Evidence for ceruloplasmin as a copper transport protein.

Rats fed a copper-deficient diet for eight weeks showed a large decrease in cytochrome $\text{c}$ oxidase in heart, spleen, liver, lung, and pancreas but no significant change in kidney and brain. Three injections of human or rat ceruloplasmin over a five day period greatly increased cytochrome $\text{c}$ oxidase activity in spleen, liver, heart and lung. Rats receiving CuCl₂, Cu-histidine, and Cu-albumin produced a smaller and slower increase in cytochrome $\text{c}$ oxidase compared to ceruloplasmin treated animals. In Cu-histidine treated rats, the increase in enzyme activity did not occur until after the plasma ceruloplasmin level reached a maximal value. It is concluded that ceruloplasmin functions as a primary copper transport protein from which copper atoms are transferred to cytochrome $\text{c}$ oxidase and probably other copper containing proteins.     

Plasma ceruloplasmin Evidence for its presence in and uptake by heart and other organs of the rat

Evidence for the presence of the plasma protein, ceruloplasmin, in heart and other tissues of the rat was sought using various techniques. With p-phenylenediamine, ceruloplasmin-like oxidase activity was detected in heart postmitochondrial and 100 000 × g supernatants in amounts far exceeding those that could be accounted for by residual blood. Much lower levels were detected in kidney, brain and liver. Oxidase activity of heart purified on DEAE-cellulose in the same way as rat plasma ceruloplasmin and behaved identically also in disc gel electrophoresis. The presence of ceruloplasmin in heart extracts was confirmed immunologically by Ouchterlony diffusion, using rabbit antibody raised against pure rat ceruloplasmin. When pure [³H]leucin-labeled ceruloplasmin was infused intravenously into a copper-deficient rat, radioactivity was concentrated in the heart and brain within 2 h; radioactive counts per g attained 11 and 3 times those of plasma in the two organs, respectively. A lesser concentration occurred in the liver. The results suggest that circulating ceruloplasmin (made by the liver) finds its way into the cells of some organs, especially the heart, a phenomenon which may be related to the function of ceruloplasmin to provide copper to the cytochrome oxidase of various tissues.     

Circulating ceruloplasmin is an important source of copper for normal and malignant animal cells

The relative uptake of copper from ceruloplasmin and non-ceruloplasmin plasma pools, by normal and malignant cells, was investigated in vivo and in vitro, using ⁶⁴Cu and ⁶⁷Cu. 1. Most of the copper administered intravenously to normal and tumor-bearing rats was removed within 1 h, a substantial portion entering the liver. There were differences in the apparent avidity of individual tissues for ceruplasmin vs. ionic copper, but when calculated on the basis of actual μg absorbed, all showed a preference for ceruplasmin. 2. Appreciable amounts of copper from either source were also absorbed by the tumors, and cultured Ehrlich ascites tumor cells showed a rapid uptake and marked preference for ceruplasmin over non-ceruplasmin copper, as did primary rat muscle cell cultures. 3. Ceruplasmin protein was also absorbed by normal and neoplastic rat tissues, but less rapidly than ceruplasmin copper, as determined by administration of pure [³H]leucine- or [¹²⁵I]ceruloplasmin. Copper deficiency did not accelerate this process. 4. It is concluded that, at least in rat, ceruloplasmin is the preferred plasma source of copper for normal and malignant cells, and that the copper on ceruplasmin turns over more rapidly than the protein moiety, a finding consistent with its role as a copper transport protein.     

Copper metabolism in the plaice, Pleuronectes platessa (L.)

Copper metabolism in a teleost, the plaice, Pleuronectes platessa (L.) from a natural environment has been studied. Distribution in the various tissues of the metal and of five key copper-dependent enzymes: ceruloplasmin EC 1.16.3.1; Superoxide dismutase EC 1.15.11; tryptophan oxygenase EC 1.13.1.12; cytochrome oxidase EC 1.9.3.1 and monoamine oxidase EC 1.4.3.4 have been determined. The copper distribution was found to be similar to that in mammals with the greatest concentrations in the brain and heart. Distribution of the copper enzymes is also similar to that found in mammals. A preliminary characterization of the copper enzymes showed that plaice cytochrome oxidase has a pH maximum 2 pH units more alkaline than the mammalian enzyme and that plaice tryptophan oxygenase is more sensitive to heat denaturation than the mammalian enzyme. The present data form a base-line against which studies on factors affecting the copper metabolism in a teleost can be assessed.     

