Binding of monovalent cations to Na+,K+-dependent ATPase purified from porcine kidney. II. Acceleration of transition from a K+-bound form to a Na+-bound form by binding of ATP to a regulatory site of the enzyme

Two kinds of ATP binding sites were found to exist on the ATPase molecule. One was the catalytic site (1 mol/mol phosphorylation site) and its apparent dissociation constant for ATP was about 1 microM. The other was the regulatory site(s) and its apparent dissociation constant for ATP was equal to or higher than about 0.2 mM. The affinities of both sites for AMPPNP were three times lower than those for ATP. The affinity of the ATPase for ATP was reduced by the addition of KCl, but unaffected by the addition of NaCl. As thermodynamically expected, the affinity of the Na+-binding sites for Na+ ions was almost completely unaffected by the addition of ATP, which markedly decreased that of the K+-binding sites for K+ and Rb+ ions. In the absence of KCl, Na+ ions were bound very rapidly to the Na+-binding sites [(1979) J. Biochem. 86, 509--523]. However, Na+ ions were bound very slowly to the enzyme preincubated with 50 microM KCl, and the Na+ binding was markedly accelerated by the addition of ATP or AMPPNP at concentrations much higher than several microM. On the other hand, in the presence of 50 microM KCl, 1 mol of ATP was bound to the catalytic site with the same dissociation constant as that in the absence of KCl, and another 1 mol of ATP bound with a dissociation constant of about 0.1 mM. Therefore, we concluded that the Na+ binding to the enzyme in a K+ form is markedly accelerated by the binding at ATP to the regulatory site.     

Gastric H/K-ATPase liberates two moles of Pi from one mole of phosphoenzyme formed from a high-affinity ATP binding site and one mole of enzyme-bound ATP at the low-affinity site during cross-talk between catalytic subunits

The maximum amount of acid-stable phosphoenzyme (E32P)/mol of alpha chain of pig gastric H/K-ATPase from [gamma-32P]ATP (K(1/2) = 0.5 microM) was found to be approximately 0.5, which was half of that formed from 32P(i) (K(1/2) = 0.22 mM). The maximum 32P binding for the enzyme during turnover in the presence of [gamma-32P]ATP or [alpha-32P]ATP was due to 0.5 mol of E32P + 0.5 mol of an acid-labile enzyme-bound [gamma-32P]ATP (EATP) or 0.5 mol of an acid-labile enzyme-bound [alpha-32P]ATP, respectively. The K(1/2) for EATP formation in both cases was 0.12 approximately 0.14 mM. The turnover number of the enzyme (i.e., the H+-ATPase activity/(EP + EATP)) was very close to the apparent rate constants for EP breakdown and P(i) liberation, both of which decreased with increasing concentrations of ATP. The ratio of the amount of P(i) liberated to that of EP that disappeared increased from 1 to approximately 2 with increasing concentrations of ATP (i.e., equal amounts of EP and EATP exist, both of which release phosphate in the presence of high concentrations of ATP). This represents the first direct evidence, for the case of a P-type ATPase, in which 2 mol of P(i) liberation occurs simultaneously from 1 mol of EP for half of the enzyme molecules and 1 mol of EATP for the other half during ATP hydrolysis. Each catalytic alpha chain is involved in cross-talk, thus maintaining half-site phosphorylation and half-site ATP binding which are induced by high- and low-affinity ATP binding, respectively, in the presence of Mg2+.     

