Mutations in the conserved proline 43 residue of the uncE protein (subunit c) of Escherichia coli F1F0-ATPase alter the coupling of F1 to F0

The conserved Pro43 residue of the uncE protein (subunit c) of the Escherichia coli F1F0-ATPase was changed to Ser or Ala by oligonucleotide-directed mutagenesis, and the mutations were incorporated into the chromosome. The resultant mutant strains were capable of oxidative phosphorylation as indicated by their ability to grow on succinate and had growth yields on glucose that were 80-90% of wild type. Membrane vesicles from the mutants were slightly less efficient than wild type vesicles in ATP-driven proton pumping as indicated by ATP-dependent quenching of quinacrine fluorescence. The decreased quenching response was not due to increased H+ leakiness of the mutant membranes or to loss of F1-ATPase activity from the membrane. These results indicate that the mutant F1F0-ATPases are defective in coupling ATP hydrolysis to H+ translocation. The membrane ATPase activity of the mutants was inhibited less by dicyclohexylcarbodiimide than that of wild type. The decrease in sensitivity to inhibition by dicyclohexylcarbodiimide was caused primarily by dissociation of the F1-ATPase from the mutant F0 in the ATPase assay mixture. These results support the idea that Pro43, and neighboring conserved polar residues play an important role in the binding and functional coupling of F1 to F0. Although a Pro residue is found at position 43 in all species of subunit c studied, surprisingly, it is not absolutely essential to function.     

H+-ATPase of Escherichia coli. An uncE mutation impairing coupling between F1 and Fo but not Fo-mediated H+ translocation

The uncE114 mutation from Escherichia coli strain KI1 (Nieuwenhuis, F. J. R. M., Kanner, B. I., Gutnick, D. L., Postma, P. W., and Van Dam, K. (1973) Biochim. Biophys. Acta 325, 62-71) was characterized after transfer to a new genetic background. A defective H+-ATPase complex is formed in strains carrying the mutation. Based upon the genetic complementation pattern of other unc mutants by a lambda uncE114 transducing phage, and complementation of uncE114 recipients by an uncE+ plasmid (pCP35), the mutation was concluded to lie in the uncE gene. The uncE gene codes for the omega subunit ("dicyclohexylcarbodiimide binding protein") of the H+-ATPase complex. The mutation was defined by sequencing the mutant gene. The G----C transversion found results in a substitution of Glu for Gln at position 42 of the omega subunit in the Fo sector of the H+-ATPase. The substitution did not significantly impair H+ translocation by Fo or affect inhibition of H+ translocation by dicyclohexylcarbodiimide. Wild-type F1 was bound by uncE114 Fo with near normal affinity, but the functional coupling between F1 and Fo was disrupted. The uncoupling was indicated by an H+-leaky membrane, even when saturating levels of wild-type F1 were bound. Disassociation of F1 from Fo under conditions of assay did partially contribute to the H+ leakiness, but the major contributor to the high H+ conductance was Fo with bound F1. The F1 bound to uncE114 membranes exhibited normal ATPase activity, but ATP hydrolysis was uncoupled from H+ translocation and was resistant to inhibition by dicyclohexylcarbodiimide. The F1 isolated from the uncE114 mutant was modified with partial loss of coupling function. However, this modification did not account for the uncoupled properties of the mutant Fo described above, since these properties were retained after reconstitution of mutant membrane (Fo) with wild-type F1.     

Mutation of alanine 24 to serine in subunit c of the Escherichia coli F1F0-ATP synthase reduces reactivity of aspartyl 61 with dicyclohexylcarbodiimide.