The blue oxidases, ascorbate oxidase, laccase and ceruloplasmin. Modelling and structural relationships

On the basis of the spatial structure of ascorbate oxidase [Messerschmidt, A., Rossi, A., Ladenstein, R., Huber, R., Bolognesi, M., Gatti, G., Marchesini, A., Petruzzelli, R. & Finazzi-Agro, A. (1989) J. Mol. Biol. 206, 513-529], an alignment of the amino acid sequence of the related blue oxidases, laccase and ceruloplasmin is proposed. This strongly suggests a three-domain structure for laccase closely related to ascorbate oxidase and a six-domain structure of ceruloplasmin. These domains demonstrate homology with the small blue copper proteins. The relationships suggest that laccase, like ascorbate oxidase, has a mononuclear blue copper in domain 3 and a trinuclear copper between domain 1 and 3 and ceruloplasmin has mononuclear copper ions in domains 2, 4 and 6 and a trinuclear copper between domains 1 and 6.     

Iron and copper metabolism

Iron and copper are essential nutrients, excesses or deficiencies of which cause impaired cellular functions and eventually cell death. The metabolic fates of copper and iron are intimately related. Systemic copper deficiency generates cellular iron deficiency, which in humans results in diminished work capacity, reduced intellectual capacity, diminished growth, alterations in bone mineralization, and diminished immune response. Copper is required for the function of over 30 proteins, including superoxide dismutase, ceruloplasmin, lysyl oxidase, cytochrome c oxidase, tyrosinase and dopamine-beta-hydroxylase. Iron is similarly required in numerous essential proteins, such as the heme-containing proteins, electron transport chain and microsomal electron transport proteins, and iron-sulfur proteins and enzymes such as ribonucleotide reductase, prolyl hydroxylase phenylalanine hydroxylase, tyrosine hydroxylase and aconitase. The essentiality of iron and copper resides in their capacity to participate in one-electron exchange reactions. However, the same property that makes them essential also generates free radicals that can be seriously deleterious to cells. Thus, these seemingly paradoxical properties of iron and copper demand a concerted regulation of cellular copper and iron levels. Here we review the most salient characteristics of their homeostasis.     

Amino acid sequence of nitrite reductase: a copper protein from Achromobacter cycloclastes.

The amino acid sequence of the copper-containing nitrite reductase (EC 1.7.99.3) from Achromobacter cycloclastes strain IAM 1013 has been determined by using peptides derived from digestion with Achromobacter protease I (Lys), Staphylococcus aureus V8 protease (Glu), cyanogen bromide, and BNPS-skatole in acetic acid. The subunit contains 340 amino acids. The identity of the first seven amino acids is tentative. The sequence has been instrumental in the X-ray structure determination of this molecule; in conjunction with the X-ray structure, ligands to a type I copper atom and a type II copper atom (one of each per subunit) have been identified. Comparison of the sequence to those of multi-copper oxidases such as ascorbate oxidase, laccase, and ceruloplasmin [Messerschmidt, A., & Huber, R. (1990) Eur. J. Biochem. 187, 341-352] reveals that each of two domains seen in the X-ray structure is similar to the oxidases and also to the small blue copper-containing proteins such as plastocyanin. The combination of sequence and structural similarity to ascorbate oxidase and sequence similarity to ceruloplasmin leads to a plausible model for the domain structure of ceruloplasmin.     

Oxidative modification of human ceruloplasmin by methylglyoxal: an in vitro study

Methylglyoxal (MG) is an endogenous physiological metabolite which is present in increased concentrations in diabetics. MG reacts with the amino acids of proteins to form advanced glycation end products. In this in vitro study, we investigated the effect of MG on the structure and function of ceruloplasmin (CP) a serum oxidase carrier of copper ions in the human. When CP was incubated with MG, the protein showed increased electrophoretic mobility which represented the aggregates at a high concentration of MG (100 mM). MG-mediated CP aggregation led to the loss of enzymatic activity and the release of copper ions from the protein. Radical scavengers and copper ion chelators significantly prevented CP aggregation. CP is an important protein that circulates in plasma as a major copper transport protein. It is suggested that oxidative damage of CP by MG may induce perturbations of the copper transport system and subsequently lead to harmful intracellular condition. The proposed mechanism, in part, may provide an explanation for the deterioration of organs in the diabetic patient.     

