Determination of rate constants for nucleotide dissociation from Na,K-ATPase.

A method for determining individual rate constants for nucleotide binding to and dissociation from membrane bound pig kidney Na,K-ATPase is presented. The method involves determination of the rate of relaxation when Na,K-ATPase in the presence of eosin is mixed with ADP or ATP in a stopped-flow fluorescence apparatus. It is shown that the nucleotide dependence of this rate of relaxation--taken together with measured equilibrium binding values for eosin and ADP--makes possible a reasonably reliable determination of the rate constant for dissociation of nucleotide, i.e., determination of the rate constant k-1 in the following model (where E denotes Na,K-ATPase): [formula: see text] All experiments are carried out at about 4 degrees C in a buffer containing 200 mM sucrose, 10 mM EDTA, 25 mM Tris and 73 mM NaCl (pH 7.4). Values obtained for the rate constants for dissociation are about 6 s-1 for ADP and 2-3 s-1 for ATP.     

The Caulobacter crescentus CgtA Protein Displays Unusual Guanine Nucleotide Binding and Exchange Properties

The Caulobacter crescentus CgtA protein is a member of the Obg-GTP1 subfamily of monomeric GTP-binding proteins. In vitro, CgtA specifically bound GTP and GDP but not GMP or ATP. CgtA bound GTP and GDP with moderate affinity at 30 degrees C and displayed equilibrium binding constants of 1.2 and 0.5 microM, respectively, in the presence of Mg(2+). In the absence of Mg(2+), the affinity of CgtA for GTP and GDP was reduced 59- and 6-fold, respectively. N-Methyl-3'-O-anthranoyl (mant)-guanine nucleotide analogs were used to quantify GDP and GTP exchange. Spontaneous dissociation of both GDP and GTP in the presence of 5 to 12 mM Mg(2+) was extremely rapid (k(d) = 1.4 and 1.5 s(-1), respectively), 10(3)- to 10(5)-fold faster than that of the well-characterized eukaryotic Ras-like GTP-binding proteins. The dissociation rate constant of GDP increased sevenfold in the absence of Mg(2+). Finally, there was a low inherent GTPase activity with a single-turnover rate constant of 5.0 x 10(-4) s(-1) corresponding to a half-life of hydrolysis of 23 min. These data clearly demonstrate that the guanine nucleotide binding and exchange properties of CgtA are different from those of the well-characterized Ras-like GTP-binding proteins. Furthermore, these data are consistent with a model whereby the nucleotide occupancy of CgtA is controlled by the intracellular levels of guanine nucleotides.     

Na(+) occupancy and Mg(2+) block of the n-methyl-d-aspartate receptor channel

The effect of extracellular and intracellular Na(+) on the single-channel kinetics of Mg(2+) block was studied in recombinant NR1-NR2B NMDA receptor channels. Na(+) prevents Mg(2+) access to its blocking site by occupying two sites in the external portion of the permeation pathway. The occupancy of these sites by intracellular, but not extracellular, Na(+) is voltage-dependent. In the absence of competing ions, Mg(2+) binds rapidly (>10(8) M(-1)s(-1), with no membrane potential) to a site that is located 0.60 through the electric field from the extracellular surface. Occupancy of one of the external sites by Na(+) may be sufficient to prevent Mg(2+) dissociation from the channel back to the extracellular compartment. With no membrane potential; and in the absence of competing ions, the Mg(2+) dissociation rate constant is >10 times greater than the Mg(2+) permeation rate constant, and the Mg(2+) equilibrium dissociation constant is approximately 12 microM. Physiological concentrations of extracellular Na(+) reduce the Mg(2+) association rate constant approximately 40-fold but, because of the "lock-in" effect, reduce the Mg(2+) equilibrium dissociation constant only approximately 18-fold.     

