Differentiation between mutants of Escherichia coli K defective in oxidative phosphorylation

Evidence from immunological studies of structure-mechanism relationship of F1 and F1F0

Monoclonal and polyclonal antibodies directed against peptides of F1-ATPase of F1F0-ATPase synthase provide new and efficient tools to study structure-function relationships and mechanisms of such complex membrane enzymes. This review summarizes the main results obtained using this approach. Antibodies have permitted the determination of the nature of subunits involved in the complex, their stoichiometry, their organization, neighboring interactions, and vectorial distribution within or on either face of the membrane. Moreover, in a few cases, amino acid sequences exposed on a face of the membrane or buried inside the complex have been identified. Antibodies are very useful for detecting the role of each subunit, especially for those subunits which appear to have no direct involvement in the catalytic mechanism. Concerning the mechanisms, the availability of monoclonal antibodies which inhibit (or activate) ATP hydrolysis or ATP synthesis, which modify nucleotide binding or regulation of activities, which detect specific conformations, etc. brings many new ways of understanding the precise functions. The specific recognition by monoclonal antibodies on the beta subunit of epitopes in the proximity of, or in the catalytic site, gives information on this site. The use of anti-alpha monoclonal antibodies has shown asymmetry of alpha in the complex as already shown for beta. In addition, the involvement of alpha with respect to nucleotide site cooperativity has been detected. Finally, the formation of F1F0-antibody complexes of various masses, seems to exclude the functional rotation of F1 around F0 during catalysis.

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.

Immunochemical analysis of Micrococcus lysodeikticus (luteus) F1-ATPase and its subunits

The F1-ATPase from Micrococcus lysodeikticus has been purified to 95% protein homogeneity in this laboratory and as all other bacterial F1S, possesses five distinct subunits with molecular weights ranging from 60 000 to 10 000 (Huberman, M. and Salton, M.R.J. (1979) Biochim. Biophys. Acta 547, 230-240). In this communication, we demonstrate the immunochemical reactivities of antibodies to native and SDS-dissociated subunits with the native and dissociated F1-ATPase and show that: (1) the antibodies generated to the native or SDS-dissociated subunits react with the native molecule; (2) all of the subunits comprising the F1 are antigenically unique as determined by crossed immunoelectrophoresis and the Ouchterlony double-diffusion techniques; (3) antibodies to the SDS-denatured individual delta- and epsilon-subunits can be used to destabilize the interaction of these specific subunits with the rest of the native F1; and (4) all subunit antibodies as well as anti-native F1 were found to inhibit ATPase activity to varying degrees, the strongest inhibition being seen with antibodies to the total F1 and anti-alpha- and anti-beta-subunit antibodies. The interaction of specific subunit antibodies may provide a new and novel way to study further and characterize the catalytic portions of F1-ATPases and in general may offer an additional method for the examination of multimeric proteins.

Antibodies to the F1-ATPase of Rhodospirillum rubrum and its purified native beta-subunit: inhibition of ATP-linked activities in R. rubrum and in lettuce

1. Antibodies prepared against the Rhodospirillum rubrum F1-ATPase (RrF1) and its purified, native-beta-subunit, exhibited cross-reactivity with the following soluble preparations of R. rubrum ATPase: RrF0 . F1, RrF1 and the beta-subunit. Anti-RrF1, but not anti-beta antibodies, also formed precipitin lines with soluble beta-less Rrf1, indicating that antigenic determinants of both the beta-subunit and the other four RrF1-subunits are expressed in the whole RrF1 molecule. Both antibodies agglutinated the R. rubrum chromatophores, suggesting that the beta-subunit is located on the external part of RrF1. 2. Both antibodies inhibited ATP synthesis and hydrolysis activities of R. rubrum chromatophores, as well as all the soluble ATPase reactions. Similar concentrations of each antibody were required for 50% inhibition of all these reactions, but anti-RrF1 was always somewhat more effective than anti-beta. These data indicate that the beta-subunit is involved in the catalytic site of the RrF1-enzyme. 3. The antibodies prepared against R. rubrum F1-ATPase and its beta-subunit could bind the soluble chloroplast F1-ATPase (CF1) and inhibited ATP-linked reactions carried out by chloroplasts and by soluble CF1. In these reactions, unlike in the R. rubrum ones, anti-beta was a more potent inhibitor than the anti-RrF1 antibody. The cross-reaction obtained between the antibodies raised against R. rubrum F1 and its beta-subunit and the chloroplast CF1 indicates the presence of similar antigenic determinants in the photosynthetic prokaryotic and eukaryotic F1-ATPases, which have been conserved during evolution.

