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

Interactions between subunit a and oligomeric subunit c are essential for the coupling of proton translocation to rotary motion in the ATP synthase. A pair of previously described mutants, R210Q/Q252R and P204T/R210Q/Q252R [L.P. Hatch, G.B. Cox and S.M. Howitt, The essential arginine residue at position 210 in the a subunit of the Escherichia coli ATP synthase can be transferred to position 252 with partial retention of activity, J. Biol. Chem. 270 (1995) 29407-29412] has been constructed and further analyzed. These mutants, in which the essential arginine of subunit a, R210, was switched with a conserved glutamine residue, Q252, are shown here to be capable of both ATP synthesis by oxidative phosphorylation, and ATP-driven proton translocation. In addition, lysine can replace the arginine at position 252 with partial retention of both activities. The pH dependence of ATP-driven proton translocation was determined after purification of mutant enzymes, and reconstitution into liposomes. Proton translocation by the lysine mutant, and to a lesser extent the arginine mutant, dropped off sharply above pH 7.5, consistent with the requirement for a positive charge during function. Finally, the rates of ATP synthesis and of ATP-driven proton translocation were completely inhibited by treatment with DCCD (N,N′-dicyclohexylcarbodiimide), while rates of ATP hydrolysis by the mutants were not significantly affected, indicating that DCCD modification disrupts the F₁-F_o interface. The results suggest that minimal requirements for proton translocation by the ATP synthase include a positive charge in subunit a and a weak interface between subunit a and oligomeric subunit c.     

ATP synthase: Subunit–subunit interactions in the stator stalk

In ATP synthase, proton translocation through the F_o subcomplex and ATP synthesis/hydrolysis in the F₁ subcomplex are coupled by subunit rotation. The static, non-rotating portions of F₁ and F_o are attached to each other via the peripheral “stator stalk”, which has to withstand elastic strain during subunit rotation. In Escherichia coli, the stator stalk consists of subunits b₂δ; in other organisms, it has three or four different subunits. Recent advances in this area include affinity measurements between individual components of the stator stalk as well as a detailed analysis of the interaction between subunit δ (or its mitochondrial counterpart, the oligomycin-sensitivity conferring protein, OSCP) and F₁. The current status of our knowledge of the structure of the stator stalk and of the interactions between its subunits will be discussed in this review.     

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, F₁F_o-type ATP synthases utilize a transmembrane H⁺ potential to drive ATP formation by a rotary catalytic mechanism. ATP is formed in alternating β subunits of the extramembranous F₁ sector of the enzyme, synthesis being driven by rotation of the γ subunit in the center of the F₁ molecule between the alternating catalytic sites . The H⁺ electrochemical potential is thought to drive γ subunit rotation by first coupling H⁺ transport to rotation of an oligomeric rotor of c subunits within the transmembrane F_o sector. The γ subunit is forced to turn with the c-oligomeric rotor due to connections between subunit c and the γ and ε subunits of F₁. 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 Asp⁶¹ centered in the second transmembrane helix (TMH). A model for the structural organization of the c₁₀ 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 c₁₀ 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 Asp⁶¹ during the protonation/deprotonation cycle, we propose that the outer, Asp⁶¹-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 Asp⁶¹ protonation/deprotonation drives the rotation of the c-ring. The NMR structures of wild-type subunit c differs according to the protonation state of Asp⁶¹. 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 c₁₀ oligomer during coupled synthesis of ATP.     

A Biological Molecular Motor, Proton-Translocating ATP Synthase: Multidisciplinary Approach for a Unique Membrane Enzyme

Proton-translocating ATP synthase (F_oF₁) synthesizes ATP from ADP and phosphate, coupled with an electrochemical proton gradient across the biological membrane. It has been established that the rotation of a subunit assembly is an essential feature of the enzyme mechanism and that F_oF₁ can be regarded as a molecular motor. Thus, experimentally, in the reverse direction (ATP hydrolysis), the chemical reaction drives the rotation of a c _10-14 subunit assembly followed by proton translocation. We discuss our very recent results regarding subunit rotation in Escherichia coli F_oF₁ with a combined biophysical and mutational approach.     

