Trinitrophenyl-ATP and -ADP bind to a single nucleotide site on isolated beta-subunit of Escherichia coli F1-ATPase. In vitro assembly of F1-subunits requires occupancy of the nucleotide-binding site on beta-subunit by nucleoside triphosphate

Two ATPases

In this article, I reflect on research on two ATPases. The first is F(1)F(0)-ATPase, also known as ATP synthase. It is the terminal enzyme in oxidative phosphorylation and famous as a nanomotor. Early work on mitochondrial enzyme involved purification in large amount, followed by deduction of subunit composition and stoichiometry and determination of molecular sizes of holoenzyme and individual subunits. Later work on Escherichia coli enzyme utilized mutagenesis and optical probes to reveal the molecular mechanism of ATP hydrolysis and detailed facets of catalysis. The second ATPase is P-glycoprotein, which confers multidrug resistance, notably to anticancer drugs, in mammalian cells. Purification of the protein in large quantity allowed detailed characterization of catalysis, formulation of an alternating sites mechanism, and recently, advances in structural characterization.

A functionally important hydrogen-bonding network at the betaDP/alphaDP interface of ATP synthase

ATP synthase uses a unique rotary mechanism to couple ATP synthesis and hydrolysis to transmembrane proton translocation. The F1 subcomplex has three catalytic nucleotide binding sites, one on each beta subunit, at the interface to the adjacent alpha subunit. In the x-ray structure of F1 (Abrahams, J. P., Leslie, A. G. W., Lutter, R., and Walker, J. E. (1994) Nature 370, 621-628), the three catalytic beta/alpha interfaces differ in the extent of inter-subunit interactions between the C termini of the beta and alpha subunits. At the closed betaDP/alphaDP interface, a hydrogen-bonding network is formed between both subunits, which is absent at the more open betaTP/alphaTP interface and at the wide open betaE/alphaE interface. The hydrogen-bonding network reaches from betaL328 (Escherichia coli numbering) and betaQ441 via alphaQ399, betaR398, and alphaE402 to betaR394, and ends in a cation/pi interaction between betaR394 and alphaF406. Using mutational analysis in E. coli ATP synthase, the functional importance of the betaDP/alphaDP hydrogen-bonding network is demonstrated. Its elimination results in a severely impaired enzyme but has no pronounced effect on the binding affinities of the catalytic sites. A possible role for the hydrogen-bonding network in coupling of ATP synthesis/hydrolysis and rotation will be discussed.

Identification of the betaTP site in the x-ray structure of F1-ATPase as the high-affinity catalytic site

ATP synthase uses a unique rotary mechanism to couple ATP synthesis and hydrolysis to transmembrane proton translocation. The F(1) subcomplex has three catalytic nucleotide binding sites, one on each beta subunit, with widely differing affinities for MgATP or MgADP. During rotational catalysis, the sites switch their affinities. The affinity of each site is determined by the position of the central gamma subunit. The site with the highest nucleotide binding affinity is catalytically active. From the available x-ray structures, it is not possible to discern the high-affinity site. Using fluorescence resonance energy transfer between tryptophan residues engineered into gamma and trinitrophenyl nucleotide analogs on the catalytic sites, we were able to determine that the high-affinity site is close to the C-terminal helix of gamma, but at considerable distance from its N terminus. Thus, the beta(TP) site in the x-ray structure [Abrahams JP, Leslie AGW, Lutter R, Walker JE (1994) Nature 370:621-628] is the high-affinity site, in agreement with the prediction of Yang et al. [Yang W, Gao YQ, Cui Q, Ma J, Karplus M (2003) Proc Natl Acad Sci USA 100:874-879]. Taking into account the known direction of rotation, the findings establish the sequence of affinities through which each catalytic site cycles during MgATP hydrolysis as low --> high --> medium --> low.

Inhibition of the ATPase activity of Escherichia coli ATP synthase by magnesium fluoride

Inhibition of ATPase activity of Escherichia coli ATP synthase by magnesium fluoride (MgFx) was studied. Wild-type F(1)-ATPase was inhibited potently, albeit slowly, when incubated with MgCl(2), NaF, and NaADP. The combination of all three components was required. Reactivation of ATPase activity, after removal of unbound ligands, occurred with half-time of approximately 14 h at 22 degrees C and was quasi-irreversible at 4 degrees C. Mutant F(1)-ATPases, in which catalytic site residues involved in transition state formation were modified, were found to be resistant to inhibition by MgFx. The data demonstrate that MgFx in combination with MgADP behaves as a tight-binding transition state analog in E. coli ATP synthase.

