Antioxidant activity related to copper binding of native prion protein

We have developed a method to affinity-purify mouse prion protein (PrP(c)) from mouse brain and cultured cells. PrP(c) from mouse brain bound three copper atoms; PrP(c) from cultured cells bound between one and four copper atoms depending on the availability of copper in the culture medium. Purified PrP(c) exhibited antioxidant activity, as determined by spectrophotometric assay. Incubation of PrP(c) with the neurotoxic peptide, PrP106-126, inactivated the superoxide dismutase-like activity. Culture experiments showed that PrP(c) protects cells against oxidative stress relative to the amount of copper it binds. These results suggest that PrP(c) is a copper-binding protein which can incorporate varying amounts of copper and exhibit protective antioxidant activity.     

X-ray absorption and NMR spectroscopic studies of CopZ,a copper chaperone in Bacillus subtilis: the coordination properties of the copper ion

XAS studies have been performed, under various experimental conditions, on a copper(I)-transporting protein, CopZ, of Bacillus subtilis. The copper(I) ion, reduced with dithiothreitol, is three-coordinate with three sulfur donor atoms, two of which presumably provided by the protein and one by dithiothreitol. If a molar excess of acetate (15 mM; 5:1 respect to CopZ) or citrate (6 mM; 2:1 respect to CopZ) is present in solution, the EXAFS spectra suggest the presence of a dimeric form involving a close contact between Cu(I) ions from two molecules, where Cu is still three-coordinate. (1)H and (15)N NMR data provide further structural details. If copper reduction is accomplished with ascorbate, the data indicate that one oxygen of ascorbate enters in the first-coordination sphere of copper, together with two sulfur atoms, in a dimeric form of the protein. These results are instructive and have been discussed with respect to the molecular basis of copper trafficking.     

Purification and properties of bovine caeruloplasmin.

A novel method is reported for isolation of bovine caeruloplasmin from plasma; it involves a rapid and mild procedure, namely two column chromatographies with stepwise elution and one (NH4)2SO4 precipitation, and results in a proteolytically undegraded homogeneous protein. The general structure of the protein, as evaluated by molecular-weight determination and amino acid composition, is very similar to that established for human and rat caeruloplasmin. Copper determination and e.p.r. spectral analysis on the native and NO-treated protein gave a metal-to-protein stoichiometry of six atoms of copper per molecule. Three copper atoms were detectable by e.p.r., with Type 2/Type 1 ratio = 1 : 3 in most samples. The protein is very sensitive to storage and/or handling. A component was isolated from aged samples, which was found to contain approximately four copper atoms per 125000 daltons, two of which were detectable by e.p.r. with the characters of Type 2 copper. However, the same component was found to be present, although to a lesser extent, in the fresh preparation and does not seem to be related to proteolytic degradation. This component has no oxidase activity. On the basis of these results it is suggested that caeruloplasmin molecules are intrinsically heterogeneous with respect to both copper content and copper type, and this can explain the intriguing stoichiometry regarding the different types of copper centres.     

A labile regulatory copper ion lies near the T1 copper site in the multicopper oxidase CueO

CueO, a multicopper oxidase, is part of the copper-regulatory cue operon in Escherichia coli, is expressed under conditions of copper stress and shows enhanced oxidase activity when additional copper is present. The 1.7-A resolution structure of a crystal soaked in CuCl2 reveals a Cu(II) ion bound to the protein 7.5 A from the T1 copper site in a region rich in methionine residues. The trigonal bipyramidal coordination sphere is unusual, containing two methionine sulfur atoms, two aspartate carboxylate oxygen atoms, and a water molecule. Asp-439 both ligates the labile copper and hydrogen-bonds to His-443, which ligates the T1 copper. This arrangement may mediate electron transfer from substrates to the T1 copper. Mutation of residues bound to the labile copper results in loss of oxidase activity and of copper tolerance, confirming a regulatory role for this site. The methionine-rich portion of the protein, which is similar to that of other proteins involved in copper homeostasis, does not display additional copper binding. The type 3 copper atoms of the trinuclear cluster in the structure are bridged by a chloride ion that completes a square planar coordination sphere for the T2 copper atom but does not affect oxidase activity.     

Nitrite and nitric oxide treatment of Helix pomatia hemocyanin: single and double oxidation of the active site.

