Modulation of proton pumping efficiency in bacterial ATP synthases

The ATP synthase in chromatophores of Rhodobacter caspulatus can effectively generate a transmembrane pH difference coupled to the hydrolysis of ATP. The rate of hydrolysis was rather insensitive to the depletion of ADP in the assay medium by an ATP regenerating system (phospho-enol-pyruvate (PEP) and pyruvate kinase (PK)). The steady state values of DeltapH were however drastically reduced as a consequence of ADP depletion. The clamped concentrations of ADP obtained using different PK activities in the assay medium could be calculated and an apparent Kd approximately 0.5 microM was estimated. The extent of proton uptake was also strongly dependent on the addition of phosphate to the assay medium. The Kd for this effect was about 70 microM. Analogous experiments were performed in membrane fragment from Escherichia coli. In this case, however, the hydrolysis rate was strongly inhibited by Pi, added up to 3 mM. Inhibition by Pi was nearly completely suppressed following depletion of ADP. The Kd's for the ADP and Pi were in the micromolar range and submillimolar range, respectively, and were mutually dependent from the concentration of the other ligand. Contrary to hydrolysis, the pumping of protons was rather insensitive to changes in the concentrations of the two ligands. At intermediate concentrations, proton pumping was actually stimulated, while the hydrolysis was inhibited. It is concluded that, in these two bacterial organisms, ADP and phosphate induce a functional state of the ATP synthase competent for a tightly coupled proton pumping, while the depletion of either one of these two ligands favors an inefficient (slipping) functional state. The switch between these states can probably be related to a structural change in the C-terminal alpha-helical hairpin of the epsilon-subunit, from an extended conformation, in which ATP hydrolysis is tightly coupled to proton pumping, to a retracted one, in which ATP hydrolysis and proton pumping are loosely coupled.     

Physiological ligands ADP and Pi modulate the degree of intrinsic coupling in the ATP synthase of the photosynthetic bacterium Rhodobacter capsulatus

The proton-pumping and the ATP hydrolysis activities of the ATP synthase of Rhodobacter capsulatus have been compared as a function of the ADP and P(i) concentrations. The proton pumping was measured either with the transmembrane pH difference probe, 9-amino-6-chloro-2-methoxyacridine, or with the transmembrane electric potential difference probe, bis(3-propyl-5-oxoisoxazol-4-yl)pentamethine oxonol, obtaining consistent results. The comparison indicates that an intrinsic uncoupling of ATP synthase is induced when the concentration of either ligand is decreased. The half-maximal effect was found in the submicromolar range for ADP and at about 70 microM for P(i). It is proposed that a switch from a partially uncoupled state of ATP synthase to the coupled state is induced by the simultaneous binding of ADP and P(i).     

Requirement of medium ADP for the steady-state hydrolysis of ATP by the proton-translocating Paracoccus denitrificans Fo.F1-ATP synthase

Fo.F1-ATP synthase in inside-out coupled vesicles derived from Paracoccus denitrificans catalyzes Pi-dependent proton-translocating ATPase reaction if exposed to prior energization that relieves ADP.Mg2+ -induced inhibition (Zharova, T.V. and Vinogradov, A.D. (2004) J. Biol. Chem.,279, 12319-12324). Here we present evidence that the presence of medium ADP is required for the steady-state energetically self-sustained coupled ATP hydrolysis. The initial rapid ATPase activity is declined to a certain level if the reaction proceeds in the presence of the ADP-consuming, ATP-regenerating system (pyruvate kinase/phosphoenol pyruvate). The rate and extent of the enzyme de-activation are inversely proportional to the steady-state ADP concentration, which is altered by various amounts of pyruvate kinase at constant ATPase level. The half-maximal rate of stationary ATP hydrolysis is reached at an ADP concentration of 8 x 10(-6) M. The kinetic scheme is proposed explaining the requirement of the reaction products (ADP and Pi), the substrates of ATP synthesis, in the medium for proton-translocating ATP hydrolysis by P. denitrificans Fo.F1-ATP synthase.     

