alpha-subunit

Isolation of novel membrane-associated ATPases, presumably soluble parts of the H+-ATPases, from archaebacteria has been recently reported, and their properties were found to be significantly different from the usual F1-ATPase. In order to assess the relationship of the archaebacterial ATPases to the F1-ATPases and other known ATPases, the amino acid sequence of the alpha subunit of the ATPase from Sulfolobus acidocaldarius, an acidothermophilic archaebacterium, was compared with the sequences of other ATPases. The gene encoding its alpha subunit was cloned from the genomic library of S. acidocaldarius, and the nucleotide sequence was determined. The 591-amino acid sequence deduced from the nucleotide sequence contains a small number of short stretches that shows sequence similarity to the alpha and beta subunits of F1-ATPase. However, the overall similarity is too weak to consider it to be a typical member of the F1-ATPase family when the highly conserved sequences of the F1-ATPase subunits among various organisms are taken into account. Moreover, most of these stretches overlap the consensus sequences that are commonly found in some nucleotide-binding proteins. There is no significant sequence similarity to the ion-translocating ATPases, which form phosphorylated intermediates, such as animal Na+,K+-ATPases. Thus, the S. acidocaldarius ATPase and probably other archaebacterial ATPases also appear to belong to a new group of ion-translocating ATPases that has only a distant relationship to F1-ATPase.     

Structure of an ATPase operon of an acidothermophilic archaebacterium, Sulfolobus acidocaldarius

The nucleotide sequence of the operon of the ATPase complex of an acidothermophilic archaebacterium, Sulfolobus acidocaldarius, has been determined. In addition to the three previously reported genes for the alpha, beta, and c (proteolipid) subunits of the ATPase complex (Denda, K., Konishi, J., Oshima, T., Date, T., and Yoshida, M. (1989) J. Biol. Chem. 264, 7119-7121), the operon contained three other genes encoding hydrophilic proteins with molecular masses 25, 13, and 7 kDa. The 25-kDa protein is the third largest subunit (gamma), the 13-kDa protein is most likely the fourth subunit (delta), and the 7-kDa protein may correspond to an unknown subunit of the ATPase, tentatively named as epsilon subunit. They do not have significant sequence similarity to subunits in F0F1-ATPases and eukaryotic V-type ATPases, whereas the other three subunits, alpha, beta, and c, have homologous counterparts in F0F1- and V-type ATPases. The order of the genes in the operon was delta alpha beta gamma epsilon c. The S. acidocaldarius ATPase operon differed from the eucabacterial F0F1-ATPase operon in that the former contains only one gene for a hydrophobic subunit at the most downstream part of the operon whereas the latter has three hydrophobic F0 genes preceding five hydrophilic F1 genes.     

Amino acid sequence of the alpha and beta subunits of Methanosarcina barkeri ATPase deduced from cloned genes. Similarity to subunits of eukaryotic vacuolar and F0F1-ATPases

The atpA and atpB genes coding for the alpha and beta subunits, respectively, of membrane ATPase were cloned from a methanogen Methanosarcina barkeri, and the amino acid sequences of the two subunits were deduced from the nucleotide sequences. The methanogenic alpha (578 amino acid residues) and beta (459 amino acid residues) subunits were highly homologous to the large and small subunits, respectively, of vacuolar H+-ATPases; 52% of the residues of the methanogenic alpha subunit were identical with those of the large subunit of vacuolar enzyme of carrot or Neurospora crassa, respectively, and 59, 60, and 59% of the residues of the methanogenic beta subunit were identical with those of the small subunits of N. crassa, Arabidopsis thaliana, and Sacharomyces cerevisiae, respectively. The methanogenic subunits were also highly homologous to the corresponding subunits of Sulfolobus acidocaldarius ATPase. The methanogenic alpha and beta subunits showed 22 and 24% identities with the beta and the alpha subunits of Escherichia coli F1, respectively. Furthermore, important amino acid residues identified genetically in the E. coli enzyme were conserved in the methanogenic enzyme. This sequence conservation suggests that vacuolar, F1, methanogenic, and S. acidocaldarius ATPases were derived from a common ancestral enzyme.     

