Kinetics Of ATP Hydrolysis Research Articles

Mg 2+ and ATP or adenosine 5′-[γ-thio]-triphosphate (ATPγS) enhances intrinsic fluorescence and induces aggregation which increases the activity of spinach Rubisco activase

ATP and Mg 2+ caused a transient increase in the intrisinc fluorescence of Rubisco activase which was inhibited by the presence of ADP. Only minor changes in fluorescence were observed with ATP or Mg 2+ alone. The fluorescence increase was stabilized by addition of an ATP regenerating system or by substitution of ATP with a non-hydrolyzable analog, adenosine 5′-[γ-thio]-triphosphate (ATPγS). The initial rate of increase in fluorescence also depended on the concentration of protein in a manner consistent with second-order kinetics. The concentration dependence for the effect of ATPγS was sigmoidal, although at pH 8 the half-saturation requirements for both ATPγS (12 μM) and Mg 2+ (1.5 mM) were not too dissimilar to the binding affinities (6 μM and 2 mM, respectively) determined indirectly with the fluorescent probe, 1-anilinonapthalene-8-sulfonate. However, the concentration dependence of ATP was about 5-fold higher than its binding affinity, also sigmoidal and quite similar to the concentration responses of ATP hydrolysis and activation of Rubisco by the protein. These characteristics of the intrinsic fluorescence indicate that it monitors a conformational change in the protein occurring after binding of the nucleotide and associated with increased aggregation. Direct evidence of increased aggregation in the presence of Mg 2+ and ATP or ATPγS was obtained by gel-filtration chromatography. However, the apparent molecular mass was heterogenous and also varied with temperature. The increased aggregation of the protein resulted in altered kinetic properties. The ATP hydrolysis activity of the protein increased and the half-maximal ATP concentration decreased as the protein concentration was increased in the assay. Also, a brief pretreatment of the protein with ATP and Mg 2+ to increase aggregation eliminated the otherwise observed time delays in the Rubisco activation and ATP hydrolysis kinetics.

The ATP-binding cassette (ABC) transporter for maltose/maltodextrins of Salmonella typhimurium. Characterization of the ATPase activity associated with the purified MalK subunit.

The ATPase activity associated with the purified MalK subunit of the maltose transport complex of Salmonella typhimurium, a bacterial ATP-Binding Cassette (ABC) transporter (Walter, C., Höner zu Bentrup, K., and Schneider, E. (1992) J. Biol. Chem. 267, 8863-8869), was characterized in detail. The analysis of the kinetics of ATP hydrolysis yielded a Km value of 70 +/- 4 microM and a Vmax of 1.3 +/- 0.3 mumol/min/mg of protein. Both GTP and CTP also served as substrates. While MalK exhibited nearly the same affinity for GTP as for ATP, the Michaelis constant for CTP as a substrate was much higher. ATP hydrolysis was strongly dependent on the presence of Mg2+ ions. Mn2+ at low concentrations, but neither Ca2+ nor Zn2+ partially substituted for Mg2+. The ATPase activity was optimal at slightly alkaline pH and was stimulated in the presence of both glycerol (7.5%) and dimethyl sulfoxide (Me2SO) (5%). ADP and the non-cleavable substrate analog ATP gamma S (adenosine 5'-O-(3-thiotriphosphate)) were identified as competitive inhibitors. The MalK-ATPase was resistant to specific inhibitors of F-, P-, and V-type ATPases, such as dicyclohexylcarbodiimide, azide, vanadate, or bafilomycin A1. In contrast, micromolar concentrations of the sulfhydryl reagent N-ethylmaleimide strongly inhibited the enzymatic activity. This inhibition was blocked in the presence of ATP. These results suggest that the intrinsic ATPase activity of purified MalK can be clearly distinguished from other ATP-hydrolyzing enzymes, e.g. ion-translocating ATPases.