Chemical modification of thiol groups of mitochondrial F1-ATPase from the yeast Schizosaccharomyces pombe. Involvement of alpha- and gamma-subunits in the enzyme activity

Mitochondrial F1-ATPase from the yeast Schizosaccharomyces pombe has been prepared under a stable form and in relatively high amounts by an improved purification procedure. Specific chemical modification of the enzyme by the thiol reagent N-ethylmaleimide (NEM) at pH 6.8 leads to complete inactivation characterized by complex kinetics and pH dependence, indicating that several thiols are related to the enzyme activity. A complete protection against NEM effect is afforded by low concentrations of nucleotides in the presence of Mg2+, with ADP and ATP being more efficient than GTP. A total binding of 5 mol of [14C]NEM/mol of F1-ATPase is obtained when the enzyme is 85% inactivated: 3 mol of the label are located on the alpha-subunits and 2 on the gamma-subunit. Two out of the 3 mol on the alpha-subunits bind very rapidly before any inactivation occurs, indicating that the two thiols modified are unrelated to the inactivation process. Complete protection by ATP against inactivation by NEM prevents the modification of three essential thiols out of the group of five thiols labeled in the absence of ATP: one is located on a alpha-subunit and two on the gamma-subunit. These two essential thiols of the gamma-subunit can be differentiated by modification with 6,6'-dithiodinicotinic acid (CPDS), another specific thiol reagent. A maximal binding of 4 mol of [14C]CPDS/mol of enzyme is obtained, concomitant to a 25% inhibition. Sequential modification of the enzyme by CPDS and [14C]NEM leads to the same final deep inactivation as that obtained with [14C]NEM alone. One out of the two thiols of the gamma-subunit is no longer accessible to [14C]NEM after CPDS treatment. When incubated at pH 6.8 with [3H]ATP in the presence of Mg2+, F1-ATPase is able to bind 3, largely exchangeable, mol of nucleotide/mol of enzyme. Modification of the three essential thiols by NEM dramatically decreases the binding of 3H-nucleotide down to about 1 mol/mol of enzyme. Partial modification modifies the cooperative properties, the enzyme being no longer sensitive to anion activation.     

The molecular weight and thiol residues of acetyl-coenzyme A synthetase from ox heart mitochondria

1. A constant molecular weight of 57000 was obtained by gel filtration of highly purified acetyl-CoA synthetase over a 1000-fold range of enzyme concentrations. The amino acid analysis is reported. 2. With native enzyme at 20 degrees C the relatively rapid reaction of four thiol residues with p-hydroxymercuribenzoate caused an immediate inhibition reversible by either CoA or mercaptoethanol. Other substrates did not protect against this rapid inhibition. 3. The much slower reaction of the remaining four thiol residues was independent of the concentration of the mercurial, first-order with respect to enzyme, and had a large energy of activation (+136kJ/mol), suggesting that a conformation change in the protein was rate-limiting. This slow phase of the reaction was accompanied by an irreversible inactivation of the enzyme. 4. The effects of substrates on this irreversible inactivation at pH7.0 in 5 mm-MgCl(2) indicated strong binding of ATP and pyrophosphate by the enzyme (concentrations for half-maximal effects, K((1/2)), were <30mum and <10mum respectively) and weaker binding of acetyl-CoA (K((1/2)) about 1 mm), AMP (K((1/2)) about 2mm) and acetate. In the presence of acetate, MgCl(2) and p-hydroxymercuribenzoate, titration of the enzyme with ATP revealed at least two ATP binding sites/mol. 5. The experiments suggest that reaction of the thiol residues with mercurial causes loss of enzymic activity by altering the structure of the enzyme, rather than that the thiol residues play a direct role in the catalysis.     