Energy-linked binding of Pi is required for continuous steady-state proton-translocating ATP hydrolysis catalyzed by F0.F1 ATP synthase

The presence of medium Pi (half-maximal concentration of 20 microM at pH 8.0) was found to be required for the prevention of the rapid decline in the rate of proton-motive force (pmf)-induced ATP hydrolysis by Fo.F1 ATP synthase in coupled vesicles derived from Paracoccus denitrificans. The initial rate of the reaction was independent of Pi. The apparent affinity of Pi for its "ATPase-protecting" site was strongly decreased with partial uncoupling of the vesicles. Pi did not reactivate ATPase when added after complete time-dependent deactivation during the enzyme turnover. Arsenate and sulfate, which was shown to compete with Pi when Fo.F1 catalyzed oxidative phosphorylation, substituted for Pi as the protectors of ATPase against the turnover-dependent deactivation. Under conditions where the enzyme turnover was not permitted (no ATP was present), Pi was not required for the pmf-induced activation of ATPase, whereas the presence of medium Pi (or sulfate) delayed the spontaneous deactivation of the enzyme which was induced by the membrane de-energization. The data are interpreted to suggest that coupled and uncoupled ATP hydrolysis catalyzed by Fo.F1 ATP synthases proceeds via different intermediates. Pi dissociates after ADP if the coupling membrane is energized (no E.ADP intermediate exists). Pi dissociates before ADP during uncoupled ATP hydrolysis, leaving the E.ADP intermediate which is transformed into the inactive ADP(Mg2+)-inhibited form of the enzyme (latent ATPase).     

Met23Lys mutation in subunit gamma of F(O)F(1)-ATP synthase from Rhodobacter capsulatus impairs the activation of ATP hydrolysis by protonmotive force

H(+)-F(O)F(1)-ATP synthase couples proton flow through its membrane portion, F(O), to the synthesis of ATP in its headpiece, F(1). 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 epsilon subunit, and activation by protonmotive force. Here we report that the Met23Lys mutation in the gamma 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 gammaLys23 with the DELSEED region of subunit beta stabilized the ADP-inhibited state of the enzyme by hindering the rotation of subunit gamma rotation which is necessary for the activation.     

Vesicular preparation of a highly coupled ATPase-ATP synthase complex from pig heart mitochondria

1. A method is described to prepare an ATPase-ATP synthase complex from pig heart mitochondria exhibiting a very high ATP-32Pi exchange activity (1.6 mumol/min per mag protein in optimal conditions). 2. The preparation is virtually devoid of nucleoside diphosphokinase and adenylate kinase activities. 3. Freeze-fracture studies show that the ATPase-ATP synthase complex is integrated in lipid vesicles of 400-600 A in diameter. 4. It contains the endogenous natural proteic inhibitor which seems to behave as a coupling factor. 5. The rate of ATP hydrolysis catalyzed by the ATPase-ATP synthase complex is competitively inhibited by ADP, while the presence of ADP increases the initial rate of 32Pi incorporation into ATP. 6. The 32Pi incorporation into ATP can occur at a rate almost equal to that of nucleoside triphosphate (NTP) hydrolysis provided that the rate of NTP hydrolysis is kept low and that the ADP concentration is high enough. In these conditions, a very high coupling between NTP hydrolysis and ATP synthesis can be demonstrated.     

Proton pumping kinetics and origin of nitrate inhibition of tonoplast-type H+-ATPase

A tonoplast-type vesicle preparation, substantially free from other subcellular membranes, was obtained from corn roots by equilibrium sucrose density gradient centrifugation. At pH 6.5 and in the presence of chloride ions, the tonoplast-type ATPase activity as measured by Pi release, was inhibited by nitrate ions. The ATPase activity was insensitive to molybdate and vanadate, indicating a minimum nonspecific phosphatase and plasma membrane contamination. The vesicles exhibited an ATP hydrolysis-supported proton uptake which was measured by the absorption change of acridine orange. The ATP hydrolysis supported uptake and the subsequent perturbant-induced release of protons (decay) was described by a kinetic model which was previously developed to evaluate the coupling between proton pumping and the primary energy yielding process for other biomembranes. The proton pumping activity was more sensitive to nitrate ions then was ATP hydrolysis. The differential effect and the kinetic analysis of nitrate inhibition led us to suggest that (i) the coupling between Pi release and proton pumping was indirect in nature and (ii) the primary inhibitory effect of nitrate ion was originated from an interaction with a protogenic protein domain which is functionally linked to the ATPase in the tonoplast-type membrane.     

