19F NMR investigations of the catalytic mechanism of phosphoglucomutase using fluorinated substrates and inhibitors.

The complexes of phosphoglucomutase with a number of fluorinated substrate analogues have been investigated by 19F NMR and the effects of the binding of Li+ and Cd2+ to these complexes determined. Very large downfield chemical shift changes (-14 to -19 ppm) accompanied binding of the inhibitors 6-deoxy-6-fluoro-alpha-D-glucopyranosyl phosphate and alpha-glucosyl fluoride 6-phosphate to the phosphoenzyme. Smaller shift changes were observed for ligands substituted with fluorine at other positions. Addition of Li+ to enzyme/fluorinated ligand complexes caused a 10(2)- to 10(3)-fold decrease in ligand dissociation constants as witnessed by the change from intermediate to slow-exchange conditions in the NMR spectra. Measurement of the 19F NMR spectra of complexes of the Li(+)-enzyme with each of the fluoroglucose 1-phosphates and 6-phosphates has provided some insight into the environment of each of these fluorines (thus also parent hydroxyls) in each of the complexes. Results obtained argue strongly against a single sugar binding mode for the glucose 1- and 6-phosphates. Two enzyme-bound species were detected in the 19F NMR spectra of the complexes formed by reaction of the Cd(2+)-phosphoenzyme complex with the 2- and 3-fluoroglucose phosphates. These are tentatively assigned as the fluoroglucose 1,6-bisphosphate species bound in two different modes to the dephosphoenzyme. Only one bound species was observed in the case of the 4-fluoroglucose phosphates.(ABSTRACT TRUNCATED AT 250 WORDS)     

Time-dependent 31P saturation transfer in the phosphoglucomutase reaction. Characterization of the spin system for the Cd(II) enzyme and evaluation of rate constants for the transfer process

Time-dependent 31P saturation-transfer studies were conducted with the Cd2+-activated form of muscle phosphoglucomutase to probe the origin of the 100-fold difference between its catalytic efficiency (in terms of kcat) and that of the more efficient Mg2+-activated enzyme. The present paper describes the equilibrium mixture of phosphoglucomutase and its substrate/product pair when the concentration of the Cd2+ enzyme approaches that of the substrate and how the nine-spin 31P NMR system provided by this mixture was treated. It shows that the presence of abortive complexes is not a significant factor in the reduced activity of the Cd2+ enzyme since the complex of the dephosphoenzyme and glucose 1,6-bisphosphate, which accounts for a large majority of the enzyme present at equilibrium, is catalytically competent. It also shows that rate constants for saturation transfer obtained at three different ratios of enzyme to free substrate are mutually compatible. These constants, which were measured at chemical equilibrium, can be used to provide a quantitative kinetic rationale for the reduced steady-state activity elicited by Cd2+ relative to Mg2+ [cf. Ray, W.J., Post, C.B., & Puvathingal, J.M. (1989) Biochemistry (following paper in this issue)]. They also provide minimal estimates of 350 and 150 s-1 for the rate constants describing (PO3-) transfer from the Cd2+ phosphoenzyme to the 6-position of bound glucose 1-phosphate and to the 1-position of bound glucose 6-phosphate, respectively. These minimal estimates are compared with analogous estimates for the Mg2+ and Li+ forms of the enzyme in the accompanying paper.     

Comparison of rate constants for (PO3-) transfer by the Mg(II), Cd(II), and Li(I) forms of phosphoglucomutase