Adenine nucleotides as allosteric effectors of pea seed glutamine synthetase

The effects of adenine nucleotides on pea seed glutamine synthetase (EC 6.3.1.2) activity were examined as a part of our investigation of the regulation of this octameric plant enzyme. Saturation curves for glutamine synthetase activity versus ATP with ADP as the changing fixed inhibitor were not hyperbolic; greater apparent Vmax values were observed in the presence of added ADP than the Vmax observed in the absence of ADP. Hill plots of data with ADP present curved upward and crossed the plot with no added ADP. The stoichiometry of adenine nucleotide binding to glutamine synthetase was examined. Two molecules of [gamma-32P]ATP were bound per subunit in the presence of methionine sulfoximine. These ATP molecules were bound at an allosteric site and at the active site. One molecule of either [gamma-32P]ATP or [14C]ADP bound per subunit in the absence of methionine sulfoximine; this nucleotide was bound at an allosteric site. ADP and ATP compete for binding at the allosteric site, although ADP was preferred. ADP binding to the allosteric site proceeded in two kinetic phases. A Vmax value of 1.55 units/mg was measured for glutamine synthetase with one ADP tightly bound per enzyme subunit; a Vmax value of 0.8 unit/mg was measured for enzyme with no adenine nucleotide bound at the allosteric site. The enzyme activation caused by the binding of ADP to the allosteric sites was preceded by a lag phase, the length of which was dependent on the ADP concentration. Enzyme incubated in 10 mM ADP bound approximately 4 mol of ADP/mol of native enzyme before activation was observed; the activation was complete when 7-8 mol of ADP were bound per mol of the octameric, native enzyme. The Km for ATP (2 mM) was not changed by ADP binding to the allosteric sites. ADP was a simple competitive inhibitor (Ki = 0.05 mM) of ATP for glutamine synthetase with eight molecules of ADP tightly bound to the allosteric sites of the octamer. Binding of ATP to the allosteric sites led to marked inhibition.     

Pre-steady-state studies of the adenosine triphosphatase activity of coupled submitochondrial particles. Regulation by ADP

ATPase activities were measured in 10 mM MgCl2, 5 mM ATP, 1 mM ADP, and 1 microM FCCP with submitochondrial particles from bovine heart that had been stimulated by delta mu H+-forming substrates and with particles whose natural inhibitor protein was partially removed by heating. The activities were not linear with time. With both particles, the rate of ATP hydrolysis in the 7-fold greater than that in the steady state. Pre-steady-state and steady-state kinetic studies showed that the decrease of ATPase activity was due to the binding of ADP in a high-affinity site of the enzyme (K0.5 of 10 microM). Inhibition of ATP hydrolysis was accompanied by the binding of approximately 1 mol of ADP/mol of particulate F1; 10 microM ADP gave half-maximal binding. ADP could be replaced by IDP, but with an affinity 50-fold lower (K0.5 of 0.5 mM). Maximal inhibition by ADP and IDP was achieved in less than 5 s. Inhibition was enhanced by uncouplers. Even in the presence of pyruvate kinase and phosphoenolpyruvate, the rates of hydrolysis were about 2.5-fold higher in the first seconds of reaction than in the steady state. This decrease of ATPase activity also correlated with the binding of nearly 1 mol of ADP/mol of F1. This inhibitory ADP remained bound to the enzyme after several thousand turnovers. Apparently, it is possible to observe maximal rates of hydrolysis only in the first few catalytic cycles of the enzyme.     

Negative homotropic cooperativity in rat muscle AMP deaminase. A kinetic study on the inhibition of the enzyme by ATP

1. Rat skeletal muscle AMP deaminase (AMP aminohydrolase, EC 3.5.4.6) at optimal KCl concentrations shows a biphasic response to increasing levels of the allosteric inhibitor ATP. 2. Up to 10 micrometer, ATP appears to convert the enzyme to a form exhibiting sigmoidal kinetics while at higher concentrations its inhibitory effect is manifested by an alteration of AMP binding to AMP deaminase indicative of negative homotropic cooperativity at about 50% saturation. 3. AMP deaminase is inactivated by incubation with the periodate oxidation product of ATP. The (oxidized ATP)--AMP deaminase complex stabilized by NaBH4 reduction shows kinetic properties similar to those of the native enzyme in the presence of high ATP concentrations. 4. A plausible explanation of the observed cooperativity is that ATP induces different conformational state of AMP deaminase subunits, causing the substrate to follow a sequential mechanism of binding to enzyme. 5. Binding of the radioactive oxidized ATP shows that 3.2 mol of this reagent bind per mol AMP deaminase.     