Influence of the alpha-, beta- and gamma-subunits of the energy-transducing adenosine triphosphates from Micrococcus lysodeikticus in the immunochemical properties of the protein and in their reconstitution studied by a radioimmunoassay method

We developed a sensitive and specific radioimmunoassay of the energy-transducing adenosine triphosphatase (F1-ATPase, EC 3.6.1.3) of Micrococcus lysodeikticus and extended the assay to the alpha-, beta- and gamma-subunits of the enzyme. We isolated these subunits and studied cross-reactions. We found the immunochemical properties of alpha- and beta-subunits to differ, and gamma-subunits showed an intermediate behaviour between that of alpha- and beta-subunits. Our findings indicate that each subunit of M. lysodeikticus F1-ATPase has its own identity and that conformational antigenic determinants and/or co-operative antigenic sites-arise from subunit assembly. Equimolecular amounts of alpha- and beta-subunits (up to three copies of each) reconstituted partially the immunochemical properties of the ATPase molecule, and addition of 2 mol of gamma-subunit per mol of alpha 3 beta 3 complex improved reconstitution. Our findings describe the first reconstitution of biological activity of this ATPase by assembly of the isolated subunits, and provide support for earlier proposals on the stoicheiometry of the alpha 3 beta 3 gamma 2 type for M. lysodeikticus F1-ATPase. The radioimmunoassay method affords opportunities to study the homologies between different energy-transducing ATPases and their constituent polypeptides before the primary structure of these complex proteins has been determined.

The coupling ATPase complex: an evolutionary view

Phospholipid micelles and vesicles, present in the primordial soup, formed both primitive (surface) catalyst and primitive replicative life forms. With the adoption of a common energy source, ATP, integrated biochemical systems within these vesicles became possible - cells. Fermentation within these primitive cells was favoured by the evolution, first of ion channels allowing protons to leak out, and then of an active ATP-driven pump. In the prokaryotic/mitochondria/chloroplast line, the proton channel was such as to be blocked by dicyclohexylcarbodiimide and the adenosine 5' triphosphate phosphohydrolase (ATPase) by 4-chloro 7-nitrobenzofurazan (Nbf-C1). The ATPase was initially simple (4 subunits) but later, possibly concomitant with its evolution to an ATP synthetase, became more complex (8 subunits). One of the steps in evolution probably involved gene duplication and divergence of 2 subunits (alpha and beta) from the largest of the ATPase subunits. From this stage, the general form of the ATPase was fixed, although sensitivity to, for example, oligomycin involved later, after divergence of the mitochondrial and chloroplast lines. A regulatory protein, the ATPase inhibitor, is found associated with a wide spectrum of coupling ATPases.

Subunits of the adenosine triphosphatase complex translated in vitro from the Escherichia coli unc operon

The unc operon of Escherichia coli was split into two fragments by the restriction endonuclease HindIII. The operator-proximal portion was cloned into plasmid pACYC184, forming plasmid pAN51, which included the genes uncB, uncE, and uncA. When plasmid pAN51 was used as template in an in vitro transcription/translation system, the alpha subunit (from the uncA gene) and delta subunit of the F(1) adenosine triphosphatase (ATPase) were formed. In addition, three polypeptides of molecular weights 18,000, 17,000, and 14,000 were formed, and the significance of these polypeptides is discussed. The operator-distal portion of the unc operon was also cloned into plasmid pACYC184, forming plasmid pAN36, which included the uncD and uncC genes. When this plasmid was used as template in an in vitro transcription/translation system, the beta subunit (from the uncD gene) and the epsilon subunit (from the uncC gene) of the F(1) ATPase were formed. A polypeptide of a molecular weight similar to the epsilon subunit but of different net charge was also formed. Plasmid pAN45, carrying the complete unc operon, was isolated after digestion of a mixture of plasmids pAN51 and pAN36 with the restriction endonuclease HindIII and then religation with T4 deoxyribonucleic acid ligase. It was concluded that a HindIII restriction site occurred within the newly described uncG gene, which was shown, by complementation studies with Mu-induced mutants, to be located between the uncA and uncD genes to give the gene order uncBEAGDC. The uncG gene appears to code for the gamma subunit of the F(1) ATPase.

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

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

A fifth gene (uncE) in the operon concerned with oxidative phosphorylation in Escherichia coli

Three mutant unc alleles (unc-408, unc-410, and unc-429) affecting the coupling of electron transport to oxidative phosphorylation in Escherichia coli K-12 have been characterized. Genetic complementation analyses using previously defined mutant unc alleles indicated that the new mutant unc alleles affect a previously undescribed gene designated uncE. The phenotype of strains carrying the uncE408 or uncE429 allele is similar in that Mg(2+)-adenosine triphosphatase activity is only found in the cytoplasmic fraction, and membranes do not bind the F(1) portion of adenosine triphosphatase purified from a normal strain. In contrast, adenosine triphosphatase activity is present both in the cytoplasm and on the membranes from a strain carrying the unc-410 allele, and normal F(1) binds to F(1)-depleted membranes from this strain. The adenosine triphosphatase solubilized from membranes of a strain carrying the unc-410 allele reconstituted ATP-dependent membrane energization in F(1)-depleted membranes from a normal strain. Genetic complementation tests using various Mu-induced unc alleles in partial diploid strains show that the uncE gene is in the unc operon and that the order of genes is uncB E A D C. The unc-410 allele differs from the uncE408 and uncE429 alleles in that complementation tests with the Mu-induced unc alleles indicate that more than one gene is affected. It is concluded that this is due to a deletion which includes part of the uncE gene and another gene, or genes, between the uncE and uncA genes.

