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.     

Identification of high-affinity (Kd 0.35 mumol/L) and low-affinity (Kd 7.9 mumol/L) platelet binding sites for ADP and competition by ADP analogues

Steady-state binding of ADP to blood platelets and isolated membranes has not previously been obtained because of complications arising from metabolism of the ligand and dilution due to its secretion from storage granules. In the present studies, competition binding isotherms (n = 9) using paraformaldehyde-fixed platelets showed that [2-3 H]ADP bound to two sites with a small amount (approximately 5% of total) of nonspecific binding: 410,000 +/- 40,000 sites of low affinity (Kd 7.9 +/- 2.0 mumol/L) and 160,000 +/- 20,000 sites of high affinity (Kd 0.35 +/- 0.04 mumol/L) corresponding to the ADP concentration required for activation in fresh platelets (0.1-0.5 mumol/L). All agonists and antagonists examined were able to compete with ADP at the high-affinity site. The strong platelet agonists 2-methylthio ADP and 2-(3- aminopropylthio)ADP competed with ADP at the high-affinity site with dissociation constant values of 7 mumol/L and 200 mumol/L, respectively. The partial agonist 2',3'-dialdehyde ADP and the weak agonist GDP also competed at the high-affinity site with Kd values of 5 mumol/L and 49 mumol/L, respectively. The sequence of binding affinities of other adenine nucleotides at the high-affinity site corresponded to their relative activities as known antagonists of platelet activation by ADP; namely, ADP(Kd 0.35 mumol/L) approximately equal to ATP (Kd 0.45 mumol/L) much greater than AMP (Kd 360 mumol/L). Adenosine and 2-chloroadenosine did not compete with ADP. ADP binding to the high-affinity site was inhibited by p-mercuribenzene sulfonate (Ki 250 mumol/L) but only very weakly by 5'-p- fluorosulfonylbenzoyladenosine (Ki 1 mmol/L). All the above nucleotides also competed with ADP at the low-affinity sites but, because of the high concentrations of competing nucleotide required, dissociation constants at this site were obtained only for ATP (21 mumol/L), 2-MeS ADP (200 mumol/L) and 2',3'-dialdehyde ADP (270 mumol/L). 8-Bromo ADP competed strongly with ADP at the high-affinity site (Kd 0.40 mumol/L) but weakly if at all at the low-affinity site. 8-Bromo ADP inhibited platelet activation induced by ADP (EC50 approximately 100 mumol/L) but not by collagen, thrombin, or ionophore A23187.(ABSTRACT TRUNCATED AT 400 WORDS)     

Evidence that the Mg-dependent low-affinity binding site for ATP and Pi demonstrated on the isolated beta subunit of the F0.F1 ATP synthase is a catalytic site.

Binding sites for one Pi and two ATP or ADP molecules have been identified on the isolated, reconstitutively active beta subunit from the Rhodospirillum rubrum F0.F1 ATP synthase. Chemical modification of this beta subunit by the histidine reagent diethyl pyrocarbonate or by the carboxyl group reagent Woodword's reagent K results in complete inhibition of Pi binding to beta. The same reagents inhibit the binding of ATP to a Mg-dependent low-affinity site but not to a Mg-independent high-affinity site on this beta subunit. The binding stoichiometry of ADP to either site is not affected by these modifications. The beta subunit modified by either one of these reagents retains its capacity to rebind to beta-less chromatophores but not its ability to restore their photo-phosphorylation. These results indicate that the low-affinity Pi binding site on beta is located at the binding site of the gamma-phosphate group of ATP in the Mg-dependent low-affinity nucleotide binding site. This site contains histidine and carboxyl group residues, both of which are required for the binding of Pi and of the gamma-phosphate group of ATP. The same residues must also be involved in the capacity of the isolated beta subunit to restore the catalytic activity of the beta-less ATP synthase. It is therefore concluded that the low-affinity Mg-dependent substrate binding site identified on the isolated beta subunit of the R. rubrum F0.F1 ATP synthase is the catalytic site of this enzyme complex.     

The structure of bovine F1-ATPase complexed with the peptide antibiotic efrapeptin.