A comparative study of essential arginine residues in Gramicidin S synthetase 2 and isoleucyl tRNA synthetase

In gramicidin S synthetase 2 (GS 2) from Bacillus brevis, L-proline, L-valine, L-ornithine, and L-leucine activations to aminoacyl adenylates are progressively inhibited by phenylglyoxal. The inactivation of GS 2 obeys pseudo-first-order kinetics. ATP completely prevents inactivation of GS 2 by phenylglyoxal, whereas amino acids only partially prevent it. In the presence of ATP, four arginine residues per mol of GS 2 are protected from modification by phenylglyoxal as determined by amino acid analysis and the incorporation of [7-14C]phenylgloxal into the enzyme protein, indicating that a single arginine residue is necessary for each amino acid activation. In isoleucyl tRNA synthetase from Escherichia coli, phenylglyoxal inhibits activation of L-isoleucine to isoleucyl adenylate. ATP completely prevents inactivation, although isoleucine only partially prevents it. One arginine residue of isoleucyl tRNA synthetase is protected by ATP from modification by phenylglyoxal, suggesting that a single arginine residue is essential for isoleucine activation. These results support the involvement of arginine residues in ATP binding with GS 2 or isoleucyl tRNA synthetase, and thus indicate that arginine residues of amino acid activating enzymes are essential for the formation of aminoacyl adenylates in both nonribosomal and ribosomal peptide biosynthesis.     

The binding of a K+ competitive ligand, 2-methyl,8-(phenylmethoxy)imidazo(1,2-a)pyridine 3-acetonitrile, to the gastric (H+ + K+)-ATPase

2-Methyl,8-(phenylmethoxy)imidazo(1,2-a)pyridine 3-acetonitrile (SCH 28080) is a freely reversible K+ site inhibitor of the gastric (H+ + K+)-ATPase. In the presence of 2 mMMgSO4, [14C]SCH 28080 bound saturably to gastric vesicle preparations containing the (H+ + K+)-ATPase and was displaced by lumenal K+. A binding stoichiometry of 2.2 +/- 0.1 mol of SCH 28080/mol of catalytic phosphorylation sites was observed. The affinity of SCH 28080 binding was increased approximately 10-fold (to 45 nM) in the presence of 2 mM ATP. High affinity binding also occurred with 2 microM ATP but not with up to 200 microM D-[beta, gamma-CH2]ATP, suggesting that high affinity binding was to a phosphorylated form of the enzyme. In the presence of ATP, the association rate constant was linearly related to the concentration of SCH 28080. However, the association and dissociation rates of SCH 28080 binding were slow, especially at low temperature (at 1.5 degrees C half-maximal binding of 50 nM SCH 28080 was calculated to occur after 232 s). Binding appeared to be predominantly entropy driven with a high activation energy (40 kJ/mol at 37 degrees C). In the absence of ATP, the association rate constant was not linearly related to the concentration of SCH 28080, suggesting that a conformational change in the enzyme was required before binding could occur.     

Histidyl transfer ribonucleic acid synthetase from Salmonella typhimurium. Interaction with substrates and ATP analogues.

Structural requirements for substrate binding to histidyl-tRNA synthetase from Salmonella typhimurium have been investigated using ATP analogues. Ki values and the relative binding affinity of the enzyme for these analogues have been determined in the tRNA aminoacylation reaction. The enzyme is highly specific for ATP: no binding was found for GTP, CTP, TTP and UTP. dATP is a very poor substrate for acylation of tRNA, with a Km 40-fold higher than that of ATP. Binding of adenosine 5'-triphosphate requires interactions of the amino group of adenosine and the sugar moiety; the 2' and the 5' positions of the ribose appear to be essential for recognition; the phosphate groups enhance the binding. AMP is a noncompetitive inhibitor with ATP. The interaction of histidyl-tRNA synthetase, a dimeric enzyme, with histidine and ATP was examined by fluorescence measurements at equilibrium and by equilibrium dialysis. Binding with L-histidine is significantly tighter at pH 6 than at pH 7, while the ATP binding is independent of pH. The stoichiometry was measured at pH 6 than at pH 7, while the ATP binding is independent of pH. The stoichiometry was measured at pH 7.5 by equilibrium dialysis and is 1 mol ATP/mol enzyme and, variably, close to 2 or 1 mol histidine/mol enzyme.     

