ATP activation of DNA polymerase III holoenzyme from Escherichia coli. II. Initiation complex: stoichiometry and reactivity

DNA polymerase III holoenzyme (holenzyme) has an ATPase activity elicited only by a primed DNA template. Reaction of preformed ATP.holoenzyme complex with a primed template results in hydrolysis of the ATP bound to the holoenzyme, release of ADP and Pi, and formation of an initiation complex between holoenzyme and the primed template. Approximately two ATP molecules are hydrolyzed for each initiation complex formed, a value in keeping with the number bound in the ATP.holoenzyme complex. The possibility that the latter and the initiation complex contain two holoenzyme molecules is supported by the presence of two beta monomers in the initiation complex. Holoenzyme action in the absence of ATP resembles that of pol III (the holoenzyme core) or DNA polymerase III (holoenzyme lacking the beta subunit), with or without ATP, in sensitivity to salt and in processivity of elongation. The initiation complex formed by ATP-activated holoenzyme resists a level of KCl (150 mM) that completely inhibits nonactivated holoenzyme and the incomplete forms of the holoenzyme, and displays a processivity at least 20 times greater. Upon completing replication of available template, holoenzyme can dissociate and form an initiation complex with another primed template, provided ATP is available to reactivate the holoenzyme. By inference, no essential subunits are lost in the cycle of initiation, elongation and dissociation.     

Kinetic characterization of a monomeric unconventional myosin V construct.

An expressed, monomeric murine myosin V construct composed of the motor domain and two calmodulin-binding IQ motifs (MD(2IQ)) was used to assess the regulatory and kinetic properties of this unconventional myosin. In EGTA, the actin-activated ATPase activity of MD(2IQ) was 7.4 +/- 1.6 s(-1) with a K(app) of approximately 1 microM (37 degrees C), and the velocity of actin movement was approximately 0.3 micrometer/s (30 degrees C). Calcium inhibited both of these activities, but the addition of calmodulin restored the values to approximately 70% of control, indicating that calmodulin dissociation caused inhibition. In contrast to myosin II, MD(2IQ) is highly associated with actin at physiological ionic strength in the presence of ATP, but the motor is in a weakly bound conformation based on the pyrene-actin signal. The rate of dissociation of acto-MD(2IQ) by ATP is fast (>850 s(-1)), and ATP hydrolysis occurs at approximately 200 s(-1). The affinity of acto-MD(2IQ) for ADP is somewhat higher than that of smooth S1, and ADP dissociates more slowly. Actin does not cause a large increase in the rate of ADP release, nor does the presence of ADP appreciably alter the affinity of MD(2IQ) for actin. These kinetic data suggest that monomeric myosin V is not processive.     

Mechanism of nucleotide binding to actomyosin VI: evidence for allosteric head-head communication

We have examined the kinetics of nucleotide binding to actomyosin VI by monitoring the fluorescence of pyrene-labeled actin filaments. ATP binds single-headed myosin VI following a two-step reaction mechanism with formation of a low affinity collision complex (1/K(1)' = 5.6 mm) followed by isomerization (k(+2)' = 176 s-1) to a state with weak actin affinity. The rates and affinity for ADP binding were measured by kinetic competition with ATP. This approach allows a broader range of ADP concentrations to be examined than with fluorescent nucleotide analogs, permitting the identification and characterization of transiently populated intermediates in the pathway. ADP binding to actomyosin VI, as with ATP binding, occurs via a two-step mechanism. The association rate constant for ADP binding is approximately five times greater than for ATP binding because of a higher affinity in the collision complex (1/K(5b)' = 2.2 mm) and faster isomerization rate constant (k(+5a)' = 366 s(-1)). By equilibrium titration, both heads of a myosin VI dimer bind actin strongly in rigor and with bound ADP. In the presence of ATP, conditions that favor processive stepping, myosin VI does not dwell with both heads strongly bound to actin, indicating that the second head inhibits strong binding of the lead head to actin. With both heads bound strongly, ATP binding is accelerated 2.5-fold, and ADP binding is accelerated >10-fold without affecting the rate of ADP release. We conclude that the heads of myosin VI communicate allosterically and accelerate nucleotide binding, but not dissociation, when both are bound strongly to actin.     

