Mode of inhibition of sodium azide on H+-ATPase of Escherichia coli

Sodium azide inhibited multi-site (steady-state) ATPase activity of E. coli F1 more than 90%, but did not affect uni-site (single-site) ATPase activity. Thus azide inhibited multi-site ATPase activity by lowering catalytic cooperativity. Consistent with this observation, azide changed the ligand-induced fluorescence response of aurovertin bound to F1.     

The binding of aurovertin to isolated beta subunit of F1 (mitochondrial ATPase). Stoicheiometry of beta subunit in F1.

1. Beef-heart mitochondrial ATPase (F1) is inactivated and dissociated by incubation with 0.85 M LiCl. ATP partly protects against inactivation. Three dissociation products could be identified after chromatography on diethylaminoethylcellulose: the delta subunit which is not adsorbed, the beta subunit which may be eluted from the column, and the alpha and gamma subunits which remain bound to the column. 2. Aurovertin binds to dissociated F1 with a fluorescence enhancement equal to about 30% that found with F1. Unlike intact F1 which shows two kinetically separated phases of fluorescence enhancement, only a fast phase is found with dissociated enzyme. 3. Fluorescence measurements at varying aurovertin and protein concentrations indicate that aurovertin binds to dissociated F1 in a simple 3-component reaction with dissociation constant 0.4 muM. There are two indistinguishable binding sites, calculated on the basis of the initial F1 concentration before dissociation. 4. The beta subunit was isolated from dissociated F1 by DEAE-cellulose chromatography. It has no ATPase activity but reacts with aurovertin with a fluorescence enhancement similar to that of dissociated F1. 5. The isolated beta subunit contains one aurovertin binding site with a dissociation constant of 0.56 muM. 6. It is concluded that F1 contains two beta subunits.     

Isolation of Escherichia coli mutants with an adenosine triphosphatase insensitive to aurovertin.

Energy-transducing adenosine triphosphatase (ATPase) from Escherichia coli is inhibited by aurovertin. Aurovertin-resistant mutants were generated by nitrosoguanidine mutagenesis of E. coli AN180, whose growth on a nonfermentable carbon source was blocked by aurovertin. The ATPase activity of cell extracts from 15 different mutants (designated MA1, MA2, MA3, etc.) was found to be at least 20 times less sensitive to aurovertin than that from the parent strain. The aurovertin-resistant mutants did not show cross-resistance towards a number of ATPase inhibitors including azide, dicyclohexylcarbodiimide, quercetin, 7-chloro-4-nitrobenzofurazan, and N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline. Aurovertin inhibited the energization brought about by addition of ATP to E. coli AN180 membrane vesicles; it was without effect on MA1 and MA2 membrane vesicles energized by ATP. The mutation in MA1, like other mutations of the ATPase complex, maps in the unc region of the bacterial chromosome.     

F1ATPase of Escherichia coli: a mutation (uncA401) located in the middle of the alpha subunit affects the conformation essential for F1 activity

F1ATPase from the Escherichia coli mutant of H+-ATPase, AN120 (uncA401), has less than 1% of the wild type activity and has been shown to be defective in the alpha subunit by in vitro reconstitution experiments. In the present study, the mutation site was located within a domain of the subunit by recombinant DNA technology. For this, a series of recombinant plasmids carrying various portions of the alpha subunit gene were constructed and used for genetic recombination with AN120. Analysis of the recombinants indicated that the mutation site could be located between amino acid residues 370 and 387. The biochemical properties of the mutant F1 were analyzed further using the fluorescent ATP analog DNS-ATP (2'-(5-dimethylaminonaphthalene-1-sulfonyl)-amino-2'-deoxy ATP). The single turnover process of E. coli F1ATPase proposed by Matsuoka et al. [(1982) J. Biochem. 92, 1383-1398.] was compared in the mutant and wild type F1's. Mutant F1 bound DNS-ATP and hydrolyzed it as efficiently as wild type F1. Results showed that binding of ATP to a low affinity site, possibly in the beta subunit, caused decrease of fluorescence of DNS-ATP in the wild type F1 and that this effect of ATP binding was inhibited by DCCD (dicyclohexyl carbodiimide). However, this effect was not inhibited by DCCD in the mutant F1, suggesting that in the proposed process some step(s) after ATP binding to the low affinity site differed in the mutant and wild F1's. When Pi was added to F1 bound to DNS-ATP or to aurovertin, a fluorescent probe capable of binding to the beta subunit, the opposite changes of fluorescence of these probes in the mutant and wild type F1's were observed, suggesting that the conformational change induced by phosphate binding was altered in the mutant F1. On the basis of the estimated mutation site and the biochemical properties of the mutant F1, the correlation of the domain of this site in the alpha subunit with the function of F1 ATPase is discussed.     