Escherichia coli F1-ATPase can use GTP-nonchaseable bound adenine nucleotide to synthesize ATP in dimethyl sulfoxide.

Escherichia coli F1-ATPase contained 3 mol of tightly-bound adenine nucleotide/mol enzyme. A further 3 mol could be loaded by incubation of the enzyme with ATP. The unloaded enzyme was designated as a F1[2,1] type on the basis of the ability of GTP to displace 1 mol of adenine nucleotide/mol of F1 [Kironde, F.A.S., & Cross, R.L. (1986) J. Biol. Chem. 261, 12544-12549]. The loaded enzyme was designated F1[3,3] since GTP could displace 3 of the 6 mol of bound adenine nucleotide/mol of F1. Incubation of F1[2,1], F1[2,0], and F1[3,0] with phosphate in the presence of 30% (v/v) dimethyl sulfoxide led to the synthesis of ATP from endogenous bound ADP. Hydrolysis of newly synthesized ATP occurred on transfer of the F1 from 30% (v/v) dimethyl sulfoxide to an entirely aqueous medium. Thus, synthesis and hydrolysis of ATP can occur at GTP-nonchaseable adenine nucleotide binding sites, and these sites in dimethyl sulfoxide are not necessarily equivalent to noncatalytic sites.     

Mechanism of carbamoyl-phosphate synthetase. Properties of the two binding sites for ATP.

Carbamoyl phosphate synthethase I synthesizes carbamoyl phosphate from ammonia, HCO3- and two molecules of ATP, one of which, ATPA, yields Pi while the other, ATPB, yields the phosphoryl group of carbamoyl phosphate. Pulse-chase experiments with [gamma-32P]ATP without added HCO3- demonstrate separate binding sites for ATPA and ATPB. Bound ATPA dissociates readily from its site (t1/2 approximately 1--2 s) and the Kd is 0.2--0.7 mM. For the ATPB binding site the t1/2 for dissociation is 5--12 s and the Kd approximately 10 mM. Kd for ATPA seems to increase with enzyme concentration whereas Kd for ATPB does not change. HClO4 releases the ATP unchanged from the enzyme . ATPB and enzyme . ATPB . ATPA complexes. In the presence of HCO3-, ATP and N-acetylglutamate, an enzyme . ATPB . HCO3- . ATPA complex is formed. Its formation by the addition of HCO3- to the enzyme . ATPB . ATPA complex appears to involve an initial bimolecular addition reaction followed by an isomerization. Treatment with HClO4 releases Pi from ATPA but ATPB is released unchanged. Spontaneous hydrolysis of ATPA is responsible for the ATPase activity of the enzyme. Thus, a covalent bond may form between HCO3- and ATPA. However, ATPA can dissociate rapidly (t1/2 less than 10 s). The Kd for ATPA is approximately 0.2 mM. ATPB appears unable to dissociate from the enzyme . ATPB . HCO3- . ATPA complex since the t1/2 for dissociation of ATPB from the enzyme is lengthened about five times in the presence of 19 mM HCO3- and at 1 mM ATP. ATPA may also hydrolyse in this complex and be replaced by another molecule of ATP in the absence of exchange of ATPB. However, the ATPA binding site must be occupied to prevent ATPB release. ATPB may be bound in a pocket which becomes inaccessible to the solution when HCO3- and ATPA also bind. In contrast, HCO3- does not inhibit the binding of ATPB to the enzyme. Various intermediate steps in the formation of the enzyme . ATPb . HCO3- . ATPA complex are discussed. Additional evidence is presented that the ATPB binding site is only periodically accessible to ATP in solution and that ATPB in the steady-state reaction binds when the products leave. Since greater than 1.3 mol ATPB and greater than 1.8 mol ATPA bind/mol enzyme dimer, the enzyme monomer may be an active species.     