Net rate constants that define the steady-state rate through a sequence of steps and the corresponding effective energy barriers for two (PO3-)-transfer steps in the phosphoglucomutase reaction were compared as a function of metal ion, M, where M = Mg2+ and Cd2+. These steps involve the reaction of either the 1-phosphate or the 6-phosphate of glucose 1,6-bisphosphate (Glc-P2) bound to the dephosphoenzyme (ED) to produce the phosphoenzyme (EP) and the free monophosphates, glucose 1-phosphate (Glc-1-P) or glucose 6-phosphate (Glc-6-P): EP.M + Glc-1-P----ED.M.Glc-P2----EP.M.Glc-6-P6. Before this comparison was made, net rate constants for the Cd2+ enzyme, obtained at high enzyme concentration via 31P NMR saturation-transfer studies [Post, C. B., Ray, W. J., Jr., & Gorenstein, D. G. (1989) Biochemistry (preceding paper in this issue)], were appropriately scaled by using the observed constants to calculate both the expected isotope-transfer rate at equilibrium and the steady-state rate under initial velocity conditions and comparing the calculated values with those measured in dilute solution. For the Mg2+ enzyme, narrow limits on possible values of the corresponding net rate constants were imposed on the basis of initial velocity rate constants for the forward and reverse directions plus values for the equilibrium distribution of central complexes, since direct measurement is not feasible. The effective energy barriers for both the Mg2+ and Cd2+ enzymes, calculated from the respective net rate constants, together with previously values for the equilibrium distribution of complexes in both enzymic systems [Ray, W. J., Jr., & Long, J. W. (1976) Biochemistry 15, 4018-4025], show that the 100-fold decrease in the kappa cat for the Cd2+ relative to the Mg2+ enzyme is caused by two factors: the increased stability of the intermediate bisphosphate complex and the decreased ability to cope with the phosphate ester involving the 1-hydroxyl group of the glucose ring. In fact, it is unlikely that the efficiency of (PO3-) transfer to the 6-hydroxyl group of bound Glc-1-P (thermodynamically favorable direction) is reduced by more than an order of magnitude in the Cd2+ enzyme. By contrast, the efficiency of the Li+ enzyme in the same (PO3-)-transfer step is less than 4 x 10(-8) that of the Mg2+ enzyme.(ABSTRACT TRUNCATED AT 400 WORDS)     

Evidence from 13C NMR for polarization of the carbonyl of oxaloacetate in the active site of citrate synthase

The carbon-13 NMR spectrum of oxaloacetate bound in the active site of citrate synthase has been obtained at 90.56 MHz. In the binary complex with enzyme, the positions of the resonances of oxaloacetate are shifted relative to those of the free ligand as follows: C-1 (carboxylate), -2.5 ppm; C-2 (carbonyl), +4.3 ppm; C-3 (methylene), -0.6 ppm; C-4 (carboxylate), +1.3 ppm. The change observed in the carbonyl chemical shift is successively increased in ternary complexes with the product [coenzyme A (CoA)], a substrate analogue (S-acetonyl-CoA), and an acetyl-CoA enolate analogue (carboxymethyl-CoA), reaching a value of +6.8 ppm from the free carbonyl resonance. Binary complexes are in intermediate to fast exchange on the NMR time scale with free oxaloacetate; ternary complexes are in slow exchange. Line widths of the methylene resonance in the ternary complexes suggest complete immobilization of oxaloacetate in the active site. Analysis of line widths in the binary complex suggests the existence of a dynamic equilibrium between two or more forms of bound oxaloacetate, primarily involving C-4. The changes in chemical shifts of the carbonyl carbon indicate strong polarization of the carbonyl bond or protonation of the carbonyl oxygen. Some of this carbonyl polarization occurs even in the binary complex. Development of positive charge on the carbonyl carbon enhances reactivity toward condensation with the carbanion/enolate of acetyl-CoA in the mechanism which has been postulated for this enzyme. The very large change in the chemical shift of the reacting carbonyl in the presence of an analogue of the enolate of acetyl-CoA supports this interpretation.     

On the coordination of inhibitors to the metal ion of carboxypeptidase A. A 113Cd and 31P NMR study

