The enzyme-bound copper of dopamine beta-monooxygenase. Reaction with copper chelators, preparation of the apoprotein, and kinetics of the reconstitution by added copper.

The enzyme-bound copper of dopamine beta-monooxygenase reacted rapidly with the chelator bathocuproine disulfonate; the reaction in the presence of ascorbate was completed in 2 min at 25 degrees C with 1mM chelator. This reaction and also the reaction with EDTA could be used to prepare the apoenzyme, which in both cases was completely reactivated in less than 10 s. The reactivation data gave apparent Michaelis constants for copper 0.03 -- 0.2 micron. Trace amounts of copper in buffers and assay mixtures gave significant reactivation without added copper, unless they had been treated with a chelating resin. Titrations using the different chelation rates of free and enzyme-bound copper indicated that four copper atoms are bound per enzyme molecule of four subunits. The native enzyme was more stable against thermal inactivation than the apoenzyme, but this stability was only partially restored by addition of copper to the apoenzyme.     

The copper-enzyme dopamine beta-monooxygenase: studies on the ability of several metals to inhibit the enzyme activity and to replace the copper

The ability of several metals to inhibit dopamine beta-monooxygenase was measured and compared with their ability to compete with the binding of 64Cu to the water-soluble form of the bovine adrenal enzyme at pH 6.0. In the presence of an optimal concentration of copper (0.5 microM in the present assay system), an inhibition was observed upon addition of Hg(II), Zn(II), or Ni(II). Only a small fraction of the inhibition with these metals may be due to uncoupling of electron transport from hydroxylation. Preincubation of these metals with the Cu-depleted apoenzyme before addition of copper, revealed a stronger inhibition than if copper was added before the other metals. Hg(II), Zn(II), and Ni(II) also compete with the binding of 64Cu(II) to the protein. Hg(II) was the most effective and Ni(II) the least effective of these metals, both with respect to inhibition of the enzyme activity and to prevent the binding of 64Cu(II). Competition experiments on the binding of Zn(II) and 64Cu in the presence and absence of ascorbate, indicated i) a similar affinity of Cu(I) and Cu(II) to the native enzyme, and ii) a more rapid binding of Cu(I) than Cu(II) to the Cu-depleted and Zn-containing enzyme. Al(III), Fe(II), Mg(II), Mn(II), Co(II), Cd(II), and Pb(II) neither inhibited the enzyme activity nor competed with the binding of 64Cu(II) to the protein (Fe(II) was not tested for binding). Of those metals cited above only Cu(II)/Cu(I) was able to reactivate the apoenzyme.     

Studies on the binding of copper to dopamine beta-monooxygenase and other proteins using the Cu2+ ion-selective electrode

The binding of Cu2+ to native and copper-free dopamine beta-monooxygenase has been investigated by potentiometric titrations using a Cu2+-selective electrode. Stoichiometric formation constants have been determined from regression analysis of the resulting titration curves. The results establish a stoichiometry of four high-affinity binding sites for Cu/+ (log Kf approximately 11) per enzyme tetramer, and more binding sites of lower affinity (log Kf approximately 5-7). The data for binding of the first four Cu2+ to the enzyme tetramer indicate interactions in the binding to the sites. Bovine serum albumin, metal-free carbonic anhydrase, and ovotransferrin have also been titrated with Cu2+, and the formation constants of both high-affinity binding sites and other sites have been determined. The stoichiometry of one high-affinity binding site of Cu2+ for carbonic anhydrase (log Kf approximately 10-12) and two sites for ovotransferrin (log Kf approximately 11) agree with the reported metal binding properties of these proteins. The number of high-affinity binding sites for bovine serum albumin was pH dependent.     

Dopamine beta-monooxygenase. Binding to apoenzyme and rapid exchange in holoenzyme of 64Cu studied with high-performance size-exclusion gel chromatography

The binding of 64Cu to the water-soluble form of dopamine beta-monooxygenase from bovine adrenal medulla was studied in reconstitution and exchange experiments using high-performance size-exclusion gel chromatography. The reconstitution experiments provide evidence for a specific binding of four copper atoms/enzyme tetramer using either Cu(I) or Cu(II), but some weaker copper-binding sites were observed in the presence of a large excess of copper. The exchanges of both Cu(I) and Cu(II) in this protein are so rapid that exact half-lives for the exchange reactions can not be obtained by the present method. The results indicate, however, that the half-life for the exchange of the enzyme-bound copper in the holoenzyme with a twofold excess of 64Cu(II) at pH 6.1 was about 1 min, whereas the exchange of Cu(I) measured at similar conditions with ascorbate present, was complete in 1 min. This is by far the most rapid exchange reported for any copper-protein, and the results points to a unique copper-binding site in this enzyme.     

