H+-ATPase of Escherichia coli uncB402 mutation leads to loss of chi subunit of subunit of F0 sector

An alternative role of FoF1-ATP synthase in Escherichia coli: synthesis of thiamine triphosphate

In E. coli, thiamine triphosphate (ThTP), a putative signaling molecule, transiently accumulates in response to amino acid starvation. This accumulation requires the presence of an energy substrate yielding pyruvate. Here we show that in intact bacteria ThTP is synthesized from free thiamine diphosphate (ThDP) and P_i, the reaction being energized by the proton-motive force (Δp) generated by the respiratory chain. ThTP production is suppressed in strains carrying mutations in F₁ or a deletion of the atp operon. Transformation with a plasmid encoding the whole atp operon fully restored ThTP production, highlighting the requirement for F_oF₁-ATP synthase in ThTP synthesis. Our results show that, under specific conditions of nutritional downshift, F_oF₁-ATP synthase catalyzes the synthesis of ThTP, rather than ATP, through a highly regulated process requiring pyruvate oxidation. Moreover, this chemiosmotic mechanism for ThTP production is conserved from E. coli to mammalian brain mitochondria.

Reversible association between the V1 and V0 domains of yeast vacuolar H+-ATPase is an unconventional glucose-induced effect

The yeast vacuolar H+-ATPase (V-ATPase) is a multisubunit complex responsible for organelle acidification. The enzyme is structurally organized into two major domains: a peripheral domain (V1), containing the ATP binding sites, and an integral membrane domain (V0), forming the proton pore. Dissociation of the V1 and V0 domains inhibits ATP-driven proton pumping, and extracellular glucose concentrations regulate V-ATPase activity in vivo by regulating the extent of association between the V1 and V0 domains. To examine the mechanism of this response, we quantitated the extent of V-ATPase assembly in a variety of mutants with known effects on other glucose-responsive processes. Glucose effects on V-ATPase assembly did not involve the Ras-cyclic AMP pathway, Snf1p, protein kinase C, or the general stress response protein Rts1p. Accumulation of glucose 6-phosphate was insufficient to maintain or induce assembly of the V-ATPase, suggesting that further glucose metabolism is required. A transient decrease in ATP concentration with glucose deprivation occurs quickly enough to help trigger disassembly of the V-ATPase, but increases in cellular ATP concentrations with glucose readdition cannot account for reassembly. Disassembly was inhibited in two mutant enzymes lacking ATPase and proton pumping activities or in the presence of the specific V-ATPase inhibitor, concanamycin A. We propose that glucose effects on V-ATPase assembly occur by a novel mechanism that requires glucose metabolism beyond formation of glucose 6-phosphate and generates a signal that can be sensed efficiently only by a catalytically competent V-ATPase.

Reconstitution of the Fo complex of Escherichia coli ATP synthase from isolated subunits. Varying the number of essential carboxylates by co-incorporation of wild-type and mutant subunit c after purification in organic solvent

Subunit c of the Escherichia coli F1F0-ATPase, purified in chloroform/methanol (2:1), was reconstituted with detergent-solubilized F0 subunits a and b to form a functionally active H+ channel. The rates of H+ uptake by the proteoliposomes containing the reconstituted F0 complex were comparable to those observed with native F0 reconstituted without subunit dissociation. The F0 reconstituted from purified subunits was also shown to form an active ATP-driven H+ pump upon binding of the F1-ATPase sector of the complex. Reconstitution of D61N and D61G mutant c subunits with wild-type subunits a and b produced an inactive F0. Hybrid F0 complexes, formed with mixtures of wild-type and D61N or D61G mutant c subunits, were also prepared. Formation of an active F0 was prevented by addition of relatively small proportions of D61N or D61G mutant c subunits, i.e. active F0 formation was gradually disrupted as the mutant/wild-type ratio was increased from 0.05 to 0.2. The hybrid reconstitution studies support a model where inactivation of one of the 9-12 c subunits found in F0 is sufficient to abolish activity.

