Studies of activating and nonactivating metal ion binding to yeast enolase

Measurements of binding of certain divalent cations to yeast apoenolase were made using a pH-meter, chromatography, a divalent cation electrode, and ultrafiltration. The binding of the activating metal ions Mg2+ and Co2+ and the nonactivator Ca2+ were studied as functions of the presence or absence of substrate/product, phosphate, and fluoride or level of Tb3+. The data suggest phosphate and fluoride increase Mg2+ binding but not Ca2+ binding. Substrate/product appears to increase Ca2+ binding as well as that of Mg2+ and Co2+. In the presence of substrate, Co2+ binding was 5-6 mol/mol dimer. In the absence of substrate/product, Tb3+ reduced Co2+ binding from 4 mol/mol to 2. These data are interpreted in terms of binding to "conformational," "catalytic" (substrate/product dependent), and "inhibitory" sites. Measurements of Tb3+ fluorescence quenching by Co2+ suggested that the distance between "conformational" sites on the two subunits was large, while the distance between "conformational" and "inhibitory" sites was ca. 17 +/- 4 A. Potentiometric titrations of apoenzyme with Ca2+ and Mg2+ showed that the metal ions produced the same proton release in the presence or absence of substrate/product. If phosphate and fluoride were present, then more protons were released if Ca2+ was the titrant rather than Mg2+, suggesting a difference in ionization state in the complex with the activating metal. Electron paramagnetic resonance studies of Co2+ binding to the various sites in the enzyme are presented. The Co2+ bound to all three sites appears to be high spin, consistent with a preponderance of oxyligands in an octahedral environment. Substrate, citrate, and a strongly binding substrate analogue strongly enhance the hyperfine structure of conformational Co2+. This is interpreted as the result of a change in interaction of an axial ligand to conformational Co2+ produced by carbon-3 of substrate or analogue.     

Differential effects of metal ions on Rhodospirillum rubrum ribulosebisphosphate carboxylase/oxygenase and stoichiometric incorporation of HCO3- into a cobalt(III)--enzyme complex.

Mg2+ or Mn2+ ions supported both the carboxylase and oxygenase activities of the Rhodospirillum rubrum ribulosebisphosphate carboxylase/oxygenase. For the carboxylase reaction, Mn2+ supported 25% of the maximum activity obtained with Mg2+; oxygenase activity, however, was twice as great with Mn2+ as compared to that with Mg2+. A further differential effect was obtained with Co2+. Co2+ did not support carboxylase activity and, in fact, was a strong inhibitor of Mg2+-dependent carboxylase activity, with a Ki of 10 microM. Co2+ did, however, support oxygenase activity, eliciting about 40% of the Mg2+-dependent oxygenase activity. No other divalent cations supported either activity. With high concentrations of Mg2+ or Mn2+, maximum carboxylase activity was seen after a 5-min activation period; activity decreased to about half of maximum after 30-min activation. A similar time dependence of activation was observed with Mn2+-dependent oxygenase activity but was not seen for Mg2+- or Co2+-dependent activity. Both carboxylase and oxygenase activities were inactivated by the oxidation of Co2+ to Co(III) with the resultant formation of a stable Co(III)--enzyme complex. In the presence of HCO3- (CO2), Co(III) modification was stoichiometric, with two cobalt atoms bound per enzyme dimer. Carbon dioxide was also incorporated into this Co(III)--enzyme complex, but only one molecule per enzyme dimer was bound, indicative of half-the-sites activity. These results thus indicate that there are substantial differences in the metal ion sites of the carboxylase and oxygenase activities of R, rubrum ribulosebisphosphate carboxylase/oxygenase.     

Site-specific substituted cobalt(II) horse liver alcohol dehydrogenases. Preparation and characterization in solution, crystalline and immobilized state.

