Insulin-degrading enzyme hydrolyzes ATP

We reported in a previous work that insulin degradation by insulin-degrading enzyme (IDE) was inhibited by ATP (Exp Biol Med 226:334-341, 2001). Then we studied ATP hydrolysis as a possible mechanism for reversion of this inhibition. ATP hydrolysis was determined by (32)P release after hydrolysis of gamma[(32)P]ATP. ATP hydrolysis was studied by Sephadex G200 chromatography, immunoprecipitation, and nondissociating gel electrophoresis. Purified recombinant rat IDE and extractive homogenous IDE showed similar ATP hydrolysis. All results showed concordance between insulin degradation and ATP hydrolysis, suggesting that IDE has both functions. In order to define the type of hydrolysis, we studied inhibitors of IDE, phosphohydrolases, and ATPases. Each substance studied had no effect on ATP hydrolysis, except 1 mM orthovanadate, a known inhibitor of ATPases, phosphatases, and insulin degradation. ATP hydrolysis followed a Michaelis-Menten kinetic with Vmax: 570.45 +/- 113.08 pmol Pi/hr and apparent Michaelis constant (Km): 63.13 +/- 3.48 microM. ATP binding studies strongly suggested an ATP binding site and enzyme kinetics established only one active hydrolytic ATP binding site per IDE molecule. ATP-induced enzyme aggregation changes as observed by electrophoresis mobility in nondissociating conditions and conformational changes on insulin binding as shown by IDE-insulin cross-linking. We conclude that IDEs have ATPase activity and that insulin-binding and degradation are dependent on ATP concentration; however, insulin does not modify the ATPase activity of IDE.     

An automated continuous assay of membrane-bound and solube ATPases and related enzymes.

A simple, rapid, and precise method is described for the continuous automated determination of the activity of membrane-bound enzymes which deliberate inorganic phosphate, e.g., ATPases and phosphatases. The characteristics of this method, which is based on the determination of liberated phosphate in the presence of nucleotides, are: (A) the enzyme reaction can be followed continuously during a certain period, thus providing a higher precision, as compared to other methods in which the enzyme reaction is measured by few distinct determinations; (B) the enzyme protein and other (membrane) proteins of the enzyme preparation have not to be removed during the continuous determination of enzyme activity because they remain solubilized after denaturation; and (C) low or moderate concentration of nonionic detergents do not disturb the reading of the absorbancy.     

Monitoring the timing of ATP hydrolysis with activation of peptide cleavage in Escherichia coli Lon by transient kinetics

Escherichia coli Lon, also known as protease La, is an oligomeric ATP-dependent protease, which functions to degrade damaged and certain short-lived regulatory proteins in the cell. To investigate the kinetic mechanism of E. coli Lon protease, we performed the first pre-steady-state kinetic characterization of the ATPase and peptidase activities of this enzyme. Using rapid quench-flow and fluorescence stopped-flow spectroscopy techniques, we demonstrated that ATP hydrolysis occurs before peptide cleavage, with the former reaction displaying a burst and the latter displaying a lag in product production. The detection of burst kinetics in ATP hydrolysis is indicative of a step after nucleotide hydrolysis being rate-limiting in ATPase turnover. At saturating substrate concentrations, the lag rate constant for peptide cleavage is comparable to the kcat of ATPase, indicating that two hydrolytic processes are coordinated during the first enzyme turnover. The involvement of subunit interaction during enzyme catalysis was detected as positive cooperativity in the binding and hydrolysis of substrates, as well as apparent asymmetry in the ATPase activity in Lon. When our data are taken together, they are consistent with a reaction model in which ATP hydrolysis is used to generate an active enzyme form that hydrolyzes peptide.     

Glutamic acid 472 and lysine 480 of the sodium pump alpha 1 subunit are essential for activity. Their conservation in pyrophosphatases suggests their involvement in recognition of ATP phosphates.

