Ceruloplasmin: macromolecular assemblies with iron-containing acute phase proteins

Copper-containing ferroxidase ceruloplasmin (Cp) forms binary and ternary complexes with cationic proteins lactoferrin (Lf) and myeloperoxidase (Mpo) during inflammation. We present an X-ray crystal structure of a 2Cp-Mpo complex at 4.7 Å resolution. This structure allows one to identify major protein-protein interaction areas and provides an explanation for a competitive inhibition of Mpo by Cp and for the activation of p-phenylenediamine oxidation by Mpo. Small angle X-ray scattering was employed to construct low-resolution models of the Cp-Lf complex and, for the first time, of the ternary 2Cp-2Lf-Mpo complex in solution. The SAXS-based model of Cp-Lf supports the predicted 1:1 stoichiometry of the complex and demonstrates that both lobes of Lf contact domains 1 and 6 of Cp. The 2Cp-2Lf-Mpo SAXS model reveals the absence of interaction between Mpo and Lf in the ternary complex, so Cp can serve as a mediator of protein interactions in complex architecture. Mpo protects antioxidant properties of Cp by isolating its sensitive loop from proteases. The latter is important for incorporation of Fe(3+) into Lf, which activates ferroxidase activity of Cp and precludes oxidation of Cp substrates. Our models provide the structural basis for possible regulatory role of these complexes in preventing iron-induced oxidative damage.

Protection of ceruloplasmin by lactoferrin against hydroxyl radicals is pH dependent1This article is part of a Special Issue entitled Lactoferrin and has undergone the Journal’s usual peer review process

Destruction of ceruloplasmin (Cp) in the presence of hydrogen peroxide is accompanied by the release of the protein’s copper ions that provoke formation of hydroxyl radicals (OH˙) and, consequently, further degradation of the protein. Under such conditions, degradation of Cp is hampered by a number of substances able to bind copper ions. Lactoferrin (Lf) is the most active protector of Cp, its protective effect depending on the pH of the medium. The best protection of Cp by Lf was detected at pH 7.4. In an acidic buffer (pH 5.5), Lf did not affect the destruction of Cp. The pH-dependent efficiency of copper binding by Lf is in good agreement with its capacity to protect Cp against degradation provoked by hydrogen peroxide. It seems likely that peroxide-dependent degradation of Cp stimulated by its own copper ions is a part of neutrophil-induced antimicrobial reactions and may take place properly at the foci of inflammation. Interaction of Lf with Cp may regulate the generation of OH˙ from hydrogen peroxide in the foci of inflammation and protect the adjacent tissues.

Identification of complexes formed by ceruloplasmin with matrix metalloproteinases 2 and 12

Marked sensitivity to proteolytic degradation results in the loss of multiple antioxidant properties of ceruloplasmin (CP), the multicopper oxidase of mammalian plasma. In this study, gel filtration of virtually pure CP (purity 99.7%) yielded complexes of this protein. Subjecting the complexes to SDS-free PAGE revealed other proteins along with CP. These were identified as matrix metalloproteinases (MMP-2 and MMP-12) by means of tryptic fragment mass spectrometry. Electrophoretic bands corresponding to MMP-2 (72 and 67 kDa) and MMP-12 (22 kDa) displayed gelatinase activity. The identified proteinases contained heparin-binding motifs inherent in the complex-forming partners of CP, such as lactoferrin, myeloperoxidase, and serprocidines. Therefore, admixtures of MMPs can be efficiently eliminated from CP preparations by chromatography on heparin-Sepharose as proposed previously.

[A study of the effect of ceruloplasmin and lactoferrin on the chlorination activity of leukocytic myeloperoxidase using the chemiluminescence method]

The chlorination activity of free myeloperoxidase and myeloperoxidase bound with ceruloplasmin or with both ceruloplasmin and lactoferrin has been studied by luminal-dependent chemiluminescence. It was shown that the addition of hydrogen peroxide to the "myeloperoxidase + Cl- + luminal" system is accompanied by a fast flash of light emission. In the absence of myeloperoxidase or Cl-, the flash intensity was considerably reduced. The inhibitor of myeloperoxidase NaN3, the HOCl scavengers taurine and methionine, and guaiacol, a substrate for peroxidation cycle of myeloperoxidase, prevented luminescence. These results suggest that the generation of luminescence was due to the halogenating activity of myeloperoxidase, and hence, the flash light sum may serve as a measure of chlorination activity of myeloperoxidase. The activity of myeloperoxidase was suppressed by ceruloplasmin. Lactoferrin exhibited no significant influence on the myeloperoxidase activity, nor did it prevent the inhibitory effect of ceruloplasmin when they both were combined with myeloperoxidase. These data were confirmed using alternative approaches for evaluating the myeloperoxidase activity, namely, the assessment of peroxidation activity and the taurine chlorination assay. It is noteworthy that the inhibitory effect of ceruloplasmin on chlorination and peroxidation activities of myeloperoxidase is seen with the latter, traditional approaches only if ceruloplasmin is present in a large excess relative to myeloperoxidase, whereas the chemiluminescence method allows the detection of the inhibitory effect of ceruloplasmin using lower proportions of the protein with respect to myeloperoxidase, which are close to the stoichiometry of the myeloperoxidase/ceruloplasmin and the myeloperoxidase'ceruloplasmin'lactoferrin complexes.

