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

FoF1 ATP synthase couples proton flow through the integral membrane portion Fo (ab2c10) to ATP-synthesis in the extrinsic F1-part ((alphabeta)3gammadeltaepsilon) (Escherichia coli nomenclature and stoichiometry). Coupling occurs by mechanical rotation of subunits c10gammaepsilon relative to (alphabeta)3deltaab2. Two residues were found to be essential for proton flow through ab2c10, 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 EFo, but not in EFoEF1, 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.     

H+ transport and coupling by the F0 sector of the ATP synthase: Insights into the molecular mechanism of function

The F₀ sector of the ATP synthase complex facilitates proton translocation through the membrane, and via interaction with the F₁ sector, couples proton transport to ATP synthesis. The molecular mechanism of function is being probed by a combination of mutant analysis and structural biochemistry, and recent progress on theEscherichia coli F₀ sector is reviewed here. TheE. coli F₀ is composed of three types of subunits (a, b, andc) and current information on their folding and organization in F₀ is reviewed. The structure of purified subunitc in chloroform-methanol-H₂O resembles that in native F₀, and progress in determining the structure by NMR methods is reviewed. Genetic experiments suggest that the two helices of subunitc must interact as a functional unit around an essential carboxyl group as protons are transported. In addition, a unique class of suppressor mutations identify a transmembrane helix of subunita that is proposed to interact with the bihelical unit of subunitc during proton transport. The role of multiple units of subunitc in coupling proton translocation to ATP synthesis is considered. The special roles of Asp61 of subunitc and Arg210 of subunita in proton translocation are also discussed.     

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.     

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 F_oF₁‐ATP synthase, in which proton transport across a membrane is used to synthesize ATP. Resolution of smaller steps in F_o has been particularly hampered by signal‐to‐noise and time resolution. Here, we show the presence of a transient dwell between F_o subunits a and c by improving the time resolution to 10 μs at unprecedented S/N, and by using Escherichia coli F_oF₁ 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 F_o motor where c‐ring rotational diffusion is limited to 36°.     

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.     

Structural and functional characterization of FoF1-ATP synthase on the extracellular surface of rat hepatocytes

Extracellular ATP formation from ADP and inorganic phosphate, attributed to the activity of a cell surface ATP synthase, has so far only been reported in cultures of some proliferating and tumoral cell lines. We now provide evidence showing the presence of a functionally active ecto-F_oF₁-ATP synthase on the plasma membrane of normal tissue cells, i.e. isolated rat hepatocytes. Both confocal microscopy and flow cytometry analysis show the presence of subunits of F₁ (α/β and γ) and F_o (F_oI-PVP(b) and OSCP) moieties of ATP synthase at the surface of rat hepatocytes. This finding is confirmed by immunoblotting analysis of the hepatocyte plasma membrane fraction. The presence of the inhibitor protein IF₁ is also detected on the hepatocyte surface. Activity assays show that the ectopic-ATP synthase can work both in the direction of ATP synthesis and hydrolysis. A proton translocation assay shows that both these mechanisms are accompanied by a transient flux of H⁺ and are inhibited by F₁ and F_o-targeting inhibitors. We hypothesise that ecto-F_oF₁-ATP synthase may control the extracellular ADP/ATP ratio, thus contributing to intracellular pH homeostasis.     

Met23Lys mutation in subunit gamma of FOF1-ATP synthase from Rhodobacter capsulatus impairs the activation of ATP hydrolysis by protonmotive force

H⁺-F_OF₁-ATP synthase couples proton flow through its membrane portion, F_O, to the synthesis of ATP in its headpiece, F₁. Upon reversal of the reaction the enzyme functions as a proton pumping ATPase. Even in the simplest bacterial enzyme the ATPase activity is regulated by several mechanisms, involving inhibition by MgADP, conformational transitions of the ε subunit, and activation by protonmotive force. Here we report that the Met23Lys mutation in the γ subunit of the Rhodobacter capsulatus ATP synthase significantly impaired the activation of ATP hydrolysis by protonmotive force. The impairment in the mutant was due to faster enzyme deactivation that was particularly evident at low ATP/ADP ratio. We suggest that the electrostatic interaction of the introduced γLys23 with the DELSEED region of subunit β stabilized the ADP-inhibited state of the enzyme by hindering the rotation of subunit γ rotation which is necessary for the activation.     