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.     

Archaebacterial ATPase: studies on subunit composition and quaternary structure of the F1-analogous ATPase from Sulfolobus acidocaldarius

A modified procedure for the purification of soluble ATPase from the thermoacidophilic archaebacterium Sulfolobus acidocaldarius is described. In addition to (alpha) 65 and (beta) 51 kDa polypeptides, further subunits gamma * (20 kDa) and delta * (12 kDa) are demonstrated to be components of the enzyme, exhibiting a total molecular mass of 380 kDa. Molecular electron microscopic images of the native enzyme indicate a quaternary structure probably formed by the gamma *, delta *-complex as a central mass surrounded by a pseudohexagon of the peripherally arranged larger alpha and beta subunits. As can be derived from both molecular mass and electron microscopy data, the archaebacterial Sulfolobus-ATPase emerges to exist as an alpha 3 beta 3-quaternary structure with respect to the larger subunits. This is normally found in typical F1-ATPases of eubacterial and eukaryotic organisms. Therefore it is postulated that F1- and F0F1-ATPases, respectively, can occur ubiquitously in all urkingdoms of organisms as functional units of energy-transducing membranes.     

Purification and properties of the ATPase solubilized from membranes of an acidothermophilic archaebacterium, Sulfolobus acidocaldarius

A novel ATPase was solubilized from membranes of an acidothermophilic archaebacterium, Sulfolobus acidocaldarius, with low ionic strength buffer containing EDTA. The enzyme was purified to homogeneity by hydrophobic chromatography and gel filtration. The molecular weight of the purified enzyme was estimated to be 360,000. Polyacrylamide gel electrophoresis of the purified enzyme in the presence of sodium dodecyl sulfate revealed that it consisted of three kinds of subunits, alpha, beta, and gamma, whose molecular weights were approximately 69,000, 54,000, and 28,000, respectively, and the most probable subunit stoichiometry was alpha 3 beta 3 gamma 1. The purified ATPase hydrolyzed ATP, GTP, ITP, and CTP but not UTP, ADP, AMP, or p-nitrophenylphosphate. The enzyme was highly heat stable and showed an optimal temperature of 85 degrees C. It showed an optimal pH of around 5, very little activity at neutral pH, and another small activity peak at pH 8.5. The ATPase activity was significantly stimulated by bisulfite and bicarbonate ions, the optimal pH remaining unchanged. The Lineweaver-Burk plot was linear, and the Km for ATP and the Vmax were estimated to be 1.6 mM and 13 mumol Pi.mg.-1.min-1, respectively, at pH 5.2 at 60 degrees C in the presence of bisulfite. The chemical modification reagent, 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole, caused inactivation of the ATPase activity although the enzyme was not inhibited by N,N'-dicyclohexylcarbodiimide, N-ethyl-maleimide, azide or vanadate. These results suggest that the ATPase purified from membranes of S. acidocaldarius resembles other archaebacterial ATPases, although a counterpart of the gamma subunit has not been found in the latter. The relationship of the S. acidocaldarius ATPase to other ion-transporting ATPases, such as F0F1 type or E1E2 type ATPases, was discussed.     

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.     

A gene encoding the proteolipid subunit of Sulfolobus acidocaldarius ATPase complex

An analysis of genes for the major two subunits of the membrane-associated ATPase from an acidothermophilic archaebacterium, Sulfolobus acidocaldarius, suggested that it belongs to a different ATPase family from the F1-ATPase (Denda, K., Konishi, J., Oshima, T., Date, T., and Yoshida, M. (1988) J. Biol. Chem. 263, 17251-17254). In the same operon of the above two genes we found a gene encoding a very hydrophobic protein of 101 amino acids (Mr = 10,362). A proteolipid was purified from the membranes of this bacteria in which partial amino acid sequences matched with the sequence deduced from the gene. Significant amino acid sequence homology and a similar hydropathy profile appeared when the sequence was compared with the 8-kDa proteolipid subunit of F0F1-ATPases. It is about 30 amino acids larger than the 8-kDa proteolipid and has a small (11-amino acid) repeat sequence. However, it is distinct from the 16-kDa proteolipid subunit of an eukaryotic vacuolar H+-ATPase (Mandel, M., Moriyama, Y., Hulmes, J.D., Pan, Y.-E., Nelson, H., and Nelson, N. (1988) Proc. Natl. Acad. Sci. U.S.A. 85,5521-5524).     

