Mutagenesis of the alpha subunit of the F1Fo-ATPase from Escherichia coli. Mutations at Glu-196, Pro-190, and Ser-199

Mechanism of proton-powered c-ring rotation in a mitochondrial ATP synthase

Proton-powered c-ring rotation in mitochondrial ATP synthase is crucial to convert the transmembrane protonmotive force into torque to drive the synthesis of adenosine triphosphate (ATP). Capitalizing on recent cryo-EM structures, we aim at a structural and energetic understanding of how functional directional rotation is achieved. We performed multi-microsecond atomistic simulations to determine the free energy profiles along the c-ring rotation angle before and after the arrival of a new proton. Our results reveal that rotation proceeds by dynamic sliding of the ring over the a-subunit surface, during which interactions with conserved polar residues stabilize distinct intermediates. Ordered water chains line up for a Grotthuss-type proton transfer in one of these intermediates. After proton transfer, a high barrier prevents backward rotation and an overall drop in free energy favors forward rotation, ensuring the directionality of c-ring rotation required for the thermodynamically disfavored ATP synthesis. The essential arginine of the a-subunit stabilizes the rotated configuration through a salt bridge with the c-ring. Overall, we describe a complete mechanism for the rotation step of the ATP synthase rotor, thereby illuminating a process critical to all life at atomic resolution.

Mutational analysis of a conserved positive charge in the c-ring of E. coli ATP synthase

F1Fo ATP synthase is a ubiquitous molecular motor that utilizes a rotary mechanism to synthesize adenosine triphosphate (ATP), the fundamental energy currency of life. The membrane-embedded Fo motor converts the electrochemical gradient of protons into rotation, which is then used to drive the conformational changes in the soluble F1 motor that catalyze ATP synthesis. In E. coli, the Fo motor is composed of a c10 ring (rotor) alongside subunit a (stator), which together provide two aqueous half channels that facilitate proton translocation. Previous work has suggested that Arg50 and Thr51 on the cytoplasmic side of each subunit c are involved in the proton translocation process, and positive charge is conserved in this region of subunit c. To further investigate the role of these residues and the chemical requirements for activity at these positions, we generated 13 substitution mutants and assayed their in vitro ATP synthesis, H+ pumping, and passive H+ permeability activities, as well as the ability of mutants to carry out oxidative phosphorylation in vivo. While polar and hydrophobic mutations were generally tolerated in either position, introduction of negative charge or removal of polarity caused a substantial defect. We discuss the possible effects of altered electrostatics on the interaction between the rotor and stator, water structure in the aqueous channel, and interaction of the rotor with cardiolipin.

F1FO ATP synthase molecular motor mechanisms

The F-ATP synthase, consisting of F1 and FO motors connected by a central rotor and the stators, is the enzyme responsible for synthesizing the majority of ATP in all organisms. The F1 (αβ)3 ring stator contains three catalytic sites. Single-molecule F1 rotation studies revealed that ATP hydrolysis at each catalytic site (0°) precedes a power-stroke that rotates subunit-γ 120° with angular velocities that vary with rotational position. Catalytic site conformations vary relative to subunit-γ position (βE, empty; βD, ADP bound; βT, ATP-bound). During a power stroke, βE binds ATP (0°–60°) and βD releases ADP (60°–120°). Årrhenius analysis of the power stroke revealed that elastic energy powers rotation via unwinding the γ-subunit coiled-coil. Energy from ATP binding at 34° closes βE upon subunit-γ to drive rotation to 120° and forcing the subunit-γ to exchange its tether from βE to βD, which changes catalytic site conformations. In F1FO, the membrane-bound FO complex contains a ring of c-subunits that is attached to subunit-γ. This c-ring rotates relative to the subunit-a stator in response to transmembrane proton flow driven by a pH gradient, which drives subunit-γ rotation in the opposite direction to force ATP synthesis in F1. Single-molecule studies of F1FO embedded in lipid bilayer nanodisks showed that the c-ring transiently stopped F1-ATPase-driven rotation every 36° (at each c-subunit in the c10-ring of E. coli F1FO) and was able to rotate 11° in the direction of ATP synthesis. Protonation and deprotonation of the conserved carboxyl group on each c-subunit is facilitated by separate groups of subunit-a residues, which were determined to have different pKa’s. Mutations of any of any residue from either group changed both pKa values, which changed the occurrence of the 11° rotation proportionately. This supports a Grotthuss mechanism for proton translocation and indicates that proton translocation occurs during the 11° steps. This is consistent with a mechanism in which each 36° of rotation the c-ring during ATP synthesis involves a proton translocation-dependent 11° rotation of the c-ring, followed by a 25° rotation driven by electrostatic interaction of the negatively charged unprotonated carboxyl group to the positively charged essential arginine in subunit-a.

