Escherichia coli mutants defective in the uncH gene

Analysis of an N-terminal deletion in subunit a of the Escherichia coli ATP synthase

Subunit a is a membrane-bound stator subunit of the ATP synthase and is essential for proton translocation. The N-terminus of subunit a in E. coli is localized to the periplasm, and contains a sequence motif that is conserved among some bacteria. Previous work has identified mutations in this region that impair enzyme activity. Here, an internal deletion was constructed in subunit a in which residues 6-20 were replaced by a single lysine residue, and this mutant was unable to grow on succinate minimal medium. Membrane vesicles prepared from this mutant lacked ATP synthesis and ATP-driven proton translocation, even though immunoblots showed a significant level of subunit a. Similar results were obtained after purification and reconstitution of the mutant ATP synthase into liposomes. The location of subunit a with respect to its neighboring subunits b and c was probed by introducing cysteine substitutions that were known to promote cross-linking: a_L207C + c_I55C, a_L121C + b_N4C, and a_T107C + b_V18C. The last pair was unable to form cross-links in the background of the deletion mutant. The results indicate that loss of the N-terminal region of subunit a does not generally disrupt its structure, but does alter interactions with subunit b.

Interactions between subunits a and b in the rotary ATP synthase as determined by cross-linking

The interaction of the membrane traversing stator subunits a and b of the rotary ATP synthase was probed by substitution of a single Cys into each subunit with subsequent Cu(2+) catalyzed cross-linking. Extensive interaction between the transmembrane (TM) region of one b subunit and TM2 of subunit a was indicated by cross-linking with 6 Cys pairs introduced into these regions. Additional disulfide cross-linking was observed between the N-terminus of subunit b and the periplasmic loop connecting TM4 and TM5 of subunit a. Finally, benzophenone-4-maleimide derivatized Cys in the 2-3 periplasmic loop of subunit a were shown to cross-link with the periplasmic N-terminal region of subunit b. These experiments help to define the juxtaposition of subunits b and a in the ATP synthase.

Theaflavins inhibit the ATP synthase and the respiratory chain without increasing superoxide production

Four dietary polyphenols, theaflavin, theaflavin-3-gallate, theaflavin-3'-gallate and theaflavin-3,3'-digallate (TF3), have been isolated from black tea, and their effects on oxidative phosphorylation and superoxide production in a model system (Escherichia coli) have been examined. The esterified theaflavins were all potent inhibitors of the membrane-bound adenosine triphosphate (ATP) synthase, inhibiting at least 90% of the activity, with IC(50) values in the range of 10-20 μM. ATP-driven proton translocation was inhibited in a similar fashion, as was the purified F(1)-ATPase, indicating that the primary site of inhibition was in the F(1) sector. Computer modeling studies supported this interpretation. All four theaflavins were also inhibitory towards the electron transport chain, whether through complex I (NDH-1) or the alternative NADH dehydrogenase (NDH-2). Inhibition of NDH-1 by TF3 appeared to be competitive with respect to NADH, and this was supported by computer modeling studies. Rates of superoxide production during NADH oxidation by each dehydrogenase were measured. Superoxide production was completely eliminated in the presence of about 15 μM TF3, suggesting that inhibition of the respiratory chain by theaflavins does not contribute to superoxide production.

Altered bacterial metabolism, not coenzyme Q content, is responsible for the lifespan extension in Caenorhabditis elegans fed an Escherichia coli diet lacking coenzyme Q

Coenzyme Q(n) is a fully substituted benzoquinone containing a polyisoprene tail of distinct numbers (n) of isoprene groups. Caenorhabditis elegans fed Escherichia coli devoid of Q(8) have a significant lifespan extension when compared to C. elegans fed a standard 'Q-replete'E. coli diet. Here we examine possible mechanisms for the lifespan extension caused by the Q-less E. coli diet. A bioassay for Q uptake shows that a water-soluble formulation of Q(10) is effectively taken up by both clk-1 mutant and wild-type nematodes, but does not reverse lifespan extension mediated by the Q-less E. coli diet, indicating that lifespan extension is not due to the absence of dietary Q per se. The enhanced longevity mediated by the Q-less E. coli diet cannot be attributed to dietary restriction, different Qn isoforms, reduced pathogenesis or slowed growth of the Q-less E. coli, and in fact requires E. coli viability. Q-less E. coli have defects in respiratory metabolism. C. elegans fed Q-replete E. coli mutants with similarly impaired respiratory metabolism due to defects in complex V also show a pronounced lifespan extension, although not as dramatic as those fed the respiratory deficient Q-less E. coli diet. The data suggest that feeding respiratory incompetent E. coli, whether Q-less or Q-replete, produces a robust life extension in wild-type C. elegans. We believe that the fermentation-based metabolism of the E. coli diet is an important parameter of C. elegans longevity.

ATP synthesis without R210 of subunit a in the Escherichia coli ATP synthase

Interactions between subunit a and oligomeric subunit c are essential for the coupling of proton translocation to rotary motion in the ATP synthase. A pair of previously described mutants, R210Q/Q252R and P204T/R210Q/Q252R [L.P. Hatch, G.B. Cox and S.M. Howitt, The essential arginine residue at position 210 in the a subunit of the Escherichia coli ATP synthase can be transferred to position 252 with partial retention of activity, J. Biol. Chem. 270 (1995) 29407-29412] has been constructed and further analyzed. These mutants, in which the essential arginine of subunit a, R210, was switched with a conserved glutamine residue, Q252, are shown here to be capable of both ATP synthesis by oxidative phosphorylation, and ATP-driven proton translocation. In addition, lysine can replace the arginine at position 252 with partial retention of both activities. The pH dependence of ATP-driven proton translocation was determined after purification of mutant enzymes, and reconstitution into liposomes. Proton translocation by the lysine mutant, and to a lesser extent the arginine mutant, dropped off sharply above pH 7.5, consistent with the requirement for a positive charge during function. Finally, the rates of ATP synthesis and of ATP-driven proton translocation were completely inhibited by treatment with DCCD (N,N'-dicyclohexylcarbodiimide), while rates of ATP hydrolysis by the mutants were not significantly affected, indicating that DCCD modification disrupts the F(1)-F(o) interface. The results suggest that minimal requirements for proton translocation by the ATP synthase include a positive charge in subunit a and a weak interface between subunit a and oligomeric subunit c.

