The chromatographic heterogeneity of rat transferrin on immobilized concanavalin A and lentil lectin

A procedure was developed for the isolation of the microheterogeneous forms of rat transferrin consisting of anion-exchange and serial lectin affinity chromatographies. By deploying this technique, four to five different anionic species of the protein were detected in plasma. The two major components obtained, which encompassed 92-94% of the plasma transferrin, were further studied by sequential lectin chromatography. The larger of the two, representing 60-63% of plasma transferrin, was bound by concanavalin A - Sepharose, while the smaller one (30-32% of plasma transferrin) resolved into an unbound (25-27% of plasma transferrin) and a retarded (4-5% of plasma transferrin) fraction. The latter eluted from the column in a volume which was 1.9 times larger than that required for the passage of nonretarded transferrin. In accordance with their fucose contents, each of these three concanavalin A fractions resolved into a bound (20-29%) and an unbound (71-80%) subfraction by chromatography on lentil-Sepharose. It is concluded that there exist two kinds of glycan microheterogeneity in rat transferrin and that they are unrelated to each other. Consequently, at least six different forms of rat transferrin are available with respect to glycosylation. Epididymal fucosidase cleaved fucose from apotransferrin slowly and from the tryptic glycopeptide rapidly. Exploratory studies performed in vivo failed thus far to identify the significance of fucose in rat transferrin.     

Studies on bovine transferrin; isolation and partial characterization

Bovine serum transferrin (type Tf-A) was isolated by a series of four techniques; (a) precipitation with Rivanol; (b) chromatography of the soluble protein fraction on a column of Sephadex G-150; (c) chromatography of the transferrin containing protein zone on a column of DEAE-Sephadex; and (d) chromatography on a column of DEAE-Sephadex after transferrin was treated with neuraminidase.
It was found that an unidentified protein binds firmly to transferrin, and its removal is only possible after the release of the sialic acid residues with neuraminidase. It is possible that this protein is hemopexin. The occurrence of multiple transferrin components is, in part, dependent on the number of sialic acid residues; possible differences in molecular weight or size seem not to be a factor. The amino acid composition of bovine transferrin, and that of each of three subfractions, resembles that of human transferrin. The calculated mol. wt. of bovine transferrin was found to be 67,000 from sedimentation and viscosity data and 72,400 from sedimentation and diffusion measurements. Sedimentation and viscosity data in concentrated urea suggest that bovine transferrin is composed of two subunits, an observation which is in contrast to data from studies which suggest that human transferrin is composed of a single polypeptide chain.     

DEAE-Affi-Gel Blue chromatography of human serum: use for purification of native transferrin

Human serum was subjected to chromatography on DEAE-Affi-Gel Blue which combines ion-exchange and pseudo-ligand-affinity chromatography in a 0.02 M phosphate buffer, pH 7.0. All serum proteins were bound with the exception of transferrin, IgG (immunoglobulin G) and trace amounts of IgA. After a second step of Sephadex G-100 gel chromatography, or affinity chromatography against goat anti-human IgG F(ab')2 coupled to AH-Sepharose 4B, IgG and IgA were removed. The transferrin obtained was homogeneous and of high yield (greater than 80%), and was unaltered as judged by analyses of molecular weight, isoelectric point, iron-binding capacity, antigenicity, and ability to bind to high-affinity specific cellular receptors. Thus, DEAE-Affi-Gel Blue chromatography may be used as the basis for a simple, rapid, two-step method for the purification of large amounts of native transferrin from serum.     

In vivo behaviour of rat transferrin bearing a hybrid glycan and its interaction with macrophages.

Production of rat transferrin containing a single hybrid glycan was induced by treating rats with swainsonine, an inhibitor of alpha-mannosidase II. The principal component of this variant transferrin containing one sialic acid residue per mole of protein was separated from other forms of transferrin by anion-exchange chromatography, followed by lectin affinity chromatography. Transferrin bearing the hybrid glycan was degraded in vivo with a half-life of 14 h as compared with 40 h for transferrin containing a standard diantennary glycan. By using 125I-labelled tyramine-cellobiose, a label whose discharge from lysosomes is strongly retarded, organs rich in reticuloendothelial elements (liver, bone marrow, lungs, and spleen) were identified as the major sites of catabolism of the transferrin variant. The liver took up more 59Fe from the variant (26% of the dose in 90 min) than from control rat transferrin (12%). The excess iron uptake was reduced by the intravenous injection of either human transferrin or ovalbumin, and it was abolished by administering both. Macrophages from bone marrow and lungs degraded the transferrin variant in vitro. The degradation was significantly enhanced when transferrin receptors were blocked by human transferrin, and it was significantly reduced by ovalbumin and methyl glucopyranoside.     

