EPR studies of the Mn(II) complex with elongation factor Tu and GDP Identification of oxygen ligands to Mn(II) by observation of 17O superhyperfine coupling

The coordination sphere of Mn(II) in the complex with GDP and elongation factor Tu from Escherichia coli has been probed by EPR spectroscopy with 17O-labeled ligands. Inhomogeneous broadening in the EPR signals for Mn(II) due to unresolved superhyperfine coupling to the 17O nucleus was used to identify directly bound oxygen ligands. Results with GDP selectively enriched with 17O either in the alpha-phosphate or in the beta-phosphate revealed that GDP was a beta-monodentate ligand for Mn(II) in the complex with the protein. Results with 17O-enriched water showed that two water molecules are coordinated to the Mn(II). The EPR spectrum for the complex is characteristic of octahedral coordination for Mn(II). Hence, three ligands from the protein are required to complete the sextet of ligands.     

Coordination scheme and stereochemical configuration of manganese(II) adenosine 5'-diphosphate at the active site of 3-phosphoglycerate kinase

The structure of the MnIIADP complex at the active site of 3-phosphoglycerate kinase from yeast has been investigated by electron paramagnetic resonance (EPR) spectroscopy. Inhomogeneous broadening in the EPR signals for Mn(II) resulting from unresolved superhyperfine coupling to 17O regiospecifically incorporated into ADP shows that Mn(II) is coordinated to the alpha- and beta-phosphate groups of ADP at the active site of the enzyme. The EPR pattern for the enzyme-MnIIADP complex is characteristic of a predominantly axially symmetric zero-field splitting tensor. The symmetry and magnitude of the zero-field splitting interaction suggest that there is an additional negatively charged oxygen ligand in the coordination sphere of Mn(II). EPR measurements for solutions of the enzyme-MnIIADP complex in 17O-enriched water indicate that there are also two or three water molecules in the coordination sphere of the metal ion. EPR data for complexes with the two epimers of [alpha-17O]ADP have been used to determine the stereochemical configuration of the MnIIADP complex at the active site. EPR spectra for Mn(II) in the enzymic complex with (Rp)-[alpha-17O]ADP show an inhomogeneous broadening due to superhyperfine coupling with 17O whereas spectra for (Sp)-[alpha-17O]ADP complexes are indistinguishable from those for matched samples with unlabeled ADP. These results show that 3-phosphoglycerate kinase selectivity binds the alpha configuration of the alpha, beta chelate of MnIIADP. Addition of 3-phosphoglycerate to form the dead-end complex (enzyme-MnIIADP-3-phosphoglycerate) does not alter the EPR spectrum, but addition of vanadate to this complex causes marked changes in the spectral parameters.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electron paramagnetic resonance studies of MN(II) complexes with myosin subfragment 1 and oxygen 17-labeled ligands

Ligands in the first coordination sphere of Mn(II) in the complex of MnADP with myosin subfragment 1 from rabbit skeletal muscle have been investigated. EPR spectroscopy was used to detect superhyperfine coupling between unpaired electrons of the metal ion and the nuclei of oxygen atoms specifically labeled with oxygen 17. The results show that ADP is a beta-monodentate ligand for Mn(II) and that there are probably two water oxygens directly bound to Mn(II). The inhibitory complex of vanadate with subfragment 1 . MnADP was also investigated. Vanadate-dependent changes in the EPR spectra for enzyme-bound Mn(II) indicate that the coordination sphere of MN(II) changes upon binding of vanadate. ADP remains a beta-monodenate ligand in the complex and experiments with 17O-labeled water indicate that two oxygen atoms originally in water are ligands in the complex. However, the oxygens of vanadate equilibrate with those of water during sample preparation so that one of these ligands may be a vanadate oxygen. Three additional ligands, probably from the protein, are required to complete the sextet of ligands to Mn(II) in both complexes studied.     