Interactions between beta D372 and gamma subunit N-terminus residues gamma K9 and gamma S12 are important to catalytic activity catalyzed by Escherichia coli F1F0-ATP synthase

Substitution of Escherichia coli F(1)F(0) ATP synthase residues betaD372 or gammaS12 with groups that are unable to form a hydrogen bond at this location decreased ATP synthase-dependent cell growth by 2 orders of magnitude, eliminated the ability of F(1)F(0) to catalyze ATPase-dependent proton pumping in inverted E. coli membranes, caused a 15-20% decrease in the coupling efficiency of the membranes as measured by the extent of succinate-dependent acridine orange fluorescence quenching, but increased soluble F(1)-ATPase activity by about 10%. Substitution of gammaK9 to eliminate the ability to form a salt bridge with betaD372 decreased soluble F(1)-ATPase activity and ATPase-driven proton pumping by 2-fold but had no effect on the proton gradient induced by addition of succinate. Mutations to eliminate the potential to form intersubunit hydrogen bonds and salt bridges between other less highly conserved residues on the gamma subunit N-terminus and the beta subunits had little effect on ATPase or ATP synthase activities. These results suggest that the betaD372-gammaK9 salt bridge contributes significantly to the rate-limiting step in ATP hydrolysis of soluble F(1) while the betaD372-gammaS12 hydrogen bond may serve as a component of an escapement mechanism for ATP synthesis in which alphabetagamma intersubunit interactions provide a means to make substrate binding a prerequisite of proton gradient-driven gamma subunit rotation.     

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.     

Regulatory interplay between proton motive force, ADP, phosphate, and subunit epsilon in bacterial ATP synthase

ATP synthase couples transmembrane proton transport, driven by the proton motive force (pmf), to the synthesis of ATP from ADP and inorganic phosphate (P(i)). In certain bacteria, the reaction is reversed and the enzyme generates pmf, working as a proton-pumping ATPase. The ATPase activity of bacterial enzymes is prone to inhibition by both ADP and the C-terminal domain of subunit epsilon. We studied the effects of ADP, P(i), pmf, and the C-terminal domain of subunit epsilon on the ATPase activity of thermophilic Bacillus PS3 and Escherichia coli ATP synthases. We found that pmf relieved ADP inhibition during steady-state ATP hydrolysis, but only in the presence of P(i). The C-terminal domain of subunit epsilon in the Bacillus PS3 enzyme enhanced ADP inhibition by counteracting the effects of pmf. It appears that these features allow the enzyme to promptly respond to changes in the ATP:ADP ratio and in pmf levels in order to avoid potentially wasteful ATP hydrolysis in vivo.     

Modulation of coupling in the Escherichia coli ATP synthase by ADP and Pi: Role of the ε subunit C-terminal domain

The ε-subunit of ATP-synthase is an endogenous inhibitor of the hydrolysis activity of the complex and its α-helical C-terminal domain (εCTD) undergoes drastic changes among at least two different conformations. Even though this domain is not essential for ATP synthesis activity, there is evidence for its involvement in the coupling mechanism of the pump. Recently, it was proposed that coupling of the ATP synthase can vary as a function of ADP and P_i concentration. In the present work, we have explored the possible role of the εCTD in this ADP- and P_i-dependent coupling, by examining an εCTD-lacking mutant of Escherichia coli. We show that the loss of P_i-dependent coupling can be observed also in the εCTD-less mutant, but the effects of P_i on both proton pumping and ATP hydrolysis were much weaker in the mutant than in the wild-type. We also show that the εCTD strongly influences the binding of ADP to a very tight binding site (half-maximal effect ≈ 1 nM); binding at this site induces higher coupling in EF_OF₁ and increases responses to P_i. It is proposed that one physiological role of the εCTD is to regulate the kinetics and affinity of ADP/P_i binding, promoting ADP/P_i-dependent coupling.     

