The cysteine introduced into the alpha subunit of the Escherichia coli F1-ATPase by the mutation alpha R376C is near the alpha-beta subunit interface and close to a noncatalytic nucleotide binding site

Torque transmission mechanism via DELSEED loop of F1-ATPase

F1-ATPase (F1) is an ATP-driven rotary motor in which the three catalytic β subunits in the stator ring sequentially induce the unidirectional rotation of the rotary γ subunit. Many lines of evidence have revealed open-to-closed conformational transitions in the β subunit that swing the C-terminal domain inward. This conformational transition causes a C-terminal protruding loop with conserved sequence DELSEED to push the γ subunit. Previous work, where all residues of DELSEED were substituted with glycine to disrupt the specific interaction with γ and introduce conformational flexibility, showed that F1 still rotated, but that the torque was halved, indicating a remarkable impact on torque transmission. In this study, we conducted a stall-and-release experiment on F1 with a glycine-substituted DELSEED loop to investigate the impact of the glycine substitution on torque transmission upon ATP binding and ATP hydrolysis. The mutant F1 showed a significantly reduced angle-dependent change in ATP affinity, whereas there was no change in the equilibrium for ATP hydrolysis. These findings indicate that the DELSEED loop is predominantly responsible for torque transmission upon ATP binding but not for that upon ATP hydrolysis.

Mechanism of the αβ conformational change in F1-ATPase after ATP hydrolysis: free-energy simulations

One of the motive forces for F1-ATPase rotation is the conformational change of the catalytically active β subunit due to closing and opening motions caused by ATP binding and hydrolysis, respectively. The closing motion is accomplished in two steps: the hydrogen-bond network around ATP changes and then the entire structure changes via B-helix sliding, as shown in our previous study. Here, we investigated the opening motion induced by ATP hydrolysis using all-atom free-energy simulations, combining the nudged elastic band method and umbrella sampling molecular-dynamics simulations. Because hydrolysis requires residues in the α subunit, the simulations were performed with the αβ dimer. The results indicate that the large-scale opening motion is also achieved by the B-helix sliding (in the reverse direction). However, the sliding mechanism is different from that of ATP binding because sliding is triggered by separation of the hydrolysis products ADP and Pi. We also addressed several important issues: 1), the timing of the product Pi release; 2), the unresolved half-closed β structure; and 3), the ADP release mechanism. These issues are fundamental for motor function; thus, the rotational mechanism of the entire F1-ATPase is also elucidated through this αβ study. During the conformational change, conserved residues among the ATPase proteins play important roles, suggesting that the obtained mechanism may be shared with other ATPase proteins. When combined with our previous studies, these results provide a comprehensive view of the β-subunit conformational change that drives the ATPase.

Molecular mechanism of ATP hydrolysis in F1-ATPase revealed by molecular simulations and single-molecule observations

Enzymatic hydrolysis of nucleotide triphosphate (NTP) plays a pivotal role in protein functions. In spite of its biological significance, however, the chemistry of the hydrolysis catalysis remains obscure because of the complex nature of the reaction. Here we report a study of the molecular mechanism of hydrolysis of adenosine triphosphate (ATP) in F(1)-ATPase, an ATP-driven rotary motor protein. Molecular simulations predicted and single-molecule observation experiments verified that the rate-determining step (RDS) is proton transfer (PT) from the lytic water molecule, which is strongly activated by a metaphosphate generated by a preceding P(γ)-O(β) bond dissociation (POD). Catalysis of the POD that triggers the chain activation of the PT is fulfilled by hydrogen bonds between Walker motif A and an arginine finger, which commonly exist in many NTPases. The reaction mechanism unveiled here indicates that the protein can regulate the enzymatic activity for the function in both the POD and PT steps despite the fact that the RDS is the PT step.

