MgATP-induced inhibition of the enzymic activity of chloroform-released ox-heart mitochondrial ATPase.

Preincubation of the chloroform-released ox-heart mitochondrial ATPase with its substrate, MgATP, results in a time-dependent inhibition of its ATPase activity. The inhibition is irreversible on the time-scale of an ATPase assay. It is not due to the accumulation of ADP and P_i. The extent of the inhibition is proportional to the number of turnovers of the enzyme during the preincubation period. It is suggested that the MgATP-induced inhibition described here is due to an intermediate enzyme-substrate complex of the ATP-hydrolytic pathway becoming converted into an inhibited enzyme species.     

Deficiency of uncoupler-stimulated adenosine triphosphatase activity in yeast mitochondria

Oligomycin-sensitive ATPase activity was studied in isolated yeast mitochondria. The protonophore CCCP, at a concentration which completely inhibited ATP synthesis, induced only a low rate of hydrolysis of externally added ATP, and the extent of hydrolysis was dependent upon phosphate (Pi) concentration. CCCP promoted hydrolysis of intramitochondrial ATP. However, hydrolysis of externally added ATP was total in a medium containing potassium phosphate plus valinomycin. Without ionophores, ATPase activity was only observed at high external pH or with detergent-treated mitochondria. Under state 4 conditions, external ATP had access to the catalytic nucleotide site of ATPase as shown by 32Pi-ATP exchange experiments. These results are discussed in terms of a limitation of the translocase-mediated ATP/ADP exchange in uncoupled mitochondria.     

Involvement of the endogenous inhibitor protein in the MgATP-induced inhibition of soluble mitochondrial adenosine triphosphatase activity.

Chloroform-released ATPase from ox heart mitochondria contains significant amounts of inhibitor protein. There is a correlation between processes that affect the interactions between the inhibitor protein and the ATPase molecule and the ability of MgATP to induce an inhibition of ATPase activity. Evidence is presented suggesting that the endogenous inhibitor protein is involved in the process of MgATP-induced inhibition of soluble ATPase activity.     

The role of tightly bound ADP on chloroplast ATPase

Isolated chloroplast coupling factor 1 ATPase is known to retain about 1 mol of tightly bound ADP/mol of enzyme. Some experimental results have given evidence that the bound ADP is at catalytic sites, but this view has not been supported by observations of a slow replacement of the bound ADP when CaATP or MgATP is added. The experiments reported in this paper show why a slow replacement of ADP bound at a catalytic site can occur. When coupling factor 1, labeled with tightly bound [3H]ADP, is exposed to Mg2+ or Ca2+ prior to the addition of MgATP or CaATP, a pronounced lag in the onset of ATP hydrolysis is observed, and only slow replacement of the [3H]ADP occurs. Mg2+ or Ca2+ can induce inhibition very rapidly, as if an inhibited form of the enzyme results whenever the enzyme with tightly bound ADP encounters Mg2+ or Ca2+ prior to ATP. The inhibited form can be slowly reactivated by incubation with EDTA, although some irreversible loss in activity is encountered. In contrast, when MgATP or CaATP is added to enzyme depleted of Mg2+ and Ca2+ by incubation with EDTA, a rapid onset of ATP hydrolysis occurs and most of the tightly bound [3H]ADP is released within a few seconds, as expected for binding at a catalytic site. The Mg2+-induced inhibition of both the ATPase activity and the lack of replacement of tightly bound [3H] ADP can be largely prevented by incubation with Pi under conditions favoring Pi addition to the site containing the tightly bound ADP. Our and other results can be explained if enzyme catalysis is greatly hindered when MgADP or CaADP without accompanying Pi is tightly bound at one of the three catalytic sites on the enzyme in a high affinity conformation.     