Copper Proteins and Oxygen : Correlations between structure and function of the copper oxidases

A comprehensive survey of the interaction of the copper proteins and oxygen is presented including a correlation of structure, function, and other properties of the known copper oxidases and of hemocyanin. The origin of their blue color and the structure of copper complexes and copper proteins are related to the oxidation state of copper ion and relevant electronic transitions probably arising from the formation of charge transfer complexes. The oxygen reactions of hemocyanin, ceruloplasmin, and cytochrome oxidase show half-saturation values far below the other Cu enzymes. The formation of hydrogen peroxide as a reaction product is associated with the presence of one Cu atom per oxidase molecule or catalytic system. Water is the corresponding product of the other Cu oxidases with four or more Cu atoms per molecule, except for monoamine oxidase. Mechanisms for the oxidase action of the two and four electron transfer Cu oxidases and tyrosinase are proposed. These reactions account for the number, the oxidation-reduction potential, and the oxidation state of Cu in the resting enzyme, the cyclical change from Cu(II) to Cu(I), the diatomic nature of O₂, the sequence of the oxidation and reduction reactions, and other salient features. The catalytic reactions involved in the oxidation of ascorbic acid by plant ascorbate oxidase, ceruloplasmin, and Cu(II) are compared. Finally the substrate specificity, inhibitory control, and the detailed mechanism of the oxidase activity of ceruloplasmin are summarized.     

A biochemical study of the reconstitution of d-lactate dehydrogenase-deficient membrane vesicles using fluorine-labeled components

Fluorine-19 labeled compounds have been incorporated into lipids and proteins of Escherichia coli. ¹⁹F-Labeled membrane vesicles, prepared by growing a fatty acid auxotroph of a d-lactate dehydrogenase-deficient strain on 8,8-difluoromyristic acid, can be reconstituted for oxidase and transport activities by binding exogenous d-lactate dehydrogenase. ¹⁹F-Labeled d-lactate dehydrogenases prepared by addition of fluorotryptophans to a tryptophan-requiring strain are able to reconstitute d-lactate dehydrogenase-deficient membrane vesicles. Thus, lipid and protein can be labeled independently and used to investigate protein-lipid interactions in membranes.     

Perspectives on copper biochemistry

The biochemistry of the essential trace element copper has been outlined. Following absorption, Cu(II) is transported by serum albumin and transcuprein to the liver where it is incorporated into the plasma Cu-protein, ceruloplasmin, or, possibly, stored as Cu-metallothionein or as superoxide dismutase. Ceruloplasmin is the long-term copper transporter and carries Cu(II) to the tissues for the biosynthesis of key Cu(II) enzymes, especially cytochrome c oxidase, lysyl oxidase and others. The production of copper enzymes raises many new questions about the metabolism of copper. Since ceruloplasmin is the centerpiece of copper metabolism and function, we conclude with more details on its chemistry and multifunctions. This Cu-protein of 132,000 daltons has now been totally sequenced and the copper-containing active sites located. Finally, we have proposed seven possible functions for ceruloplasmin, and there is now good evidence for the existence of ceruloplasmin receptors to expedite some of these functions.     

Transport of silver in virgin and lactating rats and relation to copper

Virgin and lactating Sprague Dawley rats were used to determine whether the pathways of silver transport to tissues and milk resemble those for copper. Rats were injected i.p. with small amounts of ¹¹⁰AgNO₃. Blood and tissues were examined at various times thereafter for total radioactivity and for incorporation into copper binding proteins in plasma and milk. As with ⁶⁷Cu, much of the ¹¹⁰Ag was rapidly incorporated into the liver. Skeletal muscle, spleen, mammary gland, ovaries, uterus and adrenals also were significant initial accumulation sites, with or without lactation. Lactation enhanced uptake by the mammary gland, and radioactivity rapidly entered the milk and milk ceruloplasmin. In the plasma, most of the ¹¹⁰Ag bound to a single component of apparent molecular weight 800 k throughout the 52 h period examined. A small proportion was also incorporated into plasma ceruloplasmin, as determined by immunoprecipitation and native gel electrophoresis. There was little or no association of ¹¹⁰Ag with albumin or transcuprein. The binding of ¹¹⁰Ag to the 800 kDa protein was tight. Off rates during pH 7 dialysis were <2.5%/day even in the presence of 100 M histidine or Cu(II), but were accelarated by mercaptoethanol. Subunits of 145 and 45 kDa in virtually pure peak fractions were those of ₁-macroglobulin. We conclude that silver resembles copper in aspects of its tissue distribution, response to lactation, and incorporation into ceruloplasmin. However its main plasma carrier appears to be ₁-macroglobulin, a different macroglobulin than that involved in copper transport.     