Involvement of ATP synthase residues alphaArg-376, betaArg-182, and betaLys-155 in Pi binding

alphaArg-376, betaLys-155, and betaArg-182 are catalytically important ATP synthase residues that were proposed to be involved in substrate Pi binding and subsequent steps of ATP synthesis [Senior, A.E., Nadanaciva, S. and Weber, J. (2002) Biochim. Biophys. Acta 1553, 188-211]. Here, it was shown using purified Escherichia coli F(1)-ATPase that whereas Pi protected wild-type from reaction with 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole, mutations betaK155Q, betaR182Q, betaR182K, and alphaR376Q abolished protection. Therefore, in ATP synthesis initial binding of substrate Pi in open catalytic site betaE is supported by each of these three residues.

Role of betaAsn-243 in the phosphate-binding subdomain of catalytic sites of Escherichia coli F(1)-ATPase

In the catalytic mechanism of ATP synthase, phosphate (P(i)) binding and release steps are believed to be correlated to gamma-subunit rotation, and P(i) binding is proposed to be prerequisite for binding ADP in the face of high cellular [ATP]/[ADP] ratios. In x-ray structures, residue betaAsn-243 appears centrally located in the P(i)-binding subdomain of catalytic sites. Here we studied the role of betaAsn-243 in Escherichia coli ATP synthase by mutagenesis to Ala and Asp. Mutation betaN243A caused 30-fold impairment of F(1)-ATPase activity; 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole inhibited this activity less potently than in wild type and P(i) protected from inhibition. ADP-fluoroaluminate was more inhibitory than in wild-type, but ADP-fluoroscandium was less inhibitory. betaN243D F(1)-ATPase activity was impaired by 1300-fold and was not inhibited by ADP-fluoroaluminate or ADP-fluoroscandium. 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole activated betaN243D F(1)-ATPase, and P(i) did not affect activation. We conclude that residue betaAsn-243 is not involved in P(i) binding directly but is necessary for correct organization of the transition state complex through extensive involvement in hydrogen bonding to neighboring residues. It is also probably involved in orientation of the "attacking water" and of an associated second water.

Mutagenesis of residue betaArg-246 in the phosphate-binding subdomain of catalytic sites of Escherichia coli F1-ATPase

Residues responsible for phosphate binding in F(1)F(0)-ATP synthase catalytic sites are of significant interest because phosphate binding is believed linked to proton gradient-driven subunit rotation. From x-ray structures, a phosphate-binding subdomain is evident in catalytic sites, with conserved betaArg-246 in a suitable position to bind phosphate. Mutations betaR246Q, betaR246K, and betaR246A in Escherichia coli were found to impair oxidative phosphorylation and to reduce ATPase activity of purified F(1) by 100-fold. In contrast to wild type, ATPase of mutants was not inhibited by MgADP-fluoroaluminate or MgADP-fluoroscandium, showing the Arg side chain is required for wild-type transition state formation. Whereas 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-Cl) inhibited wild-type ATPase essentially completely, ATPase in mutants was inhibited maximally by approximately 50%, although reaction still occurred at residue betaTyr-297, proximal to betaArg-246 in the phosphate-binding pocket. Inhibition characteristics supported the conclusion that NBD-Cl reacts in betaE (empty) catalytic sites, as shown previously by x-ray structure analysis. Phosphate protected against NBD-Cl inhibition in wild type but not in mutants. The results show that phosphate can bind in the betaE catalytic site of E. coli F(1) and that betaArg-246 is an important phosphate-binding residue.

Quantitative determination of direct binding of b subunit to F1 in Escherichia coli F1F0-ATP synthase

The stator in F(1)F(0)-ATP synthase resists strain generated by rotor torque. In Escherichia coli, the b(2)delta subunit complex comprises the stator, bound to subunit a in F(0) and to the alpha(3)beta(3) hexagon of F(1). To quantitatively characterize binding of b subunit to the F(1) alpha(3)beta(3) hexagon, we developed fluorimetric assays in which wild-type F(1), or F(1) enzymes containing introduced Trp residues, were titrated with a soluble portion of the b subunit (b(ST34-156)). With five different F(1) enzymes, K(d)(b(ST34-156)) ranged from 91 to 157 nm. Binding was strongly Mg(2+)-dependent; in EDTA buffer, K(d)(b(ST34-156)) was increased to 1.25 microm. The addition of the cytoplasmic portion of the b subunit increases the affinity of binding of delta subunit to delta-depleted F(1). The apparent K(d)(b(ST34-156)) for this effect was increased from 150 nm in Mg(2+) buffer to 1.36 microm in EDTA buffer. This work demonstrates quantitatively how binding of the cytoplasmic portion of the b subunit directly to F(1) contributes to stator resistance and emphasizes the importance of Mg(2+) in stator interactions.