In the previously determined structure of mitochondrial F1-ATPase determined with crystals grown in the presence of adenylyl-imidodiphosphate (AMP-PNP) and ADP, the three catalytic beta-subunits have different conformations and nucleotide occupancies. AMP-PNP and ADP are bound to subunits beta TP and beta DP, respectively, and the third beta-subunit (beta E) has no bound nucleotide. The efrapeptins are a closely related family of modified linear peptides containing 15 amino acids that inhibit both ATP synthesis and hydrolysis by binding to the F1 catalytic domain of F1F0-ATP synthase. In crystals of F1-ATPase grown in the presence of both nucleotides and inhibitor, efrapeptin is bound to a unique site in the central cavity of the enzyme. Its binding is associated with small structural changes in side chains of F1-ATPase around the binding pocket. Efrapeptin makes hydrophobic contacts with the alpha-helical structure in the gamma-subunit, which traverses the cavity, and with subunit beta E and the two adjacent alpha-subunits. Two intermolecular hydrogen bonds could also form. Intramolecular hydrogen bonds probably help to stabilize efrapeptin's two domains (residues 1-6 and 9-15, respectively), which are connected by a flexible region (beta Ala-7 and Gly-8). Efrapeptin appears to inhibit F1-ATPase by blocking the conversion of subunit beta E to a nucleotide binding conformation, as would be required by an enzyme mechanism involving cyclic interconversion of catalytic sites.     

Product inhibition of the actomyosin subfragment-1 ATPase in skeletal, cardiac, and smooth muscle.

We studied product inhibition of the actin-activated ATPase of myosin subfragment-1 (S-1) from the three types of muscle tissue: skeletal, cardiac, and smooth. Increasing levels of [MgADP] in the 0-1-mM range caused significant inhibition of the actin-activated MgATPase activity of cardiac and gizzard but not skeletal muscle S-1. When total nucleotide concentration ([ATP] + [ADP]) was kept constant at 1 mM, ATPase activity was inhibited by 50% at an ADP/ATP ratio of 6:1 for cardiac S-1 and 3:1 for gizzard S-1. For skeletal S-1, however, even a 19:1 ratio did not cause 50% inhibition of ATPase activity. The observed effect was not due to changes in pH or inorganic phosphate concentration, nor could it be explained by substrate (ATP) depletion. In the absence of actin, ADP had little or no inhibitory effect on the ATPase activity of S-1, and these observations imply that ADP is competing directly for the ATP binding site of the actin-S1 complexes of cardiac and smooth muscle S-1. ADP has previously been shown to be a weak competitive inhibitor of the ATPase activity in skeletal muscle. The current data imply that ADP is a very effective competitive inhibitor for the actin-activated ATPase activity of cardiac and gizzard S-1 and, therefore, that ADP may be a physiologically important modulator of contractile activity in cardiac and smooth muscle.     

Regulation of the nucleotide dependence of the cardiac sarcolemma Ca(2+)-ATPase.

The nucleotide dependence of the Ca(2+)-ATPase purified from cardiac sarcolemma by calmodulin-affinity chromatography was investigated for preparations either in the basal state or activated by three procedures: (i) addition of calmodulin; (ii) addition of phosphatidylserine and (iii) controlled proteolysis. Upon activation, the maximal velocity of ATP hydrolysis increases by a factor of 4-5, while the curves of ATP dependence of ATP hydrolysis change from hyperbolic to biphasic, revealing the presence of two Kmapp for ATP. A tight coupling between Ca2+ and ATP binding sites was also observed. At high ATP concentration, the ATPase activity of the basal state shows a complex dependence on Ca2+ concentration, increasing sharply at millimolar Ca2+. Our results indicate that this increase in ATPase activity is paralleled by the appearance of a second, low affinity Kmapp for ATP. When only the high affinity site for ATP is occupied the ATPase activity of the basal state displays a simple, hyperbolic dependence on the Ca2+ concentration. In addition, increasing Ca2+ concentration appears to decrease the ATP binding at the low affinity site of the enzyme. The effect of ADP on ATP hydrolysis was also examined. The finding that ADP is a potent inhibitor of the purified Ca(2+)-ATPase from heart suggests that the stimulatory action of ADP observed in cardiac sarcolemmal vesicles is not an intrinsic property of the enzyme.     