Growth of Methanosarcina barkeri (Fusaro) under nonmethanogenic conditions by the fermentation of pyruvate to acetate: ATP synthesis via the mechanism of substrate level phosphorylation.

A mutant of Methanosarcina barkeri (Fusaro) is able to grow on pyruvate as the sole carbon and energy source. During growth, pyruvate is converted to CH4 and CO2, and about 1.5 mol of ATP per mol of CH4 is formed (A.-K. Bock, A. Prieger-Kraft, and P. Schönheit, Arch. Microbiol. 161:33-46, 1994). The pyruvate-utilizing mutant of M. barkeri could also grow on pyruvate when methanogenesis was completely inhibited by bromoethanesulfonate (BES). The mutant grew on pyruvate (80 mM) in the presence of 2 mM BES with a doubling time of about 30 h up to cell densities of about 400 mg (dry weight) of cells per liter. During growth on pyruvate, the major fermentation products were acetate and CO2 (about 0.9 mol each per mol of pyruvate). Small amounts of acetoin, acetolactate, alanine, leucine, isoleucine, and valine were also detected. CH4 was not formed. The molar growth yield (Yacetate) was about 9 g of cells (dry weight) per mol of acetate, indicating an ATP yield of about 1 mol/mol of acetate formed. Growth on pyruvate in the presence of BES was limited; after six to eight generations, the doubling times increased and the final cell densities decreased. After 9 to 11 generations, growth stopped completely. In the presence of BES, suspensions of pyruvate-grown cells fermented pyruvate to acetate, CO2, and H2. CH4 was not formed. Conversion of pyruvate to acetate, in the complete absence of methanogenesis, was coupled to ATP synthesis. Dicyclohexylcarbodiimide, an inhibitor of H(+)-translocating ATP synthase, did not inhibit ATP formation. In the presence of dicyclohexylcarbodiimide, stoichiometries of up to 0.9 mol of ATP per mol of acetate were observed. The uncoupler arsenate completely inhibited ATP synthesis, while the rates of acetate, CO2, and H2 formation were stimulated up to fourfold. Cell extracts of M. barkeri grown on pyruvate under nonmethenogenic conditions contained pyruvate: ferredoxin oxidoreductase (0.5 U/mg), phosphate acetyltransferase (12 U/mg), and acetate kinase (12 U/mg). From these data it is concluded that ATP was synthesized by substrate level phosphorylation during growth of the M. barkeri mutant on pyruvate in the absence of methanogenesis. This is the first report of growth of a methanogen under nonmethanogenic conditions at the expense of a fermentative energy metabolism.     

The synthesis of enzyme-bound ATP by the F1-ATPase from the thermophilic bacterium PS3 in 50% dimethylsulfoxide

Purified TF1 (F1-ATPase from a thermophilic bacterium PS3) synthesizes enzyme-bound ATP from medium Pi and enzyme-bound ADP in the presence of 50% dimethylsulfoxide (DMSO). Once ATP was formed on the enzyme, it was not released even after removal of DMSO and Pi from the solution. The half maximal concentration of medium Pi for ATP synthesis was 1mM. The pH optimum for enzyme-bound ATP formation was about 6.5. Under the optimum conditions, a yield of up to 0.8 mol of ATP/mol of TF1 was obtained.     

cGMP-dependent protein kinase. Autophosphorylation changes the characteristics of binding site 1

cGMP-dependent protein kinase binds 4 mol cGMP/mol enzyme to two different sites. Binding to site 1 (apparent Kd 17 nM) shows positive cooperativity and is inhibited by Mg . ATP, whereas binding to site 2 (apparent Kd 100-150 nM) is non-cooperative and not affected by Mg . ATP. Autophosphorylation of the enzyme abolishes the cooperative binding to site 1 and the inhibitory effect of Mg . ATP. The association (K1) and dissociation (K-1) rate constant for site 2 and K1 for site 1 are not affected significantly by Mg . ATP or autophosphorylation. The dissociation rate from site 1 measured in the presence of 1 mM unlabelled cGMP is decreased threefold and over tenfold by Mg . ATP and autophosphorylation, respectively. In contrast, the dissociation rate from site 1 measured after a 500-fold dilution of the enzyme-ligand complex is 100-fold faster than that determined in the presence of 1 mM cGMP and is only slightly influenced by Mg . ATP or autophosphorylation. Only Kd values calculated with the latter K-1 values are similar to the Kd values obtained by equilibrium binding. These results suggest that autophosphorylation of cGMP-dependent protein kinase affects mainly the binding characteristics of site 1.     