Structural energetics of MgADP binding to the isolated beta subunit of F1-ATPase from thermophilic Bacillus PS3

The energetics of binding of MgADP to the isolated beta subunit of F(1)-ATPase from thermophilic Bacillus (Tbeta) was characterized by high-precision isothermal titration calorimetry. The reaction was enthalpically driven, with a DeltaCp of -36cal(molK)(-1). To gain insight into the molecular basis of this small DeltaCp, we analyzed the changes in accessible surface areas (DeltaASA) between the structures of empty and MgADP-filled beta subunits, extracted from the crystal structure of bovine heart F(1). Consistent with the experimental DeltaCp, the DeltaASA was small (-775A(2)). We used a reported surface area model developed for protein reactions to calculate DeltaCp and DeltaH from DeltaASA, obtaining good agreement with the experimental values. Conversely, using the same model, a DeltaASA of -770A(2) was estimated from experimental DeltaCp and DeltaH for the Tbeta-MgADP complex. Our structural-energetic study indicates that on MgADP binding the isolated Tbeta subunit exhibits intrinsic structural changes similar to those observed in F(1).

Quantitative determination of binding affinity of delta-subunit in Escherichia coli F1-ATPase: effects of mutation, Mg2+, and pH on Kd

To study the stator function in ATP synthase, a fluorimetric assay has been devised for quantitative determination of binding affinity of delta-subunit to Escherichia coli F(1)-ATPase. The signal used is that of the natural tryptophan at residue delta28, which is enhanced by 50% upon binding of delta-subunit to alpha(3)beta(3)gammaepsilon complex. K(d) for delta binding is 1.4 nm, which is energetically equivalent (50.2 kJ/mol) to that required to resist the rotor strain. Only one site for delta binding was detected. The deltaW28L mutation increased K(d) to 4.6 nm, equivalent to a loss of 2.9 kJ/mol binding energy. While this was insufficient to cause detectable functional impairment, it did facilitate preparation of delta-depleted F(1). The alphaG29D mutation reduced K(d) to 26 nm, equivalent to a loss of 7.2 kJ/mol binding energy. This mutation did cause serious functional impairment, referable to interruption of binding of delta to F(1). Results with the two mutants illuminate how finely balanced is the stator resistance function. delta' fragment, consisting of residues delta1-134, bound with the same K(d) as intact delta, showing that, at least in absence of F(o) subunits, the C-terminal domain of delta contributes zero binding energy. Mg(2+) ions had a strong effect on increasing delta binding affinity, supporting the possibility of bridging metal ion involvement in stator function. High pH environment greatly reduced delta binding affinity, suggesting the involvement of protonatable side-chains in the binding site.

Cysteine-reactive fluorescence probes of catalytic sites of ATP synthase

We searched for new fluorescent probes of catalytic-site nucleotide binding in F(1)F(0)-ATP synthase by introducing Cys mutations at positions in or close to catalytic sites and then reacting Cys-mutant F(1) with thiol-reactive fluorescent probes. Four suitable mutant/probe combinations were identified. beta F410C labeled by 7-fluorobenz-2-oxa-1,3-diazole-4-sulfonamide (ABD-F) gave very large signal changes in response to nucleotide, allowing facile measurement of fluorescence and nucleotide-binding parameters, not only in F(1) but also in F(1)F(0). The results are consistent with the presence of three asymmetric catalytic sites of widely different affinities, with similar properties in both enzymes, and revealed a unique probe environment at the high-affinity site 1. beta Y331C F(1) labeled by ABD-F gave a large signal which monitored catalytic site polarity changes that occur along the ATP hydrolysis pathway. Two other mutant/probe combinations with significant nucleotide-responsive signals were beta Y331C labeled by 5-((((2-iodoacetyl)amino)ethyl)amino)naphthaline-1-sulfonic acid and alpha F291C labeled by 2-4'-(iodoacetamido)anilino)naphthalene-6-sulfonic acid. The signal of the latter responds differentially to nucleoside diphosphate versus triphosphate bound in catalytic sites.

Bi-site catalysis in F1-ATPase: does it exist?