The specific substitution, using highly selective techniques, of catalytic and/or noncatalytic zinc ions by cobaltous ions in horse liver alcohol dehydrogenase (EC 1.1.1.1) has been studied with dissolved, crystalline and agarose-immobilised enzyme, in order to examine the effect of protein structure on the specificity of the metal exchange. The different binding sites can be clearly distinguished by the absorption spectra of their cobalt derivatives. In solution an anaerobic column chromatographic method made it possible to exchange half of the zinc in the enzyme by cobalt ions in a much shorter time than previous procedures. By raising the temperature in the exchange step, even the slowly exchanging zinc ions were substituted by cobalt, yielding products similar to cobalt alcohol dehydrogenases described earlier. Treatment of crystal suspensions of the enzyme with chelating agents (preferentially dipicolinic acid) gave an inactive protein with two zinc ions remaining bound. The enzyme could be reactivated by treatment of the crystalline protein with 5 mM zinc or cobaltous ions or by dialysis of dissolved inactive protein against 20 microM zinc or 1 mM cobaltous ions. Higher metal concentrations led to denaturation but the inactive protein could be crystallized from solution and then reactivated completely at higher metal concentrations. The preparation and absorption spectrum show that cobalt is bound specifically at the catalytic sites. Since metal substitution at these sites critically depends on the maintenance of the correct tertiary and quaternary structure, these must be preserved in the crystal lattice and partially altered in solution when the catalytic zinc ions are removed (or when excess of metal ions is applied), thus demonstrating the structure-stabilizing role of the catalytic metal ions. The enzyme immobilised on agarose, with unchanged content of active sites [Schneider-Bernl?hr et al. (1978) Eur. J. Biochem. 41, 475--484], was treated like the crystal suspensions. Although half of the zinc was removed, some activity remained. After reactivation with cobaltous ions, a loss of about 30% active sites was measured. Thus the apparently homogenous bound enzyme was rather heterogeneous in the properties of its catalytic metal binding sites. These results are taken as further proof for the dependence of the metal substitution on the proper tertiary and quaternary structure which is strained by multiple interactions in the covalently immobilised enzyme.     

The cobalt(II)-alkaline phosphatase system at alkaline pH

The uptake of cobalt(II) ions by apoalkaline phosphatase at pH 8 (the pH optimum for activity) has been investigated by the combined use of electronic and 1H NMR spectroscopies. The presence of fast-relaxing high spin cobalt(II) ions in the active site cavity of the protein induces sizable isotropic shifts of the 1H NMR signals of metal-coordinated protein residues, allowing us to propose a metal uptake pattern by the various metal binding sites both in the presence and in the absence of magnesium ions. In the absence of magnesium the active site is not organized in specific metal binding sites. The first equivalent of cobalt(II) ions per dimer binds in an essentially unspecific and possibly fluxional fashion, giving rise to a six-coordinated chromophore. The second and third equivalents induce the formation of increasing amounts of metal ions pairs, cooperatively arranged into the A and B sites of the same subunit with a five- and six-coordinated geometry, respectively. The fourth and fifth equivalents induce the formation of fully blocked A-B pairs in both subunits. Magnesium shows the property of organizing the metal binding sites, probably through coordination to the C sites. Electronic and 1H NMR titration with Co2+ ions show that the initial amount of fluxional cobalt is smaller than in the absence of magnesium and that A-B pairs are more readily formed. Titration of fully metalated Co4Mg2alkaline phosphatase samples with phosphate confirms binding of only one phosphate per dimer.     

Metal ion-induced conformational changes in Escherichia coli alkaline phosphatase.

Ultraviolet difference spectra are produced by the binding of divalent metal ions to metal-free alkaline phosphatase (EC 3.1.3.1). The interaction of the apoprotein with Zn2+, Mn2+, Co2+ and Cd2+, which induce the tight binding of one phosphate ion per dimer, give distinctly different ultraviolet spectra changes from Ni2+ and Hg2+ which do not induce phosphate binding. Spectrophotometric titrations at alkaline pH of various metallo-enzymes reveal a smaller number of ionizable tyrosines and a greater stability towards alkaline denaturation in the Zn2+- and Mn2+-enzymes than in the Ni2+-, Hg2+- and apoenzymes. The Zn2+- and Mn2+-enzymes have CD spectra in the region of the aromatic transitions that are different from the CD spectra of the Ni2+-, Hg2+- and apoenzymes. Modifications of arginines with 2,3-butanedione show that a smaller number of arginine residues are modified in the Zn2+-enzyme than in the Hg2+-enzyme. The presented data indicate that alkaline phosphatase from Escherichia coli must have a well-defined conformation in order to bind phosphate. Some metal ions (i.e. Zn2+, Co2+, Mn2+ and Cd2+), when interacting with the apoenzyme, alter the conformation of the protein molecule in such a way that it is able to interact with substrate molecules, while other metal ions (i.e. Ni2+ and Hg2+) are incapable of inducing the appropriate conformational change of the apoenzyme. These findings suggest an important structural function of the first two tightly bound metal ions in enzyme.     