Anion interactions with Na,K-ATPase: simultaneous binding of nitrate and eosin

Nucleotide binding affinity to Na,K-ATPase is reduced by a number of anions such as nitrate and perchlorate in comparison with affinity in the presence of chloride (all with sodium as the cation). The reduction correlates with the position of these anions in the Hofmeister series. Transient kinetic experiments using the fluorescent dye eosin—which binds to the nucleotide site of the Na,K-ATPase—show that simultaneous anion binding, exemplified with nitrate, and eosin binding is possible. The effect of nitrate on eosin binding is reflected in a decreased binding-rate constant and an increased dissociation rate constant, leading to a decreased equilibrium binding constant for eosin. Since eosin binding is analogous with nucleotide binding to Na,K-ATPase, the results suggest the simultaneous presence of nucleotide and anion binding sites.Abbreviations E₁ the protein conformation in Na⁺ - E₂ the enzyme conformation in K⁺ - Eo eosin (tetrabromofluorescein) - F fluorescence - I ionic strength - k_i rate constant - K_i equilibrium dissociation constant - K_i,0 equilibrium dissociation constant at zero ionic strength - N nitrate - z_i net charge - charge product z_i·z_j     

Carbodiimide inactivation of Na,K-ATPase, via intramolecular cross-link formation, is due to inhibition of phosphorylation

We have recently shown that inactivation of renal Na,K-ATPase by 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide occurs via an intramolecular cross-link formed between an activated carboxyl group and an endogenous nucleophile (Pedemonte, C.H., and Kaplan, J.H. (1986) J. Biol. Chem. 261, 3632-3639). The modified enzyme shows the same level of Rb+ binding as untreated enzyme: 3.16 and 2.93 ATP-sensitive mumol of Rb+ binding/mumol of phosphoenzyme, respectively. Thus, the Rb+ binding site and the transition accomplished by low affinity nucleotide binding which accelerates de-occlusion are not greatly affected by the carbodiimide inactivation. 1 mM K+ reduces the ADP binding to the high affinity nucleotide binding site to the same extent in normal and 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide-treated enzyme and Na+ counteracts this effect. Thus, the competition between Na+ and K+ ions for binding to the free enzyme are also largely unaltered by the modification. Phosphorylation from ATP (microM) in the presence of Na+ and Mg2+ ions and from inorganic phosphate in the presence of Mg2+ ions (in the absence or presence of ouabain) is greatly inhibited (85%) following carbodiimide treatment. The extent of inhibition of phosphorylation quantitatively correlates with the residual Na,K-ATPase activity (15%). Consequently, the rate of inactivation by carbodiimide is reduced when a greater proportion of the enzyme is in the phosphorylated form. Fluoroscein isothiocyanate, which inhibits the Na,K-ATPase by covalently modifying a lysine residue close to the high affinity binding site for ATP in the alpha-subunit does not bind to the carbodiimide-inactivated enzyme. Since high affinity nucleotide binding is only partially inhibited by the modification produced by the carbodiimide this suggests that the lysine residue to which fluoroscein isothiocyanate binds is not specifically required for competent nucleotide binding.     

Factors affecting the inhibition of yeast plasma membrane ATPase by vanadate

Inhibition of yeast plasma membrane ATPase by vanadate occurs only if either Mg2+ or MgATP2- is bound to the enzyme. The dissociation constant of the complex of vanadate and inhibitory sites is 0.14-0.20 microM in the presence of optimal concentrations of Mg2+ and of the order of 1 microM if the enzyme is saturated with MgATP2-. The dissociation constants of Mg2+ and MgATP2- for the sites involved are 0.4 and 0.62-0.73 mM, respectively, at pH 7. KCl does not increase the affinity of vanadate to the inhibitory sites as was found with (Na+ + K+)-ATPase. On the other hand, the effect of Mg2+ upon vanadate binding is similar to that upon (Na+ + K+)-ATPase, and the corresponding affinity constants of Mg2+ and vanadate for the two enzymes are of the same order of magnitude.     