Inactivation of dopamine β-monooxygenase by hydrogen peroxide and by ascorbate

The inactivation of the water-soluble form of bovine adrenal dopamine β-monooxygenase by H₂O₂ and by ascorbate was studied. Inactivation by H₂O₂ was slow for the copper-free apoenzyme, but addition of copper gave a rapid inactivation. The results presented indicate that the enzyme-bound copper during this inactivation catalyzes partial destruction of its own binding site. The reaction orders for the inactivation by H₂O₂ seem to be 1.0 with respect to the enzyme and in the range 0.6 to 0.8 with respect to H₂O₂. The rate of inactivation obtained in the presence of ascorbate increases with addition of copper and is faster than that obtained by similar concentrations of H₂O₂. The data could not, however, be used to decide whether the inactivation by ascorbate was catalyzed by the enzymebound copper. The inactivation reaction in the presence of ascorbate seems to be of first order with respect to ascorbate at ascorbate concentrations less than 40 μm and decreases toward zero as the ascorbate concentration is increased. Experiments with the Cu(I)-chelator, bathocuproine disulfonate, revealed that inactivation led to weaker binding of copper to the protein, and this effect was more pronounced with H₂O₂ than with ascorbate.     

On the copper transfer between dopamine beta-monooxygenase and Cu-thionein

Metallothionein saturated with copper is able to donate copper to apodopamine beta-monooxygenase. The complete recovery of dopamine beta-monooxygenase activity is observed at the molar ratio Cu-thionein/apoenzyme of 25. On the other hand, apothionein accepts copper easily from the holoenzyme.     

Stopped-flow fluorescence studies of inhibitor binding to tyrosinase from Streptomyces antibioticus

Tyrosinase (Ty) is a type 3 copper protein involved in the rate-limiting step of melanin synthesis. It is shown that the endogenous Trp fluorescence of tyrosinase from Streptomyces antibioticus is remarkably sensitive to the redox state. The fluorescence emission intensity of the [(Cu(I) Cu(I)] reduced species is more than twice that of the oxygen-bound [Cu(II)-O(2)(2-)-Cu(II)] form. The emission intensity of the oxidized [Cu(II)-OH(-)-Cu(II)] protein (Ty(met)) appears to be dependent on an acid-base equilibrium with a pK(a) value of 4.5 +/- 0.1. The binding of fluoride was studied under pseudo first-order conditions using stopped-flow fluorescence spectroscopy. The kinetic parameters k(on), K(d), and the fraction of fluorescence emission quenched upon fluoride binding show a similar pH dependence as above with an average pK(a) value of 4.62 +/- 0.05. Both observations are related to the dissociation of Cu(2)-bridging hydroxide at low pH. It is further shown that Ty is rapidly inactivated at low pH and that halide protects the enzyme from this inactivation. All results support the hypothesis that halide displaces hydroxide as the Cu(2)-bridging ligand in Ty(met). The relevance of the experimental findings for the catalytic cycle is discussed. The data are consistent with the data obtained from other techniques, validating the use of fluorescence quenching as a sensitive and effective tool in studying ligand binding and substrate conversion.     

Re-examination of the reaction of diethyldithiocarbamate with the copper of superoxide dismutase

The reaction of the copper of (Cu,Zn)-superoxide dismutase with diethyldithiocarbamate was studied at pH = 7.4 and the results obtained led to a reaction scheme basically different from the conclusion of a previous study (Misra, H. P. (1979) J. Biol. Chem. 254, 11623-11628). The analysis of optical and ESR spectra at 9 and 35 GHz, at different ligand/protein ratios and reaction times, showed that a ternary diethyldithiocarbamate. Cu(II).protein complex never formed in spectroscopically detectable amounts. The system is described in any condition as the mixture, in variable proportions, of only two components, that is the diethyldithiocarbamate-free (Cu(II) chelate and the copper-depleted protein. The formation of a catalytically active copper-diethyldithiocarbamate intermediate with distinct optical and ESR spectra was also ruled out by kinetic studies, which demonstrated that enzyme inactivation strictly parallels the binding of diethyldithiocarbamate as monitored by optical absorption and ESR. Separation of the copper complex from the protein was obtained for the first time, and the procedure was suitable for rapid preparation of reconstitutable copper-free superoxide dismutase.     

