Arginine 41 of subunit c of Escherichia coli H(+)-ATP synthase is essential in binding and coupling of F1 to F0

Engineered Protein Model of the ATP synthase H+- Channel Shows No Salt Bridge at the Rotor-Stator Interface

ATP synthase is powered by the flow of protons through the molecular turbine composed of two α-helical integral membrane proteins, subunit a, which makes a stator, and a cylindrical rotor assembly made of multiple copies of subunit c. Transient protonation of a universally conserved carboxylate on subunit c (D61 in E. coli) gated by the electrostatic interaction with arginine on subunit a (R210 in E. coli) is believed to be a crucial step in proton transfer across the membrane. We used a fusion protein consisting of subunit a and the adjacent helices of subunit c to test by NMR spectroscopy if cD61 and aR210 are involved in an electrostatic interaction with each other, and found no evidence of such interaction. We have also determined that R140 does not form a salt bridge with either D44 or D124 as was suggested previously by mutation analysis. Our results demonstrate the potential of using arginines as NMR reporter groups for structural and functional studies of challenging membrane proteins.

ATP Synthesis by Oxidative Phosphorylation

The F1F0-ATP synthase (EC 3.6.1.34) is a remarkable enzyme that functions as a rotary motor. It is found in the inner membranes of Escherichia coli and is responsible for the synthesis of ATP in response to an electrochemical proton gradient. Under some conditions, the enzyme functions reversibly and uses the energy of ATP hydrolysis to generate the gradient. The ATP synthase is composed of eight different polypeptide subunits in a stoichiometry of α3β3γδεab2c10. Traditionally they were divided into two physically separable units: an F1 that catalyzes ATP hydrolysis (α3β3γδε) and a membrane-bound F0 sector that transports protons (ab2c10). In terms of rotary function, the subunits can be divided into rotor subunits (γεc10) and stator subunits (α3β3δab2). The stator subunits include six nucleotide binding sites, three catalytic and three noncatalytic, formed primarily by the β and α subunits, respectively. The stator also includes a peripheral stalk composed of δ and b subunits, and part of the proton channel in subunit a. Among the rotor subunits, the c subunits form a ring in the membrane, and interact with subunit a to form the proton channel. Subunits γ and ε bind to the c-ring subunits, and also communicate with the catalytic sites through interactions with α and β subunits. The eight subunits are expressed from a single operon, and posttranscriptional processing and translational regulation ensure that the polypeptides are made at the proper stoichiometry. Recent studies, including those of other species, have elucidated many structural and rotary properties of this enzyme.

Residues in the polar loop of subunit c in Escherichia coli ATP synthase function in gating proton transport to the cytoplasm

Rotary catalysis in F1F0 ATP synthase is powered by proton translocation through the membrane-embedded F0 sector. Proton binding and release occur in the middle of the membrane at Asp-61 on the second transmembrane helix (TMH) of subunit c, which folds in a hairpin-like structure with two TMHs. Previously, the aqueous accessibility of Cys substitutions in the transmembrane regions of subunit c was probed by testing the inhibitory effects of Ag(+) or Cd(2+) on function, which revealed extensive aqueous access in the region around Asp-61 and on the half of TMH2 extending to the cytoplasm. In the current study, we surveyed the Ag(+) and Cd(2+) sensitivity of Cys substitutions in the loop of the helical hairpin and used a variety of assays to categorize the mechanisms by which Ag(+) or Cd(2+) chelation with the Cys thiolates caused inhibition. We identified two distinct metal-sensitive regions in the cytoplasmic loop where function was inhibited by different mechanisms. Metal binding to Cys substitutions in the N-terminal half of the loop resulted in an uncoupling of F1 from F0 with release of F1 from the membrane. In contrast, substitutions in the C-terminal half of the loop retained membrane-bound F1 after metal treatment. In several of these cases, inhibition was shown to be due to blockage of passive H(+) translocation through F0 as assayed with F0 reconstituted into liposomes. The results suggest that the C-terminal domain of the cytoplasmic loop may function in gating H(+) translocation to the cytoplasm.