Demonstration of a transitory tight binding of ATP and of committed P(i) and ADP during ATP synthesis by chloroplasts

Rapid mixing, quenching, and filtration experiments with chloroplast thylakoid membranes, with energization by acid-base transition, demonstrate that an ATP tightly bound to the isolated membranes is a transient intermediate in the catalytic sequence for ATP synthesis. The experiments also show that most of the P_i and ADP bound at a catalytic site is committed to ATP formation without interchange with medium P_i or ADP. Other results give evidence that upon energization, the tightly bound ADP that is detectable in isolated thylakoid membranes or coupling factor ATPase is rapidly released to the medium from a catalytic site. These findings support an alternating site model in which an energy-requiring conformational transition loosens ATP binding at one site and simultaneously promotes P_i and ADP binding at the other site in a manner favoring ATP formation.     

Evidence for a requirement for ATP hydrolysis at two distinct steps during a single turnover of the catalytic cycle of human P-glycoprotein

P-glycoprotein (Pgp) is an ATP-dependent hydrophobic natural product anticancer drug efflux pump whose overexpression confers multidrug resistance to tumor cells. The work reported here deals with the elucidation of the energy requirement for substrate interaction with Pgp during the catalytic cycle. We show that the K(d) (412 nM) of the substrate analogue [(125)I]iodoarylazidoprazoin for Pgp is not altered by the presence of the nonhydrolyzable nucleotide 5'-adenylylimididiphosphate and vanadate (K(d) = 403 nM). Though binding of nucleotide per se does not affect interactions with the substrate, ATP hydrolysis results in a dramatic conformational change where the affinity of [(125)I]iodoarylazidoprazoin for Pgp trapped in transition-state conformation (Pgp x ADP x vanadate) is reduced >30-fold. To transform Pgp from this intermediate state of low affinity for substrate to the next catalytic cycle, i.e., a conformation that binds substrate with high affinity, requires conditions that permit ATP hydrolysis. Additionally, there is an inverse correlation (R(2) = 0.96) between 8AzidoADP (or ADP) release and the recovery of substrate binding. These results suggest that the release of nucleotide is necessary for reactivation but not sufficient. The hydrolysis of additional molecule(s) of ATP (or 8AzidoATP) is obligatory for the catalytic cycle to advance to completion. These data are consistent with the observed stoichiometry of two ATP molecules hydrolyzed for the transport of every substrate molecule. Our data demonstrate two distinct roles for ATP hydrolysis in a single turnover of the catalytic cycle of Pgp, one in the transport of substrate and the other in effecting conformational changes to reset the pump for the next catalytic cycle.     

Analysis of the AAA sensor-2 motif in the C-terminal ATPase domain of Hsp104 with a site-specific fluorescent probe of nucleotide binding

Hsp104 from Saccharomyces cerevisiae is a hexameric protein with two AAA ATPase domains (N- and C-terminal nucleotide-binding domains NBD1 and NBD2, respectively) per monomer. Our previous analysis of the Hsp104 ATP hydrolysis cycle revealed that NBD1 and NBD2 have very different catalytic properties, but each shows positive cooperativity in hydrolysis. There is also communication between the two domains, in that ATP hydrolysis at NBD1 depends on the nucleotide that is bound to NBD2. Here, we extend our understanding of the Hsp104 ATP hydrolysis cycle through mutagenesis of the AAA sensor-2 motif in NBD2. To do so, we took advantage of the lack of tryptophan residues in Hsp104 to place a single tryptophan in the C-terminal domain (Y819W). The Y819W substitution has no significant effects on folding stability of the C-terminal domain or on ATP hydrolysis by NBD1 or NBD2. The fluorescence of this tryptophan changes in response to ATP and ADP binding, allowing the K(d) and Hill coefficient to be determined for each nucleotide. By using this site-specific probe of binding, we analyze the effect of mutating the conserved arginine residue in the sensor-2 motif in Hsp104 NBD2. An R826M mutation causes nearly equal decreases in affinity of NBD2 for both ATP and ADP, indicating that at this site, the sensor-2 provides binding energy, but does not act to sense the difference between these nucleotides. In addition, the rate of ATP hydrolysis at NBD1 is decreased by the R826M mutation, providing further evidence for interdomain communication in the Hsp104 ATP hydrolysis cycle.     