Effect of halide anions on the binding of FAD to D-amino acid oxidase and the tryptophanyl fluorescence of the apoenzyme.

The quenching of tryptophanyl fluorescence of native and denatured D-amino acid oxidase from hog kidney was measured. About 60% of the tryptophanyl fluorescence of the native apoenzyme was quenched by iodide at pH 8.3, and 25 degrees C. All of the tryptophanyl fluorescence of the apoenzyme in 6 M guanidine hydrochloride was quenched. The tryptophanyl fluorescence quenching of the holoenzyme by 1-methyl nicotinamide chloride was low in comparison with that of the apoenzyme. These results of the quenching experiments are discussed based on the intermolecular collision quenching mechanism. By measuring the fluorescence intensities of the tryptophanyl residues and FAD of the holoenzyme solution, and the fluorescence polarization of the holoenzyme solution containing halide anions such as iodide, bromide, chloride, or fluoride, we found that FAD dissociates from the holoenzyme in the presence of iodide, bromide, or chloride, and the ability to dissociate FAD from the holoenzyme decreases in order iodide, bromide, and chloride. However, fluoride seems to enhance the association reaction of FAD with the apoenzyme. These results were consistent with the visible absorption spectra and derivative spectra of free FAD and the holoenzyme in the presence and absence of halide anions.     

Histidine at the active site of Neurospora tyrosinase

The involvement of histidyl residues as potential ligands to the binuclear active-site copper of Neurospora tyrosinase was explored by dye-sensitized photooxidation. The enzymatic activity of the holoenzyme was shown to be unaffected by exposure to light in the presence of methylene blue; however, irradiation of the apoenzyme under the same conditions led to a progressive loss of its ability to be reactivated with Cu2+. This photoinactivation was paralleled by a decrease in the histidine content whereas the number of histidyl residues in the holoenzyme remained constant. Copper measurements of photooxidized, reconstituted apoenzyme demonstrated the loss of binding of one copper atom per mole of enzyme as a consequence of photosensitized oxidation of three out of nine histidine residues. Their sequence positions were determined by a comparison of the relative yields of the histidine containing peptides of photooxidized holo- and apotyrosinases. The data obtained show the preferential modification of histidyl residues 188, 193, and 289 and suggest that they constitute metal ligands to one of the two active-site copper atoms. Substitution of copper by cobalt was found to afford complete protection of the histidyl residues from being modified by dye-sensitized photooxidation.     

Preparation of selectively metal-free and metal-substituted derivatives by reaction of Cu--Zn superoxide dismutase with diethyldithiocarbamate.

Incubation of Cu--Zn superoxide dismutase with diethyldithiocarbamate at increasing ligand/protein ratios and subsequent high-speed centrifugation led to proportional removal of copper from the protein, at variance with previous results [Misra (1979) J. Biol. Chem. 254, 11623--11628]. No zinc was lost, even at very high excesses of chelating agent. In this way a copper-free protein could be readily prepared, with avoidance of the critical pH condition and the dialysis step required in a previous method employing cyanide. The holoprotein was fully reconstituted from the copper-free protein by stoicheiometric re-addition of copper. From the mixture of metal-depleted forms originated by treatment with slight diethyldithiocarbamate excess, the protein containing copper only on one subunit, [Cu1--Zn2], could be isolated by preparative column electrophoresis. This species reproducibly showed 25% more specific activity (catalytic constant per copper) than that of the native or reconstituted [Cu2--Zn2] protein. This may result from long-range conformational effects between the active sites. By adding Co2+ ions to the vacant copper site of [Cu1--Zn2] a hybrid molecule containing Cu(II) on one subunit and Co(II) in the homologous site of the other subunit was prepared. Its activity, referred to copper, was identical with that of the native protein.     

Role of the electrostatic loop of Cu,Zn superoxide dismutase in the copper uptake process.

