Transferrin subtypes in Iran

The frequency of transferrin Tf C subtypes has been determined by double one-dimensional electrophoresis of plasma samples from Moslems (n = 91), Zoroastrians (n = 97), Jews (n = 88) and Armenians (n = 88) of Iran. The Zoroastrians show the lowest frequency of TfC1 (0.4999) and highest frequencies of TfC2 and TfC3 (.02215, and 0.2783, respectively). The Jews have the highest TfC1- and the lowest TfC2- and TfC3 frequencies (0.8011, 0.1478, and 0.0512, respectively). It could be shown that the differences between Zoroastrians and Jews are highly significant (p less than 0.001). Arbitrary subtyping of transferrin Tf B and TfD phenotypes could be done on samples from three regional groups of Iran: North: n = 282, Central: n = 548, and South: n = 587 into Tf B (Iran 1, 2, 3 and 4) and Tf D (Iran 1, 2 and 3) was performed according to mobilities relative to the transferrin C protein during polyacrylamide gel electrophoresis and by relative pI deviations from the Fe2-transferrin C1 protein after isoelectric focussing. The allele frequencies found in the total sample (n = 1417) are: TfB1 = 0.0003, TfB2 = 0.0010, TfB3 = 0.0042, TfB4 = 0.0007; TfD1 = 0.0017, TfD2 = 0.0014, and TfD3 = 0.0010.     

Mutational analysis of the transferrin receptor reveals overlapping HFE and transferrin binding sites.

The transferrin receptor (TfR) binds two proteins critical for iron metabolism: transferrin (Tf) and HFE, the protein mutated in hereditary hemochromatosis. Previous results demonstrated that Tf and HFE compete for binding to TfR, suggesting that Tf and HFE bind to the same or an overlapping site on TfR. TfR is a homodimer that binds one Tf per polypeptide chain (2:2, TfR/Tf stoichiometry), whereas both 2:1 and 2:2 TfR/HFE stoichiometries have been observed. In order to more fully characterize the interaction between HFE and TfR, we determined the binding stoichiometry using equilibrium gel-filtration and analytical ultracentrifugation. Both techniques indicate that a 2:2 TfR/HFE complex can form at submicromolar concentrations in solution, consistent with the hypothesis that HFE competes for Tf binding to TfR by blocking the Tf binding site rather than by exerting an allosteric effect. To determine whether the Tf and HFE binding sites on TfR overlap, residues at the HFE binding site on TfR were identified from the 2.8 A resolution HFE-TfR co-crystal structure, then mutated and tested for their effects on HFE and Tf binding. The binding affinities of soluble TfR mutants for HFE and Tf were determined using a surface plasmon resonance assay. Substitutions of five TfR residues at the HFE binding site (L619A, R629A, Y643A, G647A and F650Q) resulted in significant reductions in Tf binding affinity. The findings that both HFE and Tf form 2:2 complexes with TfR and that mutations at the HFE binding site affect Tf binding support a model in which HFE and Tf compete for overlapping binding sites on TfR.     

Transferrin subtypes and variants in Germany; Further evidence for a Tf null allele

Summary Isoelectric focusing (IEF) with carrier ampholytes was used for the determination of transferrin C subtypes and transferrin B and D variants in a sample of 1125 unrelated individuals from Southern Germany. The observed TfC allele frequencies were Tf*C1=0.7872, Tf*C2=0.1365, and Tf*C3=0.0675. The rare C subtype C6 was observed twice. A new C subtype, called C10, was observed and identified by IEF with immobilized pH gradients. The rare C subtypes C4 and C8 were also studied by this method. TfB and TfD variants were found with a heterozygous frequency of 1.53%. One new TfD was found which is located between D1 and D2 and therefore named D1-2. Evidence for a Tf null allele was obtained in a child and the putative father; they were considered to be heterozygous for an allele Tf0. The theoretical exclusion rate for paternity examinations was calculated for the Tf system and found to be 17.95%.     

Transferrin C subtype frequencies in the Finnish population

Transferrin (Tf) C subtypes were determined in 419 unrelated adult Finns. The calculated gene frequencies were C1 = 0.738, C2 = 0.097 and C3 = 0.133. The Tf phenotypes in 150 mother-child pairs were in accordance with autosomal codominant inheritance. This material included a rare TfC allele product in three individuals, apparently the same in all cases.     