P-type ATPases such as the Na+,K+-ATPase (sodium pump) hydrolyze ATP to pump ions through biological membranes against their electrochemical gradients. The mechanisms that couple ATP hydrolysis to the vectorial ion transport are not yet understood, but unveiling structures that participate in ATP binding and in the formation of the ionophore might help to gain insight into this process. Looking at the alpha- and beta-phosphates of ATP as a pyrophosphate molecule, we found that peptides highly conserved among all soluble inorganic pyrophosphatases are also present in ion-transporting ATPases. Included therein are Glu48 and Lys56 of the Saccharomyces cerevisiae pyrophosphatase (SCE1-PPase) that are essential for the activity of this enzyme and have been shown in crystallographic analysis to interact with phosphate molecules. To test the hypothesis that equivalent amino acids are also essential for the activity of ion-transporting ATPases, Glu472 and Lys480 of the sodium pump alpha 1 subunit corresponding to Glu48 and Lys56 of SCE1-PPase were mutated to various amino acids. Mutants of the sodium pump alpha1 subunit were expressed in yeast and analyzed for their ATPase activity and their ability to bind ouabain in the presence of either ATP, Mg2+, and Na+ or phosphate and Mg2+. All four mutants investigated, Glu472Ala, Glu472Asp, Lys480Ala, and Lys480Arg, display only a fraction of the ATPase activity obtained with the wild-type enzyme. The same applies with respect to their ability to bind ouabain, where maximum ouabain binding to the mutants accounts for only about 10% of the binding obtained with the wild-type enzyme. On the basis of our results, we conclude that Glu472 and Lys480 are essential for the activity of the sodium pump. Their function is probably to arrest the alpha- and beta-phosphate groups of ATP in a proper position prior to hydrolysis of the gamma-phosphate group. The identification of these amino acids as essential components of the ATP-recognizing mechanism of the pump has resulted in a testable hypothesis for the initial interactions of the sodium pump, and possibly of other P-type ATPases, with ATP.     

Rabbit platelet calcium ATPase differs from the human erythrocyte (Ca2+ + Mg2+)-ATPase in its response to three purified phospholipases A2, exogenous phospholipids and calmodulin

Human erythrocyte (Ca2+ + Mg2+)-ATPase and calcium ATPase of rabbit platelets were compared by their responses to a variety of treatments. These included three purified phospholipases A2 (acidic, neutral and basic) from Agkistrodon halys blomhoffii, as well as several phospholipids and lysophospholipids. The erythrocyte enzyme was stimulated 2-3-fold by all three phospholipases with maximal stimulation occurring at different concentrations of the three enzymes. The basic phospholipase was the most potent, followed by the neutral and acidic enzymes in that order. The calcium ATPase activity of the platelet was also stimulated by phospholipase treatment, but only by 10-20%. The stimulatory activity was attributable to hydrolysis of a very small portion of the total membrane phospholipid. Inactivation of the phospholipases by heating or chemical modification with p-bromophenacyl bromide abolished their ability to stimulate. Addition of polyphosphoinositides stimulated both ATPases. However, another acidic phospholipid, lysophosphatidic acid, stimulated only the erythrocyte enzyme and failed to affect the platelet calcium ATPase. Phosphatidylcholine (PC) and phosphatidylethanolamine (PE) had no effect on either enzyme, while the platelet-activating factor (1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine), its lyso compound and lysoPC inhibited both ATPases. Calmodulin stimulated the erythrocyte enzyme, but did not affect the platelet calcium ATPase. These results demonstrate that the protein-lipid interactions operative in the erythrocyte and platelet calcium ATPases are quite different.     