Stereochemical control over Mn(II)-thio versus Mn(II)-oxy coordination in adenosine 5'-O-(1-thiodiphosphate) complexes at the active site of creatine kinase

The stereochemical configurations of the Mn(II) complexes with the resolved epimers of adenosine 5'-O-(1-thiodiphosphate) (ADP alpha S), bound at the active site of creatine kinase, have been determined in order to assess the relative strengths of enzymic stereoselectivity versus Lewis acid/base preferences in metal-ligand binding. Electron paramagnetic resonance (EPR) data have been obtained for Mn(II) in anion-stabilized, dead-end (transition-state analogue) complexes, in ternary enzyme-MnIIADP alpha S complexes, and in the central complexes of the equilibrium mixture. The modes of coordination of Mn(II) at P alpha in the nitrate-stabilized, dead-end complexes with each epimer of ADP alpha S were ascertained by EPR measurements with (Rp)-[alpha-17O]ADP alpha S and (Sp)-[alpha-17O]ADP alpha S. The EPR spectrum for the complex with (Rp)-[alpha-17O]ADP alpha S showed inhomogeneous broadening due to unresolved superhyperfine coupling from coordinated 17O at P alpha. By contrast, the EPR spectrum for Mn(II) in complex with (Sp)-[alpha-17O]ADP alpha S is indistinguishable from that obtained for a matched sample with unlabeled (Sp)-ADP alpha S. A reduction in the magnitude of the 55Mn hyperfine coupling constant in the spectrum for the complex containing (Sp)-ADP alpha S is indicative of Mn(II)-thio coordination at P alpha.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electron paramagnetic resonance measurements of the hydration of Mn(II) in ternary complexes with GDP and ras p21 proteins

Electron paramagnetic resonance (EPR) spectroscopy has been used to determine the hydration numbers of Mn(II) in complexes with GDP and three forms of ras p21. EPR signals of Mn(II) in the GDP complex with viral-Harvey p21pRAS1 (Arg 12, Thr 59), p21EC (Gly 12, Thr 59), and p21EJ (Val 12, Thr 59) have narrow line-widths that permit ready observation of inhomogeneous broadening from unresolved superhyperfine coupling with the nuclear spin of 17O of directly coordinated oxygen ligands. Quantitative analysis of the lineshapes for the samples in H2 17O-enriched water indicates that four water ligands coordinate to the metal ion in the GDP complexes with all three proteins. The four solvent ligands, together with an oxygen from the beta-phosphate group of GDP, leave space for only one ligand from the protein. An X-ray diffraction-derived model for the MgII beta-gamma-imidoguanosine-5'-triphosphate complex with p21 shows coordination of Mg(II) to the beta- and gamma-phosphate groups of the nucleotide as well as to the hydroxyl groups of Thr 35 and Ser 17 (Pai, E.F., Kabusch, W., Krengel, U., Holmes, K. H., John, J., and Wittinghofer, A., 1989, Nature (London) 341, 209-214). Thus, upon conversion of the nucleotide from a triphosphate to a diphosphate, solvent replaces both the gamma-phosphate of the nucleotide and one of the protein ligands. The EPR results are consistent with a recent X-ray crystallographic model for the p21-MgIIGDP complex (Milburn, M. V., Tong, L., DeVos, A. M., Brunger, A., Yamaizumi, Z., Nishimura, S., and Kim, S.-H., 1990, Science 247, 939-945). EPR spectra of complexes with the three forms of ras p21 differ with respect to the intrinsic linewidths of the EPR signals. These subtle differences in linewidth appear to originate from slight differences in local disorder near the metal-nucleotide binding site.     

Structures of manganese(II) complexes with ATP, ADP, and phosphocreatine in the reactive central complexes with creatine kinase: electron paramagnetic resonance studies with oxygen-17-labeled ligands

