Brain pyridoxal kinase. Mechanism of substrate addition, binding of ATP, and rotational mobility of the inhibitor pyridoxaloxime

The inhibition kinetic patterns obtained when ATP and pyridoxal analogues are used as inhibitors of the reaction catalyzed by pyridoxal kinase are consistent with a rapid equilibrium random Bi Bi, in which binary complexes, i.e. enzyme . ATP and enzyme . pyridoxal, are formed in kinetically significant amounts. Protein fluorescence quenching was used to determine the dissociation constant (Kd = 25 microM) of ATP . Zn bound to the nucleotide site of the kinase. The binding of ATP to the kinase induces a conformational change which is transmitted to other areas of the macromolecule. Pyridoxaloxime, a competitive inhibitor of pyridoxal, was used as a probe of the pyridoxal-binding site. It binds to the kinase with Ki = 2 microM and displays a fluorescent decay time of 7.8 ns. Time emission anisotropy measurements yield a rotational correlation time for bound pyridoxaloxime of approximately 2 ns, which is considerably shorter than the rotational correlation time of the protein (phi = 38 ns). The fast rotation of pyridoxaloxime remains unaffected by the binding of ATP.     

Spectroscopic studies on the mode of binding of ATP, UTP and alpha-amanitin with yeast RNA polymerase II

The binding affinity between the substrates ATP and UTP with the purified yeast RNA polymerase II have been studied here in the presence and absence of Mn2+. In the absence of template DNA, both ATP and UTP showed tight binding with the enzyme without preference for any specific nucleotide, unlike Escherichia coli RNA polymerase. Fluorescence titration of the tryptophan emission of the enzyme by nucleoside triphosphate substrates gave an estimated Kd value around 65 microM in the absence of Mn2+ whereas in the presence of Mn2+, the Kd was 20 microM. The effect of substrates on the longitudinal relaxation of the HDO proton in enzyme-substrate complex also yielded a similar Kd value.     

Reaction of two heads of gizzard myosin with ATP

The reaction intermediates formed by the two heads of smooth muscle myosin were studied. The amount of myosin-phosphate-ADP complex, MPADP, formed was measured from the Pi-burst size over a wide range of ATP concentrations. At low concentrations of ATP, the Pi-burst size was 0.5 mol/mol myosin head, and the apparent Kd value was about 0.15 microM. However, at high ATP concentrations, the Pi burst size increased from 0.5 to 0.75 mol/mol myosin head with an observed Kd value of 15 microM. The binding of nucleotides to gizzard myosin during the ATPase reaction was directly measured by a centrifugation method. Myosin bound 0.5 mol of nucleotides (ATP and ADP) with high affinity (Kd congruent to 1 microM) and 0.35 mol of nucleotides with low affinity (Kd = 24 microM) for ATP. These results indicate that gizzard myosin has two kinds of nucleotide binding sites, one of which forms MPADP with high affinity for ATP while the other forms MPADP and MATP with low affinity for ATP. We studied the correlation between the formation of MPADP and the dissociation of actomyosin. The amount of Pi-burst size was not affected by the existence of F-actin, and when 0.5 mol of ATP per mol of myosin head was added to actomyosin (1 mg/ml F-actin, 5 microM myosin at 0 degrees C) most (93%) of the added ATP was hydrolyzed in the Pi-burst phase. All gizzard actomyosin dissociated when 1 mol of ATP per mol myosin head was added to actomyosin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mg X ATP2-dependent interaction of the inhibitor protein of the cAMP-dependent protein kinase with the catalytic subunit