Reversible binding of Pi by beef heart mitochondrial adenosine triphosphatase.

Beef heart mitochondrial ATPase (F1) exhibited a single binding site for Pi. The interaction with Pi was reversible, partially dependent on the presence of divalent metal ions, and characterized by a dissociation constant at pH 7.5 of 80 micronM. A variety of substances known to influence oxidative phosphorylation or the activity of the soluble ATPase (F1) also influenced Pi binding by the enzyme. Thus aurovertin, an inhibitor of oxidative phosphorylation, which was bound tightly by F1 and inhibited ATPase activity, enhanced Pi binding via a 4-fold increase in the affinity of the enzyme for Pi (KD = 20 micronM) but did not alter binding stoichiometry. Anions such as SO4(2-), SO3(2-), chromate, and 2,4-dinitrophenolate, which stimulated ATPase activity of F1, also enhanced Pi binding. Inhibitors of ATPase activity such as nickel/bathophenanthroline and the protein ATPase inhibitor of Pullman and Monroy (Pullman, M. E., and Monroy, G. C. (1963) J. Biol. Chem. 238, 3762-3769) inhibited Pi binding. The adenine nucleotides ADP, ATP, and the ATP analog adenylyl imidodiphosphate as well as the Pi analog arsenate, also inhibited Pi binding. The observations suggest that the Pi binding site was located in or near an adenine nucleotide binding site on the molecule.     

The native mitochondrial F1-inhibitor protein complex carries out uni- and multisite ATP hydrolysis

The rate of ATP hydrolysis under multi- and unisite conditions was determined in the native F1-inhibitor protein complex of bovine heart mitochondria (Adolfsen, R., MacClung, J.A., and Moudrianakis, E.N. (1975) Biochemistry 14, 1727-1735). Aurovertin was used to distinguish between hydrolytic activity catalyzed by the F1-ATPase or the F1-inhibitor protein (F1.I) complex. We found that incubation of aurovertin with the F1.I complex, prior to the addition of substrate, results in a stimulation of the hydrolytic activity from 1 to 8-10 mumol min-1 mg-1. The addition of aurovertin to a F1.I complex simultaneously with ATP results in a 30% inhibition with respect to the untreated F1.I. In contrast, if the F1.I complex is activated up to a hydrolytic activity of 80 mumol min-1 mg-1, aurovertin inhibits the enzyme in a manner similar to that described for F1-ATPase devoid of the inhibitor protein. The native F1.I complex catalyzes the hydrolysis of ATP under conditions for single catalytic site, liberating 0.16-0.18 mol of Pi/mol of enzyme. Preincubation with aurovertin before the addition of substrate had no effect under these conditions. On the other hand, if the F1.I ATPase was allowed to hydrolyze ATP at a single catalytic site, catalysis was inhibited by 98% by aurovertin. In F1-ATPase, the hydrolysis of [gamma-32P]ATP bound to the first catalytic site is promoted by the addition of excess ATP, in the presence or absence of aurovertin. Under conditions for single site catalysis, hydrolysis of [gamma-32P]ATP in the F1.I complex was not promoted by excess ATP. We conclude that the endogenous inhibitor protein regulates catalysis by promoting the entrapment of adenine nucleotides at the high affinity catalytic site, thus hindering cooperative ATP hydrolysis.     

Investigation of the aurovertin binding site of Escherichia coli F1-ATPase by fluorescence spectroscopy and site-directed mutagenesis.