113Cd and 31P NMR have been used to investigate the interactions of inhibitors with the metal ion of bovine carboxypeptidase A, using 113Cd as a replacement for the native zinc atom. In the absence of inhibitor and over the pH range 6-9, no 113Cd resonance is visible at room temperature. Upon lowering the temperature to 270 K, however, a broad resonance can be seen at 120 ppm. These results are discussed in terms of possible sources for this resonance modulation. Binding of low molecular weight inhibitors containing potential metal-coordinating moieties results in the appearance of a sharp 113Cd resonance. These inhibitors all bind to the metal ion, a fact which is reflected in the chemical shift of the cadmium resonance and, for L-phenylalanine phosphoramidate phenyl ester, by two-bond 113Cd-31P spin-spin coupling of 30 Hz in the 31P resonance of the bound inhibitor. For inhibitors that coordinate to the metal ion via oxygen, the 113Cd chemical shift is in the range 127-137 ppm, whereas for sulfur coordination there is a downfield shift of approximately 210 ppm. The complexes of 113Cd-substituted carboxypeptidase A with the D and L isomers of thiolactic acid are distinguished by a difference of 11 ppm in the chemical shift of their cadmium resonances. The enzyme complex formed with the macromolecular inhibitor from potatoes, which fills the S1 and S2 subsites, shows one or possibly two closely spaced broad 113Cd resonances. Both the chemical shift and the line width of the 113Cd resonances of the [113Cd]carboxypeptidase-inhibitor complexes give valuable structural and dynamic information about the enzyme active site.     

Cadmium-113 and magnesium-25 NMR study of the divalent metal binding sites of isocitrate dehydrogenases from pig heart

The metal activator sites of NAD⁺-dependent and NADP⁺-dependent isocitrate dehydrogenases from pig heart have been probed using ¹¹³Cd- and ²⁵Mg-NMR. In the presence of isocitrate and ADP, a broad resonance for cadmium bound to NAD-dependent isocitrate dehydrogenase was observed ( −8 ppm) arising from exchange with isocitrate (−20 ppm) and/or ADP (27 ppm) complexes. The Cd shift with ADP suggests interaction of the metal with the nucleotide ring nitrogen. Increasing shifts with excess ADP are indicative of macrochelate formation. ²⁵Mg-NMR demonstrates that, unlike manganese, magnesium has a similar dissociation constant (1.8 mM) from NADP-dependent isocitrate dehydrogenase as from the enzyme-isocitrate complex (1.1 mM). The extrapolated line width of bound magnesium increases from 674 Hz in the binary complex to 10 200 Hz in the ternary complex. The quadrupole coupling constant, calculated from relaxation rates, is larger in the ternary complex. indicative of greater distortion in the magnesium coordination sphere. The line widths of magnesium complexed to NAD-dependent isocitrate dehydrogenase are broader, as expected for the larger octamer. ¹¹³Cd- and ²⁵Mg-NMR both show that the metal sites have anisotropic octahedral symmetry. ²⁵Mg relaxation rates yield correlation times corresponding to motions of a domain with motion independent of the enzyme multimers.     

113Cd NMR study of bovine prothrombin fragment 1 and factor X

The interaction of Cd2+ with bovine prothrombin fragment 1, prothrombin intermediate 1, factor X, and a modified (Gla-domainless) factor X has been studied with 113Cd NMR. All the 113Cd resonances observed in this study were in the chemical shift range expected for oxygen ligands, suggesting that cadmium is binding at the same sites where calcium binds. Both fragment 1 and factor X displayed two major resonances, one near 10 ppm from 113Cd2+ that did not exchange rapidly with unbound 113Cd2+ (the high-affinity, or H, resonance) and one near -15 ppm from 113Cd2+ that exchanged rapidly with unbound 113Cd2+ (the low-affinity, or L, resonance). The difference between the chemical shift of the H resonance and the chemical shift range of -90 to -125 ppm that has been reported for three other small calcium-binding proteins is postulated to be due to different coordination geometries for monocarboxylate and dicarboxylate ligands; Cd2+ binds to fragment 1 and factor X through the dicarboxylate side chains of gamma-carboxyglutamate (Gla) residues. This allows contribution of only one oxygen per carboxyl group. At least one of the first few 113Cd2+ ions bound to fragment 1 did not appear in the 113Cd NMR spectrum until a total of five 113Cd2+ had been added. This could be due to exchange broadening of initial 113Cd2+ resonances due to sharing of ligands among several sites. Filling all sites would then restrict ligand exchange. Addition of Zn2+ displaced 113Cd2+ from the H resonance sites. Factor X did not display the interactions among ion binding sites proposed for fragment 1.     

Evidence for a dynamic structure of human neuronal growth inhibitory factor and for major rearrangements of its metal-thiolate clusters.