Dicyclohexylcarbodiimide (DCCD) inhibits the activity of the F1F0-H+ ATP synthase of Escherichia coli by reacting with aspartyl 61 in subunit c of the FO sector to form a stable N-acylurea. The segment of chromosomal DNA which codes the subunits of the FO was cloned from four independently isolated DCCD-resistant mutants, and the sequence of the subunit c gene (uncE) was determined. An Ala24 to serine (A24S) substitution was found in the subunit c gene of each mutant. The A24S uncE gene was cloned into the BamHI site of a mutant derivative of plasmid pBR322. The A24S subunit c conferred DCCD resistance to a variety of recipient E. coli strains when it was overexpressed from this plasmid. A 7-base pair deletion beginning at position 132 of the plasmid vector was responsible for the observed overexpression. Hoppe et al. (Hoppe, J., Schairer, H. U., and Sebald, W. (1980) Eur. J. Biochem. 112, 17-24) had previously shown that mutation of subunit c Ile28 to threonine or valine resulted in DCCD resistance. The DCCD sensitivities of the membrane ATPase of these mutants and the A24S mutant were compared. DCCD sensitivity decreased in the order: wild-type much greater than I27V greater than I28T = A24S. The venturicidin sensitivities of wild-type and mutant membranes were also examined. The membrane ATPase of the I28T and I28V mutants was venturicidin resistant whereas the A24S substitution resulted in a hypersensitivity to inhibition by venturicidin. These results support a model in which subunit c folds in the membrane like a hairpin, where the region of residues 24-28 in transmembrane helix-1 is close to that of aspartyl 61 in transmembrane helix-2.     

The maintenance of the energized membrane state and its relation to active transport in Escherichia coli.

1. An ATPase mutant of Escherichia coli and two partial revertants of that mutant were examined for the ability to generate a high energy membrane state with D-lactate or ATP, as measured by the quenching of the fluorescent dye quinacrine. 2. All three strains showed reductions in the aerobically-driven quenching of fluorescence compared to the wild type, but the reduction could be reversed by the addition of eitherN,N'-dicyclohexylcarbodiimide or the crude soluble ATPase of the wild type. 3. The mutant exhibited a decreased ability to accumulate sugars and amino acids and showed an increased permeability to protons. 4. One partial revertant showed a slight increase in active transport and a slight decrease in proton permeability. 5. The other partial revertant showed a large increase in transport ability and a large decrease in proton permeability. 6. A model is proposed in which the conformation of the Mg-2+-ATPase is important in the utilization of energy derived from the electron transport chain and this function is independent of the catalytic activity of the Mg-2+-ATPase.     

Evidence for coupling between membrane and cytoplasmic domains of the yeast plasma membrane H(+)-ATPase. An analysis of intragenic revertants of pma1-105.

A genetic approach was used to identify interacting portions of the plasma membrane H(+)-ATPase from Saccharomyces cerevisiae. The cellular sensitivity of the pma1-105 strain (S368F) to low external pH and to NH4+ was used to select intragenic revertants of two classes: phenotypically wild-type full revertants and partial revertants that were low pH-resistant but retained resistance to hygromycin B. All 10 full revertants had S368 restored. Among five partial revertants mapping to the original site within the phosphorylation domain, S368L and S368V were each found twice. One revertant contained an E367V substitution adjacent to the original S368F alteration. Four of 13 independently isolated second-site revertants mapped to one site, V289F, in the proposed phosphatase domain. Mutations within the proposed phosphatase and phosphorylation domains resulted in enzymes with increased vanadate sensitivity relative to the vanadate-insensitive S368F enzyme. These results suggest that sites S368, E367, and V289 contribute to a vanadate (Pi) binding domain or are able to interact with such a site within the catalytic domain. The remaining nine partial second-site revertants mapped to six sites within the putative transmembrane regions. Mutations within the transmembrane region had less of an effect on vanadate sensitivity. Most revertant enzymes showed small but significant increases in the rate of ATP hydrolysis relative to the S368F enzyme. Several enzymes no longer displayed the acid-sensitive pH-dependence seen in the S368F enzyme. These data provide novel evidence for an interaction between putative transmembrane helices 1-3 and 7 and the ATP hydrolytic portion of the enzyme.     