The mechanism of rotating proton pumping ATPases

Two proton pumps, the F-ATPase (ATP synthase, F_oF₁) and the V-ATPase (endomembrane proton pump), have different physiological functions, but are similar in subunit structure and mechanism. They are composed of a membrane extrinsic (F₁ or V₁) and a membrane intrinsic (F_o or V_o) sector, and couple catalysis of ATP synthesis or hydrolysis to proton transport by a rotational mechanism. The mechanism of rotation has been extensively studied by kinetic, thermodynamic and physiological approaches. Techniques for observing subunit rotation have been developed. Observations of micron-length actin filaments, or polystyrene or gold beads attached to rotor subunits have been highly informative of the rotational behavior of ATP hydrolysis-driven rotation. Single molecule FRET experiments between fluorescent probes attached to rotor and stator subunits have been used effectively in monitoring proton motive force-driven rotation in the ATP synthesis reaction. By using small gold beads with diameters of 40-60 nm, the E. coli F₁ sector was found to rotate at surprisingly high speeds (> 400 rps). This experimental system was used to assess the kinetics and thermodynamics of mutant enzymes. The results revealed that the enzymatic reaction steps and the timing of the domain interactions among the β subunits, or between the β and γ subunits, are coordinated in a manner that lowers the activation energy for all steps and avoids deep energy wells through the rotationally-coupled steady-state reaction. In this review, we focus on the mechanism of steady-state F₁-ATPase rotation, which maximizes the coupling efficiency between catalysis and rotation.     

Fluid Mechanical Matching of H-ATP Synthase Subunit c-Ring with Lipid Membranes Revealed by H Solid-State NMR

The F₁F_o-ATP synthase utilizes the transmembrane H⁺ gradient for the synthesis of ATP. F_o subunit c-ring plays a key role in transporting H⁺ through F_o in the membrane. We investigated the interactions of Escherichia coli subunit c with dimyristoylphosphatidylcholine (DMPC-d₅₄) at lipid/protein ratios of 50:1 and 20:1 by means of ²H-solid-state NMR. In the liquid-crystalline state of DMPC, the ²H-NMR moment values and the order parameter (S_CD) profile were little affected by the presence of subunit c, suggesting that the bilayer thickness in the liquid-crystalline state is matched to the transmembrane hydrophobic surface of subunit c. On the other hand, hydrophobic mismatch of subunit c with the lipid bilayer was observed in the gel state of DMPC. Moreover, the viscoelasticity represented by a square-law function of the ²H-NMR relaxation was also little influenced by subunit c in the fluid phase, in contrast with flexible nonionic detergents or rigid additives. Thus, the hydrophobic matching of the lipid bilayer to subunit c involves at least two factors, the hydrophobic length and the fluid mechanical property. These findings may be important for the torque generation in the rotary catalytic mechanism of the F₁F_o-ATPse molecular motor.     

Half channels mediating H transport and the mechanism of gating in the Fo sector of Escherichia coli F1Fo ATP synthase

H⁺-transporting F₁F_o ATP synthase catalyzes the synthesis of ATP via coupled rotary motors within F_o and F₁. H⁺ transport at the subunit a–c interface in trans-membranous F_o drives rotation of the c-ring within the membrane, with subunit c being bound in a complex with the γ and ε subunits extending from the membrane. Finally, the rotation of subunit γ within the α₃β₃ sector of F₁ mechanically drives ATP synthesis within the catalytic sites. In this review, we propose and provide evidence supporting the route of proton transfer via half channels from one side of the membrane to the other, and the mechanism of gating H⁺ binding to and release from Asp61 of subunit c, via conformational movements of Arg210 in subunit a. We propose that protons are gated from the inside of a four-helix bundle at the periplasmic side of subunit a to drive protonation of cAsp61, and that this gating movement is facilitated by the swiveling of trans-membrane helices (TMHs) 4 and 5 at the site of interaction with cAsp61 on the periphery of the c-ring. Proton release to the cytoplasmic half channel is facilitated by the movement of aArg210 as a consequence of this proposed helical swiveling. Finally, release from the cytoplasmic half channel is mediated by residues in a complex of interacting extra-membraneous loops formed between TMHs of both subunits a and c. This article is part of a Special Issue entitled: 18th European Bioenergetic Conference.     