Human neuronal growth inhibitory factor (GIF), a metallothionein-like protein classified as metallothionein-3, impairs the survival and the neurite formation of cultured neurons. Despite its approximately 70% amino acid sequence identity with those of mammalian metallothioneins (MT-1 and MT-2 isoforms), only GIF exhibits growth inhibitory activity. In this study, structural features of the metal-thiolate clusters in recombinant Zn(7)- and Cd(7)-GIF, and in part also in synthetic GIF (68 amino acids), were investigated by using circular dichroism (CD) and (113)Cd NMR. The CD and (113)Cd NMR studies of recombinant Me(7)-GIF confirmed the existence of distinct Me(4)S(11)- and Me(3)S(9)-clusters located in the alpha- and beta-domains of the protein, respectively. Moreover, a mutual structural stabilization of both domains was demonstrated. The (113)Cd NMR studies of recombinant (113)Cd(7)-GIF were conducted at different magnetic fields (66.66 and 133.33 MHz) and temperatures (298 and 323 K). At 298 K the spectra revealed seven (113)Cd signals at 676, 664, 651, 644, 624, 622, and 595 ppm. A striking feature of all resonances is the absence of resolved homonuclear [(113)Cd-(113)Cd] couplings and large apparent line widths (between 140 and 350 Hz), which account for the absence of cross-peaks in [(113)Cd, (113)Cd] COSY. On the basis of a close correspondence in chemical shift positions of the (113)Cd signals at 676, 624, 622, and 595 ppm with those obtained in our previous studies of (113)Cd(4)-GIF(32-68) [Hasler, D. W., Faller, P., and Vasák, M. (1998) Biochemistry 37, 14966], these resonances can be assigned to a Cd(4)S(11)-cluster in the alpha-domain of (113)Cd(7)-GIF. Consequently, the remaining three (113)Cd signals at 664, 651, and 644 ppm originate from a Me(3)S(9) cluster in the beta-domain. However, the latter resonances show a markedly reduced and temperature-independent intensity (approximately 20%) when compared with those of the alpha-domain, indicating that the majority of the signal intensity remained undetected. To account for the observed NMR features of (113)Cd(7)-GIF, we suggest that dynamic processes acting on two different NMR time scales are present: (i) fast exchange processes among conformational cluster substates giving rise to broad, weight-averaged resonances and (ii) additional very slow exchange processes within the beta-domain associated with the formation of configurational cluster substates. The implications of the structure fluctuation for the biological activity of GIF are discussed.     

31P NMR of alkaline phosphatase. Saturation transfer and metal-phosphorus coupling.

The rate constants which characterize the formation and breakdown of the noncovalent (E.P) and covalent (E-P) enzyme-phosphate intermediates on the alkaline phosphatase reaction pathway are known to be sensitive to the nature of the metal ion bound to the enzyme. 31P NMR saturation transfer has been demonstrated to provide a simple and sensitive method for measuring the metal ion dependence of these rates under equilibrium conditions. When the native Zn2+ was replaced by Cd2+, the 31P NMR spectrum at high pH revealed a new resonance at 12.6 ppm which has been assigned to the noncovalent enzyme.phosphate complex. Reconstituting the enzyme with enriched 113Cd2+ caused this unusually downfield-shifted resonance to appear as a doublet due to 113Cd-31P spin coupling (2J31P-O-113Cd = 30 Hz). This result provides the first unequivocal evidence for direct metal-phosphate interaction in alkaline phosphatase.     