Suppression mutations in the defective beta subunit of F1-ATPase from Escherichia coli

The Escherichia coli mutant of the proton-translocating ATPase KF11 (Kanazawa, H., Horiuchi, Y., Takagi, M., Ishino, Y., and Futai, M. (1980) J. Biochem. (Tokyo) 88, 695-703) has a defective beta subunit with serine being replaced by phenylalanine at codon 174. Four suppression mutants (RE10, RE17, RE18, and RE20) from this strain capable of growth on minimal plate agar supplemented by succinate were isolated. The original point mutation at codon 174 was intact in these strains. Additional point mutations, Ala-295 to Thr, Gly-149 to Ser, Leu-400 to Gln, Ala-295 to Pro, for RE10, RE17, RE18, and RE20, respectively, were identified by the polymerase chain reaction and sequencing. These mutations, except for RE10, were confirmed as a single mutation conferring a suppressive phenotype by genetic suppression assay using KF11 as the host cells. The results indicated that Ser-174 has functional interaction with Gly-149, Ala-295, and Leu-400. The residues are located within the previously estimated catalytic domain of the beta subunit, indicating that this domain is indeed folded for the active site of catalytic function. Growth rates of the revertants in the minimal medium with succinate increased compared with that of KF11, showing that ATP synthesis recovered to some extent. The ATP hydrolytic activity in the revertant membranes increased in RE17 and RE20 but did not in RE10 and RE18, suggesting that synthesis and hydrolysis are not necessarily reversible in the proton-translocating ATPase (F1F0).     

Effect of disulfide cross-linking between alpha and delta subunits on the properties of the F1 adenosine triphosphatase of Escherichia coli

Under very mild oxidizing conditions the delta subunit of the F1-ATPase of Escherichia coli can be crosslinked by a disulfide linkage to one of the alpha subunits of the enzyme. The cross-linked ATPase resembles the native enzyme in the following properties: specific activity; activation by lauryldimethylamine N-oxide (LDAO); binding of aurovertin D and ADP; cross-linking products with 3,3'-dithiobis(succinimidyl propionate); binding to ATPase-stripped everted membrane vesicles and the N,N'-dicyclohexylcarbodiimide sensitivity of the rebound enzyme. However, the rebound crosslinked ATPase differed from the native enzyme in lacking the ability to restore NADH oxidation - and ATP hydrolysis-dependent quenching of the fluorescence of quinacrine to ATPase-stripped membrane vesicles. It is proposed that the delta subunit is involved in the proton pathway of the ATPase, and that this pathway is affected in the alpha delta-cross-linked enzyme. The mechanism for activation of the ATPase by LDAO was examined. Evidence against the proposal of L?tscher, H.-R., De Jong, C. and Capaldi, R.A. (Biochemistry (1984) 23, 4140-4143) that activation involves displacement of the epsilon subunit from an active site on a beta subunit was obtained.     

The F1F0-ATPase of Escherichia coli. The substitution of alanine by tyrosine at position 25 in the c-subunit affects function but not assembly

A site-directed mutation in the gene which codes for the c-subunit of the F1F0-ATPase, resulting in the substitution of Ala-25 by Tyr, has been constructed and characterized. A plasmid carrying the mutation was used to transform strain AN943 (uncE429). The resulting strain is unable to grow on succinate as sole carbon source and possesses an uncoupled growth yield. Membranes prepared from the mutant possess low levels of ATPase activity and are proton-impermeable. The F1-ATPase activity was found to be inhibited by 80% when bound to the membrane. When carried on a plasmid, the mutation is dominant in complementation tests with all mutant unc alleles tested and when transformed into wild-type strain AN346, the mutation results in an uncoupled phenotype. A mutant which overcomes this dominance was isolated and found to possess an 11-amino-acid deletion extending from Ile-55 to Met-65 within the c-subunit. These results are discussed in relation to the previously isolated Ala-25 to Thr mutant (Fimmel, A.L., Jans, D.A., Hatch, L., James, L.B., Gibson, F. and Cox, G.B. (1985) Biochim. Biophys. Acta 808, 252-258) and in relation to a previously proposed model for the F0 (Cox, G.B., Fimmel, A.L., Gibson, F. and Hatch, L. (1986) Biochim. Biophys. Acta 849, 62-69).     