Characteristics of the combination of inhibitory Mg2+ and azide with the F1 ATPase from chloroplasts.

The interactions between ADP, Mg2+, and azide that result in the inhibition of the chloroplast F1 ATPase (CF1) have been explored further. The binding of the inhibitory Mg2+ with low Kd is shown to occur only when tightly bound ADP is present at a catalytic site. Either the tightly bound ADP forms part of the Mg(2+)-binding site or it induces conformational changes creating the high-affinity site for inhibitory Mg2+. Kinetic studies show that CF1 forms two catalytically inactive complexes with Mg2+. The first complex results from Mg2+ binding with a Kd for Mg2+ dissociation of about 10-15 microM, followed by a slow conversion to a complex with a Kd of about 4 microM. The rate-limiting step of the CF1 inactivation by Mg2+ is the initial Mg2+ binding. When medium Mg2+ is chelated with EDTA, the two complexes dissociate with half-times of about 1 and 7 min, respectively. Azide enhances the extent of Mg(2+)-dependent inactivation by increasing the affinity of the enzyme for Mg2+ 3-4 times and prevents the reactivation of both complexes of CF1 with ADP and Mg2+. This results from decreasing the rate of Mg2+ release; neither the rate of Mg2+ binding to CF1 nor the rate of isomerization of the first inactive complex to the more stable form is affected by azide. This suggests that the tight-binding site for the inhibitory azide requires prior binding of both ADP and Mg2+.     

ADP binding to TF1 and its subunits induces ultraviolet spectral changes

Adenine nucleotide binding sites on the coupling factor ATPase of thermophilic bacterium PS3 (TF1) were investigated by UV spectroscopy and by equilibrium dialysis. When ADP was mixed with TF1 in the presence and in the absence of Mg2+, an UV absorbance change was induced (t1/2 approximately 1 min) with a peak at about 278 nm and a trough at about 250 nm. Similar spectral changes were induced by ADP with the isolated beta subunits in the presence and in the absence of Mg2+, and with the isolated alpha subunits in the presence of Mg2+ although the magnitudes of the changes were different. From equilibrium dialysis measurement we identified two classes of nucleotide binding sites in TF1 in the presence of Mg2+, three high-affinity sites (Kd = 61 nM) and three low-affinity sites (Kd = 87 microM). In the absence of Mg2+, TF1 has one high-affinity site (Kd less than 10 nM) and five low-affinity sites (Kd = 100 microM). Moreover, we found a single Mg2+-dependent ADP binding site on the isolated alpha subunit and a single Mg2+-independent ADP binding site on the isolated beta subunit. From the above observations, we concluded that the three Mg2+-dependent high-affinity sites for ADP are located on the alpha subunit in TF1 and that the single high-affinity site is located on one of the beta subunits in TF1 in the absence of Mg2+.     

Interaction of sodium and potassium ions with Na+,K+-ATPase. II. General properties of ouabain-sensitive K+ binding