Complementation of the Fo c subunit of Escherichia coli with that of Streptococcus mutans and properties of the hybrid FoF1 ATP synthase

The c subunit of Streptococcus mutans ATP synthase (FoF1) is functionally exchangeable with that of Escherichia coli, since E. coli with a hybrid FoF1 is able to grow on minimum succinate medium through oxidative phosphorylation. E. coli F1 bound to the hybrid Fo with the S. mutans c subunit showed N,N'-dicyclohexylcarbodiimide-sensitive ATPase activity similar to that of E. coli FoF1. Thus, the S. mutans c subunit assembled into a functional Fo together with the E. coli a and b subunits, forming a normal F1 binding site. Although the H(+) pathway should be functional, as was suggested by the growth on minimum succinate medium, ATP-driven H(+) transport could not be detected with inverted membrane vesicles in vitro. This observation is partly explained by the presence of an acidic residue (Glu-20) in the first transmembrane helix of the S. mutans c subunit, since the site-directed mutant carrying Gln-20 partly recovered the ATP-driven H(+) transport. Since S. mutans is recognized to be a primary etiological agent of human dental caries and is one cause of bacterial endocarditis, our system that expresses hybrid Fo with the S. mutans c subunit would be helpful to find antibiotics and chemicals specifically directed to S. mutans.

Probing the rotor subunit interface of the ATP synthase from Ilyobacter tartaricus

The interaction between the c(11)ring and the gammaepsilon complex, forming the rotor of the Ilyobacter tartaricus ATP synthase, was probed by surface plasmon resonance spectroscopy and in vitro reconstitution analysis. The results provide, for the first time, a direct and quantitative assessment of the stability of the rotor. The data indicated very tight binding between the c(11)ring and the gammaepsilon complex, with an apparent K(d) value of approximately 7.4nm. The rotor assembly was primarily dependent on the interaction of the cring with the gammasubunit, and binding of the cring to the free epsilon subunit was not observed. Mutagenesis of selected conserved amino acid residues of all three rotor components (cR45, cQ46, gammaE204, gammaF203 and epsilonH38) severely affected rotor assembly. The interaction kinetics between the gammaepsilon complex and c(11)ring mutants suggested that the assembly of the c(11)gammaepsiloncomplex was governed by interactions of low and high affinity. Low-affinity binding was observed between the polar loops of the cring subunits and the bottom part of the gamma subunit. High-affinity interactions, involving the two residues gammaE204 and epsilonH38, stabilized the holo-c(11)gammaepsilon complex. NMR experiments indicated the acquisition of conformational order in otherwise flexible C- and N-terminal regions of the gamma subunit on rotor assembly. The results of this study suggest that docking of the central stalk of the F(1)complex to the rotor ring of F(o) to form tight, but reversible, contacts provides an explanation for the relative ease of dissociation and reconstitution of F(1)F(o)complexes.

Fluidity of structure and swiveling of helices in the subunit c ring of Escherichia coli ATP synthase as revealed by cysteine-cysteine cross-linking

Subunit c in the membrane-traversing F(0) sector of Escherichia coli ATP synthase is known to fold with two transmembrane helices and form an oligomeric ring of 10 or more subunits in the membrane. Models for the E. coli ring structure have been proposed based upon NMR solution structures and intersubunit cross-linking of Cys residues in the membrane. The E. coli models differ from the recent x-ray diffraction structure of the isolated Ilyobacter tartaricus c-ring. Furthermore, key cross-linking results supporting the E. coli model prove to be incompatible with the I. tartaricus structure. To test the applicability of the I. tartaricus model to the E. coli c-ring, we compared the cross-linking of a pair of doubly Cys substituted c-subunits, each of which was compatible with one model but not the other. The key finding of this study is that both A21C/M65C and A21C/I66C doubly substituted c-subunits form high yield oligomeric structures, c(2), c(3)... c(10), via intersubunit disulfide bond formation. The results indicate that helical swiveling, with resultant interconversion of the two conformers predicted by the E. coli and I. tartaricus models, must be occurring over the time course of the cross-linking experiment. In the additional experiments reported here, we tried to ascertain the preferred conformation in the membrane to help define the most likely structural model. We conclude that both structures must be able to form in the membrane, but that the helical swiveling that promotes their interconversion may not be necessary during rotary function.