pH-dependent 11° F1FO ATP synthase sub-steps reveal insight into the FO torque generating mechanism

Most cellular ATP is made by rotary F₁F_O ATP synthases using proton translocation-generated clockwise torque on the F_O c-ring rotor, while F₁-ATP hydrolysis can force counterclockwise rotation and proton pumping. The F_O torque-generating mechanism remains elusive even though the F_O interface of stator subunit-a, which contains the transmembrane proton half-channels, and the c-ring is known from recent F₁F_O structures. Here, single-molecule F₁F_O rotation studies determined that the pKa values of the half-channels differ, show that mutations of residues in these channels change the pKa values of both half-channels, and reveal the ability of F_O to undergo single c-subunit rotational stepping. These experiments provide evidence to support the hypothesis that proton translocation through F_O operates via a Grotthuss mechanism involving a column of single water molecules in each half-channel linked by proton translocation-dependent c-ring rotation. We also observed pH-dependent 11° ATP synthase-direction sub-steps of the Escherichia coli c₁₀-ring of F₁F_O against the torque of F₁-ATPase-dependent rotation that result from H⁺ transfer events from F_O subunit-a groups with a low pKa to one c-subunit in the c-ring, and from an adjacent c-subunit to stator groups with a high pKa. These results support a mechanism in which alternating proton translocation-dependent 11° and 25° synthase-direction rotational sub-steps of the c₁₀-ring occur to sustain F₁F_O ATP synthesis.

Structure of a bacterial ATP synthase

ATP synthases produce ATP from ADP and inorganic phosphate with energy from a transmembrane proton motive force. Bacterial ATP synthases have been studied extensively because they are the simplest form of the enzyme and because of the relative ease of genetic manipulation of these complexes. We expressed the Bacillus PS3 ATP synthase in Eschericia coli, purified it, and imaged it by cryo-EM, allowing us to build atomic models of the complex in three rotational states. The position of subunit ε shows how it is able to inhibit ATP hydrolysis while allowing ATP synthesis. The architecture of the membrane region shows how the simple bacterial ATP synthase is able to perform the same core functions as the equivalent, but more complicated, mitochondrial complex. The structures reveal the path of transmembrane proton translocation and provide a model for understanding decades of biochemical analysis interrogating the roles of specific residues in the enzyme.

Molecular basis of diseases caused by the mtDNA mutation m.8969G>A in the subunit a of ATP synthase