Principal role of the arginine finger in rotary catalysis of F1-ATPase

F(1)-ATPase (F(1)) is an ATP-driven rotary motor wherein the γ subunit rotates against the surrounding α(3)β(3) stator ring. The 3 catalytic sites of F(1) reside on the interface of the α and β subunits of the α(3)β(3) ring. While the catalytic residues predominantly reside on the β subunit, the α subunit has 1 catalytically critical arginine, termed the arginine finger, with stereogeometric similarities with the arginine finger of G-protein-activating proteins. However, the principal role of the arginine finger of F(1) remains controversial. We studied the role of the arginine finger by analyzing the rotation of a mutant F(1) with a lysine substitution of the arginine finger. The mutant showed a 350-fold longer catalytic pause than the wild-type; this pause was further lengthened by the slowly hydrolyzed ATP analog ATPγS. On the other hand, the mutant F(1) showed highly unidirectional rotation with a coupling ratio of 3 ATPs/turn, the same as wild-type, suggesting that cooperative torque generation by the 3 β subunits was not impaired. The hybrid F(1) carrying a single copy of the α mutant revealed that the reaction step slowed by the mutation occurs at +200° from the binding angle of the mutant subunit. Thus, the principal role of the arginine finger is not to mediate cooperativity among the catalytic sites, but to enhance the rate of the ATP cleavage by stabilizing the transition state of ATP hydrolysis. Lysine substitution also caused frequent pauses because of severe ADP inhibition, and a slight decrease in ATP-binding rate.

Normal-mode-based modeling of allosteric couplings that underlie cyclic conformational transition in F(1) ATPase

F(1) ATPase, a rotary motor comprised of a central stalk (gamma subunit) enclosed by three alpha and beta subunits alternately arranged in a hexamer, features highly cooperative binding and hydrolysis of ATP. Despite steady progress in biophysical, biochemical, and computational studies of this fascinating motor, the structural basis for cooperative ATPase involving its three catalytic sites remains not fully understood. To illuminate this key mechanistic puzzle, we have employed a coarse-grained elastic network model to probe the allosteric couplings underlying the cyclic conformational transition in F(1) ATPase at a residue level of detail. We will elucidate how ATP binding and product (ADP and phosphate) release at two catalytic sites are coupled with the rotation of gamma subunit via various domain motions in alpha(3)beta(3) hexamer (including intrasubunit hinge-bending motions in beta subunits and intersubunit rigid-body rotations between adjacent alpha and beta subunits). To this end, we have used a normal-mode-based correlation analysis to quantify the allosteric couplings of these domain motions to local motions at catalytic sites and the rotation of gamma subunit. We have then identified key amino acid residues involved in the above couplings, some of which have been validated against past studies of mutated and gamma-truncated F(1) ATPase. Our finding strongly supports a binding change mechanism where ATP binding to the empty catalytic site triggers a series of intra- and intersubunit domain motions leading to ATP hydrolysis and product release at the other two closed catalytic sites.

Structure of bovine mitochondrial F(1)-ATPase inhibited by Mg(2+) ADP and aluminium fluoride

BACKGROUND

The globular domain of the membrane-associated F(1)F(o)-ATP synthase complex can be detached intact as a water-soluble fragment known as F(1)-ATPase. It consists of five different subunits, alpha, beta, gamma, delta and epsilon, assembled with the stoichiometry 3:3:1:1:1. In the crystal structure of bovine F(1)-ATPase determined previously at 2.8 A resolution, the three catalytic beta subunits and the three noncatalytic alpha subunits are arranged alternately around a central alpha-helical coiled coil in the gamma subunit. In the crystals, the catalytic sites have different nucleotide occupancies. One contains the triphosphate form of the nucleotide, the second contains the diphosphate, and the third is unoccupied. Fluoroaluminate complexes have been shown to mimic the transition state in several ATP and GTP hydrolases. In order to understand more about its catalytic mechanism, F(1)-ATPase was inhibited with Mg(2+)ADP and aluminium fluoride and the structure of the inhibited complex was determined by X-ray crystallography.