Coordination of Mn(II) to the phosphate groups of the substrates and products in the central complexes of the creatine kinase reaction mixture has been investigated by electron paramagnetic resonance (EPR) spectroscopy with regiospecifically 17O-labeled substrates. The EPR pattern for the equilibrium mixture is a superposition of spectra for the two central complexes, and this pattern differs from those observed for the ternary enzyme-Mn(II)-nucleotide complexes and from that for the dead-end complex enzyme-Mn(II)ADP-creatine. In order to identify those signals that are associated with each of the central complexes of the equilibrium mixture, spectra were obtained for a complex of enzyme, Mn(II)ATP, and a nonreactive analogue of creatine, 1-(carboxymethyl)-2-iminoimidazolidin-4-one, which is a newly synthesized competitive inhibitor. This inhibitor permits an unobstructed view of the EPR spectrum for Mn(II)ATP in the closed conformation of the active site. The EPR spectrum for this nonreactive complex with Mn(II)ATP matches one subset of signals in the spectrum for the equilibrium mixture, i.e., those due to the enzyme-Mn(II)-ATP-creatine complex. Chemical quenching of the samples followed by chromatographic assays for both ATP and ADP indicates that the enzyme-Mn(II)ADP-phosphocreatine and the enzyme-Mn(II)ATP-creatine complexes are present in a ratio of approximately 0.7 to 1. A similar value for the equilibrium constant for enzyme-bound substrates is obtained directly from the EPR spectrum for the equilibrium mixture.(ABSTRACT TRUNCATED AT 250 WORDS)     

Functional groups at the catalytic site of F1 adenosine triphosphatase

The protection of F1 ATPase by inorganic phosphate, ADP, ATP, and magnesium ion against inactivation by 1-fluoro-2,4-dinitrobenzene, 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole, and 1-(ethoxycarbonyl)-2-ethoxy-1,2-dihydroquinoline, respectively, has been investigated. Dissociation equilibrium constants and rate constants for the labeling reactions have been deduced from a quantitative treatment of the kinetic data. Comparison of these dissociation constants with each other and with the corresponding literature values indicates that the essential Tyr, Arg, Lys, and Glu or Asp residues are indeed located at the catalytic site of the enzyme. Examination of the rate constants for the labeling reactions in the presence of excess inorganic phosphate, ADP, ATP, or magnesium ion, respectively, suggests that the essential phenol and amino groups are located nearer to the bound inorganic phosphate or the gamma-phosphate group than to the alpha- or beta-phosphate group of the bound ATP, that the essential guanidinium group is located nearer to the alpha- or beta-phosphate group than to the gamma-phosphate group of the bound ATP or the bound inorganic phosphate, and that the essential carboxylate group is located slightly farther away but complexed with magnesium ion which it shares with the bound inorganic phosphate. A mechanism consistent with these topographical relationships is proposed for the catalytic hydrolysis and synthesis of ATP.     

Structure of the oxalate-ATP complex with pyruvate kinase: ATP as a bridging ligand for the two divalent cations

The 2 equiv of divalent cation that are required cofactors for pyruvate kinase reside in sites of different affinities for different species of cation [Baek, Y. H., & Nowak, T. (1982) Arch. Biochem. Biophys. 217, 491-497]. The intrinsic selectivity of the protein-based site for Mn(II) and of the nucleotide-based site for Mg(II) has been exploited in electron paramagnetic resonance (EPR) investigations of ligands for Mn(II) at the protein-based site. Oxalate, a structural analogue of the enolate of pyruvate, has been used as a surrogate for the reactive form of pyruvate in complexes with enzyme, Mn(II), Mg(II), and ATP. Addition of Mg(II) to solutions of enzyme, Mn(II), ATP, and oxalate sharpens the EPR signals for the enzyme-bound Mn(II). Superhyperfine coupling between the unpaired electron spin of Mn(II) and the nuclear spin of 17O, specifically incorporated into oxalate, shows that oxalate is bound at the active site as a bidentate chelate with Mn(II). Coordination of the gamma-phosphate of ATP to this same Mn(II) center is revealed by observation of superhyperfine coupling form 17O regiospecifically incorporated into the gamma-phosphate group of ATP. By contrast, 17O in the alpha-phosphate or in the beta-phosphate groups of ATP does not influence the spectrum. Experiments in 17O-enriched water show that there is also a single water ligand bound to the Mn(II). These data indicate that ATP bridges Mn(II) and Mg(II) at the active site. A close spacing of the two divalent cations is also evident from the occurrence of magnetic interactions for complexes in which 2 equiv of Mn(II) are present at the active site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Observation of manganese(II)-ligand superhyperfine couplings in complexes with proteins by electron spin-echo spectroscopy