Kinetics of ATP hydrolysis during the DNA helicase II-promoted unwinding of duplex DNA

The ATP hydrolysis activity of DNA helicase II from Escherichia coli was examined in the presence of linear single-stranded DNA (ssDNA) and linear double-stranded DNA (dsDNA). In the presence of ssDNA, the ATP hydrolysis reaction followed a linear time course until the ATP was depleted. In the presence of dsDNA, in contrast, there was a kinetic lag before a linear phase of ATP hydrolysis was achieved. The nonlinear kinetics of the dsDNA-dependent ATP hydrolysis reaction could be modeled by a kinetic scheme in which helicase II undergoes a time-dependent transition from an ATPase-inactive to an ATPase-active form. Order of addition experiments indicated that this transition was not due to a rate-limiting association event between helicase II and any other component of the reaction. Instead, agarose gel assays showed that progressive unwinding of the dsDNA occurs during the same time period as the lag phase of the ATP hydrolysis reaction. No significant ATP hydrolysis was observed when the linear dsDNA was replaced with closed circular dsDNA, suggesting that the ATP hydrolysis reaction requires a dsDNA substrate that can be unwound to the complementary single strands. These results are consistent with a model in which the lag phase of the dsDNA-dependent ATP hydrolysis reaction corresponds to progressive unwinding of the dsDNA, with the ATP hydrolysis reaction arising from helicase II molecules that are bound to the separated single strands.

ATP-hydrolysis in chloroplasts: evidence for the participation of three ATP binding sites

The H +-ATPase from chloroplasts, CF 0F 1, is reduced by illumination of thylakoids in the presence of thioredoxin and dithiothreitol. The endogeneous nucleotides are removed by a washing procedure so that the inactive, reduced enzyme contains one tightly bound ATP per CF 0F 1. Upon activation of the enzyme by a Δ pH Δψ jump this ATP is not released. The inactivation of the enzyme occurs with first order kinetics with a half-lifetime of 450 s (rate constant k in = 1.5 · 10 −3 s −1) without rebinding of ADP. Obviously, there exist at least two different inactive states of the enzyme, one with a tightly bound ADP and one without bound ADP. The maximal turnover of the enzyme is 30 s −1 before and after washing. The rate of ATP hydrolysis was measured from 1 nM to 1 mM ATP with this enzyme. A sigmoidal dependence of the rate is observed at low ATP concentrations, reaching a plateau rate of 0.007 s −1 between 25 nM and 55 nM, and the half-maximal rate is reached at 15 nM. From the supralinear increase of the rate below 25 nM it is concluded that two catalytic sites are involved in this range. Above 1 μM ATP the kinetics of ATP-hydrolysis can be described by Michaelis-Menten kinetics with v max = 30 s −1 and K∗ M = 220 μ M . The results indicate the participation of at least three different sites in ATP-hydrolysis catalyzed by the membrane-bound CF 0F 1.

A mutation in the consensus ATP-binding sequence of the RecD subunit reduces the processivity of the RecBCD enzyme from Escherichia coli.

We have constructed a mutant form of the RecBCD enzyme from Escherichia coli with a lysine to glutamine change in the consensus ATP-binding sequence in the RecD subunit (Korangy, F., and Julin, D.A. (1992a, 1992b) J. Biol. Chem., 1727-1732; 1733-1740). We compare here the kinetics of double-stranded DNA-dependent ATP hydrolysis by the mutant (RecBCD-K177Q) and wild-type enzymes. We included heparin to trap enzyme not bound to DNA, or the single-stranded DNA-binding (SSB) protein from Escherichia coli to prevent the enzyme from binding to single-stranded DNA products and partially single-stranded reaction intermediates. The ATP hydrolysis kinetics in either case show a rapid burst phase followed by a slower second phase. The wild-type enzyme hydrolyzes an amount of ATP about equal to the DNA nucleotide concentration in the rapid phase. The amount of ATP hydrolyzed by the RecBCD-K177Q enzyme in the burst is about 8-10-fold lower than the wild-type, in the presence of either heparin or SSB. The burst magnitude of the wild-type enzyme with heparin is proportional to the size of the DNA from about 1,420 to 22,400 base pairs whereas that of the mutant is independent of the DNA size. The wild-type enzyme completely degrades a 6,250-base pair DNA substrate with no partially degraded molecules visible on agarose gels. RecBCD-K177Q enzyme reaction mixtures in the presence of SSB protein contain a heterogeneous mixture of partially degraded molecules of 2,000-5,000 base pairs. These results indicate that the RecBCD-K177Q enzyme is less processive than the wild-type enzyme.