13C NMR studies of porphobilinogen synthase: observation of intermediates bound to a 280,000-dalton protein

13C NMR has been used to observe the equilibrium complex of [4-13C]-5-aminolevulinate ([4-13C]ALA) bound to porphobilinogen (PBG) synthase (5-aminolevulinate dehydratase), a 280,000-dalton protein. [4-13C]ALA (chemical shift = 205.9 ppm) forms [3,5-13C]PBG (chemical shifts = 121.0 and 123.0 ppm). PBG prepared from a mixture of [4-13C]ALA and [15N]ALA was used to assign the 121.0 and 123.0 ppm resonances to C5 and C3, respectively. For the enzyme-bound equilibrium complex formed from holoenzyme and [4-13C]ALA, two peaks of equal area with chemical shifts of 121.5 and 127.2 ppm are observed (line widths approximately 50 Hz), indicating that the predominant species is probably a distorted form of PBG. When excess free PBG is present, it is in slow exchange with bound PBG, indicating an exchange rate of less than 10 s-1, which is consistent with the turnover rate of the enzyme. For the complex formed from [4-13C]ALA and methyl methanethiosulfonate (MMTS) modified PBG synthase, which does not catalyze PBG formation, the predominant species is a Schiff base adduct (chemical shift = 166.5 ppm, line width approximately 50 Hz). Free ALA is in slow exchange with the Schiff base. Activation of the MMTS-modified enzyme-Schiff base complex with 113Cd and 2-mercaptoethanol results in the loss of the Schiff base signal and the appearance of bound PBG with the same chemical shifts as for the bound equilibrium complex with Zn(II) enzyme. Neither splitting nor broadening from 113Cd-13C coupling was observed.     

A nuclear magnetic resonance study of nicotinamide adenine dinucleotide phosphate binding to Lactobacillus casei dihydrofolate reductase.

The binding of NADP+ to dihydrofolate reductase (EC 1.5.1.3) in the presence and absence of substrate analogs has been studied using 1H and 13C nuclear magnetic resonance (NMR). NADP+ binds strongly to the enzyme alone and in the presence of folate, aminopterin, and methotrexate with a stoichiometry of 1 mol of NADP+/mol of enzyme. In the 13C spectra of the binary and ternary complexes, separate signals were observed for the carboxamide carbon of free and bound [13CO]NADP+ (enriched 90% in 13C). The 13C signal of the NADP+-reductase complex is much broader than that in the ternary complex with methotrexate because of exchange line broadening on the binary complex signal. From the difference in line widths (17.5 +/- 3.0 Hz) an estimate of the dissociation rate constant of the binary complex has been obtained (55 +/- 10 sec-1). The dissociation rate of the NADP+-reductase complex is not the rate-limiting step in the overall reaction. In the various complexes studied large 13C chemical shifts were measured for bound [13CO]NADP+ relative to free NADP+ (upfield shifts of 1.6-4.3 ppm). The most likely origin of the bound shifts lies in the effects on the shieldings of electric fields from nearby charged groups. For the NADP+-reductase-folate system two 13C signals from bound NADP+ are observed indicating the presence of more than one form of the ternary complex. The IH spectra of the binary and ternary complexes confirm both the stoichiometry and the value of the dissociation rate constant obtained from the 13C experiments. Substantial changes in the IH spectrum of the protein were observed in the different complexes and these are distinct from those seen in the presence of NADPH.     

Characterization of a vanadate-based transition-state-analogue complex of phosphoglucomutase by kinetic and equilibrium binding studies. Mechanistic implications