Pulsed electron paramagnetic resonance spectroscopy has been used to detect Mn(II)-ligand superhyperfine couplings in complexes with creatine kinase and in the Mn(II) metalloprotein concanavalin A. Electron spin-echo envelopes from Mn(II), bound in these complexes, are modulated by superhyperfine interactions between Mn(II) and nearby, weakly coupled nuclear spins. The characteristic frequencies of the modulations were obtained by Fourier transformation of the three-pulse, spin-echo envelopes. In transition-state analogue complexes of creatine kinase (enzyme-MnIIADP-anion-creatine), superhyperfine interactions from the directly coordinated nitrogen of the thiocyanate ligand give envelope modulations. The source of the modulations was confirmed by measurements with the 14N and 15N forms of thiocyanate. On the other hand, the nitrogen of coordinated nitrate, which is two bonds removed from the paramagnetic center, does not produce detectable modulations. In spectra for Mn(II) concanavalin A, envelope modulations are detected due to the nitrogen of the coordinated histidine residue. Complexes prepared in 2H2O give strong signals due to weakly coupled 2H. For Mn(II)-doped single crystals of sodium pyrophosphate, signals are observed in the frequency domain spectra that are due to coupling from 31P. Phosphorus signals from the ADP ligand in complexes with creatine kinase show approximately the same coupling constant but have a much broader line width.     

Electron paramagnetic resonance and water proton relaxation rate studies of formyltetrahydrofolate synthetase-manganous ion complexes. Evidence for involvement of substrates in the promotion of a catalytically competent active site.

Conformational properties of the active site of formyltetrahydrofolate synthetase from Clostridium cylindrosorum have been examined by EPR spectroscopy and by solvent proton relaxation rate (PPR) studies of manganous complexes with the enzyme. Ternary enzyme-Mn-nucleotide complexes give EPR spectra which are very similar to those for the binary Mn-nucleotide complexes. However, upon addition of tetrahydrofolate to form the quaternary complexes, enzyme-MnADP-tetrahydrofolate and enzyme MnATP-tetrahydrofolate the EPR line shapes are changed substantially. Spectra for the quaternary complexes exhibit narrow line widths, and the splitting patterns are characteristic of a slightly asymmetric electronic environment for the bound Mn(II). Addition of formate to the ADP quatenary complex induces a further significant narrowing of the EPR line widths, although in the absence of tetrahydrofolate, formate does not influence the EPR spectrum for the enzyme-MnADP species. Both Pi and nitrate cause changes in the EPR patterns for the higher complexes of the enzyme which involve both ADP and tetrahydololate. However, the Pi effect is not influenced by the presence of formate whereas the characteristic effect of nitrate is potentiated only when formate is present. EPR sectra for the thernary complex with the beta, gamma-methylene analog of ATP App(CH2)p differ significantly from spectra for the binary App(CH)p complex is not influenced by further additions of tetrahydrofolate and of tetrahydorfolate and formate. The failure of spectra for the App(CH)p complex to respond to additions of the other substrates for the reaction is in marked contrast to the behavior found for the natural nucleotide substrates and is tentatively attributed to the lack of a protein-mediated interaction between the nucleotide and tetrahydrofolate binding sites in the analog complex. The frequency dependence of solvent PRR in the presence of the various complexes allows an estimate of the correlation times for electron-nuclear dipolar interaction and thereby the extent of hydration of the bound Mn(II) among the various complexes..     

Structure-function relationships in TPN-dependent isocitrate dehydrogenase. I. Electron paramagnetic resonance studies of the interaction of enzyme-bound Mn(II) with substrates, cofactors, and substrate analogues.

Electron paramagnetic resonance (EPR) spectra were obtained for various isocitrate dehydrogenase-Mn(II) complexes. The qualitative effects of the binding of substrates, nucleotides, and substrate analogues on the isotropic character of the electronic environment of enzyme-bound Mn(II) were subsequently investigated. The addition of isocitrate produces a markedly anisotropic spectrum whereas alpha-ketoglutarate does not alter the spectrum of enzyme-Mn(II) substantially. This suggests direct coordination of isocitrate to the Mn(II) but perphaps a different mode of binding for alpha-ketoglutarate. Other studies demonstrated mutually exclusive binding relationships between TPN and TPNH, between Mn-isocitrate and TPNH, and between HCO3-(CO2) and formate or thiocyanate. Indirect evidence supporting CO2 rather than HCO3-as the actual reactive species which binds to the enzyme in the reductive carboxylation reaction is presented on the basis of the results of the formate and thiocyanate studies. From the EPR results recorded for ternary, quaternary, and quinary enzyme-substrate complexes, correlations between the appearance of fine structure signals and the binding of individual substrates and/or nucleotides are found, and tentative assignments of such signals are made on this basis. Additional studies were conducted to determine binding constants for Mg(II) Co(II), and Co-isocitrate, and a comparison was made with kinetically determined binding constants.     