Interaction of homogeneous mitochondrial ATPase from rat liver with adenine nucleotides and inorganic phosphate

Mitochondrial ATPase from rat liver mitochondria contains multiple nucleotide binding sites. At low concentrations ADP binds with high affinity (1 mole/mole ATPase, K_D = 1–2 μM). At high concentrations, ADP inhibits ATP hydrolysis presumably by competing with ATP for the active site (K_I = 240–300 μM). As isolated, mitochondrial ATPase contains between 0.6 and 2.5 moles ATP/mole ATPase. This “tightly bound” ATP can be removed by repeated precipitations with ammonium sulfate without altering hydrolytic activity of the enzyme. However, the ATP-depleted enzyme must be redissolved in high concentrations of phosphate to retain activity. AMP-PNP (adenylyl imidodiphosphate) replaces tightly bound ATP removed from the enzyme and inhibits ATP hydrolysis. AMP-PNP has little effect on high affinity binding of ADP. Kinetic studies of ATP hydrolysis reveal hyperbolic velocity vs. ATP plots, provided assays are done in bicarbonate buffer or buffers containing high concentrations of phosphate. Taken together, these studies indicate that sites on the enzyme not directly associated with ATP hydrolysis bind ATP or ADP, and that in the absence of bound nucleotide, P_i can maintain the active form of the enzyme.     

Regulatory interplay between proton motive force, ADP, phosphate, and subunit epsilon in bacterial ATP synthase

ATP synthase couples transmembrane proton transport, driven by the proton motive force (pmf), to the synthesis of ATP from ADP and inorganic phosphate (P(i)). In certain bacteria, the reaction is reversed and the enzyme generates pmf, working as a proton-pumping ATPase. The ATPase activity of bacterial enzymes is prone to inhibition by both ADP and the C-terminal domain of subunit epsilon. We studied the effects of ADP, P(i), pmf, and the C-terminal domain of subunit epsilon on the ATPase activity of thermophilic Bacillus PS3 and Escherichia coli ATP synthases. We found that pmf relieved ADP inhibition during steady-state ATP hydrolysis, but only in the presence of P(i). The C-terminal domain of subunit epsilon in the Bacillus PS3 enzyme enhanced ADP inhibition by counteracting the effects of pmf. It appears that these features allow the enzyme to promptly respond to changes in the ATP:ADP ratio and in pmf levels in order to avoid potentially wasteful ATP hydrolysis in vivo.     

Some Observations on the Characteristics and Distribution of Adenosine Triphosphatases in Young Roots of Pisum sativum, Cultivar Alaska

A study has been made of some characteristics of ATPases fromyoung pea roots and these enzymes have been shown to differfrom ß glycerophosphatases in several respects. DEAEchromotography and gel electrophoresis have confirmed the existenceof a number of different phosphatases with differing affinitiesfor ATP and sodium ß glycerophosphate. At least twoATP-specific phosphatases have been detected and these accountfor about 57 per cent of the total ATPase activity in pea roots. The distribution of ATPase activity along the axis of the roothas been determined by biochemical assay of serial sectionsand by histochemical methods. It is shown that ATPase activityhas a quite different distribution from ß glycero-phosphataseactivity, thus confirming the separate identity of the two enzymesystems. The distribution of ATPases is discussed in relation to theirpossible role in ion transport.     

Hydrolysis of adenyl-5-yl imidodiphosphate by beef heart mitochondrial ATPase

Beef heart mitochondrial ATPase (F1) catalyzes the hydrolysis of the ATP analog adenyl-5-yl imidodiphosphate (AMP-PNP). The reaction products are inorganic phosphate and adenyl-5-yl phosphoramidate (AMP-PN) as determined by HPLC analysis. The hydrolysis occurs in both the presence and absence of added divalent metal ions and is stimulated by potassium. The kinetic properties of the hydrolytic reaction depend markedly on the identity of the added divalent metal. GMP-PNP and AMP-CPP are also hydrolyzed, while AMP-PCP is not. Adenyl-5-yl phosphoramidate is a potent effect of beef heart mitochondrial ATPase activity. Based on these data, a reinterpretation of work based on the assumption that AMP-PNP is not hydrolyzed is presented.     