The reaction of nitrite and nitric oxide with Helix pomatia hemocyanin has been studied. One or both of the two copper ions in the active site can be oxidized, depending upon reaction conditions. The single oxidation of the oxygen binding site can be reversed by reduction with hydroxylamine, and the oxygen binding properties of the protein are simultaneously restored. The experiments, including electron paramagnetic resonance, indicate that nitric oxide is not a ligand of copper in the singly oxidized active site and that the oxidized copper ions is coupled to at least two nitrogen atoms of amino acid residues. The doubly oxidized protein can be reduced to a singly oxidized one with ascorbic acid or hydroxylamine; the latter reagent is again able to reduce the singly oxidized state and to restore the oxygen binding properties.     

Effect of pH, phosphate and copper on the interaction of glucose with albumin

Protein glycation is believed to play an important role in the development of long-term disorders associated with diabetes. Previous studies have shown that copper could activate this process; however, these experiments were performed under non-physiological conditions. In this study, in vitro experiments were carried out at near-physiological conditions to examine the catalytic activity of copper on the interaction of albumin with glucose. Changes in pH and phosphate buffering capacity were shown to affect albumin glycation. Under stable pH conditions, copper activates albumin glycation only at low protein concentrations (<30 gl–1). Copper had no effect on albumin glycation at higher protein concentrations probably because the metal is chelated by the protein.     

Isolation of a high specific activity pink, monomeric nitrous oxide reductase from Achromobacter cycloclastes

Nitrous oxide reductase from Achromobacter cycloclastes has been purified to homogeneity under aerobic conditions via DEAE-cellulose, phenyl-Sepharose, hydroxyapatite, and Sephacryl S-200 chromatography. It consists of a single polypeptide of MW 72 kDa, and contains 3.8 +/- 0.1 copper atoms per molecule. The enzyme is pink as isolated, yet exhibits a specific activity (86 U/mg) that is ca. 40 times greater than that observed for other N2O reductases under similar conditions. Double integration of the anomalous EPR spectrum at 77K showed the presence of 2.0 +/- 0.1 spins per molecule, implying the presence of EPR-silent copper atoms and/or spin-coupled mixed-valent centers.     

Pulse-radiolysis studies on the interaction of one-electron reduced species with blue oxidases. Reduction of type-2-copper-depleted ascorbate oxidase.

The interaction of one-electron reduced metronidazole (ArNO2.-) with native and Type-2-copper-depleted ascorbate oxidase were studied in buffered aqueous solution at pH 6.0 and 7.4 by using the technique of pulse radiolysis. With ArNO2.-, reduction of Type 1 copper of the native enzyme and of the Type-2-copper-depleted ascorbate oxidase occurs via a bimolecular step and at the same rate. Whereas the native protein accepts, in the absence of O2, 6-7 reducing equivalents, Type-2-copper-depleted ascorbate oxidase accepts only 3 reducing equivalents with stoichiometric reduction of Type 1 copper. On reaction of O2.- with ascorbate oxidase under conditions of [O2.-] much greater than [ascorbate oxidase], removal of Type 2 copper results in reduction of all the Type 1 copper atoms, in contrast with reduction of the equivalent of only one Type 1 copper atom in the holoprotein. From observations at 610 nm, the rate of reduction of ascorbate oxidase by O2.- is not dependent on the presence of Type 2 copper. For the holoprotein, no significant optical-absorption changes were observed at 330 nm. It is proposed that electrons enter the protein via Type 1 copper in a rate-determining step followed by a fast intramolecular transfer of electrons within the protein. For the Type-2-copper-depleted protein, intramolecular transfer within the protein, however, is slow or does not occur. In the presence of O2, it is also suggested that re-oxidation of the partially reduced holoprotein occurs at steady state, as inferred from the observations at 330 nm and 610 nm. The role of Type 2 copper in ascorbate oxidase is discussed in terms of its involvement in redistribution of electrons within the protein or structural considerations.     