Evolutionary relationship between Enterobacteriaceae: comparison of the ATP synthases (F1F0) of Escherichia coli and Klebsiella pneumoniae

The ATP synthase complex of Klebsiella pneumoniae (KF₁F₀) has been purified and characterized. SDS-gel electrophoresis of the purified F₁F₀ complexes revealed an identical subunit pattern for E. coli (EF₁F₀) and K. pneumoniae. Antibodies raised against EF₁ complex and purified EF₀ subunits recognized the corresponding polypeptides of EF₁F₀ and KF₁F₀ in immunoblot analysis. Protease digestion of the individual subunits generated an identical cleavage pattern for subunits , , , , a, and c of both enzymes. Only for subunit different cleavage products were obtained. The isolated subunit c of both organisms showed only a slight deviation in the amino acid composition. These data suggest that extensive homologies exist in primary and secondary structure of both ATP synthase complexes reflecting a close phylogenetic relationship between the two enterobacteric tribes.Abbreviations ACMA 9-amino-6-chloro-2-methoxyacridine - DCCD N,N-dicyclohexylcarbodiimide - FITC fluorescein isothiocyanate - SDS sodium dodecyl sulfate - TTFB 4,5,6,7-tetrachloro-2-trifluoromethylbenzimidazole     

Mitochondrial F1Fo-ATP Synthase: The Small Subunits e and g Associate with Monomeric Complexes to Trigger Dimerization

Mitochondrial F₁F_o-ATP synthase catalyzes the formation of ATP from ADP and inorganic phosphate. The enzyme is found in monomeric, dimeric and higher oligomeric forms in the inner mitochondrial membrane. Dimerization of ATP synthase complexes is a prerequisite for the generation of larger oligomers that promote membrane bending and formation of tubular cristae membranes. Two small proteins of the membrane-embedded F_o-domain, subunit e (Su e; Atp21) and Su g (Atp20), were identified as dimer-specific subunits of yeast ATP synthase and shown to be required for stabilization of the dimers. We have identified two distinct monomeric forms of yeast ATP synthase. Su e and Su g are present not only in the dimer but also in one of the monomeric forms. We demonstrate that Su e and Su g sequentially assemble with monomeric ATP synthase to form a dimerization-competent primed monomer. We conclude that association of Su e and Su g with monomeric F₁F_o-ATP synthase represents an initial step of oligomer formation.     

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.     

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.     

Organization and nucleotide sequence of the atp genes encoding the ATP synthase from alkaliphilic Bacillus firmus OF4

Summary The atp operon from the extreme alkaliphile Bacillus firmus OF4 was cloned and sequenced, and shown to contain genes for the eight structural subunits of the ATP synthase, preceded by a ninth gene predicted to encode a 14 kDa hydrophobic protein. The arrangement of genes is identical to that of the atp operons from Escherichia coli, Bacillus megaterium, and thermophilic Bacillus PS3. The deduced amino acid sequences of the subunits of the enzyme are also similar to their homologs in other ATP synthases, except for several unusual substitutions, particularly in the a and c subunits. These substitutions are in domains that have been implicated in the mechanism of proton translocation through F₀-ATPase, and therefore could contribute to the gating properties of the alkaliphile ATP synthase or its capacity for proton capture.     

Relevance of Divalent Cations to ATP-Driven Proton Pumping in Beef Heart Mitochondrial F0F1-ATPase

