Interdependence of H+, Ca2+, and Pi (or vanadate) sites in sarcoplasmic reticulum ATPase

The phosphorylation of sarcoplasmic reticulum ATPase with Pi in the absence of Ca2+ was studied by equilibrium and kinetic experimentation. The combination of these measurements was then subjected to analysis without assumptions on the stoichiometry of the reactive sites. The analysis indicates that the species undergoing covalent interaction is the tertiary complex E X Pi X Mg formed by independent interaction of the two ligands with the enzyme. The binding constant of Pi or Mg2+ to either free or partially associated enzyme is approximately equal to 10(2) M-1, and no significant synergistic effect is produced by one ligand on the binding of the other; the equilibrium constant (Keq) for the covalent reaction E X Pi X Mg E-P X Mg is approximately equal to 16, with kphosph = 53 s-1, and khyd = 3-4 s-1 (25 degrees C, pH 6.0, no K+). The phosphorylation reaction of sarcoplasmic reticulum ATPase with Pi is highly H+ dependent. Such a pH dependence involves the affinity of enzyme for different ionization states of Pi, as well as protonation of two protein residues per enzyme unit in order to obtain optimal phosphorylation. The experimental data can then be fitted satisfactorily assuming pK values of 5.7 and 8.5 for the two residues in the nonphosphorylated enzyme (changing to 7.7 for one of the two residues, following phosphorylation) and values of 50.0 and 0.58 for the equilibrium constants of the H2(E X HPO4) in equilibrium with H(E-PO3) + H2O and H(E X HPO4) in equilibrium with E-PO3 + H2O reactions, respectively. In addition to the interdependence of H+ and phosphorylation sites, an interdependence of Ca2+ and phosphorylation sites is revealed by total inhibition of the Pi reaction when two high affinity calcium sites per enzyme unit are occupied by calcium. Conversely, occupancy of the phosphate site by vanadate (a stable transition state analogue of phosphate) inhibits high affinity calcium binding. The known binding competition between the two cations and their opposite effects on the phosphorylation reaction suggest that interdependence of phosphorylation site, H+ sites, and Ca2+ sites is a basic mechanistic feature of enzyme catalysis and cation transport.     

Kinetics and mechanisms of the recombination of Zn2+, Co2+, and Ni2+ with the metal-depleted catalytic site of horse liver alcohol dehydrogenase

The kinetics of the recombination of the metal-depleted active site of horse liver alcohol dehydrogenase (LADH) with metal ions have been studied over a range of pH and temperature. The formation rates were determined optically, by activity measurements, or by using the pH change during metal incorporation with a pH-indicator as monitor. The binding of Zn2+, Co2+, and Ni2+ ions occurs in a two-step process. The first step is a fast equilibrium reaction, characterized by an equilibrium constant K1. The spectroscopic and catalytic properties of the native or metal-substituted protein are recovered in a slow, monomolecular process with the rate constant k2. The rate constants k2 5.2 X 10(-2) sec-1 (Zn2+), 1.1 X 10(-3) sec-1 (Co2+), and 2 X 10(-4) sec-1 (Ni2+). The rate constants increase with increasing pH. Using temperature dependence, the activation parameters for the reaction with Co2+ and Ni2+ were determined. Activation energies of 51 +/- 2.5 kJ/mol (0.033 M N-Tris-(hydroxymethyl)methyl-2-aminomethane sulfonic acid (TES), pH 6, 9) for Co2+ and 48.5 +/- 4 kJ/mol (0.033 M TES, pH 7, 2) for Ni2+ at 23 degrees C were found. The correspondent activation entropies are - 146 +/- 10 kJ/mol K for Co2+ and - 163 +/- 9 kJ/mol K for Ni2+. Two protons are released during the binding of Zn2+ to H4Zn(n)2 LADH in the pH range 6.8-8.1. The binding of coenzyme, either reduced or oxidized, prevents completely the incorporation of metal ions, suggesting that the metal ions enter the catalytic site via the coenzyme binding domain and not through the hydrophobic substrate channel.     