General properties of ouabain-sensitive K+ binding to purified Na+,K+-ATPase [EC 3.6.1.3] were studied by a centrifugation method with 42K+. 1) The affinity for K+ was constant at pH values higher than 6.4, and decreased at pH values lower than 6.4. 2) Mg2+ competitively inhibited the K+ binding. The dissociation constant (Kd) for Mg2+ of the enzyme was estimated to be about 1 mM, and the ratio of Kd for Mg2+ to Kd for K+ was 120 : 1. The order of inhibitory efficiency of divalent cations toward the K+ binding was Ba2+ congruent to Ca2+ greater than Zn2+ congruent to Mn2+ greater than Sr2+ greater than Co2+ greater than Ni2+ greater than Mg2+. 3) The order of displacement efficiency of monovalent cations toward the K+ binding in the presence or absence of Mg2+ was Tl+ greater than Rb+ greater than or equal to (K+) greater than NH4+ greater than or equal to Cs+ greater than Na+ greater than Li+. The inhibition patterns of Na+ and Li+ were different from those of other monovalent cations, which competitively inhibited the K+ binding. 4) The K+ binding was not influenced by different anions, such as Cl-, SO4(2-), NO3-, acetate, and glycylglycine, which were used for preparing imidazole buffers. 5) Gramicidin D and valinomycin did not affect the K+ binding, though the former (10 micrograms/ml) inhibited the Na+,K+-ATPase activity by about half. Among various inhibitors of the ATPase, 0.1 mM p-chloromercuribenzoate and 0.1 mM tri-n-butyltin chloride completely inhibited the K+ binding. Oligomycin (10 micrograms/ml) and 10 mM N-ethylmaleimide had no effect on the K+ binding. In the presence of Na+, however, oligomycin decreased the K+ binding by increasing the inhibitory effect of Na+, whether Mg2+ was present or not. 6) ATP, adenylylimido diphosphate and ADP each at 0.2 mM decreased the K+ binding to about one-fourth of the original level at 10 microM K+ without MgCl2 and at 60 microM K+ with 5 mM MgCl2. On the other hand, AMP, Pi, and p-nitrophenylphosphate each at 0.2 mM had little effect on the K+ binding.     

Distinct MutS DNA-binding modes that are differentially modulated by ATP binding and hydrolysis.

The role of MutS ATPase in mismatch repair is controversial. To clarify further the function of this activity, we have examined adenine nucleotide effects on interactions of Escherichia coli MutS with homoduplex and heteroduplex DNAs. In contrast to previous results with human MutS alpha, we find that a physical block at one end of a linear heteroduplex is sufficient to support stable MutS complex formation in the presence of ATP.Mg(2+). Surface plasmon resonance analysis at low ionic strength indicates that the lifetime of MutS complexes with heteroduplex DNA depends on the nature of the nucleotide present when MutS binds. Whereas complexes prepared in the absence of nucleotide or in the presence of ADP undergo rapid dissociation upon challenge with ATP x Mg(2+), complexes produced in the presence of ATP x Mg(2+), adenosine 5'-(beta,gamma-imino)triphosphate (AMPPNP) x Mg(2+), or ATP (no Mg(2+)) are resistant to dissociation upon ATP challenge. AMPPNP x Mg(2+) and ATP (no Mg(2+)) reduce MutS affinity for heteroduplex but have little effect on homoduplex affinity, resulting in abolition of specificity for mispaired DNA at physiological salt concentrations. Conversely, the highest mismatch specificity is observed in the absence of nucleotide or in the presence of ADP. ADP has only a limited effect on heteroduplex affinity but reduces MutS affinity for homoduplex DNA.     

Mechanism of inhibition of skeletal muscle actomyosin by N-benzyl-p-toluenesulfonamide

N-Benzyl-p-toluenesulfonamide (BTS) is a small organic molecule that specifically inhibits the contraction of fast skeletal muscle fibers. To determine the mechanism of inhibition by BTS, we performed a kinetic analysis of its effects on the elementary steps of the actomyosin subfragment-1 ATPase cycle. BTS decreases the steady-state acto-S1 ATPase rate approximately 10-fold and increases the actin concentration for half-maximal activation. BTS primarily affects three of the elementary steps of the reaction pathway. It decreases the rate of P(i) release >20-fold in the absence of actin and >100-fold in the presence of actin. It decreases the rate of S1.ADP dissociation from 3.9 to 0.8 s(-)(1) while decreasing the S1.ADP dissociation constant from 2.3 to 0.8 microM. BTS weakens the apparent affinity of S1.ADP for actin, increasing the K(d) from 7.0 to 29.5 microM. ATP binding to S1, hydrolysis, and the affinity of nucleotide-free S1 for actin are unaffected by BTS. Kinetic modeling indicates that the binding of BTS to myosin depends on actin association/dissociation and on nucleotide state. Our results suggest that the reduction of the acto-S1 ATPase rate is due to the inhibition of P(i) release, and the suppression of tension is due to inhibition of P(i) release in conjunction with the decreased apparent affinity of S1.ADP.P(i) and S1.ADP for actin.     

