Formation of ATP by the adenosine triphosphatase complex from spinach chloroplasts reconstituted together with bacteriorhodopsin

The energy-linked ATPase complex has been isolated from spinach chloroplasts. This protein complex contained all the subunits of the chloroplast coupling factor (CF₁) as well as several hydrophobic components. When the activated complex was reconstituted with added soybean phospholipids, it catalyzed the exchange of radioactive inorganic phosphate with ATP. Sonication of the complex into proteoliposomes together with bacteriorhodopsin yielded vesicles that catalyzed light-dependent ATP formation. Both the ³²P_i-ATP exchange reactions and ATP formation were sensitive to uncouplers such as 3-tert-butyl-5,2′-dichloro-4′-nitrosalicylanilide, bis-(hexafluoroacetonyl)acetone and carbonyl cyanide-p-trifluoromethoxyphenyl-hydrazone, that act to dissipate a proton gradient. The energy transfer inhibitors dicyclohexylcarbodiimide, triphenyltin chloride and 2-β-d-glucopyranosyl-4,6′-dihydroxydihydrochalcone were also effective inhibitors of both reactions.     

Purification and reconstitution of the N,N'-dicyclohexylcarbodiimide-sensitive ATPase complex from spinach chloroplasts.

The dicyclohexylcarbodiimide-sensitive ATPase from spinach chloroplast has been isolated. On sodium dodecyl sulfate gels, seven different polypeptides were seen. Five of these polypeptides coincided with the CF1 subunits, a 7,500-dalton peptide was identified as the proteolipid which interacts with [14C]dicyclohexylcarbodiimide, and there was a 15,500-dalton hydrophobic polypeptide with unknown function. In two-dimentional gels, two additional peptides were resolved, one 17,500 daltons (co-migrating in sodium dodecyl sulfate gels with subunit delta) and one 13,500 daltons (co-migrating with subunit epsilon). Reconstitution was obtained by freezing and thawing the complex with a crude mixture of phospholipids. After reconstitution the complex catalyzed 32P1-ATP exchange (rates of 200 to 400 nmoles x mg-1 x min-1) and ATP formation during acid-to-base transition. These reactions were inhibited by dicyclohexylcarbodiimide and uncouplers. Uncouplers at low concentrations stimulated and at high concentrations inhibited the Mg2+-ATPase activity. ATP hydrolysis and 32P1-ATP exchange were catalyzed by the complex in the presence of either Mg2+ or Mn2+ but not with Ca2+ or Co2+. ATP and GTP were substrates for the exchange reaction but not ADP or CTP.     

Purification of wheat germ RNA ligase. II. Mechanism of action of wheat germ RNA ligase

The mechanism of action of purified wheat germ RNA ligase has been examined. ATP was absolutely required for the ligation of substrates containing 5'-OH or 5'-P and 2',3'-cyclic P or 2'-P termini. Ligation of 1 mol of 5'-P-2',3'-cyclic P-terminated poly(A) was accompanied by the hydrolysis of 1 mol of ATP to 1 mol each of AMP and PPi. Purified RNA ligase catalyzed an ATP-PPi exchange reaction, specific for ATP and dATP, and formed a covalent enzyme-adenylate complex that was detected by autoradiography following incubation with [alpha-32P]ATP and separation of the products by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A protein doublet with a molecular weight of approximately 110 kDa, the major product detected by silver staining, was labeled in these reactions. Isolated E-AMP complex was dissociated by the addition of ligatable poly(A), containing 5'-P-2',3'-cyclic P termini, to yield AMP and by the addition of PPi to yield ATP. The unique feature of the reactions leading to an exchange reaction between ATP and PPi and to the formation of an E-AMP complex was their marked stimulation (up to 400-fold) by the addition of RNA. This property distinguishes the wheat germ RNA ligase from other known RNA and DNA ligases which catalyze ATP-PPi exchange reactions and form E-AMP complexes in the absence of substrate. Thus, RNA appears to function in two capacities in the wheat germ system: as a cofactor, to stimulate the reaction of the enzyme with ATP, and as an authentic substrate for ligation.     