Chlorinations catalyzed by chloroperoxidase occur via diffusible intermediate(s) and the reaction components play multiple roles in the overall process

The chlorination mechanism of the fungal enzyme chloroperoxidase (CPO) has been debated for (1) active site chlorination and (2) diffusible species mediated chlorination. Based upon the conversion of approximately 35 different substrates belonging to different reactive groups, it was found that substrate dimensions and topography had no pronounced effect on rates of CPO chlorination reaction. Epoxidation of indene was dependent on its concentration where as chlorination was not. Also, effective conversion was seen in the chlorination mixture for substrates that could not be epoxidized or sulfoxidized. Some insoluble substrates and certain molecules that exceeded the active site dimensions were chlorinated at rates comparable to the rates required for CPO's more natural substrate, monochlorodimedone. By terminating the enzymatic reaction with an active site ligand (azide), the amount of diffusible species was correlated to CPO in the reaction mixture. The preferential utilization of a substrate, earlier attributed to the active site, is found to be due to the specificity afforded by the reaction environment. It was found that the reaction medium components of peroxide, chloride and hydronium ions affected the reaction rates through varying roles in the enzymatic and non-enzymatic process. Besides these experimental evidences, key mechanistic and kinetic arguments are presented to infer that the final chlorine transfer occurs outside the active site via a diffusible species.     

Pyrovanadolysis, a pyrophosphorolysis-like reaction mediated by pyrovanadate, Mn2+, and DNA polymerase of bacteriophage T7

DNA polymerases catalyze the 3'-5'-pyrophosphorolysis of a DNA primer annealed to a DNA template in the presence of pyrophosphate (PP(i)). In this reversal of the polymerization reaction, deoxynucleotides in DNA are converted to deoxynucleoside 5'-triphosphates. Based on the charge, size, and geometry of the oxygen connecting the two phosphorus atoms of PP(i), a variety of compounds was examined for their ability to carry out a reaction similar to pyrophosphorolysis. We describe a manganese-mediated pyrophosphorolysis-like activity using pyrovanadate (VV) catalyzed by the DNA polymerase of bacteriophage T7. We designate this reaction pyrovanadolysis. X-ray absorption spectroscopy reveals a shorter Mn-V distance of the polymerase-VV complex than the Mn-P distance of the polymerase-PP(i) complex. This structural arrangement at the active site accounts for the enzymatic activation by Mn-VV. We propose that the Mn(2+), larger than Mg(2+), fits the polymerase active site to mediate binding of VV into the active site of the polymerase. Our results may be the first documentation that vanadium can substitute for phosphorus in biological processes.     

Mechanistic and structural studies of H373Q flavocytochrome b2: effects of mutating the active site base

His373 in flavocytochrome b2 has been proposed to act as an active site base during the oxidation of lactate to pyruvate, most likely by removing the lactate hydroxyl proton. The effects of mutating this residue to glutamine have been determined to provide further insight into its role. The kcat and kcat/Klactate values for the mutant protein are 3 to 4 orders of magnitude smaller than the wild-type values, consistent with a critical role for His373. Similar effects are seen when the mutation is incorporated into the isolated flavin domain of the enzyme, narrowing the effects to lactate oxidation rather than subsequent electron transfers. The decrease of 3500-fold in the rate constant for reduction of the enzyme-bound FMN by lactate confirms this part of the reaction as that most effected by the mutation. The primary deuterium and solvent kinetic isotope effects for the mutant enzyme are significantly smaller than the wild-type values, establishing that bond cleavage steps are less rate-limiting in H373Q flavocytochrome b2 than in the wild-type enzyme. The structure of the mutant enzyme with pyruvate bound, determined at 2.8 A, provides a rationale for these effects. The orientation of pyruvate in the active site is altered from that seen in the wild-type enzyme. In addition, the active site residues Arg289, Asp 292, and Leu 286 have altered positions in the mutant protein. The combination of an altered active site and the small kinetic isotope effects is consistent with the slowest step in turnover being a conformational change involving a conformation in which lactate is bound unproductively.     