Kinetics of ADP dissociation from the trail and lead heads of actomyosin V following the power stroke

Myosin V is a cellular motor protein, which transports cargos along actin filaments. It moves processively by 36-nm steps that require at least one of the two heads to be tightly bound to actin throughout the catalytic cycle. To elucidate the kinetic mechanism of processivity, we measured the rate of product release from the double-headed myosin V-HMM using a new ATP analogue, 3'-(7-diethylaminocoumarin-3-carbonylamino)-3'-deoxy-ATP (deac-aminoATP), which undergoes a 20-fold increase in fluorescence emission intensity when bound to the active site of myosin V (Forgacs, E., Cartwright, S., Kovács, M., Sakamoto, T., Sellers, J. R., Corrie, J. E. T., Webb, M. R., and White, H. D. (2006) Biochemistry 45, 13035-13045). The kinetics of ADP and deac-aminoADP dissociation from actomyosin V-HMM, following the power stroke, were determined using double-mixing stopped-flow fluorescence. These used either deac-aminoATP as the substrate with ADP or ATP chase or alternatively ATP as the substrate with either a deac-aminoADP or deac-aminoATP chase. Both sets of experiments show that the observed rate of ADP or deac-aminoADP dissociation from the trail head of actomyosin V-HMM is the same as from actomyosin V-S1. The dissociation of ADP from the lead head is decreased by up to 250-fold.     

Dissecting the domain structure of the regulatory subunit of cAMP-dependent protein kinase I and elucidating the role of MgATP

A truncated regulatory subunit of cAMP-dependent protein kinase I was constructed which contained deletions at both the carboxyl terminus and at the amino terminus. The entire carboxyl-terminal cAMP-binding domain was deleted as well as the first 92 residues up to the hinge region. This monomeric truncated protein still forms a complex with the catalytic subunit, and activation of this complex is mediated by cAMP. The affinity of this mutant holoenzyme for cAMP and its activation by cAMP are nearly identical to holoenzyme formed with a regulatory subunit having only the carboxyl-terminal deletion and very similar to native holoenzyme. The off rate for cAMP from both mutant regulatory subunits, however, is monophasic and very fast relative to the biphasic off rate seen for the native regulatory subunit. The effects of NaCl, urea, and pH on cAMP binding are also very similar for the mutant and native holoenzymes. Like the native type I holoenzyme, both mutant holoenzymes bind ATP with a high affinity. The positive cooperativity seen for MgATP binding to the native holoenzyme, however, is abolished in the double deletion mutant. The Hill coefficient for ATP binding to this mutant holoenzyme is 1.0 in contrast to 1.6 for the native holoenzyme. The Kd (cAMP) is increased by approximately 1 order of magnitude for both mutant forms of the holoenzyme in the presence of MgATP. A similar shift is seen for the native holoenzyme. Further characterization of the MgATP-binding properties of the wild-type holoenzyme indicates that a binary complex containing catalytic subunit and MgATP is required, in particular, for reassociation with the cAMP-bound regulatory subunit. This binary complex is required for rapid dissociation of the bound cAMP and is probably responsible for the observed reduction in cAMP-binding affinity for the type I holoenzyme in the presence of MgATP.     