Purification of transferrin and albumin from mouse ascites fluid

Mouse ascites fluid, which is readily obtained when cell lines and hybridomas are maintained in host mice, is a convenient source of several plasma proteins. This paper describes procedures for the purification of albumin and transferrin from mouse ascites fluid. Mouse transferrin was prepared from a 50-75% ammonium sulfate fraction of mouse ascites fluid by CM- and DEAE-cellulose chromatography. Mouse albumin was obtained by the same purification route, but required an additional chromatography step on Cibacron Blue F3GA-agarose. Both proteins were shown to be homogeneous by polyacrylamide gel electrophoresis and immunoelectrophoresis. Characterization, which included a determination of amino acid composition, partial N-terminal sequence, molecular weight and extinction coefficient, correlated well with known values reported for human transferrin and albumin. The purified mouse proteins may be useful for biochemical studies, antibody preparation, and as growth factors for hybridomas or other mouse cell lines maintained in culture.     

Purification of Transferrin and Albumin from Mouse Ascites Fluid

Mouse ascites fluid, which is readily obtained when cell lines and hybridomas are maintained in host mice, is a convenient source of several plasma proteins. This paper describes procedures for the purification of albumin and transferrin from mouse ascites fluid. Mouse transferrin was prepared from a 50–75% ammonium sulfate fraction of mouse ascites fluid by CM- and DEAE-cellulose chromatography. Mouse albumin was obtained by the same purification route, but required an additional chromatography step on Cibacron Blue F3GA-agarose. Both proteins were shown to be homogeneous by polyacrylamide gel electrophoresis and Immunoelectrophoresis. Characterization, which included a determination of amino acid composition, partial N-terminal sequence, molecular weight and extinction coefficient, correlated well with known values reported for human transferrin and albumin. The purified mouse proteins may be useful for biochemical studies, antibody preparation, and as growth factors for hybridomas or other mouse cell lines maintained in culture.     

Isolation, characterization and N-terminal amino-acid sequence of rabbit transferrin

Rabbit serum transferrin has been isolated and purified by ion-exchange column and high-performance liquid chromatography. The N-terminal amino-acid sequence of 32 residues was determined by automatic Edman degradation in a liquid phase sequenator. Of the first twelve residues sequenced previously three identifications were corrected. Comparison with the known transferrin sequences shows 15 common amino-acid residues. Comparison to human serum transferrin revealed that 37% of amino-acid residues were exchanged. Cys9 and Cys19 which are supposed to be involved in disulphide bridges, are conserved.     

Rapid fractionation of bovine transferrin using immobilized gangliosides.

Bovine transferrin (BTF) was fractionated from bovine whey using ganglioside affinity chromatography. After loading the immobilized matrix with a 2% whey solution, the matrix was washed with sodium acetate buffer at pH 4 containing 1 M NaCl before elution of BTF with sodium phosphate buffers at pH 7. Concanavalin-A affinity and ion exchange chromatography were used for further purification. The ganglioside column showed a 74.2% BTF recovery from whey and BTF was enriched to 61% purity with ion exchange chromatography. Bovine transferrin was identified by SDS-PAGE and western analysis. The Concanavalin-A affinity and ion exchange chromatography steps enriched BTF in the samples and removed other whey proteins from ganglioside purified fractions. These results indicate that immobilized ganglioside can be used to fractionate BTF from bovine whey. Our novel ganglioside affinity chromatography is rapid and efficient for the fractionation of BTF from whey.     

应用转铁蛋白-Sepharose 4 B亲和层析分离浓集小鼠胎肝CFU-E

本文以人血清转铁蛋白与Sepharose 4B交联制成转铁蛋白-Sepharose 4 B亲和层析凝胶,应用转铁蛋白-Sepharose 4 B亲和柱层析分离浓集小鼠胎肝红系造血祖细胞CFU-E。绝大部分CFU-S和CFU-GM均被转铁蛋白-Seph-arose 4 B亲和柱层析洗脱,且转铁蛋白-Seph-arose 4 B柱层析对CFU-S、CFU-GM无明显浓集作用。大部分BFU-E和几乎所有CFU-E均被吸附在亲和层析柱上;经解离吸附洗脱后,BFU-E和CFU-E浓集倍数分别为6.3倍和9.2倍,由此证明了CFU-E细胞膜表面转铁蛋白受体的高度密集性,为今后以转铁蛋白为分子探针,识别和研究CFU-E提供了实验依据。     

The molecular components of human transferrin type C.

