Binding and uptake of copper from ceruloplasmin

Specific binding of [67Cu]ceruloplasmin to plasma membrane containing preparations from rat tissues was shown in the presence of an excess of nonradioactive Cu(II) or ceruloplasmin. With Cu(II) there was positive cooperativity and an apparent KD of 10(-7) M. The effects of both "cold" ligands was partly additive. No "specific" binding was shown with Zn(II), unrelated proteins and after boiling the membranes. Total and specific binding of [67Cu]ceruloplasmin were 2-7 fold greater for heart and brain than for liver preparations, per g tissue or per mg protein, +/- correction for yield of 5'-nucleotidase. Cu(II) also inhibited uptake of [67Cu] from ceruloplasmin by CHO cells, but monensin did not, suggesting uptake of ceruloplasmin Cu occurs at the cell surface.     

On the mechanism of cellular cadmium uptake

Review of the available evidence on the mechanism of cellular Cd uptake in the rat jejunum supports the concept that this process consists of nonspecific binding to anionic sites on the membrane, followed by a temperature-dependent and rate-limiting internalization step. Because temperature-sensitive transmembrane movement of Cd can be demonstrated also in isolated brush-border vesicles and in erythrocyte ghosts, it is not likely to result from pinocytosis but may be related directly to membrane fluidity. There is no need to assume the existence of saturable Cd carriers, or competition of Cd with essential polyvalent cations for their specific transport systems. Uptake of Cd by tubular epithelium in the kidney of the intact rabbit appears to resemble that described for the jejunum, with the internalization step limiting the rate of uptake.     

Iron uptake and transfer from ceruloplasmin to transferrin

Background

Dietary and recycled iron are in the Fe^2 + oxidation state. However, the metal is transported in serum by transferrin as Fe^3 +. The multi-copper ferroxidase ceruloplasmin is suspected to be the missing link between acquired Fe^2 + and transported Fe^3 +.

Methods

This study uses the techniques of chemical relaxation and spectrophotometric detection.

Results

Under anaerobic conditions, ceruloplasmin captures and oxidizes two Fe^2 +. The first uptake occurs in domain 6 (< 1 ms) at the divalent iron-binding site. It is accompanied by Fe^2 + oxidation by Cu^2 +_D6. Fe^3 + is then transferred from the binding site to the holding site. Cu⁺_D6 is then re-oxidized by a Cu^2 + of the trinuclear cluster in about 200 ms. The second Fe^2 + uptake and oxidation involve domain 4 and are under the kinetic control of a 200 s change in the protein conformation. With transferrin and in the formed ceruloplasmin–transferrin adduct, two Fe^3 + are transferred from their holding sites to two C-lobes of two transferrins. The first transfer (~ 100 s) is followed by conformation changes (500 s) leading to the release of monoferric transferrin. The second transfer occurs in two steps in the 1000–10,000 second range.

Conclusion

Fe^3 + is transferred after Fe^2 + uptake and oxidation by ceruloplasmin to the C-lobe of transferrin in a protein–protein adduct. This adduct is in a permanent state of equilibrium with all the metal-free or bounded ceruloplasmin and transferrin species present in the medium.

General significance

Ceruloplasmin is a go-between dietary or recycled Fe^2 + and transferrin transported Fe^3 +.     

Few things in life are "free": cellular uptake of steroid hormones by an active transport mechanism

Conventional dogma holds that steroid hormones traverse cell membranes passively, owing to their lipophilic nature. The recently characterized protein megalin, however, functions as a transport protein on cell surfaces to carry steroids across the plasma membrane. Upon hydrolysis of steroid-associated binding globulins in lysosomes, free hormone is liberated and may exert its effects in the cell. Megalin-independent mechanisms of steroid uptake are likely important too, as the phenotypes of megalin-deficient mice do not completely mimic the phenotypes of androgen receptor- or estrogen receptor-null mice.     

Overviews on the cellular uptake mechanism of polysaccharide colloidal nanoparticles

Nanoparticulate drug/gene carriers have gained much attention in the past decades because of their versatile and tunable properties. However, efficacy of the therapeutic agents can be further enhanced using naturally occurring materials‐based nanoparticles. Polysaccharides are an emerging class of biopolymers; therefore, they are generally considered to be safe, non‐toxic, biocompatible and biodegradable. Considering that the target of nanoparticle‐based therapeutic strategies is localization of biomedical agents in subcellular compartments, a detailed understanding of the cellular mechanism involved in the uptake of polysaccharide‐based nanoparticles is essential for safe and efficient therapeutic applications. Uptake of the nanoparticles by the cellular systems occurs with a process known as endocytosis and is influenced by the physicochemical characteristics of nanoparticles such as size, shape and surface chemistry as well as the employed experimental conditions. In this study, we highlight the main endocytosis mechanisms responsible for the cellular uptake of polysaccharide nanoparticles containing drug/gene.     