Structure-activity relationship on fungal laccase from Rigidoporus lignosus: a Fourier-transform infrared spectroscopic study

The structure and thermal stability of a laccase from Rigidoporus lignosus (Rl) was analysed by Fourier-transform infrared (FT-IR) spectroscopy. The enzyme was depleted of copper atoms, then part of the apoenzyme was re-metalled and these two forms of the protein were analysed as well. The enzymatic activity, lost by the removal of copper atoms, was restored in the re-metalled apoenzyme and resulted similar to that of native protein. The infrared data indicated that the enzyme contains a large amount of beta-sheets and a small content of alpha-helices, and it displayed a marked thermostability showing the T(m) at 92.5 degrees C. The apoenzyme and the re-metalled apoenzyme did not show remarkable differences in the secondary structure with respect to the native protein, but the thermal stability of the apoenzyme was dramatically reduced showing a T(m) close to 72 degrees C, while the re-metalled protein displayed the T(m) at 90 degrees C. These data indicate that copper atoms, beside their role in catalytic activity, play also an important role on the stabilisation of the structure of Rl laccase. About 35% of the polypeptide chain is buried and/or constitutes a particular compact structure, which, beside copper atoms, is probably involved in the high thermal stability of the protein. Another small part of the structure is particularly sensitive to high temperatures and it could be the cause of the loss of enzymatic activity when the temperature is raised above 45-50 degrees C.     

Characterization of copper atoms in bilirubin oxidase by spectroscopic analyses

Bilirubin oxidase [EC 1.3.3.5], purified from the culture medium of Myrothecium verrucaria, was found to contain two blue copper atoms per protein molecule with a molecular weight of ca. 52 kDa. The two copper atoms were estimated to be in the all cupric state by the cuproine colorimetric method and also atomic absorption analysis. We could remove the reduce cuprous ions from the holo enzyme by adding ascorbate, followed by a KCN solution, yielding an apo-enzyme with no activity. The apo-enzyme can be reconstituted with Cu or other divalent cations such as Co, Fe, and Cd, with accompanying recovery of the enzyme activity. The activity recovery depended upon the species of cation employed; Cu being most effective, an almost 100% recovery, and Cd the least, only a 25% recovery. We could obtain information on the copper ions and their coordination structure by spectroscopic analyses of the apo- and reconstituted enzymes, obtaining such as absorption, CD, MCD, and XPS spectra. The bilirubin oxidase catalyzed-reaction was a second order reaction with respect to copper bound with protein. The donor set was of the CuSS*N2 (S = Cys, S* = Met, N = His) type, i.e., the same as in the case of blue copper proteins. On studying the Co-substituted enzyme, it was revealed that the copper site of the enzyme had a 4-coordinated structure.     

Metal cofactors of lysine-2,3-aminomutase.

Lysine-2,3-aminomutase from Clostridium SB4 contains iron and sulfide in equimolar amounts, as well as cobalt, zinc, and copper. The iron and sulfide apparently constitute an Fe-S cluster that is required as a cofactor of the enzyme. Although no B12 derivative can be detected, enzyme-bound cobalt is a cofactor; however, the zinc and copper bound to the enzyme do not appear to play a role in its catalytic activity. These conclusions are supported by the following facts reported in this paper. Purification of the enzyme under anaerobic conditions increases the iron and sulfide content. Lysine-2,3-aminomutase purified from cells grown in media supplemented with added CoCl2 contains higher levels of cobalt and correspondingly lower levels of zinc and copper relative to enzyme from cells grown in media not supplemented with cobalt. The specific activity of the purified enzyme increases with increasing iron and sulfide content, and it also increases with increasing cobalt and with decreasing zinc and copper content. The zinc and copper appear to occupy cobalt sites under conditions of insufficient cobalt in the growth medium, and they do not support the activity of the enzyme. The best preparations of lysine-2,3-aminomutase obtained to date exhibit a specific activity of approximately 23 units/mg of protein and contain about 12 g atoms of iron and of sulfide per mol of hexameric enzyme. These preparations also contain 3.5 g atoms of cobalt per mol, but even the best preparations contain small amounts of zinc and copper. The sum of cobalt, zinc, and copper in all preparations analyzed to date corresponds to 5.22 +/- 0.75 g atoms per mol of enzyme. An EPR spectrum of the enzyme as isolated reveals a signal corresponding to high spin Co(II) at temperatures below 20 K. The signal appears as a partially resolved 59Co octet centered at an apparent g value of 7. The 59Co hyperfine splitting (approximately 35 G) is prominent at 4.2 K. These findings show that lysine-2,3-aminomutase requires Fe-S clusters and cobalt as cofactors, in addition to the known requirement for pyridoxal 5'-phosphate and S-adenosylmethionine.     

Coordinate expression of coproporphyrinogen oxidase and cytochrome c6 in the green alga Chlamydomonas reinhardtii in response to changes in copper availability.