Characterization of a dinuclear Mn(II) tri(μ-carboxylato) complex with the hindered hydrotris(3,5-diisopropyl-1-pyrazolyl)borate (=TpPr2) ligand: intramolecular hydrogen bonding interaction between the protonated TpPr2 and Mn-coordinating carboxylate ligands

A dinuclear Mn(II) di(μ-hydroxo) complex having hydrotris(3,5-diisopropyl-1-pyrazolyl)borate (=Tp^iPr₂) reacted with benzoic acid to yield a dinuclear Mn(II) tri(μ-carboxylato) complex, Tp^iPr₂Mn-(μ-OBz)₃-Mn(Tp^iPr₂H). X-ray crystallography reveals the unsymmetrical coordination environments for the manganese centers. One of the two Tp^iPr₂ ligands, which bound to the five-coordinated Mn center, is protonated by the action of the third carboxylic acid and the resulting non-Mn-binding N–H moiety forms an intramolecular hydrogen bond with the oxygen donor of a carboxylate ligand. Steric congestion in the bimetallic core results in the large separation of the manganese centers bridged by the syn-anti carboxylate ligand.     

Electron paramagnetic resonance studies of a ras p21-MnIIGDP complex in solution.

The number of water molecules bound to Mn2+ in the complex with a variant of Ha ras p21 and GDP has been determined by electron paramagnetic resonance (EPR) measurements in 17O-enriched water. A resolution enhancement method has been used to improve quantitation of the spectral data. These spectroscopic measurements show that Mn2+ has four water ligands in this complex, a result in agreement with the conclusions of a previous paper [Smithers, G. W., Poe, M., Latwesen, D. G., & Reed, G. H. (1990) Arch. Biochem. Biophys. 280, 416-420]. The resolution enhancement method has also been applied in a measurement of the 17O-Mn2+ superhyperfine coupling constant of 17O in the beta-phosphate of the GDP in the ras p21 complex. The intrinsically narrow EPR signals of Mn2+ in the complex with ras p21 and GDP in 2H2O respond to resolution enhancement such that the superhyperfine splitting from the 17O nuclear spin (I = 5/2) becomes visible in the EPR signals. An 17O-Mn2+ superhyperfine coupling constant is obtained from simulation of the resolution-enhanced EPR spectrum.     

Magnetic resonance study of the three-dimensional structure of creatine kinase-substrate complexes. Implications for substrate specificity and catalytic mechanism.