Ceruloplasmin,extracellular-superoxide dismutase,and scavenging of superoxide anion radicals

Ceruloplasmin and extracellular-superoxide dismutase are similar in physical properties. Both are found in extracellular fluids and both are scavengers of the superoxide radical. The relationship between the two proteins was further explored in the present investigation. Ceruloplasmin preparations were found to be commonly contaminated with extracellular-superoxide dismutase. In one preparation, 80% of the superoxide dismutase activity was due to extracellular-superoxide dismutase. Ceruloplasmin, freed from contaminating superoxide dismutase, was found to catalytically dismute the superoxide anion radical with a rate constant of about 1.0 × 10⁴ M⁻ s⁻¹ per copper atom. Under physiological conditions with a low rate of superoxide production, ceruloplasmin preferentially reacts stoichiometrically with the superoxide radical with a rate constant of about 2 × 10⁵ M⁻¹ s⁻¹ per copper atom. Under such conditions, the reaction does not result in hydrogen peroxide formation. From the kinetic data obtained it was calculated that in normal human plasma, extracellular-superoxide dismutase will scavenge about twice as much superoxide as ceruloplasmin. Using immobilized antibodies toward extracellular superoxide dismutase and ceruloplasmin, no antigenic cross-reactivity between the two proteins could be detected.     

Spectral and functional properties of ceruloplasmin under UV irradiation

During oxidase reaction, spectral characteristics of ceruloplasmin at absorption of copper ions and protein part of the molecule are shown to change. It has been ascertained that upon irradiating ceruloplasmin by UV light the functioning of intramolecular electron transport chain is broken, the degree of positive cooperativity (Hill's constant) on substrate decreases. It is supposed that these changes are caused by disturbance of interdomain interactions in the protein molecule.     

Immunochemical and enzymatic study of ceruloplasmin in rheumatoid arthritis

Forty adult patients (30 women and 10 men) with rheumatoid arthritis (RA), treated with nonsteroidal anti-inflammatory drugs, were studied. Serum levels of immunoreactive ceruloplasmin, oxidase activity of the ceruloplasmin and total copper, as well as the specific oxidase activity (enzyme activity per unit of mass) and the copper/immunoreactive ceruloplasmin relationship were significantly higher in the group of patients than in the healthy control group (p < 0.001). However, no significant difference was found for the concentration of non-ceruloplasmin copper between both groups. A statistically significant negative correlation was obtained for the concentration of serum thiobarbituric acid-reacting substances with the immunoreactive ceruloplasmin and its oxidase activity in the group of patients (p < 0.005). These results suggest that in RA increases of serum copper are produced at the expense of the fraction linked to the ceruloplasmin, diminishing the proportion of apoceruloplasmin and other forms poor in copper. Although the increase in the serum concentration of ceruloplasmin might offer an additional safeguard against oxidative stress. it does not appear to have a beneficial effect upon the activity of the illness as evaluated by means the biological inflammation markers C-reactive protein, erythrocyte sedimentation rate and sialic acid.     