Role of transmembrane segment M8 in the biogenesis and function of yeast plasma-membrane H(+)-ATPase

Of the four transmembrane helices (M4, M5, M6, and M8) that pack together to form the ion-binding sites of P(2)-type ATPases, M8 has until now received the least attention. The present study has used alanine-scanning mutagenesis to map structure-function relationships throughout M8 of the yeast plasma-membrane H(+)-ATPase. Mutant forms of the ATPase were expressed in secretory vesicles and at the plasma membrane for measurements of ATP hydrolysis and ATP-dependent H(+) pumping. In secretory vesicles, Ala substitutions at a cluster of four positions near the extracytoplasmic end of M8 led to partial uncoupling of H(+) transport from ATP hydrolysis, while substitution of Ser-800 (close to the middle of M8) by Ala increased the apparent stoichiometry of H(+) transport. A similar increase has previously been reported following the substitution of Glu-803 by Gln (Petrov, V. et al., J. Biol. Chem. 275:15709-15718, 2000) at a position known to contribute directly to Ca(2+) binding in the Ca(2+)-ATPase of sarcoplasmic reticulum (Toyoshima, C., et al., Nature 405: 647-655, 2000). Four other mutations in M8 interfered with H(+)-ATPase folding and trafficking to the plasma membrane; based on homology modeling, they occupy positions that appear important for the proper bundling of M8 with M5, M6, M7, and M10. Taken together, these results point to a key role for M8 in the biogenesis, stability, and physiological functioning of the H(+)-ATPase.

Mutations in the Atp1p and Atp3p subunits of yeast ATP synthase differentially affect respiration and fermentation in Saccharomyces cerevisiae

ATP1-111, a suppressor of the slow-growth phenotype of yme1Delta lacking mitochondrial DNA is due to the substitution of phenylalanine for valine at position 111 of the alpha-subunit of mitochondrial ATP synthase (Atp1p in yeast). The suppressing activity of ATP1-111 requires intact beta (Atp2p) and gamma (Atp3p) subunits of mitochondrial ATP synthase, but not the stator stalk subunits b (Atp4p) and OSCP (Atp5p). ATP1-111 and other similarly suppressing mutations in ATP1 and ATP3 increase the growth rate of wild-type strains lacking mitochondrial DNA. These suppressing mutations decrease the growth rate of yeast containing an intact mitochondrial chromosome on media requiring oxidative phosphorylation, but not when grown on fermentable media. Measurement of chronological aging of yeast in culture reveals that ATP1 and ATP3 suppressor alleles in strains that contain mitochondrial DNA are longer lived than the isogenic wild-type strain. In contrast, the chronological life span of yeast cells lacking mitochondrial DNA and containing these mutations is shorter than that of the isogenic wild-type strain. Spore viability of strains bearing ATP1-111 is reduced compared to wild type, although ATP1-111 enhances the survival of spores that lacked mitochondrial DNA.

Structural model of the transmembrane Fo rotary sector of H+-transporting ATP synthase derived by solution NMR and intersubunit cross-linking in situ

H(+)-transporting, F(1)F(o)-type ATP synthases utilize a transmembrane H(+) potential to drive ATP formation by a rotary catalytic mechanism. ATP is formed in alternating beta subunits of the extramembranous F(1) sector of the enzyme, synthesis being driven by rotation of the gamma subunit in the center of the F(1) molecule between the alternating catalytic sites. The H(+) electrochemical potential is thought to drive gamma subunit rotation by first coupling H(+) transport to rotation of an oligomeric rotor of c subunits within the transmembrane F(o) sector. The gamma subunit is forced to turn with the c-oligomeric rotor due to connections between subunit c and the gamma and epsilon subunits of F(1). In this essay we will review recent studies on the Escherichia coli F(o) sector. The monomeric structure of subunit c, determined by NMR, shows that subunit c folds in a helical hairpin with the proton carrying Asp(61) centered in the second transmembrane helix (TMH). A model for the structural organization of the c(10) oligomer in F(o) was deduced from extensive cross-linking studies and by molecular modeling. The model indicates that the H(+)-carrying carboxyl of subunit c is occluded between neighboring subunits of the c(10) oligomer and that two c subunits pack in a "front-to-back" manner to form the H(+) (cation) binding site. In order for protons to gain access to Asp(61) during the protonation/deprotonation cycle, we propose that the outer, Asp(61)-bearing TMH-2s of the c-ring and TMHs from subunits composing the inlet and outlet channels must turn relative to each other, and that the swiveling motion associated with Asp(61) protonation/deprotonation drives the rotation of the c-ring. The NMR structures of wild-type subunit c differs according to the protonation state of Asp(61). The idea that the conformational state of subunit c changes during the catalytic cycle is supported by the cross-linking evidence in situ, and two recent NMR structures of functional mutant proteins in which critical residues have been switched between TMH-1 and TMH-2. The structural information is considered in the context of the possible mechanism of rotary movement of the c(10) oligomer during coupled synthesis of ATP.