(1) Previous mutational analyses have shown that residue beta R398 of the beta-subunit is a key residue for binding of the inhibitory antibiotic aurovertin to Escherichia coli F1Fo-ATP synthase. Here, we studied purified F1 from the beta R398C and beta R398W mutants. ATPase activity in both cases was resistant to aurovertin inhibition. The fluorescence spectrum (lambda exc = 278 or 295 nm) of beta R398W F1 showed a significant red-shift as compared to wild-type and beta R398C enzymes, indicating that residue beta R398 lies in a polar environment. On the basis of this and previous evidence, we propose that aurovertin binding to F1-ATPase involves a specific charged donor-acceptor H-bond between residue beta R398 and the 7-hydroxyl group of aurovertin. (2) The fluorescent substrate analog lin-benzo-ADP was shown to bind to beta R398W F1 catalytic sites with the same Kd values as to wild-type F1, and with the same quenching of the fluorescence of the analog. Fluorescence energy transfer was seen between the beta R398W residue and bound lin-benzo-ADP. Analysis of transfer efficiency at varying stoichiometry of bound lin-benzo-ADP showed that interaction occurred between one beta R398W residue and one catalytic-site-bound analog molecule at a distance of approximately 23 A. The relationships of the aurovertin and catalytic sites in the primary and tertiary structure are discussed.     

An additional acidic residue in the membrane portion of the b-subunit of the energy-transducing adenosine triphosphatase of Escherichia coli affects both assembly and function.

Glycine at position 9 is replaced by aspartic acid in the mutant b-subunit of Escherichia coli F1F0-ATPase coded for by the uncF476 allele. The mutant b-subunit is not assembled into the membrane in haploid strains carrying the uncF476 allele, but, if the mutant allele is incorporated into a multicopy plasmid, then some assembly of the mutant b-subunit occurs. Two revertant strains were characterized, one of which (AN2030) was a full revertant, the other (AN1953) a partial revertant. DNA sequencing indicated that in strain AN2030 the uncF476 mutation had reverted to give the sequence found in the normal uncF gene. The partial-revertant strain AN1953, however, retained the DNA sequence of the uncF476 allele, and complementation analysis indicated that the second mutation may be in the uncA gene. Membranes prepared from the partial-revertant strain carried out oxidative phosphorylation, although the membranes appeared to be impermeable to protons, and the ATPase activity was sensitive to the inhibitor dicyclohexylcarbodi-imide.     

Catalytic hydrolysis and synthesis of adenosine 5'-triphosphate by stereoisomers of covalently labeled F1-adenosinetriphosphatase and reconstituted submitochondrial particles

Bovine heart F1-adenosinetriphosphatase (F1) was labeled specifically and precisely with 7-chloro-4-nitro-2,1,3-[14C]benzoxadiazole ([14C]NBD-Cl). The stereospecifically labeled F1 (O-beta'-[14C]-NBD-F1) was partially reactivated by LiCl treatment, which could cause rearrangement of the beta subunits to form O-beta', beta'-[14C]NBD-F1. Both labeled enzymes were used to combine with F1-deficient submitochondrial particles (ASU) to form the reconstituted particles O-beta'-NBD-F1-ASU and O-beta', beta'-NBD-F1-ASU, respectively. A comparison of the observed steady-state rates of catalytic ATP hydrolysis and oxidative phosphorylation by these specifically labeled submitochondrial particles (SMP) with those of the unlabeled control samples suggests that oxidative phosphorylation involves more active sites of F1 than catalytic ATP hydrolysis. A comparison of the observed ATPase activity of uncoupled labeled SMP and the activity for ATP-driven reverse electron transport in coupled labeled SMP with the corresponding values of the unlabeled control samples shows that the observed fractional inhibition ATP hydrolysis is the same for both the coupled SMP and uncoupled SMP and is determined only by the state of stereospecific labeling of F1. The effect of preincubation under simulated oxidative phosphorylation conditions on the ATPase activity of the unperturbed, specifically NBD-labeled submitochondrial particles was also examined. The data show that respiration-generated proton flux does not cause the beta subunits in bovine heart proton-ATPase to continue switching places with each other during oxidative phosphorylation. Samples of NBD-F1 with specific labels on its nonhydrolytic beta' subunits but none on its hydrolytic beta' subunit were prepared by a three-cycle process.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of a mutation in Escherichia coli F1-ATPase beta-subunit conferring resistance to aurovertin

A mutation conferring aurovertin resistance on Escherichia coli F1-ATPase was identified as R398----H in the F1 beta-subunit. Beta-subunit from the mutant does not bind aurovertin; therefore our results suggest the region of sequence around residue beta-398 is involved in aurovertin binding. Since nucleotide and aurovertin binding to isolated beta-subunit are not mutually exclusive, the data further suggest that the beta-subunit catalytic nucleotide-binding domain does not include residue 398. The mutation prevented aurovertin inhibition of ATPase at pH 6 and 8.5, implying charge on the arginine side-chain is not a major determinant of aurovertin binding or that the pK of R398 is shifted due to a peculiar environment. The equivalent residue is usually arginine in F1 beta-subunits of different species; notably in the aurovertin-insensitive thermophilic bacterium PS3 F1-ATPase, this residue is phenylalanine.     