Acid-labile ATP and/or ADP/P(i) binding to the tetraprotomeric form of Na/K-ATPase accompanying catalytic phosphorylation-dephosphorylation cycle.

The Na/K-ATPase has been shown to bind 1 and 0.5 mol of (32)P/mol of alpha-chain in the presence [gamma-(32)P]ATP and [alpha-(32)P]ATP, respectively, accompanied by a maximum accumulation of 0.5 mol of ADP-sensitive phosphoenzyme (NaE1P) and potassium-sensitive phosphoenzyme (E2P). The former accumulation was followed by the slow constant liberation of P(i), but the latter was accompanied with a rapid approximately 0.25 mol of acid-labile P(i) burst. The rubidium (potassium congener)-occluded enzyme (approximately 1.7 mol of rubidium/mol of alpha-chain) completely lost rubidium on the addition of sodium + magnesium. Further addition of approximately 100 microM [gamma-(32)P]ATP and [alpha-(32)P]ATP, both induced 0.5 mol of (32)P-ATP binding to the enzyme and caused accumulation of approximately 1 mol of rubidium/mol of alpha-chain, accompanied by a rapid approximately 0.5 mol of P(i) burst with no detectable phosphoenzyme under steady state conditions. Electron microscopy of rotary-shadowed soluble and membrane-bound Na/K-ATPases and an antibody-Na/K-ATPase complex, indicated the presence of tetraprotomeric structures (alphabeta)(4). These and other data suggest that Na/K-ATP hydrolysis occurs via four parallel paths, the sequential appearance of (NaE1P:E.ATP)(2), (E2P:E.ATP:E2P:E. ADP/P(i)), and (KE2:E.ADP/P(i))(2), each of which has been previously referred to as NaE1P, E2P, and KE2, respectively.     

Stoichiometric photolabeling of two distinct low and high affinity nucleotide sites in sarcoplasmic reticulum ATPase

Highly purified 3'-arylazido-ATP (aATP) was obtained by high performance liquid chromatography. In the dark, this photoactivatable ATP analog was a competitive inhibitor of ATP hydrolysis catalyzed by purified sarcoplasmic reticulum (SR) ATPase with a Ki of 10 microM. The analog itself was hydrolyzed by the enzyme in the dark. A biphasic curve of velocity of hydrolysis of the analog versus aATP concentration was obtained, indicating the presence of high and low affinity sites with K0.5 of approximately 10 microM and 300 microM, respectively. Upon irradiation with visible light, a biphasic curve was obtained for the level of covalent photolabeling of the enzyme versus [beta-32P]aATP concentrations. Levels of 6.5-9 nmol of analog/mg of protein and 20-22 nmol of analog/mg of protein were obtained when labeling with 20-30 or with 400 microM aATP, respectively, showing the existence of 1 mol of high affinity sites/mol of ATPase and 1-1.5 mol of low affinity sites/mol of enzyme. The rate of light-dependent incorporation of [beta-32P]aATP was decreased by the presence of ATP, Pi, 2',3'-O-(2,4,6-trinitrocyclohexadienylidene-ATP, or Ca2+ in the illumination media. Photolabeling of the high affinity sites had little effect on the velocity of ATP hydrolysis but significantly inhibited the splitting of additional aATP added in the dark. Photolabeling the low affinity sites caused irreversible inhibition of the ATPase activity. The inhibition was prevented by having ATP in the illumination medium, which protected it from labeling. Gel filtration chromatography in the presence of detergent showed that radioactive photolabel was incorporated in the SR ATPase protein. The results indicate that aATP is a useful tool for stoichiometrically labeling and probing the nucleotide binding domains of the SR ATPase.     