The paramagnetic effects of the bound manganese ion and of a covalently attached spin label on proton nuclear spin relaxation rates have been used to calculate distances for a structural model of the MnADP and creatine complexed to creatine kinase from rabbit muscle. The nucleotide and guanidino substrates are so aligned on the enzyme that the transferable phosphoryl group on one substrate is in apposition to the acceptor moiety on the second substrate. The divalent metal ion is most probably liganded to the alpha and beta phosphates of the nucleotide substrate, both in the abortive MnADP-creatine-enzyme complex and in the active MnATP-creatine-enzyme complex. The metal ion-formate distance approximately 5 A in the Mn(II)ADP-formate-creatine-enzyme complex and less than 5 A in the Co(II)ADP-formate-creatine-enzyme complex is consistent with the suggestion that the monovalent anion is binding at the site normally occupied by the transferable phosphoryl group, thus producing a complex which mimics the transition state. Although only an upper limit of the distance from Mn(II) to the guanidino substrate could be determined in the presence of formate, it could be concluded that the disposition of the guanidino substrate changes upon addition of formate, since the relative distances of the methyl and methylene group are inverted. The effect of formate and nitrate on increasing the residence time of creatine in the MnADP-creatine-enzyme complex as determined by NMR provides evidence that the complexes observed by NMR are identical with those involved in the catalytic mechanism, since a parallel effect of formate and nitrate is observed in the kinetics of the enzymatic reaction, where the dissociation constant of creatine from the abortive quaternary complex decreases in the presence of the anions as had been determined from their inhibition of the forward reaction (Milner-White, E.J., and Watts, D.C. (1971) Biochem. J. 122, 727-740). Although the guanidino substrate is not directly liganded to the divalent metal ion, the electron paramagnetic resonance spectrum of manganese in the transition state analog complexes, i.e. nitrate-ADP-guanidino substrate-enzyme, is strongly dependent on catalytic activity of the guanidino substrate. The structural differences observed by EPR among transition state analog complexes with various guanidino substrates were not reflected in distances from Mn(II) to the guanidino substrate, which were 10% and 0.3% as active as creatine. Within the experimental error of 1 A, the distances were the same. The enzyme or the enzyme-substrate complexes may be considered to exist in a number of structurally distinct conformations in equilibrium based on the EPR spectra and on the anomalous temperature-dependence of the relaxation rates of the formate proton of the transition state analog complexes...     

Coordination of manganous ion at the active site of pyruvate, phosphate dikinase: the complex of oxalate with the phosphorylated enzyme

Electron paramagnetic resonance spectroscopy has been used to investigate the structure of the complex of manganous ion with the phosphorylated form of pyruvate,phosphate dikinase (Ep) and the inhibitor oxalate. Oxalate, an analogue of the enolate of pyruvate, is competitive with respect to pyruvate in binding to the phosphorylated form of the enzyme [Michaels, G., Milner, Y., & Reed, G.H. (1975) Biochemistry 14, 3213-3219]. Superhyperfine coupling between the unpaired electrons of Mn(II) and ligands specifically labeled with 17O has been used to identify oxygen ligands to Mn(II) in the complex with oxalate and the phosphorylated form of the enzyme. Oxalate binds at the active site as a bidentate chelate with Mn(II). An oxygen from the 3'-N-phosphohistidyl residue of the protein is in the coordination sphere of Mn(II), and at least two water molecules are also bound to Mn(II) in the complex. Oxalate also binds directly to Mn(II) in a complex with nonphosphorylated enzyme. The structure for the Ep-Mn(II)-oxalate complex implies that simultaneous coordination of a phospho group and of the attacking nucleophile to the divalent cation is likely an important factor in catalysis of this phospho-transfer reaction.     

Reduction of CuA induces a conformational change in cytochrome c oxidase from Paracoccus denitrificans.

Cytochrome c oxidase (cytochrome aa3) from Paracoccus denitrificans contains a tightly bound manganese(II) ion, which responds to reduction of the enzyme by a change in its EPR signal (Seelig et al. (1981) Biochim. Biophys. Acta 636, 162-167). In this paper, the nature of this phenomenon is studied and the bound manganese is used as a reporter group to monitor a redox-linked conformational change in the protein. A reductive titration of the cyanide-inhibited enzyme shows that the change in the manganese EPR signal is associated with reduction of CuA. The change appears to reflect a rearrangement in the rhombic octahedral coordination environment of the central Mn2+ atom and is indicative of a redox-linked conformational transition in the enzyme. The manganese is likely to reside at the interface of subunits I and II, near the periplasmic side of the membrane. One of its ligands may be provided by the transmembrane segment X of subunit I, which has been suggested to contribute ligands to cytochrome a and CuB as well. Another manganese ligand is a water oxygen, as indicated by broadening of the manganese EPR signal in the presence of H2(17)O.     