Quantitative aspects of adenosine triphosphate-driven proton translocation in spinach chloroplast thylakoids

After illumination in the presence of dithiothreitol, chloroplast thylakoids catalyze ATP hydrolysis and an exchange between ATP and Pi in the dark. ATP hydrolysis is linked to inward proton translocation. The relationships between ATP hydrolysis, ATP-Pi exchange, and proton translocation during the steady state were examined. The internal proton concentration was found to be proportional to the rate of ATP hydrolysis when these parameters were varied by procedures that do not alter the proton permeability of the thylakoid membranes. A linear relationship between the internal proton concentration and the rate of nonphosphorylating electron flow was previously verified. By determining the constant relating internal proton concentration to both ATP hydrolysis and electron flow, the proton/ATP ratio for the chloroplast ATPase complex was calculated to be 3.4 +/- 0.3. The presence of Pi, which allows ATP-Pi exchange to occur, lowers the internal proton concentration, but does not alter the relationship between the net rate of ATP hydrolysis and internal proton concentration. ATP-Pi exchange shows a dependence on the proton activity gradient very similar to that of ATP synthesis in the light. These results suggest that ATP-Pi exchange resembles photophosphorylation. In agreement with this idea, it is nucleoside diphosphate from the medium that is phosphorylated during exchange. Moreover, the energy-linked incorporation of Pi and ADP into ATP during exchange occurs at a similar rate. Thus, ATP synthesis from medium ADP and Pi takes place at the expense of the pH gradient generated by ATP hydrolysis.     

ATP-dependent H+ transport in synaptosomal membrane vesicles of the rat brain

H+ transport into synaptosomal membrane vesicles of the rat brain was stimulated by ATP and to a lesser extent by GTP, but not by ITP, CTP, UTP, ADP, AMP or beta, gamma-methylene ATP. ATP at concentrations up to 200 mM concentration-dependently stimulated the rate of H+ transport with a Km value of 0.6 mM, but at higher concentrations of this nucleotide the rate decreased. Other nucleotides such as CTP, UTP, GTP and AMP, or products of ATP hydrolysis i.e. ADP and Pi also reduced the ATP-stimulated H+ transport. The inhibition by GTP and ADP was not affected by the ATP concentration. These findings suggest that plasma membranes of nerve endings transport H+ from inside to outside of the cells utilizing energy from ATP hydrolysis, and that this transport is regulated by the intracellular concentration of nucleotides and Pi on sites other than those involved in substrate binding.     

The role of the epsilon subunit in the Escherichia coli ATP synthase. The C-terminal domain is required for efficient energy coupling

The role of the C-domain of the epsilon subunit of ATP synthase was investigated by fusing either the 20-kDa flavodoxin (Fd) or the 5-kDa chitin binding domain (CBD) to the N termini of both full-length epsilon and a truncation mutant epsilon(88-stop). All mutant epsilon proteins were stable in cells and supported F1F0 assembly. Cells expressing the Fd-epsilon or Fd-epsilon(88-stop) mutants were unable to grow on acetate minimal medium, indicating their inability to carry out oxidative phosphorylation because of steric blockage of rotation. The other forms of epsilon supported growth on acetate. Membrane vesicles containing Fd-epsilon showed 23% of the wild type ATPase activity but no proton pumping, suggesting that the ATP synthase is intrinsically partially uncoupled. Vesicles containing CBD-epsilon were indistinguishable from the wild type in ATPase activity and proton pumping, indicating that the N-terminal fusions alone do not promote uncoupling. Fd-epsilon(88-stop) caused higher rates of uncoupled ATP hydrolysis than Fd-epsilon, and epsilon(88-stop) showed an increased rate of membrane-bound ATP hydrolysis but decreased proton pumping relative to the wild type. Both results demonstrate the role of the C-domain in coupling. Analysis of the wild type and epsilon(88-stop) mutant membrane ATPase activities at concentrations of ATP from 50 mum to 8 mm showed no significant dependence of the ratio of bound/released ATPase activity on ATP concentration. These results support the hypothesis that the main function of the C-domain in the Escherichia coli epsilon subunit is to reduce uncoupled ATPase activity, rather than to regulate coupled activity.     

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.     