To maintain photosynthetic competence under copper-deficient conditions, the green alga Chlamydomonas reinhardtii substitutes a heme protein (cytochrome c6) for an otherwise essential copper protein, viz. plastocyanin. Here, we report that the gene encoding coproporphyrinogen oxidase, an enzyme in the heme biosynthetic pathway, is coordinately expressed with cytochrome c6 in response to changes in copper availability. We have purified coproporphyrinogen oxidase from copper-deficient C.reinhardtii cells, and have cloned a cDNA fragment which encodes it. Northern hybridization analysis confirmed that the protein is nuclear-encoded and that, like cytochrome c6, its expression is regulated by copper at the level of mRNA accumulation. The copper-responsive expression of coproporphyrinogen oxidase parallels cytochrome c6 expression exactly. Specifically, the copper-sensing range and metal selectivity of the regulatory components, as well as the time course of the responses, are identical. Hence, we propose that the expression of these two proteins is controlled by the same metalloregulatory mechanism. Our findings represent a novel metalloregulatory response in which the synthesis of one redox cofactor (heme) is controlled by the availability of another (Cu).     

Analysis of the non-covalent interaction between metal ions and the cysteine-rich domain of protein kinase C eta by electrospray ionization mass spectrometry

Effect of zinc and other metal ions on the folding of the protein kinase C (PKC) surrogate peptide (PKCeta-C1B) was analyzed intact under neutral conditions by electrospray ionization mass spectrometry (ESI-MS). ESI-MS spectrum of 64ZnCl(2)-folded PKCeta-C1B clearly showed that PKCeta-C1B coordinates specifically two atoms of zinc, and that the two thiol protons are lost in each zinc ion coordinate center. 113CdCl(2)-folded PKCeta-C1B also showed stoichiometry of two cadmium atoms that was proved by addition of EDTA. The dissociation constants of zinc- and cadmium-folded PKCeta-C1B in the phorbol 12,13-dibutyrate binding (PDBu) were similar (0.66 and 0.81 nM) with different B(max) values (46.4 and 71.4%). The difference would reflect higher coordination potency of cadmium ion that was demonstrated by ESI-MS when PKCeta-C1B was folded by 1:1 mixture of zinc and cadmium ions. In contrast, 63CuCl(2)-treated PKCeta-C1B did not show any copper-coordinated peak, instead a molecular mass less than 6 mass units smaller than that of apo-PKCeta-C1B was observed. The multiple charge mass envelope of copper-treated PKCeta-C1B shifted to that of the lower mass charge state like zinc-treated PKCeta-C1B. These data suggest that the copper treatment formed three intramolecular S-S bonds to abolish the PDBu binding of PKCeta-C1B.     

X-ray absorption investigation of a unique protein domain able to bind both copper(I) and copper(II) at adjacent sites of the N-terminus of Haemophilus ducreyi Cu,Zn superoxide dismutase

The N-terminal metal binding extension of the Cu,Zn superoxide dismutase from Haemophilus ducreyi is constituted by a histidine-rich region followed by a methione-rich sequence which shows high similarity with protein motifs involved in the binding of Cu(I). X-ray absorption spectroscopy experiments selectively carried out with peptides corresponding to the two metal binding regions indicate that both sequences can bind either Cu(II) or Cu(I). However, competition experiments demonstrate that Cu(II) is preferred by histidine residues belonging to the first half of the motif, while the methionine-rich region preferentially binds Cu(I) via the interaction with three methionine sulfur atoms. Moreover, we have observed that the rate of copper transfer from the peptides to the active site of a copper-free form of the Cu,Zn superoxide dismutase mutant lacking the N-terminal extension depends on the copper oxidation state and on the residues involved in metal binding, histidine residues being critically important for the efficient transfer. Differences in the enzyme reactivation rates in the presence of mixtures of the two peptides when compared to those obtained with the single peptides suggest that the two halves of the N-terminal domain functionally interact during the process of copper transfer, possibly through subtle modifications of the copper coordination environment.     