The F1F0-ATPase of Escherichia coli. The substitution of alanine by threonine at position 25 in the c-subunit affects function but not assembly

A mutant strain of Escherichia coli carrying a mutation in the uncE gene which codes for the c-subunit of the F1F0-ATPase has been isolated and examined. The mutant allele, designated uncE513, results in alanine at position 25 of the c-subunit being replaced by threonine. The mutant F1F0-ATPase appears to be fully assembled and is partially functional with respect to oxidative phosphorylation. The ATPase activity of membranes from the mutant strain is resistant to the inhibitor dicyclohexylcarbodiimide, but this is due to the F1-ATPase being lost from the membranes in the presence of the inhibitor. Mutant membranes from which the F1-ATPase has been removed have a greatly reduced proton permeability compared with similarly treated normal membranes. The results are discussed in relation to a previously proposed mechanism of oxidative phosphorylation.     

Rotational catalysis of Escherichia coli ATP synthase F1 sector. Stochastic fluctuation and a key domain of the beta subunit

A complex of gamma, epsilon, and c subunits rotates in ATP synthase (FoF(1)) coupled with proton transport. A gold bead connected to the gamma subunit of the Escherichia coli F(1) sector exhibited stochastic rotation, confirming a previous study (Nakanishi-Matsui, M., Kashiwagi, S., Hosokawa, H., Cipriano, D. J., Dunn, S. D., Wada, Y., and Futai, M. (2006) J. Biol. Chem. 281, 4126-4131). A similar approach was taken for mutations in the beta subunit key region; consistent with its bulk phase ATPase activities, F(1) with the Ser-174 to Phe substitution (betaS174F) exhibited a slower single revolution time (time required for 360 degree revolution) and paused almost 10 times longer than the wild type at one of the three 120 degrees positions during the stepped revolution. The pause positions were probably not at the "ATP waiting" dwell but at the "ATP hydrolysis/product release" dwell, since the ATP concentration used for the assay was approximately 30-fold higher than the K(m) value for ATP. A betaGly-149 to Ala substitution in the phosphate binding P-loop suppressed the defect of betaS174F. The revertant (betaG149A/betaS174F) exhibited similar rotation to the wild type, except that it showed long pauses less frequently. Essentially the same results were obtained with the Ser-174 to Leu substitution and the corresponding revertant betaG149A/betaS174L. These results indicate that the domain between beta-sheet 4 (betaSer-174) and P-loop (betaGly-149) is important to drive rotation.     

Steady state kinetics of proton translocation catalyzed by thermophilic F0F1-ATPase reconstituted in planar bilayer membranes

The proton-translocating ATPase of the thermophilic bacterium PS3 was reconstituted into planar phospholipid bilayers by the previously reported method (Hirata, H., Ohno, K., Sone, N., Kagawa, Y., and Hamamoto, T. (1986) J. Biol. Chem. 261, 9839-9843), and the relationship between the electric current induced by ATP and the concentration of ATP was examined. The magnitude of the electric current generated upon addition of ATP followed simple Michaelis-Menten type kinetics, and the Michaelis constant was found to be 0.14 mM under our conditions. This value is close to the values reported for F1- or F0F1-ATPase in its steady state catalytic cycle, indicating that the proton translocation is coupled to the steady state ATPase reaction. The relationship between the Km value and the membrane potential was also examined under the voltage-clamped condition, and we found that there was no apparent dependence of the Km on membrane voltage. These results together with the previous data suggest that the voltage dependence residues in some step that defines the apparent Vmax rather than Km in the reaction cycle, and proton translocation is not directly coupled to this ATP binding step.     