Catalysis of partial reactions of ATP synthesis by beef heart mitochondrial adenosine triphosphatase

We have found that when the ATP hydrolysis activity of beef heart mitochondrial adenosine triphosphatase (F1) is eliminated by either cold treatment or chemical modification, the enzyme attains the ability to catalyze the Pi in equilibrium ATP exchange reaction. The ATP hydrolysis activity of isolated F1 was lost upon chemical modification by phenyglyoxal, butanedione, or 7-chloro-4-nitrobenzene-2-oxa-1,3-diazole. The F1 thus chemically modified was able to catalyze an ADP-dependent Pi in equilibrium ATP exchange reaction. In addition F1 that had been cold-treated to eliminate ATP hydrolysis activity, also catalyzed the Pi in equilibrium ATP exchange reaction. The Pi in equilibrium ATP exchange catalyzed by modified F1 was shown to be totally inhibited by the F1-specific antibiotic efrapeptin. We have previously shown that isolated beef heart mitochondrial ATPase will catalyze the formation of a transition state analog of the ATP synthesis reaction (Bossard, M. J., Vik, T. A., and Schuster, S. M. (1980) J. Biol. Chem. 255, 5342-5346). While the F1-catalyzed ATP hydrolysis activity was lost rapidly upon chemical modification or cold treatment, the ability of the enzyme to produce Pi . adenosine 5'-diphosphate (chromium(III) salt) from phosphate and monodentate adenosine 5'-diphosphate (chromium(III) salt) was unimpaired. The implications of these data with regard to the mechanism of ATP synthesis are discussed.     

Properties of membrane adenosine triphosphatase of the obligately anaerobic bacterium Veillonella alcalescens.

Some properties of membrane ATPase activity in Veillonella alcalescens were examined. Mg2+ is required for the activity of the enzyme, and Ca2+ also activates the enzyme to some degree. Of the nucleotide triphosphates, GTP and ITP were hydrolyzed to a lesser extent than ATP. The apparent Km for ATP hydrolysis was 0.25 to 0.63 mM. ADP inhibited the enzyme and the kinetic data of its inhibition showed that the presence of ADP resulted in positive cooperativity. The enzyme activity was strongly inhibited by DCCD, azide, fusidic acid and the antibody to purified soluble ATPase from the thermophilic bacterium PS3. Oligomycin, dinitrophenol, and ouabain showed no significant effect.     

Transient state kinetic studies of phosphorylation by ATP and Pi of the calcium-dependent ATPase from sarcoplasmic reticulum.

The ATPase of the sarcoplasmic reticulum is phosphorylated by ATP in the presence of Ca2+. A rapid phosphorylation was observed when the enzyme was preincubated with Ca2+ prior to the addition of 0.1 or 1 mM ATP. The rate of phosphorylation was decreased when Ca2+ was omitted from the preincubation medium and added with ATP when the reaction was started. The rate of phosphorylation by ATP was further decreased when Pi was included in the preincubation medium without Ca2+. In this case, the enzyme was phosphorylated by Pi during the preincubation. When Ca2+ and ATP were added, a burst of phosphorylation by ATP was observed in the initial 16 ms. In the subsequent incubation intervals, the phosphorylation by ATP was synchronous with the hydrolysis of the phosphoenzyme formed by Pi. The rate of hydrolysis of the phosphoenzyme formed by Pi was measured when either the Pi concentration was decreased 10 fold, or when Ca2+, ATP or ATP plus Ca2+ was added to the medium. Upon the single addition of Ca2+, the time for half-maximal decay was in the range 500--1000 ms. In all other conditions it was in the range 70--90 ms.     