Cooperativity in ATP hydrolysis by GroEL is increased by GroES

The kinetics of ATP hydrolysis by the ‘molecular chaperone’ GroEL and the inhibition of this hydrolysis by GroES have been studied in more detail. It is shown that the hydrolysis of ATP by GroEL is cooperative with respect to ATP with a Hill coefficient of 1.86 (±0.13). In the presence or GroES, there is an increase in the degree of cooperativity with a Hill coefficient of 3.01 (±0.18). The observed cooperativity is not due to dissociation of the GroEL oligomer into smaller units but more probably involves structural changes within the GroEL oligomer.

Na+-K+-ATPase and Changes in ATP Hydrolysis, Monovalent Cation Affinity, and K+ Occlusion in Diabetic and Galactosemic Rats

This study showed that steady-state kinetics of ATP hydrolysis by Na(+)-K(+)-ATPase are altered in the BB Wistar diabetic rat and experimental galactosemia. Four days after onset, this change was not evident if NaCNBH3 was omitted during enzyme preparations (indicating reversibility). Ninety days after onset, NaCNBH3 reduction was not necessary to see the change in ATP hydrolysis kinetics (indicating nonreversibility). The change in steady-state ATP hydrolysis was similar to that reported earlier for Na(+)-K(+)-ATPase of the lens epithelium and kidney medulla of diabetic individuals and for two in vitro glycosylation models. Our study also showed that the affinities of Na(+)-K(+)-ATPase for K+ are altered, and Na(+)-K(+)-ATPase-dependent K+ occlusion is inhibited in diabetic and galactosemic animals. Because K+ occlusion is required for efficient K+ transport, this finding supports previous in vitro studies that indicated that glycosylation inhibits pump-dependent K+ transport. Furthermore, our study suggested an irreversible impairment of Na(+)-K(+)-ATPase function in the diabetic BB Wistar rat as early as 15 days after onset, even when blood glucose was maintained at 6.7 mM by daily insulin injection.

Nonenzymatic glycation of Na,K-ATPase. Effects on ATP hydrolysis and K+ occlusion.

Glycation of the Na,K-ATPase in vitro (formation of Schiff base with glucose followed by reduction with NaCNBH3) shows the presence of three classes of reactive amino groups that differentially affect catalysis and cation binding. Reaction in the absence of ATP results in irreversible inhibition of enzyme activity with a t1/2 of 53 min. This is due to modification of one class of amino groups that affect the catalytic domain of the enzyme. In the presence of ATP, glycation first results in a shift in the steady state kinetics of ATP hydrolysis from substrate activation to Michaelis-Menten kinetics accompanied by an increase in the apparent affinity for K+ in the p-nitrophenylphosphatase reaction. This change in kinetic properties occurs with a t1/2 of 9 min and results in the complete loss of K+ occlusion. Incorporation of glucose is into the catalytic subunit, remote from the N-terminal end. Apparent total inhibition of K+ occlusion occurs with a stoichiometry 0.8 mol of glucose incorporated per mol of enzyme. Therefore, there is a rapidly reacting amino group that affects the cation binding domain of the Na,K-ATPase. More slowly, with a t1/2 of 9 h, the ATP hydrolysis kinetics change from Michaelis-Menten to substrate inhibition without recovery of K+ occlusion, showing that, in the E1 conformation, there is a third, slower reacting class of amino groups in the Na,K-ATPase that affects low affinity nucleotide interaction with the catalytic subunit.