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

Living organisms rely on the F_oF₁ 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 F_o 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 F_oF₁ molecules embedded in lipid bilayer nanodiscs, we now report the observation of F_o-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 F_o 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.     

Osmomechanics of the Propionigenium modestum Fo Motor

In Propionigenium modestum, ATP is manufactured from ADP and phosphate by the enzyme ATP synthase using the free energy of an electrochemical gradient of Na⁺ ions. The P. modestum ATP synthase is a clear member of the family of F-type ATP synthases and the only major distinction is an extension of the coupling ion specificity to H⁺, Li⁺, or Na⁺, depending on the conditions. The use of Na⁺ as a coupling ion offers unique experimental options to decipher the ion-translocation mechanism and the osmotic and mechanical behavior of the enzyme. The single a subunit and the oligomer of c subunits are part of the stator and rotor, respectively, and operate together in the ion-translocation mechanism. During ATP synthesis, Na⁺ diffuses from the periplasm through the a subunit channel onto the Na⁺ binding site on a c subunit. From there it dissociates into the cytoplasm after the site has rotated out of the interface with subunit a. In the absence of a membrane potential, the rotor performs Brownian motions into either direction and Na⁺ ions are exchanged between the two compartments separated by the membrane. Upon applying voltage, however, the direction of Na⁺ flux and of rotation is biased by the potential. The motor generates torque to drive the rotation of the subunit, thereby releasing tightly bound ATP from catalytic sites in F₁. Hence, the membrane potential plays a pivotal role in the torque-generating mechanism. This is corroborated by the fact that for ATP synthesis, at physiological rates, the membrane potential is indispensable. We propose a catalytic mechanism for torque generation by the F_o motor that is in accord with all experimental data and is in quantitative agreement with the requirement for ATP synthesis.     

The regulatory subunit ε in Escherichia coli FOF1-ATP synthase

F-type ATP synthases are extraordinary multisubunit proteins that operate as nanomotors. The Escherichia coli (E. coli) enzyme uses the proton motive force (pmf) across the bacterial plasma membrane to drive rotation of the central rotor subunits within a stator subunit complex. Through this mechanical rotation, the rotor coordinates three nucleotide binding sites that sequentially catalyze the synthesis of ATP. Moreover, the enzyme can hydrolyze ATP to turn the rotor in the opposite direction and generate pmf. The direction of net catalysis, i.e. synthesis or hydrolysis of ATP, depends on the cell's bioenergetic conditions. Different control mechanisms have been found for ATP synthases in mitochondria, chloroplasts and bacteria. This review discusses the auto-inhibitory behavior of subunit ε found in F_OF₁-ATP synthases of many bacteria. We focus on E. coli F_OF₁-ATP synthase, with insights into the regulatory mechanism of subunit ε arising from structural and biochemical studies complemented by single-molecule microscopy experiments.     

Subunit δ Is the Key Player for Assembly of the H+-translocating Unit of Escherichia coli FOF1 ATP Synthase

The ATP synthase (F_OF₁) of Escherichia coli couples the translocation of protons across the cytoplasmic membrane to the synthesis or hydrolysis of ATP. This nanomotor is composed of the rotor c₁₀γϵ and the stator ab₂α₃β₃δ. To study the assembly of this multimeric enzyme complex consisting of membrane-integral as well as peripheral hydrophilic subunits, we combined nearest neighbor analyses by intermolecular disulfide bond formation or purification of partially assembled F_OF₁ complexes by affinity chromatography with the use of mutants synthesizing different sets of F_OF₁ subunits. Together with a time-delayed in vivo assembly system, the results demonstrate that F_OF₁ is assembled in a modular way via subcomplexes, thereby preventing the formation of a functional H⁺-translocating unit as intermediate product. Surprisingly, during the biogenesis of F_OF₁, F₁ subunit δ is the key player in generating stable F_O. Subunit δ serves as clamp between ab₂ and c₁₀α₃β₃γϵ and guarantees that the open H⁺ channel is concomitantly assembled within coupled F_OF₁ to maintain the low membrane proton permeability essential for viability, a general prerequisite for the assembly of multimeric H⁺-translocating enzymes.     