Thermodynamics of nucleotide binding to actomyosin V and VI: a positive heat capacity change accompanies strong ADP binding

We have measured the energetics of ATP and ADP binding to single-headed actomyosin V and VI from the temperature dependence of the rate and equilibrium binding constants. Nucleotide binding to actomyosin V and VI can be modeled as two-step binding mechanisms involving the formation of collision complexes followed by isomerization to states with high nucleotide affinity. Formation of the actomyosin VI-ATP collision complex is much weaker and slower than for actomyosin V. A three-step binding mechanism where actomyosin VI isomerizes between two conformations, one competent to bind ATP and one not, followed by rapid ATP binding best accounts for the data. ADP binds to actomyosin V more tightly than actomyosin VI. At 25 degrees C, the strong ADP-binding equilibria are comparable for actomyosin V and VI, and the different overall ADP affinities arise from differences in the ADP collision complex affinity. The actomyosin-ADP isomerization leading to strong ADP binding is entropy driven at >15 degrees C and occurs with a large, positive change in heat capacity (DeltaC(P) degrees ) for both actomyosin V and VI. Sucrose slows ADP binding and dissociation from actomyosin V and VI but not the overall equilibrium constants for strong ADP binding, indicating that solvent viscosity dampens ADP-dependent kinetic transitions, presumably a tail swing that occurs with ADP binding and release. We favor a mechanism where strong ADP binding increases the dynamics and flexibility of the actomyosin complex. The heat capacity (DeltaC(P) degrees ) and entropy (DeltaS degrees ) changes are greater for actomyosin VI than actomyosin V, suggesting different extents of ADP-induced structural rearrangement.     

The pre-steady state and steady-state kinetics of the ATPase activity of mitochondrial F1

1. The lag time before maximum velocity of ATP hydrolysis is reached upon mixing ATP with F1 is much greater than can be explained by a simple Michaelis-Menten mechanism, and must be due to an activation reaction. The lag time is dependent on the concentration of MgATP (half-maximal at 30 microM) and is equal to 30 ms at infinite MgATP concentration. The initial rate of hydrolysis by nucleotide-depleted F1 is much greater than with normal F1. It is tentatively suggested that the activation reaction with normal preparations is due to replacement of firmly bound ADP by MaATP. 2. After the initial time lag, the reaction follows very closely first-order kinetics provided that the concentration of MgATP is much less than the Km and the reaction is completed within 2 s. This is not expected if the dissociation constant of the enzyme-MgADP complex, an intermediate in the enzymic reaction, is much lower than the Km as has been reported in the literature. The value of V/Km, calculated from the exponential decay, is very close to that calculated from independent measurements of V and Km. 3. The low values for Ki(ADP) reported in the literature were found to be due to a slow (in the order of seconds) formation of an inhibited MgADP-enzyme complex. Dissipation of this inhibited complex by ATP requires seconds. The dissociation constant of the MgADP-enzyme complex that is an intermediate in the enzyme reaction was found to be 150 microM. 4. ADP but not ATP becomes firmly bound to nucleotide-depleted F1 in the absence of Mg2+.     

Diol dehydratase-reactivating factor is a reactivase--evidence for multiple turnovers and subunit swapping with diol dehydratase

Adenosylcobalamin-dependent diol dehydratase (DD) undergoes suicide inactivation by glycerol, one of its physiological substrates, resulting in the irreversible cleavage of the coenzyme Co-C bond. The damaged cofactor remains tightly bound to the active site. The DD-reactivating factor reactivates the inactivated holoenzyme in the presence of ATP and Mg(2+) by mediating the exchange of the tightly bound damaged cofactor for free intact coenzyme. In this study, we demonstrated that this reactivating factor mediates the cobalamin exchange not stoichiometrically but catalytically in the presence of ATP and Mg(2+). Therefore, we concluded that the reactivating factor is a sort of enzyme. It can be designated DD reactivase. The reactivase showed broad specificity for nucleoside triphosphates in the activation of the enzyme·cyanocobalamin complex. This result is consistent with the lack of specific interaction with the adenine ring of ADP in the crystal structure of the reactivase. The specificities of the reactivase for divalent metal ions were also not strict. DD formed 1:1 and 1:2 complexes with the reactivase in the presence of ADP and Mg(2+). Upon complex formation, one β subunit was released from the (αβ)? tetramer of the reactivase. This result, together with the similarity in amino acid sequences and folds between the DD β subunit and the reactivase β subunit, suggests that subunit displacement or swapping takes place upon formation of the enzyme·reactivase complex. This would result in the dissociation of the damaged cofactor from the inactivated holoenzyme, as suggested by the crystal structures of the reactivase and DD.     