The H+‐ATPase of the plasma membrane from yeast

The H(+)-ATPase of the plasma membrane from Saccharomyces cerevisiae has been isolated, purified and reconstituted into asolectin liposomes. The kinetics of ATP hydrolysis have been compared for the H(+)-ATPase in the plasma membrane, in a protein/lipid/detergent micelle (isolated enzyme) and in asolectin proteoliposomes (reconstituted enzyme). In all three cases the kinetics of ATP hydrolysis can be described by Michaelis-Menten kinetics with Km = 0.2 mM MgATP (plasma membranes), Km = 2.4 mM MgATP (isolated enzyme) and Km = 0.2 mM MgATP (reconstituted enzyme). However, the maximal turnover decreases only by a factor of two during isolation of the enzyme and does not change during reconstitution; the activation of the H(+)-ATPase by free Mg2+ is also only slightly influenced by the detergent. The dissociation constant of the enzyme-Mg2+ complex Ka, does not alter during isolation and the dissociation constant of the enzyme-substrate complex, Ks, increases from Ks = 30 microM (plasma membranes) to Ks = 90 microM (isolated enzyme). ATP binding to the H(+)-ATPase ('single turnover' conditions) for the isolated and the reconstituted enzyme resulted in both cases in a second-order rate constant k1 = 2.6 x 10(4) M-1.s-1. From these observations it is concluded that the detergent used (Zwittergent TM 3-14) interacts reversibly with the H(+)-ATPase and that practically all H(+)-ATPase molecules are reconstituted into the liposomes with the ATP-binding site being directed to the outside of the vesicle.

Measurement of steady-state Ca2+ pump current caused by purified Ca2(+)-ATPase of sarcoplasmic reticulum incorporated into a planar bilayer lipid membrane.

The electrogenicity and some molecular properties of the sarcoplasmic reticulum Ca2+ pump protein were studied by measuring steady-state Ca2+ pump currents. Ca2(+)-ATPase protein was solubilized from rabbit skeletal muscle sarcoplasmic reticulum membrane preparations and purified by liquid chromatography. The purified Ca(+)-ATPase molecules were reconstituted into proteoliposomes and then incorporated by fusion into a planar bilayer lipid membrane. Short circuit currents across the planar membrane were detected when the ATPase molecules were activated by addition of ATP under optimal ionic conditions. Thus, the electrogenicity of the Ca2+ pump molecules was directly demonstrated. The amplitude of the pump current was dependent on the ATP concentration, and the relation was described by a Michaelis-Menten-type equation. The Michaelis constant was calculated to be 0.69 +/- 0.16 mM, which agrees well with the dissociation constant for a low affinity ATP-binding site deduced previously from the kinetics of ATP hydrolysis and from ATP binding.

Defective H+-ATPase of Hygromycin B-resistant pma1 Mutants from Saccharomyces cerevisiae

Mutations in the plasma membrane H(+)-ATPase gene (PMA1) of Saccharomyces cerevisiae that confer growth resistance to hygromycin B have been shown recently to cause a marked depolarization of whole cell membrane potential (Perlin, D. S., Brown, C. L., and Haber, J. E. (1988) J. Biol. Chem. 263, 18118-18122). In this report, the biochemical and genetic properties of H+-ATPases from four prominent hygromycin B-resistant pma1 mutants, pma1-105, pma1-114, pma1-147, and pma1-155, are described. Single base pair changes were identified in pma1-105, pma1-114, and pma1-147 that resulted in amino acid substitutions of Ser-368----Phe, Gly-158----Asp, Pro-640----Leu, respectively. An A----G transition mutation at -39 in the 5'-untranslated region of the mRNA of pma1-155 was also found. This mutation creates an out-of-Frame upstream AUG initiation codon that apparently reduces normal translation of PMA1. DNA sequence analysis of PMA1 from strain Y55 identified 9 base pair substitutions that resulted in 6 amino acid changes in nonconserved regions when compared to the published sequence for strain S288C. Plasma membranes of three of the four pma1 mutants contained normal amounts of H(+)-ATPase; membranes from pma1-155 contained enzyme at 62% of the wild-type level. The kinetics of ATP hydrolysis were most strongly altered for enzymes from pma1-105 and pma1-147 which showed changes in both Km and Vmax. A striking pH dependence for these parameters was found for enzyme from pma1-105 which resulted in a precipitous decline in Km and Vmax below pH 6.5. ATP hydrolysis by enzymes from pma1-105 and pma1-147 was insensitive to inhibition by vanadate. These enzymes, in contrast to wild-type and vanadate-sensitive mutant enzymes, were poorly protected from trypsin-induced inactivation by MgATP and vanadate or Pi alone. These results are pertinent to the mechanism of vanadate-induced enzyme inhibition and suggest that Ser-368 and Pro-640 influence the affinity of the phosphate-binding site for Pi. All mutant enzymes catalyzed ATP-induced pH gradient formation following purification and reconstitution into liposomes. Finally, these results further demonstrate the usefulness of hygromycin B as a generalized screening tool for isolating diverse plasma membrane ATPase mutants.