The use of aurovertin to determine the F1 content of submitochondrial particles and the ATPase complex.

(1) The concentration of aurovertin-binding sites calculated from fluorimetric titrations of submitochondrial particles is equal to the F1 concentration, calculated from the concentration of F1-binding sites in stripped particles. (2) Direct binding experiments show that the fluorescence enhancement of aurovertin bound to submitochondrial particles and the isolated ATPase complex is less (or absent) at higher concentrations than at lower concentrations. The binding data can be described by 'specific' and 'non-specific' binding. The concentration of the 'specific' sites is twice that derived from fluorimetric titrations. (3) After dissociation of the bound F1 with LiCl, fluorimetric titrations with aurovertin yield linear Scatchard plots. The fluorescence enhancement and KD are equal to those of the beta-subunit-aurovertin complex. The concentration of beta-subunits is double the concentration of F1. (4) It is concluded that both for submitochondrial particles and the isolated ATPase complex the most reliable and simple way to determine the F1 content is to dissociate the F1 with LiCl, spin down the insoluble material and titrate the supernatant (containing free beta-subunit) with aurovertin.     

无机磷和叠氮钠对线粒体F_1-ATPase构象的不同影响

用εＡＤＰ作荧光探针,用荧光猝灭的方法证明无机磷（Ｐｉ）能影响Ｆ１－ＡＴＰａｓｅ的构象从而使酶结合ＡＤＰ的能力降低．用ａｕｒｏｖｅｒｔｉｎＢ作荧光探针研究了Ｐｉ和叠氮钠对Ｆ１－ＡＴＰａｓｅ构象的影响,发现Ｐｉ能影响洗去催化位点核苷酸的Ｆ１的构象,而叠氮钠对其没有影响,但却能影响结合有ＡＤＰ的Ｆ１的构象．因此Ｐｉ和叠氮钠对酶构象的影响是不同的,二者可能有不同的作用位点．     

Antibiotic inhibitors of mitochondrial ATP synthesis.

Fourteen antibiotics have been found to inhibit oxidative phosphorylation and uncoupler-stimulated adenosinetriphosphatase in mitochondria. Four different types of binding sites for these inhibitors have been found. The first (1) binds aurovertin to purified MF1 ATPase in the stoichiometric ratio of two aurovertin molecules per molecule of ATPase. Site II is the locus for efrapeptin (A23871) and may be a catalytic site on purified ATPase. The remaining two sites have been demonstrated only in mitochondria or submitochondrial particles when the APTase is bound to other membrane components. Oligomycin, venturiciden, venturicidin X and ossamycin probably all bind at site III. Leucinostatin (A20668) binds at site IV. At low concentrations, this antibiotic acts like oligomycin; at higher concentrations it uncouples oxidative phosphorylation. Venturicidin appears to prevent leucinostation from binding at site IV for it allows uncoupling to occur at very low concentrations of the latter antibiotic. Venturicidin aglycone, which is a more effective inhibitor than its parent compound, does not exert this effect. It is concluded that sites III and IV are in juxtaposition and that when venturicidin binds at site III its sugar moiety projects into the area of site IV to prevent leucinostation from binding at its inhibitory site.     

Adenosine triphosphatase and nucleotide binding activity of isolated beta-subunit preparations from Escherichia coli F1F0-ATP synthase