Role of phosphate on the ADP-induced hysteretic inhibition of mitochondrial adenosine 5'-triphosphatase. Effects of the natural protein inhibitor

Preincubation of F1-ATPase with ADP and Mg2+ leads to ADP binding at regulatory site inducing a hysteretic inhibition of ATP hydrolysis, i.e., an inhibition that slowly develops after Mg-ATP addition (Di Pietro, A., Penin, F., Godinot, C. and Gautheron, D.C. (1980) Biochemistry 19, 5671-5678). It is shown here that inorganic phosphate (Pi) together with ADP during preincubation abolishes the time-dependence of the inhibition after the addition of the substrate Mg-ATP. This preincubation in the presence of both Pi and ADP slowly leads to a conformation of the enzyme immediately inhibited after the addition of the substrate Mg-ATP. The Pi effect is half-maximal at 35 microM and pH 6.6, whereas a limited effect is induced at pH 8.0. The preincubation of F1-ATPase with Pi and ADP must last long enough (t1/2 = 5 min). The effects can be correlated to the amount of Pi bound to the enzyme, 1 mol Pi per mol (apparent KD of 33 microM) at saturation. Pi neither modifies the ADP binding nor the final level of the concomitant inhibition. When Pi is not present in the preincubation, the final stable rate of ADP-induced hysteretic inhibition is always reached when a near-constant amount of Pi has been generated during Mg-ATP hydrolysis. Kinetic experiments indicate that preincubation with ADP and Pi decreases both Vmax and Km which would favor a conformational change of the enzyme. Taking into account the Pi effects, a more precise model of hysteretic inhibition is proposed. The natural protein inhibitor IF1 efficiently prevents the binding of Pi produced by ATP hydrolysis indicating that the hysteretic inhibition and the IF1-dependent inhibition obey different mechanisms.     

Mechanism of actomyosin adenosine triphosphatase. Evidence that adenosine 5'-triphosphate hydrolysis can occur without dissociation of the actomyosin complex.

We have investigated the steps in the actomyosin ATPase cycle that determine the maximum ATPase rate (Vmax) and the binding between myosin subfragment one (S-1) and actin which occurs when the ATPase activity is close to Vmax. We find that the forward rate constant of the initial ATP hydrolysis (initial Pi burst) is about 5 times faster than the maximum turnover rate of the actin S-1 ATPase. Thus, another step in the cycle must be considerably slower than the forward rate of the initial Pi burst. If this slower step occurs only when S-1 is complexed with actin, as originally predicted by the Lymn-Taylor model, the ATPase activity and the fraction of S-1 bound to actin in the steady state should increase almost in parallel as the actin concentration is increased. As measured by turbidity determined in the stopped-flow apparatus, the fraction of S-1 bound to actin, like the ATPase activity, shows a hyperbolic dependence on actin concentration, approaching 100% asymptotically. However, the actin concentration required so that 50% of the S-1 is bound to actin is about 4 times greater than the actin concentration required for half-maximal ATPase activity. Thus, as previously found at 0 degrees C, at 15 degrees C much of the S-1 is dissociated from actin when the ATPase is close to Vmax, showing that a slow first-order transition which follows the initial Pi burst (the transition from the refractory to the nonrefractory state) must be the slowest step in the ATPase cycle. Stopped-flow studies also reveal that the steady-state turbidity level is reached almost instantaneously after the S-1, actin, and ATP are mixed, regardless of the order of mixing. Thus, the binding between S-1 and actin which is observed in the steady state is due to a rapid equilibrium between S-1--ATP and acto--S-1--ATP which is shifted toward acto-S-1--ATP at high actin concentration. Furthermore, both S-1--ATP and S-1--ADP.Pi (the state occurring immediately after the initial Pi burst) appear to have the same binding constant to actin. Thus, at high actin concentration both S-1--ATP and S-1--ADP.Pi are in rapid equilibrium with their respective actin complexes. Although at very high actin concentration almost complete binding of S-1--ATP and S-1--ADP.Pi to actin occurs, there is no inhibition of the ATPase activity at high actin concentration. This strongly suggests that both the initial Pi burst and the slow rate-limiting transition which follows (the transition from the refractory to the nonrefractory state) occur at about the same rates whether the S-1 is bound to or dissociated from actin. We, therefore, conclude that S-1 does not have to dissociate from actin each time an ATP molecule is hydrolyzed.     

