Chicken ceruloplasmin. Evidence in support of a trinuclear cluster involving type 2 and 3 copper centers

Ceruloplasmin was isolated to purity from chicken plasma by a single-step chromatography on amino-ethyl-derivatized Sepharose. Molecular mass, as estimated by nonreducing sodium dodecyl sulfate-electrophoresis, was approximately 140 kDa, slightly higher than that found for ceruloplasmins from other sources. Specific activity as p-phenylenediamine oxidase was five times higher than that reported for mammalian ceruloplasmins. The copper content was estimated to be 5.01 +/- 0.35 atoms per protein molecule, 50% of which was EPR-detectable. The EPR spectrum was completely devoid of any signal typical of the type 2 copper as seen in the other blue multicopper oxidases and in ceruloplasmin from mammalian species. Anaerobic reduction of chicken ceruloplasmin resulted in the disappearance of the 330 nm optical band typical of type 3 copper, which was followed by the appearance of an EPR signal typical of type 2 copper. Subsequently, the type 1 copper and finally the newly formed type 2 copper were reduced. The original optical and EPR spectra were recovered within few minutes upon exposure of reduced ceruloplasmin to air. It is concluded that in oxidized chicken ceruloplasmin type 2 copper interacts with the diamagnetic pair responsible for the 330 nm absorption in such a way as to become EPR-undetectable and that the interaction is relieved by reduction of the pair. Whether this interaction is intrinsically weaker in other blue oxidases and ceruloplasmins studied or is lost with standard preparation procedures remains to be established.     

Purification and partial characterization of camel (Camelus Dromedarius) ceruloplasmin

Adult and young camel ceruloplasmin (Cp) were isolated and purified using the single-step chromatography on amino ethyl-activated sepharose. There are no differences between the adult and the young camel protein. The molecular mass of the protein, as estimated by SDS-PAGE (denaturant conditions), was approximately 130000 Da. The electrophoretic mobility of camel Cp is slightly higher as compared to human and sheep protein suggesting that the camel Cp is homogeneous, compact and more acid. The copper content was estimated to be 5.8+/-0.3 atoms per molecule. The spectroscopic feature includes an absorption maximum at 610 nm, which could be attributed to type 1 copper. The EPR spectrum was completely devoid of any typical signal of the type 2 copper. The kinetic parameters of the adult camel Cp for the specific activity as p-phenylendiamine oxidase were determined as K(m)=0.42 mM and V(max)=0.93 microM NADH/mn/mg Cp. The optimum pH for the activity was 5.7.     

Unusual stability properties of a reptilian ceruloplasmin

Ceruloplasmin from the turtle Caretta caretta was isolated to purity by using the single-step procedure recently developed by us to purify sheep and chicken ceruloplasmin. It has a Mr of ca. 145,000 and a total copper content of 5.1 +/- 0.2 atoms of copper per molecule, 50% of which are detectable by EPR. The spectroscopic features include an absorption maximum at 603 nm in the electronic spectrum and the total absence of any resonance attributable to Type 2 copper in the EPR spectrum. Turtle ceruloplasmin was found to be unusually resistant to aging and proteolysis, when compared to ceruloplasmins isolated from other species. p-Phenyl-endiamine oxidase activity measurements revealed an unusually low catalytic efficiency, while the kinetic parameters of Fe(II) oxidation were consistent with those reported for other species of ceruloplasmin.     

Site-directed mutagenesis of human ceruloplasmin:. production of a proteolytically stable protein and structure-activity relationships of type 1 sites