Adenosine triphosphatase activity and nucleotide binding affinity of isolated beta-subunit preparations from Escherichia coli F1F0-ATP synthase were studied. The aim was to find out whether isolated beta-subunit would provide an experimental model in which effects of mutations on catalysis per se, unencumbered by complications due to their effects on positive catalytic cooperativity, could be studied. Three types of purified, isolated beta-subunit preparations were studied. Type I-beta was from a strain lacking all F1F0 subunits except beta and epsilon. Type II-beta was from F1 carrying the alpha S375F mutation which blocks positive catalytic cooperativity. Type III-beta was from normal F1. Type I- and II-beta had very low ATPase activity (less than 10(-4) s-1) which was azide-insensitive, aurovertin-insensitive, and unaffected by anti-beta antibody. Type I-beta activity was EDTA-insensitive. We conclude that isolated beta-subunit from E. coli F1F0 has zero or at most very low intrinsic ATPase activity. Type III-beta had low ATPase activity (8.4 x 10(-5) s-1 to 1.1 x 10(-3) s-1 in seven different preparations). This activity was aurovertin-sensitive, but varied in azide sensitivity from 0 to 34% inhibited. The azide-sensitive component, like F1 and alpha 3 beta 3 gamma oligomer, was inhibited by anti-beta and anti-alpha antibodies. The azide-insensitive component was stimulated by anti-beta and unaffected by anti-alpha. We show here that (alpha beta)-oligomer has ATPase activity which is azide-insensitive, aurovertin-sensitive, stimulated by anti-beta, and unaffected by anti-alpha. The intrinsic ATPase activity of Type III-beta could be due to contaminating (alpha beta)-oligomer plus alpha 3 beta 3 gamma-oligomer. Isolated beta had very low affinity for nucleotide as compared to the first catalytic site on F1. Taken together with the very low ATPase activity of isolated beta (even if real), the work shows that isolated beta is not a good experimental model of F1 catalysis.     

Catalytic site of F1-ATPase of Escherichia coli. Lys-155 and Lys-201 of the beta subunit are located near the gamma-phosphate group of ATP in the presence of Mg2+.

The catalytic site of Escherichia coli F1 was probed using a reactive ATP analogue, adenosine triphosphopyridoxal (AP3-PL). For complete loss of enzyme activity, about 1 mol of AP3-PL bound to 1 mol of F1 was estimated to be required in the presence or absence of Mg2+. About 70% of the label was bound to the alpha subunit and the rest to the beta subunit in the absence of Mg2+, and the alpha Lys-201 and beta Lys-155 residues, respectively, were the major target residues (Tagaya, M., Noumi, T., Nakano, K., Futai, M., and Fukui, T. (1988) FEBS Lett. 233, 347-351). Addition of Mg2+ decreased the AP3-PL concentration required for half-maximal inhibition, and predominant labeling of the beta subunit (beta Lys-155 and beta Lys-201) with the reagent. ATP and ADP were protective ligands in the presence and absence of Mg2+. The alpha subunit mutation (alpha Lys-201----Gln or alpha Lys-201 deletion) were active in oxidative phosphorylation. However, purified mutant F1s showed impaired low multi-site activity, although their uni-site catalyses were essentially normal. Thus alpha Lys-201 is not a catalytic residue, but may be important for catalytic cooperativity. Mutant F1s were inhibited less by AP3-PL in the absence of Mg2+, and consistent with this, modifications of their alpha subunits by AP3-PL were reduced. AP3-PL was more inhibitory to the mutant enzymes in the presence of Mg2+, and bound to the beta Lys-155 and beta Lys-201 residues of mutant F1 (alpha Lys-201----Gln). These results strongly suggest that alpha Lys-201, beta Lys-155, and beta Lys-201 are located close together near the gamma-phosphate group of ATP bound to the catalytic site, and that the two beta residues and the gamma-phosphate group become closer to each other in the presence of Mg2+.     

A nuclear mutation conferring aurovertin resistance to yeast mitochondrial adenosine triphosphatase.

A single gene nuclear yeast mutant was isolated whose mitochondrial F1-ATPase was resistant to the specific F1 inhibitor aurovertin. The mutant enzyme was not cross-resistant to other F1 inhibitors. The binding of aurovertin to F1 and to the two largest F1 subunits (alpha and beta) was measured by enhancement of aurovertin fluorescence. Aurovertin bound to wild type F1-ATPase and to its monomeric beta subunit with about the same binding constant. It failed to bind to wild type alpha subunit or to either F1 or F1 subunits from the mutant. The aurovertin-resistant mutant thus contains an altered nuclear gene which specifies the structure of the beta subunit of F1.     