The characteristics and effect on catalysis of nucleotide binding to noncatalytic sites of chloroplast F1-ATPase.

The recent finding that the presence of ATP at non-catalytic sites of chloroplast F1-ATPase (CF1) is necessary for ATPase activity (Milgrom, Y. M., Ehler, L. L., and Boyer, P. D. (1990) J. Biol. Chem. 265,18725-18728) prompted more detailed studies of the effect of noncatalytic site nucleotides on catalysis. CF1 containing at noncatalytic sites less than one ADP or about two ATP was prepared by heat activation in the absence of Mg2+ and in the presence of ADP or ATP, respectively. After removal of medium nucleotides, the CF1 preparations were used for measurement of the time course of nucleotide binding from 10 to 100 microM concentrations of 3H-labeled ADP, ATP, or GTP. The presence of Mg2+ strongly promotes the tight binding of ADP and ATP at noncatalytic sites. For example, the ADP-heat-activated enzyme in presence of 1 mM Mg2+ binds ADP with a rate constant of 0.5 x 10(6) M-1 min-1 to give an enzyme with two ADP at noncatalytic sites with a Kd of about 0.1 microM. Upon exposure to Mg2+ and ATP the vacant noncatalytic site binds an ATP rapidly and, as an ADP slowly dissociates, a second ATP binds. The binding correlates with an increase in the ATPase activity. In contrast the tight binding of [3H]GTP to noncatalytic sites gives an enzyme with no ATPase activity. The three noncatalytic sites differ in their binding properties. The noncatalytic site that remains vacant after the ADP-heat-activated CF1 is exposed to Mg2+ and ADP and that can bind ATP rapidly is designated as site A; the site that fills with ATP as ADP dissociates when this enzyme is exposed to Mg2+ and ATP is called site B, and the site to which ADP remains bound is called site C. Procedures are given for attaining CF1 with ADP at sites B and C, with GTP at sites A and/or B, and with ATP at sites A, B, and/or C, and catalytic activities of such preparations are measured. For example, little or no ATPase activity is found unless ATP is at site A, but ADP can remain at site C with no effect on ATPase. Maximal GTPase activity requires ATP at site A but about one-fifth of maximal GTPase is attained when GTP is at sites A and B and ATP at site C. Noncatalytic site occupancy can thus have profound effects on the ATPase and GTPase activities of CF1.     

Mg2+ is not catalytically required in the intrinsic and kirromycin-stimulated GTPase action of Thermus thermophilus EF-Tu

The influence of divalent metal ions on the intrinsic and kirromycin-stimulated GTPase activity in the absence of programmed ribosomes and on nucleotide binding affinity of elongation factor Tu (EF-Tu) from Thermus thermophilus prepared as the nucleotide- and Mg(2+)-free protein has been investigated. The intrinsic GTPase activity under single turnover conditions varied according to the series: Mn(2+) (0.069 min(-1)) > Mg(2+) (0.037 min(-1)) approximately no Me(2+) (0.034 min(-1)) > VO(2+) (0.014 min(-1)). The kirromycin-stimulated activity showed a parallel variation. Under multiple turnover conditions (GTP/EF-Tu ratio of 10:1), Mg(2+) retarded the rate of hydrolysis in comparison to that in the absence of divalent metal ions, an effect ascribed to kinetics of nucleotide exchange. In the absence of added divalent metal ions, GDP and GTP were bound with equal affinity (K(d) approximately 10(-7) m). In the presence of added divalent metal ions, GDP affinity increased by up to two orders of magnitude according to the series: no Me(2+) < VO(2+) < Mn(2+) approximately Mg(2+) whereas the binding affinity of GTP increased by one order of magnitude: no Me(2+) < Mg(2+) < VO(2+) < Mn(2+). Estimates of equilibrium (dissociation) binding constants for GDP and GTP by EF-Tu on the basis of Scatchard plot analysis, together with thermodynamic data for hydrolysis of triphosphate nucleotides (Phillips, R. C., George, P., and Rutman, R. J. (1969) J. Biol. Chem. 244, 3330-3342), showed that divalent metal ions stabilize the EF-Tu.Me(2+).GDP complex over the protein-free Me(2+).GDP complex in solution, with the effect greatest in the presence of Mg(2+) by approximately 10 kJ/mol. These combined results show that Mg(2+) is not a catalytically obligatory cofactor in intrinsic and kirromycin-stimulated GTPase action of EF-Tu in the absence of programmed ribosomes, which highlights the differential role of Mg(2+) in EF-Tu function.     