The role of transmembrane span 2 in the structure and function of subunit a of the ATP synthase from Escherichia coli

The importance of the second transmembrane span of subunit a of the ATP synthase from Escherichia coli has been established by two approaches. First, biochemical analysis of five cysteine-substitution mutants, four of which were previously constructed for labeling experiments, revealed that only D119C, found within the second transmembrane span, was deleterious to ATP synthase function. This mutant had a greatly reduced growth yield, indicating inefficient ATP synthesis, but it retained a significant level of ATP-driven proton translocation and sensitivity to N,N(')-dicyclohexyl-carbodiimide, indicating more robust function in the direction of ATP hydrolysis. Second, the entire second transmembrane span was probed by alanine-insertion mutagenesis at six different positions, from residues 98 to 122. Insertions at the central four positions from residues 107 to 117 resulted in the inability to grow on succinate minimal medium, although normal levels of membrane-bound ATPase activity and significant levels of subunit a were detected. Double mutants were constructed with a mutation that permits cross-linking to the b subunit. Cross-linked products in the mutant K74C/114iA were seen, indicating no major disruption of the a-b interface due to the insertion at 114. Analysis of the K74C/110iA double mutant indicated that K74C is a partial suppressor of 110iA. In summary, the results support a model in which the amino-terminal, cytoplasmic end of the second transmembrane span has close contact with subunit b, while the carboxy-terminal, periplasmic end is important for proton translocation.

Mutagenesis of subunit N of the Escherichia coli complex I. Identification of the initiation codon and the sensitivity of mutants to decylubiquinone

The last gene in the nuo operon of Escherichia coli, nuoN, encodes a membrane-bound subunit of Complex I (NADH:ubiquinone oxidoreductase). In this report, the gene for subunit N was disrupted by a 163 bp deletion in the chromosome, resulting in the loss of Complex I function, as measured by deamino-NADH oxidase activity. This activity could be recovered after transformation of the mutant strain by a plasmid that contains the previously identified nuoN gene and the upstream intergenic region between nuoM and nuoN. Mutagenesis of the first ATG downstream of nuoM led to a loss of function, indicating that this is the likely initiation codon for nuoN, and predicting a protein of 485 amino acids and 52 044 Da. Thirty site-specific mutations in nuoN at 19 different positions were constructed in a vector that expresses the full-length subunit N with both an octahistidine tag and an HA epitope tag at the carboxyl terminus. Highly conserved charged and aromatic residues were selected for mutagenesis, as well as a substitution that occurs as a secondary mutation in Leber's hereditary optic neuropathy (LHON). Membranes from the mutant strains were tested for production of subunit N by immunoblots and for NADH-linked activities. Mutants with substitutions at six different positions (K158, K217, H224, K247, Y300, and K395) had rates of deamino-NADH oxidase activity that were no more than 50% of that of the wild type and had reduced rates of proton translocation. These mutants also showed enhanced inhibition by decylubiquinone, indicating that subunit N interacts with quinones. The mutation associated with LHON, G391S, had little effect on these functions.

Characterization of the first cytoplasmic loop of subunit a of the Escherichia coli ATP synthase by surface labeling, cross-linking, and mutagenesis

The first cytoplasmic loop of subunit a of the Escherichia coli ATP synthase has been analyzed by cysteine substitution mutagenesis. 13 of the 26 residues tested were found to be accessible to the reaction with 3-(N-maleimidylpropionyl)-biocytin. The other 13 residues predominantly found in the central region of the polypeptide chain between the two transmembrane spans were more resistant to labeling by 3-(N-maleimidylpropionyl)-biocytin while in membrane vesicle preparations. This region of subunit a contains a conserved residue Glu-80, which when mutated to lysine resulted in a significant loss of ATP-driven proton translocation. Other substitutions including glutamine, alanine, and leucine were much less detrimental to function. Cross-linking studies with a photoactive cross-linking reagent were carried out. One mutant, K74C, was found to generate distinct cross-links to subunit b, and the cross-linking had little effect on proton translocation. The results indicate that the first transmembrane span (residues 40-64) of subunit a is probably near one or both of the b subunits and that a less accessible region of the first cytoplasmic loop (residues 75-90) is probably near the cytoplasmic surface, perhaps in contact with b subunits.

His(15) of subunit a of the Escherichia coli ATP synthase is important for the structure or assembly of the membrane sector F(o)

Approximately 37 amino acids at the amino-terminus of subunit a of the Escherichia coli ATP synthase are found localized to the periplasm. Results indicate that a single amino acid substitution, H15D, disrupts assembly of subunit a and causes a loss of ATP synthase function. In this study, a conserved region of nine amino acids, 11-19, was initially mutagenized randomly, generating no mutants that could grow on succinate-minimal medium. Subsequent mutagenesis, confined to residues His(14), His(15), and Asn(17), indicated that constructs containing H15D were the most deleterious. Four single mutants were constructed and analyzed: H15A, H14D, H15A, and H15D. Only H15D was significantly impaired, with respect to ATP-driven proton translocation, passive proton permeability through F(o), and sensitivity of membrane-bound ATPase to DCCD. Immunoblot analysis indicated very low levels of subunit a from H15D. Cysteine mutations were constructed at positions 14, 15, 17, and 18. Residues 14, 15, and 17 were shown to be accessible in the periplasmic space, while residue 18 was not, indicating that this region was stably folded. While both His(14) and His(15) are conserved among a group of bacteria, results presented here indicate that they are not equivalent, and that a specific role for His(15) in the assembly or structure of the ATP synthase is supported.