Post-chemiluminescence behaviour of Ni2+, Mg2+, Cd2+ and Zn2+ in the potassium ferricyanide-luminol reaction.

A new chemiluminescence (CL) reaction was observed when Ni2+, Mg2+, Cd2+ or Zn2+ was injected into the reaction mixture after the finish of the CL reaction of alkaline luminol and potassium ferricyanide. This reaction is described as a post-chemiluminescence (PCL) reaction. The possible mechanism for the PCL was proposed based on studies of the CL kinetic characteristic and the CL spectra. The experimental conditions of the CL reactions were optimized and the feasibility of using the reaction to analyse these metal ions was evaluated. The PCL reaction method operates in the ranges: 1 x 10(-7)-8 x 10(-6) g/L Ni2+; 3 x 10(-6)-2 x 10(-4) g/L Mg2+; 8 x 10(-7)-1 x 10(-4) g/L Cd2+; and 2 x 10(-4)-2 x 10(-3) g/L Zn2+, with detection limits of 4 x 10(-8) g/mL, 1 x 10(-6) g/mL, 3 x 10(-7) g/mL, 8 x 10(-5) g/mL, respectively.     

The mechanism of p21-activated kinase 2 autoactivation

The p21-activated kinases (PAKs) play an important role in diverse cellular processes. PAK2 is activated by autophosphorylation upon binding of small G proteins such as Cdc42 and Rac in the GTP-bound state. However, the mechanism of PAK2 autophosphorylation in vitro is unclear. In the present study, the kinetic theory of the substrate reaction during modification of enzyme activity has been applied to a study of the autoactivation of PAK2. On the basis of the kinetic equation of the substrate reaction during the autophosphorylation of PAK2, the activation rate constants for the free enzyme and enzyme-substrate complex have been determined. The results indicate that 1) in the presence of Cdc42, PAK2 autophosphorylation is a bipartite mechanism, with the regulatory domain autophosphorylated at multiple residues, whereas activation coincides with autophosphorylation of the catalytic domain at Thr-402; 2) the autophosphorylation reactions in regulatory domain are either a nonlimiting step or not required for activation of enzyme; 3) the autophosphorylation at site Thr-402 on the catalytic domain occurs by an intermolecular mechanism and is required for phosphorylation of exogenous substrates examined; 4) binding of the exogenous protein/peptide substrates at the active site of PAK2 has little or no effect on the autoactivation of PAK2, suggesting that multiple regions of PAK2 are involved in the enzyme-substrate recognition. The present method also provides a novel approach for studying autophosphorylation reactions. Since the experimental conditions used resemble more closely the in vivo situation where the substrate is constantly being turned over while the enzyme is being modified, this new method would be particularly useful when the regulatory mechanisms of the reversible phosphorylation reaction toward certain enzymes are being assessed.     

The role of arginine 310 in catalysis and substrate specificity in xanthine dehydrogenase from Rhodobacter capsulatus