Evidence for a novel,strongly bound acto-S1 complex carrying ADP and phosphate stabilized in the G680V mutant of Dictyostelium myosin II

Gly 680 of Dictyostelium myosin II sits at a critical position within the reactive thiol helices. We have previously shown that G680V mutant subfragment 1 largely remains in strongly actin-bound states in the presence of ATP. We speculated that acto-G680V subfragment 1 complexes accumulate in the A.M.ADP.P(i) state on the basis of the biochemical phenotypes conferred by mutations which suppress the G680V mutation in vivo [Wu, Y., et al. (1999) Genetics 153, 107-116]. Here, we report further characterization of the interaction between actin and G680V subfragment 1. Light scattering data demonstrate that the majority of G680V subfragment 1 is bound to actin in the presence of ATP. These acto-G680V subfragment 1 complexes in the presence of ATP do not efficiently quench the fluorescence of pyrene-actin, unlike those in rigor complexes or in the presence of ADP alone. Kinetic analyses demonstrated that phosphate release, but not ATP hydrolysis or ADP release, is very slow and rate limiting in the acto-G680V subfragment 1 ATPase cycle. Single turnover kinetic analysis demonstrates that, during ATP hydrolysis by the acto-G680V subfragment 1 complex, quenching of pyrene fluorescence significantly lags the increase of light scattering. This is unlike the situation with wild-type subfragment 1, where the two signals have similar rate constants. These data support the hypothesis that the main intermediate during ATP hydrolysis by acto-G680V subfragment 1 is an acto-subfragment 1 complex carrying ADP and P(i), which scatters light but does not quench the pyrene fluorescence and so has a different conformation from the rigor complex.     

Adenosine 5'-O-(3-thiotriphosphate) can support the formation of an initiation complex between the DNA polymerase III holoenzyme and primed DNA

Adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S) will substitute for ATP in the formation of an initiation complex between the DNA polymerase III holoenzyme of Escherichia coli and primed DNA. The initiation complex formed in the presence of ATP gamma S between the DNA polymerase III holoenzyme and single-stranded DNA-binding protein-encoated primed M13 Gori DNA is stabile and isolable by gel filtration at room temperature. Upon addition of the four required deoxynucleoside triphosphates, this complex is rapidly converted to the duplex replicative form without dissociation of the polymerase. Initiation complexes formed in the presence of either ATP gamma S or ATP are indistinguishable by their resistance to antibody directed against the beta subunit of the holoenzyme and by their ability to elongate without further activation. A 2-fold difference was observed, however, in both the extent of initiation complex formation and in the dissociation of initiation complexes once formed. This difference is discussed in the light of previous proposals regarding a dimeric polymerase capable of replicating both strands at a replication fork concurrently.     

Kinetic mechanism of the fastest motor protein, Chara myosin

Chara corallina class XI myosin is by far the fastest molecular motor. To investigate the molecular mechanism of this fast movement, we performed a kinetic analysis of a recombinant motor domain of Chara myosin. We estimated the time spent in the strongly bound state with actin by measuring rate constants of ADP dissociation from actin.motor domain complex and ATP-induced dissociation of the motor domain from actin. The rate constant of ADP dissociation from acto-motor domain was >2800 s(-1), and the rate constant of ATP-induced dissociation of the motor domain from actin at physiological ATP concentration was 2200 s(-1). From these data, the time spent in the strongly bound state with actin was estimated to be <0.82 ms. This value is the shortest among known values for various myosins and yields the duty ratio of <0.3 with a V(max) value of the actin-activated ATPase activity of 390 s(-1). The addition of the long neck domain of myosin Va to the Chara motor domain largely increased the velocity of the motility without increasing the ATP hydrolysis cycle rate, consistent with the swinging lever model. In addition, this study reveals some striking kinetic features of Chara myosin that are suited for the fast movement: a dramatic acceleration of ADP release by actin (1000-fold) and extremely fast ATP binding rate.     