The ATP synthase which provides aerobic eukaryotes with ATP, organizes into a membrane-extrinsic catalytic domain, where ATP is generated, and a membrane-embedded F_O domain that shuttles protons across the membrane. We previously identified a mutation in the mitochondrial MT-ATP6 gene (m.8969G>A) in a 14-year-old Chinese female who developed an isolated nephropathy followed by brain and muscle problems. This mutation replaces a highly conserved serine residue into asparagine at amino acid position 148 of the membrane-embedded subunit a of ATP synthase. We showed that an equivalent of this mutation in yeast (aS₁₇₅N) prevents F_O-mediated proton translocation. Herein we identified four first-site intragenic suppressors (aN₁₇₅D, aN₁₇₅K, aN₁₇₅I, and aN₁₇₅T), which, in light of a recently published atomic structure of yeast F_O indicates that the detrimental consequences of the original mutation result from the establishment of hydrogen bonds between aN₁₇₅ and a nearby glutamate residue (aE₁₇₂) that was proposed to be critical for the exit of protons from the ATP synthase towards the mitochondrial matrix. Interestingly also, we found that the aS₁₇₅N mutation can be suppressed by second-site suppressors (aP₁₂S, aI₁₇₁F, aI₁₇₁N, aI₂₃₉F, and aI₂₀₀M), of which some are very distantly located (by 20-30 Å) from the original mutation. The possibility to compensate through long-range effects the aS₁₇₅N mutation is an interesting observation that holds promise for the development of therapeutic molecules.

The 3.5-Å CryoEM Structure of Nanodisc-Reconstituted Yeast Vacuolar ATPase Vo Proton Channel

The molecular mechanism of transmembrane proton translocation in rotary motor ATPases is not fully understood. Here, we report the 3.5-Å resolution cryoEM structure of the lipid nanodisc-reconstituted V_o proton channel of the yeast vacuolar H⁺-ATPase, captured in a physiologically relevant, autoinhibited state. The resulting atomic model provides structural detail for the amino acids that constitute the proton pathway at the interface of the proteolipid ring and subunit a. Based on the structure and previous mutagenesis studies, we propose the chemical basis of transmembrane proton transport. Moreover, we discovered that the C terminus of the assembly factor Voa1 is an integral component of mature V_o. Voa1's C-terminal transmembrane α helix is bound inside the proteolipid ring, where it contributes to the stability of the complex. Our structure rationalizes possible mechanisms by which mutations in human V_o can result in disease phenotypes and may thus provide new avenues for therapeutic interventions.

Protonation-dependent stepped rotation of the F-type ATP synthase c-ring observed by single-molecule measurements

The two opposed rotary molecular motors of the F0F1-ATP synthase work together to provide the majority of ATP in biological organisms. Rotation occurs in 120° power strokes separated by dwells when F1 synthesizes or hydrolyzes ATP. F0 and F1 complexes connect via a central rotor stalk and a peripheral stator stalk. A major unresolved question is the mechanism in which the interaction between subunit-a and rotating subunit-c-ring in the F0 motor uses the flux of H+ across the membrane to induce clockwise rotation against the force of counterclockwise rotation driven by the F1-ATPase. In single-molecule measurements of F0F1 embedded in lipid bilayer nanodiscs, we observed that the ability of the F0 motor to form transient dwells increases with decreasing pH. Transient dwells can halt counterclockwise rotation powered by the F1-ATPase in steps equivalent to the rotation of single c-subunits in the c-ring of F0, and can push the common axle shared by the two motors clockwise by as much as one c-subunit. Because the F0 proton half-channels that access the periplasm and the cytoplasm are exposed to the same pH, these data are consistent with the conclusion that the periplasmic half-channel is more easily protonated in a manner that halts ATPase-driven rotation by blocking ATPase-dependent proton pumping. The fit of transient dwell occurrence to the sum of three Gaussian curves suggests that the asymmetry of the three ATPase-dependent 120° power strokes imposed by the relative positions of the central and peripheral stalks affects c-subunit stepping efficiency.

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.

Structure and mechanism of the ATP synthase membrane motor inferred from quantitative integrative modeling

The ATP synthase is a molecular rotor that recycles ADP into ATP. Leone and Faraldo-Gómez use structural modeling to reinterpret and reconcile recent cryo-EM data for its membrane domain with other experimental evidence, gaining insights into its mechanism and the mode of inhibition by oligomycin.