Insights into the rotary catalytic mechanism of F0F1 ATP synthase from the cross-linking of subunits b and c in the Escherichia coli enzyme

The transmembrane sector of the F(0)F(1) rotary ATP synthase is proposed to organize with an oligomeric ring of c subunits, which function as a rotor, interacting with two b subunits at the periphery of the ring, the b subunits functioning as a stator. In this study, cysteines were introduced into the C-terminal region of subunit c and the N-terminal region of subunit b. Cys of N2C subunit b was cross-linked with Cys at positions 74, 75, and 78 of subunit c. In each case, a maximum of 50% of the b subunit could be cross-linked to subunit c, which suggests that either only one of the two b subunits lie adjacent to the c-ring or that both b subunits interact with a single subunit c. The results support a topological arrangement of these subunits, in which the respective N- and C-terminal ends of subunits b and c extend to the periplasmic surface of the membrane and cAsp-61 lies at the center of the membrane. The cross-linking of Cys between bN2C and cV78C was shown to inhibit ATP-driven proton pumping, as would be predicted from a rotary model for ATP synthase function, but unexpectedly, cross-linking did not lead to inhibition of ATPase activity. ATP hydrolysis and proton pumping are therefore uncoupled in the cross-linked enzyme. The c subunit lying adjacent to subunit b was shown to be mobile and to exchange with c subunits that initially occupied non-neighboring positions. The movement or exchange of subunits at the position adjacent to subunit b was blocked by dicyclohexylcarbodiimide. These experiments provide a biochemical verification that the oligomeric c-ring can move with respect to the b-stator and provide further support for a rotary catalytic mechanism in the ATP synthase.

The ATP synthase of Escherichia coli: structure and function of F(0) subunits

In this review we discuss recent work from our laboratory concerning the structure and/or function of the F(0) subunits of the proton-translocating ATP synthase of Escherichia coli. For the topology of subunit a a brief discussion gives (i) a detailed picture of the C-terminal two-thirds of the protein with four transmembrane helices and the C terminus exposed to the cytoplasm and (ii) an evaluation of the controversial results obtained for the localization of the N-terminal region of subunit a including its consequences on the number of transmembrane helices. The structure of membrane-bound subunit b has been determined by circular dichroism spectroscopy to be at least 75% alpha-helical. For this purpose a method was developed, which allows the determination of the structure composition of membrane proteins in proteoliposomes. Subunit b was purified to homogeneity by preparative SDS gel electrophoresis, precipitated with acetone, and redissolved in cholate-containing buffer, thereby retaining its native conformation as shown by functional coreconstitution with an ac subcomplex. Monoclonal antibodies, which have their epitopes located within the hydrophilic loop region of subunit c, and the F(1) part are bound simultaneously to the F(0) complex without an effect on the function of F(0), indicating that not all c subunits are involved in F(1) interaction. Consequences on the coupling mechanism between ATP synthesis/hydrolysis and proton translocation are discussed.