Reconstitution in vitro of V1 complex of Thermus thermophilus V-ATPase revealed that ATP binding to the A subunit is crucial for V1 formation

Vacuolar-type H(+)-ATPase (V-ATPase or V-type ATPase) is a multisubunit complex comprised of a water-soluble V(1) complex, responsible for ATP hydrolysis, and a membrane-embedded V(o) complex, responsible for proton translocation. The V(1) complex of Thermus thermophilus V-ATPase has the subunit composition of A(3)B(3)DF, in which the A and B subunits form a hexameric ring structure. A central stalk composed of the D and F subunits penetrates the ring. In this study, we investigated the pathway for assembly of the V(1) complex by reconstituting the V(1) complex from the monomeric A and B subunits and DF subcomplex in vitro. Assembly of these components into the V(1) complex required binding of ATP to the A subunit, although hydrolysis of ATP is not necessary. In the absence of the DF subcomplex, the A and B monomers assembled into A(1)B(1) and A(3)B(3) subcomplexes in an ATP binding-dependent manner, suggesting that ATP binding-dependent interaction between the A and B subunits is a crucial step of assembly into V(1) complex. Kinetic analysis of assembly of the A and B monomers into the A(1)B(1) heterodimer using fluorescence resonance energy transfer indicated that the A subunit binds ATP prior to binding the B subunit. Kinetics of binding of a fluorescent ADP analog, N-methylanthraniloyl ADP (mant-ADP), to the monomeric A subunit also supported the rapid nucleotide binding to the A subunit.     

Cysteine-mediated cross-linking indicates that subunit C of the V-ATPase is in close proximity to subunits E and G of the V1 domain and subunit a of the V0 domain

The vacuolar (H+)-ATPases (V-ATPases) are multisubunit complexes responsible for ATP-dependent proton transport across both intracellular and plasma membranes. The V-ATPases are composed of a peripheral domain (V1) that hydrolyzes ATP and an integral domain (V0) that conducts protons. Dissociation of V1 and V0 is an important mechanism of controlling V-ATPase activity in vivo. The crystal structure of subunit C of the V-ATPase reveals two globular domains connected by a flexible linker (Drory, O., Frolow, F., and Nelson, N. (2004) EMBO Rep. 5, 1-5). Subunit C is unique in being released from both V1 and V0 upon in vivo dissociation. To localize subunit C within the V-ATPase complex, unique cysteine residues were introduced into 25 structurally defined sites within the yeast C subunit and used as sites of attachment of the photoactivated sulfhydryl reagent 4-(N-maleimido)benzophenone (MBP). Analysis of photocross-linked products by Western blot reveals that subunit E (part of V1) is in close proximity to both the head domain (residues 166-263) and foot domain (residues 1-151 and 287-392) of subunit C. By contrast, subunit G (also part of V1) shows cross-linking to only the head domain whereas subunit a (part of V0) shows cross-linking to only the foot domain. The localization of subunit C to the interface of the V1 and V0 domains is consistent with a role for this subunit in controlling assembly of the V-ATPase complex.     