RESULTS

The structure of bovine F(1)-ATPase inhibited with Mg(2+)ADP and aluminium fluoride determined at 2.5 A resolution differs little from the original structure with bound AMP-PNP and ADP. The nucleotide occupancies of the alpha and beta subunits are unchanged except that both aluminium trifluoride and Mg(2+)ADP are bound in the nucleotide-binding site of the beta(DP) subunit. The presence of aluminium fluoride is accompanied by only minor adjustments in the surrounding protein.

CONCLUSIONS

The structure appears to mimic a possible transition state. The coordination of the aluminofluoride group has many features in common with other aluminofluoride-NTP hydrolase complexes. Apparently, once nucleotide is bound to the catalytic beta subunit, no additional major structural changes are required for catalysis to occur.

Molecular mechanisms of rotational catalysis in the F(0)F(1) ATP synthase

Rotation of the F(0)F(1) ATP synthase gamma subunit drives each of the three catalytic sites through their reaction pathways. The enzyme completes three cycles and synthesizes or hydrolyzes three ATP for each 360 degrees rotation of the gamma subunit. Mutagenesis studies have yielded considerable information on the roles of interactions between the rotor gamma subunit and the catalytic beta subunits. Amino acid substitutions, such as replacement of the conserved gammaMet-23 by Lys, cause altered interactions between gamma and beta subunits that have dramatic effects on the transition state of the steady state ATP synthesis and hydrolysis reactions. The mutations also perturb transmission of specific conformational information between subunits which is important for efficient conversion of energy between rotation and catalysis, and render the coupling between catalysis and transport inefficient. Amino acid replacements in the transport domain also affect the steady state catalytic transition state indicating that rotation is involved in coupling to transport.

Importance of F1-ATPase residue alpha-Arg-376 for catalytic transition state stabilization

The functional role of essential residue alpha-Arg-376 in the catalytic site of F1-ATPase was studied. The mutants alpha R376C, alpha R376Q, and alpha R376K were constructed, and combined with the mutation beta Y331W, to investigate catalytic site nucleotide-binding parameters, and to assess catalytic transition state formation by measurement of MgADP-fluoroaluminate binding. Each mutation caused large impairment of ATP synthesis and hydrolysis. Despite the apparent proximity of alpha-Arg-376 to bound nucleoside di- and triphosphate in published X-ray structures, the mutations had little effect on MgADP or MgATP binding affinities, particularly at the highest affinity catalytic site, site 1. Both Cys and Gln mutants abolished transition state formation, demonstrating that alpha-Arg-376 is normally involved at this step of catalysis. A model of the F1-ATPase catalytic transition state structure is presented and discussed. The Lys mutant, although severely impaired, supported transition state formation, suggesting that an additional essential role for the alpha-Arg-376 guanidinium group exists, likely in alpha/beta conformational signal transmission required for steady-state catalysis. Parallels between alpha-Arg-376 and GAP/G-protein "arginine finger" residues are evident.

Catalytic mechanism of F1-ATPase

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

The trapping of different conformations of the Escherichia coli F1 ATPase by disulfide bond formation. Effect on nucleotide binding affinities of the catalytic sites