Reversible binding of Pi by beef heart mitochondrial adenosine triphosphatase.

Beef heart mitochondrial ATPase (F1) exhibited a single binding site for Pi. The interaction with Pi was reversible, partially dependent on the presence of divalent metal ions, and characterized by a dissociation constant at pH 7.5 of 80 micronM. A variety of substances known to influence oxidative phosphorylation or the activity of the soluble ATPase (F1) also influenced Pi binding by the enzyme. Thus aurovertin, an inhibitor of oxidative phosphorylation, which was bound tightly by F1 and inhibited ATPase activity, enhanced Pi binding via a 4-fold increase in the affinity of the enzyme for Pi (KD = 20 micronM) but did not alter binding stoichiometry. Anions such as SO4(2-), SO3(2-), chromate, and 2,4-dinitrophenolate, which stimulated ATPase activity of F1, also enhanced Pi binding. Inhibitors of ATPase activity such as nickel/bathophenanthroline and the protein ATPase inhibitor of Pullman and Monroy (Pullman, M. E., and Monroy, G. C. (1963) J. Biol. Chem. 238, 3762-3769) inhibited Pi binding. The adenine nucleotides ADP, ATP, and the ATP analog adenylyl imidodiphosphate as well as the Pi analog arsenate, also inhibited Pi binding. The observations suggest that the Pi binding site was located in or near an adenine nucleotide binding site on the molecule.     

Dicyclohexylcarbodiimide-sensitive ATPase in Halobacterium saccharovorum

Membranes from Halobacterium saccharovorum contained a cryptic ATPase which required Mg2+ or Mn2+ and was activated by Triton X-100. The optimal pH for ATP hydrolysis was 9-10. ATP or GTP were hydrolyzed at the same rate while ITP, CTP, and UTP were hydrolyzed at about half that rate. The products of ATP hydrolysis were ADP and phosphate. The ATPase required high concentrations (3.5 M) of NaCl for maximum activity. ADP was a competitive inhibitor of the activity, with an apparent Ki of 50 microM. Dicyclohexylcarbodiimide (DCCD) inhibited ATP hydrolysis. The inhibition was marginal at the optimum pH of the enzyme. When the ATPase was preincubated with DCCD at varying pH values, but assayed at the optimal pH for activity, DCCD inhibition was observed to increase with increasing acidity of the preincubation medium. DCCD inhibition was also dependent on time of preincubation, and protein and DCCD concentrations. When preincubated at pH 6.0 for 4 h at a protein:DCCD ratio of 40 (w/w), ATPase activity was inhibited 90%.     

Halobacterial adenosine triphosphatases and the adenosine triphosphatase from Halobacterium saccharovorum

Abstract Membranes prepared from various members of the genus Halobacterium contained a Triton X-100 activated adenosine triphosphatase. The enzyme from Halobacterium saccharovorum was unstable in solutions of low ionic strength (< 3 M NaCl) and maximally active in the presence of 3.5 M NaCl. A variety of nucleotide triphosphates was hydrolyzed. MgADP, the product of ATP hydrolysis, was not hydrolyzed and was a competitive inhibitor with respect to MgATP. The enzyme from H. saccharovorum was composed of at least 2 and possibly 4 subunits. The 83-kDa and 60-kDa subunits represented about 90% of total protein. The 60-kDa subunit reacted with dicyclohexylcarbodiimide (DCCD) when inhibition was carried out in an acidic medium. The significance of the two minor components (28 kDa and 12 kDa) is not established. The enzyme from H. saccharovorum , which differs from previously described halobacterial ATPases, possesses properties of an F₁F₀ as well as an E₁E₂ ATPase.     