The structure of bovine F1-ATPase complexed with the antibiotic inhibitor aurovertin B.

In the structure of bovine mitochondrial F1-ATPase that was previously determined with crystals grown in the presence of adenylyl-imidodiphosphate (AMP-PNP) and ADP, the three catalytic beta-subunits have different conformations and nucleotide occupancies. Adenylyl-imidodiphosphate is bound to one beta-subunit (betaTP), ADP is bound to the second (betaDP), and no nucleotide is bound to the third (betaE). Here we show that the uncompetitive inhibitor aurovertin B binds to bovine F1 at two equivalent sites in betaTP and betaE, in a cleft between the nucleotide binding and C-terminal domains. In betaDP, the aurovertin B pocket is incomplete and is inaccessible to the inhibitor. The aurovertin B bound to betaTP interacts with alpha-Glu399 in the adjacent alphaTP subunit, whereas the aurovertin B bound to betaE is too distant from alphaE to make an equivalent interaction. Both sites encompass betaArg-412, which was shown by mutational studies to be involved in binding aurovertin. Except for minor changes around the aurovertin pockets, the structure of bovine F1-ATPase is the same as determined previously. Aurovertin B appears to act by preventing closure of the catalytic interfaces, which is essential for a catalytic mechanism involving cyclic interconversion of catalytic sites.     

KATP channel interaction with adenine nucleotides

ATP-sensitive potassium (K(ATP)) channels are regulated by adenine nucleotides to convert changes in cellular metabolic levels into membrane excitability. Hence, elucidation of interaction of SUR and Kir6.x with adenine nucleotides is an important issue to understand the molecular mechanisms underlying the metabolic regulation of the K(ATP) channels. We analyzed direct interactions with adenine nucleotides of each subunit of K(ATP) channels. Kir6.2 binds adenine nucleotides in a Mg(2+)-independent manner. SUR has two NBFs which are not equivalent: NBF1 is a Mg(2+)-independent high affinity nucleotide binding site, whereas NBF2 is a Mg-dependent low affinity site. Although SUR has ATPase activity at NBF2, it is not used to transport substrates against the concentration gradient unlike other ABC proteins. The ATPase cycle at NBF2 serves as a sensor of cellular metabolism. This may explain the low ATP hydrolysis rate compared to other ABC proteins. Based on studies of photoaffinity labeling, a model of K(ATP) channel regulation is proposed, in which K(ATP) channel activity is regulated by SUR via monitoring the intracellular MgADP concentration. K(ATP) channel activation is expected to be induced by the cooperative interaction of ATP binding at NBF1 and MgADP binding at NBF2.     

Ecto-nucleotide pyrophosphatase/phosphodiesterase as part of a multiple system for nucleotide hydrolysis by platelets from rats: kinetic characterization and biochemical properties

In this study, we describe an ecto-nucleotide pyrophosphatase/phosphodiesterase (E-NPP) activity in rat platelets. Using p-nitrophenyl 5'-thymidine monophosphate (p-Nph-5'-TMP) as a substrate for E-NPP, we demonstrate an enzyme activity that shares the major biochemical properties described for E-NPPs: alkaline pH dependence, divalent cation dependence and blockade of activity by metal ion chelator. K(m) and V(max) values for p-Nph-5'-TMP hydrolysis were found to be 106 +/- 18 microM and 3.44 +/- 0.18 nmol p-nitrophenol/min/mg (mean +/- SD, n = 5). We hypothesize that an E-NPP is co-localized with an ecto-nucleoside triphosphate diphosphohydrolase and an ecto-5'-nucleotidase on the platelet surface, as part of a multiple system for nucleotide hydrolysis, since they can act under distinct physiological conditions and can be differently regulated. Thus, 0.25 mM suramin inhibited p-Nph-5'-TMP, ATP and ADP hydrolysis, while 0.5 mM AMP decreased only p-Nph-5'-TMP hydrolysis. Besides, 5.0, 10 and 20 mM sodium azide just inhibited ATP and ADP hydrolysis. Angiotensin II (5.0 and 10 nM) affected only ADP hydrolysis. Gadolinium chloride (0.2 and 0.5 mM) strongly inhibited the ATP and ADP hydrolysis. The E-NPP described here represents a novel insight into the control of platelet purinergic signaling.     