Human transferrin (Tf): a single mutation at codon 570 determines Tf C1 or Tf C2 variant

Transferrin (Tf) has many variants, as revealed by isoelectric focusing (IEF). Although these Tf variants have long been thought to arise from the multiple alleles at single Tf locus, amino acid substitution related to the two major variants, Tf C1 and Tf C2, has so far not been reported. We investigated the difference responsible for Tf C1 and Tf C2 variants and identified a single base change in exon 15 of the Tf gene resulting in the phenotypes on IEF. C/T base substitution at codon 570 replaced Pro in Tf C1 with Ser in Tf C2. Based on this nucleotide substitution, we established PCR-based genotyping for the Tf C1 and Tf 2 alleles. Received: 20 February 1997 / Accepted: 9 April 1997     

Distribution of C subtypes and other Tf variants in populations of the USSR

Serum samples from seventeen Caucasoids and Mongoloid populations of the USSR were tested for transferrin (Tf) subtypes. According to Tf patterns, the Caucasoids groups had high TfC1 frequency, whereas Mongoloids are characterized by increased frequency of TfC2 suballele. The following gene frequencies were observed: TfC1 - 0.8515, TfC2 - 0.1166, TfC3 - 0.0129, TfD - 0.0129, TfB - 0.0065 for Russians of Yegoryevsk town; TfC1 - 0.8663, TfC2 - 0.0930, TfC3 - 0.0233 for West-Pamirian populations of Khuf, those being for Pastkhuf 0.8476, 0.1159 and 0.0244, respectively. Mongoloid populations demonstrate following frequencies of five genes described (in the order shown above): 0.7870, 0.1620, 0.0232, 0.0139 for Kirghizes of East Pamir; 0.7963, 0.1805, 0.0050, 0.0182 for Buriats of Suduntui; 0.7647, 0.1985, 0.0074, 0.0221, 0.0037 and 0.0037 (gene TfDX) for Buriats of Sakhiurta, the frequencies of these genes being 0.7647, 0.1985, 0.0074, 0.021, 0.0037 and 0.0037 for Aginsky national district, Chita Region. The total sample of Buriats of Gakhan cluster (Ust-Ordyn national district) and Olkhon island of Irkutsk Region demonstrates following frequencies of genes (in the same order): 0.7876, 0.1962, 0.0012, 0.0057, 0.0082 and 0.7679 and 0.2321, respectively. In addition, a rare anodal variant designated tentatively TfC12Like was found among Pamir populations. The results obtained are compared with those reported for world populations.     

Comparative studies of the binding and growth-supportive ability of mammalian transferrins in human cells

The ability of human-derived cells in culture to bind, remove iron from, and grow in the presence of transferrins (Tf) isolated from the sera of species commonly included in tissue culture medium was investigated. Kinetic studies on HeLa cells reveal apparent first-order association rate constants of 0.43 min-1 for human Tf and 0.15 min-1 for equine Tf. Labeled chicken ovo-Tf and fetal bovine Tf were not recognized by the HeLa cells. Competition experiments with HeLa cells that use either isolated Tf or parent serum confirm these findings. Equilibrium binding experiments performed on HeLa cells at 37 degrees C in the presence of 2,4-dinitrophenol to prevent iron removal indicate 1 X 10(6) Tf bound/cell with a dissociation constant (K'D) of 28 nM for human Tf and 182 nM for equine Tf. Equilibrium binding performed at 0 degrees C to prevent endocytosis reveals 4.1-6.7 X 10(5) Tf binding sites/cell with a K'D of 8.3 nM for human Tf and 41.5 nM for equine Tf. Parallel experiments in normal human diploid fibroblast-like MRC-5 cells indicate expression of 0.82-2.78 X 10(5) Tf binding sites/cell with a K'D of 8.2 nM for human and 39.1 nM for equine Tf. Thus, the results of equilibrium binding studies of a more differentiated cell type are consistent with those found for HeLa cells. Fetal bovine Tf was found to compete weakly with labeled human Tf for human receptor on HeLa cells in a soluble receptor assay, with an approximately 500-fold excess needed to reduce binding to half maximal. Iron uptake experiments show an iron donating hierarchy where human greater than horse greater than calf, suggesting that the rate of iron uptake depends on the affinity of receptor for transferrin. Growth experiments involving HeLa cells in chemically defined serum-free medium demonstrate that bovine Tf will support growth as well as human Tf, but at concentrations much higher than are required of human Tf.     