Mechanisms by which reactions catalyzed by chloroplast coupling factor 1 are inhibited: ATP synthesis and ATP-H2O oxygen exchange

The ATP-H2O back-exchange reaction catalyzed by membrane-bound chloroplast coupling factor 1 (CF1) in the light is known to be extensive; each reacting ATP molecule nearly equilibrates its gamma-PO3 oxygens with H2O before it dissociates from the enzyme. Pi, ASi, ADP, and GDP, alternate substrates of photophosphorylation, each inhibit the exchange reaction. At all concentrations of these substrate/inhibitor molecules tested, the high extent of exchange per molecule of ATP that reacts remains the same, while the number of ATP molecules experiencing exchange decreases. Thus, these inhibitors appear to act in a competitive-type manner, decreasing ATP turnover, as opposed to modulating the rate constants responsible for the partitioning of E X ATP during the exchange reaction. This is consistent with the identity of CF1 catalytic sites for ATP-H2O back-exchange and ATP synthesis. Carbonyl cyanide m-chlorophenylhydrazone and NH4Cl (uncouplers of photophosphorylation) and phloridzin (an energy-transfer inhibitor) also lower the rate of ATP-H2O back-exchange; they too are found to act by decreasing the turnover of the ATP pool, not the extent of exchange per reacting ATP molecule. The extent of ATP-H2O forward oxygen exchange, which occurs during net ATP synthesis prior to product dissociation, is unaffected by uncouplers, whether catalyzed by native CF1 (ATPase latent) or the dithiothreitol/light-activated ATPase form. The mode of NH4Cl inhibition of the ATP synthesis reaction, therefore, is not through a change in the partitioning of the E X ATP complex.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sheep kidney pyruvate carboxylase. Studies on the coupling of adenosine triphosphate hydrolysis and CO2 fixation.

Initial velocity and isotope exchange studies confirmed that the over-all reaction, like that catalyzed by pyruvate carboxylase purified from rat liver and chicken liver, was a nonclassical Ping Pong Bi Bi Uni Uni sequence with ATP and HCO3-binding randomly in the Bi Bi partial reaction. Three possible mechanisms for the coupling of ATP hydrolysis and CO2 fixation are considered: (i) Mechanism i, a concerted mechanism without the formation of a kinetically significant or detectable intermediate; (ii) Mechanism ii, activation of the enzyme by ATP to form an activated phosphoenzyme complex which can react with HCO3- by formation of a phosphorylated intermediate. On the basis of other evidence, an activated intermediate containing the ADP moiety was considered improbable. Evidence is presented which indicates that an isotopic exchange between ATP and ADP in the absence of added orthophosphate is not a property of the sheep kidney enzyme. This observation removed the need to postulate either that this exchange is an abortive reaction, or that there is a compulsory formation of a phosphoenzyme intermediate. Two analogues of ADP, alpha,beta-methylene adenosine diphosphate, and adenosine 5'-phosphosulfate, have been used to provide further evidence against Mechanism ii. Both compounds were competitive inhibitors with respect to MgATP2- (Ki values respectively, 0.58 mM and 3.0 mM, compared with 0.17 mM for ADP), but neither could be phosphorylated by the enzyme. Neither analogue could replace ADP in the HCO3-: oxalacetate isotopic exchange reaction, indicating that phosphorylation of ADP is necessary for this exchange to occur, and that Mechanism ii is not applicable. Since Mechanism iii involves formation of a carbonly phosphate intermediate, analogues of this compound, namely, carbamyl phosphate and phosphonacetic acid were used to examine this pathway. The fact that the enzyme catalyzed the synthesis of ATP from ADP and carbamyl phosphate, and that phosphonacetic acid was a noncompetitive inhibitor with respect to MgATP2- (Ki = 0.5 mM) provides strong evidence that a carbonyl phosphate derivative is involved in the reaction mechanism. However, we have not found from initial velocity studies evidence for the formation of this intermediate, and it may therefore have only a transient existence in an essentially concerted reaction.     

The interaction between the archaeal elongation factor 1alpha and its nucleotide exchange factor 1beta.