The ATP hydrolysis rate and the ATP hydrolysis-linked proton translocation by the F₀F₁-ATPase of beef heart submitochondrial particles were examined in the presence of several divalent metal cations. All Me–ATP complexes tested sustained ATP hydrolysis, although to a different extent. However, only Mg- and Mn-ATP-dependent hydrolysis could sustain a high level of proton pumping activity, as determined by acridine fluorescence quenching. Moreover, the K _m of the Me-ATP hydrolysis-induced proton pumping activity was very similar to the K _m value of Me-ATP hydrolysis. Both oligomycin and DCCD caused the full recovery of the fluorescence, providing clear evidence for the association of Mg-ATP hydrolysis with proton translocation through the F₀F₁-ATPase complex. In contrast, with other Me-ATP complexes, including Ca-ATP as substrate, the proton pumping activity was undetectable, implicating an uncoupling nature for these substrates. Attempts to demonstrate the involvement of the subunit of the enzyme in the coupling mechanism failed, suggesting that the participation of at least the N-terminal segment of the subunit in the coupling mechanism of the mitochondrial enzyme is unlikely.     

Structure analysis of membrane-reconstituted subunit <Emphasis Type="Italic">c</Emphasis>-ring of <Emphasis Type="Italic">E. coli</Emphasis> H<Superscript>+</Superscript>-ATP synthase by solid-state NMR

The subunit c-ring of H⁺-ATP synthase (F_o c-ring) plays an essential role in the proton translocation across a membrane driven by the electrochemical potential. To understand its structure and function, we have carried out solid-state NMR analysis under magic-angle sample spinning. The uniformly [¹³C, ¹⁵N]-labeled F_o c from E. coli (EF_o c) was reconstituted into lipid membranes as oligomers. Its high resolution two- and three-dimensional spectra were obtained, and the ¹³C and ¹⁵N signals were assigned. The obtained chemical shifts suggested that EF_o c takes on a hairpin-type helix-loop-helix structure in membranes as in an organic solution. The results on the magnetization transfer between the EF_o c and deuterated lipids indicated that Ile55, Ala62, Gly69 and F76 were lined up on the outer surface of the oligomer. This is in good agreement with the cross-linking results previously reported by Fillingame and his colleagues. This agreement reveals that the reconstituted EF_o c oligomer takes on a ring structure similar to the intact one in vivo. On the other hand, analysis of the ¹³C nuclei distance of [3-¹³C]Ala24 and [4-¹³C]Asp61 in the F_o c-ring did not agree with the model structures proposed for the EF_o c-decamer and dodecamer. Interestingly, the carboxyl group of the essential Asp61 in the membrane-embedded EF_o c-ring turned out to be protonated as COOH even at neutral pH. The hydrophobic surface of the EF_o c-ring carries relatively short side chains in its central region, which may allow soft and smooth interactions with the hydrocarbon chains of lipids in the liquid-crystalline state.     

猪心线粒体Fo的纯化、重建及其质子转运功能

比较了猪心线粒体F_oF₁-ATPase膜部分F_o的四种纯化方法.结果表明,用NaBr从亚线粒体除去F_oF₁-ATPase的水溶性部分F₁-ATPase后,再以CHAPS增溶,并经蔗糖梯度离心,可获得高纯度的F_o.SDS-聚丙烯酰胺凝胶电泳鉴定表明,纯化的F_o含有b、OSCP（寡霉素敏感授予蛋白）、d、a、e、F₆、IF₁、A6L和c等9种亚基.用去污剂稀释法将纯化的F_o在脂质体上重建后,重建F_o表现较高的被动转运质子活性.这为在体外深入研究F_o的活性、构象与膜脂的关系,以及F_o与F₁-ATPase的组装等提供了很好的实验模型.     

Mutagenic Analysis of the F 0 Stator Subunits

The a and b subunits constitute the stator elements in the F₀ sector of F₁F₀-ATP synthase.Both subunits have been difficult to study by physical means, so most of the information onstructure and function relationships in the a and b subunits has been obtained using mutagenesisin combination with biochemical methods. These approaches were used to demonstrate thatthe a subunit in association with the ring of c subunits houses the proton channel throughF₁F₀-ATP synthase. The map of the amino acids contributing to the proton channel is probablycomplete. The two b subunits dimerize, forming an extended flexible unit in the peripheralstalk linking the F₁ and F₀ sectors. The unique characteristics of specific amino acid substitutionsaffecting the a and b subunits suggested differential effects on rotation during F₁F₀-ATPaseactivity.     