Active site trapping of nucleotides by crosslinking two sulfhydryls in myosin subfragment 1.

Studies with reagents that crosslink two thiol groups have shown that it is possible to trap nucleotides at the active site of myosin chymotryptic subfragment 1. Subfragment 1 incorporates nearly stoichiometric quantities of [14C]ATP or [14C]ADP in a manner that depends linearly on the extent of inactivation by either N,N'-p-phenylenedimaleimide or Co(II)phenanthroline/[Co(III)(phenanthroline)2CO3]+ complexes. The incorporated radioactive nucleotide is retained after gel filtration, even when the enzyme derivatives are stored in the presence of EDTA or nonradioactive nucleotides (t 1/2 approximately 5 days). The nucleotide incorporated is not covalently bound because HClO4 denaturation allows immediate release of bound nucleotide. The nucleotide retained is ADP because the gamma-phosphate of [gamma-32P]ATP is lost after trapping. Subfragment 1 inactivated as above does not bind the competitive inhibitor adenosine 5'-[beta, gamma-imido]triphosphate, indicating that the active site is blocked. It is proposed that a jawlike nucleotide cleft closes on MgADP or MgATP, which can be locked shut by crosslinking two thiol groups by reaction with N,N'-p-phenylenedimaleimide or cobalt phenanthroline complexes.     

Pharmacological plasticity of cardiac ATP-sensitive potassium channels toward diazoxide revealed by ADP

The pharmacological phenotype of ATP-sensitive potassium (K(ATP)) channels is defined by their tissue-specific regulatory subunit, the sulfonylurea receptor (SUR), which associates with the pore-forming channel core, Kir6.2. The potassium channel opener diazoxide has hyperglycemic and hypotensive properties that stem from its ability to open K(ATP) channels in pancreas and smooth muscle. Diazoxide is believed not to have any significant action on cardiac sarcolemmal K(ATP) channels. Yet, diazoxide can be cardioprotective in ischemia and has been found to bind to the presumed cardiac sarcolemmal K(ATP) channel-regulatory subunit, SUR2A. Here, in excised patches, diazoxide (300 microM) activated pancreatic SUR1/Kir6.2 currents and had little effect on native or recombinant cardiac SUR2A/Kir6.2 currents. However, in the presence of cytoplasmic ADP (100 microM), SUR2A/Kir6.2 channels became as sensitive to diazoxide as SUR1/Kir6. 2 channels. This effect involved specific interactions between MgADP and SUR, as it required Mg(2+), but not ATP, and was abolished by point mutations in the second nucleotide-binding domain of SUR, which impaired channel activation by MgADP. At the whole-cell level, in cardiomyocytes treated with oligomycin to block mitochondrial function, diazoxide could also activate K(ATP) currents only after cytosolic ADP had been raised by a creatine kinase inhibitor. Thus, ADP serves as a cofactor to define the responsiveness of cardiac K(ATP) channels toward diazoxide. The present demonstration of a pharmacological plasticity of K(ATP) channels identifies a mechanism for the control of channel activity in cardiac cells depending on the cellular ADP levels, which are elevated under ischemia.     

Studies on the mechanism of oxidative phosphorylation: effects of specific F0 modifiers on ligand-induced conformation changes of F1.

Aurovertin is a fluorescent antibiotic that binds to the catalytic beta subunits of the mitochondrial F1-ATPase and inhibits ATP synthesis and hydrolysis. ATP, ADP, and membrane energization in submitochondrial particles (SMP) alter the fluorescence of F1-bound aurovertin. These fluorescence changes are considered to be in response to the conformation changes of F1-ATPase. This paper shows that the ATP-induced fluorescence change of aurovertin bound to SMP or complex V (purified ATP synthase complex F0-F1) is inhibited when these preparations are pretreated with oligomycin or N,N'-dicyclohexylcarbodiimide (DCCD). This inhibition is not seen with isolated F1-ATPase. These and other results have suggested that modifications of the DCCD-binding protein in the membrane sector (F0) of the ATP synthase complex are communicated to F1, thereby altering the binding characteristics of ATP to the beta subunits. By analogy, it is proposed that modifications (e.g., protonation/deprotonation) of the DCCD-binding protein effected by protonic energy alter the conformation of F1 and bring about the substrate/product binding changes that appear to be essential features of the mechanism and regulation of oxidative phosphorylation.     