High-affinity metal-binding site in beef heart mitochondrial F1ATPase: an EPR spectroscopy study

The high-affinity metal-binding site of isolated F(1)-ATPase from beef heart mitochondria was studied by high-field (HF) continuous wave electron paramagnetic resonance (CW-EPR) and pulsed EPR spectroscopy, using Mn(II) as a paramagnetic probe. The protein F(1) was fully depleted of endogenous Mg(II) and nucleotides [stripped F(1) or MF1(0,0)] and loaded with stoichiometric Mn(II) and stoichiometric or excess amounts of ADP or adenosine 5'-(beta,gamma-imido)-triphosphate (AMPPNP). Mn(II) and nucleotides were added to MF1(0,0) either subsequently or together as preformed complexes. Metal-ADP inhibition kinetics analysis was performed showing that in all samples Mn(II) enters one catalytic site on a beta subunit. From the HF-EPR spectra, the zero-field splitting (ZFS) parameters of the various samples were obtained, showing that different metal-protein coordination symmetry is induced depending on the metal nucleotide addition order and the protein/metal/nucleotide molar ratios. The electron spin-echo envelope modulation (ESEEM) technique was used to obtain information on the interaction between Mn(II) and the (31)P nuclei of the metal-coordinated nucleotide. In the case of samples containing ADP, the measured (31)P hyperfine couplings clearly indicated coordination changes related to the metal nucleotide addition order and the protein/metal/nucleotide ratios. On the contrary, the samples with AMPPNP showed very similar ESEEM patterns, despite the remarkable differences present among their HF-EPR spectra. This fact has been attributed to changes in the metal-site coordination symmetry because of ligands not involving phosphate groups. The kinetic data showed that the divalent metal always induces in the catalytic site the high-affinity conformation, while EPR experiments in frozen solutions supported the occurrence of different precatalytic states when the metal and ADP are added to the protein sequentially or together as a preformed complex. The different states evolve to the same conformation, the metal(II)-ADP inhibited form, upon induction of the trisite catalytic activity. All our spectroscopic and kinetic data point to the active role of the divalent cation in creating a competent catalytic site upon binding to MF1, in accordance with previous evidence obtained for Escherichia coli and chloroplast F(1).     

Magnetic resonance studies on manganese-nucleotide complexes of phosphoglycerate kinase.

Measurements of the relaxation rate of water protons (PRR) have been used to study the interaction of yeast phosphoglycerate kinase with the manganous complexes of a number of nucleotides. The results indicate that phosphoglycerate kinase belongs to the same class of enzymes as creatine kinase, adenylate kinase, formyltetrahydrofolate synthetase, and arginine kinase, with maximal binding of metal ion to tne enzyme in the presence of the nucleotide substrate. However, an analysis of titration curves for a number of nucleoside diphosphates (ADP, IDP, GDP) showed that there is a substantial synergism in binding of the metal ion and nucleotide to the enzyme in the ternary complex. The metal-substrate binds to the enzyme approximately two orders of magnitude more tightly than the free nucleotide; Other evidence for an atypical binding scheme for Mn(II)-nucleoside diphosphates was obtained by electron paramagnetic resonance (EPR) studies; the EPR spectrum for the bound Mn(II) in the enzyme-MnADP complex differed substantially from those obtained for other kinases. An identical EPR spectrum is observed with the MnADP complex with the rabbit muscle enzyme as with the yeast enzyme. In contrast, the dissociation constant for the enzyme-MnATP complex is approximately fourfold lower than that for enzyme-ATP, and there are no substantial changes in the electron paramagnetic resonance spectrum of MnATP2- when the complex is bound to phosphoglycerate kinase. A small but significant change in the PRR of water is observed on addition of 3-phosphoglycerate (but not 2-phosphoglycerate) to the MnADP-enzyme complex. However, addition of 3-phosphoglycerate to enzyme-MnADP did not influence the EPR spectrum of the enzyme-bound Mn(II).     

Evidence for changes in the nucleotide conformation in the active site of H(+)-ATPase as determined by pulsed EPR spectroscopy