Enzyme-bound copper of dopamine β-monooxygenase.: Activation of the holoenzyme by added copper and uncoupling of electron transfer from hydroxylation by copper salicylate

Preparations of dopamine β-monooxygenase containing a full complement of copper (4.2 copper atoms per tetramer) show increased ascorbate-supported catalytic activities after addition of an excess of copper ions. The significance ot this observation on the question of the number of copper atoms per active site is discussed.Low molecular weight copper complexes such as copper salicylate cause uncoupling of electron transport from hydroxylation. This uncoupling is probably the reason for the well-known inhibition of this enzyme observed at high copper concentration.The onset of inhibition by the copper chelator bathocuproine disulfonate occurs on a faster time scale than the removal of enzyme-bound copper. Nevertheless, the copper removal is sufficiently rapid to require that it be considered in interpretation of inhibition experiments with chelators.     

Stellacyanin. Studies of the metal-binding site using x-ray absorption spectroscopy.

Stellacyanin is a mucoprotein of molecular weight approximately 20,000 containing one copper atom in a blue or type I site. The metal ion can exist in both the Cu(II) and Cu(I) redox states. The metal binding site in plastocyanin, another blue copper protein, contains one cysteinyl, one methionyl, and two imidazoyl residues (Colman et al. 1978. Nature [Lond.]. 272:319-324.), but an exactly analogous site cannot exist in stellacyanin as it lacks methionine. The copper coordination in stellacyanin has been studied by x-ray edge absorption and extended x-ray absorption fine structure (EXAFS) analysis. A new, very conservative data analysis procedure has been introduced, which suggests that the there are two nitrogen atoms in the first coordination shell of the oxidized [Cu(II)] protein and one in the reduced [Cu(I)] protein; these N atoms have normal Cu--N distances: 1.95-2.05 A. In both redox states there are either one or two sulfur atoms coordinating the copper, the exact number being indeterminable from the present data. In the oxidized state the Cu--S distance is intermediate between the short bond found in plastocyanin and those found in near tetragonal copper model compounds. Above -140 degree C, radiation damage of the protein occurs. At room temperature the oxidized proteins is modified in the x-ray beam at a rate of 0.25%/s.     

Characterization of the recombinant copper chaperone (CCS) from the plant Glycine (G.) max

The goal of the present work was to characterize the recombinant copper chaperone (CCS) from soybean. Very little is known about plant copper chaperones, which makes this study of current interest, and allows for a comparison with the better known homologues from yeast and humans. To obtain sizeable amounts of pure protein suitable for spectroscopic characterization, we cloned and overexpressed the G. max CCS chaperone in E. coli in the presence of 0.5 mM CuSO(4) and 0.5 mM ZnSO(4) in the broth. A pure protein preparation was obtained by using two IMAC steps and pH gradient chromatography. Most of the proteins were obtained as apo-form, devoid of copper atoms. The chaperone showed a high content (i.e., over 40%) of loops, turns and random coil as determined both by circular dichroism and homology modelling. The homology 3-D structural model suggests the protein might fold in three structural protein domains. The 3-D model along with the primary structure and spectroscopic data may suggest that copper atoms occupy the two metal binding sites, MKCEGC and CTC, within the N-terminal domain I and C-terminal domain III, respectively. But only one Zn-binding site was obtained spectroscopically.     

Neutrophil-activating protein (HP-NAP) versus ferritin (Pfr): comparison of synthesis in Helicobacter pylori

We recently reported that the neutrophil-activating protein (HP-NAP) of Helicobacter pylori is capable of binding iron in vitro. To more fully understand the relationship between iron and HP-NAP the synthesis of HP-NAP was compared to that of Pfr, another iron-binding protein of H. pylori. Synthesis of HP-NAP and Pfr in growing cultures of H. pylori was analysed under iron depletion and iron, copper, nickel and zinc overload. The synthesis of HP-NAP and Pfr in H. pylori was also analysed under conditions of varying pH and oxidative stress. In addition, recombinant HP-NAP and Pfr were produced in Escherichia coli to assess the contribution of the two proteins to increased survival of E. coli under heavy metal overload. Our data reveal that both HP-NAP and Pfr accumulate in the stationary phase of growth. HP-NAP synthesis is not regulated by iron depletion or overload or by the presence of copper, nickel or zinc in liquid medium and it does not confer resistance to these metals when produced in E. coli. Except for an increase in the synthesis of Pfr at pH 5.7 neither the pH or oxidative stress conditions investigated had an affect on the synthesis of either protein. An increase in Pfr synthesis was observed under iron overload and a decrease was observed under conditions of copper, nickel and zinc overload confirming previous reports. Recombinant Pfr, as well as conferring resistance to iron and copper as previously reported, also conferred resistance to zinc overload when produced in E. coli.