Studies of the nucleotide-binding sites on the mitochondrial F1-ATPase through the use of a photoactivable derivative of adenylyl imidodiphosphate

(1)N-4-Azido-2-nitrophenyl-gamma-[3H]aminobutyryl-AdoPP[NH] P(NAP4-AdoPP[NH]P) a photoactivable derivative of 5-adenylyl imidodiphosphate (AdoPP[NH]P), was synthesized. (2) Binding of [3H]NAP4-AdoPP[NH]P to soluble ATPase from beef heart mitochondria (F1) was studied in the absence of photoirradiation, and compared to that of [3H]AdoPP[NH]P. The photoactivable derivative of AdoPP[NH]P was found to bind to F1 with high affinity, like AdoPP[NH]P. Once [3H]NAP4-AdoPP[NH]P had bound to F1 in the dark, it could be released by AdoPP[NH]P, ADP and ATP, but not at all by NAP4 or AMP. Furthermore, preincubation of F1 with unlabeled AdoPP[NH]P, ADP, or ATP prevented the covalent labeling of the enzyme by [3H]NAP4-AdoPP[NH]P upon photoirradiation. (3) Photoirradiation of F1 by [3H]NAP4-AdoPP[NH]P resulted in covalent photolabeling and concomitant inactivation of the enzyme. Full inactivation corresponded to the binding of about 2 mol [3H]NAP4-AdoPP[NH]P/mol F1. Photolabeling by NAP4-AdoPP[NH]P was much more efficient in the presence than in the absence of MgCl2. (4) Bound [3H]NAP4-AdoPP[NH]P was localized on the alpha- and beta- subunits of F1. At low concentrations (less than 10 microM), bound [3H]NAP4-AdoPP[NH]P was predominantly localized on the alpha-subunit; at concentrations equal to, or greater than 75 microM, both alpha- and beta-subunits were equally labeled. (5) The extent of inactivation was independent of the nature of the photolabeled subunit (alpha or beta), suggesting that each of the two subunits, alpha and beta, is required for the activity of F1. (6) The covalently photolabeled F1 was able to form a complex with aurovertin, as does native F1. The ADP-induced fluorescence enhancement was more severely inhibited than the fluorescence quenching caused by ATP. The precentage of inactivation of F1 was virtually the same as the percentage of inhibition of the ATP-induced fluorescence quenching, suggestion that fluorescence quenching is related to the binding of ATP to the catalytic site of F1.     

Aurovertin binds to the beta subunit of yeast mitochondrial ATPase.

Isolated beta subunit of ATPase (F1) from yeast mitochondria does not catalyze an ATPase reaction but still binds the specific F1 inhibitor aurovertin. Binding was measured by enhancement of aurovertin fluorescence; it was as tight as that to F1-ATPase. No binding was observed with F1 or with isolated beta subunit from a single-gene nuclear yeast mutant whose F1-ATPase was resistant to aurovertin.     

Introduction of reactive cysteine residues in the epsilon subunit of Escherichia coli F1 ATPase, modification of these sites with tetrafluorophenyl azide-maleimides, and examination of changes in the binding of the epsilon subunit when different nucleotides are in catalytic sites.

Cysteine residues have been exchanged for serine residues at positions 10 and 108 in the epsilon subunit of the Escherichia coli F1 ATPase by site-directed mutagenesis to create two mutants, epsilon-S10C and epsilon-S108C. These two mutants and wild-type enzyme were reacted with [14C]N-ethylmaleimide (NEM) to examine the solvent accessibility of Cys residues and with novel photoactivated cross-linkers, tetrafluorophenyl azide-maleimides (TFPAM's), to examine near-neighbor relationships of subunits. In native wild-type F1 ATPase, NEM reacted with alpha subunits at a maximal level of 1 mol/mol of enzyme (1 mol/3 alpha subunits) and with the delta subunit at 1 mol/mol of enzyme; other subunits were not labeled by the reagent. In the mutants epsilon-S10C and epsilon-S108C, Cys10 and Cys108, respectively, were also labeled by NEM, indicating that these are surface residues. Reaction of wild-type enzyme with TFPAM's gave cross-linking of the delta subunit to both alpha and beta subunits. Reaction of the mutants with TFPAM's also cross-linked delta to alpha and beta and in addition formed covalent links between Cys10 of the epsilon subunit and the gamma subunit and between Cys108 of the epsilon subunit and the alpha subunit. The yield of cross-linking between sites on epsilon and other subunits depended on the nucleotide conditions used; this was not the case for delta-alpha or delta-beta cross-linked products. In the presence of ATP+EDTA the yield of cross-linking between epsilon-Cys10 and gamma was high (close to 50%) while the yield of epsilon-Cys108 and alpha was low (around 10%).(ABSTRACT TRUNCATED AT 250 WORDS)     

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.