Labeling of integrin alpha v beta 3 with 58Co(III). Evidence of metal ion coordination sphere involvement in ligand binding.

Integrin-mediated cell adhesion to the extracellular matrix is divalent metal ion-dependent; however, a demonstration of the interaction between native integrins and divalent metal ions is lacking. Here we provide direct evidence that the vitronectin receptor (VNR) is a metalloprotein. The unique electron shell of Co(II), an ion which we show supports ligand recognition by VNR, enables its oxidative conversion to inert Co(III). This property facilitated "affinity labeling" of VNR with 58Co(III) by oxidation of the metal ion in situ (i.e. in position). An average of 3.5 +/- 0.5 mol of cobalt were incorporated per mol of VNR. The ability of VNR to bind metal ions was independently confirmed by examining the interaction between VNR and Mn2+ under native conditions. The apparent high affinity between VNR and Mn2+ allowed us to observe the specific binding between 54Mn2+ and VNR by equilibrium gel filtration studies. Interestingly, the oxidative incorporation of Co(III) into VNR specifically blocked ligand binding, suggesting that the coordination sphere of metal ion bound to VNR is a critical determinant in integrin-ligand recognition. Furthermore, Mn2+ abolished the oxidative affinity labeling of VNR with Co(III) and consequently blocked the inactivation of VNR by in situ incorporation of Co(III). Thus, Mn2+ and Co2+ bind to the same or mutually exclusive sites on VNR. These observations provide the first demonstration that an integrin, specifically VNR, is a metalloprotein and demonstrate a functional link between the coordination sphere of the bound metal ion and ligand recognition by this receptor.     

Divalent metal ion, inorganic phosphate, and inorganic phosphate analogue binding to yeast inorganic pyrophosphatase

Four different techniques, equilibrium dialysis, protection of enzymatic activity against chemical inactivation, 31P relaxation rats, and water proton relaxation rates, are used to study divalent metal ion, inorganic phosphate, and inorganic phosphate analogue binding to yeast inorganic pyrophosphatase, EC 3.6.1.1. A major new finding is that the binding of a third divalent metal ion per subunit, which has elsewhere been implicated as being necessary for enzymatic activity [Springs, B., Welsh, K. M., & Cooperman, B. S. (1981) Biochemistry (in press)], only becomes evident in the presence of added inorganic phosphate and that, reciprocally, inorganic phosphate binding to both its high- and low-affinity sites on the enzyme is markedly enhanced in the presence of divalent metal ions, with Mn2+ causing an especially large increase in affinity. The results obtained allow evaluation of all of the relevant equilibrium constants for the binding of Mn2+ and inorganic phosphate or of Co2+ and inorganic phosphate to the enzyme and show that the high-affinity site has greater specificity for inorganic phosphate than the low-affinity site. In addition, they provide. The results obtained allow evaluation of all of the relevant equilibrium constants for the binding of Mn2+ and inorganic phosphate or of Co2+ and inorganic phosphate to the enzyme and show that the high-affinity site has greater specificity for inorganic phosphate than the low-affinity site. In addition, they provide. The results obtained allow evaluation of all of the relevant equilibrium constants for the binding of Mn2+ and inorganic phosphate or of Co2+ and inorganic phosphate to the enzyme and show that the high-affinity site has greater specificity for inorganic phosphate than the low-affinity site. In addition, they provide evidence against divalent metal ion inner sphere binding to phosphate for enzyme subunits having one or two divalent metal ions bound per subunit and evidence for a conformational change restricting active-site accessibility to solvent on the binding of a third divalent metal ion per subunit.     