Subunit composition of the H+-ATPase complex from anaerobic bacterium Lactobacillus casei

The H+-ATPase complex has been isolated from the membranes of the anaerobic bacterium Lactobacillus casei by two independent methods. 1. The crossed-immunoelectrophoresis of the 14C-labelled ATPase complex against antibodies to a highly purified soluble ATPase has been used. The subunit composition of the complex has been established by autoradiography. The soluble part of L. casei ATPase, in contrast to coupling factor F1-ATPases of aerobic bacteria, chloroplasts and mitochondria which include two kinds of large subunit (alpha and beta), consists of one kind of large subunit with a molecular mass of 43 kDa. Moreover, a minor polypeptide of 25 kDa has been found in the soluble ATPase. Factor F0 of L. casei ATPase complex consists of a 16-kDa subunit and two subunits with molecular masses less than 14 kDa. 2. A dicyclohexylcarbodiimide-sensitive ATPase complex has been isolated from L. casei membranes by treating them with a mixture of octyl glucoside and sodium cholate. The complex, purified by centrifugation on a sucrose density gradient, contains the main subunits with molecular masses of 43 kDa, 25 kDa and 16 kDa and a dicyclohexylcarbodiimide-binding subunit with a molecular mass less than 14 kDa.     

The ATP synthase of Halobacterium salinarium (halobium) is an archaebacterial type as revealed from the amino acid sequences of its two major subunits.

The head piece of the A-type ATP synthase in an extremely halophilic archaebacterium, namely Halobacterium salinarium (halobium), is composed of two kinds of subunit, alpha and beta, and is associated with ATP-hydrolyzing activity. The genes encoding these subunits with hydrolytic activity have been cloned and sequenced. The putative amino acid sequences of the alpha and beta subunits deduced from the nucleotide sequences of the genomic DNA consist of 585 and 471 residues, respectively. The amino acid sequence of the alpha subunit of the halobacterial ATPase is 63 and 49% identical to the alpha subunits of ATPases from two other archaebacteria, Methanosarcina barkeri and Sulfolobus acidocaldarius, respectively. The sequence of the beta subunit is 66 and 55% identical to the beta subunits from these respective organisms. The homology between the alpha and beta subunits is around 30%. In contrast, the sequences of the halobacterial ATPase is less than 30% identical to F1 ATPase when any combination of subunits is considered. However, they are greater than 50% identical to a eukaryotic vacuolar ATPase when alpha and a, beta and b combinations are considered. These data fully confirm the first demonstration of this kind of relationship which was achieved by immunoblotting with an antibody raised against the halobacterial ATPase. We concluded that the archaebacterial ATP synthase is an A-type and not an F-type ATPase. This classification is also demonstrated by a "rooted" phylogenetic tree where halobacteria locate close to other archaebacteria and eukaryotes and distant from eubacteria.     

Specific labelling of the (Ca2+ + Mg2+)-ATPase of Escherichia coli with 8-azido-ATP and 4-chloro-7-nitrobenzofurazan.

1. 8-Azido-ATP is a substrate for Escherichia coli (Ca2+ + Mg2+)-ATPase (E. coli F1). 2. Illumination of E. coli F1 in the presence of 8-azido-ATP causes inhibition of ATPase activity. The presence of ATP during illumination prevents inhibition. 3. 8-Azido-ATP and 4-chloro-7-nitrobenzofurazan (NbfCl) bind predominantly to the alpha subunit of the enzyme, but also significantly to the beta subunit. 4. The alpha subunit of E. coli F1 seems to have some properties that in other F1-ATPases are associated with the beta subunit.     