A fully active recombinant human ceruloplasmin was obtained, and it was mutated to produce a ceruloplasmin stable to proteolysis. The stable ceruloplasmin was further mutated to perturb the environment of copper at the type 1 copper sites in two different domains. The wild type and the mutated ceruloplasmin were produced in the yeast Pichia pastoris and characterized. The mutations R481A, R701A, and K887A were at the proteolytic sites, did not alter the enzymatic activity, and were all necessary to protect ceruloplasmin from degradation. The mutation L329M was at the tricoordinate type 1 site of the domain 2 and was ineffective to induce modifications of the spectroscopic and catalytic properties of ceruloplasmin, supporting the hypothesis that this site is reduced and locked in a rigid frame. In contrast the mutation C1021S at the type 1 site of domain 6 substantially altered the molecular properties of the protein, leaving a small fraction endowed with oxidase activity. This result, while indicating the importance of this site in stabilizing the overall protein structure, suggests that another type 1 site is competent for dioxygen reduction. During the expression of ceruloplasmin, the yeast maintained a high level of Fet3 that was released from membranes of yeast not harboring the ceruloplasmin gene. This indicates that expression of ceruloplasmin induces a state of iron deficiency in yeast because the ferric iron produced in the medium by its ferroxidase activity is not available for the uptake.     

Investigation of the anomalous spectroscopic features of the copper sites in chicken ceruloplasmin: comparison to human ceruloplasmin.

Chicken ceruloplasmin has been previously reported to display a number of key differences relative to human ceruloplasmin: a lower copper content and a lack of a type 2 copper signal by electron paramagnetic resonance (EPR) spectroscopy. We have studied the copper sites of chicken ceruloplasmin in order to probe the origin of these differences, focusing on two forms of the enzyme: "resting" (as isolated by a fast, one-step procedure) and "peroxide-oxidized". From X-ray absorption, EPR, and UV/visible absorption spectroscopies, we have shown that all of the copper sites are oxidized in peroxide-oxidized chicken ceruloplasmin and that none of the type 1 copper sites display the EPR features typical for type 1 copper sites that lack an axial methionine. In the resting form, the type 2 copper center is reduced. Upon oxidation, it does not appear in the EPR spectrum at 77 K, but it can be observed by using magnetic susceptibility, EPR at approximately 8 K, and magnetic circular dichroism spectroscopy. It displays unusually fast relaxation, indicative of coupling with the adjacent type 3 copper pair of the trinuclear copper cluster. From reductive titrations, we have found that the reduction potential of the type 2 center is higher than those of the other copper sites, thus explaining why it is reduced in the resting form. These results provide new insight into the nature of the additional type 1 copper sites and the redox distribution among copper sites in the different ceruloplasmins relative to other multicopper oxidases.     

Reaction of human ceruloplasmin and anion treated ceruloplasmin with diethyldithiocarbamate

The reaction of human ceruloplasmin and anion treated ceruloplasmin with diethyldithiocarbamate was studied at pH 5.5. The analysis of optical and EPR spectra at 9 GHz showed that ceruloplasmin contains five paramagnetic copper ions, two of which, X and Y, not involved in enzymatic activity, are chelated by diethyldithiocarbamate; the complex thus formed is easily removed by high-speed centrifugation. However, the enzyme depleted of these two X and Y copper ions is able to compete with the Cu(II)-diethyldithiocarbamate complex, as time elapses, recovering both Cu(II) atoms. In addition diethyldithiocarbamate acts as a reducing agent for the two type-I copper atoms when added in large excess to the enzyme or the anion treated enzyme.     

Interaction of nitric oxide with ceruloplasmin lacking an EPR-detectable type 2 copper.

Nitric oxide (NO) has previously been reported to modify the EPR spectrum of multicopper blue oxidases, disclosing a pure type 2 copper and inducing half-field transitions at g = 4. In the present work the reactivity of NO was reinvestigated with respect to ceruloplasmins having an apparently EPR-silent type 2 copper in their native state. The optical properties of NO-treated ceruloplasmin were independent of the initial redox state of the metal sites. Addition of NO caused the absorption at 600 nm to decrease in the case of oxidized ceruloplasmin and to increase when starting from the reduced proteins. In this latter case the absorbance at 330 nm was also restored, indicating that NO was able to reoxidize the reduced protein. In all cases the band at 600 nm leveled to ca. 60% of the intensity of the native untreated protein, and new bands below 500 nm appeared in the spectra. While the blue absorption band was restored by removal of NO, the absorbance below 500 nm remained higher even after dialysis. The EPR spectrum resulting from reaction of NO with either oxidized, partially reduced, or fully reduced ceruloplasmin consisted in all cases of a broad, structureless resonance around g = 2. NO caused the reversible disappearance of the type 1 copper EPR spectrum in oxidized ceruloplasmin. Also, the transient novel copper signal that arises during the anaerobic reduction process by ascorbate completely disappeared in the presence of NO and did not reappear upon removal of the gas.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of some anions on the spectral properties of bovine ceruloplasmin

