Human T lymphotropic virus I infection deregulates surface expression of the transferrin receptor

Human T-lymphotropic virus I (HTLV-I) is an etiologic agent in adult T cell leukemia. In an effort to understand the relationship between HTLV-I infection and malignant transformation, we have examined transferrin receptor expression in HTLV-I-infected cells. Transferrin receptor expression in normal T cells is tightly regulated and essential for cell proliferation. We have used matched T cell sets originating from a normal donor, consisting of tetanus toxoid-specific normal T cell clones (TM3 and TM5) and their in vitro HTLV-I-infected counterparts (TM3H and TM5H). Using these matched sets of virus-infected and normal T cells, we have determined that HTLV-I infection leads to hyperexpression of surface transferrin receptors (five- to six-fold higher than normal counterparts). Although the growth rates of the virus-infected cells did not differ significantly from their normal controls, HTLV-I-infected cells constitutively hyperexpressed surface transferrin receptors, whereas the level of surface receptor expression of normal counterpart cells varied during the cycle of antigenic stimulation. Immunoprecipitation of total (surface plus cytoplasmic) transferrin expression showed that the HTLV-I-infected cells did not possess a greater total number of transferrin receptors than their normal counterparts. This data was supported by Northern blot analysis, which showed equivalent transferrin receptor mRNA expression in HTLV-I-infected and uninfected cells. Functional analysis revealed a marked defect in 59Fe-transferrin internalization in the HTLV-I-infected cells. Furthermore, the HTLV-I-infected cells showed markedly decreased transferrin receptor phosphorylation and internalization in response to active phorbol ester. Thus the data demonstrate that in peripheral blood T cells, HTLV-I infection is accompanied by surface transferrin receptor overexpression secondary to subcellular redistribution and defective internalization.     

Regulation of transferrin receptor expression in concanavalin A stimulated and Gross virus transformed rat lymphoblasts

Expression of the cell surface receptor for the serum glycoprotein transferrin has been correlated with cellular proliferation in normal lymphocytes undergoing mitogen or antigen induced proliferative responses. In the present study, the expression of transferrin receptor in Concanavalin A stimulated rat lymphocytes or Gross virus transformed lymphoma cells has been examined with respect to the following questions: (1) is expression of receptor activity related to blastogenesis or to the subsequent IL-2 dependent DNA synthetic activity, and (2) is transferrin receptor expression regulated in similar fashion in both normal and malignant lymphoblasts? Scatchard analysis of saturation binding data illustrated that binding site number increased and subsequently decreased during the response while the receptor affinity for transferrin remained constant. These findings were confirmed by SDS-polyacrylamide gel electrophoretic analysis of radiolabeled cell surface proteins which specifically interact with transferrin. Examination of nonproliferating normal lymphoblasts (96 hr post Con A stimulation) compared with the same population of cells stimulated to reinitiate DNA synthesis with a partially purified preparation of Interleukin 2 (IL-2) showed that transferrin receptor expression was tightly linked to the IL-2 dependent stimulation of DNA replication. This coordinate regulation of receptor expression was markedly less stringent in retrovirus transformed thymic lymphoma cells.     

Heme regulation of HeLa cell transferrin receptor number

The number of diferic transferrin receptors on HeLa cells decreases when cells are grown in iron-supplemented media. The experiments reported here suggest that heme is the iron-containing compound which serves as the signal for receptor number regulation. When HeLa cells were grown in the presence of hemin, transferrin receptor number decreased to a greater degree than when cells were grown in equivalent amounts of iron supplied as ferric ammonium citrate. Incubation of cells in conditions which increased cellular heme content resulted in a decrease in cellular transferrin receptors. Incubating cells with 5-aminolevulinic acid (thus bypassing the rate-limiting step in heme biosynthesis, 5-aminolevulinic acid synthase) led to a decrease in transferrin receptor number. Incubation of cells with an inhibitor of heme oxygenase, Sn-protoporphyrin IX, also led to a decrease in transferrin receptor number. When cellular heme content was decreased by inhibiting heme synthesis with succinylacetone (an inhibitor of 5-aminolevulinic acid dehydratase), or by depriving cells of iron with deferoxamine, an increase in HeLa cell transferrin receptor number was seen. When HeLa cells were incubated with inducers of heme oxygenase (CoCl2, SnCl2, Co-protoporphyrin IX), transferrin receptor number also increased. The effects of all compounds which alter transferrin receptor number were dependent on the concentration of the supplement, as well as the duration of the supplementation. These experiments suggest that intracellular heme content may be an important signal controlling transferrin receptor number.     