Functional production of the Na+ F1FO ATP synthase from Acetobacterium woodii in Escherichia coli requires the native AtpI

The Na⁺ F₁F_O ATP synthase of the anaerobic, acetogenic bacterium Acetobacterium woodii has a unique F_OV_O hybrid rotor that contains nine copies of a F_O-like c subunit and one copy of a V_O-like c ₁ subunit with one ion binding site in four transmembrane helices whose cellular function is obscure. Since a genetic system to address the role of different c subunits is not available for this bacterium, we aimed at a heterologous expression system. Therefore, we cloned and expressed its Na⁺ F₁F_O ATP synthase operon in Escherichia coli. A Δatp mutant of E. coli produced a functional, membrane-bound Na⁺ F₁F_O ATP synthase that was purified in a single step after inserting a His₆-tag to its β subunit. The purified enzyme was competent in Na⁺ transport and contained the F_OV_O hybrid rotor in the same stoichiometry as in A. woodii. Deletion of the atpI gene from the A. woodii operon resulted in a loss of the c ring and a mis-assembled Na⁺ F₁F_O ATP synthase. AtpI from E. coli could not substitute AtpI from A. woodii. These data demonstrate for the first time a functional production of a F_OV_O hybrid rotor in E. coli and revealed that the native AtpI is required for assembly of the hybrid rotor.     

The regulatory C-terminal domain of subunit ε of F₀F₁ ATP synthase is dispensable for growth and survival of Escherichia coli

The C-terminal domain of subunit ε of the bacterial F_oF₁ ATP synthase is reported to be an intrinsic inhibitor of ATP synthesis/hydrolysis activity in vitro, preventing wasteful hydrolysis of ATP under low-energy conditions. Mutants defective in this regulatory domain exhibited no significant difference in growth rate, molar growth yield, membrane potential, or intracellular ATP concentration under a wide range of growth conditions and stressors compared to wild-type cells, suggesting this inhibitory domain is dispensable for growth and survival of Escherichia coli.F_oF₁ ATP synthases are ubiquitous enzymes that synthesize ATP using a transmembrane electrochemical potential of protons or proton motive force (PMF) generated by the respiratory chain across the cytoplasmic membrane of bacteria, the thylakoid membrane of chloroplasts, or the mitochondrial inner membrane (4, 5, 37). The enzyme consists of two parts: membrane-embedded F_o subcomplex (a complex of subunits a, b, and c in bacteria) and hydrophilic F₁ subcomplex (composed of subunits α, β, γ, δ, and ε). The enzyme is also known as a molecular motor, which is composed of the stator subcomplex (α, β, δ, a, and b) and the rotor subcomplex (γ, ε, and c), and its rotation is coupled to ATP synthesis and proton flow across the membrane (20, 31, 52). The reaction of the enzyme is reversible; ATP is hydrolyzed into ADP and inorganic phosphate, the rotor subcomplex rotates in reverse, and protons are extruded to the periplasmic side, resulting in the generation of PMF. Although some bacteria utilize the reverse reaction under particular conditions, the primary function of F_oF₁ ATP synthase is generation of ATP from the PMF. Therefore, the direction of the activity of F_oF₁ ATP synthase is regulated to avoid wasteful ATP hydrolysis.Subunit ε in bacterial F_oF₁ has been known to be an intrinsic inhibitor of F₁ and F_oF₁ complex (18, 21, 23) and is proposed to have a regulatory function (10, 11, 42). Although the inhibitory effects of subunit ε vary among species, in general, ε inhibits ATP hydrolysis activity while repressing ATP synthesis activity to a lesser degree (14, 27). This regulatory function of the ε subunit is mediated almost exclusively by the C-terminal region of ε, which is comprised of two antiparallel α-helices (18, 49, 50). Biochemical and crystallographic studies have revealed that the C-terminal helices can adopt two different conformations (34, 46, 47, 48). In the retracted conformation, the α-helices form a hairpin-like structure and sit on the N-terminal β-sandwich domain of the ε subunit. When the ε subunit exhibits an inhibitory effect, it adopts a more extended conformation in which the C-terminal α-helices extend along the γ subunit, which composes the central stalk. It has also been shown that basic, positively charged residues on the second α-helix of the ε subunit interact with negatively charged residues in the DELSEED segment of subunit β to exert the inhibitory effect (12).Escherichia coli mutants deleted in the entire ε subunit exhibit a reduced growth rate and growth yield, and this effect is proposed to be a result of a deficiency in assembly of the F_o and F₁ complexes (21). The N-terminal β-sandwich domain of the ε subunit is responsible for the assembly of F_o and F₁ and is therefore important for efficient coupling between proton translocation through F_o and ATP synthesis/hydrolysis in F₁ (15, 39). Deletion of the ε subunit leads to dissociation of the F_oF₁ complex and wasteful ATP hydrolysis by free (cytoplasmic) F₁ and dissipation of PMF through free F_o (21, 22, 51).While the importance of the entire ε subunit in the whole-cell physiology of E. coli is fairly well established, the role of the regulatory C-terminal region of ε has received little attention and warrants investigation to determine if the regulatory functions (e.g., inhibition of ATP hydrolysis) observed in vitro are manifested in the physiology of E. coli under various growth conditions. To address this question, we constructed isogenic E. coli mutants that were deleted in the C-terminal region of ε subunit (ε^DC) and used these strains to compare physiological properties of wild-type versus ε^DC cells under a wide range of environmental conditions and stressors.     