Effects of oligomycin on the partial reactions of the sodium plus potassium-stimulated adenosine triphosphatase

The effects on phosphoenzyme (E-P) formation of ligands which activate Electrophorus (Na,K)-ATPase were investigated in the presence of oligomycin. When the enzyme was allowed to bind oligomycin in the presence of NaCl and MgCl2, subsequent addition of ATP plus KCl produced a monoexponential time course of E-P formation with a rate of 56 s-1, similar to the rate obtained in the uninhibited enzyme phosphorylated by ATP in the absence of KCl. Pi liberation under these conditions was slow and showed no initial burst phase, consistent with the inhibitory effect oligomycin has on the E1-P to E2-P conformational transition. Addition to KCl to a preincubation medium containing oligomycin, NaCl, and MgCl2 had no further effect on E-P formation. However, equilibration with oligomycin, KCl, and MgCl2 prior to the addition of NaCl plus ATP gave a much slower rate of E-P formation (5 s-1) and resulted in an initial rapid release of Pi similar to that found in the uninhibited enzyme. The slow increase in E-P level observed after incubation with oligomycin, KCl, and MgCl2 may be due to secondary formation of an inhibition complex following rapid binding of oligomycin. In contrast to the monophasic behavior which resulted from pre-exposure to NaCl or KCl, preincubation with oligomycin in the presence of MgCl2 plus Tris or Tris alone gave a biphasic pattern of E-P formation in which about 50% of the intermediate accumulated at a rate of 56 s-1 and the remainder at a rate of 5 s-1. In addition, the Pi burst amplitude was reduced, indicating partial inhibition of the enzyme. These results suggest that in the absence of Na+ and K+ only half of the enzyme is inhibited by oligomycin while the remainder undergoes inhibition subsequent to initiation of phosphorylation. Since the oligomycin concentration was saturating, the partial inhibition reflected in the biphasic pattern of E-P formation may be due to half-of-the-sites reactivity in which only half of the subunits bind oligomycin in the absence of monovalent cations.     

Occurrence and significance of oxygen exchange reactions catalyzed by mitochondrial adenosine triphosphatase preparations.

The capacity of various ATPase preparations from beef heart mitochondria to catalyze exchange of phosphate oxygens with water has been evaluated. Oligomycin-sensitive ATPase preparations retain a capacity for considerable intermediate Pi equilibrium HOH exchange per Pi formed during ATP hydrolysis at relatively high ATP concentration (5 mM). Submitochondrial particles prepared by an ammonia-Sephadex procedure with 5 mM ATP showed more rapid ATPase, less oligomycin sensitivity, and less capacity for intermediate exchange. With these particles, intermediate Pi equilibrium HOH exchange per Pi formed was increased as ATP concentration was decreased. The purified, soluble ATPase from mitochondria catalyzed little or no intermediate Pi equilibrium HOH exchange at 5 mM ATP but showed pronounced increase in capacity for such exchange as ATP concentration was lowered. The ATPase also showed a weak catalysis of an ADP-stimulated medium Pi equilibrium HOH exchange. The results support the alternating catalytic site model for ATP synthesis or cleavage. They also demonstrate that a transmembrane protonmotive force is not necessary for oxygen exchange reactions. At lower ATP concentrations, ADP and Pi formed at a catalytic site appear to remain bound and continue to allow exchange of Pi oxygens until ATP binds at another site on the enzyme.     

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.     

Nucleotide exchange and control of ATPase activity in Rhodospirillum rubrum chromatophores