Kinetic characterization of the unisite catalytic pathway of seven β-subunit mutant F1-ATPases from Escherichia coli

Abstract We have studied the kinetics of ATP hydrolysis and synthesis in seven mutant Escherichia coli F1-ATPase enzymes. The seven mutations are distributed over a 105-residue segment of the catalytic nucleotide-binding domain in beta-subunit and are: G142S, K155Q, K155E, E181Q, E192Q, M209I, and R246C. We report forward and reverse rate constants and equilibrium constants in all seven mutant enzymes for the four steps of unisite kinetics, namely (i) ATP binding/release, (ii) ATP hydrolysis/synthesis, (iii) Pi release/binding, and (iv) ADP release/binding. The seven mutant enzymes displayed a wide range of deviations from normal in both rate and equilibrium constants, with no discernible common pattern. Notably, steep reductions in Kd ATP were seen in some cases, the value of Kd Pi was high, and K2 (ATP hydrolysis/synthesis) was relatively unaffected. Significantly, when the data from the seven mutations were combined with previous data from two other E. coli F1-beta-subunit mutations (D242N, D242V), normal E. coli F1, soluble and membranous mitochondrial F1, it was found that linear free energy relationships obtained for both ATP binding/release (log k+1 versus log K1) and ADP binding/release (log k-4 versus log K-4). Two conclusions follow. 1) The seven mutations studied here cause subtle changes in interactions between the catalytic nucleotide-binding domain and substrate ATP or product ADP. 2) The mitochondrial, normal E. coli, and nine total beta-subunit mutant enzymes represent a continuum in which subtle structural differences in the catalytic site resulted in changes in binding energy; therefore insights into the nature of energy coupling during ATP hydrolysis and synthesis by F1-ATPase may be ascertained by detailed studies of this group of enzymes.

Kinetics of ATP hydrolysis and tension production in skinned cardiac muscle of the guinea pig.

The kinetics of ATP hydrolysis and tension responses were studied simultaneously in a permeabilized preparation of cardiac tissue of the guinea pig. This was achieved by combining laserflash photolysis of P3-1-(2-nitrophenyl)ethyladenosine 5'-triphosphate ("caged-ATP") and a rapid freezing technique. In the presence of calcium ions, tension increased following the photolytic production of ATP with a half-time of 0.3 s. The timecourse of ATP hydrolysis consisted of an initial rapid phase followed by a steady-state hydrolysis rate of 0.4 s-1, indicating that the rate-limiting step of the ATPase in isometric fibers is slower and subsequent to the nucleotide hydrolysis step: the isometric steady state intermediate is probably an actomyosin-ADP complex. In the absence of calcium ions, rigor tension decreased upon the photolytic production of ATP with a half-time of 0.45 s. The time course of ATP hydrolysis was biphasic with a rapid initial phase of ATP hydrolysis, followed by a steady-state hydrolysis rate which was too slow to measure over the time scale of these experiments (less than 0.04 s-1). A comparison of the results obtained in this study with those reported for rabbit skeletal muscle reveals qualitative similarities between cardiac and skeletal muscle and also quantitative differences in their physiological and kinetic behavior.

Energy-induced modulation of the kinetics of oxidative phosphorylation and reverse electron transfer.