Structural interpretations of F(0) rotary function in the Escherichia coli F(1)F(0) ATP synthase

F(1)F(0) ATP synthases are known to synthesize ATP by rotary catalysis in the F(1) sector of the enzyme. Proton translocation through the F(0) membrane sector is now proposed to drive rotation of an oligomer of c subunits, which in turn drives rotation of subunit gamma in F(1). The primary emphasis of this review will be on recent work from our laboratory on the structural organization of F(0), which proves to be consistent with the concept of a c(12) oligomeric rotor. From the NMR structure of subunit c and cross-linking studies, we can now suggest a detailed model for the organization of the c(12) oligomer in F(0) and some of the transmembrane interactions with subunits a and b. The structural model indicates that the H(+)-carrying carboxyl of subunit c is located between subunits of the c(12) oligomer and that two c subunits pack in a front-to-back manner to form the proton (cation) binding site. The proton carrying Asp61 side chain is occluded between subunits and access to it, for protonation and deprotonation via alternate entrance and exit half-channels, requires a swiveled opening of the packed c subunits and stepwise association with different transmembrane helices of subunit a. We suggest how some of the structural information can be incorporated into models of rotary movement of the c(12) oligomer during coupled synthesis of ATP in the F(1) portion of the molecule.

Secondary structure composition of reconstituted subunit b of the Escherichia coli ATP synthase

Subunit b of the Escherichia coli ATP synthase was isolated by preparative gel electrophoresis, acetone precipitated and after ion-pair extraction redissolved in a buffer either containing n-dodecyl-beta-D-maltoside or sodium cholate. The secondary structure of isolated subunit b was shown to be the same as within the FO complex, but was strongly dependent on the detergent used for replacement of the phospholipid environment. This was shown by an identical tryptic digestion pattern, which was strongly influenced by the detergent used for solubilization. An influence of the detergent n-dodecyl-beta-D-maltoside on the secondary structure of the hydrophilic part of subunit b was also shown for the soluble part of the polypeptide comprising residues Val25 to Leu156 (bsol) using CD spectroscopy. In order to determine the secondary structure of subunit b in its native conformation, isolated subunit b was reconstituted into E. coli lipid vesicles and analyzed with CD spectroscopy. The resulting spectrum revealed a secondary structure composition of 80% alpha helix together with 14% beta turn conformation. These results suggest that subunit b is not a rigid rod-like alpha helix simply linking F1 to FO, but rather provides an inherent flexibility for the storage of elastic energy within the second stalk generated by rotational movements within the F1FO complex.

F0 complex of the Escherichia coli ATP synthase. Not all monomers of the subunit c oligomer are involved in F1 interaction

The antigenic determinants of mAbs against subunit c of the Escherichia coli ATP synthase were mapped by ELISA using overlapping synthetic heptapeptides. All epitopes recognized are located in the hydrophilic loop region and are as follows: 31-LGGKFLE-37, 35-FLEGAAR-41, 36-LEGAAR-41 and 36-LEGAARQ-42. Binding studies with membrane vesicles of different orientation revealed that all mAbs bind to everted membrane vesicles independent of the presence or absence of the F1 part. Although the hydrophilic region of subunit c and particularly the highly conserved residues A40, R41, Q42 and P43 are known to interact with subunits gamma and epsilon of the F1 part, the mAb molecules have no effect on the function of F0. Furthermore, it could be demonstrated that the F1 part and the mAb molecule(s) are bound simultaneously to the F0 complex suggesting that not all c subunits are involved in F1 interaction. From the results obtained, it can be concluded that this interaction is fixed, which means that subunits gamma and epsilon do not switch between the c subunits during catalysis and furthermore, a complete rotation of the subunit c oligomer modified with mAb(s) along the stator of the F1F0 complex, proposed to be composed of at least subunits b and delta, seems to be unlikely.

Defining the domain of binding of F1 subunit epsilon with the polar loop of F0 subunit c in the Escherichia coli ATP synthase

We have previously shown that the E31C-substituted epsilon subunit of F1 can be cross-linked by disulfide bond formation to the Q42C-substituted c subunit of F0 in the Escherichia coli F1F0-ATP synthase complex (Zhang, Y., and Fillingame, R. H. (1995) J. Biol. Chem. 270, 24609-24614). The interactions of subunits epsilon and c are thought to be central to the coupling of H+ transport through F0 to ATP synthesis in F1. To further define the domains of interaction, we have introduced additional Cys into subunit epsilon and subunit c and tested for cross-link formation following sulfhydryl oxidation. The results show that Cys, in a continuous stretch of residues 26-33 in subunit epsilon, can be cross-linked to Cys at positions 40, 42, and 44 in the polar loop region of subunit c. The results are interpreted, and the subunit interaction is modeled using the NMR and x-ray diffraction structures of the monomeric subunits together with information on the packing arrangement of subunit c in a ring of 12 subunits. In the model, residues 26-33 form a turn of antiparallel beta-sheet which packs between the polar loop regions of adjacent subunit c at the cytoplasmic surface of the c12 oligomer.