Archaebacterial ATPases: relationship to other ion-translocating ATPase families examined in terms of immunological cross-reactivity

Immunological cross-reactivity among three types of H(+)-ATPases, that is, three archaebacterial ATPases, the F1-ATPase from thermophilic bacterium PS3 (TF1) and the vacuolar membrane ATPase from Saccharomyces cerevisiae, was examined by means of immunoblot analyses. The three archaebacterial ATPases were very similar in immunological cross-reactivity, suggesting that they belong to the same family of ATPases. Cross-reaction was also observed between the ATPase from Sulfolobus acidocaldarius, one of the three archaebacteria, and TF1. S. cerevisiae vacuolar ATPase reacted with the antibodies prepared against each of the three archaebacterial ATPases, but did not react with the antibody against TF1. Electron microscopic examination revealed that the oligomeric structure of Sulfolobus ATPase was very similar to that of F1-ATPase. These results, taken together, suggest that the archaebacterial ATPases share close structural similarities with the vacuolar ATPases, and, to a lesser degree, with the F0F1-ATPases.     

A homologous sequence between H+-ATPase (F0F1) and cation-transporting ATPases. Thr-285----Asp replacement in the beta subunit of Escherichia coli F1 changes its catalytic properties

A sequence of 10 amino acids (I-C-S-D-K-T-G-T-L-T) of ion motive ATPases such as Na+/K+-ATPase is similar to the sequence of the beta subunit of H+-ATPases, including that of Escherichia coli (I-T-S-T-K-T-G-S-I-T) (residues 282-291). The Asp (D) residue phosphorylated in ion motive ATPase corresponds to Thr (T) of the beta subunit. This substitution may be reasonable because there is no phosphoenzyme intermediate in the catalytic cycle of F1-ATPase. We replaced Thr-285 of the beta subunit by an Asp residue by in vitro mutagenesis and reconstituted the alpha beta gamma complex from the mutant (or wild-type) beta and wild-type alpha and gamma subunits. The uni- and multisite ATPase activities of the alpha beta gamma complex with mutant beta subunits were about 20 and 30% of those with the wild-type subunit. The rate of ATP binding (k1) of the mutant complex under uni-site conditions was about 10-fold less than that of the wild-type complex. These results suggest that Thr-285, or the region in its vicinity, is essential for normal catalysis of the H+-ATPase. The mutant complex could not form a phosphoenzyme under the conditions where the H+/K+-ATPase is phosphorylated, suggesting that another residue(s) may also be involved in formation of the intermediate in ion motive ATPase. The wild-type alpha beta gamma complex had slightly different kinetic properties from the wild-type F1, possibly because it did not contain the epsilon subunit.     

The plasma membrane ATPase of the thermoacidophilic archaebacterium Sulfolobus acidocaldarius. Purification and immunological relationships to F1-ATPases

The plasma-membrane-associated ATPase of the thermoacidophilic archaebacterium Sulfolobus acidocaldarius characterized in a previous work [M. Lübben & G. Sch?fer (1987) Eur. J. Biochem. 164, 533-540] has been solubilized. It can be easily removed from the membrane by mild treatment with zwitterionic detergents, therefore it appears to be a peripheral membrane protein analogous to the soluble F1-ATPase of eubacteria and eukaryotes. Further purification has been achieved by subsequent gel permeation and ion-exchange chromatography. The final purity is greater than 70% as judged by staining intensities after SDS/polyacrylamide gel electrophoresis. The ATPase consists of two major polypeptides of 65 kDa (alpha) and 51 kDa (beta) in comparable quantities; a minor band (20 kDa) is assumed to be a contaminant or a constitutive part of the enzyme, possibly copurified in substoichiometric amount. The native molecular mass of the solubilized ATPase determined by gel permeation is 430 kDa. Considering the precision of these methods, it remains open whether a 3:3 stoichiometry reflects the contribution of alpha and beta subunits to the quaternary structure, in analogy to known F1-ATPases. The catalytic properties resemble those of the membrane-bound state. There are two pH optima at 5.3 and 8.0 in the absence and only one optimum at 6.5 in the presence of the activating anion sulfite. Activity is strictly dependent on the divalent cations Mg2+ or Mn2+. ATP and dATP are hydrolyzed with highest rates; also other purine and pyrimidine nucleotides are cleaved significantly, but not ADP, pyrophosphate and p-nitrophenyl phosphate. The ATPase is insensitive to azide or vanadate but is inhibited by relatively low concentrations of nitrate. Polyclonal antisera have been raised against the beta subunit of the Sulfolobus ATPase. Cross-reactivities with cellular or membrane extracts of a number of archaebacteria, eubacteria and chloroplasts have been analyzed by means of Western blotting and immunodecoration. A strong cross-reactivity with other genera of the Sulfolobales is observed, also with Methanobacterium, Methanosarcina, Methanolobus and Halobacterium. Even membranes of the eubacterium Escherichia coli and of eukaryotic chloroplast react with the antibodies. With one exception, in all cases the molecular mass of the cross-reacting polypeptide falls in the range of 51-56 kDa. Only in Halobacterium halobium, bands at 66 and 68 kDa have been detected. In order to identify the cross-reacting polypeptides, the purified F1-ATPases of E. coli, chloroplasts and beef heart mitochondria have been tested.(ABSTRACT TRUNCATED AT 400 WORDS)     