A nucleophilic catalysis step is involved in the hydrolysis of aryl phosphate monoesters by human CT acylphosphatase

Acylphosphatase, one of the smallest enzymes, is expressed in all organisms. It displays hydrolytic activity on acyl phosphates, nucleoside di- and triphosphates, aryl phosphate monoesters, and polynucleotides, with acyl phosphates being the most specific substrates in vitro. The mechanism of catalysis for human acylphosphatase (the organ-common type isoenzyme) was investigated using both aryl phosphate monoesters and acyl phosphates as substrates. The enzyme is able to catalyze phosphotransfer from p-nitrophenyl phosphate to glycerol (but not from benzoyl phosphate to glycerol), as well as the inorganic phosphate-H(2)18O oxygen exchange reaction in the absence of carboxylic acids or phenols. In short, our findings point to two different catalytic pathways for aryl phosphate monoesters and acyl phosphates. In particular, in the aryl phosphate monoester hydrolysis pathway, an enzyme-phosphate covalent intermediate is formed, whereas the hydrolysis of acyl phosphates seems a more simple process in which the Michaelis complex is attacked directly by a water molecule generating the reaction products. The formation of an enzyme-phosphate covalent complex is consistent with the experiments of isotope exchange and transphosphorylation from substrates to glycerol, as well as with the measurements of the Br?nsted free energy relationships using a panel of aryl phosphates with different structures. His-25 involvement in the formation of the enzyme-phosphate covalent complex during the hydrolysis of aryl phosphate monoesters finds significant confirmation in experiments performed with the H25Q mutated enzyme.     

Three deoxyribonucleic acid-dependent adenosine triphosphatases from Bacillus subtilis.

We have isolated from Bacillus subtilis three deoxyribonucleic acid (DNA)-dependent adenosine triphosphatases (ATPases) (gamma-phosphohydrolases). The enzymes were extensively purified, and their physicochemical and functional properties were determined. The three enzymes (ATPases I, II, and III) were shown to be different by several criteria. ATPases II and III showed an absolute requirement for single-stranded DNA as a cofactor, whereas ATPase I had some residual activity also with double-stranded DNA. They required Mg2+ and had a pH optimum of 6.5 to 7. Only adenosine 5'-triphosphate and deoxyadenosine 5'-triphosphate were hydrolyzed. The molecular weights of ATPases I, II, and III were 108,000, 115,000, and 148,000, respectively. Km values for adenosine 5'-triphosphate and DNA were also evaluated and shown to be different for each enzyme. All three enzymes formed physical complexes with single-stranded DNA. We present evidence that ATPases I and II might migrate along DNA during adenosine 5'-triphosphate hydrolysis. On the other hand, this effect was not observed with ATPase III, which exhibited the highest affinity for single-stranded DNA.     

Thermus thermophilus membrane-associated ATPase. Indication of a eubacterial V-type ATPase

An ATPase with Mr of 360,000 was purified from plasma membranes of a thermophilic eubacterium Thermus thermophilus, and was characterized. ATP hydrolytic activity of the purified enzyme was extremely low, 0.07 mumol of Pi released mg-1 min-1, and it was stimulated up to 30-fold by bisulfite. The following properties of the enzyme indicate that it is not a usual F1-ATPase but that it belongs to the V-type ATPase family, another class of ATPases found in membranes of archaebacteria and eukaryotic endomembranes. Among its four kinds of subunits with approximate Mr values of 66,000 (alpha), 55,000 (beta), 30,000 (gamma), and 12,000 (delta), the alpha subunit had a similar molecular size to the catalytic subunits of the V-type ATPases but was significantly larger than the alpha subunit of F1-ATPases. ATP hydrolytic activity was not affected by azide, an inhibitor of F1-ATPases, but was inhibited by nitrate, an inhibitor of the V-type ATPase. N-terminal amino acid sequences determined for the purified alpha and beta subunits showed much higher similarity to those of the V-type ATPases than those of F1-ATPases. Thus the distribution of the V-type ATPase in the prokaryotic kingdom may not be restricted to archaebacteria.     