The inhibitor complex produced by the binding of alpha-D-glucose 1-phosphate 6-vanadate to the dephospho form of muscle phosphoglucomutase exhibits an unusually small dissociation constant: about 15 fM for the Mg2+ enzyme at pH 7.4, when calculated in terms of the tetraanion. Such tight binding suggests that the enzyme/vanadate/glucose phosphate complex mimics a state that at least approaches the transition state for (PO3-) transfer in the normal enzymic reaction. This hypothesis also is supported by the observation that replacement of Mg2+, the normal metal ion activator, by Li+, a poor activator, substantially reduces the binding constant for the glucose phosphate/vanadate mixed diester. Other indicators that support this hypothesis are described. One is the derived equilibrium constant for replacement of a PO4(2-) group in bound glucose bisphosphate by VO4(2-): 3 x 10(6) when the replaced group is the phosphate at the (PO3-) transfer site of the Mg2+ enzyme--in contrast to about 10 for the same replacement (of PO4(2-) by VO4(2-)) in an aqueous solution of a phosphate ester. Another is the greatly decreased rate at which Mg2+ dissociates from the glucose phosphate/vanadate complex of the enzyme, relative to the rate at which it dissociates from the corresponding bisphosphate complex (rate ratio less than or equal to 3 x 10(-4)), presumably because Mg2+ binds more tightly to the glucose phosphate/vanadate complex than to the corresponding bisphosphate complex. This apparent increase in Mg2+ binding occurs in spite of what appears to be a reduced charge density at the bound vanadate grouping, relative to the bound phosphate grouping, and in spite of the somewhat weaker binding of Mg2+ by dianionic vanadate than by the phosphate dianion. Although a direct assessment of the binding constant for Mg2+ was not possible, the equilibrium constant for Mg2+/Li+ exchange could be evaluated for the complexes of dephospho enzyme with glucose bisphosphate or glucose 1-phosphate 6-vanadate. The results suggest that the glucose phosphate/vanadate complex of the Mg2+ enzyme mimics a state about halfway between the ground state and the transition state for (PO3-) transfer. This estimate also is in accord with the binding of glucose phosphate/vanadate relative to that expected for transition-state binding of glucose bisphosphate. A possible scenario for the (PO3-) transfer catalyzed by the Mg2+ form of phosphoglucomutase is discussed, on the basis of these observations, together with possible reasons why the bound vanadate group appears to mimic an intermediate state for (PO3-) transfer rather than the ground state for phosphate binding.     

NMR spectroscopy of 113Cd(II)-substituted gene 32 protein

Gene 32 protein (g32P), the single-stranded DNA binding protein from bacteriophage T4, contains 1 mol of Zn(II)/mol of protein. This intrinsic zinc is retained within the DNA-binding core fragment, g32P-(A+B) (residues 22-253), obtained by limited proteolysis of the intact protein. Ultraviolet circular dichroism provides evidence that Zn(II) binding causes significant changes in the conformation of the peptide chain coupled with alterations in the microenvironments of tryptophan and tyrosine side chains. NMR spectroscopy of the 113Cd(II) derivative of g32P-(A+B) at both 44.4 and 110.9 MHz shows a single 113Cd resonance, delta 637, a chemical shift consistent with coordination to three of the four sulfhydryl groups in the protein. In vitro mutagenesis of Cys166 to Ser166 creates a mutant g32P that still contains 1 Zn(II)/molecule. This mutant protein when substituted with 113Cd(II) shows a 113Cd signal with a delta and a line width the same as those observed for the wild-type protein. Thus, the S-ligands to the metal ion appear to be contributed by Cys77, Cys87, and Cys90. Relaxation data suggest that chemical shift anisotropy is the dominant, but not exclusive, mechanism of relaxation of the 113Cd nucleus in g32P, since a dipolar modulation from ligand protons is observed at 44.4 MHz but not at 110.9 MHz. Complexation of core 113Cd g32P with d(pA)6 or Co(II) g32P with poly(dT) shows only minor perturbation of the NMR signal or d-d electronic transitions, respectively, suggesting that the metal ion in g32P does not add a ligand from the bound DNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

19F NMR studies of the binding of 5-fluoro-2′-deoxyuridylate to thymidylate synthase

Summary In the presence of thymidylate synthase, the ¹⁹F signal of 5-fluoro-2-deoxyuridylate is shifted upfield 0.6 ppm or 4.5 ppm depending on the enzyme preparation used. The bands at these positions represent different species of binary complex. When either binary complex is reacted with methylenetetrahydrofolate a ternary complex is formed with a ¹⁹F signal shifted 12.5 ppm upfield and broadened to 120 Hz.Substitution of the hydrogen atoms of the methylene group of methylenetetrahydrofolate with deuterium atoms results in line-narrowing of the spectrum of the ternary complex from 120 to 80 Hz indicating the close proximity of the methylene group to the fluorine atom in the ternary complex. A model compound, 5-fluoro-6-hydroxy-5-methyl-5, 6-dihydrouracil, gives a chemical shift in the same direction and of similar magnitude to that seen with the ternary complex.     