The rapid reaction kinetics of wild-type xanthine dehydrogenase from Rhodobacter capsulatus and variants at Arg-310 in the active site have been characterized for a variety of purine substrates. With xanthine as substrate, k(red) (the limiting rate of enzyme reduction by substrate at high [S]) decreased approximately 20-fold in an R310K variant and 2 x 10(4)-fold in an R310M variant. Although Arg-310 lies on the opposite end of the substrate from the C-8 position that becomes hydroxylated, its interaction with substrate still contributed approximately 4.5 kcal/mol toward transition state stabilization. The other purines examined fell into two distinct groups: members of the first were effectively hydroxylated by the wild-type enzyme but were strongly affected by the exchange of Arg-310 to methionine (with a reduction in k(red) greater than 10(3)), whereas members of the second were much less effectively hydroxylated by wild-type enzyme but also much less significantly affected by the amino acid exchanges (with a reduction in k(red) less than 50-fold). The effect was such that the 4000-fold range in k(red) seen with wild-type enzyme was reduced to a mere 4-fold in the R310M variant. The data are consistent with a model in which "good" substrates are bound "correctly" in the active site in an orientation that allows Arg-310 to stabilize the transition state for the first step of the overall reaction via an electrostatic interaction at the C-6 position, thereby accelerating the reaction rate. On the other hand, "poor" substrates bound upside down relative to this "correct" orientation. In so doing, they are unable to avail themselves of the additional catalytic power provided by Arg-310 in wild-type enzyme but, for this reason, are significantly less affected by mutations at this position. The kinetic data thus provide a picture of the specific manner in which the physiological substrate xanthine is oriented in the active site relative to Arg-310 and how this residue is used catalytically to accelerate the reaction rate (rather than simply bind substrate) despite being remote from the position that is hydroxylated.     

PAR对氨基酰化酶不可逆抑制动力学研究

本文将邹氏的在酶的活性修饰剂存在下的底物反应动力学理论应用于氨基酰化酶被金属螯合剂PAR脱锌而失活的动力学研究。通过对不同浓度的PAR存在下底物反应过程和含有PAR的不同浓度的底物中酶促反应的分析,讨论了PAR对氨基酰化酶的脱锌机制。这一过程很可能按如下机制进行:首先,PAR与酶分子活性部位的锌结合,形成一复合物,这一步是较快的反应,然后发生一个可逆的构象变化,最后是不可逆的去锌步骤。锌的存在显然稳定了酶活性部位的构象,而这正是酶活性所必需的。     

Characterization of the Saccharomyces cerevisiae galactose mutarotase/UDP-galactose 4-epimerase protein, Gal10p

Saccharomyces cerevisiae and some related yeasts are unusual in that two of the enzyme activities (galactose mutarotase and UDP-galactose 4-epimerase) required for the Leloir pathway of d-galactose catabolism are contained within a single protein-Gal10p. The recently solved structure of the protein shows that the two domains are separate and have similar folds to the separate enzymes from other species. The biochemical properties of Gal10p have been investigated using recombinant protein expressed in, and purified from, Escherichia coli. Protein-protein crosslinking confirmed that Gal10p is a dimer in solution and this state is unaffected by the presence of substrates. The steady-state kinetic parameters of the epimerase reaction are similar to those of the human enzyme, and are not affected by simultaneous activity at the mutarotase active site. The mutarotase active site has a strong preference for galactose over glucose, and is not affected by simultaneous epimerase activity. This absence of reciprocal kinetic effects between the active sites suggests that they act independently and do not influence or regulate each other.     

Inhibition of dextransucrase by Zn2+, Ni2+, Co2+, and Tris(hydroxymethyl)aminomethane (Tris)

Initial rate kinetics of polysaccharide formation indicate that Zn2+, Ni2+, and Co2+ inhibit dextransucrase [sucrose: 1,6-alpha-D-glucan 6-alpha-D-glucosyltransferase, EC 2.4.1.5] by binding to two types of metal ion sites. One type consists of a single site and has a low apparent affinity for Ca2+. At the remaining site(s), Ca2+ has a much higher apparent affinity than Zn2+, Ni2+, or Co2+, and prevents inhibition by these metal ions. These findings are consistent with a two-site model previously proposed from studies with Ca2+ and EDTA. Initial rate kinetics also show that Tris is competitive with sucrose, but that, unlike Zn2+, Tris does not bind with significant affinity to a second site. This argues that there is a site which is both the sucrose binding site and a general cation site.     