Modeling the Leigh syndrome nt8993 T-->C mutation in Escherichia coli F1F0 ATP synthase

The mutations in human mitochondrial DNA at nt8993 are associated with a range of neuromuscular disorders. One mutation encodes a proline in place of a leucine conserved in all animal mitochondrial ATPase-6 subunits and bacterial a subunits of F1F0 ATP synthases. This conserved site is leu-156 and leu-207 in humans and Escherichia coli, respectively. An aleu-207-->pro substitution mutation has been constructed in the E. coli F1F0 ATP synthase in order to model the biochemical basis of the human disease mutation. The phenotype of the aleu-207-->pro substitution has been compared to that of the previously studied aleu-207-->arg substitution (Hartzog and Cain, 1993, Journal of Biological Chemistry 268, 12250-12252). The leu-207-->pro mutation resulted in approximately a 35% decrease in the number of intact enzyme complexes as determined by N, N'-dicyclohexylcarbodiimide-sensitive membrane associated ATP hydrolysis activity and western analysis using an anti-a subunit antibody. A 75% reduction in the efficiency of proton translocation through F1F0 ATP synthase was observed in ATP-driven proton pumping assays. Interestingly, the loss in F1F0 ATP synthase activity resulting from the leu-207-->pro substitution was markedly less dramatic than had been observed for the leu-207-->arg mutation studied earlier. By analogy, the human enzyme may also be affected by the leu-156-->pro substitution to a lesser extent than the leu-156-->arg substitution, and this would account for the milder clinical manifestations of the human leu-156-->pro disease mutations.

A novel labeling approach supports the five-transmembrane model of subunit a of the Escherichia coli ATP synthase

Cysteine mutagenesis and surface labeling has been used to define more precisely the transmembrane spans of subunit a of the Escherichia coli ATP synthase. Regions of subunit a that are exposed to the periplasmic space have been identified by a new procedure, in which cells are incubated with polymyxin B nonapeptide (PMBN), an antibiotic derivative that partially permeabilizes the outer membrane of E. coli, along with a sulfhydryl reagent, 3-(N-maleimidylpropionyl) biocytin (MPB). This procedure permits reaction of sulfhydryl groups in the periplasmic space with MPB, but residues in the cytoplasm are not labeled. Using this procedure, residues 8, 27, 37, 127, 131, 230, 231, and 232 were labeled and so are thought to be exposed in the periplasm. Using inside-out membrane vesicles, residues near the end of transmembrane spans 1, 64, 67, 68, 69, and 70 and residues near the end of transmembrane spans 5, 260, 263, and 265 were labeled. Residues 62 and 257 were not labeled. None of these residues were labeled in PMBN-permeabilized cells. These results provide a more detailed view of the transmembrane spans of subunit a and also provide a simple and reliable technique for detection of periplasmic regions of inner membrane proteins in E. coli.

Membrane topology of subunit a of the F1F0 ATP synthase as determined by labeling of unique cysteine residues

The membrane topology of the a subunit of the F1F0 ATP synthase from Escherichia coli has been probed by surface labeling using 3-(N-maleimidylpropionyl) biocytin. Subunit a has no naturally occurring cysteine residues, allowing unique cysteines to be introduced at the following positions: 8, 24, 27, 69, 89, 128, 131, 172, 176, 196, 238, 241, and 277 (following the COOH-terminal 271 and a hexahistidine tag). None of the single mutations affected the function of the enzyme, as judged by growth on succinate minimal medium. Membrane vesicles with an exposed cytoplasmic surface were prepared using a French pressure cell. Before labeling, the membranes were incubated with or without a highly charged sulfhydryl reagent, 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid. After labeling with the less polar biotin maleimide, the samples were solubilized with octyl glucoside/cholate and the subunit a was purified via the oligohistidine at its COOH terminus using immobilized nickel chromatography. The purified samples were electrophoresed and transferred to nitrocellulose for detection by avidin conjugated to alkaline phosphatase. Results indicated cytoplasmic accessibility for residues 69, 172, 176, and 277 and periplasmic accessibility for residues 8, 24, 27, and 131. On the basis of these and earlier results, a transmembrane topology for the subunit a is proposed.

Insertion scanning mutagenesis of subunit a of the F1F0 ATP synthase near His245 and implications on gating of the proton channel

Subunit a of the E. coli F1F0 ATP synthase was probed by insertion scanning mutagenesis in a region between residues Glu219 and His245. A series of single amino acid insertions, of both alanine and aspartic acid, were constructed after the following residues: 225, 229, 233, 238, 243, and 245. The mutants were tested for growth yield, binding of F1 to membranes, dicyclohexylcarbodiimide sensitivity of ATPase activity, ATP-driven proton translocation, and passive proton permeability of membranes stripped of F1. Significant loss of function was seen only with insertions after positions 238 and 243. In contrast, both insertions after residue 225 and the alanine insertion after residue 245 were nearly identical in function to the wild type. The other insertions showed an intermediate loss of function. Missense mutations of His245 to serine and cysteine were nonfunctional, while the W241C mutant showed nearly normal ATPase function. Replacement of Leu162 by histidine failed to suppress the 245 mutants, but chemical rescue of H245S was partially successful using acetate. An interaction between Trp241 and His245 may be involved in gating a "half-channel" from the periplasmic surface of F0 to Asp61 of subunit a.