Immunologically pure human transferrin type C (TfC) was isolated from the plasmas of 11 individual healthy donors. After conversion into the 2Fe-form, the preparations were analysed by polyacrylamide gel electrophoresis and chromatography on DEAE-cellulose. In all samples studied by either method the presence of three components, designated A, B and C, was observed. Calculations from eight chromatograms yielded the following relative proportions for the components: A:6%, B:62% and C:32%. The quantity of iron bound played no role in this chromatographic resolution. The components were immunologically identical but their sialic acid content increased inthe order of A less than B less than C. The presence of galactose as an ultimate residue of the oligosaccharide chains in TfC component A was confirmed by a biological test. This observation together with the results of earlier analyses for hexose, hexosamine and galactose in the subfractions from Behringwerke human transferrin, suggests that sialic acid is probably the only variable among TfC components A, B and C. Loss of sialic acid from component C during the isolation of TfC was excluded as an explanation for the presence of the other two components. The electrophoretic appearance of TfC samples from five patients with liver disease (chronic active hepatitis, cirrhosis or alcoholic liver) did not noticeably differ from that of TfC FROM HEALTHY PERSONS. Baboon transferrin resembles TfC with respect to sialic acid heterogeneity. This species was therefore studied to decide whether sialic acid is gradually lost from transferrin in the circulation or whether transferrin is not fully sialylated before discharge from the hepatocyte. Using DEAE-cellulose chromatography no difference was found between baboon transferrin molecules which were less than 6h old and those which had a mean age of 8.9 days. By inference it is suggested that the reason for the multiplicity of TfC is also likely to be biosynthetic.     

Purification and characterization of testicular transferrin secreted by rat Sertoli cells.

Sertoli cells synthesize and secrete a transferrin-like protein (testicular transferrin) [Skinner & Griswold (1980) J. Biol. Chem. 255, 1923-1925]. The purpose of the present study was to purify and characterize testicular transferrin and to compare it with serum transferrin. Testicular transferrin was obtained from the medium of cultured rat Sertoli cells, whereas serum transferrin was obtained from rat serum. Both proteins were purified with the use of phenyl-Sepharose hydrophobic chromatography and transferrin immunoaffinity chromatography. The purified proteins were shown to have similar molecular masses (75 000 Da) and amino acid compositions. The pattern of tryptic peptides from testicular and serum transferrin were found to be essentially the same when analysed by reverse-phase high-pressure liquid chromatography. The carbohydrate composition of both transferrins was determined by several colorimetric assays and g.l.c. Testicular transferrin, isolated from cell culture medium, had increased amounts of glucose, galactose and glucosamine. Serum transferrin that was incubated with cell culture medium also had a large amount of associated glucose. The results show that testicular transferrin and serum transferrin are structurally very similar and are possibly products of the same gene expressed in two different tissues, the testis and liver. However, the amount of carbohydrate associated with these two proteins is different.     

Demonstration of the specific binding of bovine transferrin to the human transferrin receptor in K562 cells: evidence for interspecies transferrin internalization

Specific binding of ferric bovine transferrin to the human transferrin receptor was investigated using K562 cells propagated in serum-free medium without transferrin supplemented with 10(-5) elemental iron. Affinity chromatography of solubilized extracts of K562 cells surface-labeled with 125I was performed using bovine transferrin- and human transferrin-Sepharose 4B resins. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of resin eluates reveal that bovine transferrin specifically binds a Mr = 188,000 protein which dissociates into a Mr = 94,000 protein under reducing conditions, a finding identical to what is seen with human transferrin. The Mr = 94,000 reduced protein isolated by bovine transferrin resin shows an identical one-dimensional partial proteolytic digestion map with that of the human transferrin receptor. Unlabeled bovine transferrin was shown to specifically compete 125I-labeled human transferrin from the human transferrin receptor on the surface of K562 cells at 4 degrees C in a similar manner as unlabeled human transferrin; however, approximately a 2,000-fold higher concentration of bovine ligand was required to achieve comparable competition (50% inhibition of binding). Indirect immunofluorescence cytolocalization of bovine transferrin in K562 cells grown in serum-free medium supplemented with ferric bovine transferrin reveal patterns similar to those seen for human transferrin (both focal perinuclear and diffuse cytoplasmic fluorescence). Monensin treatment results in a dramatic accumulation of bovine ligand in perinuclear aggregates, suggesting that it is recycled through the Golgi, as is human transferrin. K562 cells grown in serum-free medium supplemented with either 300 micrograms/ml of ferric human or ferric bovine transferrin were found to demonstrate superimposable growth curves.     