Two subunits within the transmembrane domain of the ATP synthase—the c-ring and subunit a—energize the production of 90% of cellular ATP by transducing an electrochemical gradient of H⁺ or Na⁺ into rotational motion. The nature of this turbine-like energy conversion mechanism has been elusive for decades, owing to the lack of definitive structural information on subunit a or its c-ring interface. In a recent breakthrough, several structures of this complex were resolved by cryo–electron microscopy (cryo-EM), but the modest resolution of the data has led to divergent interpretations. Moreover, the unexpected architecture of the complex has cast doubts on a wealth of earlier biochemical analyses conducted to probe this structure. Here, we use quantitative molecular-modeling methods to derive a structure of the a–c complex that is not only objectively consistent with the cryo-EM data, but also with correlated mutation analyses of both subunits and with prior cross-linking and cysteine accessibility measurements. This systematic, integrative approach reveals unambiguously the topology of subunit a and its relationship with the c-ring. Mapping of known Cd²⁺ block sites and conserved protonatable residues onto the structure delineates two noncontiguous pathways across the complex, connecting two adjacent proton-binding sites in the c-ring to the space on either side of the membrane. The location of these binding sites and of a strictly conserved arginine on subunit a, which serves to prevent protons from hopping between them, explains the directionality of the rotary mechanism and its strict coupling to the proton-motive force. Additionally, mapping of mutations conferring resistance to oligomycin unexpectedly reveals that this prototypical inhibitor may bind to two distinct sites at the a–c interface, explaining its ability to block the mechanism of the enzyme irrespective of the direction of rotation of the c-ring. In summary, this study is a stepping stone toward establishing the mechanism of the ATP synthase at the atomic level.

Identification of G8969>A in mitochondrial ATP6 gene that severely compromises ATP synthase function in a patient with IgA nephropathy

Here we elucidated the pathogenesis of a 14-year-old Chinese female who initially developed an isolated nephropathy followed by a complex clinical presentation with brain and muscle problems, which indicated that the disease process was possibly due to a mitochondrial dysfunction. Careful evaluation of renal biopsy samples revealed a decreased staining of cells induced by COX and NADH dehydrogenase activities, and a strong fragmentation of the mitochondrial network. These anomalies were due to the presence of a mutation in the mitochondrial ATP6 gene, G8969>A. This mutation leads to replacement of a highly conserved serine residue at position 148 of the a-subunit of ATP synthase. Increasing the mutation load in cybrid cell lines was paralleled by the appearance of abnormal mitochondrial morphologies, diminished respiration and enhanced production of reactive oxygen species. An equivalent of the G8969>A mutation in yeast had dramatic consequences on ATP synthase, with a block in proton translocation. The mutation was particularly abundant (89%) in the kidney compared to blood and urine, which is likely the reason why this organ was affected first. Based on these findings, we suggest that nephrologists should pay more attention to the possibility of a mitochondrial dysfunction when evaluating patients suffering from kidney problems.

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.

Aerobic Growth of Escherichia coli Is Reduced, and ATP Synthesis Is Selectively Inhibited when Five C-terminal Residues Are Deleted from the ϵ Subunit of ATP Synthase

F-type ATP synthases are rotary nanomotor enzymes involved in cellular energy metabolism in eukaryotes and eubacteria. The ATP synthase from Gram-positive and -negative model bacteria can be autoinhibited by the C-terminal domain of its ϵ subunit (ϵCTD), but the importance of ϵ inhibition in vivo is unclear. Functional rotation is thought to be blocked by insertion of the latter half of the ϵCTD into the central cavity of the catalytic complex (F1). In the inhibited state of the Escherichia coli enzyme, the final segment of ϵCTD is deeply buried but has few specific interactions with other subunits. This region of the ϵCTD is variable or absent in other bacteria that exhibit strong ϵ-inhibition in vitro. Here, genetically deleting the last five residues of the ϵCTD (ϵΔ5) caused a greater defect in respiratory growth than did the complete absence of the ϵCTD. Isolated membranes with ϵΔ5 generated proton-motive force by respiration as effectively as with wild-type ϵ but showed a nearly 3-fold decrease in ATP synthesis rate. In contrast, the ϵΔ5 truncation did not change the intrinsic rate of ATP hydrolysis with membranes. Further, the ϵΔ5 subunit retained high affinity for isolated F1 but reduced the maximal inhibition of F1-ATPase by ϵ from >90% to ∼20%. The results suggest that the ϵCTD has distinct regulatory interactions with F1 when rotary catalysis operates in opposite directions for the hydrolysis or synthesis of ATP.