The mechanism of action of F(1)F(0)-ATP synthase is controversial. Some favor a tri-site mechanism, where substrate must fill all three catalytic sites for activity, others a bi-site mechanism, where one of the three sites is always unoccupied. New approaches were applied to examine this question. First, ITP was used as hydrolysis substrate; lower binding affinities of ITP versus ATP enable more accurate assessment of sites occupancy. Second, distributions of all eight possible enzyme species (with zero, one, two or three sites filled) as fraction of total enzyme population at each ITP concentration were calculated, and compared with measured ITPase activity. Confirming data were obtained with ATP as substrate. Third, we performed a theoretical analysis of possible bi-site mechanisms. The results argue convincingly that bi-site hydrolysis activity is negligible, and may not even exist. Effectively, tri-site hydrolysis is the only mechanism. We argue that only tri-site hydrolysis drives subunit rotation. Theoretical analyses of possible bi-site mechanisms reveal serious flaws, not previously recognized. One is that, in bi-site catalysis, the predicted direction of subunit rotation is the same for both ATP synthesis and hydrolysis; a second is that infrequently occurring enzyme species are required.

Effect of the epsilon-subunit on nucleotide binding to Escherichia coli F1-ATPase catalytic sites

The influence of the epsilon-subunit on the nucleotide binding affinities of the three catalytic sites of Escherichia coli F1-ATPase was investigated, using a genetically engineered Trp probe in the adenine-binding subdomain (beta-Trp-331). The interaction between epsilon and F1 was not affected by the mutation. Kd for binding of epsilon to betaY331W mutant F1 was approximately 1 nM, and epsilon inhibited ATPase activity by 90%. The only nucleotide binding affinities that showed significant differences in the epsilon-depleted and epsilon-replete forms of the enzyme were those for MgATP and MgADP at the high-affinity catalytic site 1. Kd1(MgATP) and Kd1(MgADP) were an order of magnitude higher in the absence of epsilon than in its presence. In contrast, the binding affinities for MgATP and MgADP at sites 2 and 3 were similar in the epsilon-depleted and epsilon-replete enzymes, as were the affinities at all three sites for free ATP and ADP. Comparison of MgATP binding and hydrolysis parameters showed that in the presence as well as the absence of epsilon, Km equals Kd3. Thus, in both cases, all three catalytic binding sites have to be occupied to obtain rapid (Vmax) MgATP hydrolysis rates.

Binding of the transition state analog MgADP-fluoroaluminate to F1-ATPase

Escherichia coli F1-ATPase from mutant betaY331W was potently inhibited by fluoroaluminate plus MgADP but not by MgADP alone. beta-Trp-331 fluorescence was used to measure MgADP binding to catalytic sites. Fluoroaluminate induced a very large increase in MgADP binding affinity at catalytic site one, a smaller increase at site two, and no effect at site three. Mutation of either of the critical catalytic site residues beta-Lys-155 or beta-Glu-181 to Gln abolished the effects of fluoroaluminate on MgADP binding. The results indicate that the MgADP-fluoroaluminate complex is a transition state analog and independently demonstrate that residues beta-Lys-155 and (particularly) beta-Glu-181 are important for generation and stabilization of the catalytic transition state. Dicyclohexylcarbodiimide-inhibited enzyme, with 1% residual steady-state ATPase, showed normal transition state formation as judged by fluoroaluminate-induced MgADP binding affinity changes, consistent with a proposed mechanism by which dicyclohexylcarbodiimide prevents a conformational interaction between catalytic sites but does not affect the catalytic step per se. The fluorescence technique should prove valuable for future transition state studies of F1-ATPase.

Effects of the inhibitors azide, dicyclohexylcarbodiimide, and aurovertin on nucleotide binding to the three F1-ATPase catalytic sites measured using specific tryptophan probes

Equilibrium nucleotide binding to the three catalytic sites of Escherichia coli F1-ATPase was measured in the presence of the inhibitors azide, dicyclohexylcarbodiimide, and aurovertin to elucidate mechanisms of inhibition. Fluorescence signals of beta-Trp-331 and beta-Trp-148 substituted in catalytic sites were used to determine nucleotide binding parameters. Azide brought about small decreases in Kd(MgATP) and Kd(MgADP). Notably, under MgATP hydrolysis conditions, it caused all enzyme molecules to assume a state with three catalytic site-bound MgATP and zero bound MgADP. These results rule out the idea that azide inhibits by "trapping" MgADP. Rather, azide blocks the step at which signal transmission between catalytic sites promotes multisite hydrolysis. Aurovertin bound with stoichiometry of 1.8 (mol/mol of F1) and allowed significant residual turnover. Cycling of the aurovertin-free beta-subunit catalytic site through three normal conformations was indicated by MgATP binding data. Aurovertin did not change the normal ratio of 1 bound MgATP/2 bound MgADP in catalytic sites. The results indicate that it acts to slow the switch of catalytic site affinities ("binding change step") subsequent to MgATP hydrolysis. Dicyclohexylcarbodiimide shifted the ratio of catalytic site-bound MgATP/MgADP from 1:2 to 1.6:1.4, without affecting Kd(MgATP) values. Like azide, it also appears to affect activity at the step after MgATP binding, in which signal transmission between catalytic sites promotes MgATP hydrolysis.