人血清转铁蛋白遗传多态性与疾病相关的研究

本文应用等电聚焦电泳技术,调查了广州地区128例白血病、80例原发性肝癌、52例系统性红斑狼疮和1456例正常人的Tf遗传多态性分布。与正常人组相比,急性粒细胞白血病组的Tf~(C_1)基因频率显著增高(P<0.05);TfC_1C_1表型频率也显著高于正常人组(P<0.05),TfC_1C_1人群的患病相对危险率为1.9。未发现急性淋巴细胞白血病、慢性粒细胞白血病、原发性肝癌疾病组的Tf表型和基因频率与正常人组有显著性统计学差异。此外,还发现系统性红斑狼疮组的Tf~(C_2)基因频率显著高于正常人(P<0.025),Tf~(C_1)频率则相应下降(P<0.05);表型频率TfC_1C_2显著增高(P<0.005),相对危险率为2.3,TfC_1C_2相应下降(P<0.01)。     

Determinants of the interaction between the iron-responsive element-binding protein and its binding site in rat L-ferritin mRNA

Ferritin messenger RNA has been shown to be translationally inactivated by the binding of a cytosolic protein to a 28-nucleotide iron-responsive element (IRE) located in the 5'-untranslated region of the mRNA. This interaction has been studied using quantitative receptor-ligand binding methods with gel retardation and nitrocellulose filter binding assays for the separation of bound complex from free RNA. In competition assays the entire 5'-untranslated region and the isolated IRE bound identically. The specificity of the RNA binding was studied using IRE variants. Two IREs from transferrin receptor mRNA and several variants with single base substitutions in the stem or loop had similar affinities. RNAs which could not form a stem-loop structure bound 1000-fold less well. These studies demonstrate the importance of the RNA conformation and the relative insensitivity of binding to much of the primary sequence. Saturation assays with increasing concentrations of 32P-IRE resulted in a binding hyperbola characteristic of mass action binding to a single class of sites with a KD = 0.09 nM. At 37 degrees C the dissociation rate is 0.04 min-1 (t 1/2 = 17 min). This rate is fast enough to account for the shift of ferritin RNA from the ribonucleoprotein pool to polysomes after rats are injected with iron. Determination of the concentration of the repressor requires accounting for three interconverting pools: free active repressor, mRNA-bound protein, and inactive (low affinity) repressor. Rat liver cytosol has a concentration of free active repressor of about 1 pmol/mg protein. Protein bound to endogenous mRNA can be measured by pretreatment with micrococcal nuclease or by separation with DEAE-Sepharose chromatography; it is present at a level similar to that of the free active protein. Inclusion of high levels of thiol reductants in the binding incubations reduces the inactive or low affinity repressor, forming unstably activated protein which has the same KD as the endogenous active protein; this inactive or low affinity protein is 2-4 times more abundant. A mechanism for iron regulation is proposed which accounts for the kinetics, the multiple protein pools, and the characteristics of the protein in these pools.     

Conserved interaction between transferrin and transferrin-binding proteins from porcine pathogens

Gram-negative porcine pathogens from the Pasteurellaceae family possess a surface receptor complex capable of acquiring iron from porcine transferrin (pTf). This receptor consists of transferrin-binding protein A (TbpA), a transmembrane iron transporter, and TbpB, a surface-exposed lipoprotein. Questions remain as to how the receptor complex engages pTf in such a way that iron is positioned for release, and whether divergent strains present distinct recognition sites on Tf. In this study, the TbpB-pTf interface was mapped using a combination of mass shift analysis and molecular docking simulations, localizing binding uniquely to the pTf C lobe for multiple divergent strains of Actinobacillus plueropneumoniae and suis. The interface was further characterized and validated with site-directed mutagenesis. Although targeting a common lobe, variants differ in preference for the two sublobes comprising the iron coordination site. Sublobes C1 and C2 participate in high affinity binding, but sublobe C1 contributes in a minor fashion to the overall affinity. Further, the TbpB-pTf complex does not release iron independent of other mediators, based on competitive iron binding studies. Together, our findings support a model whereby TbpB efficiently captures and presents iron-loaded pTf to other elements of the uptake pathway, even under low iron conditions.     