Sheep ceruloplasmin: isolation and characterization

Molecular and Cellular Biochemistry - Ceruloplasmin has been isolated from sheep plasma by a procedure involving two chromatographic steps and (NH4)2SO4 fractionation. The ovine protein is similar...     

Liver endothelium mediates the hepatocyte''s uptake of ceruloplasmin

The mode of transport of ceruloplasmin (CP) into the liver was investigated in fractionated liver cell suspensions. Incubation of 125I-CP at 4 degrees C with these different fractions led to its binding only to endothelial cells but not Kupffer cells and hepatocytes. Incubation at 37 degrees C led to rapid uptake of 125I-CP by endothelium, but cell-associated radioactivity declined after 15 min, which suggests the release of the labeled substance. Internalization was confirmed by fractionation of surface-bound and internalized ligand. The released label now acquired binding potential for fresh target hepatocytes, and the binding was inhibitable with asialoceruloplasmin but not native CP. This suggested that the released molecule was modified in the endothelium by desialation. Desialation was confirmed by incubation of endothelium with double-labeled CP (3H label on sialic acid and 125I on the protein part). We conclude that in the liver, CP is first recognized and taken up by endothelial cells that are endowed with appropriate surface receptors for the protein. Endothelium then modifies the molecule by desialation to expose the penultimate galactosyl residues. The modified molecule is then released, recognized, and taken up by hepatocytes through their membrane galactosyl-recognition system. These findings are consistent with the role of endothelium as an active mediator of molecular transport between blood and tissue, and further assign a biological role for the galactosyl-recognition system in hepatocytes.     

Cell-penetrating peptides. A reevaluation of the mechanism of cellular uptake

Cellular uptake of a family of cationic cell-penetrating peptides (examples include Tat peptides and penetratin) have been ascribed in the literature to a mechanism that does not involve endocytosis. In this work we reevaluate the mechanisms of cellular uptake of Tat 48-60 and (Arg)(9). We demonstrate here that cell fixation, even in mild conditions, leads to the artifactual uptake of these peptides. Moreover, we show that flow cytometry analysis cannot be used validly to evaluate cellular uptake unless a step of trypsin digestion of the cell membrane-adsorbed peptide is included in the protocol. Fluorescence microscopy on live unfixed cells shows characteristic endosomal distribution of peptides. Flow cytometry analysis indicates that the kinetics of uptake are similar to the kinetics of endocytosis. Peptide uptake is inhibited by incubation at low temperature and cellular ATP pool depletion. Similar data were obtained for Tat-conjugated peptide nucleic acids. These data are consistent with the involvement of endocytosis in the cellular internalization of cell-penetrating peptides and their conjugates to peptide nucleic acids.     

Purification and partial characterization of ceruloplasmin from chicken serum

The preparation and properties of ceruloplasmin from chicken serum are described. Ethanol-CHCl3 was used to precipitate the crude protein, followed by adsorption and elution from DEAE-Sephadex. Further treatment with Sephadex G-200 and CM-Sephadex yielded an intensely blue protein judged 1572-fold purer than starting serum. epsilon-Aminocaproic acid (0.02 M) was present in all buffers and starting sera. Chicken ceruloplasmin appears to be a single polypeptide, apparent Mr 124,000, with an A610/A280 ratio of 0.07 and an absorption maximum at 602 nm. Hexose, hexosamine, and sialic acid accounted for 7.2% of the weight; copper represented 0.20%, which suggested four or five copper atoms per molecule. Chicken ceruloplasmin catalyzed the azide-sensitive oxidation of p-phenylenediamine (PPD) and N,N'-dimethyl-p-phenylenediamine (DPD), and showed ferroxidase activity similar to that of human ceruloplasmin. Its amino acid composition, although similar in many residues to human ceruloplasmin, was decidedly lower in methionine and tyrosine. The chicken protein had one-third the sialic acid content of human ceruloplasmin and showed immunochemical nonidentity with human ceruloplasmin.     