Transferrin glycosylation in hypoxia

The aim of this study was to examine the effect of reduced O2 tension on the glycosylation of transferrin. Rats were placed in a hypobaric chamber (380 mmHg) that corresponded to an altitude of 5486 m above sea level for 21 days. The animals responded with marked increases in hematocrit (from 44 to 76%) and cardiac weight, and with reductions in the concentration of plasma transferrin averaging 15%. Analyses of their plasma transferrin by serial anion-exchange and lectin affinity chromatography revealed no changes in the extent of glycan branching. However, there was a moderate rise in the proportion of fucosylated transferrin molecules (fucosylation index) and a slight decrease in the transferrin fraction bearing a tetrasialylated biantennary glycan. The fucosylation index correlated positively with plasma transferrin concentrations in the test animals, but not in the controls. In contradistinction to the situation with transferrin, hypoxic rats exhibited a reduced fucosylation index of immunoglobulin G.     

Improved purification of the human placental transferrin receptor and a novel immunoradiometric assay for receptor protein

A simplified method for the purification of human placental transferrin receptor is described. The procedure involves chromatography of a detergent extract of placenta on immobilized iron-loaded transferrin. Knowledge of the physiology of the interaction between transferrin and its receptor is applied to enable bound receptor to be eluted under mild conditions and essentially free of containing transferrin. Purified transferrin receptor and a monoclonal antibody to the receptor were used to develop a novel immunoradiometric assay for the receptor in which the monoclonal antibody is the radiolabelled species. A competition between two populations of receptor, one immobilized on a particulate support and the other in solution, provides the basis for the assay. Using this assay we have measured transferrin receptor levels in placental and hepatic tissue and in three cell lines during both the logarithmic and stationary phases of cell growth.     

Identification of the segment for binding of transferrin using a cellular receptor

Methods of proteolysis, radio-immunoblotting and affinity chromatography were used for identifying the human transferrin molecular binding site with cellular receptor. Monoclonal antibody HTF-14 which inhibits binding of the transferrin molecule with the receptor was employed. We showed that this monoclonal antibody has an antigenic determinant of the conformational type which is localized on the COOH-sublobe of the NH2-lobe of the molecule of the transferrin.     

Relationship of the glycan structure of glycoproteins to the desialylation process by rat liver endothelium

To investigate the variations in desialylation of glycoproteins by liver endothelium, we compared endothelial desialylation for 3 glycoproteins, human ceruloplasmin, human and rat transferrin. Radiolabeled glycoproteins were chased through purified rat liver endothelium and then fractionated by lectin affinity chromatography. Endothelium processed glycoproteins were fractionated by RCA120 chromatography into sialylated and desialylated components. The latter was then studied by Con A chromatography. Desialylation occurred only when the molecule contained at least a single triantennary chain of glycan. Desialylation was minimal in the case of human transferrin which contains mostly biantennary branching pattern. Thus, it appears that a single triantennary glycan chain is necessary and sufficient to trigger desialylation of glycoproteins by liver endothelium and this process is an all-or-none phenomenon.     

Primate (Macaca fascicularis) transferrin: isolation and partial characterization

The serum transferrin from the primate, Macaca fascicularis is isolated by a purification protocol consisting of ammonium sulphate precipitation and column chromatography. The hexose (galactose + mannose) content of Macaca transferrin is 4.7 mole per mole of protein. Quantitative determination of the sialic acid content shows that there are two sialic acid residues per molecule of Macaca transferrin. This conclusion is supported by the neuraminidase treatment of Macaca transferrin, in which there is a 2-step decrease in electrophoretic mobility. Monoferric Macaca transferrins with Fe3+ selectively labelled at the C- and N-terminal sites (TfFec and FeNTf) are prepared at pH 5.5 and 8.5 using ferric dinitrilotriacetate [Fe(NTA)2] chelate and ferrous ammonium sulphate, respectively.     

Affibody-mediated transferrin depletion for proteomics applications

An Affibody (Affibody) ligand with specific binding to human transferrin was selected by phage display technology from a combinatorial protein library based on the staphylococcal protein A (SpA)-derived Z domain. Strong and selective binding of the selected Affibody ligand to transferrin was demonstrated using biosensor technology and dot blot analysis. Impressive specificity was demonstrated as transferrin was the only protein recovered by affinity chromatography from human plasma. Efficient Affibody-mediated capture of transferrin, combined with IgG- and HSA-depletion, was demonstrated for human plasma and cerebrospinal fluid (CSF). For plasma, 85% of the total transferrin content in the samples was depleted after only two cycles of transferrin removal, and for CSF, 78% efficiency was obtained in single-step depletion. These results clearly suggest a potential for the development of Affibody-based resins for the removal of abundant proteins in proteomics analyses.     