Investigations of the metal ion-binding sites of yeast inorganic pyrophosphatase

Yeast inorganic pyrophosphatase was found to bind two Mn2+ per subunit in the absence of phosphate and three Mn2+ per subunit in the presence of phosphate. Kinetic studies of the pyrophosphatase-catalyzed hydrolysis of Cr(NH3)4PP and Cr(H2O)4PP were carried out with Mn2+ and with Mg2+ as activators. The results from these studies suggest that three divalent cations per pyrophosphatase active site are required for catalysis. NMR and EPR studies were conducted to evaluate the relative location of the metal ion binding sites on the enzyme. The two Mn2+ ions bound to the free enzyme are in close enough proximity to magnetically interact. Analysis of the NMR and EPR data in terms of a dipolar relaxation mechanism between Mn2+ ions provides an estimate of the distance between them of 10-14 A. When the diamagnetic substrate analog [Co(NH3)4PNP]- or intermediate analog [Co(NH3)4 (P)2]- are bound to pyrophosphatase, two Mn2+ ions still bind to the enzyme and their magnetic interaction increases. In the presence of these Co3+ complexes, the Mn2+--Mn2+ separation decreases to 7-9 A. Several NMR and EPR experiments were conducted at low Mn2+ to pyrophosphatase ratios (approximately 0.3), where only one Mn2+ ion binds per subunit, in the presence of Cr3+ or Co3+ complexes of PNP or PP. Analysis of the Mn2+--Cr3+ dipolar relaxation evident in proton NMR and EPR data provided for the calculation of Mn2+--Cr3+ distances. When the substrate analog CrPNP was present, the Mn2+--Cr3+ distance was congruent to 7 A whereas, when Cr(P)2 was bound to pyrophosphatase, the Mn2+--Cr3+ distance was congruent to 5 A. These results strongly support a model for the catalytic site of pyrophosphatase that involves three metal ion cofactors.     

Binding of inhibitory metals to yeast enolase

Certain divalent cations can inhibit yeast enolase by binding at sites that are distinct from those metal binding sites normally associated with catalytic activity, i.e., the conformational and catalytic binding sites. By using a buffer that does not compete with metal ions (tetrapropylammonium borate) Zn, Co, Mn, Cu, Cd, and Ni are found to exhibit similar inhibitory characteristics. Inhibition by those metals is alleviated by the addition of imidazole or tris buffer and, for zinc, by a metal chelating agent (Calcein). Inhibition by zinc was examined in detail through binding studies and enzymatic activity measurement. In tetrapropylammonium buffers at pH 8.0, enolase binds up to four moles of zinc per mole of enzyme (two moles per subunit). An imidazole concentration of 0.05 M reduces the binding: in the absence of substrate, just two moles of zinc per enzyme are bound. The enzyme will bind two additional moles of zinc upon the addition of substrate in either buffer, but the enzyme in tetrapropylammonium buffer is nearly inactive. Inhibition is, therefore, correlated with the binding of two moles of zinc per mole of enzyme. Some additional metal ions, Ca, Tb, Hg, and Ag also caused inhibition of yeast enolase but not by binding to the inhibitory site described.     

Metal binding to DNA polymerase I, its large fragment, and two 3',5'-exonuclease mutants of the large fragment