Structural characterization of the ceruloplasmin: lactoferrin complex in solution

Ceruloplasmin is a copper protein found in vertebrate plasma, which belongs to the family of multicopper oxidases. Like transferrin of the blood plasma, lactoferrin, the iron-containing protein of human milk, saliva, tears, seminal plasma and of neutrophilic leukocytes tightly binds two ferric ions. Human lactoferrin and ceruloplasmin have been previously shown to interact both in vivo and in vitro forming a complex. Here we describe a study of the conformation of the human lactoferrin/ceruloplasmin complex in solution using small angle X-ray scattering. Our ab initio structural analysis shows that the complex has a 1:1 stoichiometry and suggests that complex formation occurs without major conformational rearrangements of either protein. Rigid-body modeling of the mutual arrangement of proteins in the complex essentially yields two families of solutions. Final discrimination is possible when integrating in the modeling process extra information translating into structural constraints on the interaction between the two partners.     

Copper uptake and its compartmentalization in Pseudomonas aeruginosa strains: Chemical nature of cellular metal

Copper-sensitive (Cu^s) and copper-resistant (Cu^r) strains of Pseudomonas aeruginosa were characterized in terms of Cu²⁺ sensitivity, uptake and its compartmentalization in the possible cell sectors. Minimum inhibitory concentrations (MICs) of Cu²⁺ for the Cu^r strain (3.2 mM and 0.12 mM in enriched- and in minimal-medium, respectively) were almost 5-fold higher over that of its sensitive counterpart. While Cu^s strain accumulated Cu²⁺ to a maximum of 1.8 mol mg^–1 protein, Cu^r strain increased it to 2.37 mol mg^–1 protein. Both the strains also demonstrated energy- and pH-dependent Cu²⁺ uptake through the broad-substrate range divalent cation (Zn²⁺, Mg²⁺, Co²⁺) uptake system as well as through the system specific for Cu²⁺. Cell-fractionation study revealed that in Cu^r strain, periplasm and membrane are the main Cu²⁺ binding sites, whereas, in case of Cu^s strain, it is the cytoplasm. The overall observations indicate that the Cu^r strain restricted Cu²⁺ sequestration exterior to the cytoplasm as the possible strategy for Cu-resistance. The chemical nature of Cu²⁺ deposition in the respective strains was also ascertained by X-ray powder diffraction analysis.     

Anion uptake in halorhodopsin from Natromonas pharaonis studied by FTIR spectroscopy: consequences for the anion transport mechanism

The uptake of chloride, bromide, iodide, nitrate, and azide by anion-depleted blue halorhodopsin from Natronobacterium pharaonis has been followed by FTIR difference spectroscopy using an ATR sampling device. The spectra are compared with the spectrum of the O intermediate obtained by time-resolved FTIR studies of the photocycle. It is demonstrated that anion-free blue halorhodopsin can be identified with the O intermediate and, thus, that the decay of O is due to the passive uptake of the anion. The great similarity of the anion-binding spectra and their identity in the case of the monoatomic anions indicate a rather unspecific binding site for the different anions dominated by electrostatic interactions. Comparing spectra obtained with 15N nitrate and unlabeled nitrate, the NO-stretching bands could be identified. The small splitting and the small IR intensity of those bands indicate a rather nonpolar binding site with a rather isotropic influence on the nitrate, in contrast to aqueous nitrate. In further experiments on the photocycle of blue halorhodopsin, the all-trans --> 13-cis isomerization can be clearly identified. Up to 100 micros, the isomerization-induced structural changes deduced from amide I changes are similar to those occurring during the anion-transporting photocycle. Compared to these, the molecular changes involved in the release and their reversion during the uptake of anions are considerably larger. They can be reached via two pathways: (1) by reducing the anion concentration and (2) transiently during the anion-transporting photocycle with the formation of the precursor of O with O conformation. Consequences of the anion transport mechanism are discussed.     

Copper regulation of ceruloplasmin in copper-deficient rats.

In copper-deficient rats, oral intubation of copper increases the rate of ceruloplasmin synthesis without affecting general synthesis of plasma or liver proteins. It also restores the enzyme from half to full activity. Copper given by injection at doses commonly employed has additional nonspecific effects on protein synthesis and in some strains of rats produces severe hemolysis. In contrast to deficient rats, in normal rats copper does not elevate plasma ceruloplasmin unless hemolysis also occurs. Thus, at least in deficiency, copper availability controls the rate of synthesis, acitvation, and plasma concentration of ceruloplasmin.     