Adenosine 5'-O-(3-thiotriphosphate) hydrolysis by dynein

The interaction of dynein with ATP gamma S, a phosphorothioate analogue of ATP, has been investigated in depth. The hydrolyses of ATP gamma S and of ATP were shown to be mutually competitive. ATP gamma S induced complete dissociation of the microtubule-dynein complex such that the time course of dissociation monitored by stopped-flow light-scattering methods followed a single exponential. The ATP gamma S concentration dependence of the rate of dissociation was hyperbolic, indicating that the dissociation is at least a two-step process: M.D + ATP gamma S in equilibrium M.D.ATP gamma S----M + D.ATP gamma S. The fit to the hyperbola gives an apparent Kd = 0.5 mM for the binding of ATP gamma S to the microtubule-dynein complex, and the maximal rate of 45 s-1 defines the rate of dissociation of the ternary M.D.ATP gamma S complex. Rapid quench-flow experiments demonstrated that the hydrolysis of ATP gamma S by dynein exhibited an initial burst of product formation. The size of the burst was 1.2 mol/10(6) g of dynein, comparable to that in the case of ATP hydrolysis. The steady-state rate of ATP gamma S turnover by dynein was activated by MAP-free microtubules. Because the rate of ATP gamma S turnover is severalfold (4-8) slower than ATP turnover, the rate-limiting step must be release of thiophosphate, not ADP. Thus, microtubules can activate the rate of thiophosphate release. The stereochemical course of phosphoric residue transfer was determined by using ATP gamma S stereospecifically labeled in the gamma position with 18O.(ABSTRACT TRUNCATED AT 250 WORDS)     

Presteady state kinetic analysis of vanadate-induced inhibition of the dynein ATPase

The effects of vanadate on the kinetics of ATP binding and hydrolysis by Tetrahymena 30 S dynein were examined by presteady state kinetic analysis. Up to a concentration of 400 microM, vanadate did not inhibit the rate or amplitude of the ATP binding-induced dissociation of the microtubule-dynein complex measured by stopped flow light-scattering methods. Chemical quench flow experiments showed that vanadate (80 microM) did not alter the rate or amplitude of the presteady state ATP binding or ATP hydrolysis transients, but the steady state hydrolysis of ATP was blocked immediately after a single turnover of ATP. Preincubation of the enzyme with ADP and vanadate inhibited both presteady state and steady state hydrolysis. These data suggest that vanadate acts as a phosphate analog to form an enzyme-ADP-vanadate complex, analogous to the transition state during catalysis, by the following pathway: (formula; see text) where V represents vanadate and D represents a dynein active site. ADP and vanadate, added together, induced dissociation of the microtubule-dynein complex at a maximum rate of 0.6 S-1. These observations imply that a microtubule-dynein-ADP-vanadate complex was formed which subsequently dissociated as shown below: (formula; see text) where M denotes a microtubule. The ADP plus vanadate-induced dissociation may represent the reverse of the normal forward pathway involving the binding of a dynein-ADP-phosphate complex to a microtubule.     

Heterogeneous nucleotide occupancy stimulates functionality of phage shock protein F, an AAA+ transcriptional activator

The catalytic AAA+ domain (PspF1-275) of an enhancer-binding protein is necessary and sufficient to contact sigma54-RNA polymerase holoenzyme (Esigma54), remodel it, and in so doing catalyze open promoter complex formation. Whether ATP binding and hydrolysis is coordinated between subunits of PspF and the precise nature of the nucleotide(s) bound to the oligomeric forms responsible for substrate remodeling are unknown. We demonstrate that ADP stimulates the intrinsic ATPase activity of PspF1-275 and propose that this heterogeneous nucleotide occupancy in a PspF1-275 hexamer is functionally important for specific activity. Binding of ADP and ATP triggers the formation of functional PspF1-275 hexamers as shown by a gain of specific activity. Furthermore, ATP concentrations congruent with stoichiometric ATP binding to PspF1-275 inhibit ATP hydrolysis and Esigma54-promoter open complex formation. Demonstration of a heterogeneous nucleotide-bound state of a functional PspF1-275.Esigma54 complex provides clear biochemical evidence for heterogeneous nucleotide occupancy in this AAA+ protein. Based on our data, we propose a stochastic nucleotide binding and a coordinated hydrolysis mechanism in PspF1-275 hexamers.     