Cu,Zn superoxide dismutases are characterized by the presence of four highly conserved charged residues (Lys120, Glu/Asp130, Glu131 and Lys134), which are placed at the edge of the active site channel and have been shown to be individually involved in the electrostatic attraction of the substrate toward the catalytically active copper ion. By genetic engineering we mutated these four residues into neutrally charged ones (Leu120, Gln130, Gln131, Thr134). The effects of these mutations on the rate of superoxide dismutation were not dramatic. In fact, at two different pH and ionic strength values, the mutant enzyme had a catalytic constant even higher with respect to the wild-type protein, showing that electrostatic interaction at these surface sites is not essential for high catalytic efficiency of the enzyme. The mutant and the wild-type enzyme showed the same degree of inhibition by CN(-), and both were not affected by I(-), showing that mutations did not alter the sensitivity of the enzyme to anions. On the other hand, reconstitution of active enzyme from either the wild-type or mutant copper-free enzymes with a copper(I)-glutathione [Cu(I)-GSH] complex showed that metal uptake by the mutant was much slower than by the wild-type enzyme. The demonstration that the 'electrostatic loop' is apparently conserved to assure optimal copper uptake by the enzyme, rather than fast dismutation, may provide further support to the idea that Cu,Zn superoxide dismutase is a bifunctional protein, acting in cellular defense against oxidative stress both as a copper buffer and as a superoxide radical scavenger.     

Subunit interactions in yeast glyceraldehyde-3-phosphate dehydrogenase.

The spontaneous inactivation of yeast glyceraldehyde-3-phosphate dehydrogenase was found to fit a simple two-state model at pH 8.5 and 25 degrees. The first step is a relatively rapid dissociation of the tetramer to dimers with the equilibrium largely in favor of the tetramer. In the absence of NAD+ the dimer inactivates irreversibly. The apoenzyme is quite stable with a half-life for complete activity loss proportional to the square root of the enzyme concentration. Perturbances of the protein structure (by pH, ionic strength, and specific salts), which have no effect on the tetrameric state of the molecule, result in an alteration of the cooperativity of NAD+ binding, the reactivity of the active-site sulfhydryl group, and the catalytic activity of the enzyme. Covalent modification of two of the four active-site sulfhydryl groups has profound effects on the enzymic activity which are mediated by changes in the subunit interactions. Sedimentation analysis and hybridization studies indicate that the interaction between subunits remains strong after covalent modification. Under normal physiological and equilibrium dialysis conditions the protein is a tetramer. Equilibrium dialysis studies of NAD+ binding to the enzyme at pH 8.5 and 25 degrees reveal a mixed cooperativity pattern. A model consistent with these observations and the observed half-of-the-sites reactivity is that of ligand induced sequential conformational changes which are transferred across strongly interacting subunit domains. Methods for distinguishing negatively cooperative binding patterns from mixtures of denatured enzyme and multiple species are discussed.     

Reconstitution of Cu,Zn-superoxide dismutase by the Cu(I).glutathione complex

The reconstitution of Cu,Zn-superoxide dismutase from the copper-free protein by the Cu(I).GSH complex was monitored by: (a) EPR and optical spectroscopy upon reoxidation of the enzyme-bound copper; (b) NMR spectroscopy following the broadening of the resonances of the Cu(I).GSH complex after addition of Cu-free,Zn-superoxide dismutase; and (c) NMR spectroscopy of the Cu-free,Co(II) enzyme following the appearance of the isotropically shifted resonances of the Cu(I), Co enzyme, Cu(I).GSH was found to be a very stable complex in the presence of oxygen and a more efficient copper donor to the copper-free enzyme than other low molecular weight Cu(II) complexes. In particular, 100% reconstitution was obtained with stoichiometric copper at any GSH:copper ratio between 2 and 500. Evidence was obtained for the occurrence of a Cu(I).GSH.protein intermediate in the reconstitution process. In view of the inability of copper-thionein to reconstitute Cu,Zn-superoxide dismutase and of the detection of copper.GSH complexes in copper-over-loaded hepatoma cells (Freedman, J.H., Ciriolo, M.R., and Peisach, J. (1989) J. Biol. Chem. 264, 5598-5605), Cu(I).GSH is proposed as a likely candidate for copper donation to Cu-free,Zn-superoxide dismutase in vivo.     