Altered expression of the H+ ATPase in Streptococcus faecalis membranes

Evidence is presented that expression of the H+ ATPase in S. faecalis is influenced by the extracellular pH and K+ level during growth. Altered expression was detected by assay of F1 ATPase and electrophoretic analysis of membrane proteins. K+-limited growth caused about a 2-fold increase in the F1 ATPase. The effect of growth at pH 6, 7 and 9 was studied. Compared to cells grown at pH 7, growth at pH 6 increased the F1 ATPase about 2-fold while growth at pH 9 reduced the F1 ATPase by nearly 4-fold. The elevated F1 ATPase activity in the pH 6 cells was associated with an increase in the F1 ATPase alpha and beta subunits in the membrane while the decrease in F1 ATPase in the pH 9 cells was associated with a marked loss of the alpha subunit. It is suggested that intracellular protons may act as effectors which regulate expression of the F1F0 gene cluster at the level of translation.     

Monoclonal Antibodies to the [alpha]- and [beta]-Subunits of the Plant Mitochondrial F1-ATPase

We have generated nine monoclonal antibodies against subunits of the maize (Zea mays L.) mitochondrial F1-ATPase. These monoclonal antibodies were generated by immunizing mice against maize mitochondrial fractions and randomly collecting useful hybridomas. To prove that these monoclonal antibodies were directed against ATPase subunits, we tested their cross-reactivity with purified F1-ATPase from pea cotyledon mitochondria. One of the antibodies ([alpha]-ATPaseD) cross-reacted with the pea F1-ATPase [alpha]-subunit and two ([beta]-ATPaseD and [beta]-ATPaseE) cross-reacted with the pea F1-ATPase [beta]-subunit. This established that, of the nine antibodies, four react with the maize [alpha]-ATPase subunit and the other five react with the maize [beta]-ATPase subunit. Most of the monoclonal antibodies cross-react with the F1-ATPase from a wide range of plant species. Each of the four monoclonal antibodies raised against the [alpha]-subunit recognizes a different epitope. Of the five [beta]-subunit antibodies, at least three different epitopes are recognized. Direct incubation of the monoclonal antibodies with the F1-ATPase failed to inhibit the ATPase activity. The monoclonal antibodies [alpha]-ATPaseD and [beta]-ATPaseD were bound to epoxide-glass QuantAffinity beads and incubated with a purified preparation of pea F1-ATPase. The ATPase activity was not inhibited when the antibodies bound the ATPase. The antibodies were used to help map the pea F1-ATPase subunits on a two-dimensional map of whole pea cotyledon mitochondrial protein. In addition, the antibodies have revealed antigenic similarities between various isoforms observed for the [alpha]- and [beta]-subunits of the purified F1-ATPase. The specificity of these monoclonal antibodies, along with their cross-species recognition and their ability to bind the F1-ATPase without inhibiting enzymic function, makes these antibodies useful and invaluable tools for the further purification and characterization of plant mitochondrial F1-ATPases.     