36° step size of proton‐driven c‐ring rotation in FoF1‐ATP synthase

Synthesis of adenosine triphosphate ATP, the ‘biological energy currency’, is accomplished by F_oF₁‐ATP synthase. In the plasma membrane of Escherichia coli, proton‐driven rotation of a ring of 10 c subunits in the F_o motor powers catalysis in the F₁ motor. Although F₁ uses 120° stepping during ATP synthesis, models of F_o predict either an incremental rotation of c subunits in 36° steps or larger step sizes comprising several fast substeps. Using single‐molecule fluorescence resonance energy transfer, we provide the first experimental determination of a 36° sequential stepping mode of the c‐ring during ATP synthesis.     

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 Cd²⁺ 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 Cd²⁺ 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 Cd²⁺ 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.     

None of the Rotor Residues of F1-ATPase Are Essential for Torque Generation

F₁-ATPase is a powerful rotary molecular motor that can rotate an object several hundred times as large as the motor itself against the viscous friction of water. Forced reverse rotation has been shown to lead to ATP synthesis, implying that the mechanical work against the motor’s high torque can be converted into the chemical energy of ATP. The minimal composition of the motor protein is α₃β₃γ subunits, where the central rotor subunit γ turns inside a stator cylinder made of alternately arranged α₃β₃ subunits using the energy derived from ATP hydrolysis. The rotor consists of an axle, a coiled coil of the amino- and carboxyl-terminal α-helices of γ, which deeply penetrates the stator cylinder, and a globular protrusion that juts out from the stator. Previous work has shown that, for a thermophilic F₁, significant portions of the axle can be truncated and the motor still rotates a submicron sized bead duplex, indicating generation of up to half the wild-type (WT) torque. Here, we inquire if any specific interactions between the stator and the rest of the rotor are needed for the generation of a sizable torque. We truncated the protruding portion of the rotor and replaced part of the remaining axle residues such that every residue of the rotor has been deleted or replaced in this or previous truncation mutants. This protrusionless construct showed an unloaded rotary speed about a quarter of the WT, and generated one-third to one-half of the WT torque. No residue-specific interactions are needed for this much performance. F₁ is so designed that the basic rotor-stator interactions for torque generation and control of catalysis rely solely upon the shape and size of the rotor at very low resolution. Additional tailored interactions augment the torque to allow ATP synthesis under physiological conditions.     

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 (F_oF₁) is functionally exchangeable with that of Escherichia coli, since E. coli with a hybrid F_oF₁ is able to grow on minimum succinate medium through oxidative phosphorylation. E. coli F₁ bound to the hybrid F_o with the S. mutans c subunit showed N,N′-dicyclohexylcarbodiimide-sensitive ATPase activity similar to that of E. coli F_oF₁. Thus, the S. mutans c subunit assembled into a functional F_o 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 F_o with the S. mutans c subunit would be helpful to find antibiotics and chemicals specifically directed to S. mutans.     