Characterization of nucleotide binding sites on the membrane-bound chloroplast ATP synthase (coupling factor CF1)

Phosphorylation of ADP and nucleotide exchange by membrane-bound coupling factor CF₁ are very fast reactions in the light, so that a direct comparison of both reactions is difficult. By adding substrate ADP and phosphate to illuminated thylakoids together with the uncoupler FCCP, the phosphorylation time is limited and the amount of ATP formed can be reduced to less than 1 ATP per enzyme. Low concentrations of medium nucleotides during illumination increase the amount of ATP formed during uncoupling presumably by binding to the tight nucleotide binding site (further designated as ‘site A’) with an affinity of 1 to 7 μM for ADP and ATP. ATP formation itself shows half-saturation at about 30 μM. Loosely bound nucleotides are exchanged upon addition of nucleotides with uncoupler (Schumann, J. (1984) Biochim. Biophys. Acta 766, 334–342). Release depends binding of nucleotides to a second site. The affinity of this site for ADP (in the presence of phosphate) is about 30 μM. It is assumed that phosphorylation and induction of exchange both occur on the same site (site B). During ATP hydrolysis, an ATP molecule is bound to site A, while on another site, ATP is hydrolyzed rapidly. The affinity of ADP for the catalytic site (70 μM) is in the same range as the observed Michaelis constant of ADP during phosphorylation; it is assumed that site B is involved in ATP hydrolysis. Site A exhibits some catalytic activity; it might be that site A is involved in ATP formation in a dual-site mechanism. For ATP hydrolysis, however, direct determination of exchange rates showed that the exchange rate of ATP bound to site A is about 30-times lower than ATP hydrolysis under the same conditions.     

Interaction between aurovertin and adenine nucleotide binding sites on mitochondrial F1-ATPase and the isolated beta subunit

The effect of aurovertin on the binding parameters of ADP and ATP to native F1 from beef heart mitochondria in the presence of EDTA has been explored. Three exchangeable sites per F1 were titrated by ADP and ATP in the absence or presence of aurovertin. Curvilinear Scatchard plots for the binding of both ADP and ATP were obtained in the absence of aurovertin, indicating one high affinity site (Kd for ADP = 0.6-0.8 microM; Kd for ATP = 0.3-0.5 microM) and two lower affinity sites (Kd for ADP = 8-10 microM; Kd for ATP = 7-10 microM). With a saturating concentration of aurovertin capable of filling the three beta subunits of F1, the curvilinearity of the Scatchard plots was decreased for ATP binding and abolished for ADP binding, indicating homogeneity of ADP binding sites in the F1-aurovertin complex (Kd for ADP = 2 microM). When only the high affinity aurovertin site was occupied, maximal enhancement of the fluorescence of the F1-aurovertin complex was attained with 1 mol of ADP bound per mol of F1 and maximal quenching for 1 mol of ATP bound per mol of F1. When the F1-aurovertin complex was incubated with [3H]ADP followed by [14C]ATP, full fluorescence quenching was attained when ATP had displaced the previously bound ADP. In the case of the isolated beta subunit, both ADP and ATP enhanced the fluorescence of the beta subunit-aurovertin complex. The Kd values for ADP and ATP in the presence of EDTA were 0.6 mM and 3.7 mM, respectively; MgCl2 decreased the Kd values to 0.1 mM for both ADP and ATP. It is postulated that native F1 possesses three equivalent interacting nucleotide binding sites and exists in two conformations which are in equilibrium and recognize either ATP (T conformation) or ADP (D conformation). The negative interactions between the nucleotide binding sites of F1 are strongest in the D conformation. Upon addition of aurovertin, the site-site cooperativity between the beta subunits of F1 is decreased or even abolished.