Gene structure of Enterococcus hirae (Streptococcus faecalis) F1F0-ATPase, which functions as a regulator of cytoplasmic pH.

Enterococcus hirae (formerly Streptococcus faecalis) ATCC 9790 has an F1F0-ATPase which functions as a regulator of the cytoplasmic pH but does not synthesize ATP. We isolated four clones which contained genes for c, b, delta, and alpha subunits of this enzyme but not for other subunit genes. It was revealed that two specific regions (upstream of the c-subunit gene and downstream of the gamma-subunit gene) were lost at a specific site in the clones we isolated, suggesting that these regions were unstable in Escherichia coli. The deleted regions were amplified by polymerase chain reaction, and the nucleotide sequences of these regions were determined. The results showed that eight genes for a, c, b, delta, alpha, gamma, beta, and epsilon subunits were present in this order. Northern (RNA) blot analysis showed that these eight genes were transcribed to one mRNA. The i gene was not found in the upper region of the a-subunit gene. Instead of the i gene, this operon contained a long untranslated region (240 bp) whose G + C content was only 30%. There was no typical promoter sequence such as was proposed for E. coli, suggesting that the promoter structure of this species is different from that of E. coli. Deduced amino acid sequences suggested that E. hirae H(+)-ATPase is a typical F1F0-type ATPase but that its gene structure is not identical to that of other bacterial F1F0-ATPases.     

A mutation in the alpha-subunit of F1-ATPase from Escherichia coli affects the binding of F1 to the membrane

The mutation Gly-29----Asp in the alpha-subunit of the F1-ATPase from Escherichia coli was characterized and shown to cause the following effects. 1) Oxidative phosphorylation was markedly impaired in vivo 2) Membrane ATPase and ATP-driven proton-pumping activities were decreased markedly. 3) Membranes were proton-permeable, and membrane-bound ATPase was dicyclohexylcarbodiimide-insensitive. Therefore, it appeared that integration between F1 and F0 was abnormal. This was confirmed directly by the demonstration that the mutant F1 bound poorly to stripped membranes from a normal strain. Purified, soluble mutant F1 had normal ATPase activity. These results suggest that residue Gly-29, which is strongly conserved in alpha-subunits of F1-ATPases, lies in a region of the alpha-subunit important for membrane binding. Thus, three regions of the F1-alpha-subunit have now been recognized, specialized for membrane binding, nucleotide binding, and alpha/beta intersubunit signal transmission, respectively. The approximate locations of the three regions are described.     

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)     

Isolation of the structural genes for the alpha and beta subunits of the mitochondrial ATPase from the fission yeast Schizosaccharomyces pombe

The structural genes for the two major subunits of the mitochondrial ATPase were isolated among genomic clones from the yeast Schizosaccharomyces pombe by transformation and complementation of mutants unable to grow on glycerol and lacking either the alpha or the beta subunits. The plasmid pMa1 containing a 2.3-kilobase genomic insert transformed the mutant A23-13 lacking a detectable alpha subunit. The transformant grew on glycerol and contained an alpha subunit of normal electrophoretic mobility. The plasmid pMa2 containing a 5.4-kilobase genomic insert transformed the mutant B59-1 lacking the beta subunit. The transformant grew on glycerol and contained a beta subunit of normal mobility. The structural gene for the beta ATPase subunit for the fission yeast S. pombe was localized within the pMa2 insert by hybridization to a probe containing the beta ATPase gene from the budding yeast Saccharomyces cerevisiae (Saltzgaber, J., Kunapuli, S., and Douglas, M. G. (1983) J. Biol. Chem. 258, 11465-11470). The mRNAs which hybridized to pMa1 and pMa2 were translated by a reticulocyte lysate into polypeptides of Mr = 59,000 and 54,000, respectively. These genes products reacted with an anti-F1-ATPase serum and therefore correspond most probably to precursors of the alpha and beta subunits.