A mutation in the Escherichia coli F0F1-ATP synthase rotor, gammaE208K, perturbs conformational coupling between transport and catalysis

Cross-linking studies on the Escherichia coli F0F1-ATP synthase indicated a site of interaction involving gamma and epsilon subunits in F1 and subunit c in F0 (Watts, S. D., Tang, C., and Capaldi, R. A. (1996) J. Biol. Chem. 271, 28341-28347). To assess the function of these interactions, we introduced random mutations in this region of the gamma subunit (gamma194-213). One mutation, gammaGlu-208 to Lys (gammaE208K), caused a temperature-sensitive defect in oxidative phosphorylation-dependent growth. ATP hydrolytic rates of the gammaE208K F0F1 enzyme became increasingly uncoupled from H+ pumping above 28 degreesC. In contrast, Arrhenius plot of steady-state ATP hydrolysis of the mutant enzyme was linear from 20 to 50 degreesC. Analysis of this plot revealed a significant increase in the activation energy of the catalytic transition state to a value very similar to soluble, epsilon subunit-inhibited F1 and suggested that the mutation blocked normal release of epsilon inhibition of ATP hydrolytic activity upon binding of F1 to F0. The difference in temperature dependence suggested that the gammaE208K mutation perturbed release of inhibition via a different mechanism than it did energy coupling. Suppressor mutations in the polar loop of subunit c restored ATP-dependent H+ pumping and transition state thermodynamic parameters close to wild-type values indicating that interactions between gamma and c subunits mediate release of epsilon inhibition and communication of coupling information.

Identification of an uncoupling mutation affecting the b subunit of F1F0 ATP synthase in Escherichia coli

A specific b subunit arginine, b(Arg-36) in Escherichia coli, displays evolutionary conservation among bacterial F1F0 ATP synthases. Site-directed mutagenesis was used to generate a collection of mutations affecting b(Arg-36). The phenotype differed depending upon the substitution, and the b(Arg-36-Glu) and b(Arg-36-Ile) substitutions virtually abolished enzyme function. Although the total amounts of F1F0 ATP synthase present in the membranes prepared from mutant strains were reduced, the primary effect of the b(Arg-36) substitutions was on the activities of the intact enzyme complexes. The most interesting result was that the b(Arg-36-Glu) substitution results in the uncoupling of a functional F0 from F1 ATP hydrolysis activity.

On the role of Arg-210 and Glu-219 of subunit a in proton translocation by the Escherichia coli F0F1-ATP synthase

A strain of Escherichia coli was constructed which had a complete deletion of the chromosomal uncB gene encoding subunit a of the F0F1-ATP synthase. Gene replacement was facilitated by a selection protocol that utilized the sacB gene of Bacillus subtilis cloned in a kanamycin resistance cartridge (Ried, J. L., and Collmer, A. (1987) Gene (Amst.) 57, 239-246). F0 subunits b and c inserted normally into the membrane in the DeltauncB strain. This observation confirms a previous report (Hermolin, J., and Fillingame, R. H. (1995) J. Biol. Chem. 270, 2815-2817) that subunit a is not required for the insertion of subunits b and c. The DeltauncB strain has been used to characterize mutations in Arg-210 and Glu-219 of subunit a, residues previously postulated to be essential in proton translocation. The aE219G and aE219K mutants grew on a succinate carbon source via oxidative phosphorylation and membranes from these mutants exhibited ATPase-coupled proton translocation (i.e. ATP driven 9-amino-6-chloromethoxyacridine quenching responses that were 60-80% of wild type membranes). We conclude that the aGlu-219 residue cannot play a critical role in proton translocation. The aR210A mutant did not grow on succinate and membranes exhibited no ATPase-coupled proton translocation. However, on removal of F1 from membrane, the aR210A mutant F0 was active in passive proton translocation, i.e. in dissipating the DeltapH normally established by NADH oxidation with these membrane vesicles. aR210A membranes with F1 bound were also proton permeable. Arg-210 of subunit a may play a critical role in active H+ transport that is coupled to ATP synthesis or hydrolysis, but is not essential for the translocation of protons across the membranes.