Fo-driven Rotation in the ATP Synthase Direction against the Force of F1 ATPase in the FoF1 ATP Synthase

Living organisms rely on the FoF1 ATP synthase to maintain the non-equilibrium chemical gradient of ATP to ADP and phosphate that provides the primary energy source for cellular processes. How the Fo motor uses a transmembrane electrochemical ion gradient to create clockwise torque that overcomes F1 ATPase-driven counterclockwise torque at high ATP is a major unresolved question. Using single FoF1 molecules embedded in lipid bilayer nanodiscs, we now report the observation of Fo-dependent rotation of the c10 ring in the ATP synthase (clockwise) direction against the counterclockwise force of ATPase-driven rotation that occurs upon formation of a leash with Fo stator subunit a. Mutational studies indicate that the leash is important for ATP synthase activity and support a mechanism in which residues aGlu-196 and cArg-50 participate in the cytoplasmic proton half-channel to promote leash formation.

Functional analysis of membranous Fo-a subunit of F1Fo-ATP synthase by in vitro protein synthesis

The a subunit of F(1)F(o) (F(1)F(o)-ATP synthase) is a highly hydrophobic protein with five putative transmembrane helices which plays a central role in H(+)-translocation coupled with ATP synthesis/hydrolysis. In the present paper, we show that the a subunit produced by the in vitro protease-free protein synthesis system (the PURE system) is integrated into a preformed F(o) a-less F(1)F(o) complex in Escherichia coli membrane vesicles and liposomes. The resulting F(1)F(o) has a H(+)-coupled ATP synthesis/hydrolysis activity that is approximately half that of the native F(1)F(o). By using this procedure, we analysed five mutations of F(1)F(o), where the conserved residues in the a subunit (Asn(90), Asp(112), Arg(169), Asn(173) and Gln(217)) were individually replaced with alanine. All of the mutant F(o) a subunits were successfully incorporated into F(1)F(o), showing the advantage over conventional expression in E. coli by which three (N90A, D112A, and Q217A) mutant a subunits were not found in F(1)F(o). The N173A mutant retained full activity and the mutants D112A and Q217A had weak, but detectable, activity. No activity was observed for the R169A and N90A mutants. Asn(90) is located in the middle of putative second transmembrane helix and likely to play an important role in H(+)-translocation. The present study exemplifies that the PURE system provides an alternative approach when in vivo expression of membranous components in protein complexes turns out to be difficult.

Direct observation of stepped proteolipid ring rotation in E. coli F₀F₁-ATP synthase

Although single-molecule experiments have provided mechanistic insight for several molecular motors, these approaches have proved difficult for membrane bound molecular motors like the F₀F₁-ATP synthase, in which proton transport across a membrane is used to synthesize ATP. Resolution of smaller steps in F₀ has been particularly hampered by signal-to-noise and time resolution. Here, we show the presence of a transient dwell between F₀ subunits a and c by improving the time resolution to 10 μs at unprecedented S/N, and by using Escherichia coli F₀F₁ embedded in lipid bilayer nanodiscs. The transient dwell interaction requires 163 μs to form and 175 μs to dissociate, is independent of proton transport residues aR210 and cD61, and behaves as a leash that allows rotary motion of the c-ring to a limit of ∼36° while engaged. This leash behaviour satisfies a requirement of a Brownian ratchet mechanism for the F₀ motor where c-ring rotational diffusion is limited to 36°.