The conformation of di- and triphosphate nucleosides in the active site of ATPsynthase (H(+)-ATPase) from thermophilic Bacillus PS3 (TF1) and their interaction with Mg(2+)/Mn(2+) cations have been investigated using EPR, ESEEM, and HYSCORE spectroscopies. For a ternary complex formed by a stoichiometric mixture of TF1, Mn(2+), and ADP, the ESEEM and HYSCORE data reveal a (31)P hyperfine interaction with Mn(2+) (|A((31)P)| approximately 5.20 MHz), significantly larger than that measured for the complex formed by Mn(2+) and ADP in solution (|A((31)P)| approximately 4.50 MHz). The Q-band EPR spectrum of the Mn.TF1.ADP complex indicates that the Mn(2+) binds in a slightly distorted environment with |D| approximately 180 x 10(-4) cm(-1) and |E| approximately 50 x 10(-4) cm(-1). The increased hyperfine coupling with (31)P in the presence of TF1 reflects the specific interaction between the central Mn(2+) and the ADP beta-phosphate, illustrating the role of the enzyme active site in positioning the phosphate chain of the substrate for efficient catalysis. Results with the ternary Mn.TF1.ATP and Mn.TF1.AMP-PNP complexes are interpreted in a similar way with two hyperfine couplings being resolved for each complex (|A((31)P(beta))| approximately 4.60 MHz and |A((31)P(gamma))| approximately 5.90 MHz with ATP, and |A((31)P(beta))| approximately 4.20 MHz and |A((31)P(gamma))| approximately 5.40 MHz with AMP-PNP). In these complexes, the increased hyperfine coupling with (31)P(gamma) compared with (31)P(beta) reflects the smaller Mn.P distance with the gamma-phosphate compared with the beta-phosphate as found in the crystal structure of the analogous enzyme from mitochondria [3.53 vs 3.70 A (Abrahams, J. P., Leslie, A. G. W., Lutter, R., and Walker, J. E. (1994) Nature 370, 621-628)] and the different binding modes of the two phosphate groups. The ESEEM and HYSCORE data of a complex formed with Mn(2+), ATP, and the isolated beta subunit show that the (31)P hyperfine coupling is close to that measured in the absence of the protein, indicating a poorly structured nucleotide site in the isolated beta subunit in the presence of ATP. The inhibition data obtained for TF1 incubated in the presence of Mg(2+), ADP, Al(NO(3))(3), and NaF indicate the formation of the inhibited complex with the transition state analogue namely Mg.TF1.ADP.AlF(x) with the equilibrium dissociation constant K(D) = 350 microM and rate constant k = 0.02 min(-1). The ESEEM and HYSCORE data obtained for an inhibited TF1 sample, Mn.TF1.ADP.AlF(x), confirm the formation of the transition state analogue with distinct spectroscopic footprints that can be assigned to Mn.(19)F and Mn.(27)Al hyperfine interactions. The (31)P(beta) hyperfine coupling that is measured in the inhibited complex with the transition state analogue (|A((31)P(beta))| approximately 5.10 MHz) is intermediate between those measured in the presence of ADP and ATP and suggests an increase in the bond between Mn and the P(beta) from ADP upon formation of the transition state.     

Nitric oxide-induced formation of the S-2 state in the oxygen-evolving complex of photosystem II from Synechococcus elongatus

In spinach photosystem II (PSII) membranes, the tetranuclear manganese cluster of the oxygen-evolving complex (OEC) can be reduced by incubation with nitric oxide at -30 degrees C to a state which is characterized by an Mn(2)(II, III) EPR multiline signal [Sarrou, J., Ioannidis, N., Deligiannakis, Y., and Petrouleas, V. (1998) Biochemistry 37, 3581-3587]. This state was recently assigned to the S(-)(2) state of the OEC [Schansker, G., Goussias, C., Petrouleas, V., and Rutherford, A. W. (2002) Biochemistry 41, 3057-3064]. On the basis of EPR spectroscopy and flash-induced oxygen evolution patterns, we show that a similar reduction process takes place in PSII samples of the thermophilic cyanobacterium Synechococcus elongatus at both -30 and 0 degrees C. An EPR multiline signal, very similar but not identical to that of the S(-)(2) state in spinach, was obtained with monomeric and dimeric PSII core complexes from S. elongatus only after incubation at -30 degrees C. The assignment of this EPR multiline signal to the S(-)(2) state is corroborated by measurements of flash-induced oxygen evolution patterns and detailed fits using extended Kok models. The small reproducible shifts of several low-field peak positions of the S(-)(2) EPR multiline signal in S. elongatus compared to spinach suggest that slight differences in the coordination geometry and/or the ligands of the manganese cluster exist between thermophilic cyanobacteria and higher plants.