DNA polymerase I (Pol I) is an enzyme of DNA replication and repair containing three active sites, each requiring divalent metal ions such as Mg2+ or Mn2+ for activity. As determined by EPR and by 1/T1 measurements of water protons, whole Pol I binds Mn2+ at one tight site (KD = 2.5 microM) and approximately 20 weak sites (KD = 600 microM). All bound metal ions retain one or more water ligands as reflected in enhanced paramagnetic effects of Mn2+ on 1/T1 of water protons. The cloned large fragment of Pol I, which lacks the 5',3'-exonuclease domain, retains the tight metal binding site with little or no change in its affinity for Mn2+, but has lost approximately 12 weak sites (n = 8, KD = 1000 microM). The presence of stoichiometric TMP creates a second tight Mn2+ binding site or tightens a weak site 100-fold. dGTP together with TMP creates a third tight Mn2+ binding site or tightens a weak site 166-fold. The D424A (the Asp424 to Ala) 3',5'-exonuclease deficient mutant of the large fragment retains a weakened tight site (KD = 68 microM) and has lost one weak site (n = 7, KD = 3500 microM) in comparison with the wild-type large fragment, and no effect of TMP on metal binding is detected. The D355A, E357A (the Asp355 to Ala, Glu357 to Ala double mutant of the large fragment of Pol I) 3',5'-exonuclease-deficient double mutant has lost the tight metal binding site and four weak metal binding sites. The binding of dGTP to the polymerase active site of the D355A,E357A double mutant creates one tight Mn2+ binding site with a dissociation constant (KD = 3.6 microM), comparable with that found on the wild-type enzyme, which retains one fast exchanging water ligand. Mg2+ competes at this site with a KD of 100 microM. It is concluded that the single tightly bound Mn2+ on Pol I and a weakly bound Mn2+ which is tightened 100-fold by TMP are at the 3',5'-exonuclease active site and are essential for 3',5'-exonuclease activity, but not for polymerase activity. Additional weak Mn2+ binding sites are detected on the 3',5'-exonuclease domain, which may be activating, and on the polymerase domain, which may be inhibitory. The essential divalent metal activator of the polymerase reaction requires the presence of the dNTP substrate for tight metal binding indicating that the bound substrate coordinates the metal.(ABSTRACT TRUNCATED AT 400 WORDS)     

ADP, chloride ion, and metal ion binding to bovine brain glutamine synthetase

The binding of divalent cations and nucleotide to bovine brain glutamine synthetase and their effects on the activity of the enzyme were investigated. In ADP-supported gamma-glutamyl transfer at pH 7.2, kinetic analyses of saturation functions gave [S]0.5 values of approximately 1 microM for Mn2+, approximately 2 mM for Mg2+, 19 nM for ADP.Mn, and 7.2 microM for ADP.Mg. The method of continuous variation applied to the Mn2+-supported reaction indicated that all subunits of the purified enzyme express activity when 1.0 equiv of ADP is bound per subunit. Measurements of equilibrium binding of Mn2+ to the enzyme in the absence and presence of ADP were consistent with each subunit binding free Mn2+ (KA approximately equal to 1.5 X 10(5) M-1) before binding the Mn.ADP complex (KA' approximately equal to 1.1 X 10(6) M-1). The binding of the first Mn2+ or Mg2+ to each subunit produces structural perturbations in the octameric enzyme, as evidenced by UV spectral and tryptophanyl residue fluorescence changes. The enzyme, therefore, has one structural site per subunit for Mn2+ or Mg2+ and a second site per subunit for the metal ion-nucleotide complex, both of which must be filled for activity expression. Chloride binding (KA' approximately equal to 10(4) M-1) to the enzyme was found to have a specific effect on the protein conformation, producing a substantial (30%) quench of tryptophanyl fluorescence and increasing the affinity of the enzyme 2-4-fold for Mg2+ or Mn2+. Arsenate, which activates the gamma-glutamyl transfer activity by binding to an allosteric site, and L-glutamate also cause conformational changes similar to those produced by Cl- binding. Anion binding to allosteric sites and divalent metal ion binding at active sites both produce tryptophanyl residue exposure and tyrosyl residue burial without changing the quaternary enzyme structure.     

Investigating the effects of posttranslational adenylylation on the metal binding sites of Escherichia coli glutamine synthetase using lanthanide luminescence spectroscopy.