The interaction between the inhibitor protein and the catalytic subunit of the cAMP-dependent protein kinase has been investigated by steady state kinetics and by an assessment of the requirement of this interaction for ATP. By analysis for tightly bound inhibitors, inhibition by the inhibitor protein was shown to be competitive versus peptide substrate and uncompetitive versus Mg X ATP2-. This, together with the observations of Gronot et al. (Gronot, J., Mildvan, A.S., Bramson, H. N., Thomas, N., and Kaiser, E.T. (1981) Biochemistry 20, 602-610) and those given in the accompanying paper (Whitehouse, S., Feramisco, J.R., Casnellie, J.E., Krebs, E.G., and Walsh, D.A. (1983) J. Biol. Chem. 258, 3693-3701), would indicate that the probable reaction mechanism of the protein kinase is ordered with the nucleotide binding first and that the inhibitor protein blocks catalysis by interaction with the catalytic subunit-Mg X ATP complex. The Ki for this interaction at saturating Mg X ATP and zero peptide substrate is 0.49 nM. Multiple inhibition analysis in the presence of 5'-adenylimidodiphosphate (AMP X PNP) indicates that the inhibitor protein does not interact with a catalytic subunit-AMP X PNP complex. The requirement for ATP for the inhibitor protein-catalytic subunit interaction has also been demonstrated by direct binding measurements and by the observation that the efficiency of the inhibitor protein is increased by preincubation of the inhibitor protein, catalytic subunit, and ATP in the absence of peptide substrate. By either measurement, the catalytic subunit in the presence of the inhibitor protein, was shown to exhibit an apparent Kd of 20 approximately 60 nM for ATP; this value is two orders of magnitude higher than the affinity for ATP by the catalytic subunit alone. This high apparent affinity of the catalytic subunit for ATP (in the presence of the inhibitor) does not require that there be a specific binding site on the inhibitor protein for some moiety of the ATP but may simply be a reflection of the formation of a catalytic subunit-Mg X ATP X inhibitor protein complex with resultant displacement of the equilibrium of ATP binding to the protein kinase.     

ATP regulation of the human red cell sugar transporter

Purified human red blood cell sugar transport protein intrinsic tryptophan fluorescence is quenched by D-glucose and 4,6-ethylidene glucose (sugars that bind to the transport), phloretin and cytochalasin B (transport inhibitors), and ATP. Cytochalasin B-induced quenching is a simple saturable phenomenon with Kd app of 0.15 microM and maximum capacity of 0.85 cytochalasin B binding sites per transporter. Sugar-induced quenching consists of two saturable components characterized by low and high Kd app binding parameters. These binding sites appear to correspond to influx and efflux transport sites, respectively, and coexist within the transporter molecule. ATP-induced quenching is also a simple saturable process with Kd app of 50 microM. Indirect estimates suggest that the ratio of ATP-binding sites per transporter is 0.87:1. ATP reduces the low Kd app and increases the high Kd app for sugar-induced fluorescence quenching. This effect is half-maximal at 45 microM ATP. ATP produces a 4-fold reduction in Km and 2.4-fold reduction in Vmax for cytochalasin B-inhibitable D-glucose efflux from inside-out red cell membrane vesicles (IOVs). This effect on transport is half-maximal at 45 microM ATP. AMP, ADP, alpha, beta-methyleneadenosine 5'-triphosphate, and beta, gamma-methyleneadenosine 5'-triphosphate at 1 mM are without effect on efflux of D-glucose from IOVs. ATP modulation of Km for D-glucose efflux from IOVs is immediate in onset and recovery. ATP inhibition of Vmax for D-glucose exit is complete within 5-15 min and is only partly reversed following 30-min incubation in ATP-free medium. These findings suggest that the human red cell sugar transport protein contains a nucleotide-binding site(s) through which ATP modifies the catalytic properties of the transporter.     

Affinity modification of creatine kinase from rabbit skeletal muscle by 2',3'-dialdehyde derivatives of ADP and ATP

Periodate-oxidized ADP and ATP (oADP and oATP) are substrates and affinity reagents for creatine kinase from rabbit skeletal muscle. oADP and oATP modified a lysine epsilon-amino group in the nucleotide-binding site of the enzyme. Complete inactivation is observed upon binding 2 moles oADP per 1 mole of the enzyme dimer. Modification with oADP is described by a liner dependence of the log of enzyme activity on time, testifying to a pseudo-first-order of the reaction. The reaction rate constant (ki = 8.10(3) min-1) and dissociation constant for the reversible enzyme-oADP complex (Kd = 62 microM) were determined. ADP protected the enzyme from inactivation and covalent binding of the analog, whereas oADP covalently bound to the enzyme was phosphorylated by phosphocreatine. The data obtained allow to suggest that the epsilon-amino group of a lysine residue of the active site is located in close proximity to ribose of ATP and ADP forming a complex with the enzyme. This group seems essential for correct orientation of the nucleotide polyphosphate chain in the enzyme active center, but take no immediate part in the transphosphorylation process.     