Plasma membrane and intracellular pools of transferrin receptors decline during in vitro cultivation of U937 cells

Transferrin receptor expression in the monocyte-like cell line U937 was investigated during in vitro cultivation. U937 cells expressed a single class of high affinity surface transferrin receptors (KD approximately 4 nM), with apparent subunit Mr of 90-95,000 Da as determined by SDS-reducing PAGE. [125I]-transferrin binding studies on detergent-solubilized cells revealed that half to two-thirds of the total functional binding sites were located intracellularly. Radioligand binding, immunofluorescence and flow cytometry studies were performed on intact, detergent-solubilized, or saponin-permeabilized cells, using either transferrin or the anti-transferrin receptor monoclonal antibody OKT9 IgG. These studies demonstrated that functional and antigenic transferrin receptor levels were maximal on cells 24 h after subculture at low density and declined during the culture period. Scatchard analysis of radioligand binding data suggested that the decline in functional transferrin binding sites resulted from a decline in the number of available receptors. These results demonstrate that in U937 cells there is a density-dependent regulation of transferrin receptor expression, resulting in a loss of functional and antigenic receptors from both plasma membrane and intracellular locations.     

Effect of aluminium on iron uptake and transferrin-receptor expression by human erythroleukaemia K562 cells.

Incubation of human erythroleukaemia K562 cells with Al-transferrin inhibited iron uptake from 59Fe-transferrin by about 80%. The inhibition was greater than that produced by a similar quantity of Fe-transferrin. Preincubation of cells for 6 h with either Al-transferrin or Fe-transferrin diminished the number of surface transferrin receptors by about 40% compared with cells preincubated with apo-transferrin. Al-transferrin did not compete significantly with Fe-transferrin for transferrin receptors and, when cells were preincubated for 15 min instead of 6 h, the inhibitory effect of Al-transferrin on receptor expression was lost. Both forms of transferrin also decreased the level of transferrin receptor mRNA by about 50%, suggesting a common regulatory mechanism. Aluminium citrate had no effect on iron uptake or transferrin-receptor expression. AlCl3 also had no effect on transferrin-receptor expression, but at high concentration it caused an increase in iron uptake by an unknown, possibly non-specific, mechanism. Neither Al-transferrin nor AlCl3 caused a significant change in cell proliferation. It is proposed that aluminium, when bound to transferrin, inhibits iron uptake partly by down-regulating transferrin-receptor expression and partly by interfering with intracellular release of iron from transferrin.     

Effects of epidermal growth factor on transferrin receptor phosphorylation and surface expression in malignant epithelial cells

The transferrin (Tf) receptor is a major transmembrane protein which provides iron for normal and malignant cell growth. Epidermal growth factor (EGF) has been reported to rapidly and transiently alter the number of surface Tf receptors in normal and transformed epithelial cells. To investigate mechanisms of EGF-induced changes in surface Tf display, EGF effects on surface Tf receptors were compared in two cell lines which differ in their number of EGF receptors and growth responses to EGF. In cloned A431 cells with high receptor numbers which are growth-inhibited by EGF, EGF caused a 50% decrease in Tf receptor expression after 30 min. In contrast, EGF induced a rapid, transitory increase (within 5 min) in the number of surface Tf receptors on KB carcinoma cells which returned to basal levels by 15 min. The observed changes in Tf receptor display were due to altered receptor distribution and not changes in ligand affinity or total cellular transferrin receptor pools. Anti-EGF receptor monoclonal antibody blocked effects of EGF on transferrin receptor expression. Since the antibody is internalized and causes EGF receptor down-regulation, effects on transferrin receptor expression were independent of these events. EGF-induced alterations in Tf receptor display occurred even when cells were pretreated with colchicine, suggesting that changes in surface Tf binding were not mediated by cytoskeletal components. Na orthovanadate, which mimics some early cellular effects of EGF, duplicated EGF's effects on A431 Tf receptors, but had no effect on KB cells, suggesting these responses occur by differing mechanisms. To determine whether EGF caused changes in Tf receptor phosphorylation, 32P-labelled Tf receptors were immunoprecipitated after EGF treatment. After exposure to EGF, A431 cells showed no change in Tf phosphorylation, but KB cells showed a transient, 6-fold increase in transferrin receptor phosphorylation on serine residues. In both A431 and KB cells, phorbol ester (PMA) also increased phosphorylation on transferrin receptors, but had little effect on surface Tf receptor expression. In malignant cell lines, EGE induces rapid, variable changes in transferrin receptor expression and phosphorylation which differ from the effects of PMA. These early responses to EGF appear to differ with the cell type and correlate poorly with alterations in Tf receptor phosphorylation. These results suggest Tf receptor phosphorylation does not regulate Tf receptor display in all cells.     