Thermolysin-inhibitor complexes examined by 31P and 113Cd NMR spectroscopy

Complexes between phosphoramidon (N-(alpha-rhamnopyranosyloxyhydroxyphosphinyl)-L-leucyl-L-tryptoph an) and zinc thermolysin and between phosphoramidon or N-phosphoryl-L-leucineamide and 113Cd-substituted thermolysin have been examined by 31P and 113Cd NMR spectroscopy. 113Cd resonances are observed at 168 and 152 ppm for the phosphoramidon and N-phosphoryl-L-leucineamide complexes, respectively. There are large but different chemical shift anisotropy contributions to the 113Cd line widths for the two complexes, which reflect the known structural differences for the zinc-enzyme complexes. 113Cd-31P spin-spin coupling is also seen and differs for the two cadmium complexes, being larger, 28 Hz, for the bidentate N-phosphoryl-L-leucineamide ligand than for the monodentate phosphoramidon, 16 Hz. Large changes in chemical shift, 7.5-10.9 ppm, are seen for the 31P resonances of the inhibitors upon binding to the enzyme reflecting direct phosphoryl-metal ligation. Chemical shift anisotropy is the dominant relaxation mechanism for the 31P nuclei at 9.4 T, while the dipole-dipole contribution seems to be unaffected by a change of solvent from H2O to D2O.     

Multinuclear NMR studies of the divalent metal binding site of NADP-dependent isocitrate dehydrogenase from pig heart

The metal activator site of NADP-dependent isocitrate dehydrogenase from pig heart has been probed by using 113Cd and 25Mg NMR as well as manganese paramagnetic relaxation of nuclei in the fast-exchanging ligands alpha-ketoglutarate and adenosine 2'-monophosphate. Cadmium NMR shows that cadmium, bound to the enzyme in the presence of isocitrate, has a resonance at 9 ppm relative to cadmium perchlorate, while the free Cd-isocitrate complex has a resonance at -23 ppm. Comparison with model compounds and previously studied proteins indicates that cadmium is coordinated with six oxygen ligands. Measurements as a function of cadmium concentration give a dissociation constant of 66 microM and a dissociation rate constant of 1.5 X 10(4) s-1 at pH 7.0. 25Mg NMR demonstrates that the line width of the magnesium resonance is increased upon binding to isocitrate dehydrogenase. A further increase in line width is observed upon addition of isocitrate. Measurement of line widths as a function of temperature reveals that in the binary complex between magnesium and enzyme, exchange is the major contributor to broadening while in the ternary complex containing isocitrate, the intrinsic relaxation in the bound state is also important, suggesting an increase in the dissociation rate constant for magnesium from the ternary complex. Paramagnetic relaxation studies of nuclei of alpha-ketoglutarate, bicarbonate, and adenosine 2'-monophosphate locate the divalent metal within the active site. The results with adenosine 2'-monophosphate show that atoms in the adenosine moiety of the coenzyme are at least 8 A from the metal site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Exploring the calcium-binding site in photosystem II membranes by solid-state (113)Cd NMR

Calcium (Ca(2+)) is an essential cofactor for photosynthetic oxygen evolution. Although the involvement of Ca(2+) at the oxidizing side of photosystem II of plants has been known for a long time, its ligand interactions and mode of action have remained unclear. In the study presented here, (113)Cd magic-angle spinning solid-state NMR spectroscopy is used to probe the Ca(2+)-binding site in the water-oxidizing complex of (113)Cd(2+)-substituted PS2. A single NMR signal 142 ppm downfield from Cd(ClO(4))(2).2H(2)O was recorded from Cd(2+) present at the Ca(2+)-binding site. The anisotropy of the signal is small, as indicated by the absence of spinning side bands. The signal intensity is at its maximum at a temperature of -60 degrees C. The line width of the proton signal in a WISE (wide-line separation) two-dimensional (1)H-(113)Cd NMR experiment demonstrates that the signal arises from Cd(2+) in a solid and magnetically undisturbed environment. The chemical shift, the small anisotropy, and the narrow line of the (113)Cd NMR signal provide convincing evidence for a 6-fold coordination, which is achieved partially by oxygen and partially by nitrogen or chlorine atoms in otherwise a symmetric octahedral environment. The absence of a (113)Cd signal below -70 degrees C suggests that the Ca(2+)-binding site is close enough to the tetramanganese cluster to be affected by its electron spin state. To our knowledge, this is the first report for the application of solid-state NMR in the study of the membrane-bound PS2 protein complex.     