Critical role of specific ions for ligand-induced changes regulating pyruvate dehydrogenase kinase isoform 2

In the complete absence of K+ and phosphate (Pi), pyruvate dehydrogenase kinase isoform 2 (PDHK2) was catalytically very active but with an elevated Km for ATP, and this activity is insensitive to effector regulation. We find that K+ or 5-fold lower levels of NH4+ markedly enhanced quenching of Trp383 fluorescence of PDHK2 by ADP and ATP. K+ binding caused an approximately 40-fold decrease in the equilibrium dissociation constants (Kd) for ATP from approximately 120 to 3.0 microM and an approximately 25-fold decrease in Kd for ADP from approximately 950 to 38 microM. Linked reductions in Kd of PDHK2 for K+ were from approximately 30 to approximately 0.75 mM with ATP bound and from approximately 40 to approximately 1.7 mM with ADP bound. Without K+, there was little effect of ADP on pyruvate binding, but with 100 mM K+ and 100 microM ADP, the L0.5 of PDHK2 for pyruvate was reduced by approximately 14 fold. In the absence of K+, Pi had small effects on ligand binding. With 100 mM K+, 20 mM Pi modestly enhanced binding of ADP and hindered pyruvate binding but markedly enhanced the binding of pyruvate with ADP; the L0.5 for pyruvate was specifically decreased approximately 125-fold with 100 microM ADP. Pi effects were minimal when NH4+ replaced K+. We have quantified coupled binding of K+ with ATP and ADP and elucidated how linked K+ and Pi binding are required for the potent inhibition of PDHK2 by ADP and pyruvate.     

Engineering the serine/threonine protein kinase Raf-1 to utilise an orthogonal analogue of ATP substituted at the N6 position

One key area of protein kinase research is the identification of cognate substrates. The search for substrates is hampered by problems in unambiguously assigning substrates to a particular kinase in vitro and in vivo. One solution to this impasse is to engineer the kinase of interest to accept an ATP analogue which is orthogonal (unable to fit into the ATP binding site) for the wild-type enzyme and the majority of other kinases. The acceptance of structurally modified, gamma-(32)P-labelled, nucleotide analogue by active site-modified kinase can provide a unique handle by which the direct substrates of any particular kinase can be displayed in crude mixtures or cell lysates. We have taken this approach with the serine/threonine kinase Raf-1, which plays an essential role in the transduction of stimuli through the Ras-->Raf-->MEK-->ERK/MAP kinase cascade. This cascade plays essential roles in proliferation, differentiation and apoptosis. Here we detail the mutagenesis strategy for the ATP binding pocket of Raf-1, such that it can utilise an N(6)-substituted ATP analogue. We show that these mutations do not alter the substrate specificity and signal transduction through Raf-1. We screen a library of analogues to identify which are orthogonal for Raf-1, and show that mutant Raf-1 can utilise the orthogonal analogue N(6)(2-phenethyl) ATP in vitro to phosphorylate its currently only accepted substrate MEK. Importantly we show that our approach can be used to tag putative direct substrates of Raf-1 kinase with (32)P-N(6)(2-phenethyl) ATP in cell lysates.     

Characterization of the HslU chaperone affinity for HslV protease

The HslVU complex is a bacterial two-component ATP-dependent protease, consisting of HslU chaperone and HslV peptidase. Investigation of protein-protein interactions using SPR in Escherichia coli HslVU and the protein substrates demonstrates that HslU and HslV have moderate affinity (Kd = 1 microM) for each other. However, the affinity of HslU for HslV fivefold increased (Kd approximately 0.2 microM) after binding with the MBP approximately SulA protein indicating the formation of a "ternary complex" of HslV-HslU-MBP approximately SulA. The molecular interaction studies also revealed that HslU strongly binds to MBP approximately SulA with 10(-9) M affinity but does not associate with nonstructured casein. Conversely, HslV does not interact with the MBP-SulA whereas it strongly binds with casein (Kd = 0.2 microM) requiring an intact active site of HslV. These findings provide evidence for "substrate-induced" stable HslVU complex formation. Presumably, the binding of HslU to MBP approximately SulA stimulates a conformational change in HslU to a high-affinity form for HslV.     

