Reactions of bovine serum amine oxidase with NN-diethyldithiocarbamate. Selective removal of one copper ion.

NN-Diethyldithiocarbamate (DDC) was able to bind, at 1.0 mM concentration, only about 50% the Cu(II) ions of bovine plasma amine oxidase. Under reducing conditions, this Cu(II) was removed with inactivation of the enzyme. Up to 90% activity could be recovered by treatment with excess Cu(II). The organic cofactor, sensitive to carbonyl reagents, was reduced in the half-Cu-depleted protein and no longer bound phenylhydrazine. The fully reacted protein, in the presence of 10 mM-DDC, lost 50% Cu(II) upon storage at -20 degrees C, but in this case the residual Cu(II) was in the DDC-bound form and the cofactor was in the oxidized state, as it could still bind phenylhydrazine. In the presence of DDC, the rate of reaction with phenylhydrazine was always low, even at 50% DDC saturation, and all derivatives showed identical modifications of the optical and e.p.r. spectra with respect to the phenylhydrazone of the native protein. It is concluded that the two Cu(II) ions are not equivalent, that removal of a single Cu(II) is sufficient to inhibit the re-oxidation of the organic cofactor, and that both Cu(II) ions are in some way involved in the reaction with phenylhydrazine. After reaction with DDC, the optical and e.p.r. spectra of 63Cu(II)-amine oxidase and of 63Cu(II)-carbonic anhydrase [Morpurgo, Desideri, Rigo, Viglino & Rotilio (1983) Biochim. Biophys. Acta 746, 168-175] are very similar and show distorted equatorial co-ordination to Cu(II) of two sulphur atoms and two magnetically equivalent nitrogen atoms.     

Alternate substrate binding modes to two mutant (D98N and H255N) forms of nitrite reductase from Alcaligenes faecalis S-6: structural model of a transient catalytic intermediate

High-resolution nitrite soaked oxidized and reduced crystal structures of two active site mutants, D98N and H255N, of nitrite reductase (NIR) from Alcaligenes faecalis S-6 were determined to better than 2.0 A resolution. In the oxidized D98N nitrite-soaked structures, nitrite is coordinated to the type II copper via its oxygen atoms in an asymmetric bidentate manner; however, elevated B-factors and weak electron density indicate that both nitrite and Asn98 are less ordered than in the native enzyme. This disorder likely results from the inability of the N delta 2 atom of Asn98 to form a hydrogen bond with the bound protonated nitrite, indicating that the hydrogen bond between Asp98 and nitrite in the native NIR structure is essential in anchoring nitrite in the active site for catalysis. In the oxidized nitrite soaked H255N crystal structure, nitrite does not displace the ligand water and is instead coordinated in an alternative mode via a single oxygen to the type II copper. His255 is clearly essential in defining the nitrite binding site despite the lack of direct interaction with the substrate in the native enzyme. The resulting pentacoordinate copper site in the H255N structure also serves as a model for a proposed transient intermediate in the catalytic mechanism consisting of a hydroxyl and nitric oxide molecule coordinated to the copper. The formation of an unusual dinuclear type I copper site in the reduced nitrite soaked D98N and H255N crystal structures may represent an evolutionary link between the mononuclear type I copper centers and dinuclear Cu(A) sites.     

Formation and spectral characterization of Cu(II)-poly(L-ornithine) complexes.

Cu(II)-Poly-(1-ornithine) complexes in aqueous solution have been studied using potentiometric titration and absorption and circular dichroism spectra. As in the case of Cu(II)-poly(L-arginine) complexes studied previously, two types of compounds have been detected, labeled complexes I and II. Complex I contains two amine nitrogens and two water molecules coordinated to the copper. Complex II, two amine and two amide nitrogens. Amide nitrogen coordination confers optical activity to the copper d-d transitions. Furthermore, amine and amide nitrogen coordination to the copper are characterized by charge transfer transitions at 250 and 320 nm respectively which were already identified in Cu(II)-poly(L-arginine) systems.     

Models for metal-sulfur coordination in copper proteins.

The oxidation state of copper in several model compounds containing copper coordinated to sulfur, some of which are suggested model compounds for naturally occurring Cu-S chromophores, was determined employing x-ray photoelectron spectrometry. Copper was found to be present in a 3d10 state, which is characteristic for Cu(I). An initial photoreduction is excluded, as Cu(ethylenediamine)2 (SCN)2, in which a Cu-S bond is also present, was found to contain Cu(II) (3d9). As was the case with native parsley plastocyanin, the model compounds reacted effectively with superoxide anion radicals. We suggest that the electrons of the metal-sulfur chromophore in blue copper proteins are delocalized and that an equilibrium: RS--Cu(II) in equilibrium or formed from RS.Cu(I) exists.     