Improvement of MRI probes to allow efficient detection of gene expression

Recently, it has been demonstrated that magnetic resonance imaging (MRI) utilizing monocrystalline iron oxide nanoparticles (MIONs) targeted to an engineered transferrin receptor enables imaging of gene expression. However, the relatively high doses of iron oxides used indicated the need for improved MR imaging probes to monitor changes in gene expression in vivo. Using alternative conjugation chemistries to link targeting ligands and iron oxide nanoparticles, we present the development and characterization as well as improved receptor binding and MRI detection of a novel imaging probe. Iron oxide nanoparticles with a cross-linked dextran coat were conjugated to transferrin (Tf) through the linker molecule N-succinimidyl 3-(2-pyridyldithio)propionate (SPDP) to yield Tf-S-S-CLIO. The characteristics of this conjugate were evaluated in comparison to Tf-MION and Tf-CLIO generated by oxidative activation of the dextran-coat with subsequent reduction of Schiff's base. SPDP conjugation allowed approximately a 4-fold increase in the number of Tf molecules attached per iron oxide nanoparticle and resulted in a more than 10-fold improvement of binding and uptake by cells. This translated into an imaging probe that was 16 times better for imaging gene expression in a cellular MRI assay. This novel probe for MRI may substantially increase the sensitivity for the detection of endogenous or genetically induced transferrin receptor expression in small numbers of cells and may significantly reduce the imaging dose from over 100 mg/kg to doses of iron oxides that are currently used in clinical imaging.     

Insulin-like growth factor I and epidermal growth factor regulate the expression of transferrin receptors at the cell surface by distinct mechanisms

The transferrin receptor cycles rapidly between cell surface and endosomal membrane compartments. Treatment of cultured cells with epidermal growth factor (EGF) or insulin-like growth factor I (IGF-I) at 37 degrees C causes a rapid redistribution of transferrin receptors from an intracellular compartment to the cell surface. The effects of EGF and IGF-I on the kinetics of the cycling of the transferrin receptor in A431 human epidermoid carcinoma cells were compared. The primary site of EGF action was found to be an increase in the rate of transferrin receptor exocytosis. The exocytotic rate constant was measured to be 0.11 min-1 in control cells and 0.33 min-1 in EGF-treated cells. In contrast, IGF-I was found to increase the cell surface expression of transferrin receptors by causing a small increase in the rate of exocytosis (from 0.11 to 0.17 min-1) and a decrease in the rate of endocytosis (from 0.33 to 0.24 min-1). It is concluded that the mechanisms for EGF and IGF-I action to increase the cell surface expression of the transferrin receptor are distinct. A kinetic model of the cycling of the transferrin receptor based on experimentally determined rate constants is presented. The model predicts that a consequence of IGF-I action on transferrin receptor cycling is to decrease the apparent Km for the uptake of diferric transferrin by cells. This prediction is confirmed by direct measurement of the accumulation of 59Fe-labeled diferric transferrin by A431 cells. These data demonstrate that the accumulation of iron by cultured cells is a complex function of the rate of cycling of the transferrin receptor and that this process is under acute regulation by growth factors.     

地衣霉素对细胞膜表面运铁蛋白受体功能的影响

应用抑制糖蛋白Ｎ－糖链合成的地衣霉素处理ＳＭＭＣ－７７２１人肝癌细胞,３Ｈ甘露糖掺入实验显示细胞膜表面糖蛋白Ｎ－糖链的合成受到显著抑制,但细胞膜表面运铁蛋白受体内吞再循环的过程无显明变化,进一步的研究表明受体与运铁蛋白的亲和力亦无改变,但细胞膜表面运铁蛋白受体数减少。结果提示用地衣霉素处理细胞后,在内质网合成的无Ｎ－糖链的运铁蛋白受体影响其运输到细胞膜表面表达。     