Kinetic analyses of a truncated mammalian myosin I suggest a novel isomerization event preceding nucleotide binding

MI(1IQ) is a complex of calmodulin and an epitope-tagged 85-kDa fragment representing the amino-terminal catalytic motor domain and the first of 6 calmodulin-binding IQ domains of the mammalian myosin I gene, rat myr-1 (130-kDa myosin I or MI(130)). We have determined the transient kinetic parameters that dictate the ATP hydrolysis cycle of mammalian myosin I by examining the properties of MI(1IQ). Transient kinetics reveal that the affinity of MI(1IQ) for actin is 12 nm. The ATP-induced dissociation of actin-MI(1IQ) is biphasic. The fast phase is dependent upon [ATP], whereas the slow phase is not; both phases show a Ca(2+) sensitivity. The fast phase is eliminated by the addition of ADP, 10 micrometer being required for half-saturation of the effect in the presence of Ca(2+) and 3 micrometer ADP in the absence of Ca(2+). The slow phase shares the same rate constant as ADP release (8 and 3 s(-)(1) in the presence and absence of Ca(2+), respectively), but cannot be eliminated by decreasing [ADP]. We interpret these results to suggest that actin-myosin I exists in two forms in equilibrium, one of which is unable to bind nucleotide. These results also indicate that the absence of the COOH-terminal 5 calmodulin binding domains of myr-1 do not influence the kinetic properties of MI(130) and that the Ca(2+) sensitivity of the kinetics are in all likelihood due to Ca(2+) binding to the first IQ domain.     

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.     

Nucleotide Binding to Na,K-ATPase: The Role of Electrostatic Interactions.

The contribution of electrostatic forces to the interaction of Na,K-ATPase with adenine nucleotides was investigated by studying the effect of ionic strength on nucleotide binding. At pH 7.0 and 20 degrees C, there was a qualitative correlation between the equilibrium dissociation constant (K(d)) values for ATP, ADP, and MgADP and their total charges. All K(d) values increased with increasing ionic strength. According to the Debye-Hückel theory, this suggests that the nucleotide binding site and its ligands have "effective" charges of opposite signs. However, quantitative analysis of the dependence on ionic strength shows that the product of the effective electrostatic charges on the ligand and the binding site is the same for all nucleotides, and is therefore independent of the total charge of the nucleotide. The data suggest that association of nucleotides with Na,K-ATPase is governed by a partial charge rather than the total charge of the nucleotide. This charge, interacting with positive charges on the protein, is probably the one corresponding to the alpha-phosphate of the nucleotide. Dissociation rate constants measured in complementary transient kinetic experiments were 13 s(-1) for ATP and 27 s(-1) for ADP, independent of the ionic strength in the range 0.1-0.5 M. This implies similar association rate constants for the two nucleotides (about 40 x 10(6) M(-1) s(-1) at I = 0.1 M). The results suggest that long-range Coulombic forces, affecting association rates, are not the main contributors to the observed differences in affinities, and that local interactions, affecting dissociation rates, may play an even greater role.     