Oxygen-induced Regulation of Na/K ATPase in cerebellar granule cells

Adjustment of the Na/K ATPase activity to changes in oxygen availability is a matter of survival for neuronal cells. We have used freshly isolated rat cerebellar granule cells to study oxygen sensitivity of the Na/K ATPase function. Along with transport and hydrolytic activity of the enzyme we have monitored alterations in free radical production, cellular reduced glutathione, and ATP levels. Both active K(+) influx and ouabain-sensitive inorganic phosphate production were maximal within the physiological pO(2) range of 3-5 kPa. Transport and hydrolytic activity of the Na/K ATPase was equally suppressed under hypoxic and hyperoxic conditions. The ATPase response to changes in oxygenation was isoform specific and limited to the alpha1-containing isozyme whereas alpha2/3-containing isozymes were oxygen insensitive. Rapid activation of the enzyme within a narrow window of oxygen concentrations did not correlate with alterations in the cellular ATP content or substantial shifts in redox potential but was completely abolished when NO production by the cells was blocked by l-NAME. Taken together our observations suggest that NO and its derivatives are involved in maintenance of high Na/K ATPase activity under physiological conditions.     

Is ATP a substrate for 15-lipoxygenase?

Lipoxygenases catalyze peroxidation of polyunsaturated fatty acids containing the 1-cis, 4-cis pentadiene structure. Linoleic (18:2), linolenic (18:3), and arachidonic (20:4) acids are the predominant substrates for this class of enzymes. Effects of 15-lipoxygenase on the hydrolysis of adenosine 5'-triphosphate were investigated in vitro using soybean lipoxygenase and adenosine 5'-[gamma-32P]triphosphate. The amount of inorganic phosphate released from adenosine 5'-triphosphate was dependent upon enzyme as well as substrate concentrations, pH, and the duration of incubation. The ATPase activity with a Vmax value of 3.3 mumol.mg protein-1.h-1 and a Km value of 5.9 mM was noted in the presence of different concentrations of ATP at pH = 7.4. Phenidone, a lipoxygenase inhibitor, had no effect on this reaction. These findings suggest that soybean lipoxygenase catalyzes the release of inorganic phosphate from ATP primarily via hydrolysis.     

Effect of triiodo-L-thyronine treatment on Ca2+ sequestration in rat liver microsomes

T3 administration to rats exerts quite different effects on enzyme activities associated to liver microsomal membranes such as G-6-Pase, Mg ATPase and Ca2(+)-dependent ATPase: in fact G-6-Pase activity is significantly enhanced, Mg ATPase is not affected whereas Ca2(+)-dependent ATPase is drastically inhibited. The T3 induced decrease in Ca2(+)-dependent ATPase activity is associated with a net reduction (to about 50% with respect to controls) of the Ca2+ sequestration in liver microsomal vesicles. The enhanced level of inorganic phosphate in the endoplasmic reticulum due to the stimulation of G-6-Pase activity does not significantly affect the uptake of calcium in microsomal vesicles. The decreased Ca2(+)-dependent ATPase activity is associated to an enhanced level of the enzyme in the phosphorylated form (E-P). This suggests that in liver preparations from T3 treated rats the turnover of ATP and cleavage of E-P is reduced, thus resulting in the accumulation of the phosphorylated intermediate. The accumulation of E-P is in agreement with the inhibition of the calcium sequestration since the active transport of this cation in microsomal membranes requires the hydrolysis of the E-P complex.     