Binding of TNP-ATP and TNP-ADP to the non-catalytic sites of Escherichia coli F1-ATPase

Using site-directed-tryptophan fluorescence, parameters for equilibrium binding of (Mg)TNP-ATP and (Mg)TNP-ADP to non-catalytic sites of Escherichia coli F1-ATPase were determined. All three non-catalytic sites showed the same affinity for MgTNP-ATP (Kd = 0.2 microM) or MgTNP-ADP (Kd = 6.5 microM) whereas even at concentrations of 100 microM no binding of uncomplexed TNP-ATP or TNP-ADP was observed. The results demonstrate that the three non-catalytic sites bind TNP-nucleotides non-cooperatively, and emphasize the importance of Mg2+ for non-catalytic-site nucleotide binding. Parameters for binding of (Mg)TNP-ADP to the three catalytic sites were also determined, and showed marked cooperativity. This work completes the set of thermodynamic parameters for equilibrium binding of (Mg)TNP-ATP and (Mg)TNP-ADP to all six nucleotide sites of F1, providing essential information to fully exploit the potential of these nucleotide analogs in studies of F1-ATPase.

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.

F1-ATPase, roles of three catalytic site residues

Three critical residues, beta-Lys-155, beta-Asp-242, and beta-Glu-181, situated close to the gamma-phosphate of MgATP in F1-ATPase catalytic sites, were investigated. The mutations betaK155Q, betaD242N, and betaE181Q were each combined with the betaY331W mutation; the fluorescence signal of beta-Trp-331 was used to determine MgATP, MgADP, ATP, and ADP binding parameters for the three catalytic sites of the enzyme. The quantitative contribution of side chains to binding energy at all three catalytic sites was calculated. The following conclusions were made. The major functional interaction of beta-Lys-155 is with the gamma-phosphate of MgATP and is of primary importance at site 1 (the site of highest affinity) and site 2. Release of MgATP during oxidative phosphorylation requires conformational re-positioning of this residue. The major functional interaction of beta-Asp-242 is with the magnesium of the magnesium nucleotide at site 1; it has little or no influence at site 2 or 3. In steady-state turnover, the MgATP hydrolysis reaction occurs at site 1. beta-Glu-181 contributes little to nucleotide binding; its major catalytic effect derives apparently from a role in reaction chemistry per se. This work also emphasizes that nucleotide binding cooperativity shown by the three catalytic sites toward MgATP and MgADP is absolutely dependent on the presence of magnesium.

Specific tryptophan substitution in catalytic sites of Escherichia coli F1-ATPase allows differentiation between bound substrate ATP and product ADP in steady-state catalysis

Tryptophan was specifically inserted as the residue immediately preceding the P-loop sequence in F1-ATPase catalytic sites. The mutant enzyme (betaF148W) showed normal enzymatic characteristics. The fluorescence responses of beta-tryptophan 148 enabled us to differentiate between nucleoside di- and triphosphate bound in catalytic sites; MgADP quenched at 350 nm, whereas MgAMPPNP and MgADP.BeFx complex enhanced the fluorescence at 325 nm. With MgATP, both effects were seen simultaneously. This allowed analysis of bound catalytic site nucleotides directly under steady-state MgATP hydrolysis conditions. At mM concentration of MgATP (Vmax conditions) one of the three catalytic sites was filled with substrate MgATP and the other two sites were filled with product MgADP. A model for F1-ATPase steady-state turnover is presented that encompasses these findings. Given the structural similarity of the P-loop in nucleotide-binding proteins, this approach may prove widely useful.