The role of the transferrin receptor in human B lymphocyte activation

Transferrin receptors are expressed on proliferating cells and are required for their growth. Transferrin receptors can be detected after, but not before, mitogenic stimulation of normal peripheral blood T and B cells. T cells demonstrate a functional requirement for transferrin receptors in the activation process. These receptors, in turn, are induced to appear by T cell growth factor (interleukin 2). In the experiments reported here, we examined the regulation of transferrin receptor expression on activated human B cells and whether these receptors are necessary for activation to occur. Activation was assessed by studying both proliferation and immunoglobulin secretion. We determined that transferrin receptor expression on B cells is regulated by a factor contained in supernatants of mitogen-stimulated T cells (probably B cell growth factor). This expression is required for proliferation to occur, because antibody to transferrin receptor (42/6) blocks B cell proliferation. Induction of immunoglobulin secretion, however, although dependent on phytohemagglutinin-treated T cell supernatant, is not dependent on transferrin receptor expression and can occur in mitogen-stimulated cells whose proliferation has been blocked by anti-transferrin receptor antibody. These findings support a model for B cell activation in which mitogen (or antigen) delivers two concurrent but distinct signals to B cells: one, dependent on B cell growth factor and transferrin receptor expression, for proliferation; and a second, dependent on T cell-derived factors and not requiring transferrin receptors, which leads to immunoglobulin secretion.     

Regulation of HeLa cell transferrin receptors

HeLa cells were found to have a single class of non-interacting receptors specific for transferrin. Both apotransferrin and diferric transferrin competed equally with 125I-diferric transferrin for receptor binding. Transferrin binding was temperature-dependent and reversible. Binding of transferrin to cells exhibited a KD of 27 nM with a maximum binding capacity of 1.8-3.7 x 10(6) molecules/cell. Cells grown in the presence of diferric transferrin or in the presence of ferric ammonium citrate exhibited a concentration- and time-dependent decrease in 125I-diferric transferrin binding. The decrease in binding activity reflected a reduction in receptor number rather than an alteration in ligand receptor affinity. Growth of cells in saturating concentrations of apotransferrin did not cause a decrease in receptor number. When iron-treated cells were removed to media free of ferric ammonium citrate, the receptor number returned to control values by 40 h. When receptors were removed with trypsin, cells grown and maintained in ferric ammonium citrate-supplemented media demonstrated a rate of receptor reappearance 47% that of control cells grown in ferric ammonium citrate-free media. Cells grown in media supplemented with diferric transferrin or ferric ammonium citrate exhibited an increase in cytosolic iron content. The transferrin receptor number returned to normal after cells were removed to unsupplemented media, despite persistent elevation of cytosolic iron content. Increased iron content did not appear to be the sole factor determining receptor number.     

Inhibition of the receptor-mediated endocytosis of diferric transferrin is associated with the covalent modification of the transferrin receptor with palmitic acid

The human transferrin receptor is post-translationally modified by the covalent attachment of palmitic acid to Cys62 and Cys67 via a thio-ester bond. To investigate the role of the acylation of the transferrin receptor, Cys62 and Cys67 were substituted with serine and alanine residues. The properties of the mutant receptors were compared with wild-type receptors after expression in Chinese hamster ovary cells that lack endogenous transferrin receptors. Rapid incorporation of [3H]palmitate into the wild-type transferrin receptor was observed, but the mutant receptors were found to be palmitoylation-defective. The kinetics of endocytosis and recycling of the wild-type and mutant receptors were compared. It was observed that the rate of endocytosis of the palmitoylation-defective transferrin receptors was significantly greater than the rate measured for the wild-type transferrin receptor. In contrast, the mutation of Cys62 and Cys67 was found to have no significant effect on the rate of transferrin receptor recycling. Consistent with these observations, it was found that cells expressing palmitoylation-defective transferrin receptors exhibited an increased rate of accumulation of [59Fe]diferric transferrin. Together, these data indicate that the palmitoylation of the transferrin receptor is associated with an inhibition of the rate of transferrin receptor endocytosis. Addition of insulin to cultured cells causes an increase in the palmitoylation of cell surface transferrin receptors and a decrease in the rate of transferrin receptor internalization. It was observed that the effect of insulin to inhibit the endocytosis of the acylation-defective [Ala62 Ala67]transferrin receptor was attenuated in comparison with the wild-type receptor. The decreased effectiveness of insulin to inhibit the internalization of the acylation-defective transferrin receptor is consistent with the hypothesis that palmitoylation represents a potential mechanism for the regulation of transferrin receptor endocytosis.     

Intermolecular disulfide bonds are not required for the expression of the dimeric state and functional activity of the transferrin receptor.