The molecular mechanism for receptor-stimulated iron release from the plasma iron transport protein transferrin

Human transferrin receptor 1 (TfR) binds iron-loaded transferrin (Fe-Tf) and transports it to acidic endosomes where iron is released in a TfR-facilitated process. Consistent with our hypothesis that TfR binding stimulates iron release from Fe-Tf at acidic pH by stabilizing the apo-Tf conformation, a TfR mutant (W641A/F760A-TfR) that binds Fe-Tf, but not apo-Tf, cannot stimulate iron release from Fe-Tf, and less iron is released from Fe-Tf inside cells expressing W641A/F760A-TfR than cells expressing wild-type TfR (wtTfR). Electron paramagnetic resonance spectroscopy shows that binding at acidic pH to wtTfR, but not W641A/F760A-TfR, changes the Tf iron binding site > or =30 A from the TfR W641/F760 patch. Mutation of Tf histidine residues predicted to interact with the W641/F760 patch eliminates TfR-dependent acceleration of iron release. Identification of TfR and Tf residues critical for TfR-facilitated iron release, yet distant from a Tf iron binding site, demonstrates that TfR transmits long-range conformational changes and stabilizes the conformation of apo-Tf to accelerate iron release from Fe-Tf.     

Characterization of the Interaction between Diferric Transferrin and Transferrin Receptor 2 by Functional Assays and Atomic Force Microscopy

Transferrin receptor 2 (TfR2), a homologue of the classical transferrin receptor 1 (TfR1), is found in two isoforms, α and β. Like TfR1, TfR2α is a type II membrane protein, but the β form lacks transmembrane portions and therefore is likely to be an intracellular protein. To investigate the functional properties of TfR2α, we expressed the protein with FLAG tagging in transferrin-receptor-deficient Chinese hamster ovary cells. The association constant for the binding of diferric transferrin (Tf) to TfR2α is 5.6 × 10⁶ M^− 1, which is about 50 times lower than that for the binding of Tf to TfR1, with correspondingly reduced rates of iron uptake. Evidence for Tf internalization and recycling via TfR2α without degradation, as in the TfR1 pathway, was also found. The interaction of TfR2α with Tf was further investigated using atomic force microscopy, a powerful tool used for investigating the interaction between a ligand and its receptor at the single-molecule level on the living cell surface. Dynamic force microscopy reveals a difference in the interactions of Tf with TfR2α and TfR1, with Tf-TfR1 unbinding characterized by two energy barriers, while only one is present for Tf-TfR2. We speculate that this difference may reflect Tf binding to TfR2α by a single lobe, whereas two lobes of Tf participate in binding to TfR1. The difference in the binding properties of Tf to TfR1 and TfR2α may help account for the different physiological roles of the two receptors.     

Evidence for transferrin polymorphism in Spanish wild rabbits

Serum samples from 412 Spanish wild rabbits were analysed by starch and polyacrylamide gel electrophoresis. Three different transferrin (Tf) phenotypes (A, AB and B) were observed by both methods. The occurrence of two codominant alleles (TfA and TfB with frequencies of 0.89 and 0.11 respectively) at an autosomal locus (Tf) was supported by the population data on genetic equilibrium. Electrophoretic mobility differences between the Tf variants A and B could not be explained by differences in sialic acid or iron contents. Each of the two Tf variants were shown to have two sialic acid residues by neuraminidase treatment. These variants had similar affinities for iron, and iron binding did not lead to the conversion of one variant into the other.     

Structural and functional studies on the stalk of the transferrin receptor

Transferrin (Tf) is an iron carrier protein that consists of two lobes, the N- and C-lobes, which can each bind a Fe³⁺ ion. Tf binds to its receptor (TfR), which mediates iron delivery to cells through an endocytotic pathway. Receptor binding facilitates iron release from the Tf C-lobe, but impedes iron release from the N-lobe. An atomic model of the Tf-TfR complex based on single particle electron microscopy (EM) indicated that receptor binding is indeed likely to hinder opening of the N-lobe, thus interfering with its iron release. The atomic model also suggested that the TfR stalks could form additional contacts with the Tf N-lobes, thus potentially further slowing down its iron release. Here, we show that the TfR stalks are unlikely to make strong interactions with the Tf N-lobes and that the stalks have no effect on iron release from the N-lobes of receptor-bound Tf.     