3-Phosphono-2-imino-4-oxoimidazoline--a competitive substrate of AMP-dephosphorylating enzymes from the cytosol fraction of the rat heart

3-Phosphono-2-imino-1-methyl-4-oxoimidazolidine (PIMOI), AMP and p-nitrophenyl phosphate (pNPP) were dephosphorylated in the presence of rat heart cytosol at 37 degrees C pH 6.3 at the rates of 0.71, 0.45 and 1.07 mumol/mg X h, respectively. When mixed together, these compounds inhibited the hydrolysis of each other, which points to the participation of common enzyme(s) in this process. The inhibitor of 5'-nucleotidase (alpha,beta-methylene)-ADP, did not affect PIMOI cleavage and moderately inhibited AMP hydrolysis (by ADP, did not affect PIMOI cleavage and moderately inhibited AMP hydrolysis (by 30-50%), thus suggesting that acidic phosphatases are responsible for PIMOI and AMP hydrolysis under these conditions (pH 6.3). Phosphocreatine (PCr) and phosphocyclocreatine (PcCr) were stable to hydrolysis by the cytosolic fraction. However, addition of AMP to the medium containing PCr or PcCr resulted in AMP phosphorylation down to ATP due to the effects of these phosphagens and, probably, of microcontaminations of ATP. This was followed by gradual disappearance of PCr or PcCr and by accumulation of Pi as a result of the "ATPase" activity in the cytosol. The hydrolysis of AMP, PIMOI and p-NPP was sensitive to sulfhydryl reagents [5,5'-dithio-bis-(2-nitrobenzoate) and, in part, 2,4-dinitro-fluorobenzene] and fluoride ion. Thus, PIMOI is a competitive substrate of acidic phosphatases in heart cytosol with respect to AMP and p-NPP. This may partly explain the protective effect of PIMOI on ischemic myocardium.     

Identification of the phosphorylated intermediate of the Neurospora plasma membrane H+-ATPase as beta-aspartyl phosphate

The chemical nature of the phosphoryl enzyme linkage of the electrogenic proton-translocating ATPase (ATP phosphohydrolase, EC 3.6.1.3) in the plasma membrane of Neurospora has been identified as a mixed anhydride between phosphate and the beta-carboxyl group of an aspartic acid residue in the polypeptide chain. Incubation of isolated Neurospora plasma membrane vesicles containing 32P-labeled ATPase in buffers of increasing pH followed by analysis of the hydrolysis products yielded a pH versus hydrolysis profile characteristic of an acyl phosphate linkage. Reaction of labeled membranes with hydroxylamine at pH 5.3 also released [32P]i from the ATPase. Amino acid analyses of the Na[3H]BH4 reduction products obtained from membranes containing phosphorylated and dephosphorylated ATPase identified [3H]homoserine, the expected reduction product of beta-aspartyl phosphate, as the only additional tritiated reduction product in the samples from phosphorylated membranes. Tritium was not found in alpha-amino-delta-hydroxyvaleric acid, the reduction product of gamma-glutamyl phosphate, nor in proline, the degradation product of alpha-amino-delta-hydroxyvaleric acid. These results indicate that the phosphorylated intermediate of the Neurospora plasma membrane ATPase is a beta-aspartyl phosphate identical with that already known to exist in the Na+:K+- and Ca2+-translocating ATPases of animal cell origin. A common model for the mechanisms of all 3 ion-translocating ATPases is presented.     

Characterization of an ATP diphosphohydrolase (EC 3.6.1.5) in synaptosomes from cerebral cortex of adult rats