Site-directed mutagenesis of two conserved charged amino acids in the N-terminal region of alpha subunit of E. coli-F(0)F(1)

Two conserved charged amino acids of the N-terminal 'crown' region of the alpha subunit of E. coli-F(1), alpha-D36 and alpha-R40 were exchanged for chemically related (alpha-D36-->E, alpha-R40-->K) or unrelated amino acids (alpha D-36-->K, alpha R40-->G), respectively, by employing oligonucleotide-directed mutagenesis. ATP formation and ATP hydrolyzing activity of isolated plasma membrane vesicles was strongly inhibited in mutant HS2 (alpha-D36-->K), but only slightly affected in the other mutants. The inhibition is not due to a lower content of F0F1 in HS2. In this mutant the extent of the proton gradient generated by ATP hydrolysis was more than 80% inhibited; in all other transformants much smaller effects were observed. The proton gradient established by NADH oxidation was 33% decreased in HS2, but was decreased to a lesser extent in all other mutants. After blockage of F0 by DCCD treatment, the same NADH-induced proton gradient was obtained in all transformants including HS2. This and the fact that the activity of NADH oxidation was unchanged indicate increased proton leakiness of F0F1 carrying the alpha-D36-->K mutation. In F1 alpha-D36 is located in a domain contacting the beta subunit in the vicinity of the arginine beta-R52. The effect of alpha-D36-->K replacement on catalysis and coupling thus may be due to an electrostatic repulsive effect in the crown region which alters the alpha and beta interaction.

Construction and plasmid-borne complementation of strains lacking the epsilon subunit of the Escherichia coli F1F0 ATP synthase

Two strains of Escherichia coli that lack the epsilon subunit of the F1F0 ATP synthase have been constructed. They are shown to be viable but with very low growth yields (28%). These strains can be complemented by plasmids carrying wild-type uncC, but not when epsilon is overproduced. These results indicate that epsilon is not essential for growth on minimal glucose medium and that the level of its expression affects the assembly of the ATP synthase.

Complementation of Escherichia coli uncD mutant strains by a chimeric F1-beta subunit constructed from E. coli and spinach chloroplast F1-beta

ATP-synthesizing F0F1-ATPases are complex enzymes consisting of at least eight different subunits. These subunits are conserved during evolution to a very variable degree ranging in pairwise comparison between, for example, Escherichia coli and spinach chloroplast from 20% to 66% identical residues. It was surprising to find that some of the less well conserved subunits like delta and epsilon could replace their E. coli counterparts, whereas the highly conserved beta subunit, which carries the active site, in the E. coli enzyme could not be substituted by spinach chloroplast beta (Lill et al. (1993) Biochim. Biophys. Acta 1144, 278-284). We constructed a chimeric F1-beta subunit consisting of spinach beta in which the 96 N-terminal amino acids were replaced by the respective residue sequence from E. coli beta. Whereas spinach beta did not complement E. coli uncD mutant strains, the chimeric beta subunit restored growth under conditions of oxidative phosphorylation.

The tryptophan repressor sequence is highly conserved among the Enterobacteriaceae

Tryptophan biosynthesis in Escherichia coli is regulated by the product of the trpR gene, the tryptophan (Trp) repressor. Trp aporepressor binds the corepressor, L-tryptophan, to form a holorepressor complex, which binds trp operator DNA tightly, and inhibits transcription of the tryptophan biosynthetic operon. The conservation of trp operator sequences among enteric Gram-negative bacteria suggests that trpR genes from other bacterial species can be cloned by complementation in E. coli. To clone trpR homologues, a deletion of the E. coli trpR gene, delta trpR504, was made on a plasmid by site-directed mutagenesis, then crossed onto the E. coli genome. Plasmid clones of the trpR genes of Enterobacter aerogenes and Enterobacter cloacae were isolated by complementation of the delta trpR504 allele, scored as the ability to repress beta-galactosidase synthesis from a prophage-borne trpE-lacZ gene fusion. The predicted amino acid sequences of four enteric TrpR proteins show differences, clustered on the backside of the folded repressor, opposite the DNA-binding helix-turn-helix substructures. These differences are predicted to have little effect on the interactions of the aporepressor with tryptophan, holorepressor with operator DNA, or tandemly bound holorepressor dimers with one another. Although there is some variation observed at the dimer interface, interactions predicted to stabilize the interface are conserved. The phylogenetic relationships revealed by the TrpR amino acid sequence alignment agree with the results of others.

Mutations in the delta subunit influence the assembly of F1F0 ATP synthase in Escherichia coli

Missense mutations affecting Asp-161 and Ser-163 in the delta subunit of F1F0 ATP synthase have been generated. Although most substitutions allowed substantial enzyme function, the delta Asp-161-->Pro substitution resulted in a loss of enzyme activity. The loss of activity was attributable to a structural failure altering assembly of the enzyme complex.

Complementation of Escherichia coli unc mutant strains by chloroplast and cyanobacterial F1-ATPase subunits

The genes encoding the five subunits of the F1 portion of the ATPases from both spinach chloroplasts and the cyanobacterium Synechocystis sp. PCC 6803 were cloned into expression vectors and expressed in Escherichia coli. The recombinant subunits formed inclusion bodies within the cells. Each particular subunit was expressed in the respective unc mutant, each unable to grow on non-fermentable carbon sources. The following subunits restored growth under conditions of oxidative phosphorylation: alpha (both sources, cyanobacterial subunit more than spinach subunit), beta (cyanobacterial subunit only), delta (both spinach and Synechocystis), and epsilon (both sources), whereas no growth was achieved with the gamma subunits from both sources. Despite a high degree of sequence homology the large subunits alpha and beta of spinach and cyanobacterial F1 were not as effective in the substitution of their E. coli counterparts. On the other hand, the two smallest subunits of the E. coli ATPase could be more effectively replaced by their cyanobacterial or chloroplast counterparts, although the sequence identity or even similarity is very low. We attribute these findings to the different roles of these subunits in F1: The large alpha and beta subunits contribute to the catalytic centers of the enzyme, a function rendering them very sensitive to even minor changes. For the smaller delta and epsilon subunits it was sufficient to maintain a certain tertiary structure during evolution, with little emphasis on the conservation of particular amino acids.