Amount and turnover rate of the F0F1-ATPase and the stoichiometry of its inhibition by oligomycin in Rhodospirillum rubrum chromatophores

The amount of F1-ATPase in chromatophores from Rhodospirillum rubrum was determined by Western blotting using anti-RrF1 rabbit antibodies. 9.1 mmol F1 (mol bacteriochlorophyll)-1 was obtained or 14% of the total protein content of the chromatophores. The turnover rate of the F0F1-ATPase was 17 molecules ATP s-1 during synthesis, 2 molecules ATP s-1 during hydrolysis under coupled conditions with Mg2+ as the divalent cation, and 7 molecules ATP s-1 during hydrolysis in the presence of carbonyl cyanide p-trifluoromethoxyphenylhydrazone. Binding of 1 mol oligomycin/mol F0F1-ATPase was found to inhibit the activities of the enzyme completely. A single binding site was found with a Kd of approximately 2 microM.     

A calorimetric study of the interaction of ATP with rabbit muscle phosphofructokinase.

The heat of interaction of ATP with phosphofructokinase from rabbit muscle was determined at 25 degrees C in 0.1 M potassium phosphate, pH 7.0 and 8.0. The limiting value of the enthalpy change at high ATP concentrations was found to be -11.5 kcal mol of enzyme polypeptide chains. Since phosphate and imidazole have very different heats of ionization (+0.8 and +7.5 kcal/mol, respectively), this suggests that the binding of at least two protons to the enzyme occurs concomitantly with the binding of ATP at the regulatory site.     

Thermodynamics of active-site ligand binding to Escherichia coli glutamine synthetase

Active-site ligand interactions with dodecameric glutamine synthetase from Escherichia coli have been studied by calorimetry and fluorometry using the nonhydrolyzable ATP analogue 5'-adenylyl imidodiphosphate (AMP-PNP), L-glutamate, L-Met-(S)-sulfoximine, and the transition-state analogue L-Met-(S)-sulfoximine phosphate. Measurements were made with the unadenylylated enzyme at pH 7.1 in the presence of 100 mM KCl and 1.0 mM MnCl2, under which conditions the two catalytically essential metal ion sites per subunit are occupied and the stoichiometry of active-site ligand binding is equal to 1.0 equiv/subunit. Thermodynamic linkage functions indicate that there is strong synergism between the binding of AMP-PNP and L-Met-(S)-sulfoximine (delta delta G' = -6.4 kJ/mol). In contrast, there is a small antagonistic effect between the binding of AMP-PNP and L-glutamate (delta delta G' = +1.4 kJ/mol). Proton effects were negligible (less than or equal to 0.2 equiv of H+ release or uptake/mol) for the different binding reactions. The binding of AMP-PNP (or ATP) to the enzyme is entropically controlled at 303 K with delta H = +5.4 kJ/mol and delta S = +150 J/(K.mol). At 303 K, the binding of L-glutamate (delta H = -22.2 kJ/mol) or L-Met-(S)-sulfoximine [delta H = -45.6 kJ/mol with delta Cp approximately equal to -670 +/- 420 J/(K.mol)] to the AMP-PNP.Mn.enzyme complex is enthalpically controlled with opposing delta S values of -29 or -46 J/(K.mol), respectively. The overall enthalpy change is negative and the overall entropy change is positive for the simultaneous binding of AMP-PNP and L-glutamate or of AMP-PNP and L-Met-(S)-sulfoximine to the enzyme. For the binding of the transition-state analogue L-Met-(S)-sulfoximine phosphate (which inactivates the enzyme by blocking active sites), both enthalpic and entropic contributions also are favorable at 303 K [delta G' approximately equal to -109 and delta H = -54.8 kJ/mol of subunit and delta S approximately equal to +180 J/(K.mol)].