Conformational changes of active site of copper zinc superoxide dismutase can be detected sensitively by electron-transfer reaction

The electron-transfer (ET) reaction between Fe(CN)64- and copper zinc superoxide dismutase (CuZn-SOD) occurs at the active site of the enzyme. The ET parameters which are sensitive to the denaturation have been used to determine the conformational changes of the active site induced by guanidine hydrochloride and thermal denaturation. The decreases of ET rates for all the denatured enzyme samples reflect the collapse of the active cavity of enzyme in the unfolding processes. The interesting changes of ET amplitude for the enzyme denatured at different pH values suggest that electrostatic interaction plays an important role in the conformational changes of active site. From the results of the kinetic analyses, it is concluded that the conformational changes of the active site are parallel with the inactivation.     

Site-directed mutagenesis of the beta subunit of tryptophan synthase from Salmonella typhimurium. Role of active site glutamic acid 350.

To investigate the functional role of glutamic acid 350 in the active site of the beta subunit of tryptophan synthase from Salmonella typhimurium, we have replaced this residue by glutamine or alanine by use of site-directed mutagenesis. The mutant alpha 2 beta 2 complexes were expressed, purified, crystallized, and characterized by spectroscopic and kinetic studies with several substrates. We find large alterations in the substrate and reaction specificity of each mutant form of the alpha 2 beta 2 complex. Since the two mutant enzymes are virtually inactive in reactions with L-serine but are active in reactions with beta-chloro-L-alanine, glutamic acid 350 may facilitate the beta-elimination of the weak hydroxyl leaving group of L-serine. The mutant alpha 2 beta 2 complexes are more active than the wild type enzyme in the beta-elimination reaction with beta-chloro-L-alanine. These enzymes are irreversibly inactivated by beta-chloro-L-alanine, whereas the wild type enzyme is not. These altered properties may result from a change in the conformation of the active site, from a change in the orientation of the coenzyme relative to active site residues, or from a change in the solvent accessibility of the active site. The alteration in the active site may enhance the release of amino acrylate from the Schiff base intermediate by hydrolysis or by transamination.     

Flavin redox chemistry precedes substrate chlorination during the reaction of the flavin-dependent halogenase RebH

The flavin-dependent halogenase RebH catalyzes chlorination at the C7 position of tryptophan as the initial step in the biosynthesis of the chemotherapeutic agent rebeccamycin. The reaction requires reduced FADH(2) (provided by a partner flavin reductase), chloride ion, and oxygen as cosubstrates. Given the similarity of its sequence to those of flavoprotein monooxygenases and their common cosubstrate requirements, the reaction of FADH(2) and O(2) in the halogenase active site was presumed to form the typical FAD(C4a)-OOH intermediate observed in monooxygenase reactions. By using stopped-flow spectroscopy, formation of a FAD(C4a)-OOH intermediate was detected during the RebH reaction. This intermediate decayed to yield a FAD(C4a)-OH intermediate. The order of addition of FADH(2) and O(2) was critical for accumulation of the FAD(C4a)-OOH intermediate and for subsequent product formation, indicating that conformational dynamics may be important for protection of labile intermediates formed during the reaction. Formation of flavin intermediates did not require tryptophan, nor were their rates of formation affected by the presence of tryptophan, suggesting that tryptophan likely does not react directly with any flavin intermediates. Furthermore, although final oxidation to FAD occurred with a rate constant of 0.12 s(-)(1), quenched-flow kinetic data showed that the rate constant for 7-chlorotryptophan formation was 0.05 s(-)(1) at 25 degrees C. The kinetic analysis establishes that substrate chlorination occurs after completion of flavin redox reactions. These findings are consistent with a mechanism whereby hypochlorite is generated in the RebH active site from the reaction of FADH(2), chloride ion, and O(2).     