Spectroscopic analysis of the trinuclear cluster in the Fet3 protein from yeast, a multinuclear copper oxidase

The Fet3 protein (Fet3p) is a multinuclear copper oxidase essential for high-affinity iron uptake in yeast. Fet3p contains one type 1, one type 2, and a strongly antiferromagnetically coupled binuclear Cu(II)-Cu(II) type 3 copper. The type 2 and type 3 sites constitute a structurally distinct trinuclear cluster at which dioxygen is reduced to water. In Fet3p, as in ceruloplasmin, Fe(II) is oxidized to Fe(III) at the type 1 copper; this is the ferroxidase reaction that is fundamental to the physiologic function of these two enzymes. Using site-directed mutagenesis, we have generated type 1-depleted (T1D), type 2-depleted (T2D), and T1D/T2D mutants. None were active in the essential ferroxidase reaction catalyzed by Fet3p. However, the spectroscopic signatures of the remaining Cu(II) sites in any one of the three mutants were indistinguishable from those exhibited by the wild type. Although the native protein and the T1D mutant were isolated in the completely oxidized Cu(II) form, the T2D and T1D/T2D mutants were found to be completely reduced. This result is consistent with the essential role of the type 2 copper in dioxygen turnover, and with the suggestions that cuprous ion is the valence state of intracellular copper. Although stable to dioxygen, the Cu(I) sites in both proteins were readily oxidized by hydrogen peroxide. The double mutant was extensively analyzed by X-ray absorption spectroscopy. Edge and near-edge features clearly distinguished the oxidized from the reduced form of the binuclear cluster. EXAFS was strongly consistent with the expected coordination of each type 3 copper by three histidine imidazoles. Also, copper scattering was observed in the oxidized cluster along with scattering from a ligand corresponding to a bridging oxygen. The data derived from the reduced cluster indicated that the bridge was absent in this redox state. In the reduced form of the double mutant, an N/O ligand was apparent that was not seen in the reduced form of the T1D protein. This ligand in T1D/T2D could be either the remaining type 2 copper imidazole ligand (from His416) or a water molecule that could be stabilized at the type 3 cluster by H-bonding to this side chain. If present in the native protein, this H(2)O could provide acid catalysis of dioxygen reduction at the reduced trinuclear center.     

The Methylococcus capsulatus (Bath) Secreted Protein, MopE*, Binds Both Reduced and Oxidized Copper

Under copper limiting growth conditions the methanotrophic bacterium Methylococcus capsulatus (Bath) secrets essentially only one protein, MopE*, to the medium. MopE* is a copper-binding protein whose structure has been determined by X-ray crystallography. The structure of MopE* revealed a unique high affinity copper binding site consisting of two histidine imidazoles and one kynurenine, the latter an oxidation product of Trp130. In this study, we demonstrate that the copper ion coordinated by this strong binding site is in the Cu(I) state when MopE* is isolated from the growth medium of M. capsulatus. The conclusion is based on X-ray Near Edge Absorption spectroscopy (XANES), and Electron Paramagnetic Resonance (EPR) studies. EPR analyses demonstrated that MopE*, in addition to the strong copper-binding site, also binds Cu(II) at two weaker binding sites. Both Cu(II) binding sites have properties typical of non-blue type II Cu (II) centres, and the strongest of the two Cu(II) sites is characterised by a relative high hyperfine coupling of copper (A_|| = 20 mT). Immobilized metal affinity chromatography binding studies suggests that residues in the N-terminal part of MopE* are involved in forming binding site(s) for Cu(II) ions. Our results support the hypothesis that MopE plays an important role in copper uptake, possibly making use of both its high (Cu(I) and low Cu(II) affinity properties.     

Pulsed EPR studies of the type 2 copper binding site in the mercury derivative of laccase.

The nuclear modulation effect in pulsed EPR spectroscopy was used to study the type 2 copper binding site in the mercury derivative of laccase (MDL) in which the type 1 copper is substituted by Hg(II). By comparing the three-pulse electron spin-echo modulations and Fourier transform spectra of MDL and several model compounds, we conclude that the imidazole groups of two histidyl amino acid residues are equatorially coordinated to Cu(II) in the type 2 site. Computer simulations of these data suggest that the remote nonbonding nitrogens of the two imidazoles possess nuclear quadrupole parameters e2qQ = 1.47 MHz and eta = 0.83. A(iso) values of these two nitrogens are not identical, being 1.5 and 2.0 MHz. We have also used samples of the enzyme exchanged with D2O to examine the coordination of the water to the type 2 copper site. The deuterium modulation that is resolved by taking the ratio of the time domain ESEEM data from native and D2O-exchanged enzyme indicates that there is an equatorial water ligand, and further data show that this water is displaced by azide.     