Partial Assembly of the Yeast Mitochondrial ATP Synthase 1

The mitochondrial ATP synthase is a molecular motor that drives the phosphorylation ofADP to ATP. The yeast mitochondrial ATP synthase is composed of at least 19 differentpeptides, which comprise the F₁ catalytic domain, the F₀ proton pore, and two stalks, oneof which is thought to act as a stator to link and hold F₁ to F₀, and the other as a rotor.Genetic studies using yeast Saccharomyces cerevisiae have suggested the hypothesis thatthe yeast mitochondrial ATP synthase can be assembled in the absence of 1, and even 2, ofthe polypeptides that are thought to comprise the rotor. However, the enzyme complexassembled in the absence of the rotor is thought to be uncoupled, allowing protons to freelyflow through F₀ into the mitochondrial matrix. Left uncontrolled, this is a lethal process andthe cell must eliminate this leak if it is to survive. In yeast, the cell is thought to lose ordelete its mitochondrial DNA (the petite mutation) thereby eliminating the genes encodingessential components of F₀. Recent biochemical studies in yeast, and prior studies in E. coli,have provided support for the assembly of a partial ATP synthase in which the ATP synthaseis no longer coupled to proton translocation.     

Essential arginine in subunit a and aspartate in subunit c of FoF1 ATP synthase: Effect of repositioning within Helix 4 of subunit a and Helix 2 of subunit c

F_oF₁ ATP synthase couples proton flow through the integral membrane portion F_o (ab₂c₁₀) to ATP-synthesis in the extrinsic F₁-part ((αβ)₃γδε) (Escherichia coli nomenclature and stoichiometry). Coupling occurs by mechanical rotation of subunits c₁₀γε relative to (αβ)₃δab₂. Two residues were found to be essential for proton flow through ab₂c_10, namely Arg₂₁₀ in subunit a (aR210) and Asp₆₁ in subunits c (cD61). Their deletion abolishes proton flow, but “horizontal” repositioning, by anchoring them in adjacent transmembrane helices, restores function. Here, we investigated the effects of “vertical” repositioning aR210, cD61, or both by one helical turn towards the N- or C-termini of their original helices. Other than in the horizontal the vertical displacement changes the positions of the side chains within the depth of the membrane. Mutant aR210A/aN214R appeared to be short-circuited in that it supported proton conduction only through EF₁-depleted EF_o, but not in EF_oEF_1, nor ATP-driven proton pumping. Mutant cD61N/cM65D grew on succinate, retained the ability to synthesize ATP and supported passive proton conduction but apparently not ATP hydrolysis-driven proton pumping.     

Obstruction of Transmembrane Helical Movements in Subunit a Blocks Proton Pumping by F1Fo ATP Synthase

Subunit a plays a key role in promoting H⁺ transport-coupled rotary motion of the subunit c ring in F₁F_o ATP synthase. H⁺ binding and release occur at Asp-61 in the middle of the second transmembrane helix (TMH) of F_o subunit c. H⁺ are thought to reach cAsp61 via aqueous half-channels formed by TMHs 2–5 of subunit a. Movements of TMH4 and TMH5 have been proposed to facilitate protonation of cAsp61 from a half channel centered in a four helix bundle at the periplasmic side of subunit a. The possible necessity of these proposed TMH movements was investigated by assaying ATP driven H⁺ pumping function before and after cross-linking paired Cys substitutions at the center of TMHs within subunit a. The cross-linking of the Cys pairs aG218C/I248C in TMH4 and TMH5, and aL120C/H245C in TMH2 and TMH5, inhibited H⁺ pumping by 85–90%. H⁺ pumping function was largely unaffected by modification of the same Cys residues in the absence of cross-link formation. The inhibition is consistent with the proposed requirement for TMH movements during the gating of periplasmic H⁺ access to cAsp61. The cytoplasmic loops of subunit a have been implicated in gating H⁺ release to the cytoplasm, and previous cross-linking experiments suggest that the chemically reactive regions of the loops may pack as a single domain. Here we show that Cys substitutions in these domains can be cross-linked with retention of function and conclude that these domains need not undergo large conformational changes during enzyme function.