黄喉拟水龟转铁蛋白基因的克隆以及表达特征分析

转铁蛋白在铁的新陈代谢中起着重要的作用,参与细菌感染后的免疫反应。研究克隆了黄喉拟水龟Tf基因组DNA全长序列,并对Tf基因的序列特征进行了分析。序列分析表明,黄喉拟水龟Tf是由两个相似结构域构成的单一肽链,每个结构域包含两个亚基,它们相互作用形成一个深的、亲水的铁结合位点。其基因组DNA由17个外显子和16个内含子组成,与其他脊椎动物Tf基因结构相似,显示了黄喉拟水龟Tf基因在结构上的保守性。同源性分析表明,黄喉拟水龟的Tf基因与鸟类、爬行类的Tf基因同源性最高,约为75%—97%;与哺乳类Tf基因的同源性约为65%—75%;与爪蟾等两栖类的Tf基因也有一定的同源性。荧光定量PCR结果显示,黄喉拟水龟人工感染粘质沙雷氏菌后,Tf基因在其肝脏、脾脏、肾脏及心脏各组织中的表达量均有上调的趋势,这与其他动物经病原刺激后的表达特征具有相似性。       

"Dilysine trigger" in transferrins probed by mutagenesis of lactoferrin: crystal structures of the R210G,R210E,and R210L mutants of human lactoferrin

The mammalian iron-binding proteins lactoferrin (Lf) and transferrin (Tf) bind iron very tightly, but reversibly. Despite homologous structures and essentially identical iron binding sites, Tf begins to release iron at pH 6.0, whereas Lf retains iron to pH approximately 3.5. This difference in iron retention gives the two proteins different biological roles. Two lysine residues, Lys 206 and Lys 296, which form a hydrogen-bonded dilysine pair in human Tf, have been shown to strongly influence iron release from the N-lobe. The equivalent residues in human Lf are Arg 210 and Lys 301, and we have here mutated Arg 210 in the N-lobe half-molecule of human lactoferrin, Lf(N), to probe its role in iron release. The Lf(N) mutants R210G, R210E, and R210L were expressed, purified, and crystallized, and their crystal structures were determined and refined at resolutions of 1.95 A (R210G), 2.2 A (R210E), and 2.0 A (R210L). The overall structures are very similar to that of wild-type Lf(N), but with small differences in domain orientations. In each of the mutants, however, Lys 301 (equivalent to Lys 296 in Tf) changes its conformation to fill the space occupied by Arg 210 Neta2 in wild-type Lf(N), interacting with the two tyrosine ligands Tyr 92 and Tyr 192. By comparison with other Lf and Tf structures, we conclude that Lys 301 (or Lys 296 in Tf) only occupies this site when residue 210 (206 in Tf) is nonpositive (neutral as in R210G and R210L or negative as in R210E). Thus, Lys 206 in the Tf dilysine pair is identified as having a depressed pK(a). Three specific sites are variably occupied by polar groups in the Lf mutants and other Lf and Tf proteins, and when coupled with iron-release data, these give new insights into the factors that most influence iron retention at low pH.     

Site-specific rate constants for iron acquisition from transferrin by the Aspergillus fumigatus siderophores N′,N′′,N′′′-triacetylfusarinine C and ferricrocin

Aspergillus fumigatus is an opportunistic fungal pathogen that causes life-threatening infections in immunocompromised patients. Despite low levels of free iron, A. fumigatus grows in the presence of human serum in part because it produces high concentrations of siderophores. The most abundant siderophores produced by A. fumigatus are N',N',N'-triacetylfusarinine C (TAF) and ferricrocin, both of which have thermodynamic iron binding constants that theoretically allow them to remove transferrin (Tf)-bound iron. Urea-polyacrylamide gel electrophoresis was used to measure the change in concentration of Tf species incubated with TAF or ferricrocin. The rate of removal of iron from diferric Tf by both siderophores was measured, as were the individual microscopic rates of iron removal from each Tf species (diferric Tf, N-terminal monoferric Tf and C-terminal monoferric Tf). TAF removed iron from all Tf species at a faster rate than ferricrocin. Both siderophores showed a preference for removing C-terminal iron, evidenced by the fact that k(1C) and k(2C) were much larger than k(1N) and k(2N). Cooperativity in iron binding was observed with TAF, as the C-terminal iron was removed by TAF much faster from monoferric than from diferric Tf. With both siderophores, C-terminal monoferric Tf concentrations remained below measurable levels during incubations. This indicates that k(2C) and k(1C) are much larger than k(1N). TAF and ferricrocin both removed Tf-bound iron with second-order rate constants that were comparable to those of the siderophores of several bacterial pathogens, indicating they may play a role in iron uptake in vivo and thereby contribute to the virulence of A. fumigatus.     