Assembly of the Escherichia coli F1F0 ATPase, a large multimeric membrane-bound enzyme

The F1F0 proton translocating ATPase of Escherichia coli is a large membrane-bound enzyme complex consisting of more than 20 polypeptides that are encoded by the unc operon. Besides being a system for analysing the enzymology of ATP synthesis and energy coupling, the ATPase is a model system for determining how large oligomeric membrane-bound proteins are synthesized and assembled. The assembly of the ATPase involves differential gene expression and assembly of the subunits within the membrane and with each other. This review discusses the influence of F1 subunits on the assembly and proton permeability of the F0 proton channel, and the possible advantages to assembly of the particular arrangement of genes in the unc operon.

The role of arginine in the conserved polar loop of the c-subunit of the Escherichia coli H(+)-ATPase

The Arg-41 of the c-subunit of the F0F1-ATPase of Escherichia coli has been changed by site-directed mutagenesis to Glu, Leu or Lys. None of the mutants can carry out oxidative phosphorylation. No detectable F1-ATPase activity is found on the membranes and only small amounts in the cytoplasm. Two-dimensional gel electrophoresis shows that in all three mutant strains the assembly of the F0F1-ATPase has been affected. When plasmids carrying the mutant genes, together with other normal unc genes, were inserted into strains each carrying a mutation in one of the unc genes other than uncE their capacity for oxidative phosphorylation was reduced or eliminated, the effect being most pronounced with the uncG and uncC mutants and least pronounced with the plasmid giving the Arg-->Lys substitution. The c-subunit is a multimer in the ATP synthase complex and it appears that a mixture of normal and mutant gene products allows assembly of a functional complex.

Mutagenic analysis of the a subunit of the F1F0 ATP synthase in Escherichia coli: Gln-252 through Tyr-263

The a subunit of F1F0 ATP synthase contains a highly conserved region near its carboxyl terminus which is thought to be important in proton translocation. Cassette site-directed mutagenesis was used to study the roles of four conserved amino acids Gln-252, Phe-256, Leu-259, and Tyr-263. Substitution of basic amino acids at each of these four sites resulted in marked decreases in enzyme function. Cells carrying a subunit mutations Gln-252-->Lys, Phe-256-->Arg, Leu-259-->Arg, and Tyr-263-->Arg all displayed growth characteristics suggesting substantial loss of ATP synthase function. Studies of both ATP-driven proton pumping and proton permeability of stripped membranes indicated that proton translocation through F0 was affected by the mutations. Other mutations, such as the Phe-256-->Asp mutation, also resulted in reduced enzyme activity. However, more conservative amino acid substitutions generated at these same four positions produced minimal losses of F1F0 ATP synthase. The effects of mutations and, hence, the relative importance of the amino acids for enzyme function appeared to decrease with proximity to the carboxyl terminus of the a subunit. The data are most consistent with the hypothesis that the region between Gln-252 and Tyr-263 of the a subunit has an important structural role in F1F0 ATP synthase.

Carbon and energy metabolism of atp mutants of Escherichia coli

The membrane-bound H(+)-ATPase plays a key role in free-energy transduction of biological systems. We report how the carbon and energy metabolism of Escherichia coli changes in response to deletion of the atp operon that encodes this enzyme. Compared with the isogenic wild-type strain, the growth rate and growth yield were decreased less than expected for a shift from oxidative phosphorylation to glycolysis alone as a source of ATP. Moreover, the respiration rate of a atp deletion strain was increased by 40% compared with the wild-type strain. This result is surprising, since the atp deletion strain is not able to utilize the resulting proton motive force for ATP synthesis. Indeed, the ratio of ATP concentration to ADP concentration was decreased from 19 in the wild type to 7 in the atp mutant, and the membrane potential of the atp deletion strain was increased by 20%, confirming that the respiration rate was not controlled by the magnitude of the opposing membrane potential. The level of type b cytochromes in the mutant cells was 80% higher than the level in the wild-type cells, suggesting that the increased respiration was caused by an increase in the expression of the respiratory genes. The atp deletion strain produced twice as much by-product (acetate) and exhibited increased flow through the tricarboxylic acid cycle and the glycolytic pathway. These three changes all lead to an increase in substrate level phosphorylation; the first two changes also lead to increased production of reducing equivalents. We interpret these data as indicating that E. coli makes use of its ability to respire even if it cannot directly couple this ability to ATP synthesis; by respiring away excess reducing equivalents E. coli enhances substrate level ATP synthesis.