Data from the literature have demonstrated that synaptosomal preparations from various sources can hydrolyze externally added ATP. Various authors characterized this activity as an ecto-ATPase. In the present report, we demonstrate that synaptosomal preparations obtained from the cerebral cortex of rats show ATPase activity that could not be dissociated from ADPase activity, suggesting that an ATP-diphosphohydrolase is involved in ATP and ADP hydrolysis. Furthermore, the ATP and ADP hydrolysis could not be attributed to associations of enzymes that could mimic an ATP-diphosphohydrolase because none of the following activities were detected in our assay conditions inorganic pyrophosphatase, adenylate kinase, or nonspecific phosphatases. A possible association between an ATPase and an ADPase was excluded on the basis of both the kinetics and much additional data on inhibitors, ion dependence, pH, etc. The present results demonstrate that in synaptosomal preparations from cerebral cortex an ATP-diphosphohydrolase is involved, at least in part, in ATP and ADP hydrolysis.Abbreviations DCCD dicyclohexylcarboiimide - EDTA ethylenediaminetetraacetic acid - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - Pi inorganic phosphate Enzymes ATP diphosphohydrolase, Apyrase (EC 3.6.1.5) - ATPase ATP phosphohydrolase (EC 3.6.1.3) 5-nucleotidase (EC 3.1.3.5) Hexokinase (EC 2.7.1.1) Glucose-6-phosphate dehydrogenase (EC 1.1.1.49) Adenylate kinase (EC 2.7.4.3) Inorganic pyrophosphatase (EC 3.6.1.1) - ATP pyrophosphohydrolase (EC 3.6.1.8) - LDH lactate dehydrogenase (EC 1.1.1.27) - SDH succinate dehydrogenase (EC 1.3.1.6) - ACHE acethylcholinesterase (EC 3.1.1.7) - G-6-Pase glucose-6-phosphatase (EC 3.1.3.9) - NADPH cytoehrome c oxidoreductase (NCR) (EC 1.6.2.4)     

Characterization of an ATP diphosphohydrolase activity (APYRASE,EC 3.6.1.5) in rat blood platelets

In the present report we describe an apyrase (ATP diphosphohydrolase, EC 3.6.1.5) in rat blood platelets. The enzyme hydrolyses almost identically quite different nucleoside di- and triphosphates. The calcium dependence and pH requirement were the same for the hydrolysis of ATP and ADP and the apparent Km values were similar for both Ca²⁺-ATP and Ca²⁺-ADP as substrates. Ca²⁺-ATP and Ca²⁺-ADP hydrolysis could not be attributed to the combined action of different enzymes because adenylate kinase, inorganic pyrophosphatase and nonspecific phosphatases were not detected under our assay conditions. The Ca²⁺-ATPase and Ca²⁺-ADPase activity was insensitive to ATPase, adenylate kinase and alkaline phosphatase classical inhibitors, thus excluding these enzymes as contaminants. The results demonstrate that rat blood platelets contain an ATP diphosphohydrolase involved in the hydrolysis of ATP and ADP which are vasoactive and platelet active adenine nucleotides.     

Replacement of arginine 246 by histidine in the beta subunit of Escherichia coli H+-ATPase resulted in loss of multi-site ATPase activity

A mutant strain KF43 of Escherichia coli defective in the beta subunit of H+-translocating ATPase (F0F1) was examined. In this mutant, replacement of Arg246 by His was identified by DNA sequencing of the mutant gene and confirmed by tryptic peptide mapping. The mutant F1-ATPase was defective in multi-site hydrolysis of ATP but was active in uni-site hydrolysis. Studies on the kinetics of uni-site hydrolysis indicated that the k1 (rate of ATP binding) was similar to that of the wild-type, but the k-1 (rate of release of ATP) could not be measured. The mutant enzyme had a k3 (rate of release of inorganic phosphate) about 15-fold higher than that of the wild-type and showed 3 orders of magnitude lower promotion from uni- to multi-site catalysis. These results suggest that Arg246 or the region in its vicinity is important in multi-site hydrolysis of ATP and is also related to the binding of inorganic phosphate. Reconstitution experiments using isolated subunits suggested that hybrid enzymes (alpha beta gamma complexes) carrying both the mutant and wild-type beta subunits were inactive in multi-site hydrolysis of ATP, supporting the notion that three intact beta subunits are required for activity of the F1 molecule.