Chemical modification of mono-cysteine mutants allows a more global look at conformations of the epsilon subunit of the ATP synthase from Escherichia coli

The epsilon subunit of the ATP synthase from E. coli undergoes conformational changes while rotating through 360 degrees during catalysis. The conformation of epsilon was probed in the membrane-bound ATP synthase by reaction of mono-cysteine mutants with 3-N-maleimidyl-propionyl biocytin (MPB) under resting conditions, during ATP hydrolysis, and after inhibition by ADP-AlF(3). The relative extents of labeling were quantified after electrophoresis and blotting of the partially purified epsilon subunit. Residues from the N-terminal beta-sandwich domain showed a position-specific pattern of labeling, consistent with prior structural studies. Some residues near the epsilon-gamma interface showed changes up to two-fold if labeling occurred during ATP hydrolysis or after inhibition by ADP-AlF(3). In contrast, residues found in the C-terminal alpha-helices were all labeled to a moderate or high level with a pattern that was consistent with a partially opened helical hairpin. The results indicate that the two C-terminal alpha-helices do not adopt a fixed conformation under resting conditions, but rather exhibit intrinsic flexibility.

Structure and Function of Subunit a of the ATP Synthase of Escherichia coli

The structure of subunit a of the Escherichia coli ATP synthase has been probed by construction of more than one hundred monocysteine substitutions. Surface labeling with 3-N-maleimidyl-propionyl biocytin (MPB) has defined five transmembrane helices, the orientation of the protein in the membrane, and information about the relative exposure of the loops connecting these helices. Cross-linking studies using TFPAM-3 (N-(4-azido-2,3,5,6-tetrafluorobenzyl)-3-maleimido-propionamide) and benzophenone-4-maleimide have revealed which elements of subunit a are near subunits b and c. Use of a chemical protease reagent, 5-(-bromoacetamido)-1,10-phenanthroline-copper, has indicated that the periplasmic end of transmembrane helix 5 is near that of transmembrane helix 2.

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.

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.

A model for the structure of subunit a of the Escherichia coli ATP synthase and its role in proton translocation

Most of what is known about the structure and function of subunit a, of the ATP synthase, has come from the construction and isolation of mutations, and their analysis in the context of the ATP synthase complex. Three classes of mutants will be considered in this review. (1) Cys substitutions have been used for structural analysis of subunit a, and its interactions with subunit c. (2) Functional residues have been identified by extensive mutagenesis. These studies have included the identification of second-site suppressors within subunit a. (3) Disruptive mutations include deletions at both termini, internal deletions, and single amino acid insertions. The results of these studies, in conjunction with information about subunits b and c, can be incorporated into a model for the mechanism of proton translocation in the Escherichia coli ATP synthase.

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.

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.

Interaction of the delta and b subunits contributes to F1 and F0 interaction in the Escherichia coli F1F0-ATPase

Interactions of the F1F0-ATPase subunits between the cytoplasmic domain of the b subunit (residues 26-156, bcyt) and other membrane peripheral subunits including alpha, beta, gamma, delta, epsilon, and putative cytoplasmic domains of the a subunit were analyzed with the yeast two-hybrid system and in vitro reconstitution of ATPase from the purified subunits as well. Only the combination of bcyt fused to the activation domain of the yeast GAL-4, and delta subunit fused to the DNA binding domain resulted in the strong expression of the beta-galactosidase reporter gene, suggesting a specific interaction of these subunits. Expression of bcyt fused to glutathione S-transferase (GST) together with the delta subunit in Escherichia coli resulted in the overproduction of these subunits in soluble form, whereas expression of the GST-bcyt fusion alone had no such effect, indicating that GST-bcyt was protected by the co-expressed delta subunit from proteolytic attack in the cell. These results indicated that the membrane peripheral domain of b subunit stably interacted with the delta subunit in the cell. The affinity purified GST-bcyt did not contain significant amounts of delta, suggesting that the interaction of these subunits was relatively weak. Binding of these subunits observed in a direct binding assay significantly supported the capability of binding of the subunits. The ATPase activity was reconstituted from the purified bcyt together with alpha, beta, gamma, delta, and epsilon, or with the same combination except epsilon. Specific elution of the ATPase activity from glutathione affinity column with the addition of glutathione after reconstitution demonstrated that the reconstituted ATPase formed a complex. The result indicated that interaction of b and delta was stabilized by F1 subunits other than epsilon and also suggested that b-delta interaction was important for F1-F0 interaction.