Effect of an uncE ribosome-binding site mutation on the synthesis and assembly of the Escherichia coli proton-translocating ATPase

Plasmid pRPG54, which carries the genes for the eight subunits of the proton-translocating ATPase of Escherichia coli, has been found to carry a single base change of a G to an A in the ribosome-binding site for uncE, the gene which codes for the N,N'-dicyclohexylcarbodiimide-binding subunit c of the Fo. This noncoding region mutation both lowers expression of uncE by a factor of 2-3 and affects the function of the ATPase, specifically of the Fo sector. The presence of the mutation results in a decrease in the proton permeability of the Fo or of the entire F1Fo-ATPase complex when either is synthesized from genes on a multicopy plasmid. Expression of uncE from an F1Fo plasmid carrying the wild type ribosome binding site results in increased membrane proton permeability and decreased ability of the resultant ATPase to couple a transmembrane proton gradient to ATP synthesis both in vitro and in vivo. Also, although an Fo plasmid carrying the correct ribosome-binding site causes harmful, F1-dependent proton permeability in unc+ cells (Brusilow, W. S. S. (1987) J. Bacteriol. 169, 4984-4990), an identical plasmid carrying the mutation does not, even though it still codes for a functional reconstitutable Fo. The results show a relationship between the relative level of expression of uncE from a multicopy plasmid and the assembly pathway, proton permeability, and energy-coupling characteristics of the ATPase.     

Energy-dependent transformation of F0.F1-ATPase in Paracoccus denitrificans plasma membranes

F(0).F(1)-ATP synthase in tightly coupled inside-out vesicles derived from Paracoccus denitrificans catalyzes rapid respiration-supported ATP synthesis, whereas their ATPase activity is very low. In the present study, the conditions required to reveal the Deltamu(H+)-generating ATP hydrolase activity of the bacterial enzyme have been elucidated. Energization of the membranes by respiration results in strong activation of the venturicidin-sensitive ATP hydrolysis, which is coupled with generation of Deltam?(H+). Partial uncoupling stimulates the proton-translocating ATP hydrolysis, whereas complete uncoupling results in inhibition of the ATPase activity. The presence of inorganic phosphate is indispensable for the steady-state turnover of the Deltam?(H+)-activated ATPase. The collapse of Deltam?(H+) brings about rapid deactivation of the enzyme, which has been subjected to pre-energization. The rate and extent of the deactivation depend on protein concentration, i.e. the more vesicles are present in the assay mixture, the higher the rate and extent of the deactivation is seen. Sulfite and the ADP-trapping system protect ATPase against the Deltam?(H+) collapse-induced deactivation, whereas phosphate delays the rate of deactivation. A low concentration of ADP (<1 microm) increases the rate of deactivation. Taken together, the results suggest that latent proton-translocating ATPase in P. denitrificans is kinetically equivalent to the previously characterized ADP(Mg2+)-inhibited, azide-trapped bovine heart mitochondrial F(0).F(1)-ATPase (Galkin, M. A., and Vinogradov, A. D. (1999) FEBS Lett. 448, 123-126). A Deltam?(H+)-sensitive mechanism operates in P. denitrificans that prevents physiologically wasteful consumption of ATP by F(0).F(1)-ATPase (synthase) complex when the latter is unable to maintain certain value of Deltam?(H+).     

ATP synthesis and hydrolysis by a hybrid system reconstituted from the beta-subunit of Escherichia coli F1-ATPase and beta-less chromatophores of Rhodospirillum rubrum