ε-Adenylylated Glutamine Synthetase: An Internal Fluorescence Probe for Enzyme Conformation

A fluorescent derivative of ATP, epsilon-ATP, was used to adenylylate glutamine synthetase (EC 6.3.1.2) from Escherichia coli enzymatically. The epsilon-adenylylated enzyme exhibits similar catalytic properties and inhibitor susceptibility to those of the naturally adenylylated enzyme. The fluorescence properties of the epsilon-adenosine and of tryptophan residues of the enzyme were used to study ligand-induced conformational changes involving alterations of the tryptophan regions and the adenylylation site of the protein. Binding of Mn(2+) to the epsilon-adenylylated enzyme is accompanied by a decrease of epsilon-adenosine fluorescence as compared to the effect observed for the Mg(2+) binding. An ADP binding study shows that at low ADP concentration, ADP causes enhancement of the tryptophan fluorescence only, reflecting the binding to unadenylylated subunits; and at high ADP concentration, ADP causes not only enhancement of the fluorescence, but also a quenching of the fluorescence of enzyme-bound epsilon-AMP, reflecting binding to the adenylylated subunits. Dissociation constants calculated from these fluorescence changes agree well with those determined from binding studies of ADP to adenylylated and unadenylylated enzymes. Binding of the feedback inhibitor, alanine, to Mn(2+)-dependent glutamine synthetase causes enhancement of the epsilon-AMP fluorescence, from which a dissociation constant of 1.5 mM was calculated for the inhibitor. The fluorescence changes observed due to ligands binding suggest that Mg(2+) and Mn(2+) stabilize different conformational states of the enzyme.     

Vacuolar ATPases, like F1,F0-ATPases, show a strong dependence of the reaction velocity on the binding of more than one ATP per enzyme.

Recent studies with vacuolar ATPases have shown that multiple copies catalytic subunits are present and that these have definite sequence homology with catalytic subunits of the F1,F0-ATPases. Experiments are reported that assess whether the vacuolar ATPases may have the unusual catalytic cooperativity with sequential catalytic site participation as in the binding change mechanism for the F1,F0-ATPases. The extent of reversal of bound ATP hydrolysis to bound ADP and Pi as medium ATP concentration was lowered was determined by 18O-exchange measurements for yeast and neurospora vacuolar ATPases. The results show a pronounced increase in the extent of water oxygen incorporation into the Pi formed as ATP concentration is decreased to the micromolar range. The F1,F0-ATPase from neurospora mitochondria showed an even more pronounced modulation, similar to that of other F1-type ATPases. The vacuolar ATPases thus appear to have a catalytic mechanism quite analogous to that of the F1,F0-ATPases.     

Coupling of active ion transport and aerobic respiratory rate in isolated renal tubules.

We report the results of studies in which the cytoplasmic coupling between Na+,K+-ATPase activity (presumably a measure of active transport) and the mitochondrial respiratory rate was investigated in a tubule suspension from the rabbit kidney cortex. Simultaneous measurements of the redox state of mitochondrial nicotinamide adenine dinucleotide (NAD) (performed fluorometrically), the cellular ATP and ADP concentrations, and the oxygen consumption rate (QO2) were made under conditions known to alter the Na+,K+-ATPase turnover. Ouabain (25 microM) caused: (i) a 54% inhibition of QO2, (ii) a net reduction of NAD, and (iii) a 30% increase in the ATP/ADP ratio. The addition of K+ (5 ?M) to K+-depleted tubules caused: (i) an initial 127% stimulation of QO2 followed by a new steady-state QO2 50% above control, (ii) an initial large oxidation of NAD followed by a new steady state more oxidized than the control level, and (iii) a 47% decrease in the cellular ATP/ADP ratio. These data indicate that the cellular ATP and ADP concentrations or the ATP/ADP ratio may be part of the coupling mechanism linking Na+,K+-ATPase turnover and the aerobic metabolic rate in kidney.