Roles of Ile209 and Ile210 on the heme pocket structure and regulation of histidine kinase activity of oxygen sensor FixL from Rhizobium meliloti

FixL is a sensor histidine kinase having a heme-containing domain as an O(2) sensing site. In the study presented here, Ile209 and Ile210 located near the heme iron of the heme domain of Rhizobium meliloti FixL (RmFixL) were mutated, and the mutational effects on the regulation of the kinase activity and the heme pocket structure were examined by the autophosphorylation assay and UV-visible absorption and resonance Raman (RR) spectroscopies. The mutation of these residues disrupted the regulation of the kinase activity by the sensor (heme) domain, indicating that Ile209 and Ile210 play important roles in the signal transduction between the heme and the kinase domains. By measurement of the resonance Raman and optical absorption spectra of Ile209 and Ile210 mutants in several oxidation, spin, and ligation states, it was found that both residues are highly flexible, and their side chains sterically interact with the O(2) ligand, when it binds to the heme iron. On the basis of the results, we propose an O(2) sensing mechanism of RmFixL; the kinase activity is regulated via conformational changes of Ile209 and Ile210 induced by the O(2) binding to the sensory center.     

DNA binding activity of the Arabidopsis G-box binding factor GBF1 is stimulated by phosphorylation by casein kinase II from broccoli.

To study the phosphorylation of one of the G-box binding factors from Arabidopsis (GBF1), we have obtained large amounts of this protein by expression in Escherichia coli. Bacterial GBF1 was shown to be phosphorylated very efficiently by nuclear extracts from broccoli. The phosphorylation activity was partially purified by chromatography on heparin-Sepharose and DEAE-cellulose and was characterized. It showed the essential features of casein kinase II activity: utilization of GTP in addition to ATP as a phosphate donor, strong inhibition by heparin, preference for acidic protein substrates, salt-induced binding to phosphocellulose, and salt-dependent deaggregation. The very low Km value for GBF1 (220 nM compared to approximately 10 microM for casein) was in the range observed for identified physiological substrates of casein kinase II. Phosphorylation of GBF1 resulted in stimulation of the G-box binding activity and formation of a slower migrating protein-DNA complex. The conditions of this stimulatory reaction fully corresponded to the properties of casein kinase II, in particular its dependence on the known phosphate donors. The DNA binding activity of the endogenous plant GBF was shown to be reduced by treatment with calf alkaline phosphatase; this reduction was diminished by addition of fluoride and phosphate or incubation in the presence of casein kinase II and ATP.     

Identifying specific kinase substrates through engineered kinases and ATP analogs

Intracellular signaling by protein kinases controls many aspects of cellular biochemistry and physiology. Determining the direct substrates of protein kinases is important in understanding how these signaling enzymes exert their effect on cellular functions. One of the recent developments in this area takes advantage of the similarity in the ATP binding domains of protein kinases, where a few conserved amino acids containing large side chains come in close contact with the N-6 position of bound ATP. Mutation of one or more of these residues generates a "pocket" in the ATP binding site that allows the mutant kinase, but not other cellular kinases, to utilize analogs of ATP with bulky substituents synthesized onto the N-6 position. The use of such a mutated kinase and radiolabeled ATP analogs allows for the specific labeling of direct substrates of the kinase within a mixture of cellular proteins. We have recently reported the generation of "pocket" mutants of extracellular regulated kinase 2 (ERK2) and their use in the identification of two novel substrates of ERK2. In this report, we discuss the generation and characterization of ERK2 mutants that utilize analogs of ATP and describe the methodology used to identify ERK2-associated substrates. We also describe the direct labeling of ERK2 substrates in cell lysates. These methodologies can be adapted for use with other protein kinases to increase the understanding of intracellular signal transduction.     

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

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

Reverse reaction of smooth muscle myosin light chain kinase. Formation of ATP from phosphorylated light chain plus ADP

Incubation of smooth muscle phosphorylated heavy meromyosin in the presence of myosin light chain kinase, calmodulin, ADP, and Ca2+ results in a decrease of the protein-bound phosphate. The dephosphorylation is not due to phosphatase activity and is dependent on the presence of ADP and the active ternary myosin light chain kinase complex. Using 32P-labeled phosphorylated 20,000-dalton light chains as the phosphate donor, the formation of ATP from ADP can be demonstrated. This reaction requires the presence of Ca2+, calmodulin, and myosin light chain kinase. These results indicate that myosin light chain kinase can catalyze a reverse reaction and form ATP from ADP and phosphorylated substrate. The rate of the reverse reaction, kcat/KLC approximately 0.21 min-1 microM-1, is considerably slower than the forward reaction under similar conditions and is therefore detectable only at relatively high concentrations of myosin light chain kinase. For the reverse reaction, KmADP is approximately 30 microM and ATP is a competitive inhibitor, KIATP approximately 88 microM. For the forward reaction, measured with both isolated light chains and intact myosin, KmATP is approximately 100 microM and ADP is a competitive inhibitor, KiADP approximately 140 microM (myosin) and 120 microM (light chains). Thus, the affinity of ATP for the forward and reverse reactions is similar, but the affinity of ADP is higher for the reverse reaction. From the light chain dependence of the two reactions, the following was calculated: forward, Km = 5 microM, kcat = 1720 min-1, and reverse, Km = 130 microM, kcat = 27 min-1. In contrast to the data obtained with isolated light chains, it is suggested that, with intact myosin as substrate, the Km term is primarily responsible for determining the rate of the reverse reaction. With light chains phosphorylated at serine 19 and threonine 18, it was shown that both sites act as a phosphate donor, although the reverse reaction for threonine 18 is slower than that for serine 19.     