Lanthanide luminescence was used to examine the effects of posttranslational adenylylation on the metal binding sites of Escherichia coli glutamine synthetase (GS). These studies revealed the presence of two lanthanide ion binding sites of GS of either adenylylation extrema. Individual emission decay lifetimes were obtained in both H2O and D2O solvent systems, allowing for the determination of the number of water molecules coordinated to each bound Eu3+. The results indicate that there are 4.3 +/- 0.5 and 4.6 +/- 0.5 water molecules coordinated to Eu3+ bound to the n1 site of unadenylylated enzyme, GS0, and fully adenylylated enzyme, GS12, respectively, and that there are 2.6 +/- 0.5 water molecules coordinated to Eu3+ at site n2 for both GS0 and GS12. Energy transfer measurements between the lanthanide donor-acceptor pair Eu3+ and Nd3+, obtained an intermetal distance measurement of 12.1 +/- 1.5 A. Distances between a Tb3+ ion at site n2 and tryptophan residues were also performed with the use of single-tryptophan mutant forms of E. coli GS. The dissociation constant for lanthanide ion binding to site n1 was observed to decrease from Kd = 0.35 +/- 0.09 microM for GS0 to Kd = 0.06 +/- 0.02 microM for GS12. The dissociation constant for lanthanide ion binding to site n2 remained unchanged as a function of adenylylation state; Kd = 3.8 +/- 0.9 microM and Kd = 2.6 +/- 0.7 microM for GS0 and GS12, respectively. Competition experiments indicate that Mn2+ affinity at site n1 decreases as a function of increasing adenylylation state, from Kd = 0.05 +/- 0.02 microM for GS0 to Kd = 0.35 +/- 0.09 microM for GS12. Mn2+ affinity at site n2 remains unchanged (Kd = 5.3 +/- 1.3 microM for GS0 and Kd = 4.0 +/- 1.0 microM for GS12). The observed divalent metal ion affinities, which are affected by the adenylylation state, agrees with other steady-state substrate experiments (Abell LM, Villafranca JJ, 1991, Biochemistry 30:1413-1418), supporting the hypothesis that adenylylation regulates GS by altering substrate and metal ion affinities.     

Circular dichroism (CD) studies on yeast enolase: activation by divalent cations

The effect of divalent cations on the near ultraviolet circular dichroism (CD) spectrum of yeast enolase showed that calcium, magnesium, and nickel ions produced identical changes. This was interpreted as indicating that the cations bound to the same sites on the enzyme and produced identical changes in tertiary structure. There was no effect of magnesium ion on the far ultraviolet spectrum. Evidently magnesium ion has no effect on the secondary structure. Substrate bound to the enzyme when the above cations were present although calcium permits no enzymatic activity. The CD spectral difference produced by the substrate was nearly the reverse of that produced by the metal ions. Glycolic acid phosphate, a competitive inhibitor lacking carbon-3, produced no effect, indicating carbon-3 was necessary for the CD spectral changes. The CD and visible absorption spectra of nickel and cobalt bound to various sites on the enzyme showed that the binding sites were octahedral or distorted octahedral in coordination and that the ligands appeared to be oxyligands: water molecules, hydroxyl or carboxyl groups. Examination of the effects of substrate and two compounds thought to be "transition state analogues" showed that these perturbed the "conformational" sites of the enzyme. The "catalytic" and "inhibitory" sites did not appear to be very CD active.     

19-F NMR studies of the binding of a fluorine-labeled phosphonate ion to E. coli alkaline phosphatase.

The interaction of a fluorinated phosphonate with Zn-2+-and Mn-2+-alkaline phosphatase as studied by 19-F NMR revealed a stoichiometry of 1:1 for the binding of the phosphonate anion to the enzyme. In the presence of two metal ions, one fluorinated phosphonate ion was found to interact strongly with the enzyme, while a different interaction was observed when the number of metal ions per enzyme exceeded two. Phosphate replaced enzyme bound phosphonate, as is shown by the 19-F NMR spectra. No direct interaction between the fluorinated phosphonate and the metal ion responsible for enzyme activity was indicated by the 19-F NMR data. This observation supports the idea of a considerable distance between metal ion and substrate binding site in Escherichia coli alkaline phosphatase.     