Escherichia coli H(+)-ATPase: role of the delta subunit in binding Fl to the Fo sector

The roles of the Escherichia coli H(+)-ATPase (FoFl) delta subunit (177 amino acid residues) was studied by analyzing mutants. The membranes of nonsense (Gln-23----end, Gln-29----end, Gln-74----end) and missense (Gly-150----Asp) mutants had very low ATPase activities, indicating that the delta subunit is essential for the binding of the Fl portion to Fo. The Gln-176----end mutant had essentially the same membrane-bound activity as the wild type, whereas in the Val-174----end mutant most of the ATPase activity was in the cytoplasm. Thus Val-174 (and possibly Leu-175 also) was essential for maintaining the structure of the subunit, whereas the two carboxyl terminal residues Gln-176 and Ser-177 were dispensable. Substitutions were introduced at various residues (Thr-11, Glu-26, Asp-30, Glu-42, Glu-82, Arg-85, Asp-144, Arg-154, Asp-161, Ser-163), including apparently conserved hydrophilic ones. The resulting mutants had essentially the same phenotypes as the wild type, indicating that these residues do not have any significant functional role(s). Analysis of mutations (Gly-150----Asp, Pro, or Ala) indicated that Gly-150 itself was not essential, but that the mutations might affect the structure of the subunit. These results suggest that the overall structure of the delta subunit is necessary, but that individual residues may not have strict functional roles.

Substitution of the cysteinyl residue (Cys21) of subunit b of the ATP synthase from Escherichia coli

The Fo complex of the ATP synthase (F1Fo) of Escherichia coli contains only two cysteinyl residues, Cys21, of the two copies of subunit b. Modification of Cys21 with the hydrophobic maleimide N-(7-dimethylamino-4-methyl-coumarinyl)maleimide resulted in impairment of Fo functions [Schneider, E. & Altendorf, K. (1985) Eur. J. Biochim. 153, 105-109]. We replaced this residue (via cassette mutagenesis) by Ser, Gly, Ala, Thr, Asp and Pro. None of the replacements resulted in detectable alterations of the function of the ATP synthase, making a functional role for these sulfhydryl residues unlikely. Due to its high tolerance towards amino acid substitutions, the region around Cys21 seems not to be a protein-protein contact area.

Targeted mutagenesis of the b subunit of F1F0 ATP synthase in Escherichia coli: Glu-77 through Gln-85

Subunit b of Escherichia coli F1F0 ATP synthase contains a large hydrophilic region thought to be involved in the interaction between F1 and F0. Oligonucleotide-directed mutagenesis was used to evaluate the functional importance of a segment of this region from Glu-77 through Gln-85. The mutagenesis procedure employed a phagemid DNA template and a doped oligonucleotide primer designed to generate a predetermined collection of missense mutations in the target segment. Sixty-one mutant phagemids were identified and shown to contain nucleotide substitutions encoding 37 novel missense mutations. Mutations were isolated singly or in combinations of up to four mutations per recombinant phagemid. F1F0 ATP synthase function was studied by mutant phagemid complementation of a novel E. coli strain in which the uncF (b) gene was deleted. Complementation was assessed by observing growth on solid succinate minimal medium. Many phagemid-encoded uncF (b) gene mutations in the targeted segment resulted in growth phenotypes indistinguishable from those of strains expressing the native b subunit, suggesting abundant F1F0 ATP synthase activity. In contrast, several specific mutations were associated with a loss of enzyme function. Phagemids specifying the Ala-79----Pro, Arg-82----Pro, Arg-83----Pro, or Gln-85----Pro mutation failed to complement uncF (b) gene-deficient E. coli. F1F0 ATP synthase displayed the greatest sensitivity to mutations altering a single site in the target segment, Ala-79. The evidence suggests that Ala-79 occupies a restricted position in the enzyme complex.

Temperature-sensitive mutations at the carboxy terminus of the alpha subunit of the Escherichia coli F1F0 ATP synthase

Mutations were constructed in the a subunit of the F1F0 ATP synthase from Escherichia coli. Truncated forms of this subunit showed a temperature sensitivity phenotype. We conclude that the carboxy terminus of the a subunit is not involved directly with proton translocation but that it has an important structural role.

Mutagenesis of the a subunit of the F1F0-ATP synthase from Escherichia coli in the region of Asn-192

Site-directed cassette mutagenesis was used to generate a series of amino acid substitutions in the a subunit of the Escherichia coli F1F0-ATP synthase. The following substitutions for Asn-192 were analyzed and shown to inhibit partially the ATP-dependent proton translocation without disrupting F1-F0 interactions: Leu, Val, Pro, Ser, Thr, and Arg. A group of multiple substitutions at residues Gln-181, Asn-184, and His-185 had no significant effect on ATP synthase function, as judged by growth yields, or by assays of ATP-dependent proton translocation, indicating that this region of the a subunit is not involved in function. Three double mutants were constructed in order to assess the independence of residues Asn-192, Glu-196, and Asn-214. Results of proton translocation assays of membranes from cells containing these double mutations are consistent with the interpretation that each of these residues is involved with proton movement, and that residues Asn-192 and Glu-196 may be coupled. Finally, the relationship between the mechanism of proton translocation by the E. coli ATP synthase and the chloroplast enzyme was probed by constructing variants of the E. coli a subunit containing several features of homologous chloroplast proteins. It was determined that these chloroplast features, in the region of Glu-196 of the E. coli a subunit,, were detrimental to ATP synthase function.