Steady-state kinetic mechanism of PDK1

PDK1 catalyzes phosphorylation of Thr in the conserved activation loop region of a number of its downstream AGC kinase family members. In addition to the consensus sequence at the site of phosphorylation, a number of PDK1 substrates contain a PIF sequence (PDK1-interacting fragment), which binds and activates the kinase domain of PDK1 (PDK1(deltaPH)). To gain further insight to PIF-dependent catalysis, steady-state kinetic and inhibition studies were performed for His6-PDK1(deltaPH)-catalyzed phosphorylation of PDK1-Tide (Tide), which contains an extended "PIF" sequence C-terminal to the consensus sequence for PDK1 phosphorylation. In two-substrate kinetics, a large degree of negative binding synergism was observed to occur on formation of the active ternary complex (alphaKd(ATP) = 40 microM and alphaKd(Tide) = 80 microM) from individual transitory binary complexes (Kd(ATP) = 0.6 microM and Kd(Tide) = 1 microM). On varying ATP concentrations, the ADP product and the (T/E)-PDK1-Tide product analog (p'Tide) behaved as competitive and noncompetitive inhibitors, respectively; on varying Tide concentrations, ADP and p'Tide behaved as noncompetitive and competitive inhibitors, respectively. Also, negative binding synergism was associated with formation of dead-end inhibited ternary complexes. Time progress curves in pre-steady-state studies under "saturating" or kcat conditions showed (i) no burst or lag phenomena, (ii) no change in reaction velocity when adenosine 5'-O-(thiotriphosphate) was used as a phosphate donor, and (iii) no change in reaction velocity on increasing relative microviscosity (0 < or = eta/eta0 < or = 3). Taken together, PDK1-catalyzed trans-phosphorylation of PDK1-Tide approximates a Rapid Equilibrium Random Bi Bi system, where motions in the central ternary complex are largely rate-determining.     

pp60c-src kinase activity in bovine coronary extracts is stimulated by ATP

pp60c-src kinase is believed to participate in regulating key cellular mechanisms including signal transduction and differentiation of smooth muscle during early embryogenesis. In this study, pp60c-src kinase activity was demonstrated in extracts from adult bovine coronary arterial smooth muscle. Activity, reflected by autophosphorylation of pp60c-src, phosphorylation of exogenous substrates, and phosphorylation of several endogenous substrates, was enhanced about 2 fold when added Mg2+ was replaced by Mn2+. Unexpectedly, activity was dramatically stimulated 20-50 fold by prior incubation with ATP. Such stimulation appears to be mediated through a novel mechanism which is independent of ATP-induced phosphorylation of reaction components. These new observations strongly suggest that a unique mechanism exists for regulation of coronary arterial pp60c-src kinase activity. Conceivably, this mechanism may serve important roles in modulating signal transduction and contractility of vascular smooth muscle.     