The kinetics of ATP synthesis by bovine heart submitochondrial particles (SMP) are modulated by the rate of energy production by the respiratory chain between two fixed limits characterized by apparent KmADP = 2-4 microM and Vmax approximately 200 nmol of ATP min-1 (mg of SMP protein)-1 at low energy levels and apparent KmADP = 120-160 microM and Vmax = 11,000 nmol of ATP min-1 (mg of SMP protein)-1 at high energy levels. These data indicate that KmADP and Vmax increase approximately 50-fold each; therefore, there is essentially no change in the catalytic efficiency of the ATP synthase complex in going from one extreme to the other. At intermediate rates of energy production, the kinetic data required introduction of a third, intermediate KmADP. A KmADP of 10-15 microM fitted all the data reported here and previously [Matsuno-Yagi, A., & Hatefi, Y. (1986) J. Biol. Chem. 261, 14031-14038]. However, this is not meant to suggest that there is a fixed intermediate KmADP, as the transition from one fixed limit to the other may be fluid or involve more than one intermediate state. In addition, it has been shown that kinetic plots of SMP-catalyzed and ATP-driven reverse electron transfer from succinate to NAD are curvilinear and resolvable into a minimum of two apparent KmNAD values of about 20-30 and 200-300 microM. These results have been discussed in relation to the three potentially active catalytic sites of F1-ATPase and the structure of the NADH:ubiquinone oxidoreductase complex, the curvilinear kinetics of ATP hydrolysis, and changes in KmADP and KmPi in photophosphorylation as affected by the duration and intensity of light.

Characterization of three-subunit chloroplast coupling factor.

The delta- and epsilon-polypeptides were removed from chloroplast coupling factor 1 (CF1). The resulting enzyme, CF1(-delta, epsilon), is a stable active ATPase containing only alpha-, beta-, and gamma-polypeptides. The dependence of the steady-state kinetics of ATP hydrolysis catalyzed by CF1(-delta, epsilon) on the concentrations of ATP and ADP was found to be essentially the same as by activated CF1. Nucleotide binding studies with CF1(-delta, epsilon) revealed three binding sites: a nondissociable ADP site (site 1), a tight MgATP binding site (site 2), and a site that binds ADP and ATP with a dissociation constant in the micromolar range (site 3). Similar results have been obtained with CF1. For both CF1 and CF1(-delta, epsilon), the binding of MgATP at site 2 is tight only in the presence of Mg2+. Fluorescence resonance energy transfer was used to map distances between the gamma-sulfhydryl ("dark" site) and gamma-disulfide and between the gamma-sulfhydryl and the three nucleotide sites. These distances are within 5% of the corresponding distances on CF1. These results indicate that removal of the delta- and epsilon-polypeptides from CF1 does not cause significant changes in the structure, kinetics, and nucleotide binding sites of the enzyme.

Stimulation of glucosylated lens epithelial Na,K-ATPase by an aldose reductase inhibitor

In diabetes, glucosylation of the Na,K-ATPase of the lens epithelium makes the pump inefficient. K+ transport and ATP hydrolysis (at near saturating ATP concentrations) are inhibited and the kinetics of ATP hydrolysis become substrate inhibition type. The AR inhibitor (AL1576, Alcon Laboratories) stimulates K+ transport and ATP hydrolysis by glucosylated bovine lens Na,K-ATPase. This inhibitor has a slight stimulatory effect upon the unmodified enzyme function also. The AR inhibitor is not able to prevent glucosylation of the pump in high-glucose-containing medium.