Binding and hydrolysis of TNP-ATP by Escherichia coli F1-ATPase

It had previously been suggested that Vmax hydrolysis rate of 2', 3'-O-(2,4,6-trinitrophenyl)adenosine 5'-triphosphate (TNP-ATP) by F1-ATPase required filling of only two catalytic sites on the enzyme (Grubmeyer, C., and Penefsky, H. S. (1981) J. Biol. Chem. 256, 3718-3727), whereas recently it was shown that Vmax rate of ATP hydrolysis requires that all three catalytic sites are filled (Weber, J., Wilke-Mounts, S., Lee, R. S. F., Grell, E., and Senior, A. E. (1993) J. Biol. Chem. 268, 20126-20133). To resolve this apparent discrepancy, we measured equilibrium binding and hydrolysis of MgTNP-ATP under identical conditions, using betaY331W mutant Escherichia coli F1-ATPase, in which the genetically engineered tryptophan provides a direct fluorescent probe of catalytic site occupancy. We found that MgTNP-ATP hydrolysis at Vmax rate did require filling of all three catalytic sites, but in contrast to the situation with MgATP, "bisite hydrolysis" of MgTNP-ATP amounted to a substantial fraction (approximately 40%) of Vmax. Binding of MgTNP-ATP to the three catalytic sites showed strong binding cooperativity (Kd1 < 1 nm, Kd2 = 23 nm, Kd3 = 1.4 microM). Free TNP-ATP (i.e. in presence of EDTA) bound to all three catalytic sites with lower affinity but was not hydrolyzed. These data emphasize that the presence of Mg2+ is critical for cooperativity of substrate binding, formation of the very high affinity first catalytic site, and hydrolytic activity in F1-ATPases and that these three properties are strongly correlated.

Structural asymmetry of F1-ATPase caused by the gamma subunit generates a high affinity nucleotide binding site

The alpha 3 beta 3 gamma and alpha 3 beta 3 complexes of F1-ATPase from a thermophilic Bacillus PS3 were compared in terms of interaction with trinitrophenyl analogs of ATP and ADP (TNP-ATP and TNP-ADP) that differed from ATP and ADP and did not destabilize the alpha 3 beta 3 complex. The results of equilibrium dialysis show that the alpha 3 beta 3 gamma complex has a high affinity nucleotide binding site and several low affinity sites, whereas the alpha 3 beta 2 complex has only low affinity sites. This is also supported from analysis of spectral change induced by TNP-ADP, which in addition indicates that this high affinity site is located on the beta subunit. Single-site hydrolysis of substoichiometric amounts of TNP-ATP by the alpha 3 beta 3 gamma complex is accelerated by the chase addition of excess ATP, whereas that by the alpha 3 beta 3 complex is not. We further examined the complexes containing mutant beta subunits (Y341L, Y341A, and Y341C). Surprisingly, in spite of very weak affinity of the isolated mutant beta subunits to nucleotides (Odaka, M., Kaibara, C., Amano, T., Matsui, T., Muneyuki, E., Ogasawara, K, Yutani, K., and Yoshida, M. (1994) J. Biochem. (Tokyo) 115, 789-796), a high affinity TNP-ADP binding site is generated on the beta subunit in the mutant alpha 3 beta 3 gamma complexes where single-site TNP-ATP hydrolysis can occur. ATP concentrations required for the chase acceleration of the mutant complexes are higher than that of the wild-type complex. The mutant alpha 3 beta 3 complexes, on the contrary, catalyze single-site hydrolysis of TNP-ATP rather slowly, and there is no chase acceleration. Thus, the gamma subunit is responsible for the generation of a high affinity nucleotide binding site on the beta subunit in F1-ATPase where cooperative catalysis can proceed.

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.

Location and properties of pyrophosphate-binding sites in Escherichia coli F1-ATPase

Binding of pyrophosphate (PPi) to the three catalytic ("C") and three noncatalytic ("NC") nucleotide sites of Escherichia coli F1-ATPase was determined by fluorescence spectroscopy using mutant enzymes with tryptophan inserted specifically in either C sites (beta Y331W) or NC sites (alpha R365W). Fluorescence of the tryptophan is quenched on binding of nucleotide; PPi binding parameters were determined by competition with ATP or adenyl-5'-yl imidodiphosphate. It was found that MgPPi binds to each NC site with Kd = 20 microM. In contrast, even at millimolar concentration, neither MgPPi nor free PPi showed significant binding to C sites. We confirmed that free PPi displaces nucleotide from C sites, but this was shown to be due to complexation of Mg2+ ions rather than to occupancy of the sites. MgPPi bound at NC sites was found not to affect ATP hydrolysis rates. From the data we propose a two-phase model for nucleotide binding at NC sites. In phase one, NC sites recognize the pyrophosphate "end" of the nucleotide, which binds initially with Kd similar to MgPPi; in phase two, a slow conformational change occurs which tightly sequesters adenine nucleotide. Phase two does not occur with guanine nucleotide. This model explains the preference of NC sites for adenine nucleotides. Pi (5 mM) did not bind to either C or NC sites.