The effect of binding of N3-, SCN-, OCN-, and F- to bovine ceruloplasmin (Cp) has been studied in detail using absorption, circular dichroic (CD), and electron paramagnetic resonance (EPR) spectroscopies. With the addition of increasing amounts of N3-, SCN-, and OCN- to a Cp solution, the intensity of the band at 614 nm at first increased several percent and then decreased gradually as at least one type I copper was reduced and/or as the type I copper was changed to type II copper. Concomitantly, new bands appeared at 430 and 365 nm for N3-, 435 and 380 nm for SCN-, and about 390 nm for OCN-. A conformational change in the protein induced by the binding of N3-, SCN-, and OCN- to the type II and type III coppers led to the change in the CD spectra. The observed increase of the band at about 430 nm was attributed to the change occurring at the type I copper site. On the other hand, the band at about 370 nm may come from a charge transfer of coordinated anions to the Cu(II) ion. Fluoride ion did not induce the appearance of the band at around 430 and 370 nm, but the parallel component of the type II copper EPR signal was split upon the binding of two fluoride ions to the copper ion.     

Copper(II) and zinc(II) complexes of the peptides Ac-HisValHis-NH2 and Ac-HisValGlyAsp-NH2 related to the active site of the enzyme CuZnSOD

Copper(II) and zinc(II) complexes of the peptides Ac-HisValHis-NH2 and Ac-HisValGlyAsp-NH2 related to the active site of the enzyme CuZnSOD were studied by potentiometric and spectroscopic (UV-Vis, CD and EPR) techniques. The results reveal that both ligands have effective metal binding sites, but the tripeptide is a much stronger complexing agent than the tetrapeptide. The formation of a macrochelate via the coordination of the imidazolyl residues is suggested in the copper(II)-Ac-HisValHis-NH2 system in the acidic pH range, while a 4N complex predominates at physiological pH. The interaction of Ac-HisValHis-NH2 with zinc(II) results in the formation of a precipitate indicating polynuclear complex formation. Both copper(II)-Ac-HisValHis-NH2 and copper(II)-HisValHis systems exhibit catalytic activity toward the dismutation of superoxide anion at physiological pH, but the saturated coordination sphere of the metal ions in both systems results in low reactivity as compared to the native enzyme.     

Role of the axial ligand in type 1 Cu centers studied by point mutations of met148 in rusticyanin.

Type 1 Cu centers in cupredoxins, nitrite reductases, and multi-copper oxidases utilize the same trigonal core ligation to His-Cys-His, with a weak axial ligand generally provided by a Met sulfur. In azurin, an additional axial ligand, a carbonyl oxygen from a Gly, is present. The importance of these axial ligands and in particular the Met has been debated extensively in terms of their role in fine-tuning the redox potential, spectroscopic properties, and rack-induced or entatic state properties of the copper sites. Extensive site-directed mutagenesis of the Met ligand has been carried out in azurin, but the presence of an additional carbonyl oxygen axial ligand has made it difficult to interpret the effects of these substitutions. Here, the axial methionine ligand (Met148) in rusticyanin is replaced with Leu, Gln, Lys, and Glu to examine the effect on the redox potential, acid stability, and copper site geometry. The midpoint redox potential varies from 363 (Met148Lys) to 798 mV (Met148Leu). The acid stability of the oxidized proteins is reduced except for the Met148Gln mutant. The Gln mutant remains blue at all pH values between 2.8 and 8, and has a redox potential of 563 mV at pH 3.2. The optical and rhombic EPR properties of this mutant closely resemble those of stellacyanin, which has the lowest redox potential among single-type 1 copper proteins (185 mV). The Met148Lys mutant exhibits type 2 Cu EPR and optical spectra in this pH range. The Met148Glu mutant exhibits a type 2 Cu EPR spectrum above pH 3 and a mixture of type 1 and type 2 Cu spectra at lower pH. The Met148Leu mutant exhibits the highest redox potential ( approximately 800 mV at pH 3.2) which is similar to the values in fungal laccase and in the type 1 Cu site of ceruloplasmin where this axial ligand is also a Leu.     