Left-handed Z-DNA binding by the recA protein of Escherichia coli.

recA binding to left-handed Z-DNA was measured using nitrocellulose filter binding assays with four DNA polymers with defined nucleotide sequences and four recombinant plasmids. Two to 7-fold preferential binding of recA to Z-DNA polymers was observed. Left-handed Z-DNA polymer binding by recA required ATP or its nonhydrolyzable analog, ATP(gamma S), while ADP inhibited binding. Complex formation with both B- and Z-forms was influenced by polymer length; recA bound longer DNAs better. recA binding to recombinant plasmids containing supercoil-stabilized Z-DNA was essentially similar to that found for the control vector; thus, no preferential binding of recA to the Z-form was observed. Comparative experiments with the rec1 protein of Ustilago maydis and the Escherichia coli recA protein were performed. In our hands, recA and rec1 have a similar capacity for binding left-handed Z-DNA polymers and for binding recombinant plasmids containing B- and/or Z-regions. recA contains a left-handed Z-DNA-stimulated ATPase activity. This activity differs from the right-handed B-DNA-stimulated activity since it is less sensitive to increasing pH. The kinetics of ATP hydrolysis in B-DNA/Z-DNA mixing experiments showed that the turnover of the Z-DNA recA complex was slower than for B-DNA suggesting that left-handed Z-DNA is more stably bound by recA. Our results are consistent with the postulate that left-handed Z-DNA is involved in genetic recombination.

Kinetics of ATP hydrolysis catalyzed by isolated TF1 and reconstituted TF0F1 ATPase.

The rate of ATP hydrolysis catalyzed by isolated TF1 and reconstituted TF0F1 was measured as a function of the ATP concentration in the presence of inhibitors [ADP, Pi and 3'-O-(1-naphthoyl)ATP]. ATP hydrolysis can be described by Michaelis-Menten kinetics with Km(TF1) = 390 microM and Km (TF0F1) = 180 microM. The inhibition constants are for ADP Ki(TF1) = 20 microM and Ki(TF0F1) = 100 microM, for 3'-O-(1-naphthoyl)ATP Ki(TF1) = 150 microM and Ki(TF0F1) = 3 microM, and for Pi Ki(TF1) = 60 mM. From these results it is concluded that upon binding of TF0 to TF1 the mechanism of ATP hydrolysis catalyzed by TF1 is not changed qualitatively; however, the kinetic constants differ quantitatively.

Phosphate burst in permeable muscle fibers of the rabbit

The transient kinetics of ATP hydrolysis in chemically skinned psoas muscle fibers of the rabbit have been measured. Muscles fibers in the rigor state (absence of nucleotide) were relaxed rapidly by the photochemical release of [2-3H]ATP from caged-ATP (P3-1-(2-nitro)phenylethyl[2-3H]adenosine 5'-triphosphate) in the absence of calcium ions. Rapid freezing of the fiber to stop hydrolysis, followed by analysis of the tritiated nucleotide content allowed the course of the hydrolysis to be determined. The timecourse of ATP hydrolysis was biphasic, with an initial rapid phase occurring at a rate of approximately 60 s-1 at 12 degrees C for fibers exposed to greater than 0.7 mM ATP. The amplitude of the rapid phase was as previously reported (Ferenczi, M. A., E. Homsher, and D. R. Trentham, 1984, J. Physiol. (Lond.)., 352:575-599).

Steady state kinetic studies of purified yeast plasma membrane proton-translocating ATPase.

The plasma membrane H+-ATPase from bakers' yeast was purified and reconstituted with phosphatidylserine. The steady state kinetics of ATP hydrolysis catalyzed by the H+-ATPase were studied over a wide range of Mg2+ and ATP concentrations. Whereas MgATP was the substrate hydrolyzed, excess concentrations of either Mg2+ or ATP were inhibitory. The dependence of the steady state initial velocity of ATP hydrolysis on the concentration of MgATP at a fixed concentration of Mg2+ was sigmoidal rather than hyperbolic. This precluded mechanisms involving only activation and inhibition by Mg2+ and competitive inhibition by ATP. Two alternative interpretations of these results are: 1) the enzyme possesses multiple catalytic sites which interact cooperatively; or 2) the enzyme can exist in multiple conformational states which catalyze MgATP hydrolysis by parallel pathways. The rate laws for both mechanisms are identical so that the two mechanisms cannot be distinguished on the basis of the kinetic data. The data are well fit by the rate law for these mechanisms with the inclusion of competitive inhibition by Mg2+ and ATP and an independent inhibition site for Mg2+.