Subunit delta of H(+)-ATPases: at the interface between proton flow and ATP synthesis

The ATP synthases in photophosphorylation and respiration are of the F-type with a membrane-bound proton channel, F0, and an extrinsic catalytic portion, F1. The properties of one particular subunit, delta (in chloroplasts and Escherichia coli) and OSCP (in mitochondria), are reviewed and the role of this subunit at the interface between F0 and F1 is discussed. Delta and OSCP from the three sources have in common the molecular mass (approximately 20 kDa), an elongated shape (axial ratio in solution about 3:1), one high-affinity binding site to F1 (Kd approximately 100 nM) plus probably one or two further low-affinity sites. When isolated delta is added to CF1-depleted thylakoid membranes, it can block proton flow through exposed CF0 channels, as do CF1 or CF1(-delta)+ delta. This identifies delta as part of the proton conductor or, alternatively, conformational energy transducer between F0 (proton flow) and F1 (ATP). Hybrid constructs as CF1(-delta)+ E. coli delta and EF1(-delta)+ chloroplast delta diminish proton flow through CF0.CF1(-delta) + E. coli delta does the same on EF0. Impairment of proton leaks either through CF0 or through EF0 causes "structural reconstitution' of ATP synthesis by remaining intact F0F1. Functional reconstitution (ATP synthesis by fully reconstructed F0F1), however, is absolutely dependent on the presence of subunit delta and is therefore observed only with CF1 or CF1(-delta) + chloroplast delta on CF0 and EF1 or EF1(-delta) + E. coli delta on EF0. The effect of hybrid constructs on F0 channels is surprising in view of the limited sequence homology between chloroplast and E. coli delta (36% conserved residues including conservative replacements). An analysis of the distribution of the conserved residues at present does not allow us to discriminate between the postulated conformational or proton-conductive roles of subunit delta.

Ribosome-binding sites and RNA-processing sites in the transcript of the Escherichia coli unc operon

The polycistronic mRNA encoding the nine genes of the unc operon of Escherichia coli was studied. We demonstrated the ribosome-binding capabilities of six of the nine unc genes, uncB, uncE, uncF, uncH, uncA, and uncD, by using the technique of primer extension inhibition or "toeprinting." No toeprint was detected for the other genes, uncI, uncG, and uncC. The lack of a toeprint for uncG suggests that this gene is expressed by some form of translational coupling, such that either uncG is read by ribosomes which have translated the preceding gene, uncA, or translation of uncA is required for ribosome binding at the uncG site. RNA sequencing and primer extension in the regions of uncI and uncC, the first and last genes in the operon, respectively, gave less intense signals than those obtained for the other unc genes. This suggested that there are fewer copies of those regions of the transcript and that processing of the unc transcript occurred. Using primer extension and RNA sequencing, we identified sites in the unc transcript at which processing appears to take place, including a site which may remove much of the uncI portion of the transcript. Northern (RNA) blot analysis of unc RNA is consistent with the presence of an RNA-processing site in the uncI region of the transcript and another in the uncH region. These processing events may account for some of the differential levels of expression of the unc genes.

Cross-reconstitution of the F0F1-ATP synthases of chloroplasts and Escherichia coli with special emphasis on subunit delta

F0F1-ATP synthases catalyse ATP formation from ADP and Pi by using the free energy supplied by the transmembrane electrochemical potential of the proton. The delta subunit of F1 plays an important role at the interface between the channel portion F0 and the catalytic portion F1. In chloroplasts it can plug the protonic conductance of CF0 and in Escherichia coli it is required for binding of EF1 to EF0. We wanted to know whether or not delta of one species was effective between F0 and F1 of the other species and vice versa. To this end the respective coupling membrane (thylakoids, everted vesicles from E. coli) was (partially) depleted of F1 and purified F1, F1(-delta), and delta were added in various combinations to the F1-depleted membranes. The efficiency or reconstitution was measured in thylakoids via the rate of phenazinemethosulfate-mediated cyclic photophosphorylation and in E. coli everted vesicles via the degree of 9-amino-6-chloro-2-methoxyacridine fluorescence quenching. Addition of CF1 to partially CF1-depleted thylakoid vesicles restored photophosphorylation to the highest extent. CF1(-delta)+chloroplast delta, EF1, EF1(-delta)+E. coli delta were also effective but to lesser extent. CF1(-delta)+E. coli delta and EF1(-delta)+chloroplast delta restored photophosphorylation to a small but still significant extent. With F1-depleted everted vesicles prepared by repeated EDTA treatment of E. coli membranes, addition of CF1, CF1 (-delta)+chloroplast delta and CF1(-delta)+E. coli delta gave approximately half the extent of 9-amino-6-chloro-2-methoxyacridine fluorescence quenching as compared to EF1 or EF1(-delta)+E. coli delta by energization of the vesicles with NADH, while Ef1(-delta)+chloroplast delta was ineffective. All 'mixed' combinations were probably reconstitutively active only by plugging the protonic leak through the exposed F0 (structural reconstitution) rather than by catalytic activity. Nevertheless, the cross-reconstitution is stunning in view of the weak sequence similarity between chloroplast delta and E. coli delta. It favors a role of delta as a conformational transducer rather than as a proton conductor between F0 and F1.

Defective gamma subunit of ATP synthase (F1F0) from Escherichia coli leads to resistance to aminoglycoside antibiotics

A strain of Escherichia coli which was derived from a gentamicin-resistant clinical isolate was found to be cross-resistant to neomycin and streptomycin. The molecular nature of the genetic defect was found to be an insertion of two GC base pairs in the uncG gene of the mutant. The insertion led to the production of a truncated gamma subunit of 247 amino acids in length instead of the 286 amino acids that are present in the normal gamma subunit. A plasmid which carried the ATP synthase genes from the mutant produced resistance to aminoglycoside antibiotics when it was introduced into a strain with a chromosomal deletion of the ATP synthase genes. Removal of the genes coding for the beta and epsilon subunits abolished antibiotic resistance coded by the mutant plasmid. The relationship between antibiotic resistance and the gamma subunit was investigated by testing the antibiotic resistance of plasmids carrying various combinations of unc genes. The presence of genes for the F0 portion of the ATP synthase in the presence or absence of genes for the gamma subunit was not sufficient to cause antibiotic resistance. alpha, beta, and truncated gamma subunits were detected on washed membranes of the mutant by immunoblotting. The first 247 amino acid residues of the gamma subunit may be sufficient to allow its association with other F1 subunits in such a way that the proton gate of F0 is held open by the mutant F1.