Interaction of ceruloplasmin, lactoferrin, and myeloperoxidase

When lactoferrin (LF) and myeloperoxidase (MPO) are added to ceruloplasmin (CP), a CP-LF-MPO triple complex forms. The complex is formed under physiological conditions, but also in the course of SDS-free PAGE. Polyclonal antibodies to both LF and MPO displace the respective proteins from the CP-LF-MPO complex. Similar replacement is performed by a PACAP38 fragment (amino acids 29-38) and protamine that bind to CP. Interaction of LF and MPO with CP-Sepharose is blocked at ionic strength above 0.3 M NaCl and at pH below 4.1 (LF) and 3.9 (MPO). Two peptides (amino acids 50-109 and 929-1012) were isolated by affinity chromatography from a preparation of CP after its spontaneous proteolytic cleavage. These peptides are able to displace CP from its complexes with LF and MPO. Both human and canine MPO could form a complex when mixed with CP from seven mammalian species. Upon intravenous injection of human MPO into rats, the rat CP-human MPO complex could be detected in plasma. Patients with inflammation were examined and CP-LF, CP-MPO, and CP-LF-MPO complexes were revealed in 80 samples of blood serum and in nine exudates from purulent foci. These complexes were also found in 45 samples of serum and pleural fluid obtained from patients with pleurisies of various etiology.

Identification and isolation from breast milk of ceruloplasmin-lactoferrin complex

The presence of a complex of the copper-containing protein ceruloplasmin (Cp) with lactoferrin (Lf) in breast milk (BM) is shown for the first time. In SDS-free polyacrylamide gel electrophoresis (PAGE), electrophoretic mobility of Cp in BM is lower than that of plasma Cp, coinciding with the mobility of the complex obtained upon mixing purified Cp and Lf. Affinity chromatography of delipidated BM on Cp-Sepharose resulted in retention of Lf. SDS-PAGE of the 0.3 M NaCl eluate revealed a single band with Mr approximately 78,000 that has the N-terminal amino acid sequence of Lf and reacts with antibodies to that protein. Synthetic peptides R-R-R-R (the N-terminal amino acid stretch 2-5 in Lf) and K-R-Y-K-Q-R-V-K-N-K (the C-terminal stretch 29-38 in PACAP 38) caused efficient elution of Lf from Cp-Sepharose. Cp-Lf complex from delipidated BM is not retained on the resins used for isolation of Cp (AE-agarose) and of Lf (CM-Sephadex). Anionic peptides from Cp--(586-597), (721-734), and (905-914)--provide an efficient elution of Cp from AE-agarose, but do not cause dissociation of Cp-Lf complex. When anti-Lf is added to BM flowed through CM-Sephadex, Cp co-precipitates with Lf. Cp-Lf complex can be isolated from BM by chromatography on CM-Sephadex, ethanol precipitation, and affinity chromatography on AE-agarose, yielding 98% pure complex. The resulting complex Cp-Lf (1 : 1) was separated into components by chromatography on heparin-Sepharose. Limited tryptic hydrolysis of Cp obtained from BM and from blood plasma revealed identical proteolytic fragments.

Effect of Lactoferrin on the Ferroxidase Activity of Ceruloplasmin

The effects of various forms of lactoferrin (Lf) interacting with ceruloplasmin (Cp, ferro-O2-oxidoreductase, EC 1.16.3.1) on oxidase activity of the latter were studied. Comparing the incorporation of Fe3+ oxidized by Cp into Lf and serum transferrin (Tf) showed that at pH 5.5 apo-Lf binds the oxidized iron seven times and at pH 7.4 four times faster than apo-Tf under the same conditions. Apo-Lf increased the oxidation rate of Fe2+ by Cp 1.25 times when Cp/Lf ratio was 1 : 1. Lf saturated with Fe3+ or Cu2+ increased the oxidation rate of iron 1.6 and 2 times when Cp to holo-Lf ratios were 1 : 1 and 1 : 2, respectively. Upon adding to Cp the excess amounts of apo-Lf (Cp/apo-Lf < 1 : 1) or of holo-Lf (Cp/holo-Lf < 1 : 2) the oxidation rate of iron no longer changed. Complex Cp-Lf demonstrating ferroxidase activity was discovered in breast milk.

Studies of the ceruloplasmin-lactoferrin complex

We have previously shown that iron-containing human lactoferrin (LF) purified from breast milk is able to form both in vitro and in vivo a complex with ceruloplasmin (CP), the copper-containing protein of human plasma. Here we present evidence that the CP-LF complex is dissociated by high concentrations of NaCl, CaCl2, or EDTA, or by decreasing the pH to 4.7. In addition, DNA, bacterial lipopolysaccharide, and heparin can displace CP from its complex with LF. Antibodies to either of the two proteins also cause dissociation of the complex.

Interaction of lactoferrin with ceruloplasmin

When added to human blood serum, the iron-binding protein lactoferrin (LF) purified from breast milk interacts with ceruloplasmin (CP), a copper-containing oxidase. Selective binding of LF to CP is evidenced by the results of polyacrylamide gel electrophoresis, immunodiffusion, gel filtration, and affinity chromatography. The molar stoichiometry of CP:LF in the complex is 1:2. Near-uv circular dichroism spectra of the complex showed that neither of the two proteins undergoes major structural perturbations when interacting with its counterpart. K(d) for the CP/LF complex was estimated from Scatchard plot as 1.8 x 10(-6) M. The CP/LF complex is found in various fluids of the human body. Upon injection into rat of human LF, the latter is soon revealed within the CP/LF complex of the blood plasma, from where the human protein is substantially cleared within 5 h.