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.

Transmembrane topology of Escherichia coli H(+)-ATPase (ATP synthase) subunit a

Escherichia coli H(+)-ATPase subunit a is a hydrophobic F0 subunit. To investigate the topology of the subunit in the membrane, we prepared site-specific polyclonal antibodies against amino-terminal (Ser-3 to Leu-16), middle loop (Lys-167 to Gln-181), and carboxyl-terminal (Thr-259 to His-271) peptide segments. Enzyme-linked immunosorbent assay revealed that these antibodies specifically reacted with subunit a of inside-out membrane vesicles, but not with that of right-side-out spheroplasts. Full reactivity appeared when spheroplasts were disrupted with Triton X-100 (0.5%) or by sonication. These results suggest that at least parts of the three peptide segments of subunit a face the cytoplasm. Based on these observations, we propose a novel transmembrane topology of subunit a.

Alanine-scanning mutagenesis of the epsilon subunit of the F1-F0 ATP synthase from Escherichia coli reveals two classes of mutants

Alanine-scanning mutagenesis was applied to the epsilon subunit of the F1-F0 ATP synthase from E. coli. Nineteen amino acid residues were changed to alanine, either singly or in pairs, between residues 10 and 93. All mutants, when expressed in the epsilon deletion strain XH1, were able to grow on succinate minimal medium. Membranes were prepared from all mutants and assayed for ATP-driven proton translocation, ATP hydrolysis +/- lauryldiethylamine oxide, and sensitivity of ATPase activity to N,N'-dicyclohexylcarbodiimide (DCCD). Most of the mutants fell into 2 distinct classes. The first group had inhibited ATPase activity, with near normal levels of membrane-bound F1, but decreased sensitivity to DCCD. The second group had stimulated ATPase activity, with a reduced level of membrane-bound F1, but normal sensitivity to DCCD. Membranes from all mutants were further characterized by immunoblotting using 2 monoclonal antibodies. A model for the secondary structure of epsilon and its role in the function of the ATP synthase has been developed. Some residues are important for the binding of epsilon to F1 and therefore for inhibition. Other residues, from Glu-59 through Glu-70, are important for the release of inhibition by epsilon that is part of the normal enzyme cycle.

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.

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.

Prediction of transmembrane topology of F0 proteins from Escherichia coli F1F0 ATP synthase using variational and hydrophobic moment analyses

The a subunit, a membrane protein from the E. coli F1F0 ATP synthase has been examined by Fourier analysis of hydrophobicity and of amino-acid residue variation. The amino-acid sequences of homologous subunits from Vibrio alginolyticus, Saccharomyces cerevisiae, Neurospora crassa, Aspergillus nidulans, Schizosaccharomyces pombe and Candida parapsilosis were used in the variability analysis. By Fourier analysis of sequence variation, two transmembrane helices are predicted to have one face in contact with membrane lipids, while the other spans are predicted to be more shielded from the lipids by protein. By Fourier analysis of hydrophobicity, six amphipathic alpha-helical segments are predicted in extra-membrane regions, including the region from Glu-196 to Asn-214. Fourier analysis of sequence variation in the b- and the c-subunits of the Escherichia coli F1F0 ATP synthase indicates that the single transmembrane span of the b-subunit and the C-terminal span of the c subunit each have a face in contact with membrane lipids. On the basis of this analysis topographical models for the a- and c-subunits and for the F0 complex are proposed.