Relationship of tightly bound ADP and ATP to control and catalysis by chloroplast ATP synthase

Whether the tightly bound ADP that can cause a pronounced inhibition of ATP hydrolysis by the chloroplast ATP synthase and F1 ATPase (CF1) is bound at catalytic sites or at noncatalytic regulatory sites or both has been uncertain. We have used photolabeling by 2-azido-ATP and 2-azido-ADP to ascertain the location, with Mg2+ activation, of tightly bound ADP (a) that inhibits the hydrolysis of ATP by chloroplast ATP synthase, (b) that can result in an inhibited form of CF1 that slowly regains activity during ATP hydrolysis, and (c) that arises when low concentrations of ADP markedly inhibit the hydrolysis of GTP by CF1. The data show that in all instances the inhibition is associated with ADP binding without inorganic phosphate (Pi) at catalytic sites. After photophosphorylation of ADP or 2-azido-ADP with [32P]Pi, similar amounts of the corresponding triphosphates are present on washed thylakoid membranes. Trials with appropriately labeled substrates show that a small portion of the tightly bound 2-azido-ATP gives rise to covalent labeling with an ATP moiety at noncatalytic sites but that most of the bound 2-azido-ATP gives rise to covalent labeling by an ADP moiety at a catalytic site. We also report the occurrence of a 1-2-min delay in the onset of the Mg2+-induced inhibition after addition of CF1 to solutions containing Mg2+ and ATP, and that this delay is not associated with the filling of noncatalytic sites. A rapid burst of Pi formation is followed by a much lower, constant steady-state rate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Multidrug resistance protein 4 (ABCC4)-mediated ATP hydrolysis: effect of transport substrates and characterization of the post-hydrolysis transition state

Multidrug resistance protein 4 (MRP4/ABCC4), transports cyclic nucleoside monophosphates, nucleoside analog drugs, chemotherapeutic agents, and prostaglandins. In this study we characterize ATP hydrolysis by human MRP4 expressed in insect cells. MRP4 hydrolyzes ATP (Km, 0.62 mm), which is inhibited by orthovanadate and beryllium fluoride. However, unlike ATPase activity of P-glycoprotein, which is equally sensitive to both inhibitors, MRP4-ATPase is more sensitive to beryllium fluoride than to orthovanadate. 8-Azido[alpha-32P]ATP binds to MRP4 (concentration for half-maximal binding approximately 3 microm) and is displaced by ATP or by its non-hydrolyzable analog AMPPNP (concentrations for half-maximal inhibition of 13.3 and 308 microm). MRP4 substrates, the prostaglandins E1 and E2, stimulate ATP hydrolysis 2- to 3-fold but do not affect the Km for ATP. Several other substrates, azidothymidine, 9-(2-phosphonylmethoxyethyl)adenine, and methotrexate do not stimulate ATP hydrolysis but inhibit prostaglandin E2-stimulated ATP hydrolysis. Although both post-hydrolysis transition states MRP4.8-azido[alpha-32P]ADP.Vi and MRP4.8-azido[alpha-32P]ADP.beryllium fluoride can be generated, nucleotide trapping is approximately 4-fold higher with beryllium fluoride. The divalent cations Mg2+ and Mn2+ support comparable levels of nucleotide binding, hydrolysis, and trapping. However, Co2+ increases 8-azido[alpha-32P]ATP binding and beryllium fluoride-induced 8-azido[alpha-32P]ADP trapping but does not support steady-state ATP hydrolysis. ADP inhibits basal and prostaglandin E2-stimulated ATP hydrolysis (concentrations for half-maximal inhibition 0.19 and 0.25 mm, respectively) and beryllium fluoride-induced 8-azido[alpha-32P]ADP trapping, whereas Pi has no effect up to 20 mm. In aggregate, our results demonstrate that MRP4 exhibits substrate-stimulated ATP hydrolysis, and we propose a kinetic scheme suggesting that ADP release from the post-hydrolysis transition state may be the rate-limiting step during the catalytic cycle.     