The Glu(B13) carboxylates of the insulin hexamer form a cage for Cd2+ and Ca2+ ions

Substitution of Cd2+ for Zn2+ yields a hexameric insulin species containing 3 mol of metal ion per hexamer. The Cd2+ binding loci consist of the two His(B10) sites and a new site involving the Glu(B13) residues located at the center of the hexamer [Sudmeier, J. L., Bell, S. J., Storm, M. C., & Dunn, M. F. (1981) Science (Washington, D.C.) 212, 560-562]. Substitution of Co2+ or Co3+ for Zn2+ gives hexamers containing 2 mol of metal per hexamer. Insulin solutions to which both Cd2+ and Co2+ have been added in a ratio of 6:2:1 [In]:[Co2+]:[Cd2+] followed by oxidation to the exchange-inert Co3+ state yield stable hybrid species containing both Co3+ and Cd2+ with a composition of (In)6(Co3+)2Cd2+. The kinetics of the reaction of 2,2',2"-terpyridine (terpy) with the exchange-labile (In)6(Cd2+)2 and (In)6(Co2+)2 derivatives are biphasic and involve the rapid formation of an intermediate with coordination of one terpy molecule to each protein-bound metal ion; then, in a rate-limiting step the terpy-coordinated metal ion dissociates from the protein, and a second molecule of terpy binds to the metal ion to form a bis complex. Reaction of the exchange-inert Co3+ ions of (In)6(Co3+)2 with terpy is a slow apparent first-order process (t1/2 = 13.1 h). In contrast to the kinetic behavior of (In)6(Co2+)2 and (In)6(Cd2+)2, the Cd2+ ions bound to the hybrid (In)6(Co3+)2Cd2+ react quite slowly with terpy (t1/2 = 1 h at pH 8.0).(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence of a calcium-induced structural change in the ATP-binding site of the sarcoplasmic-reticulum Ca2+-ATPase using terbium formycin triphosphate as an analogue of Mg-ATP

Terbium ions and terbium formycin triphosphate have been used to investigate the interactions between the cation and nucleotide binding sites of the sarcoplasmic reticulum Ca2+-ATPase. Three classes of Tb3+-binding sites have been found: a first class of low-affinity (Kd = 10 microM) corresponds to magnesium binding sites, located near a tryptophan residue of the protein; a second class of much higher affinity (less than 0.1 microM) corresponds to the calcium transport sites, their occupancy by terbium induces the E1 to E2 conformational change of the Ca2+-ATPase; a third class of sites is revealed by following the fluorescence transfer from formycin triphosphate (FTP) to terbium, evidencing that terbium ions can also bind into the nucleotide binding site at the same time as FTP. Substitution of H2O by D2O shows that Tb-FTP binding to the enzyme nucleotide site is associated with an important dehydration of the terbium ions associated with FTP. Two terbium ions, at least, bind to the Ca2+-ATPase in the close vicinity of FTP when this nucleotide is bound to the ATPase nucleotide site. Addition of calcium quenches the fluorescence signal of the terbium-FTP complex bound to the enzyme. Calcium concentration dependence shows that this effect is associated with the replacement of terbium by calcium in the transport sites, inducing the E2----E1 transconformation when calcium is bound. One interpretation of this fluorescence quenching is that the E1----E2 transition induces an important structural change in the nucleotide site. Another interpretation is that the high-affinity calcium sites are located very close to the Tb-FTP complex bound to the nucleotide site.     

Activation and inactivation of horseradish peroxidase by cobalt ions

The effect of cobalt ions (Co2+) on horseradish peroxidase (HRP) was studied in vitro by enzymatic activity assay, electronic absorption spectra, intrinsic fluorescence spectra and 8-anilo-1-naphthalenesulfonate(ANS)-binding fluorescence spectra. Co2+ at concentrations below 0.1 mM mildly increased the HRP activity, whereas higher concentrations of Co2+ significantly inactivated HRP in a time and concentration-dependent manner. Steady-state kinetic studies show that Co2+ was a noncompetitive inhibitor of o-dianisidine oxidation by HRP. The Ki value dropped as the incubation time increased. Furthermore, Co2+ was found to be an uncompetitive inhibitor of H2O2. These results suggested that Co2+ would slowly bind to the enzyme and progressively induce conformational changes. Spectroscopic analysis showed that even for high Co2+ concentrations, the structure of HRP as a whole only changed slightly; however, there were significant conformational changes near or in the active site of HRP. Based on the above results, we suggest that Co2+ may bind with some amino acids near or in the active site of HRP and the conformational changes of HRP induced by such binding should be the main reason for activation and inactivation effect of Co2+. The potential binding sites of Co2+ were also proposed.     