(1) Light-activated ‘dark’ ATPase in Rhodospirillum rubrum chromatophores is inhibited by preincubation with ADP or ATP (in the absence of Mg²⁺). I₅₀ values were 0.5 and 6 μM, respectively, after 20 s of preincubation. (2) In the absence of MgATP, the rate constant for dissociation of ADP or ATP from the inhibitory site was less than 0.2 min^?1 in deenergized membranes. Illumination in the absence of MgATP caused an increase of over 60-fold in both rate constants. (3) In some experiments hydrolysis was performed in the presence of 10 μM Mg²⁺ and 0.2 mM MgATP. Under these conditions, the ADP or ATP inhibition was reversed within about 20 or about 80 s, respectively, after the onset of hydrolysis. This suggests that recovery from ADP or ATP inhibition (i.e., release of tightly bound ADP or ATP) in the dark is induced by MgATP binding to a second nucleotide-binding site on the enzyme. (4) Results obtained with variable concentrations of uncoupler suggest that in the absence of bound Mg²⁺ (see below), MgATP-induced release of tightly bound ADP or ATP does not require a transmembrane . This, together with the inhibitor/substrate ratios prevalent during hydrolysis, suggests that these reactivation reactions involve MgATP binding to a high-affinity binding site (Kd < 2 μM). (5) At high concentrations of uncoupler, a time-dependent inhibition of hydrolysis occurred in the control chromatophores as well as in the nucleotide-pretreated chromatophores. This deactivation was dependent on Mg²⁺. In addition, MgATP-dependent reversal of ADP inhibition in the dark was inhibited by Mg²⁺ at concentrations above 20–30 μM. By contrast, MgATP-dependent reversal of ADP inhibition occurs within 3–4 s, despite the presence of high concentrations of Mg²⁺ if the chromatophores are illuminated during contact with the nucleotides. Uncoupler abolishes the effect of illumination. A reaction scheme incorporating these findings is proposed. (6) The implications of these findings for the mechanism of lightactivation of ATP hydrolysis (Slooten, L. and Nuyten, A., (1981) Biochim. Biophys. Acta 638, 305–312) are discussed.     

Intermediate reaction states of the red beet plasma membrane ATPase

The phosphorylation reaction for the plasma membrane ATPase of red beet (Beta vulgaris L.) was examined in order to further understand the mechanism of this enzyme. The level of steady-state phosphorylation had a pH optimum of about 6.0 while ATPase activity (32Pi production) measured under identical conditions had a pH optimum of 7.0. Phosphoenzyme decomposition was accelerated as both the pH and temperature were increased. The former effect may account for the observed difference between the pH optimum for phosphorylation and ATPase. Although the kinetics of K+ stimulation of ATP hydrolysis have been observed to be complex, the kinetics of K+ stimulation of phosphoenzyme turnover were observed to be simple Michaelis-Menten. An antagonism was observed between MgATP and K+ for the stimulation of phosphoenzyme turnover. Increased MgATP concentration reduced the degree of K+ stimulation of phosphoenzyme turnover and ATPase activity. These effects could be explained by the observation that two forms of phosphoenzyme occur during ATP hydrolysis. One form is discharged by ADP while the other form is ADP insensitive. Potassium stimulation of phosphoenzyme breakdown occurs primarily because of effects on the ADP-insensitive phosphoenzyme form. These results are consistent with a mechanism of ATP hydrolysis involving interconversions of conformational states.     

Effect of substrates and effectors on the reversible inactivation of pig spleen phosphofructokinase by adenosine triphosphate