Photophosphorylation and ATPase activities were restored to beta-less Rhodospirillum rubrum chromatophores by their reconstitution with purified beta-subunits of either R. rubrum F1-ATPase (Rr beta) or Escherichia coli F1-ATPase (Ec beta). In the homologous reconstituted system both activities were restored to the same extent, whereas in the hybrid system ATP synthesis was restored to about 10% when the hydrolysis was restored to 200%. This difference in rates of synthesis and hydrolysis was not due to any general uncoupling effect of Ec beta leading to an increased membrane permeability to protons, because with both hybrid and homologous systems an identical light-induced quenching of quinacrine fluorescence was observed. They differed, however, in ATP-driven quenching of quinacrine fluorescence, which was much lower in the hybrid system. These results suggest that the hybrid has a decreased capacity for proton-translocation through the membrane-bound Fo channel during ATP hydrolysis, and probably also during ATP synthesis. The very high ATPase activity of the hybrid system indicates that it might enable the released protons to leak to the outside medium rather than to move inside through the Fo channel. The activities restored by Rr beta and Ec beta exhibit a similar sensitivity to dicyclohexylcarbodiimide, but different sensitivities to oligomycin and to an anti-E. coli F1 (EcF1) antibody. Oligomycin inhibited only the homologous R. rubrum system whereas anti-EcF1 was a much more effective inhibitor of the hybrid system. It is therefore concluded that Rr beta plays a role, that the Ec beta cannot fulfill, in conferring oligomycin sensitivity to the RrFo X F1-ATP synthase-ATPase complex.     

Mutations altering aspartyl-61 of the omega subunit (uncE protein) of Escherichia coli H+ -ATPase differ in effect on coupled ATP hydrolysis.

Mutations in the H+-translocating ATPase complex (F1F0) of Escherichia coli have been described in which aspartyl-61 of the omega subunit ( uncE protein) is substituted by either glycine ( uncE105 ) or asparagine ( uncE107 ). Either substitution blocks the H+-translocation activity of the F0 sector of the complex. Here we report a difference in the effects of the two substitutions on the coupled ATPase activity of F1 bound to F0. Wild-type F1 was bound to the F0 of either mutant with affinities comparable to wild-type. The ATPase activity of F1 bound to uncE107 F0 was inhibited by 50%, whereas that bound to uncE105 F0 was not inhibited. Complementation studies with a pBR322-derived plasmid that carried the E gene of the unc operon only indicated that a single mutation in the host strain was responsible for the respective phenotypes. In mutants complemented by the uncE + plasmid, restoration of wild-type biochemical properties was only partial and may be attributed to a mixing of wild-type and mutant omega subunits in a hybrid F0 complex. The activity of membrane-bound F1 was less inhibited in the uncE +/ uncE107 hybrid. Paradoxically, complementation of uncE105 by the uncE + plasmid resulted in substantial inhibition of the activity of membrane-bound F1. The results indicate that a glycine-versus-asparagine substitution for aspartyl-61 must lead to altered conformations of omega and that these differences in conformation are important in the coupling between the F0 and F1 sectors of the complex.     

The hydrogen ion-pumping adenosine triphosphatase of platelet dense granule membrane. Differences from F1F0- and phosphoenzyme-type ATPases

Using a coupled transport assay which detects only those ATPase molecules functionally inserted into the platelet dense granule membrane, we have characterized the inhibitor sensitivity, substrate specificity, and divalent cation requirements of the granule H+ pump. Under identical assay conditions, the granule ATPase was insensitive to concentrations of NaN3, oligomycin, and efrapeptin which almost completely inhibit ATP hydrolysis by mitochondrial membranes. The granule ATPase was inhibited by dicyclohexylcarbodiimide but only at concentrations much higher than those needed to maximally inhibit mitochondrial ATPase. Vanadate (VO3-) ion and ouabain also failed to inhibit granule ATPase activity at concentrations which maximally inhibited purified Na+,K+-ATPase. Two alkylating agents, 7-chloro-4-nitrobenz-2-oxa-1,3-diazole and N-ethylmaleimide both completely inhibited H+ pumping by the granule ATPase under conditions where ATP hydrolysis by mitochondrial membranes or Na+,K+-ATPase was hardly affected. These results suggest that the H+-pumping ATPase of platelet granule membrane may belong to a class of ion-translocating ATPases distinct from both the phosphoenzyme-type ATPases present in plasma membrane and the F1F0-ATPases of energy-transducing membranes.     