Purification and partial characterization of ceruloplasmin receptors from rat liver endothelium

Ceruloplasmin (CP), a circulating glycoprotein, is known for its copper transport. Recently the spectrum of its activity has been increased to include numerous enzymatic functions. CP binds to the liver endothelium and is transported across the cell via a mechanism involving receptor-mediated endocytosis. To isolate CP receptors, we obtained purified preparations of liver endothelium in rats. The membrane was then isolated by ultracentrifugation and solubilized in Triton X-100. Membrane proteins were labeled with 125I and passed through an affinity column in which CP was covalently linked to Sepharose 4B. Most of the radioactivity was eluted with buffer during the first 5 days. When no more radioactivity was eluted with buffer, elution was done either competitively with cold excess CP or 1 M NaCl. By this technique, a sharp single peak of radioactivity was obtained and subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing and nonreducing conditions. Under both conditions receptors appeared as a single band with Mr of 35,000 containing 3% carbohydrate and an isoelectric point of 5.2.     

Copper reduction by the octapeptide repeat region of prion protein: pH dependence and implications in cellular copper uptake

The physiological function of the prion protein (PrP) remains enigmatic despite its established involvement in the pathogenesis of spongiform encephalopathies. PrP is a glycolipid-anchored membrane protein, which constitutively recycles between the cell surface and an endosomal compartment. The N-terminal region of PrP contains a four tandem repeat (OP4) of the octapeptide PHGGGWGQ (OP) that binds and reduces Cu(II) ions. We have examined the kinetic properties of the OP4-mediated Cu(II) reduction and found that OP4 exhibits the highest reduction activity around pH 6.5, close to the pH in early endosomes. All four OP units and at least one tryptophan side chain are essential for Cu(II) reduction. The reaction is described by an uncompetitive substrate inhibition mechanism involving a 1:1 Cu(II)-OP4 active intermediate. Structural analysis by Raman spectroscopy has revealed that the Cu(II) ion is coordinated by four histidine Ntau atoms in the active intermediate and the feasibility of formation of this intermediate correlates with the Cu(II) reduction over a pH range from 5.0 to 8.2. Molecular mechanics calculations suggest that two tryptophan residues of OP4 are located near the Cu(II) site, being consistent with the importance of redox-active tryptophan in the Cu(II) reduction. PrP has been proposed to capture Cu(II) ions in the extracellular space and release them in the endosome. The results of this study strongly suggest that PrP also plays a role in the reduction of captured Cu(II) ions prior to their transfer to Cu(I)-specific intracellular copper trafficking proteins.     

Purification and partial characterization of goose ceruloplasmin

The preparation and properties of ceruloplasmin from goose blood plasma are described. Ammonium sulfate was used to precipitate the crude protein followed by adsorption and elution from DEAE-Sephadex A-50. Further treatment with an ethanol-chloroform mixture and Sephadex G-200 yielded an intensely blue protein possessing a high degree of chemical purity and biological activity. Goose ceruloplasmin, existing in two forms, appears to be a single polypeptide, apparent Mr121,300, with an A610/A280 ratio of 0.07. Copper represented 0.32%, which corresponded to six atoms of copper per protein molecule. Although the amount of EPR-detectable copper was the same as in mammalian ceruloplasmins there were some differences in EPR parameters, mainly in A parallel. Goose ceruloplasmin's amino acid composition, although similar in many residues to human ceruloplasmin, was lower in tyrosine, cystine/cysteine, and acidic amino acids. Valine was found as the N-terminal amino acid. Hexose, hexosamine, sialic acid, and fucose accounted for 6.65% of the weight. Goose protein contained only half the sialic acid of human ceruloplasmin. Two values for Km using either p-phenylenediamine (0.64 and 0.053 mM) or o-dianisidine (0.76 and 0.15 mM) were evaluated from Lineweaver-Burk plots. EPR studies on reactions with water radiolysis products at cryogenic temperatures allowed us to discover that goose ceruloplasmin, like human and bovine ceruloplasmins, possesses superoxide dismutase activity.     

Spectral characteristics of the mechanism of oxidase activity of ceruloplasmin

The absorbance and EPR spectra of type 1 and 2 copper-binding centres which are present in ceruloplasmin (Cp) molecule were shown to disappear upon the reduction of the enzyme by ascorbate under anaerobic conditions. The fluorescence band attributed to type 3 Cu was altered concomitantly. The electron-accepting nitroxyl radical added to reduced Cp restored the absorbance, EPR and fluorescence spectra of the oxidase. Only type 1 and 3 copper ions, as judged by spectral changes, can be reduced by ascorbate and then reoxidized by the nitroxyl radical in the azide-treated Cp. The spectral properties of Cp provided by copper ions of different types change simultaneously and concordantly upon oxidation/reduction. This seems to be caused by cooperative interaction of these ions involved in the electron transfer from the donating substrate to the accepting molecule of the nitroxyl radical (in model studies of oxidase reaction) or oxygen (under natural conditions). The copper ions in the active centre of Cp constitute an intramolecular electron transport chain, which may, at least in vitro, function without one of its links.