1. To investigate the mechanism of the reversible inactivation of pig spleen phosphofructokinase by ATP, the effect of order of addition of reactants (substrates, effectors and enzyme solution) was studied by preincubating the enzyme before assay with various combinations of its substrates and effectors. 2. Preincubation of the enzyme with MgATP or ATP at pH7.0 before addition of fructose 6-phosphate caused a rapid and much greater inhibition of activity than that observed when the reaction (carried out at identical substrate concentrations) was initiated with enzyme. 3. The rapid inhibition caused by preincubation with ATP, together with the sigmoidal response to fructose 6-phosphate and activation by AMP, were all blocked by prior photo-oxidation of the enzyme with Methylene Blue, which selectively destroys the inhibitory binding site for ATP [Ahlfors & Mansour (1969) J. Biol. Chem.244, 1247-1251]. 4. Fructose 6-phosphate, but not Mg(2+), protected phosphofructokinase from inhibition during preincubation with ATP in a manner that was sigmoidally dependent on the fructose 6-phosphate concentration. 5. Mg(2+), by protecting the enzyme from the inhibitory effect of preincubation at low pH (7.0) and by preventing its activation during preincubation with fructose 6-phosphate, demonstrated both a weak activating effect in the absence of the other substrates and a stronger inhibitory effect in the presence of fructose 6-phosphate. 6. Positive effectors (K(+), NH(4) (+), AMP and aspartate) protected the enzyme from inhibition during preincubation with MgATP in proportion to their potency as activators, but citrate potentiated the ATP inhibition. P(i) significantly slowed the inactivation process without itself acting as a positive effector. 7. The non-linear dependence of the initial rate of the unmodified enzyme on protein concentration (associated with increased positive homotropic co-operativity to fructose 6-phosphate) was intensified by preincubation with ATP and abolished by photo-oxidation. 8. The results are interpreted in terms of an association-dissociation model which postulates that protonation, at low pH, of a photo-oxidation-sensitive inhibitory site for ATP allows more rapid dissociation of an active tetramer to an inactive dimeric species.     

Interactions between the mitochondrial adenosinetriphosphatase and periodate-oxidized adenosine 5'-triphosphate, an affinity label for adenosine 5'-triphosphate binding sites

Periodate-oxidized ATP (o-ATP) was prepared as an affinity label of nucleotide binding sites on the chloroform-released ox heart mitochondrial ATPase. In the presence of MgSO4, o-ATP is a substrate for the ATPase. It can act as a reversible, competitive inhibitor of ATPase activity and can also induce an irreversible inhibition of ATPase activity. In parallel with the irreversible inhibition, covalent incorporation of [3H]o-ATP occurs. ATPase has about 1.05 mol of o-ATP bound per mol of ATPase when the enzyme is 50% inhibited. Most of the covalently bound o-ATP is associated with the alpha and beta subunits and is equally distributed between them. The incorporation of o-ATP into the ATPase is reduced, and the irreversible inhibition induced by o-ATP can be prevented totally by MgADP, MgATP, EDTA/ATP, or EDTA. The location, number, and the functional significance of the o-ATP binding sites are discussed. o-ATP can decompose to form an adenosine-containing compound and the tripolyphosphate anion in a beta-elimination reaction mechanism. The structures of the adenine-containing compound and its borohydride reduction product were determined. The adenine-containing elimination product inhibited the mitochondrial ATPase activity at a rate greater than that observed with o-ATP. The nature and mechanism of the inhibition of ATPase activity exerted by o-ATP and the elimination product were examined. The significance of the beta-elimination reaction to the use of periodate-oxidized nucleotides as affinity labels of nucleotide binding sites on other proteins is discussed.     

Stimulation of rat liver mitochondrial adenosine triphosphatase by anions.

The hydrolysis of MgATP by isolated rat liver mitochondrial ATPase (EC 3.6.1.3) at pH 8.0 was stimulated by various anions. The rate of hydrolysis was increased from 18 to 170 mumol per min per mg, a 9.4-fold stimulation, by HSeO3 at 1 mM MgATP. In the absence of a stimulatory anion, reciprocal plots of initial velocity studies with MgATP as the variable substrate were curved (Hill coefficient approximately 0.5). With the addition of anion, the reciprocal plots became linear. When the substrate was MgITP or MgGTP with the isolated enzyme or MgATP with submitochondrial particles, no curvature of the reciprocal plots was observed. With purified ATPase, anions stimulated the hydrolysis of MgITP, MgGTP, MgUTP or MgCTP only slightly. With submitochondrial particles the stimulation by anions of MgATP hydrolysis was limited to approximately 2-fold. These data are interpreted to indicate the existence of two substrate sites for MgATP and an anion-binding site on the isolated enzyme.