Assembly of F0 sector of Escherichia coli H+ ATP synthase. Interdependence of subunit insertion into the membrane

The F0 sector of the Escherichia coli H+ transporting ATP synthase is composed of a complex of three subunits, each of which traverses the inner membrane. We have studied the interdependence of subunit insertion into the membrane in a series of chromosomal mutants in which the primary mutation prevented insertion of one of the F0 subunits. Subunit insertion was assessed using Western blots of mutant membrane preparations. Subunit b and subunit c were found to insert into the membrane independently of the other two F0 subunits. On the other hand, subunit a was not inserted into membranes that lacked either subunit b or subunit c. The conclusion that subunit a insertion is dependent upon the co-insertion of subunits b and c differs from the conclusion of several studies, where subunits were expressed from multicopy plasmids.

Role of the carboxyl terminal region of H(+)-ATPase (F0F1) a subunit from Escherichia coli

The effects of amino acid substitutions in the carboxyl terminal region of the H(+)-ATPase a subunit (271 amino acid residues) of Escherichia coli were studied using a defined expression system for uncB genes coded by recombinant plasmids. The a subunits with the mutations, Tyr-263----end, Trp-231----end, Glu-219----Gln, and Arg-210----Lys (or Gln) were fully defective in ATP-dependent proton translocation, and those with Gln-252----Glu (or Leu), His-245----Glu, Pro-230----Leu, and Glu-219----His were partially defective. On the other hand, the phenotypes of the Glu-269----end, Ser-265----Ala (or end), and Tyr-263----Phe mutants were essentially similar to that of the wild-type. These results suggested that seven amino acid residues between Ser-265 and the carboxyl terminus were not required for the functional proton pathway but that all the other residues except Arg-210, Glu-219, and His-245 were required for maintaining the correct conformation of the proton pathway. The results were consistent with a report that Arg-210 is directly involved in proton translocation.

Mutations in three of the putative transmembrane helices of subunit a of the Escherichia coli F1F0-ATPase disrupt ATP-driven proton translocation

Three missense mutants in subunit a of the Escherichia coli F1F0-ATPase were isolated and characterized after hydroxylamine mutagenesis of a plasmid carrying the uncB (subunit a) gene. The mutations resulted in Asp119----His, Ser152----Phe, or Gly197----Arg substitutions in subunit a. Function was not completely abolished by any of the mutations. The F0 membrane sector was assembled in all three cases as judged by restoration of dicyclohexylcarbodiimide sensitivity to the F1F0-ATPase. The H+ translocation capacity of F0 was reduced in all three mutants. ATP-driven H+-translocation was also reduced, with the response in the Gly197----Arg mutant being almost nil and that in the Asp119----His and Ser152----Phe mutants less severely affected. The substituted residues are predicted to lie in the second, third, and fourth transmembrane helices suggested in most models for subunit a. The Gly197----Arg mutation lies in a very conserved region of the protein and the substitution may disrupt a structure that is critical to function. The Asp119----His and Ser152----Phe mutations also lie in areas with sequence conservation. A further analysis of randomly generated mutants may provide more information on regions of the protein that are crucial to function. Heterodiploid transformants, carrying plasmids with either the wild-type uncB gene or mutant uncB genes in an uncB (Trp231----stop) background, were characterized biochemically. The truncated subunit a was not detected in membranes of the background strain by Western blotting, and the uncB+ plasmid complemented strain showed normal biochemistry. The uncB mutant genes were shown to cause equivalent defects in either the heterodiploid background configuration, or after incorporation into an otherwise wild-type unc operon. The subunit a (Trp231----stop) background strain was shown to bind F1-ATPase nearly normally despite lacking subunit a in its membrane.

Accessibility of F0 subunits from Escherichia coli ATP synthase. A study with subunit specific antisera

Antisera have been raised against denatured and non-denatured subunits a, b and c of the F0 complex of the ATP synthase from Escherichia coli. The subunit specificity of the antibodies has been established with immunoblot analysis or enzyme-linked immunosorbent assay (ELISA). In inside-out oriented membrane vesicles the binding avidities of both sets of antisera, against denatured and non-denatured subunits of F0, were similar in the presence as well as in the absence of the F1 part. F1-depleted everted membrane vesicles always produced an efficient binding of the different antisera. In the presence of F1 no antibody recognition could be observed with the anti-a antisera, while anti-b and anti-c antisera showed strong binding. However, a higher membrane protein concentration was necessary for the same antibody binding as in F1-stripped vesicles. In membrane vesicles with right-side-out orientation the recognition of the three F0 subunits was dependent on the antisera set used. Antisera raised against denatured subunits showed no binding to the membrane vesicles, only in case of anti-(dodecylsulfate-denatured b) antiserum could a slight affinity be detected. An antigen-antibody recognition with all three F0 subunits occurred when the antisera against non-denatured subunits were incubated with membrane vesicles of right-side-out orientation. The membrane protein concentration which was necessary to produce a significant binding was 10-100-fold higher compared to that of F1-depleted everted membrane vesicles.