An iron-dependent and transferrin-mediated cellular uptake pathway for plutonium

Plutonium is a toxic synthetic element with no natural biological function, but it is strongly retained by humans when ingested. Using small-angle X-ray scattering, receptor binding assays and synchrotron X-ray fluorescence microscopy, we find that rat adrenal gland (PC12) cells can acquire plutonium in vitro through the major iron acquisition pathway--receptor-mediated endocytosis of the iron transport protein serum transferrin; however, only one form of the plutonium-transferrin complex is active. Low-resolution solution models of plutonium-loaded transferrins derived from small-angle scattering show that only transferrin with plutonium bound in the protein's C-terminal lobe (C-lobe) and iron bound in the N-terminal lobe (N-lobe) (Pu(C)Fe(N)Tf) adopts the proper conformation for recognition by the transferrin receptor protein. Although the metal-binding site in each lobe contains the same donors in the same configuration and both lobes are similar, the differences between transferrin's two lobes act to restrict, but not eliminate, cellular Pu uptake.     

Comparison of the interactions of transferrin receptor and transferrin receptor 2 with transferrin and the hereditary hemochromatosis protein HFE

The transferrin receptor (TfR) interacts with two proteins important for iron metabolism, transferrin (Tf) and HFE, the protein mutated in hereditary hemochromatosis. A second receptor for Tf, TfR2, was recently identified and found to be functional for iron uptake in transfected cells (Kawabata, H., Germain, R. S., Vuong, P. T., Nakamaki, T., Said, J. W., and Koeffler, H. P. (2000) J. Biol. Chem. 275, 16618-16625). TfR2 has a pattern of expression and regulation that is distinct from TfR, and mutations in TfR2 have been recognized as the cause of a non-HFE linked form of hemochromatosis (Camaschella, C., Roetto, A., Cali, A., De Gobbi, M., Garozzo, G., Carella, M., Majorano, N., Totaro, A., and Gasparini, P. (2000) Nat. Genet. 25, 14-15). To investigate the relationship between TfR, TfR2, Tf, and HFE, we performed a series of binding experiments using soluble forms of these proteins. We find no detectable binding between TfR2 and HFE by co-immunoprecipitation or using a surface plasmon resonance-based assay. The affinity of TfR2 for iron-loaded Tf was determined to be 27 nm, 25-fold lower than the affinity of TfR for Tf. These results imply that HFE regulates Tf-mediated iron uptake only from the classical TfR and that TfR2 does not compete for HFE binding in cells expressing both forms of TfR.     

Biochemical and spectroscopic studies of human melanotransferrin (MTf): electron-paramagnetic resonance evidence for a difference between the iron-binding site of MTf and other transferrins

Melanotransferrin (MTf) is a member of the transferrin (Tf) family of iron (Fe)-binding proteins that was first identified as a cell-surface marker of melanoma. Although MTf has a high-affinity Fe-binding site that is practically identical to that of serum Tf, the protein does not play an essential role in Fe homeostasis and its precise molecular function remains unclear. A Zn(II)-binding motif, distinct from the Fe-binding site, has been proposed in human MTf based on computer modelling studies. However, little is known concerning the interaction of its proposed binding site(s) with metals and the consequences in terms of MTf conformation. For the first time, biochemical and spectroscopic techniques have been used in this study to characterise metal ion-binding to recombinant MTf. Initially, the binding of Fe to MTf was examined using 6M urea gel electrophoresis. Although four different iron-loaded forms were observed with serum Tf, only two forms were found with MTf, the apo-form and the N-monoferric holo-protein, suggesting a single high-affinity site. The presence of a single Fe(III)-binding site was also supported by EPR results which indicated that the Fe(III)-binding characteristics of MTf were unique, but somewhat comparable to the N-lobes of human serum Tf and chicken ovo-Tf. Circular dichroism (CD) analysis indicated that, as for Tf, no changes in secondary structure could be observed upon Fe(III)-binding. The ability of MTf to bind Zn(II) was also investigated using CD which demonstrated that the single high-affinity Fe-binding site was distinct from a potential Zn(II)-binding site.