Mechanistic studies of Escherichia coli adenosine-5'-phosphosulfate kinase

Adenosine-5'-phosphosulfate kinase (APS kinase) catalyzes the formation of 3'-phosphoadenosine 5'-phosphosulfate (PAPS), the major form of activated sulfate in biological systems. The enzyme from Escherichia coli has complex kinetic behavior, including substrate inhibition by APS and formation of a phosphorylated enzyme (E-P) as a reaction intermediate. The presence of a phosphorylated enzyme potentially enables the steady-state kinetic mechanism to change from sequential to ping-pong as the APS concentration decreases. Kinetic and equilibrium binding measurements have been used to evaluate the proposed mechanism. Equilibrium binding studies show that APS, PAPS, ADP, and the ATP analog AMPPNP each bind at a single site per subunit; thus, substrates can bind in either order. When ATPgammaS replaces ATP as substrate the V(max) is reduced 535-fold, the kinetic mechanism is sequential at each APS concentration, and substrate inhibition is not observed. The results indicate that substrate inhibition arises from a kinetic phenomenon in which product formation from ATP binding to the E. APS complex is much slower than paths in which product formation results from APS binding either to the E. ATP complex or to E-P. APS kinase requires divalent cations such as Mg(2+) or Mn(2+) for activity. APS kinase binds one Mn(2+) ion per subunit in the absence of substrates, consistent with the requirement for a divalent cation in the phosphorylation of APS by E-P. The affinity for Mn(2+) increases 23-fold when the enzyme is phosphorylated. Two Mn(2+) ions bind per subunit when both APS and the ATP analog AMPPNP are present, indicating a potential dual metal ion catalytic mechanism.     

Interaction between aurovertin and adenine nucleotide binding sites on mitochondrial F1-ATPase and the isolated beta subunit

The effect of aurovertin on the binding parameters of ADP and ATP to native F1 from beef heart mitochondria in the presence of EDTA has been explored. Three exchangeable sites per F1 were titrated by ADP and ATP in the absence or presence of aurovertin. Curvilinear Scatchard plots for the binding of both ADP and ATP were obtained in the absence of aurovertin, indicating one high affinity site (Kd for ADP = 0.6-0.8 microM; Kd for ATP = 0.3-0.5 microM) and two lower affinity sites (Kd for ADP = 8-10 microM; Kd for ATP = 7-10 microM). With a saturating concentration of aurovertin capable of filling the three beta subunits of F1, the curvilinearity of the Scatchard plots was decreased for ATP binding and abolished for ADP binding, indicating homogeneity of ADP binding sites in the F1-aurovertin complex (Kd for ADP = 2 microM). When only the high affinity aurovertin site was occupied, maximal enhancement of the fluorescence of the F1-aurovertin complex was attained with 1 mol of ADP bound per mol of F1 and maximal quenching for 1 mol of ATP bound per mol of F1. When the F1-aurovertin complex was incubated with [3H]ADP followed by [14C]ATP, full fluorescence quenching was attained when ATP had displaced the previously bound ADP. In the case of the isolated beta subunit, both ADP and ATP enhanced the fluorescence of the beta subunit-aurovertin complex. The Kd values for ADP and ATP in the presence of EDTA were 0.6 mM and 3.7 mM, respectively; MgCl2 decreased the Kd values to 0.1 mM for both ADP and ATP. It is postulated that native F1 possesses three equivalent interacting nucleotide binding sites and exists in two conformations which are in equilibrium and recognize either ATP (T conformation) or ADP (D conformation). The negative interactions between the nucleotide binding sites of F1 are strongest in the D conformation. Upon addition of aurovertin, the site-site cooperativity between the beta subunits of F1 is decreased or even abolished.     

pH and magnesium dependence of ATP binding to sarcoplasmic reticulum ATPase. Evidence that the catalytic ATP-binding site consists of two domains

Nucleotide binding to sarcoplasmic reticulum vesicles was investigated in the absence of calcium using both filtration and fluorescence measurements. Filtration assays of binding of radioactive nucleotides at concentrations up to 0.1 mM gave a stoichiometry of one ATP-binding site/sarcoplasmic reticulum ATPase molecule. When measured in the presence of calcium under otherwise similar conditions, ATPase velocity rose 4-8-fold (depending on pH and magnesium concentration) when the ATP concentration was increased from 1 microM to 0.1 mM. Binding of ATP and ADP enhanced the intrinsic fluorescence of sarcoplasmic reticulum ATPase, but AMP and adenosine did not affect it. Both filtration and fluorescence measurements showed that binding of metal-free ATP is independent of pH (Kd = 20-25 microM) but that the presence of magnesium induces pH dependence of the binding of the Mg.ATP complex (Kd = 10 microM at pH 6.0 and 1.5 microM at pH 8.0). Binding of metal-free ADP was pH-dependent but was not affected by magnesium. High magnesium concentrations inhibited nucleotide binding. These results suggest that ATP interacts with two different domains of Ca-ATPase that form the catalytic site. The first domain may bind the adenine moiety of the substrate, and the pH dependence of ADP binding suggests the participation of His683 in this region. The second domain of the catalytic site may bind the gamma-phosphate and the magnesium ion of the Mg.ATP complex and constitute the locus of the electrostatic interactions between the substrate and the enzyme.