Modification of subunit b of the F0 complex from Escherichia coli ATP synthase by a hydrophobic maleimide and its effects on F0 functions

Purified F0 from Escherichia coli ATP synthase was labelled with N-(7-dimethylamino-4-methyl-coumarinyl)-maleimide (DACM), a hydrophobic reagent which forms a stable, strongly fluorescent adduct with SH groups. Sodium dodecyl sulfate gel electrophoresis clearly demonstrated that subunit b was exclusively labelled, most likely at Cys-21, the only cysteine residue in E. coli F0. The amount of two molecules of DACM bound per F0, which was calculated from the absorption spectrum at 380 nm, is in full agreement with the postulated stoichiometry of two copies of subunit b/F0 complex. Thus the label provides a useful tool for simply detecting subunit b in protein chemical studies. DACM-labelled F0 was incorporated into liposomes and assayed for H+ translocating activity and its capacity to bind purified F1. Whereas the initial rate of H+ uptake was inhibited about 40% the reconstitution of a dicyclohexylcarbodiimide-sensitive F1F0 ATPase activity was completely unaffected. In a second set of experiments we reconstituted an F0 complex from DACM-labelled purified subunit b and an ac complex. In contrast to the results obtained with intact, DACM-labelled F0, both H+ translocating activity and F1 binding capacity were greatly reduced. Our data indicate that cysteine-21, probably together with other amino acids, is involved in maintaining a proper interaction of the hydrophobic N-terminal region of subunit b with the ac complex. This interplay seems to be a prerequisite for at least the in vitro assembly of a functional F0 complex.

Mitochondrial adenosine triphosphatase in mit- mutants of Saccharomyces cerevisiase with defective subunit 6 of the enzyme complex

mit- Mutants carrying genetically defined mutations in the oli2 region of the mitochondrial DNA were analysed. Most of these mutants demonstrated either the absence of subunit 6 or its replacement by shorter mitochondrial translation products which could be shown to be structurally related to subunit 6 by using a rabbit anti F1F0-antiserum, and by limited proteolytic mapping of the new mitochondrial translation products. Three representative oli2 mit- strains were analysed for the effects of a grossly altered subunit 6 or of a complete absence of this subunit on the activity and assembly of the H+-ATPase. Our results suggest that this subunit is not required for the assembly of the proton channel of the enzyme complex. Thus, in the absence of subunit 6, the mitochondrial respiratory activities in the oli2 mutants were found to be still sensitive to oligomycin, a specific inhibitor of the H+-ATPase proton channel. Immunoprecipitation of the assembled H+-ATPase subunits from these mutant strains using a monoclonal anti-beta-subunit antibody indicates that subunit 6 is also not essential for the assembly of most F1 subunits to components of the F0 sector.

An acidic or basic amino acid at position 26 of the b subunit of Escherichia coli F1F0-ATPase impairs membrane proton permeability: suppression of the uncF469 nonsense mutation

The uncF469 allele differed from normal in that a G----A base change occurred at nucleotide 77 of the uncF gene, resulting in a TAG stop codon rather than the tryptophan codon TGG. Two partial revertant strains were isolated which retained the uncF469 allele but formed a partially functional b-subunit, due to suppression of the uncF469 nonsense mutation. From the altered isoelectric points of the b-subunits from these strains, it was concluded that the suppressor gene of partial revertant strain AN1956 inserts an acidic amino acid for the TAG codon, and that the suppressor gene of partial revertant strain AN1958 inserts a basic amino acid. The membranes of both partial revertant strains showed impaired permeability to protons on removal of F1-ATPase. The membranes of both strains, however, were able to carry out oxidative phosphorylation, and the ATPase activities of both were resistant to the inhibitor dicyclohexylcarbodiimide.