Recognition dynamics of trinuclear copper cluster and associated histidine residues through conserved or semi-conserved water molecules in human Ceruloplasmin: The involvement of aspartic and glutamic acid gates

Human Ceruloplasmin belongs to the family of multi-copper oxidases and it is involved in different physiological processes, copper ion transport, iron metabolism, iron homeostasis, and biogenic amine metabolism. MD-simulation studies have indicated the higher hydrophilic susceptibility of the trinuclear copper cluster in native CP compared to its oxygen bound form. The copper (T2/T3) atom Cu3047 of the cluster, which is close to T1 copper center Cu3052 (~13 Å) has a higher affinity for water molecules compared to other copper centers. The water molecules of W3, W4, W5, W9, and W12 conserved water sites are coordinated to Cu3047, where W3, W9, and W12 centers are found to play some crucial role in the stabilization of native trinuclear copper cluster. The hydrogen bonding interaction of Asp169, Glu112, Asp995, and Glu1032 residues with the copper-bound conserved water molecules (W3, W4, W5, W10, and W11) in native CP is observed to be unique. The conformational flexibility of Asp169 and Glu112 and their association with the copper-bound water molecules, but the absence of such interaction in O₂-bound simulated structure of the enzyme is indicating some plausible rational on the role of these acidic residues in the gating of O₂ molecule in the native trinuclear Cu cluster of CP. The simulation results may shade some new light on the biochemistry/chemistry of CP, specially on the hydration dynamics of the trinuclear copper cluster.     

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.     

Avoiding premature oxidation during the binding of Cu(II) to a dithiolate site in BsSCO. A rapid freeze-quench EPR study

The Bacillus subtilis version of SCO1 (BsSCO) is required for assembly of Cu(A) in cytochrome c oxidase and may function in thiol-disulfide exchange and/or copper delivery. BsSCO binds Cu(II) with ligation by two cysteines, one histidine and one water. However, copper is a catalyst of cysteine oxidation and BsSCO must avoid this reaction to remain functional. Time resolved, rapid freeze-quench (RFQ) electron paramagnetic resonance of apo-BsSCO reacting with Cu(II) reveals an initial Cu(II) species with two equatorially coordinated nitrogen atoms, but no sulfur. We propose that BsSCO evolves from this initial sulfur free coordination of Cu(II) to the final dithiolate species via a change in conformation, and that the initial binding by nitrogen is a means for BsSCO to avoid premature thiol oxidation.     

Crystal structure and nuclease activity of mono(1,10-phenanthroline) copper complex

The hydroxo-bridged dinuclear copper (II)/phen complex [Cu(2)(phen)(2)(OH)(2)(H(2)O)(2)][Cu(2)(phen)(2)(OH)(2)Cl(2)]Cl(2).6H(2)O (phen=1,10-phenanthroline) has been prepared and characterized by single crystal X-ray diffraction. The coordinated area of the complex shows two distorted [CuN(2)O(2)O(w)] and [CuN(2)O(2)Cl] square-pyramidal and one strictly planar configuration CuO(2)Cu involving two O atoms of hydroxo-bridged, Cu(2+) cations, N atoms of two phen ligands and disorder solvate water and chlorine anions. In the presence of H(2)O(2), the complex of mono(1,10-phenanthroline)copper exhibits higher activity as a nuclease than bis(1,10-phenanthroline)copper.     

Binding of Cu(II) to non-prosthetic sites in ceruloplasmin and bovine serum albumin

The binding of Cu(II) to native human, porcine, bovine and ovine ceruloplasmin (Cp) and to bovine serum albumin (bSA) has been studied at pH 7.4, 30 mM barbital buffer. The results were analyzed for the strength and the number of binding sites using Scatchard plots. Evidence for additional copper binding sites in Cp and bSA was obtained suggesting a role for copper ion in the homeostatic regulation of Cu(II) and other metal ions in the serum. In the binding studies the Cp was freed of exogenous Cu(II) by passing it over a Chelex-100 column. Two flow rates were used, 4 ml/hr and 40 ml/hr, which removed Cu(II) of different affinities. Cp passed at the slower flow rate (Cp4) only contained the prosthetic copper atoms. Cp passed at the faster flow rate (Cp40) contained one additional copper atom with a Ka approximately 10(7) M-1. Another 2-6 Cu(II) ion could be added to the Cp40 with an average affinity of about Ka approximately 10(5) M-1. The Cu(II) ions found in Cp provide two distinguishable classes: (1) the prosthetic copper atoms and (2) the exogenous copper atoms that can be removed by Chelex-100. For bSA one copper atom was bound strongly with a Ka value approaching 10(12) - 10(13) M-1 and was not removed by Chelex-100 at any flow rate. A second copper atom was found with a Ka = 5.2 x 10(6) M-1 and was removed by Chelex-100 at 4 ml/hr. Three additional copper atoms were bound with a Ka = 1.6 x 10(5) M-1; they were readily removed by Chelex-100 at 40 ml/hr but were nondialysable.     