The multifunctional oxidase activity of ceruloplasmin as revealed by anion binding studies.

The effect of multiple binding of azide, N3-, on the structural and functional properties of ceruloplasmin (CP) has been reinvestigated by means of both spectroscopic and enzymatic techniques. High affinity binding of the anion to human CP resulted in a dramatic increase of the absorbance at 610 nm and in a concomitant decrease of the optical density at 330 nm. The oxidase activity toward Fe(II) was essentially unaffected, while turnover parameters versus nonferrous substrates dramatically changed, with an approximately 100-fold enhancement of the kcat/Km parameter. Chloride at physiological concentration proved to behave very similarly to N3- bound with high affinity, in that it not only induced the spectroscopic changes previously interpreted in terms of an intramolecular electron transfer from reduced type 1 to type 3 copper ions [Musci, G., Bonaccorsi di Patti, M.C. & Calabrese, L. (1995) J. Protein Chem. 14, 611-617], but it also enhanced some 60-fold the kcat/Km value. A different behavior was observed with chicken CP, where a decrease at 330 nm occurred without a concomitant modification at 603 nm. The chicken enzyme was less sensitive also in terms of enzymatic activity, which was nearly unchanged in the presence of either high affinity N3- or Cl-. At higher N3- concentrations, optical changes of both human and chicken CP were mainly focussed on the appearance of ligand-to-metal charge transfer bands below 500 nm, and the anion behaved as an inhibitor of the oxidase activity versus Fe(II) as well as noniron substrates. The well known bleaching of the blue chromophore could be observed, at neutral pH, only at very high N3-/CP ratios. The data presented in this paper are consistent with a mechanism of structural and functional modulation of CP by anions, that would be able to dictate the substrate specificity of the cuproprotein, and suggest the possibility that CP may act in vivo as a multifunctional oxidase.     

Ceruloplasmin-anion interaction. A circular dichroism spectroscopic study.

The effect of anion binding to ceruloplasmin has been studied using absorption and cirbular dichroism spectral data. At anion to ceruloplasmin molar ratios approaching infinite, OCN-, N3- and SCN- bind to ceruloplasmin giving rise to similar alterations in circular dichroism and absorption spectra. The positive bands at 610 and 520 nm in circular dichroism spectra disappear, a negative one apperars at 600 nm and the peak at 450 nm is only slightly modified. There is a new negative band at 410 nm well-defined in OCN- ceruloplasmin spectra. The decrease in absorption at 610 nm is ascribed to the disruption of one type I Cu-S(cysteine) bond owing presumably to the changes induced by anions in the protein secondary structure. The new band at 410 nm is assigned to a charge transfer transition from the ligand replacing cysteine at its binding site. Both absorption and circular dichroism spectra show isobestic points indicating that anion binding to the enzyme, disruption of one of the two type I Cu-S bonds and coordination of this Cu to another protein residue take place simultaneously.     

Preparation and properties of a single-sited fragment from the C-terminal domain of human transferrin

A single-sited iron-binding fragment of human transferrin has been obtained by thermolysin cleavage of the protein, selectively loaded with iron in the C-terminal binding site, in a urea-containing buffer. The fragment contains carbohydrate, and hence derives from the C-terminal half of transferrin. Its metal-binding site accepts Fe3+ and Cu2+ with bicarbonate as accompanying anion, but only Fe3+ with oxalate as anion. EPR spectroscopic properties of the fragment are similar to those of the corresponding site in the intact protein. However, iron-binding by the fragment is weaker than by the C-terminal site of the intact protein, particularly at low pH, suggesting that overall as well as local protein conformation influences the metal-binding functions of the site.     