113Cd nuclear magnetic resonance of Cd(II) alkaline phosphatases

113Cd NMR spectra of 113Cd(II)-substituted Escherichia coli alkaline phosphatase have been recorded over a range of pH values, levels of metal site occupancy, and states of phosphorylation. Under all conditions resonances attributable to cadmium specifically bound at one or more of the three pairs of metal-binding sites (A, B, and C sites) are detected. By following changes in both the 113Cd and 31P NMR spectra of 113Cd(II)2 alkaline phosphatase during and after phosphorylation, it has been possible to assign the cadmium resonance that occurs between 140 and 170 ppm to Cd(II) bound to the A or catalytic site of the enzyme and the resonance occurring between 51 and 76 ppm to Cd(II) bound to B site, which from x-ray data is located 3.9 A from the A site. The kinetics of phosphorylation show that cadmium migration from the A site of one subunit to the B site of the second subunit follows and is a consequence of phosphate binding, thus precluding the migration as a sufficient explanation for half-of-the-sites reactivity. Rather, there is evidence for subunit-subunit interaction rendering the phosphate binding sites inequivalent. Although one metal ion, at A site, is sufficient for phosphate binding and phosphorylation, the presence of a second metal ion at B site greatly enhances the rate of phosphorylation. In the absence of phosphate, occupation of the lower affinity B and C sites produces exchange broadening of the cadmium resonances. Phosphorylation abolishes this exchange modulation. Magnesium at high concentration broadens the resonances to the point of undetectability. The chemical shift of 113Cd(II) in both A and B sites (but not C site) is different depending on the state of the bound phosphate (whether covalently or noncovalently bound) and gives separate resonances for each form. Care must be taken in attributing the initial distribution of cadmium or phosphate in the reconstituted enzyme to that of the equilibrium species in samples reconstituted from apoenzyme. Both 113Cd NMR and 31P NMR show that some conformational changes consequent to metal ion or phosphate binding require several days before the final equilibrium species is formed.     

Effects of sample preparation conditions on biomolecular solid-state NMR lineshapes

Sample preparation conditions with the 46 kDa enzyme complex of 5-enolpyruvyl-shikimate-3-phosphate (EPSP) synthase, shikimate-3-phosphate (S3P) and glyphosate (GLP) have been examined in an attempt to reduce linewidths in solid-state NMR spectra. The linewidths of ¹³P resonances associated with enzyme bound S3P and GLP in the lyophilized ternary complex have been reduced to 150 ± 12 Hz and 125 ± 7 Hz respectively, by a variety of methods involving additives and freezing techniques.     

Calcium ion as a probe of the monovalent cation center of sodium, potassium ATPase

Sodium and potassium ion-transport adenosine triphosphatase from dog kidney was incubated with 0.4-2 mM Ca2+ at 23 degrees C for more than 2 min in the absence of monovalent inorganic cations, cooled to 0 degrees C, and phosphorylated from 1 mM Pi with 2.4 mM MgCl2. The resultant phosphoenzyme resembled that obtained by incubating the enzyme with K+ in place of Ca2+ in six respects. It was concluded that Ca2+ can occupy the monovalent cation-binding center for K+. The rate constant for release of Ca2+ from the dephosphoenzyme at 0 degrees C was 0.17 s-1. The rate of release from the phosphoenzyme was at least 7-fold slower. Phosphorylation stabilized the binding of Ca2+ to the enzyme in contrast to its destabilization of the corresponding K X enzyme complex. K-sensitive phosphoenzyme did not respond to free Ca2+. Thus Ca2+ was not easily accepted by nor released from the phosphoenzyme and would not be an effective substrate for transport. A selective barrier against Ca2+ between the monovalent cation binding center and the extracellular solution is proposed. Release of calcium from the dephosphoenzyme yielded a conformation that was not phosphorylated from Pi. The enzyme changed the conformation of its center for phosphorylation before or at the same time that it changed the conformation of its center for ion transport.