Further characterization of nucleotide binding sites on chloroplast coupling factor one

The solubilized coupling factor from spinach chloroplasts (CF1) contains one nondissociable ADP/CF1 which exchanges slowly with medium ADP in the presence of Ca2+, Mg2+, or EDTA; medium ATP also exchanges in the presence of Ca2+ or EDTA, but it is hydrolyzed, and only ADP is found bound to CF1. The rate of ATP exchange with heat-activated CF1 is approximately 1000 times slower than the rate of ATP hydrolysis. In the presence of Mg2+, both latent CF1 and heat-activated CF1 bind one ATP/CF1, in addition to the ADP. This MgATP is not removed by dialysis, by gel filtration, or by the substrate CaATP during catalytic turnover; however, it is released when the enzyme is stored several days as an ammonium sulfate precipitate. The photoaffinity label 3'-O-[3-[N-(4-azido-2-nitrophenyl)amino]-propionyl]-ATP binds to the MgATP site, and photolysis results in labeling of the beta subunit of CF1. Equilibrium binding measurements indicate that CF1 has two identical binding sites for ADP with a dissociation constant of 3.9 microM (in addition to the nondissociable ADP site). When MgATP is bound to CF1, one ADP binding site with a dissociation constant of 2.9 microM is found. One ATP binding site is found in addition to the MgATP site with a dissociation constant of 2.9 microM. Reaction of CF1 with the photoaffinity label 3'-O-[3-[N-(4-azido-2-nitrophenyl)amino]propionyl]-ADP indicates that the ADP binding site which is not blocked by MgATP is located near the interface of alpha and beta subunits. No additional binding sites with dissociation constants less than 200 micro M are observed for MgATP with latent CF1 and for CaADP with heat-activated CF1. Thus, three distinct nucleotide binding sites can be identified on CF1, and the tightly bound ADP and MgATP are not at the catalytic site. The active site is either the third ADP and ATP binding site or a site not yet detected.     

ATP inactivates hydrolysis of the K+-sensitive phosphoenzyme of kidney Na+,K+-transport ATPase and activates that of muscle sarcoplasmic reticulum Ca2+-transport ATPase

In order to characterize low affinity ATP-binding sites of renal (Na+,K+) ATPase and sarcoplasmic reticulum (Ca2+)ATPase, the effects of ATP on the splitting of the K+-sensitive phosphoenzymes were compared. ATP inactivated the dephosphorylation in the case of (Na+,K+)ATPase at relatively high concentrations, while activating it in the case of (Ca2+)ATPase. When various nucleotides were tested in place of ATP, inactivators of (Na+,K+)ATPase were found to be activators in (Ca2+)ATPase, with a few exceptions. In the absence of Mg2+, the half-maximum concentration of ATP for the inhibition or for the activation was about 0.35 mM or 0.25 mM, respectively. These values are comparable to the previously reported Km or the dissociation constant of the low affinity ATP site estimated from the steady-state kinetics of the stimulation of ATP hydrolysis or from binding measurements. By increasing the concentration of Mg2+, but not Na+, the effect of ATP on the phosphoenzyme of (Na+,K+)ATPase was reduced. On the other hand, Mg2+ did not modify the effect of ATP on the phosphoenzyme of (Ca2+)ATPase. During (Na+,K+)ATPase turnover, the low affinity ATP site appeared to be exposed in the phosphorylated form of the enzyme, but the magnesium-complexed ATP interacted poorly with the reactive K+-sensitive phosphoenzyme, which has a tightly bound magnesium, probably because of interaction between the divalent cations. In the presence of physiological levels of Mg2+ and K+, ATP appeared to bind to the (Na+,K+)ATPase only after the dephosphorylation, while it binds to the (Ca2+)-ATPase before the dephosphorylation to activate the turnover.     