Mechanism of Copper Uptake from Blood Plasma Ceruloplasmin by Mammalian Cells

Ceruloplasmin, the main copper binding protein in blood plasma, has been of particular interest for its role in efflux of iron from cells, but has additional functions. Here we tested the hypothesis that it releases its copper for cell uptake by interacting with a cell surface reductase and transporters, producing apoceruloplasmin. Uptake and transepithelial transport of copper from ceruloplasmin was demonstrated with mammary epithelial cell monolayers (PMC42) with tight junctions grown in bicameral chambers, and purified human ⁶⁴Cu-labeled ceruloplasmin secreted by HepG2 cells. Monolayers took up virtually all the ⁶⁴Cu over 16h and secreted half into the apical (milk) fluid. This was partly inhibited by Ag(I). The ⁶⁴Cu in ceruloplasmin purified from plasma of ⁶⁴Cu-injected mice accumulated linearly in mouse embryonic fibroblasts (MEFs) over 3-6h. Rates were somewhat higher in Ctr1+/+ versus Ctr1-/- cells, and 3-fold lower at 2°C. The ceruloplasmin-derived ⁶⁴Cu could not be removed by extensive washing or trypsin treatment, and most was recovered in the cytosol. Actual cell copper (determined by furnace atomic absorption) increased markedly upon 24h exposure to holoceruloplasmin. This was accompanied by a conversion of holo to apoceruloplasmin in the culture medium and did not occur during incubation in the absence of cells. Four different endocytosis inhibitors failed to prevent ⁶⁴Cu uptake from ceruloplasmin. High concentrations of non-radioactive Cu(II)- or Fe(III)-NTA (substrates for cell surface reductases), or Cu(I)-NTA (to compete for transporter uptake) almost eliminated uptake of ⁶⁴Cu from ceruloplasmin. MEFs had cell surface reductase activity and expressed Steap 2 (but not Steaps 3 and 4 or dCytB). However, six-day siRNA treatment was insufficient to reduce activity or uptake. We conclude that ceruloplasmin is a circulating copper transport protein that may interact with Steap2 on the cell surface, forming apoceruloplasmin, and Cu(I) that enters cells through CTR1 and an unknown copper uptake transporter.     

Possible mechanisms underlying copper-induced damage in biological membranes leading to cellular toxicity

It is generally accepted that copper toxicity is a consequence of the generation of reactive oxygen species (ROS) by copper ions via Fenton or Haber-Weiss reactions. Copper ions display high affinity for thiol and amino groups occurring in proteins. Thus, specialized proteins containing clusters of these groups transport and store copper ions, hampering their potential toxicity. This mechanism, however, may be overwhelmed under copper overloading conditions, in which copper ions may bind to thiol groups occurring in proteins non-related to copper metabolism. In this study, we propose that indiscriminate copper binding may lead to damaging consequences to protein structure, modifying their biological functions. Therefore, we treated liver subcellular membrane fractions, including microsomes, with Cu²⁺ ions either alone or in the presence of ascorbate (Cu²⁺/ascorbate); we then assayed both copper-binding to membranes, and microsomal cytochrome P450 oxidative system and GSH-transferase activities. All assayed sub-cellular membrane fractions treated with Cu²⁺ alone displayed Cu²⁺-binding, which was significantly increased in the presence of Zn²⁺, Hg²⁺, Cd²⁺, Ag⁺¹ and As³⁺. Treatment of microsomes with Cu²⁺ in the μM range decreased the microsomal thiol content; in the presence of ascorbate, Cu²⁺ added in the nM concentrations range induced a significant microsomal lipoperoxidation; noteworthy, increasing Cu²⁺ concentration to ≥50 μM led to non-detectable lipoperoxidation levels. On the other hand, μM Cu²⁺ led to the inhibition of the enzymatic activities tested to the same extent in either presence or absence of ascorbate. We discuss the possible significance of indiscriminate copper binding to thiol proteins as a possible mechanism underlying copper-induced toxicity.     

Advances in the Purification of the Mitochondrial Ca2+ Uniporter Using the Labeled Inhibitor 103Ru360

For many years the calcium uniporter has eluded attempts of purification, partly because of the difficulties inherent in the purification of low-abundance hydrophobic proteins (Reed and Bygrave, 1974). Liquid-phase preparative isoelectric focusing improved the fractionation of mitochondrial membrane proteins. A single 6-h run resulted in a 90-fold increase in specific activity of pooled active fractions over a semipurified fraction, allowing for enrichment of the calcium transport function in cytochrome oxidase vesicles. An additional powerful tool in the isolation of the uniporter was the use of the labeled inhibitor ¹⁰³Ru₃₆₀ as an affinity ligand; by following this procedure a protein of 18 kDa was purified in nondenatured, but rather inactive, form. The labeled protein corresponds to the protein that showed Ca²⁺ transport activity.