Cofactor processing in galactose oxidase

GO (galactose oxidase; E.C. 1.1.3.9) is a monomeric 68 kDa enzyme that contains a single copper ion and an amino acid-derived cofactor. The enzyme is produced by the filamentous fungus Fusarium graminearum as an extracellular enzyme. The enzyme has been extensively studied by structural, spectroscopic, kinetic and mutational approaches that have provided insight into the catalytic mechanism of this radical enzyme. One of the most intriguing features of the enzyme is the post-translational generation of an organic cofactor from active-site amino acid residues. Biogenesis of this cofactor involves the autocatalytic formation of a thioether bond between Cys-228 and Tyr-272, the latter being one of the copper ligands. Formation of this active-site feature is closely linked to the loss of an N-terminal 17 amino acid prosequence. When copper and oxygen are added to this pro-form of GO (pro GO), purified in copper-free conditions from the heterologous host Aspergillus nidulans, mature GO is formed by an autocatalytic process. Structural comparison of pro GO with mature GO reveals overall structural similarity, but with some regions showing significant local differences in main-chain position. Some side chains of the active-site residues differ significantly from their positions in the mature enzyme. These structural effects of the prosequence suggest that it may act as an intramolecular chaperone to provide an open active-site structure conducive to copper binding and chemistry associated with cofactor formation. The prosequence is not mandatory for processing, as a recombinant form of GO lacking this region and purified under copper-free conditions can also be processed in an autocatalytic copper- and oxygen-dependent manner.     

The incorporation of divalent metal ions into recombinant human tyrosine hydroxylase apoenzymes studied by intrinsic fluorescence and 1H-NMR spectroscopy.

Three isoforms of human tyrosine hydroxylase were expressed in Escherichia coli and purified to homogeneity as the apoenzymes (metal-free). The apoenzymes exhibit typical tryptophan fluorescence emission spectra when excited at 250-300 nm. The emission maximum (342 nm) was not shifted by the addition of metal ions, but reconstitution of the apoenzymes with Fe(II) at pH 7-9 reduced the fluorescence intensity by about 35%, with an end point at 1.0 iron atom/enzyme subunit. The fluorescence intensity of purified bovine adrenal tyrosine hydroxylase, containing 0.78 mol tightly bound iron/mol subunit, was reduced by only 6% on addition of an excess amount of Fe(II). Other divalent metal ions [Zn(II), Co(II), Mn(II), Cu(II) and Ni(II)] also reduced the fluorescence intensity of the human enzyme by 12-30% when added in stoichiometric amounts. The binding of Co(II) at pH 7.2 was also found to affect its 1H-NMR spectrum and this effect was reversed by lowering the pH to 6.1. The quenching of the intrinsic fluorescence of the human isoenzymes by Fe(II) was reversed by the addition of metal chelators. However, the addition of stoichiometric amounts of catecholamines, which are potent feedback inhibitors of tyrosine hydroxylase, to the iron-reconstituted enzyme, prevented the release of iron by the metal chelators. Fluorescence quenching, nuclear magnetic relaxation measurements and EPR spectroscopy all indicate that the reconstitution of an active holoenzyme from the isolated apoenzyme, with stoichiometric amounts of Fe(II) at neutral pH, occurs without a measurable change in the redox state of the metal. However, on addition of dopamine or suprastoichiometric amounts of iron, the enzyme-bound iron is oxidized to a high-spin Fe(III) (S = 5/2) form in an environment of nearly axial symmetry, thus providing an explanation for the inhibitory action of the catecholamines.     

Correlation of copper valency with product formation in single turnovers of dopamine beta-monooxygenase

Chemical- and freeze-quench EPR techniques have allowed single-turnover studies of the copper-containing enzyme dopamine beta-monooxygenase. Reduction of enzyme by a stoichiometric amount of ascorbate followed by rapid mixing with tyramine leads to oxidation of bound copper and formation of hydroxylated product in the expected 2:1 ratio. The tyramine dependence of single turnovers yields a limiting rate of 82 +/- 9 s-1 and Km of 3 +/- 1 mM, in agreement with kinetic modeling based on steady-state parameters. Together these results show that the reduced enzyme is a catalytically competent species, with bound copper acting as the sole reservoir of reducing equivalents. The correlation of copper oxidation and substrate hydroxylation rules out significant antiferromagnetic spin coupling in the enzyme-product complex. Since the enzyme-product complex's Cu2+ EPR signal is absent in the transient approach to the steady state [Brenner, M. C., Murray, C. J., & Klinman, J. P. (1989) Biochemistry (preceding paper in this issue)], this result implies that ascorbate reduces copper in the enzyme-product complex. These findings have important consequences for catalysis and active site structure in dopamine beta-monooxygenase.     