Calcium binding to the H+,K(+)-ATPase. Evidence for a divalent cation site that is occupied during the catalytic cycle

The binding and conformational properties of the divalent cation site required for H+,K(+)-ATPase catalysis have been explored by using Ca2+ as a substitute for Mg2+. 45Ca2+ binding was measured with either a filtration assay or by passage over Dowex cation exchange columns on ice. In the absence of ATP, Ca2+ was bound in a saturating fashion with a stoichiometry of 0.9 mol of Ca2+ per active site and an apparent Kd for free Ca2+ of 332 +/- 39 microM. At ATP concentrations sufficient for maximal phosphorylation (10 microM), 1.2 mol of Ca2+ was bound per active site with an apparent Kd for free Ca2+ of 110 +/- 22 microM. At ATP concentrations greater than or equal to 100 microM, 2.2 mol of Ca2+ were bound per active site, suggesting that an additional mole of Ca2+ bound in association with low affinity nucleotide binding. At concentrations sufficient for maximal phosphorylation by ATP (less than or equal to 10 microM), APD, ADP + Pi, beta,gamma-methylene-ATP, CTP, and GTP were unable to substitute for ATP. Active site ligands such as acetyl phosphate, phosphate, and p-nitrophenyl phosphate were also ineffective at increasing the Ca2+ affinity. However, vanadate, a transition state analog of the phosphoenzyme, gave a binding capacity of 1.0 mol/active site and the apparent Kd for free Ca2+ was less than or equal to 18 microM. Mg2+ displaced bound Ca2+ in the absence and presence of ATP but Ca2+ was bound about 10-20 times more tightly than Mg2+. The free Mg2+ affinity, like Ca2+, increased in the presence of ATP. Monovalent cations had no effect on Ca2+ binding in the absence of ATP but dit reduce Ca2+ binding in the presence of ATP (K+ = Rb+ = NH4 + greater than Na+ greater than Li+ greater than Cs+ greater than TMA+, where TMA is tetramethylammonium chloride) by reducing phosphorylation. These results indicate that the Ca2+ and Mg2+ bound more tightly to the phosphoenzyme conformation. Eosin fluorescence changes showed that both Ca2+ and Mg2+ stabilized E1 conformations (i.e. cytosolic conformations of the monovalent cation site(s)) (Ca.E1 and Mg.E1). Addition of the substrate acetyl phosphate to either Ca.E1 or Mg.E1 produced identical eosin fluorescence showing that Ca2+ and Mg2+ gave similar E2 (extracytosolic) conformations at the eosin (nucleotide) site. In the presence of acetyl phosphate and K+, the conformations with Ca2+ or Mg2+ were also similar. Comparison of the kinetics of the phosphoenzyme and Ca2+ binding showed that Ca2+ bound prior to phosphorylation and dissociated after dephosphorylation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Interdependence of profilin, cation, and nucleotide binding to vertebrate non-muscle actin

The interaction of profilin and non-muscle beta,gamma-actin prepared from bovine spleen has been investigated under physiologic ionic conditions. Profilin binding to actin decreases the affinity of actin for MgADP and MgATP by about 65- and 13-fold, respectively. Kinetic measurements indicate that profilin binding to actin weakens the affinity of actin for nucleotides primarily due to an increased nucleotide dissociation rate constant, but the nucleotide association rate constant is also increased about 2-fold. Removal of the actin-bound nucleotide and divalent cation produces the labile intermediate species in the nucleotide exchange reaction, nucleotide free actin (NF-actin), and increases the affinity of actin for profilin about 10-fold. Profilin binds NF-actin with high affinity, K(D) = 0.013 microM, and slows the observed denaturation rate of NF-actin. Addition of ATP to NF-actin weakens the affinity for profilin and addition of Mg(2+) to ATP-actin further weakens the affinity for profilin. The high-affinity Mg(2+) of actin regulates binding of both nucleotide and profilin to actin and is important for actin interdomain coupling. The data suggest that profilin binding to actin weakens nucleotide binding to actin by disrupting Mg(2+) coordination in the actin central cleft.