Genetic fusions of globular proteins to the epsilon subunit of the Escherichia coli ATP synthase: Implications for in vivo rotational catalysis and epsilon subunit function

The rotational mechanism of ATP synthase was investigated by fusing three proteins from Escherichia coli, the 12-kDa soluble cytochrome b(562), the 20-kDa flavodoxin, and the 28-kDa flavodoxin reductase, to the C terminus of the epsilon subunit of the enzyme. According to the concept of rotational catalysis, because epsilon is part of the rotor a large domain added at this site should sterically clash with the second stalk, blocking rotation and fully inhibiting the enzyme. E. coli cells expressing the cytochrome b(562) fusion in place of wild-type epsilon grew using acetate as the energy source, indicating their capacity for oxidative phosphorylation. Cells expressing the larger flavodoxin or flavodoxin reductase fusions failed to grow on acetate. Immunoblot analysis showed that the fusion proteins were stable in the cells and that they had no effect on enzyme assembly. These results provide initial evidence supporting rotational catalysis in vivo. In membrane vesicles, the cytochrome b(562) fusion caused an increase in the apparent ATPase activity but a minor decrease in proton pumping. Vesicles bearing ATP synthase containing the larger fusion proteins showed reduced but significant levels of ATPase activity that was sensitive to inhibition by dicyclohexylcarbodiimide (DCCD) but no proton pumping. Thus, all fusions to epsilon generated an uncoupled component of ATPase activity. These results imply that a function of the C terminus of epsilon in F(1)F(0) is to increase the efficiency of the enzyme by specifically preventing the uncoupled hydrolysis of ATP. Given the sensitivity to DCCD, this uncoupled ATP hydrolysis may arise from rotational steps of gammaepsilon in the inappropriate direction after ATP is bound at the catalytic site. It is proposed that the C-terminal domain of epsilon functions to ensure that rotation occurs only in the direction of ATP synthesis when ADP is bound and only in the direction of hydrolysis when ATP is bound.     

Inhibition of steady-state mitochondrial ATP synthesis by bicarbonate, an activating anion of ATP hydrolysis.

Bicarbonate, an activating anion of ATP hydrolysis, inhibited ATP synthesis coupled to succinate oxidation in beef heart submitochondrial particles but diminished the lag time and increased the steady-state velocity of the (32)Pi-ATP exchange reaction. The latter effects exclude the possibility that bicarbonate is inducing an intrinsic uncoupling between ATP hydrolysis and proton translocation at the level of F(1)F(o) ATPase. The inhibition of ATP synthesis was competitive with respect to ADP at low fixed [Pi], mixed at high [Pi] and non-competitive towards Pi at any fixed [ADP]. From these results we can conclude that (i) bicarbonate does not bind to a Pi site in the mitochondrial F(1); (ii) it competes with the binding of ADP to a low-affinity site, likely the low-affinity non-catalytic nucleotide binding site. It is postulated that bicarbonate stimulates ATP hydrolysis and inhibits ATP synthesis by modulating the relative affinities of the catalytic site for ATP and ADP.     

Probes of catalytic site cooperativity during catalysis by the chloroplast adenosine triphosphate and the adenosine triphosphate synthase

During net nucleoside triphosphate synthesis by chloroplast ATP synthase the extent of water oxygen incorporation into each nucleoside triphosphate released increases with decrease in ADP, GDP or IDP concentration. Likewise, during net ATP hydrolysis by the Mg2+-activated chloroplast ATPase, the extent of water oxygen incorporation into each Pi released increases as the ATP, GTP, or ITP concentration is decreased. However, the concentration ranges in which substrate modulation occurs differs with each nucleotide. Modulation of oxygen exchange during synthesis and hydrolysis of adenine nucleotides, as measured by variation in the extent of water oxygen incorporation into products, occurs below 250 microM. In contrast, guanosine and inosine nucleotides alter the extent of exchange at higher and much wider concentration ranges. Activation of the chloroplast ATPase by either heat or trypsin results in similar catalytic behavior as monitored by ATP modulation of oxygen exchanges during hydrolysis in the presence of Mg2+. More exchange capacity is evident with octylglucoside-activated enzyme at all ATP concentrations. High levels of tentoxin were also found to alter the catalytic exchange parameters resulting in continued water oxygen exchange into Pi released during hydrolysis at high ATP concentrations. Little or no oxygen exchange accompanies ATP hydrolysis in the presence of Ca2+. The [18O]Pi species formed from highly gamma-18O-labeled ATP at lower ATP concentrations gives a distribution as expected if only one catalytic pathway is operative at a given ATP concentration. This and other results support the concept of catalytic cooperativity between alternating sites as explanation for the modulation of oxygen exchange by nucleotide concentration.