In Sulfolobus solfataricus the binding of the exchange factor 1beta (SsEF-1beta) to SsEF-1alpha-GDP displaces the nucleotide and the SsEF-1alpha-SsEF-1beta complex is formed. The complex itself is stable, but it dissociates upon the addition of GDP or Gpp(NH)p but not ATP. Since the rate of the formation of the SsEF-1alpha-SsEF-1beta complex is significatively slower than the rate of the nucleotide exchange catalyzed by SsEF-1beta it can be inferred that in vivo the GDP/GTP exchange reaction proceeds via an SsEF-1alpha-SsEF-1beta interaction without involving the formation of a stable binary complex as an intermediate.     

ATP-dependent reactions catalyzed by inner membrane vesicles of rat liver mitochondria. Kinetics, substrate specificity, and bicarbonate sensitivity.

Three ATP-dependent reactions catalyzed by the inner membrane of rat liver mitochondria and the ATPase reaction catalyzed by purified mitochondrial ATPase (F1), were studied with respect to kinetic properties, substrates specificity, and sensitivity to bicarbonate. The ATP-dependent transhydrogenase reaction (reduction of NADP+ by NADH) catalyzed by inner membrane vesicles displays typical Michaelis-Menten kinetics in both Tris-Cl and Tris-bicarbonate buffers, with Km (ATP) values of 0.035 mM and 0.054 mM respectively. The Vmax of transhydrogenase activity (25 nmol min-1 mg-1) is the same in Tris-bicarbonate or Tris-Cl buffer. ITP and GTP readily substitute for ATP in the transhydrogenase reaction. The ATP-P1 exchange reaction catalyzed by inner membrane vesicles displays typical Michaelis-Menten kinetics in both Tris-Cl and Tris-bicarbonate buffers with Km (ATP) values of 1.0 mM and 1.4 mM respectively. The Vmax of exchange (200 nmol min-1 mg-1) is the same in either buffer. ITP and GTP do not effectively replace ATP in the exchange reaction.     

Microtubules accelerate ADP release by dynein

The effects of microtubules on the phosphate-water oxygen exchange reactions catalyzed by dynein were examined in order to determine the mechanism by which microtubules activate the ATPase. Microtubules inhibited the rate of medium exchange observed during net ATP hydrolysis. Inhibition of the exchange reaction was proportional to the extent of microtubule activation of ATP turnover with no effect on the partition coefficient. These data argue that microtubules do not increase the rate of release of phosphate from dynein; rather, they increase the rate of ADP release. Microtubules markedly inhibited medium phosphate-water exchange reactions observed in the presence of ADP and Pi. With increasing concentrations of ADP, the rate of exchange increased in parallel to the dissociation of dynein from the microtubules, suggesting that only free dynein and not the microtubule-dynein complex catalyzes the exchange reaction. The rates of dynein binding to microtubules in the absence and presence of saturating ADP were 1.6 X 10(6) and 9.8 X 10(5) M-1 s-1, respectively. ADP inhibited the rate of the ATP-induced dissociation of the microtubule-dynein complex with an apparent Kd = 0.37 mM for the binding of ADP to the microtubule-dynein complex. However, the rate of dissociation of ADP from the M.D.ADP complex was quite fast (approximately 1000 s-1). These data support the postulate of a high-energy dynein-ADP intermediate and indicate that microtubules activate the dynein ATPase by enhancing the rate of ADP release.     

Evidence for energy-dependent change in phosphate binding for mitochondrial oxidative phosphorylation based on measurements of medium and intermediate phosphate-water exchanges.