Synthesis and structural analysis of the copper(II) complexes of N2-(2-pyridylmethyl)-2-pyridinecarboxamide

Previous investigations of the potential of metal-organic compounds as inhibitors of human immunodeficiency virus type I protease (HIV-1 PR) showed that the copper(II) complex diaqua [bis(2-pyridylcarbonyl)amido] copper(II) nitrate dihydrate and the complex bis[N2-(2,3,6-trimethoxybenzyl)-4-2-pyridinecarboxamide] copper(II) behaved as inhibitors of HIV-1 PR. In a search for similar readily accessible ligands, we synthesised and studied the structural properties of N2-(2-pyridylmethyl)-2-pyridinecarboxamide (L) copper(II) complexes. Three different crystal structures were obtained. Two were found to contain ligand L simultaneously in a tridentate and bidentate conformation [Cu(L(tri)L(bi))]. The other contained two symmetry-related ligands, coordinated through the pyridine nitrogen and the amide oxygen atoms [Cu(L(bi))(2)]. A search of the Cambridge Structural Database indicated that L(tri) resulting from nitrogen bound amide hydrogen metal substitution is favoured over chelation through the amide oxygen atom. In our case, we calculated that the conformation of L(tri) is 11 kcal/mol more favourable than that of L(bi). ESI-MS experiments showed that the Cu(L(bi))(2) structure could not be observed in solution, while Cu(L(tri)L(bi))-related complexes were indeed present. The lack of protease inhibition of the pyridine carboxamide copper(II) complexes was explained by the fact that the Cu(L(bi)L(tri)) complex could not fit into the HIV-1 active site.     

113Cd-NMR investigation of a cadmium-substituted copper, zinc-containing superoxide dismutase from yeast

113Cd nuclear magnetic resonance spectroscopy has been used to investigate the metal binding sites of cadmium-substituted copper, zinc-containing superoxide dismutase from baker's yeast. NMR signals were obtained for 113Cd(II) at the Cu site as well as for 113Cd(II) at the Zn site. The two subunits in the dimeric enzyme were found to have identical coordination properties towards 113Cd(II) at the Zn site when no copper is coordinated at the Cu site, and when Cu(I) or Cd(II) is coordinated, were found to be very small indicating that 113Cd(II) must be bound to the same number and type of ligands in both cases. Furthermore, the spectra show that the rate of exchange of protein-bound 113Cd(II) and free 113Cd2+ is slow on the NMR time scale also at the Cu site. The present study suggests an explanation for the discrepancy in the literature regarding 113Cd-NMR investigations of bovine superoxide dismutase.     

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.     

Acute Copper and Cupric Ion Toxicity in an Estuarine Microbial Community

Copper was acutely toxic to the estuarine microbial community of Middle Marshes, N.C. Under ambient water quality conditions, 10 μg of added total copper [Cu(II)] liter⁻¹ reduced the CFU bacterial abundance by up to 60% and inhibited the amino acid turnover rate (AATR) by as much as 30%. Copper toxicity, however, was a quantitative function of free cupric ion (Cu²⁺) activity that was not directly related to Cu(II) or ligand-bound copper. By using a nitrilotriacetic acid-cupric ion buffer to control pCu (−log Cu²⁺ activity), it was found that an in situ pCu of 10.1 was bactericidal, reducing the CFU by 60%, but inhibited the AATR by only about 10%. A bacterial bioassay that was used to estimate the pCu in Cu(II)-treated Middle Marshes samples indicated that less than 0.5% of added Cu(II) was in the free cupric ion form. CFU was a more sensitive indicator of low-level copper stress than was AATR. When tested at different times, native microbial community responses to acute cupric ion stress were quantitatively quite similar even when there were large differences in bacterial abundances and in situ metabolic rates. Variations were observed in response to Cu(II) treatments at different times, but these were likely due to differences in water quality, which would quantitatively influence the distribution of copper complexes that were present. Asymptotic response curves suggest that some degree of copper resistance exists in this community. At a pCu of 8, more than 2 orders of magnitude above the minimum inhibitory level, the CFU was still 5 to 10% and the AATR was about 3% of the control values.     