Catalytic mechanism of F1-ATPase

The structure of the core catalytic unit of ATP synthase, alpha 3 beta 3 gamma, has been determined by X-ray crystallography, revealing a roughly symmetrical arrangement of alternating alpha and beta subunits around a central cavity in which helical portions of gamma are found. A low-resolution structural model of F0, based on electron spectroscopic imaging, locates subunit a and the two copies of subunit b outside of a subunit c oligomer. The structures of individual subunits epsilon and c (largely) have been solved by NMR spectroscopy, but the oligomeric structure of c is still unknown. The structures of subunits a and delta remain undefined, that of b has not yet been defined but biochemical evidence indicates a credible model. Subunits gamma, epsilon, b, and delta are at the interface between F1 and F0; gamma epsilon complex forms one element of the stalk, interacting with c at the base and alpha and beta at the top. The locations of b and delta are less clear. Elucidation of the structure F0, of the stalk, and of the entire F1F0 remains a challenging goal.

Energy coupling, turnover, and stability of the F0F1 ATP synthase are dependent on the energy of interaction between gamma and beta subunits

Replacement of the F0F1 ATP synthase gamma subunit Met-23 with Lys (gammaM23K) perturbs coupling efficiency between transport and catalysis (Shin, K., Nakamoto, R. K., Maeda, M., and Futai, M. (1992) J. Biol. Chem. 267, 20835-20839). We demonstrate here that the gammaM23K mutation causes altered interactions between subunits. Binding of delta or epsilon subunits stabilizes the alpha3beta3gamma complex, which becomes destabilized by the mutation. Significantly, the inhibition of F1 ATP hydrolysis by the epsilon subunit is no longer relieved when the gammaM23K mutant F1 is bound to F0. Steady state Arrhenius analysis reveals that the gammaM23K enzyme has increased activation energies for the catalytic transition state. These results suggest that the mutation causes the formation of additional bonds within the enzyme that must be broken in order to achieve the transition state. Based on the x-ray crystallographic structure of Abrahams et al. (Abrahams, J. P., Leslie, A. G. W., Lutter, R., and Walker, J. E. (1994) Nature 370, 621-628), the additional bond is likely due to gammaM23K forming an ionized hydrogen bond with one of the betaGlu-381 residues. Two second site mutations, gammaQ269R and gammaR242C, suppress the effects of gammaM23K and decrease activation energies for the gammaM23K enzyme. We conclude that gammaM23K is an added function mutation that increases the energy of interaction between gamma and beta subunits. The additional interaction perturbs transmission of conformational information such that epsilon inhibition of ATPase activity is not relieved and coupling efficiency is lowered.

The effect of mild trypsin digestion of F1 on energy coupling in the mitochondrial ATP synthase

Mild trypsin digestion of isolated bovine-heart mitochondrial F1-ATPase removed the first 15 residues from the N-terminus of subunit alpha under conditions in which other F1 subunits were apparently untouched. When the trypsinized F1 (TF1) was reconstituted with the F0 sector in the mitochondrial membrane (USMP), the ATP hydrolase activity acquired oligomycin sensitivity but ATP hydrolysis was decoupled from proton pumping. TF1 added to USMP did not block the proton channel in F0 as the native F1 did. AMP-PNP inhibited proton conductivity in reconstituted F1-USMP but this effect was lost in reconstituted TF1-USMP. These results indicate that the N-terminus of the F1 alpha subunit plays a critical role in the conformational communication between F1 and F0.