Rat liver ATP synthase. Relationship of the unique substructure of the F1 moiety to its nucleotide binding properties, enzymatic states, and crystalline form

The F1 moiety of rat liver ATP synthase has a molecular mass of 370,000, exhibits the unique substructure alpha 3 beta 3 gamma delta epsilon, and fully restores ATP synthesis to F1-depleted membranes. Here we provide new information about rat liver F1 as it relates to the relationship of its unique substructure to its nucleotide binding properties, enzymatic states, and crystalline form. Seven types of experiments were performed in a comprehensive study. First, the capacity of F1 to bind [3H]ADP, the substrate for ATP synthesis and [32P]AMP-PNP (5'-adenylyl-beta,gamma-imidodiphosphate), a nonhydrolyzable ATP analog, was quantified. Second, double-label experiments were performed to establish whether ADP and AMP-PNP bind to the same or different sites. Third, total nucleotide binding was assessed by the luciferin-luciferase assay. Fourth, F1 was subfractionated into an alpha gamma and a beta delta epsilon fraction, both of which were subjected to nucleotide binding assays. Fifth, the nucleotide binding capacity of F1 was quantified after undergoing ATP hydrolysis. Sixth, the intensity of the fluorescence probe pyrene maleimide bound at alpha subunits was monitored before and after F1 experienced ATP hydrolysis. Finally, the catalytic activity and nucleotide content of F1 obtained from crystals being used in x-ray crystallographic studies was determined. The picture of rat liver F1 that emerges is one of an enzyme molecule that 1) loads nucleotide readily at five sites; 2) requires for catalysis both the alpha gamma and the beta delta epsilon fractions; 3) directs the reversible binding of ATP and ADP to different regions of the enzyme's substructure; 4) induces inhibition of ATP hydrolysis only after ADP fills at least five sites; and 5) exists in several distinct forms, one an active, symmetrical form, obtained in the presence of ATP and high P(i) and on which an x-ray map at 3.6 A has been reported (Bianchet, M., Ysern, X., Hullihen, J., Pedersen, P. L., and Amzel, L. M. (1991) J. Biol. Chem. 266, 21197-21201). These results are discussed within the context of a multistate model for rat liver F1 and also discussed relative to those reported for bovine heart F1, which has been crystallized with inhibitors in an asymmetrical form and has a propensity for binding nucleotides more tightly.

A model for the catalytic site of F1-ATPase based on analogies to nucleotide-binding domains of known structure

An updated topological model is constructed for the catalytic nucleotide-binding site of the F1-ATPase. The model is based on analogies to the known structures of the MgATP site on adenylate kinase and the guanine nucleotide sites on elongation factor Tu (Ef-Tu) and the ras p21 protein. Recent studies of these known nucleotide-binding domains have revealed several common functional features and similar alignment of nucleotide in their binding folds, and these are used as a framework for evaluating results of affinity labeling and mutagenesis studies of the beta subunit of F1. Several potentially important residues on beta are noted that have not yet been studied by mutagenesis or affinity labeling.

Catalytic sites of Escherichia coli F1-ATPase

The catalytic site of Escherichia coli F1-ATPase is reviewed in terms of structure and function. Structural prediction, biochemical analyses, and mutagenesis experiments suggest that the catalytic site is formed primarily by residues 137-335 of beta-subunit. Subdomains of the site involved in phosphate-bond cleavage/synthesis and adenine-ring binding are discussed. Ambiguities inherent in steady-state catalytic measurements due to catalytic site cooperativity are discussed, and the advantages of pre-steady-state ("unisite") techniques are emphasized. The emergence of a single high-affinity catalytic site occurs as a result of F1-oligomer assembly. Measurements of unisite catalysis rate and equilibrium constants, and their modulation by varied pH, dimethylsulfoxide, and mutations, are described and conclusions regarding the nature of the high-affinity catalytic site and mechanism of catalysis are presented.

Large-scale purification and characterization of the five subunits of F1-ATPase from pig heart mitochondria

A large-scale purification procedure was developed to isolate the five subunits of F1-ATPase from pig heart mitochondria. The previously described procedure (Williams, N. and Pedersen, P.L. (1986) Methods Enzymol. 126, 484-489) to dissociate the rat liver F1-ATPase by cold treatment followed by warming at 37 degrees C has been adapted for the pig heart enzyme. Removal of endogenous nucleotides from that enzyme before dissociation led to the efficient separation of the alpha and gamma subunits from beta, delta and epsilon subunits. The beta subunit was purified in the hundred-milligram range by anion-exchange chromatography in the absence of any denaturing agent. This subunit was free from any bound nucleotide and almost no ATPase and adenylate kinase-like activities were detected. The delta and epsilon subunits were purified by reversed-phase chromatography (RP-HPLC) in the milligram range. As recently reported (Penin, F., Deléage, G., Gagliardi, D., Roux, B. and Gautheron, D.C. (1990) Biochemistry 29, 9358-9364), these purified subunits kept biophysical features of folded proteins and their ability to reconstitute the tight delta epsilon complex. The alpha and gamma subunits remained poorly soluble and required dissociation by 8 M guanidinium chloride prior to their purification by RP-HPLC. In addition, characterizations of the five subunits by IEF and SDS-polyacrylamide gel electrophoresis are reported, as well as ultraviolet spectra and solubility properties of the beta, delta and epsilon subunits.