Reduced anion binding and anion inhibition in Cu,Zn superoxide dismutase chemically modified at lysines without alteration of the rhombic distortion of the copper site

The spectroscopic binding constant (visible absorption and EPR spectra) and the catalytic inhibition constant of N₃^? and CN^? were measured for bovine Cu, Zn superoxide dismutase chemically modified at all lysines by either succinylation or carbamoylation. These modifications partially inactivate the enzyme (10% and 50% residual activity respectively) but leave the native rhombic geometry of the copper site unaffected. It could thus be shown that the observed reduction of anion affinity of the lysines-modified proteins is related to the decreased positive charge of the protein.     

Discrete roles of copper ions in chemical unfolding of human ceruloplasmin

Human ceruloplasmin (CP) is a multicopper oxidase essential for normal iron homeostasis. The protein has six beta-barrel domains with one type 1 copper in each of domains 2, 4, and 6; the remaining copper ions form a catalytic trinuclear cluster, one type 2 and two type 3 coppers, at the interface between domains 1 and 6. We have characterized urea-induced unfolding of holo- and apo-forms of CP by far-UV circular dichroism, intrinsic fluorescence, 8-anilinonaphthalene-1-sulfonic acid binding, visible absorption, copper content, and oxidase activity probes (pH 7, 23 degrees C). We find that holo-CP unfolds in a complex reaction with at least one intermediate. The formation of the intermediate correlates with decreased secondary structure, exposure of aromatics, loss of two coppers, and reduced oxidase activity; this step is reversible, indicating that the trinuclear cluster remains intact. Further additions of urea trigger complete protein unfolding and loss of all coppers. Attempts to refold this species result in an inactive apoprotein with molten-globule characteristics. The apo-form of CP also unfolds in a multistep reaction, albeit the intermediate appears at a slightly lower urea concentration. Again, correct refolding is possible from the intermediate but not the unfolded state. Our study demonstrates that in vitro equilibrium unfolding of CP involves intermediates and that the copper ions are removed in stages. When the catalytic site is finally destroyed, refolding is not possible at neutral pH. This implies a mechanistic role for the trinuclear metal cluster as a nucleation point, aligning domains 1 and 6, during CP folding in vivo.     

Photoreduction of copper chromophores in blue oxidases.

The low temperature (77 K) irradiation of oxidized ceruloplasmin and Rhus vernicifera laccase at the 330 nm absorption which arises from type 3 copper leads to the reduction of type 1 copper as demonstrated by bleaching of the 610 nm chromophore and the decrease of the EPR signal associated with this species. Type 2 copper remains unaffected. Concomitant with the type 1 copper reduction, a new EPR signal which is possibly that of a biradical appears. Upon thawing, type 1 copper is reversibly oxidized and the radical signal disappears. Irradiation of oxidized protein at the absorption band of type 1 copper produces no spectral change. An EPR study at room temperature confirms the wave-length specificity and reversibility of the photoreduction of type 1 copper and radical formation. Radical appearance and disappearance at room temperature are extremely slow (tau1/2 approximately 30 min). Optical studies at room temperature show that upon anaerobic irradiation of laccase in the 330 nm absorption band, both type 3 and type 1 chromophores are slowly reduced. Upon return to the dark and in the presence of O2, both type 3 and type 1 centers are reoxidized. Oxidizing equivalents either from O2 or K3Fe(CN)6 are required for the reoxidation reaction. These studies demonstrate that there is a direct energy transfer between type 3 and type 1 copper sites in blue copper oxidases.     

Alcaligenes xylosoxidans dissimilatory nitrite reductase: alanine substitution of the surface-exposed histidine 139l ligand of the type 1 copper center prevents electron transfer to the catalytic center