The F0F1-type ATP synthases of bacteria: structure and function of the F0 complex

Membrane-bound ATP synthases (F0F1-ATPases) of bacteria serve two important physiological functions. The enzyme catalyzes the synthesis of ATP from ADP and inorganic phosphate utilizing the energy of an electrochemical ion gradient. On the other hand, under conditions of low driving force, ATP synthases function as ATPases, thereby generating a transmembrane ion gradient at the expense of ATP hydrolysis. The enzyme complex consists of two structurally and functionally distinct parts: the membrane-integrated ion-translocating F0 complex and the peripheral F1 complex, which carries the catalytic sites for ATP synthesis and hydrolysis. The ATP synthase of Escherichia coli, which has been the most intensively studied one, is composed of eight different subunits, five of which belong to F1, subunits alpha, beta, gamma, delta, and epsilon (3:3:1:1:1), and three to F0, subunits a, b, and c (1:2:10 +/- 1). The similar overall structure and the high amino acid sequence homology indicate that the mechanism of ion translocation and catalysis and their mode of coupling is the same in all organisms.

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.

Changing the ion binding specificity of the Escherichia coli H(+)-transporting ATP synthase by directed mutagenesis of subunit c

Most F1F0 type ATP synthases, including that in Escherichia coli, use H+ as the coupling ion for ATP synthesis. However, the structurally related F1F0 ATP synthase in Propionigenium modestum uses Na+ instead. The binding site for Na+ residues in the F0 sector of the P. modestum enzyme. We postulated that Na+ might interact with subunit c of F0. Subunit c of P. modestum and E. coli are reasonably homologous (19% identity) but show striking variations around the H(+)-translocating, dicyclohexylcarbodiimide-reactive carboxyl (Asp61 in E. coli). Several hydrophobic residues around Asp61 were replaced with polar residues according to the P. modestum sequence in the hope that the polar replacements might provide liganding groups for Na+. One mutant from 31 different mutation combinations did generate an active enzyme that binds Li+, the combination being V60A, D61E, A62S, and I63T. Li+ binding was detected by Li+ inhibition of ATP-driven H+ transport, Li+ inhibition of F1F0-ATPase activity, and Li+ inhibition of F0-mediated H+ transport. The Li+ effects were observed with membrane vesicles prepared from a delta nhaA, delta nhaB mutant background which lacks Na+/H+ antiporters, and with purified, reconstituted preparations of F0 prepared from this background strain. Li+ inhibition was observed at pH 8.5 but not at pH 7.0. H+ thus appears to compete with Li+ for the binding site. Li+ binding was abolished by replacement of Glu61 by Asp or Ser62 by Ala. The side chains at Ala60 and Thr63 may act in a supporting structural role by providing a more flexible conformation for the Li+ binding cavity. Thr63 does not appear to provide a liganding group since H+ transport in two other mutants, with Gly or Ala in place of Thr63, was also inhibited by Li+. We suggest that a X-Glu-Ser-Y or X-Glu-Thr-Y sequence may provide a general structural motif for monovalent cation binding, and that the flexibility provided by residues X and Y will prove crucial to this structure.

Hybrid Fo complexes of the ATP synthases of spinach chloroplasts and Escherichia coli. Immunoprecipitation and mutant analyses

Hybrid Fo complexes of the ATP synthases of spinach chloroplast (CFo) and Escherichia coli (EFo) were investigated. Immunoprecipitations with polyclonal antibodies against the different Fo subunits clearly revealed that hybrid Fo complexes derived from CFo subunit III and EFo subunits a and b were formed in vivo. In addition, the ATPase activities of the hybrid ATP synthase, measured in everted cytoplasmic membranes of an atpE mutant strain transformed with the atpH gene coding for CFo III, were comparable to activities obtained for the same mutant strain complemented with the atpE gene (EFo c). Nevertheless, CFo III was not able to replace EFo c functionally, since the strain containing the hybrid ATP synthase was not able to grow on succinate. In order to investigate the reason for this lack of function, hybrid proteolipids of CFo III and EFo c were constructed. Only a chimaeric protein comprising the seven N-terminal amino acid residues from CFo III and the remaining part of EFo c was able to replace wild-type EFo c, whereas hybrid proteins with 13 and 33 N-terminal amino acids of CFo III were not functional. The results suggested that a network of interactions between the subunits essential for proton translocation and/or coupling of the F1 part exists, which was optimized for each species during evolution, although the overall structure of FoF1 complexes has been conserved.