Two mutants of the Escherichia coli F1 ATPase, betaY331W:E381C/epsilonS108C and alphaS411C/betaY331W/epsilonS108C, have been used to relate nucleotide binding in catalytic sites with different interactions of the stalk-forming subunits gamma and epsilon at the alpha3beta3 subunit domain. Essentially full yield cross-linking between beta + gamma and beta + epsilon, or between alpha + gamma and alpha + epsilon, was obtained in these mutants by Cu2+-induced disulfide bond formation, thereby trapping the enzyme in states with the small subunits interacting either with beta or alpha subunits. The presence of the Trp for beta Tyr-331 in both mutants allowed direct measurement of nucleotide occupancy of catalytic sites. Before cross-linking, Mg2+ATP could be bound in all three catalytic sites in both mutants with a Kd of around 0.1 microM for the highest affinity site and Kd values of approximately 2 microM and 30-40 microM for the second and third sites, respectively. In the absence of Mg2+, ATP also bound in all three catalytic sites but with a single low affinity (above 100 microM) in both mutants. Cu2+-induced cross-linking of ECF1 from the mutant betaY331W:E381C/epsilonS108C had very little effect on nucleotide binding. The binding affinities of the three catalytic sites for Mg2+ATP were not significantly altered from those obtained before cross-linking, and the enzyme still switched between cooperative binding and equal binding affinities of the three catalytic sites (when Mg2+ was absent). When the gamma and epsilon subunits were cross-linked to alpha subunits, ATP binding in the highest affinity catalytic site was dramatically altered. This site became closed so that nucleotide (ATP or ADP) that had been bound into it prior to cross-linking was trapped and could not exchange out. Also, ATP or ADP could not enter this site, although empty, once the enzyme had been cross-linked. Finally, cross-linking of the gamma and epsilon to the alpha subunits prevented the switching between cooperative binding and the state where the three catalytic sites are equivalent. We argue that the conformation of the enzyme in which the small subunits are at alpha subunits occurs during functioning of the enzyme in the course of the rotation of gamma and epsilon subunits within the alpha3beta3 hexamer and that this may be the activated state for ATP synthesis.

Subunit movement during catalysis by F1-F0-ATP synthases

The catalytic portion (F1) of ATP synthases have the subunit composition alpha 3, beta 3, gamma, delta, epsilon. This composition imparts structural asymmetry to the entire complex that results in differences in nucleotide binding affinity among the six binding sites. Evidence that two or more sites participate in catalysis, alternating their properties, led to the notion that the interactions of individual alpha beta pairs with the small subunit must change as binding sites properties alternate. A rotation of the gamma subunit within the alpha 3 beta 3 hexamer has been proposed as a means of alternating the properties of catalytic sites. Evidence argues that the rotation of the complete gamma subunit during ATP hydrolysis is not mandatory for activity. The gamma subunit of chloroplast F1 may be cleaved into three large fragments that remain bound to F1. This cleavage enhances ATPase activity without loss of evidence of site-site interactions. Complexes of alpha 3 beta 3 have been shown to have significant ATPase activity in the absence of gamma. Mg2+ATP affects the interaction of gamma with the different beta subunits, and induces other changes in F1, but whether these changes are induced by catalysis, or are fast enough to be involved in the catalytic turnover of the enzyme has not been established. Likewise, changes in structure and in binding site properties induced in thylakoid membrane bound CF1 by formation of an electrochemical proton gradient may activate the enzyme rather than be apart of catalysis. Mechanisms other than rotary catalysis should be considered.

The Escherichia coli F1-ATPase mutant beta Tyr-297-->Cys: functional studies and asymmetry of the enzyme under various nucleotide conditions based on reaction of the introduced Cys with N-ethylmaleimide and 7-chloro-4-nitrobenzofurazan

Conversion of residue beta Tyr-297 of the Escherichia coli F1-ATPase (ECF1) to a Cys in the mutant beta Y297C led to impaired oxidative phosphorylation based on growth curves. The ATPase activity of ECF1 isolated from the mutant beta Y297C was only 1% of wild-type activity, but the residual activity involves cooperative multi-site enzyme turnover based on inhibition by DCCD and azide. ATPase activity could be increased to 8%, and 13% of wild-type by reaction of the introduced Cys with N-ethyl maleimide (NEM), and 7-chloro-4-nitrobenzofurazan (NbfCl), respectively, suggesting that enzymatic function is improved by an increased hydrophobicity of residue beta Cys-297. The mutation beta Tyr-297-->Cys had no effect on nucleotide binding in studies with the fluorescent analog lin-benzo-ADP. The asymmetry of ECF1 was investigated in the mutants beta Y297C and beta Y297C:E381C/epsilon S108C by examining the relative reactivity of Cys-297 in the three copies of the beta subunit under different nucleotide binding conditions. In agreement with a previous study (Haughton, M.A. and Capaldi, R.A. (1995) J. Biol. Chem., 270, 20568-20574), the asymmetry was maintained under all nucleotide conditions. The NbfCl reaction site was found to be beta free, which is also the site most reactive to NEM, beta epsilon is the second site which reacts with NbfCl or NEM, while the third site, beta gamma, is poorly reactive to either reagent.