Structural and catalytic properties of copper in lysyl oxidase

The spectral and catalytic properties of the copper cofactor in highly purified bovine aortic lysyl oxidase have been examined. As isolated, various preparations of purified lysyl oxidase are associated with 5-9 loosely bound copper atoms per molecule of enzyme which are removed by dialysis against EDTA. The enzyme also contains 0.99 +/- 0.10 g atom of tightly bound copper per 32-kDa monomer which is not removed by this treatment. The copper-free apoenzyme, prepared by dialysis of lysyl oxidase against alpha,alpha'-dipyridyl in 6 M urea, catalyzed neither the oxidative turnover of amine substrates nor the anaerobic production of aldehyde at levels stoichiometric with enzyme active site content, thus contrasting with the ping pong metalloenzyme. Moreover, the spectrum of the apoenzyme was not measurably perturbed upon anaerobic incubation with n-butylamine, while difference absorption bands were generated at 250 and 308 nm in the spectrum of the metalloenzyme incubated under the same conditions. A difference absorption band also developed at 300-310 nm upon anaerobic incubation of pyrroloquinoline quinone, the putative carbonyl cofactor of lysyl oxidase, with n-butylamine. Full restoration of catalytic activity occurred upon the reconstitution of the apoenzyme with 1 g atom of copper/32-kDa monomer, whereas identical treatment of the apoenzyme with divalent salts of zinc, cobalt, iron, mercury, magnesium, or cadmium failed to restore catalytic activity. The EPR spectrum of copper in lysyl oxidase is typical of the tetragonally distorted, octahedrally coordinated Cu(II) sites observed in other amine oxidases and indicates coordination by at least three nitrogen ligands. The single copper atom in the lysyl oxidase monomer is thus essential at least for the catalytic and possibly for the structural integrity of this protein.     

Purification and some properties of rat liver cysteine oxidase (cysteine dioxygenase).

Cysteine oxidase (cysteine dioxygenase, EC 1.13.11.20) was purified approximately 1000-fold from rat liver. The purified enzyme (protein-B) was obtained as an inactive form, which was activated by anaerobic preincubation with L-cysteine. The active form of protein-B was inactivated during aerobic incubation to produce cysteine sulfinate. This inactivation of protein-B was protected by a distinct protein in rat liver cytoplasm, namely stabilizing protein (protein-A). The Ka and Km values for L-cysteine were 0.8-10(-3) M and 1.3-10(-3) M respectively. The enzyme was strongly inhibited by Cu+ and/or Fe2+ chelating agents but not by Cu2+ chelating agent. The optimum pH of enzyme reaction was 8.5-9.5 while that of enzyme activation was 6.8-9.5, with a broad peak.     

Reaction of N,N-diethyldithiocarbamate and other bidentate ligands with Zn, Co and Cu bovine carbonic anhydrases. Inhibition of the enzyme activity and evidence for stable ternary enzyme-metal-ligand complexes

The reactions with N,N-diethyldithiocarbamate (DDC) of zinc, cobalt and copper carbonic anhydrase from bovine erythrocytes were investigated. The native zinc enzyme was inhibited by DDC, but no removal of zinc could be detected even at a very high [ligand]/[protein] ratio. At identical pH values a larger inhibitory effect was found for the cobalt enzyme. The metal was removed by DDC from the protein at pH less than 7.0. No cobalt removal occurred at pH 10, where a stable ternary complex with the enzyme-bound Co(II) was detected. Its optical and EPR spectra are indicative of five-coordinate Co(II). The reaction of the Cu(II) enzyme with stoichiometric chelating agent was marked by the appearance of an electronic transition at 390 nm (epsilon = 4300 M-1 X cm-1). Metal removal from the copper enzyme readily occurred as the ligand was in excess over the metal, with parallel appearance of a band at 440 nm, which was attributed to the free Cu(II)-DDC complex. Also, in the case of the copper enzyme an alkaline pH was found to stabilize the ternary adduct with the diagnostic 390 nm band. EPR spectra showed that the ternary adduct is a mixture of two species, both characterized by the presence in the EPR spectrum of a superhyperfine structure from two protein nitrogens and by a low g parallel value, indicative of coordination to sulfur ligands. It is suggested that the two species contain the metal as penta- and hexacoordinated, respectively. Measurements of the longitudinal relaxation time, T1, of the water protons suggested that water coordination is retained in the latter case. Hexacoordination with retention of water is also proposed for the Cu(II) derivatives with the bidentate oxalate and bicarbonate anions, unlike the corresponding Co(II) derivatives, which are pentacoordinated. Different coordination of Co(II) and Cu(II) adducts may be relevant to the difference of activity of the two substituted enzymes.