ATP synthetase (F1F0) of Escherichia coli K-12. High-yield preparation of functional F0 by hydrophobic affinity chromatography

1. The purified ATP synthetase complex (F1F0) from Escherichia coli was adsorbed to immobilized poly-(L-lysine)-deoxycholic acid. About 0.7 mg F1F0 were bound per ml of settled gel. The hydrophilic F1 part was dissociated from the complex by treatment with 7 M urea. F0 was eluted in high yield either with deoxycholate (6 mM) or taurodeoxycholate (10 mM). About 14% of the total protein bound to the column was eluted as F0, which corresponds to 64% of the total F0 in the F1F0 complex. 2. The purified F0 preparation obtained was composed of three different kinds of subunits with apparent molecular weights of 24000 (a), 19000 (b) and 8300 (c), respectively as determined by sodium dodecyl sulfate gel electrophoresis. 3. After incorporation into liposomes and the generation of a potassium diffusion potential by valinomycin, the F0 preparation mediated H+ translocation. This H+ uptake is inhibited by either dicyclohexylcarbodiimide or purified F1 ATPase. 4. Incubation of F0-containing liposomes with F1 led to the reconstitution of an ATP-driven quenching of acridine-dye fluorescence. The quenching was abolished by uncoupler and prevented by dicyclohexylcarbodiimide.     

Chemical modification of the F0 part of the ATP synthase (F1F0) from Escherichia coli. Effects on proton conduction and F1 binding

The purified F0 part of the ATP synthase complex from Escherichia coli was incorporated into liposomes and chemically modified by various reagents. The modified F0-liposomes were assayed for H+ uptake and, after reconstitution with F1, for total and dicyclohexylcarbodiimide-sensitive ATPase activity. The water-soluble carbodiimide, 1-ethyl-3-(-3-dimethylaminopropyl)carbodiimide methiodide, (1.2 mM), inhibited H+ uptake to a great extent. Binding of F1 was almost unaffected, but the hydrolysis of ATP was uncoupled from H+ transport. This is reflected by the inhibition of dicyclohexylcarbodiimide-sensitive ATPase activity. Woodward's reagent K, N-ethyl-5-phenylisoxazolium-3'-sulfonate, inhibited both H+ uptake and total ATPase activity. Modification of arginine residues by phenylglyoxal (20 mM) was followed by inhibition of the F1 binding activity by 80% of the control. H+ translocation was reduced to 70%. Diethylpyrocarbonate (3 mM) exhibited a strong inhibiting effect on H+ uptake but not on F1 binding. Modification of tyrosine (by tetranitromethane) as well as lysine residues (by succinic anhydride) did not affect F0 functions. From the data presented we conclude that carboxyl-groups, different from the dicyclohexylcarbodiimide-binding site, are involved in H+ translocation through F0 and, in part, in the functional binding of F1. Furthermore, for the latter function, also arginine residues seem to be important. The role of histidine residues remains unclear at present.     

Characterization of the H(+)-pumping F1F0 ATPase of Vibrio alginolyticus.

The F1F0 ATPase of Vibrio alginolyticus was cloned from a chromosomal lambda library. The unc operon, which contains the structural genes for the ATPase, was sequenced and shown to have a gene organization of uncIBEFHAGDC. The sequence of each subunit was compared with those of other eubacterial ATPases. The V. alginolyticus unc genes exhibited greater similarity to the Escherichia coli unc genes than to any of the other bacterial unc genes for which the sequence is available. The ATPase was expressed in an E. coli unc deletion strain, and the ATP hydrolytic activity was characterized. It has a pH optimum of 7.6 and is stimulated by the addition of Triton X-100 or any of a variety of salts. The recombinant F1F0 was purified 30.4-fold and reconstituted into proteoliposomes. This enzyme catalyzed the pumping of protons coupled to ATP hydrolysis as measured in fluorescence quenching experiments but would not pump Na+ ions under similar conditions.     

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.