Quaternary structure of ATP synthases: symmetry and asymmetry in the F1 moiety

It has been proposed that during ATP synthesis/hydrolysis F1 ATPases experience a complex pattern of nucleotide binding and release during the catalytic cycle (binding change mechanism). This type of mechanism has implications that can be correlated with the structure of the enzyme. F1-ATPases (stoichiometry alpha 3 beta 3 gamma delta epsilon) are essentially a symmetrical trimer of pairs of the major subunits (alpha and beta); the minor subunits (gamma, delta and epsilon) are in single copies and interact with the trimer in an asymmetrical fashion. The asymmetry introduced by the minor subunits has important structural and functional consequences: (1) it introduces differences between the potentially equivalent binding and catalytic sites in the major subunits, (2) it restricts the ways in which a binding change mechanism can occur, and (3) it governs the way in which the F1 interacts with the (asymmetrical) F0 sector.

Evolution of organellar proton-ATPases

Proton ATPases function in biological energy conversion in every known living cell. Their ubiquity and antiquity make them a prime source for evolutionary studies. There are two related families of H(+)-ATPases; while the family of F-ATPases function in eubacteria chloroplasts and mitochondria, the family of V-ATPases are present in archaebacteria and the vacuolar system of eukaryotic cells. Sequence analysis of several subunits of V- and F-ATPases revealed several of the important steps in their evolution. Moreover, these studies shed light on the evolution of the various organelles of eukaryotes and suggested some events in the evolution of the three kingdoms of eubacteria, archaebacteria and eukaryotes.

Mutations at Glu-32 and His-39 in the epsilon subunit of the Escherichia coli F1F0 ATP synthase affect its inhibitory properties

A collection of amino acid substitutions at residues Glu-32 and His-39 in the epsilon subunit of the Escherichia coli F1F0 ATP synthase has been constructed by cassette mutagenesis. Substitutions for residue Glu-32 appeared to cause abnormal inhibition of membrane-bound F1 ATPase activity, and replacement of His-39 by Arg, Val, and Pro affected F1F0 interactions.

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

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

Expression of the wheat chloroplast gene for CF0 subunit IV of ATP synthase

The nucleotide sequence of the wheat chloroplast atp I gene encoding CF0 subunit IV of ATP synthase has been determined. The gene encodes a polypeptide of 247 amino acid residues with high sequence similarity to subunit IV from other plant chloroplasts and from cyanobacteria. The polypeptide shows sequence homology to the C-terminus of the F0 alpha subunit of Escherichia coli ATP synthase and subunit 6 of mitochondrial ATP synthase. The atp I gene is co-transcribed with the atp H, atp F and atp A genes for other subunits of ATP synthase in wheat. A gene-fusion of most of the atp I coding region with cro'-lacI'-lacZ' has been constructed in pEX2 and the fusion-protein has been used to raise antibodies in rabbits. The antibodies react with a polypeptide of 17 kDa in wheat thylakoid membranes indicating that the wheat atp I gene is expressed at the protein level. A model for the organisation of the polypeptide in the thylakoid membrane with four membrane-spanning segments is proposed.

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.

The transmembrane topology of the a [corrected] subunit from the ATPase in Escherichia coli analyzed by PhoA protein fusions

The atpB encodes the a [corrected] subunit of the H(+)-ATPase of E. coli. The topology of this membrane protein has been analyzed by PhoA fusions. The results support an eight transmembrane segment model that is consistent with the hydropathic profile.

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

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

Use of lacZ fusions to measure in vivo expression of the first three genes of the Escherichia coli unc operon

We have constructed in-frame lacZ protein fusions to the first three genes of the Escherichia coli unc operon, which codes for the subunits of the proton-translocating ATPase. We have used these constructions to measure the relative in vivo expression of these genes. The second and third genes, uncB and uncE, which code for the a and c subunits of the F0 sector, were expressed at relative levels of approximately 1:10, although the measured expression of uncB depended upon how much of the gene was fused to lacZ. These rates compared favorably with the relative numbers of a and c subunits (a1:c10) in the purified F1F0 complex. The in vivo expression of uncI, the first gene of the operon, was very low, at best 10 to 20 times less than the expression of uncB.