Proteoglycan synthesis by cultured liver endothelium: the role of membrane-associated heparan sulfate in transferrin binding

Liver endothelium has been reported to possess membrane receptors for the iron-binding protein transferrin (Tf). Similarly, the core protein of proteoglycans (PG) associated with cell membrane in many cell systems can bind Tf. To find out if membrane-associated proteoglycans can explain Tf-binding ability of liver endothelium, we investigated the synthesis and distribution of proteoglycans by isolated, cultured liver capillary endothelium. Cells were isolated and cultured for 48 h in sulfate-free medium and pulse-labeled with 35SO4. The relative distribution of 35SO4-labeled macromolecules, determined in the extracellular (EC), membrane-associated (MA), and intracellular (IC) pools, was respectively 74, 15, and 10%. Membrane-associated proteoglycan (MA-PG) was further purified by ion exchange and gel chromatography. Glycosaminoglycan (GAG) chain characterization indicated about 78% chondroitin sulfate, 7% dermatan sulfate, and about 14% heparan sulfate (HS). Similar GAG chain characterization was made for PG in the EC and IC pools. Transferrin-binding ability of MA-PG was studied by affinity column chromatography, using CNBr-activated sepharose bound to transferrin. About 15% of the labeled MA-PG was specifically bound to Tf-affinity column and could be eluted by excess soluble Tf. This proportion was similar to the proportion of HS in the total membrane-associated pool. Moreover, the eluted labeled material was susceptible to pretreatment with heparitinase, confirming its HS nature. We conclude that the transport capillary endothelium of the liver can synthesize HS proteoglycans which are membrane-associated and this MA-HS pool can bind transferrin. The finding may provide a molecular basis for transferrin binding to liver endothelium and may explain the subsequent transendothelial transport of iron-transferrin complexes into the liver.     

Synthesis of the transferrin receptor by cultures of embryonic chicken spinal neurons

We have purified a glycoprotein from chicken sciatic nerves, sciatin, which has pronounced trophic effects on avian skeletal muscle cells in culture. Recent studies have shown that sciatin is identical to the iron-transport protein, transferrin, in terms of its physicochemical structure, immunological reactivity, and biological activity. To determine whether transferrin is synthesized and released by neuronal tissue, we incubated cultures of dissociated chicken spinal neurons in a medium free of L-leucine containing either L-3H-amino acids or L-[14C]leucine and immunoprecipitated transferrin with highly specific antibodies. The radiolabeled protein precipitated by rabbit heteroclonal, goat heteroclonal, or mouse monoclonal antitransferrin antibodies increased in specific activity in a linear manner for at least 30 min. Synthesis of this protein was abolished by the presence of puromycin (20 micrograms/ml) or cycloheximide (10(-5) M). The disappearance of the radiolabeled protein from cells was linear with a half-life (t 1/2) of 8-10 h. When immunoprecipitates were separated by SDS gel electrophoresis, a prominent band corresponding to transferrin (Mr 84,000) was visualized by staining with Coomassie Blue. However, when such gels were fluorographed, no radioactivity was apparent in the transferrin region of the gel although a prominent radioactive band was visualized at an Mr of 56,000. The protein of Mr 56,000 was not simply a degradation product of transferrin because this particular protein band was not generated by incubating radiolabeled transferrin with unlabeled neuronal homogenates. The protein of Mr 56,000 was purified from embryonic chicken brain and spinal cord by immunoabsorption chromatography on mouse monoclonal antitransferrin IgG conjugated to Sepharose 4B followed by affinity chromatography on immobilized transferrin. The purified protein bound radioiodinated transferrin and was precipitated by rabbit anti-chicken transferrin-receptor antibodies. Furthermore, this receptor protein was found to be localized on the plasma membrane of dorsal root ganglion neurons by immunocytochemistry using the peroxidase-antiperoxidase technique, and by blocking experiments, which showed that antitransferrin receptor IgG could inhibit the binding of fluorescein-conjugated transferrin at 4 degrees C to cultured neurons in vitro. From these data, we conclude that transferrin is not synthesized by cultures of chicken spinal cord neurons, but that the receptor for transferrin is synthesized by these cultures and is precipitated by antitransferrin antibodies as an antigen-receptor complex.