Characteristics of the exchange reactions catalyzed by beef heart submitochondrial particles give new insight into energy transducing steps of oxidative phosphorylation. The uncoupler-insensitive portion of the total Pi in equilibrium HOH exchange in presence of ATP, ADP, and Pi is the intermediate Pi in equilibrium HOH exchange, that is the exchange occurring with Pi formed by hydrolysis of ATP prior to release of Pi from the catalytic site. The exchange of medium Pi with HOH is as sensitive to uncouplers as the Pi in equilibrium ATP exchange and net oxidative phosphorylation, demonstrating a requirement of an uncoupler-sensitive energized state, probably a transmembrane potential or proton gradient, for bringing medium Pi to the reactive state. The covalent bond forming and breaking step at the catalytic site (ADP + Pi in equilibrium ATP + HOH) appears relatively insensitive to uncouplers. Thus to the extent that uncouplers dissipate transmembrane proton-motive force, it is unlikely that such a force is used to drive ATP formation by direct protonations of Pi oxygens. When only Pi and ADP are added and formation of ATP from added ADP by adenylate kinase and subsequent ATP hydrolysis are adequately blocked, no Pi in equilibrium HOH exchange can be observed, demonstrating a requirement of energization by ATP binding and cleavage for such an exchange. This uncoupler-insensitive energization is suggested to represent a conformationally energized state that can be used reversibly to develop a transmembrane protonmotive force accompanying ADP and Pi release. Rates of various exchanges as estimated by improved procedures are compatible with all oxygen exchanges occurring by dynamic reversal of ATP hydrolysis at the catalytic site.     

Energy-linked reactions in photosynthetic bacteria: Pi in equilibrium with HOH oxygen exchange catalyzed by the membrane-bound inorganic pyrophosphatase of Rhodospirillum rubrum

The inorganic phosphate-water oxygen exchange reaction has been studied in chromatophores of Rhodospirillum rubrum. Under appropriate conditions, chromatophores catalyzed this exchange at a rate of up to 150 μatom oxygen/h/mg bacteriochlorophyll. The reaction is largely inhibited by inhibitors of the membrane-bound inorganic pyrophosphatase, fluoride and methylene diphosphonate, and is not inhibited by oligomycin. These results indicate that the P_i ? HOH oxygen exchange is almost entirely due to the pyrophosphatase. In the presence of ADP, the exchange reaction was stimulated by about 40% and this portion of the exchange was sensitive to oligomycin, but not to fluoride or methylene diphosphonate. Thus this portion of the exchange can be attributed to the ATP synthese complex. The rates of the oxygen exchange reaction and other chromatophore-catyalyzed reactions are compared.     

The enzymatic conversion of 3'-phosphate terminated RNA chains to 2',3'-cyclic phosphate derivatives

The enzyme, RNA cyclase, has been purified from cell-free extracts of HeLa cells approximately 6000-fold. The enzyme catalyzes the conversion of 3'-phosphate ends of RNA chains to the 2',3'-cyclic phosphate derivative in the presence of ATP or adenosine 5'-(gamma-thio)triphosphate (ATP gamma S) and Mg2+. The formation of 1 mol of 2',3'-cyclic phosphate ends is associated with the disappearance of 1 mol of 3'-phosphate termini and the hydrolysis of 1 mol of ATP gamma S to AMP and thiopyrophosphate. No other nucleotides could substitute for ATP or ATP gamma S in the reaction. The reaction catalyzed by RNA cyclase was not reversible and exchange reactions between [32P]pyrophosphate and ATP were not detected. However, an enzyme-AMP intermediate could be identified that was hydrolyzed by the addition of inorganic pyrophosphate or 3'-phosphate terminated RNA chains but not by 3'-OH terminated chains or inorganic phosphate. 3'-[32P](Up)10Gp* could be converted to a form that yielded, (Formula: see text) after degradation with nuclease P1, by the addition of wheat germ RNA ligase, 5'-hydroxylpolynucleotide kinase, RNA cyclase, and ATP. This indicates that the RNA cyclase had catalyzed the formation of the 2',3'-cyclic phosphate derivative, the kinase had phosphorylated the 5'-hydroxyl end of the RNA, and the wheat germ RNA ligase had catalyzed the formation of a 3',5'-phosphodiester linkage concomitant with the conversion of the 2',3'-cyclic end to a 2'-phosphate terminated residue.     

A stereochemical method for detection of ATP terminal phosphate transfer in enzymatic reactions. Glutamine synthetase.