Trinitrophenyl-ATP binding to the ArsA protein: the catalytic subunit of an anion pump

The ars operon of the conjugative R-factor R773 confers resistance to arsenicals by coding for an anion pump for extrusion of arsenicals from cells of Escherichia coli. Extrusion of arsenite requires only two polypeptides, the ArsA and ArsB proteins. Purified ArsA protein exhibits oxyanion-stimulated ATPase activity and has been shown to bind ATP by photoaffinity labeling with [alpha-32P]ATP. From sequence analysis the ArsA protein is predicted to have two nucleotide binding folds, one in the N-terminal half and one in the C-terminal half of the protein. Purified ArsA protein bound a fluorescent ATP analogue, 2',3'-O-(2,4,6-trinitrophenylcyclohexadienylidene)adenosine- 5'-triphosphate, with an apparent stoichiometry of 2 mol of nucleotide per mole of ArsA. Strains expressing plasmids with mutations in the N-terminal consensus nucleotide sequence bound only 1 mol of nucleotide per mole of protein.

Catalytic site nucleotide and inorganic phosphate dependence of the conformation of the epsilon subunit in Escherichia coli adenosinetriphosphatase

The rate of trypsin cleavage of the epsilon subunit of Escherichia coli F1 (ECF1) has been found to be ligand-dependent, as measured indirectly by the activation of the enzyme that occurs on protease digestion, or when followed directly by monitoring the cleavage of this subunit using monoclonal antibodies. The cleavage of the epsilon subunit was fast in the presence of ADP alone, ADP + MG2+, ATP + EDTA, or AMP-PNP, but slow when Pi was added along with ADP + Mg2+ or when ATP + Mg2+ was added to generate ADP + Pi (+Mg2+) in the catalytic site(s). The half-maximal concentration of Pi required in the presence of ADP + Mg2+ to protect the epsilon subunit from cleavage by trypsin was 50 microM, which is in the range measured for the high-affinity binding of Pi to F1. The ligand-dependent conformational changes in the epsilon subunit were also examined in cross-linking experiments using the water-soluble carbodiimide 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide (EDC). In the presence of ATP + Mg2+ or ADP + Mg2+ + Pi, the epsilon subunit cross-linked to beta in high yield. With ATP + EDTA or ADP + Mg2+ (no Pi), the yield of the beta-epsilon cross-linked product was much reduced. We conclude that the epsilon subunit undergoes a conformational change dependent on the presence of Pi. It has been found previously that binding of the epsilon subunit to ECF1 inhibits ATPase activity by decreasing the off rate of Pi [Dunn, S. D., Zadorozny, V. D., Tozer, R. G., & Orr, L. E. (1987) Biochemistry 26, 4488-4493]. This reciprocal relationship between Pi binding and epsilon-subunit conformation has important implications for energy transduction by the E. coli ATP synthase.

Tight ATP and ADP binding in the noncatalytic sites of Escherichia coli F1-ATPase is not affected by mutation of bulky residues in the 'glycine-rich loop'

It is shown that ATP dissociates very slowly (koff less than 6.4 x 10(5) s-1, t1/2 greater than 3 h) from the three noncatalytic sites of E. coli F1-ATPase and that ADP dissociates from these three sites in a homogeneous fashion with koff = 1.5 x 10(-4) s-1 (t1/2 = 1.35 h). Mutagenesis of alpha-subunit residues R171 and Q172 in the 'glycine-rich loop' (Homology A) consensus region of the noncatalytic sites was carried out to test the hypothesis that unusually bulky residues at these positions are responsible wholly or partly for the observed tight binding of adenine nucleotides. The mutations alpha Q172G or alpha R171S,Q172G had no effects on ATP or ADP binding to or rates of dissociation from F1 noncatalytic sites. KdATP and KdADP of isolated alpha-subunit were weakened by approximately 1 order of magnitude in both mutants. The results suggest that neither residue alpha R171 nor alpha Q172 interacts directly with bound nucleotide, and show that the presence of bulky residues per se in the glycine-rich loop region of F1-alpha-subunit is not responsible for tight binding in the noncatalytic sites.