Synthesis,crystal structure,and DNA-binding properties of a new copper (II) complex containing mixed-ligands of 2,2′-bipyridine and p-methylbenzoate

A novel copper complex of [Cu(bpy)(pba)₂ · H₂O] · 0.5H₂O (bpy = 2,2′-bipyridine, pba = p-methylbenzoate) was synthesized. The interaction of the complex to native fish sperm DNA was investigated through electrochemistry, electronic absorption spectroscopy and viscosity experiments. In the X-ray crystallography structure, the copper (II) ion is coordinated by two oxygen atoms of two p-methylbenzoate groups, two nitrogen atoms of 2,2′-bipyridine and one water molecule. The observed changes in the physicochemical features of the copper (II) complex on binding to DNA suggested that the complex bind to DNA with intercalation mode via 2,2′-bipyridine ring into DNA base pairs. Electrochemical studies revealed that the complex prefer to bind to DNA in Cu(I) form rather than Cu(II) oxidation state form. Additionally, the nuclease activity of the title complex was assessed by gel electrophoresis assay and the results shown that the copper complex can cleave pBR322 DNA effectively in the presence of ascorbic acid.     

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.     

Preparation and characterisation of copper(II) hyaluronate

Amorphous copper complexes of the general composition Cu(C14H20O11N)2 x xH2O have been prepared with high- and low-molecular-weight hyaluronic acid (HA). Optimal conditions for preparation are obtained at pH values from 5.0 to 5.5, with a molar ratio of HA versus Cu2+ of 1:1, and at a mass concentration of 5 and 10 mg/mL for high- (Mw = 1.8 x 10(6) Da) and low-molecular-weight sodium hyaluronate (Mw = 2 x 10(5) Da), respectively. The coordination polyhedron of the copper ion has been elucidated by EXAFS and XANES spectroscopy. Copper atoms are octahedrally coordinated in both cases with four equatorial Cu-O bond lengths of 1.95 A, and two axial Cu-O bonds of 2.46 A. Visible spectra of acidic aqueous solution suggest that substitution of axial oxygens by NH groups occurs at pH 6.5 or higher. If the pH value of the copper(II) hyaluronate solution increases above 6.5, the coordination of copper(II) changes. It is very likely that the N atom coming from the acetamido group enters into the coordination sphere of the copper(II) ion.     

Crystallographic structures of bovine copper-zinc superoxide dismutase reveal asymmetry in two subunits: functionally important three and five coordinate copper sites captured in the same crystal

A key feature of the generally accepted catalytic mechanism of CuZn superoxide dismutase (CuZnSOD) is the breakage of the imidazolate bridge between copper and zinc and the loss of a coordinated water molecule from copper on reduction from Cu(II) to Cu(I). Crystal structures exist for the enzyme from a number of sources in the oxidised, five coordinate copper form. For the reduced form two structures from different sources have been determined only recently but provide contradictory results. We present crystal structures of bovine CuZnSOD (BSOD) in two different space groups. The structure of the P212121 form (pBSOD), at 1.65 A resolution clearly shows one subunit with Cu in the five coordinate, oxidised form, and the other with Cu in the three coordinate form expected for the reduced state. This mixed state of pBSOD is confirmed by XANES data of these crystals. The pBSOD structure has thus captured each subunit in one of the two oxidation state conformations and thus provides direct crystallographic evidence for the superoxide dismutase mechanism involving the breakage of the imidazole bridge between Cu and Zn. A shift in the position of copper in subunit A poises the catalytic centre to undergo the first stage of catalysis via dissociation of Cu from His61 with a concomittant movement of the coordinated water molecule towards His61, which rotates by approximately 20 degrees, enabling it to form a hydrogen bond to the water molecule. The Cu-Zn separation in the reduced site is increased by approximately 0.5 A. In contrast the 2.3 A resolution structure in space group C2221 (cBSOD) shows both of the Cu atoms to be in the five coordinate, oxidised form but in this space group the whole of subunit A is significantly more disordered than subunit B. An examination of published structures of "oxidised" SODs, shows a trend towards longer Cu-Zn and Cu-His61 separations in subunit A, which together with the structures reported here indicate a potential functional asymmetry between the subunits of CuZnSODs. We also suggest that the increased separation between Cu and Zn is a precursor to breakage of His61.