Thermodynamics of Ni2+, Cu2+, and Zn2+ binding to the urease metallochaperone UreE

The two Ni2+ ions in the urease active site are delivered by the metallochaperone UreE, whose metal binding properties are central to the assembly of this metallocenter. Isothermal titration calorimetry (ITC) has been used to quantify the stoichiometry, affinity, and thermodynamics of Ni2+, Cu2+, and Zn2+ binding to the well-studied C-terminal truncated H144*UreE from Klebsiella aerogenes, Ni2+ binding to the wild-type K. aerogenes UreE protein, and Ni2+ and Zn2+ binding to the wild-type UreE protein from Bacillus pasteurii. The stoichiometries and affinities obtained by ITC are in good agreement with previous equilibrium dialysis results, after differences in pH and buffer competition are considered, but the concentration of H144*UreE was found to have a significant effect on metal binding stoichiometry. While two metal ions bind to the H144*UreE dimer at concentrations <10 microM, three Ni2+ or Cu2+ ions bind to 25 microM dimeric protein with ITC data indicating sequential formation of Ni/Cu(H144*UreE)4 and then (Ni/Cu)2(H144*UreE)4, or Ni/Cu(H144*UreE)2, followed by the binding of four additional metal ions per tetramer, or two per dimer. The thermodynamics indicate that the latter two metal ions bind at sites corresponding to the two binding sites observed at lower protein concentrations. Ni2+ binding to UreE from K. aerogenes is an enthalpically favored process but an entropically driven process for the B. pasteurii protein, indicating chemically different Ni2+ coordination to the two proteins. A relatively small negative value of DeltaCp is associated with Ni2+ and Cu2+ binding to H144*UreE at low protein concentrations, consistent with binding to surface sites and small changes in the protein structure.     

Interaction of transition metal ions with ribonuclease A. II. The selective effects of Mn2+, Zn2+, Cd2+ and Hg2+ on the histidine magnetic resonance.

Zn2+, Cd2+ and Hg2+ inhibit ribonuclease but Mn2+ does not except at very high concentrations. By high resolution NMR one can detect in the pH range 5-8 the C-2 protons of histidines 105, 12, and 119. The inhibiting ions produce large shifts of the resonance of His-12 but not of His-105. On the other hand Mn2+ broadens the C-2 proton of His-105 much more than it does those of His-12 and 119. The selective shifts suggest that the mechanism of inhibition is binding at or near the active site of which His-12 and 119 are a part. The selective broadening is a consequence of binding of the Mn2+ to a site very far from the active site but closer to His-105.     

Mechanism of 4-chlorobenzoate:coenzyme a ligase catalysis

Within the accompanying paper in this issue (Reger et al. (2008) Biochemistry, 47, 8016-8025) we reported the X-ray structure of 4-chlorobenzoate:CoA ligase (CBL) bound with 4-chlorobenzoyl-adenylate (4-CB-AMP) and the X-ray structure of CBL bound with 4-chlorophenacyl-CoA (4-CP-CoA) (an inert analogue of the product 4-chlorobenzoyl-coenzyme A (4-CB-CoA)) and AMP. These structures defined two CBL conformational states. In conformation 1, CBL is poised to catalyze the adenylation of 4-chlorobenzoate (4-CB) with ATP (partial reaction 1), and in conformation 2, CBL is poised to catalyze the formation of 4-CB-CoA from 4-CB-AMP and CoA (partial reaction 2). These two structures showed that, by switching from conformation 1 to conformation 2, the cap domain rotates about the domain linker and thereby changes its interface with the N-terminal domain. The present work was carried out to determine the contributions made by each of the active site residues in substrate/cofactor binding and catalysis, and also to test the role of domain alternation in catalysis. In this paper, we report the results of steady-state kinetic and transient state kinetic analysis of wild-type CBL and of a series of site-directed CBL active site mutants. The major findings are as follows. First, wild-type CBL is activated by Mg (2+) (a 12-75-fold increase in activity is observed depending on assay conditions) and its kinetic mechanism (ping-pong) supports the structure-derived prediction that PP i dissociation must precede the switch from conformation 1 to conformation 2 and therefore CoA binding. Also, transient kinetic analysis of wild-type CBL identified the rate-limiting step of the catalyzed reaction as one that follows the formation of 4-CB-CoA (viz. CBL conformational change and/or product dissociation). The single turnover rate of 4-CB and ATP to form 4-CB-AMP and PP i ( k = 300 s (-1)) is not affected by the presence of CoA, and it is approximately 3-fold faster than the turnover rate of 4-CB-AMP and CoA to form 4-CB-CoA and AMP ( k = 120 s (-1)). Second, the active site mutants screened via steady-state kinetic analysis were ranked based on the degree of reduction observed in any one of the substrate k cat/ K m values, and those scoring higher than a 50-fold reduction in k cat/ K m value were selected for further evaluation via transient state kinetic analysis. The single-turnover time courses, measured for the first partial reaction, and then for the full reaction, were analyzed to define the microscopic rate constants for the adenylation reaction and the thioesterification reaction. On the basis of our findings we propose a catalytic mechanism that centers on a small group of key residues (some of which serve in more than one role) and that includes several residues that function in domain alternation.     