An isotope scrambling method is described for the detection of transient [Enz:ADP:P-X] formation from [18O]ATP in ATP-coupled enzyme reactions. The method makes use of torsional symmetry of the newly formed (see article) group in ADP. [18 O]ATP labeled in the betagama bridge oxygen was incubated with enzyme and reversible cleavage of the PbetaO -- Pgamma bond was detected by the appearance of 18O in the beta nonbridge oxygens of the ATP pool. Experiments with sheep brain and Escherichia coli glutamine synthetases show that cleavage of ATP of enzyme-bound ADP and P-X requires glutamate. The exchange catalyzed by the E. coli enzyme with glutamate occurs in the absence of ammonia and is partially inhibited by added NH4Cl, as expected if the exchange is in the mechanistic pathway for glutamine synthesis. The results provide kinetic support for a two-step mechanism where phosphoryl transfer from ATP to glutamate precedes reaction with ammonia.     

Stereochemical reaction mechanism formulations for enzyme-catalyzed pyrophosphate hydrolysis,ATP hydrolysis,and ATP synthesis

Fundamental concepts pertaining to the stereochemistry paths of polar additionelimination (nucleophilic substitution) reactions at phosphate phosphorus centers are reviewed and employed to analyze ¹⁸O exchange reactions catalyzed by inorganic pyrophosphatase and mitochondrial ATP synthetase. The analysis suggests reasonable choices for the stereochemistry path of the ¹⁸O exchanges. This, in turn, permits reasonable choices for the stereochemistry paths of hydrolysis of pyrophosphate catalyzed by pyrophosphatase and of hydrolysis and synthesis of ATP catalyzed by ATP synthetase.     

The mechanism of action of methionyl-tRNA synthetase from Escherichia coli. Inhibition by adenosine and 8-aminoadenosine of the amino-acid activation reaction.

Adenosine and 8-aminoadenosine, both competitive inhibitors of ATP-Mg2+ in the ATP-PPi exchange reaction catalyzed by methionyl-tRNA synthetase, are used to investigate the active center for methionyl-adenylate formation. Resolution of the kinetics parameters of the reaction indicates that methionine markedly enhances the affinity of the nucleosides for the enzyme, providing evidence for coupling between the sites for amino acid and the nucleoside moiety of ATP. Furthermore, occupation of both of these sites is a prerequisite for binding of pyrophosphate. Introduction of an amino group in position 8 of the adenine ring strongly increases the affinity constants for the nucleoside and for pyrophosphate in the coupled reactions described above.     

Inactivation of gamma-glutamylcysteine synthetase, but not of glutamine synthetase, by S-sulfocysteine and S-sulfohomocysteine

The reactions catalyzed by gamma-glutamylcysteine synthetase and glutamine synthetase are thought to proceed via enzyme-bound gamma-glutamyl phosphate intermediates. We investigated the possibility that S-sulfocysteine and S-sulfohomocysteine might act as analogs of gamma-glutamyl phosphate or of the associated putative tetrahedral intermediates. The D- and L-enantiomers of S-sulfocysteine and S-sulfohomocysteine were found to rapidly inactivate rat kidney gamma-glutamylcysteine synthetase but to be reversible inhibitors of sheep brain glutamine synthetase. Inactivation of gamma-glutamylcysteine synthetase does not require ATP and is associated with noncovalent binding of close to 1 mol of inactivator/mol of enzyme. The findings indicate that the S-sulfo amino acids are transition-state analogs, and that binding of S-sulfo amino acid to the enzyme induces formation of a very stable enzyme-inactivator complex. The data suggest that stabilization of the enzyme-inactivator complex results from interactions involving the sulfenyl sulfur atom of the S-sulfo amino acid and the active site thiol group of the enzyme.     