The role of divalent cations in structure and function of murine adenosine deaminase.

For murine adenosine deaminase, we have determined that a single zinc or cobalt cofactor bound in a high affinity site is required for catalytic function while metal ions bound at an additional site(s) inhibit the enzyme. A catalytically inactive apoenzyme of murine adenosine deaminase was produced by dialysis in the presence of specific zinc chelators in an acidic buffer. This represents the first production of the apoenzyme and demonstrates a rigorous method for removing the occult cofactor. Restoration to the holoenzyme is achieved with stoichiometric amounts of either Zn2+ or Co2+ yielding at least 95% of initial activity. Far UV CD and fluorescence spectra are the same for both the apo- and holoenzyme, providing evidence that removal of the cofactor does not alter secondary or tertiary structure. The substrate binding site remains functional as determined by similar quenching measured by tryptophan fluorescence of apo- or holoenzyme upon mixing with the transition state analog, deoxycoformycin. Excess levels of adenosine or N6- methyladenosine incubated with the apoenzyme prior to the addition of metal prevent restoration, suggesting that the cofactor adds through the substrate binding cleft. The cations Ca2+, Cd2+, Cr2+, Cu+, Cu2+, Mn2+, Fe2+, Fe3+, Pb2+, or Mg2+ did not restore adenosine deaminase activity to the apoenzyme. Mn2+, Cu2+, and Zn2+ were found to be competitive inhibitors of the holoenzyme with respect to substrate and Cd2+ and Co2+ were noncompetitive inhibitors. Weak inhibition (Ki > or = 1000 microM) was noted for Ca2+, Fe2+, and Fe3+.     

Ni2+-binding RNA motifs with an asymmetric purine-rich internal loop and a G-A base pair.

RNA molecules with high affinity for immobilized Ni2+ were isolated from an RNA pool with 50 randomized positions by in vitro selection-amplification. The selected RNAs preferentially bind Ni2+ and Co2+ over other cations from first series transition metals. Conserved structure motifs, comprising about 15 nt, were identified that are likely to represent the Ni2+ binding sites. Two conserved motifs contain an asymmetric purine-rich internal loop and probably a mismatch G-A base pair. The structure of one of these motifs was studied with proton NMR spectroscopy and formation of the G-A pair at the junction of helix and internal loop was demonstrated. Using Ni2+ as a paramagnetic probe, a divalent metal ion binding site near this G-A base pair was identified. Ni2+ ions bound to this motif exert a specific stabilization effect. We propose that small asymmetric purine-rich loops that contain a G-A interaction may represent a divalent metal ion binding site in RNA.     

Energy-transfer studies of the distance between the high-affinity metal binding site and the colchicine and 8-anilino-1-naphthalenesulfonic acid binding sites on calf brain tubulin

The high-affinity metal divalent cation Mg2+, associated with the exchangeable guanosine 5'-triphosphate (GTP) binding site (E site) on purified tubulin, has been replaced by the transition metal ion Co2+ on tubulin as well as on the tubulin-colchicine, tubulin-allocolchicine and tubulin-8-anilino-1-naphthalenesulfonic acid (tubulin-ANS) complexes. While pure native tubulin readily incorporated 0.8 atom of Co2+ per tubulin alpha-beta dimer, incorporation was reduced to 0.4 atom of Co2+ per mole of tubulin when it was complexed with colchicine, indicating that the conformational change induced in tubulin by the binding of colchicine leads to a reduced accessibility of the divalent cation binding site linked to the E site without necessarily changing the intrinsic binding constant. The fluorescence emission spectra of tubulin-bound colchicine, allocolchicine, and ANS displayed a strong overlap with the Co2+ absorption spectrum, identifying these as adequate donor-acceptor pairs. Fluorescence energy-transfer measurements were carried out between tubulin-bound colchicine (or allocolchicine) and ANS as donors and tubulin-complexed Co2+ as acceptor. It was found that the distance between the ANS and the high-affinity divalent cation binding sites is greater than 28 A, while that between the colchicine and the divalent cation binding sites is greater than 24 A.(ABSTRACT TRUNCATED AT 250 WORDS)