ATP hydrolysis in a marine bacterium

The membrane-bound adenosine triphosphatase of marine pseudomonad B-16, when solubilized, is able to rebind to depleted membrane residues of the bacterium and to those of Escherichia coli.

Adenosine 5'-triphosphate synthesis driven by a protonmotive force in membrane vesicles of Escherichia coli

Adenosine 5'-triphosphate (ATP) synthesis energized by an artificially imposed protonmotive force (delta p) in adenosine 5'-diphosphate-loaded membrane vesicles of Escherichia coli was investigated. The protonmotive force is composed of an artificially imposed pH gradient (delta pH) or membrane potential (deltapsi), or both. A delta pH was established by a rapid alteration of the pH of the assay medium. A delta psi was created by the establishment of diffusion potential of K+ in the presence of valinomycin. The maximal amount of ATP synthesized was 0.4 to 0.5 nmol/mg of membrane protein when energized by a delta pH and 0.2 to 0.3 nmol/mg of membrane protein when a delta psi was imposed. Simultaneous imposition of both a delta pH and delta psi resulted in the formation of greater amounts of ATP (0.8 nmol/mg of membrane protein) than with either alone. The amount of ATP synthesized was roughly proportional to the magnitude of the artificially imposed delta p. Although p-chloromercuribenzoate, 2-heptyl-4-hydroxyquinoline-N-oxide, or NaCN each inhibits oxidation of D-lactate, and thus oxidative phosphorylation, none inhibited ATP synthesis driven by an artificially imposed delta p. Membrane vesicles prepared from uncA or uncB strains, which are defective in oxidative phosphorylation, likewise were unable to catalyze ATP synthesis when energy was supplied by an artificially imposed delta p.

Membrane-associated, energy-linked reactions in Bdellovibrio bacteriovorus

Disrupted cells of Bdellovibrio bacteriovorus exhibited adenosine triphosphatase activity, 60 to 80% of which was in the soluble fraction. Dicyclohexylcarbodiimide did not inhibit the adenosine triphosphatase activity in membrane particles. The particles did not show energy-linked transhydrogenase activity. The activity of non-energy-linked transhydrogenase as well as the rate of oxygen consumption were higher in membrane particles of the host-independent strain than in the host-dependent strains. The uptake of amino acid uptake was inhibited by cyanide and by carbonyl cyanide p-trifluoromethoxyphenyl hydrazone. Valinomycin, in the presence of K+, did not inhibit the uptake, and only partial inhibition was exerted by arsenate and dicyclohexylarbodiimide. Sulfhydryl reagents inhibited amino acid uptake.

Effect of inhibitors on the substrate-dependent quenching of 9-aminoacridine fluorescence in inside-out membrane vesicles of Escherichia coli

The effect of various inhibitors on the substrate-dependent quenching of the fluorescence of 9-aminoacridine was measured in inside-out membrane vesicles of Escherichia coli. The rate of fluorescence quenching in the presence of inhibitors was dependent on the rate of electron transfer through the respiratory chain with NADH, succinate, D-lactate or DL-glycerol 3-phosphate as substrates. Several patterns of response were given by the inhibitors. Inhibitors competitive with substrate, or those acting only on the dehydrogenases, gave a direct relationship between the extent of inhibition of oxidase activity and the rate of quenching. A biphasic relationship was given by 2-heptyl-4-hydroxyquinoline N-oxide and piericidin A which was due to these compounds acting both as inhibitors of the respiratory chain and, at higher concentrations, as uncoupling agents. Uncouplers inhibited fluorescence quenching with minimal inhibition of oxidase activity. The transmembrane pH difference was calculated from the extent of fluorescence quenching and the intravesicular volume. The maximum pH difference of 3.3--3.7 units was generated by each of the substrates tested.

The use of several energy-coupling reactions in characterizing mutants of Escherichia coli K12 defective in oxidative phosphorylation

Oxidative phosphorylation, ATP-32Pi exchange, ATP-dependent quenching of acridine-dye fluorescence, ATP-dependent transhydrogenase and ATP-dependent transport of thiomethyl beta-D-galactoside are shown to be experimentally equivalent tools to study the functional state of the ATPase complex in Escherichia coli wild-type and mutant strains defective in oxidative phosphorylation. According to these criteria ten mutants in the ATPase complex were classified having lesions in the unc A,B region of the chromosome. The first mutant type lacks ATPase activity, but the membrane-integrated part of the complex remains functional (class I). The second mutant type lacks a functional membrane-integrated part, but retains ATPase activity (class II). The third mutant type is shown to be defective in both parts of the ATPase complex (class III).