Proton leakiness caused by cloned genes for the F0 sector of the proton-translocating ATPase of Escherichia coli: requirement for F1 genes

To study expression of uncG, the gene coding for the gamma subunit of the Escherichia coli proton-translocating ATPase, deletions were made in the intergenic region between uncA, the gene coding for the alpha subunit, and uncG. Two deletions which fused uncA and uncG coded for alpha-gamma fusion polypeptides which were synthesized well both in vitro and in vivo, demonstrating that uncG expression is normally controlled by nucleotides in the intergenic region. Multicopy plasmids carrying these fusion genes and the genes for the other subunits of the ATPase had a harmful effect on the growth of E. coli. The effect was overcome by N,N'-dicyclohexylcarbodiimide, indicating that the cells probably leaked protons. The deleterious effect was eliminated by making a nonpolar deletion in the upstream F0 gene uncB, or by cloning each of the uncA-uncG fusion genes onto a separate plasmid, removed from the F0 genes, thus demonstrating that the fusion genes were not primarily responsible for the proton permeability. A plasmid which carried F0 genes and the gene for the delta subunit caused deleterious proton leakiness in unc+ cells but not in cells from which the unc operon was deleted. The proton leakiness caused by these different plasmids was therefore due to the production of a leaky F0 proton channel and required the presence of F1 genes. The results support a model for ATPase assembly in which F1 genes or polypeptides are involved in the formation or opening of the F0 proton channel.

A physical map of the Escherichia coli K12 genome

A physical map of a genome is the structure of its DNA. Construction of such a map is a first step in the complete characterization of that DNA. The restriction endonuclease Not I cuts the genome of Escherichia coli K12 into 22 DNA fragments ranging from 20 kilobases (20,000 base pairs) to 1000 kilobases. These can be separated by pulsed field gel electrophoresis. The order of the fragments in the genome was determined from available E. coli genetic information and analysis of partial digest patterns. The resulting ordered set of fragments is a macrorestriction map. This map facilitates genetic and molecular studies on E. coli, and its construction serves as a model for further endeavors on larger genomes.

Oxidation of reduced menaquinone by the fumarate reductase complex in Escherichia coli requires the hydrophobic FrdD peptide

Plasmids carrying cloned segments of the frd operon of Escherichia coli have been used in genetic complementation studies to identify two independent mutants defective in the frdD gene, which encodes the hydrophobic FrdD polypeptide of the fumarate reductase complex. Mutations in the frdA and frdB genes have also been mapped by this technique. One of the FrdD peptide mutants, DW109 (frdD-109), showed that fumarate reductase was not as tightly bound to the membrane in this mutant. In addition, the mutation in the FrdD peptide caused an almost total loss of the ability of the enzyme to oxidize either menaquinol-6, a physiological donor for fumarate reduction, or reduced benzyl viologen. However, the mutation did not impair the ability of the membrane-bound fumarate reductase complex to function with succinate as substrate, as evidenced by unchanged turnover numbers for phenazine methosulfate and 2,3-dimethoxy-5-methyl-6-pentyl-1,4-benzoquinone (a quinone analogue) reductase activities. These data establish the essential role of the FrdD polypeptide both in the interaction of the enzyme with reduced menaquinone and thus in anaerobic respiration with fumarate as electron acceptor, and in binding the enzyme to the membrane.

Synthesis of a functional F0 sector of the Escherichia coli H+-ATPase does not require synthesis of the alpha or beta subunits of F1

The uncB, E, F, and H genes of the Escherichia coli unc operon were cloned behind the lac promoter of plasmid pUC9, generating plasmid pBP101. These unc loci code, respectively, for the chi, omega, and psi subunits of the F0 sector and the delta subunit of the F1 sector of the H+-ATP synthase complex. Induction of expression of the four unc genes by the addition of isopropyl-beta-D-thiogalactoside resulted in inhibition of growth. During isopropyl-beta-D-thiogalactoside induction, the three subunits of F0 were integrated into the cytoplasmic membrane with a resultant increase in H+ permeability. A functional F0 was formed from plasmid pBP101 in a genetic background lacking all eight of the unc structural genes coding the F1F0 complex. In the unc deletion background, a reasonable correlation was observed between the amount of F0 incorporated into the membrane and the function measured, i.e., high-affinity binding of F1 and rate of F0-mediated H+ translocation. This correlation indicates that most or all of the F0 assembled in the membrane is active. Although the F0 assembled under these conditions binds F1, only partial restoration of NADH-dependent or ATP-dependent quenching of quinacrine fluorescence was observed with these membranes. Proteolysis of a fraction of the psi subunit may account for this partial deficiency. The experiments described demonstrate that a functional F0 can be assembled in vivo in E. coli strains lacking genes for the alpha, beta, gamma, and epsilon subunits of F1.

Synthesis of maize chloroplast ATP-synthase beta-subunit fusion proteins in Escherichia coli and binding to the inner membrane

The maize chloroplast gene for the beta subunit (atpB) of the chloroplast CF1 component of ATPase from maize, when fused to either the lacZ or ral genes in the vectors pMC1403 or pHUB4, is expressed in Escherichia coli as a fusion protein with beta-galactosidase or with bacteriophage lambda Ral sequences. Some of the fusion proteins are converted to a membrane-bound form, as determined by differential and sucrose-gradient centrifugation. The specificity of membrane binding has been examined using E. coli unc mutants that are defective in binding of the F1 ATPase component to the F0 receptor site on the membrane, and by the use of two different length maize atpB::lacZ gene fusions. We show that the first 365 N-terminal amino acids (aa) of the maize beta subunit are involved in binding to the E. coli inner membrane, and that this binding is probably mediated by the bacterial F0 receptor.