Influence of pH on the Mn2+ activation of and binding to yeast enolase: a functional study.

The influence of pH on the activation of yeast enolase by Mn2+ was measured by steady-state kinetics. The pH influence on the binding of Mn2+ to apoenolase and the enolase-substrate complex was measured by EPR spectroscopy. At pH values above 6.6, activation by Mn2+ is fit by Michaelis-Menten kinetics, but at higher concentrations of Mn2+, inhibition is observed. Under conditions analogous to the kinetic studies, the enzyme binds two Mn2+ per dimer with a Kd in the micromolar range. In the presence of the substrate 2-phosphoglycerate, three thermodynamically distinct cation binding sites per monomer are detected and the binding constants are determined by a fit to the data. As the pH decreases, the reaction velocity decreases and the cation inhibition becomes minimal. Under these conditions, only two Mn2+ binding sites per monomer are observed; the third site must be the inhibitory site. The velocity and kinetic constants are minimally affected by buffer except at pH 5.8 with PIPES. Under these conditions, the velocity is only about 40% that observed with other buffers and only a single binding site for Mn2+ per monomer is detected in the presence or absence of substrate. A direct role in the catalytic mechanism by the second cation is called to question. The binding constant for Mn2+ at site I is independent of pH over the range from 7.5 to 5.2, and the binding at site II increases only slightly over this same pH range. These results indicate that the cation sites at positions I and II contain ligands that are pH independent over this range.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of adenosine-5'-O-(3-thiotriphosphate) with Ca2+,Mg2+-adenosine triphosphatase of sarcoplasmic reticulum

Interaction of adenosine-5'-O-(3-thiotriphosphate) (ATP gamma S) with Ca2+,Mg2+-ATPase of sarcoplasmic reticulum was studied. The nucleotide was slowly hydrolyzed by the ATPase at 30 degrees C at a rate of about 0.5% that of ATP hydrolysis. Whereas at 0 degrees C, ATP gamma S showed only a limited reactivity toward the ATPase in that a thiophosphorylated intermediate was formed and ADP was released, but hydrolysis of the intermediate to complete the catalytic cycle did not occur. A fairly stable analog of the E-P intermediate could thus be obtained. Presence of the thiophosphorylated intermediate was indicated by the [3H]ADP in equilibrium ATP gamma S exchange reaction and also by using [35S]ATP gamma S. When the ATPase was reacted with ATP gamma S at 0 degrees C in the presence of ferricyanide, EP-forming activity was rapidly lost. Free Ca2+ ions were required for this inactivation. Disulfide bond formation between a cysteinyl residue located near the substrate binding site and the enzyme-bound ATP gamma S or the thiophosphorylated intermediate was suggested by the fact that 2-mercaptoethanol reversed the inactivation. The reaction may prove to be a useful tool for affinity labeling of the active site of the ATPase.