Nitrite reductase of Alcaligenes xylosoxidans contains three blue type 1 copper centers with a function in electron transfer and three catalytic type 2 copper centers. The mutation H139A, in which the solvent-exposed histidine ligand of the type 1 copper ion was changed to alanine, resulted in the formation of a colorless protein containing 4.4 Cu atoms per trimer. The enzyme was inactive with reduced azurin as the electron donor, and in contrast to the wild-type enzyme, no EPR features assignable to type 1 copper centers were observed. Instead, the EPR spectrum of the H139A enzyme, with parameters of g(1) = 2.347 and A(1) = 10 mT, was typical of type 2 copper centers. On the addition of nitrite, the EPR features developed spectral features with increased rhombicity, with g(1) = 2.29 and A(1) = 11 mT, arising from the type 2 catalytic site. As assessed by visible spectroscopy, ferricyanide (E degree = +430 mV) was unable to oxidize the H139A enzyme, and this required a 30-fold excess of K(2)IrCl(6) (E degree = +867 mV). Oxidation resulted in the EPR spectrum developing additional axial features with g(1) = 2.20 and A(1) = 9.5 mT, typical of type 1 copper centers. The oxidized enzyme after separation from the excess of K(2)IrCl(6) by gel filtration was a blue-green color with absorbance maxima at 618 and 420 nm. The instability of the protein prevented the precise determination of the midpoint potential, but these properties indicate that it is in the range 700-800 mV, an increase of at least approximately 470 mV compared with the native enzyme. This high potential, which is consistent with a trigonal planar geometry of the Cu ion, effectively prevents azurin-mediated electron transfer from the type 1 center to the catalytic type 2 Cu site. However, with dithionite as reductant, 20% of the activity of the wild-type enzyme was observed, indicating that the direct reduction of the catalytic site by dithionite can occur. When CuSO(4) was added to the crude extract before isolation of the enzyme, the Cu content of the purified H139A enzyme increased to 5.7 Cu atoms per trimer. The enzyme remained colorless, and the activity with dithionite as a donor was not significantly increased. The additional copper in such preparations was associated with an axial type 2 Cu EPR signal with g(1) = 2.226 and A(1) = 18 mT, and which were not changed by the addition of nitrite, consistent with the activity data.     

Oxidation of reduced cucumber ascorbate oxidase

Reoxidation process of reduced cucumber ascorbate oxidase (1.10.3.3) with dioxygen was investigated in detail through absorption, circular dichroic (CD) and electron paramagnetic resonance (EPR) spectra. One of the three type I coppers and the type II copper were reoxidized more rapidly than other type I coppers. The principal active site of ascorbate oxidase was considered to be comprised of one type I, one type II and a pair of type III coppers similarly to the active sites in laccase and ceruloplasmin. Remaining two type I and a pair of type III coppers were also disclosed to contribute to the oxidation of L-ascorbate.     

Magnetic susceptibility of laccases and ceruloplasmin.

1. Recent magnetic susceptibility measurements on laccase (monophenol,dihydroxyphenylalanine:oxygen oxidoreductase, EC 1.14.18.1) from the lacquer tree Rhus vernicifera showed a deviation from Curie behaviour above 50 K, which was taken as evidence for an antiferromagnetically coupled Cu(II)-Cu(II) pair in the oxidized enzyme. The magnetic susceptibility of this protein has been reinvestigated. Further measurements on laccase from the fungus Polyporus versicolor and human ceruloplasmin (iron(II):oxygen oxidoreductase, EC 1.16.3.1) are presented. 2. The magnetic susceptibility of fungal laccase and lacquer tree laccase can be accounted for by the EPR detectable copper ions in the temperature range 40--300 K. 3. If an antiferromagnetically coupled Cu(II)-Cu(II) pair exists in the laccases, then the coupling, expressed as --J, should be at least of the order of 300 cm-1, as deduced from the Curie dependence of the susceptibility and the sensitivity in our measurements. 4. If an analogy with the laccases is assumed for the EPR invisible copper in ceruloplasmin then a limiting value of the coupling may be deduced also in this case, with --J at least of the order of 200 cm-1.     

Involvement of the Copper in the Inhibition of Cu,Zn Superoxide Dismutase Activity at high pH

The alkaline spectroscopic transition of the copper at the active site of Cu, Zn superoxide dismutase has been reexamined by room temperature EPR. in order to correlate it with the inhibition of the enzyme activity at high pH. The EPR transition is governed by a single prototropic equilibrium, with pK values of 11.3 and 11.1 for ox and shark superoxide dismutase. respectively. This result suggests possible contributions of changes of the copper environment to the higher pK of the activity/pH curve.

When Arg141 was cheniically modified by phenylglyoxal treatment of the ox protein. a lower pK value (10.8) was obtained, indicating that Arg141 is involved in the observed modifications of the EPR spectra.