ATP-dependent inactivation of the beta-Ser339Cys mutant F1-ATPase from Escherichia coli by N-ethylmaleimide

We introduced mutations at the highly-conserved residue Ser-339 in subunit beta of Escherichia coli F1-ATPase. The mutations beta S339Y and beta S339F abolished ATPase activity and impaired enzyme assembly. In contrast beta S339C F1 retained function to a substantial degree. N-Ethylmaleimide (NEM) at 0.2-0.3 mM inactivated beta S339C F1-ATPase by 80-95% in the presence of MgATP or MgADP but did not inactivate appreciably in absence of nucleotide or presence of EDTA. In absence of nucleotide, 0.7 mol of [14C-NEM] was incorporated into beta-subunits of 1.0 mol F1: in presence of MgATP the amount was 1.7 mol/mol, i.e. the introduced Cys residue became more accessible to reaction in the presence of MgATP. In the X-ray structure of F1 (Abrahams et al. (1994) Nature 370, 621-628) one of the catalytic nucleotide-binding domains is empty (on the "beta E subunit") and contains a cleft. Residue beta-339 lies within this cleft; the cleft does not occur in the other two beta-subunits. Our data are consistent with the conclusion that in wild-type enzyme under physiological conditions, MgATP or MgADP induce an enzyme conformation in which residue beta-Ser-339 becomes more exposed, possibly similar to the situation seen in the "beta E-subunit" in the X-ray structure.

F1-ATPase alpha-subunit made up from two fragments (1-395, 396-503) is stabilized by ATP and complexes containing it obey altered kinetics

Inferred from the crystal structure of mitochondrial F1-ATPase (Abrahams, J.P. et al. (1994) Nature 370, 621-628), the proteinase-sensitive region around Phe-395 of thermophilic F1-ATPase alpha-subunit corresponds to the loop which connects main part of the carboxyl-terminal helical bundle domain with the ATP binding domain. This loop is in contact with the gamma- and adjacent beta-subunits. Two polypeptides corresponding to the sequence 1-395 and 396-503 of the alpha-subunit were expressed in Escherichia coli cells and they were copurified as an apparently functional alpha-subunit (alpha(395/396)) made up of two polypeptides. The isolated alpha(395/396) was stabilized by ATP-Mg, but not by ADP-Mg, although it bound both ATP-Mg and ADP-Mg with similar affinities (Kd, 11 microM and 14 microM, respectively). The alpha(395/396) was reconstitutable into alpha(395/396)3 beta 3 and alpha(395/396)3 beta 3 gamma complexes. Different from the intact the ATP-Mg-induced dissociation into alpha 1 beta 1 heterodimers. ATP hydrolysis by the alpha(395/396)3 beta 3 gamma complex underwent a slow initial phase, whereas the intact alpha 3 beta 3 gamma complex exhibited an accelerated initial phase. Steady-state ATPase activity at various ATP concentrations showed negative cooperativity for the intact alpha 3 beta 3 gamma complex but apparently positive cooperativity for the alpha(395/396)3 beta 3 gamma complex. The ATPase activities at a saturating ATP concentration of the complexes containing the alpha(395/396) were 180% of those containing intact alpha-subunits. These results indicate that a loop around Phe-395 is involved in intersubunit interaction in F1-ATPase.