Possible steps of complete disassembly of post-termination complex by yeast eEF3 deduced from inhibition by translocation inhibitors

Ribosomes, after one round of translation, must be recycled so that the next round of translation can occur. Complete disassembly of post-termination ribosomal complex (PoTC) in yeast for the recycling consists of three reactions: release of tRNA, release of mRNA and splitting of ribosomes, catalyzed by eukaryotic elongation factor 3 (eEF3) and ATP. Here, we show that translocation inhibitors cycloheximide and lactimidomycin inhibited all three reactions. Cycloheximide is a non-competitive inhibitor of both eEF3 and ATP. The inhibition was observed regardless of the way PoTC was prepared with either release factors or puromycin. Paromomycin not only inhibited all three reactions but also re-associated yeast ribosomal subunits. On the other hand, sordarin or fusidic acid, when applied together with eEF2/GTP, specifically inhibited ribosome splitting without blocking of tRNA/mRNA release. From these inhibitor studies, we propose that, in accordance with eEF3’s known function in elongation, the release of tRNA via exit site occurs first, then mRNA is released, followed by the splitting of ribosomes during the disassembly of post-termination complexes catalyzed by eEF3 and ATP.     

On the mechanism of H+ translocation by mitochondrial H+-ATPase. Studies with chemical modifier of tyrosine residues

In this paper a detailed study of the effect of nitration of tyrosine residues by tetranitromethane on H⁺ conduction and other reactions catalyzed by the H⁺-ATPase complex in phosphorylating submitochondrial particles, uncoupled particles, and the purified complex is presented. Tetranitromethane treatment of submitochondrial particles results in marked inhibition of ATP hydrolysis, ATP-³³P_i exchange, and proton conduction by the H⁺-ATPase complex. These effects are caused by nitration of tyrosine residues of H⁺-ATPase complex as shown by the appearance of the absorption peak at 360 nm (specific for nitrotyrosine formation) and inhibition of ATP hydrolysis and ATP-³³P_i exchange in the complex purified from tetranitromethane-treated particles. H⁺ conduction in phospholipid vesicles inlaid with F₀ is also inhibited by tetranitromethane treatment. These observations indicate that tyrosine residue(s) of F₀ are critically involved in energy-linked proton translocation in the ATP-ase complex.     

Measurement of positional isotope exchange rates in enzyme-catalyzed reactions by fast atom bombardment mass spectrometry: application to argininosuccinate synthetase

Fast atom bombardment mass spectrometry (FAB-MS) has been used to measure positional isotope exchange rates in enzyme-catalyzed reactions. The technique has been applied to the reactions catalyzed by acetyl-CoA synthetase and argininosuccinate synthetase. The FAB technique is also able to quantitatively determine the oxygen-18 or oxygen-17 content of nucleotides on as little as 10 nmol of material with no prior derivatization. Acetyl-CoA synthetase has been shown by FAB-MS to catalyze the positional exchange of an oxygen-18 of ATP from the beta-nonbridge position to the alpha beta-bridge position in the presence of acetate. These results are consistent with acetyl adenylate as a reactive intermediate in this reaction. Argininosuccinate synthetase was shown not to catalyze a positional isotope exchange reaction designed to test for the formation of citrulline adenylate as a reactive intermediate. Argininosuccinate synthetase was also found not to catalyze the transfer of oxygen-18 from [ureido-18O]citrulline to the alpha-phosphorus of ATP in the absence of added aspartate. This experiment was designed to test for the transient formation of carbodiimide as a reactive intermediate. These results suggest that either argininosuccinate synthetase does not catalyze the formation of citrulline adenylate or the enzyme is able to completely suppress the rotation of the phosphoryl groups of PPi.     

Kinetics of oxygen-18 exchange between inorganic phosphate and water catalyzed by myosin subfragment 1, using the 18O shift in 31P NMR

The time course of oxygen-18 exchange between [18O]Pi and normal water, catalyzed by myosin subfragment 1 in the presence of MgADP, was followed using the shift in 31P NMR caused by the presence of oxygen-18 bound to the phosphorus. Essentially all molecules of [18O]Pi that bind to the enzyme undergo complete exchange and are released as [16O4]Pi. Exchange probably occurs by formation of myosin.ATP from a myosin.ADP.Pi complex and is rapid relative to release of Pi from this complex. The kinetics of exchange give a value for the rate constant for binding Pi to myosin.ADP of 0.23 M-1 S-1 (pH 8.0, 22 degrees C). This value is consistent with exchange occurring by reversal of the ATP-ase reaction back to the myosin.ATP complex.