ATP Synthases With Novel Rotor Subunits: New Insights into Structure,Function and Evolution of ATPases

ATPases with unusual membrane-embedded rotor subunits were found in both F₁F₀ and A₁A₀ ATP synthases. The rotor subunit c of A₁A₀ ATPases is, in most cases, similar to subunit c from F₀. Surprisingly, multiplied c subunits with four, six, or even 26 transmembrane spans have been found in some archaea and these multiplication events were sometimes accompanied by loss of the ion-translocating group. Nevertheless, these enzymes are still active as ATP synthases. A duplicated c subunit with only one ion-translocating group was found along with “normal” F₀ c subunits in the Na⁺ F₁F₀ ATP synthase of the bacterium Acetobacterium woodii. These extraordinary features and exceptional structural and functional variability in the rotor of ATP synthases may have arisen as an adaptation to different cellular needs and the extreme physicochemical conditions in the early history of life.     

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.     

Subunit Organization of the Stator Part of the F 0 Complex from Escherichia coli ATP Synthase

Membrane-bound ATP synthases (F₁F₀) catalyze the synthesis of ATP via a rotary catalyticmechanism utilizing the energy of an electrochemical ion gradient. The transmembrane potentialis supposed to propel rotation of a subunit c ring of F₀ together with subunits and of F₁,hereby forming the rotor part of the enzyme, whereas the remainder of the F₁F₀ complexfunctions as a stator for compensation of the torque generated during rotation. This reviewfocuses on our recent work on the stator part of the F₀ complex, e.g., subunits a and b. Usingepitope insertion and antibody binding, subunit a was shown to comprise six transmembranehelixes with both the N- and C-terminus oriented toward the cytoplasm. By use of circulardichroism (CD) spectroscopy, the secondary structure of subunit b incorporated intoproteoliposomes was determined to be 80% -helical together with 14% turn conformation, providingflexibility to the second stalk. Reconstituted subunit b together with isolated ac subcomplexwas shown to be active in proton translocation and functional F₁ binding revealing the nativeconformation of the polypeptide chain. Chemical crosslinking in everted membrane vesiclesled to the formation of subunit b homodimers around residues bQ37 to bL65, whereas bA32Ccould be crosslinked to subunit a, indicating a close proximity of subunits a and b near themembrane. Further evidence for the proposed direct interaction between subunits a and b wasobtained by purification of a stable ab ₂ subcomplex via affinity chromatography using Histags fused to subunit a or b. This ab ₂ subcomplex was shown to be active in proton translocationand F₁ binding, when coreconstituted with subunit c. Consequences of crosslink formationand subunit interaction within the F₁F₀ complex are discussed.     

Effects of mutations in the beta subunit hinge domain on ATP synthase F1 sector rotation: interaction between Ser 174 and Ile 163

A complex of γ, ε, and c subunits rotates in ATP synthase (F_oF₁) coupling with proton transport. Replacement of βSer174 by Phe in β-sheet4 of the β subunit (βS174F) caused slow γ subunit revolution of the F₁ sector, consistent with the decreased ATPase activity [M. Nakanishi-Matsui, S. Kashiwagi, T. Ubukata, A. Iwamoto-Kihara, Y. Wada, M. Futai, Rotational catalysis of Escherichia coli ATP synthase F1 sector. Stochastic fluctuation and a key domain of the β subunit, J. Biol. Chem. 282 (2007) 20698-20704]. Modeling of the domain including β-sheet4 and α-helixB predicted that the mutant βPhe174 residue undergoes strong and weak hydrophobic interactions with βIle163 and βIle166, respectively. Supporting this prediction, the replacement of βIle163 in α-helixB by Ala partially suppressed the βS174F mutation: in the double mutant, the revolution speed and ATPase activity recovered to about half of the levels in the wild-type. Replacement of βIle166 by Ala lowered the revolution speed and ATPase activity to the same levels as in βS174F. Consistent with the weak hydrophobic interaction, βIle166 to Ala mutation did not suppress βS174F. Importance of the hinge domain [phosphate-binding loop (P-loop)/α-helixB/loop/β-sheet4, βPhe148-βGly186] as to driving rotational catalysis is discussed.