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.

Intracistronic mapping of the defective site and the biochemical properties of beta subunit mutants of Escherichia coli H+-ATPase: correlation of structural domains with functions of the beta subunit

Sixteen mutants of Escherichia coli defective in H+-ATPase (proton-translocating ATPase) were tested for their ability to recombine with hybrid plasmids carrying various portions of the beta subunit cistron. Twelve mutations were mapped within the carboxyl half of the cistron corresponding to amino acid residues 279 to 459 (domain II), while four mutations were mapped within residues 17 to 278 (domain I). The biochemical properties of these mutants were analyzed in terms of the proton permeability of their membranes and the assembly properties of their F1F0 complex. The mutants were classified according to the properties into three types, I, II, and III. In 12 mutants of type I, proton conduction in membrane vesicles was blocked and little F1 was released from the membranes under conditions in which F1 could be released from wild-type membranes, suggesting that assembly of the F1F0 complex is structurally and functionally defective. F1 was partially purified with very low recovery from one of the type I mutants, KF16. ATPase activity was reconstituted from this F1 with the beta subunit of the wild type, confirming the genetic results. Only one mutant, KF38, was classified as type II. Its membranes were partially leaky to protons and its F1 was releasable, suggesting that the interaction of its F1 and F0 was unstable. Type III mutants, KF11 and KF43, had an F1F0 complex with very low activity, in which the structure of F1 was relatively similar to that of the wild type. F1 was purified as a single complex from KF43 in this study and from KF11 previously (H. Kanazawa, Y. Horiuchi, M. Takagi, Y. Ishino, and M. Futai (1980) J. Biochem. 88, 695-703). Reconstitution experiments in vitro showed that the F1's of both mutants were defective in the beta subunit. The properties of the altered F1 of KF43 differed from those of F1 of KF11, suggesting that the mutation sites of KF43 and KF11 were different. From the results of mapping mutation sites and the biochemical properties of the mutants, the correlation of structural domains with function of the beta subunit is discussed. Most type I and type II mutations except that of KF39 were mapped in domain II, while the type III mutations were mapped in domain I, suggesting that domain II is more important than domain I for the function of the beta subunit, especially in terms of proper assembly of the F1F0 complex.

Use of lambda unc transducing bacteriophages in genetic and biochemical characterization of H+-ATPase mutants of Escherichia coli

The eight subunits of the H+-ATPase of Escherichia coli are coded by the genes of the unc operon, which maps between bglB and asnA. A collection of unc mutations were transferred via P1 transduction into a strain in which lambda cI857 S7 was inserted into bglB. The lambda phage was induced, and asnA+ transducing phage that carried unc were selected. Transducing phage carrying mutations in the uncA, B, D, E, and F genes were used for complementation analysis with a collection of unc mutants, including mutants which had been reported previously but not genetically characterized. Some mutations gave a simple complementation pattern, indicating a single defective gene, whereas other mutations gave more complex patterns. Two mutants (uncE105 and uncE107) altered in the proteolipid (omega) subunit of F0 were not complemented by any of the lambda unc phage, even though both mutants had a fully functional F1 ATPase and therefore normal A and D genes. Hence, only limited conclusions can be drawn from genetic complementation alone, since it cannot distinguish normal from abnormal genes in certain classes of unc mutants. The lambda unc phage proved to be essential in characterizing several mutants defective in F0-mediated H+ translocation. The unc gene products were overproduced by heat induction of the lysogenized lambda unc phage to determine whether all the F0 subunits were in the membrane. Two mutants that gave a simple complementation pattern, indicative of one defective gene, did not assemble a three-subunit F0. The uncB108 mutant was shown to lack the chi subunit of F0 but to retain psi and omega. Trace amounts of an altered omega subunit and normal amounts of chi and psi were found in the uncE106 mutant. A substitution of aspartate for glycine at residue 58 of the protein was determined by DNA sequence analysis of the uncE gene cloned from the lambda uncE106 phage DNA. One of the omega-defective, noncomplementing mutants (uncE107) was shown to retain all three F0 subunits. The uncE gene from this mutant was also sequenced to confirm an asparagine-for-aspartate substitution at position 61 (the dicyclohexylcarbodiimide-binding site) of the omega subunit.