The human transferrin receptor is expressed as a disulfide-linked dimer at the cell surface. The sites of intermolecular disulfide bonds are Cys-89 and Cys-98. We have examined the functional significance of the covalent dimeric structure of the transferrin receptor by substitution of Cys-89 and Cys-98 with serine residues. Wild-type and mutated transferrin receptors were expressed in Chinese hamster ovary cells (clone TF-) that lack detectable endogenous transferrin receptors. The rates of receptor endocytosis and recycling were measured and the accumulation of iron by cells incubated with [59Fe]diferric transferrin was investigated. No significant differences between these rates were observed when cells expressing wild-type and mutated receptors were compared. The structure of the mutant receptor lacking intermolecular disulfide bonds was investigated. The presence of a population of mutant receptors with a non-covalent dimeric structure was indicated by cross-linking studies using diferric [125I]transferrin and the bifunctional reagent disuccinimidyl suberimidate. However, sucrose density gradient sedimentation analysis of Triton X-100 solubilized transferrin receptors demonstrated that the mutant receptor existed as a monomer in the absence of diferric transferrin and as an apparent dimer in the presence of this receptor ligand. We conclude that the covalent dimeric structure of the transferrin receptor is not required for the expression of the dimeric state and functional activity of the receptor.     

Transferrin receptor expression during exponential and plateau phase growth of human tumour cells in culture

Transferrin receptor expression by the human tumour cell lines CCRF-CEM leukaemia and PMC-22B melanoma was studied, measuring the specific binding of fluorescein isothiocyanate (FITC)-labelled transferrin using a fluorescence-activated cell sorter. By measuring the fluorescence of cells stained at subsaturating concentrations of conjugate it was possible to calculate the average numbers of receptors per cell and the binding affinity by Scatchard analysis. These values (1.9 × 10⁵ binding sites/cell, K^A 1.2 × 10⁹ M^?1 for CCRF-CEM during exponential growth and 6.9 × 10⁴ binding sites/cell, K_A 1.4 × 10^?9 M^?1 for PMC-22B) are in close agreement with previously published data obtained using radiolabelled transferrin. The present method, however, allowed the transferrin receptor expression of individual cells within a population to be measured and thus it has been possible to test the hypothesis that transferrin receptor is a marker for cycling cells. Frequency-distribution histograms of transferrin receptor showed a wide range of values for both cell lines during exponential growth. When the extreme ranges were sorted and the cells examined for cellular DNA content it was found that those with the highest transferrin receptor expression were enriched with cells in S, G₂, and M phases of the cell cycle, whereas those with low transferrin receptor expression were mainly in G₁. However, two-parameter-correlated dot plots of transferrin receptor expression versus DNA content showed there was considerable overlap between the ranges of receptor expression for the different cell cycle compartments. Using a stathmokinetic method we have measured the proportion of quiescent cells in fed plateau phase cultures. Transferrin receptor expression was downgraded under these growth conditions but, contrary to expectation, the decline affected the population uniformly, without the emergence of a distinct, transferrin receptor-negative subpopulation corresponding to the increasing proportion of quiescent cells. Thus, although transferrin receptor expression bears some relation to cell cycle phase and reflects the proliferative activity of populations of cells, it is incapable of identifying individual cells which are out of cycle.     

The p97 antigen is mapped to the q24-qter region of chromosome 3; the same region as the transferrin receptor.

Since the p97 antigen, a membrane-associated iron-binding protein, has extensive amino acid sequence with homology with transferrin, is functionally related to the transferrin receptor, and has been previously mapped to chromosome 3, we have performed additional studies for regional mapping of the gene expressing p97 antigen. In these experiments, Chinese hamster-human cell lines were chosen that contained a large spectrum of autosomal human chromosomes, but mainly consisted of clones expressing all or a part of chromosome 3. These cell lines included a clone that previously allowed for mapping of human transferrin receptor to q22-qter region. Human p97 expression was assessed by specific binding of [125I]monoclonal antibody 96.5, and human transferrin receptor expression was tested by specific [125I]human transferrin binding and [125I]monoclonal antibody OKT-9 specific for human transferrin receptor. Based on these analyses, both human p97 antigenic expression and human transferrin receptor are mapped concordantly to the q24-qter region. These data and previous reports, therefore, suggest that the related iron-transport proteins are closely linked and may be under coordinate regulation. However, studies of several cell lines that exhibit up-regulation of human transferrin receptor expression with cellular proliferation, and down-regulation of receptor with increased transferrin-iron in the media, showed no change in expression of p97 antigen. p97 antigenic expression increased when melanocyte-stimulating hormone was added to a human melanoma cell line in tissue culture. These latter studies suggest that in mammalian cells the two proteins do not show coordinate regulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Insulin stimulates cellular iron uptake and causes the redistribution of intracellular transferrin receptors to the plasma membrane

Insulin stimulates the accumulation of iron by isolated fat cells by increasing the uptake of diferric transferrin. Analysis of the cell-surface binding of diferric 125I-transferrin indicated that insulin caused a 3-fold increase in the cell surface number of transferrin receptors. This result was confirmed by the demonstration that insulin increases the binding of an anti-rat transferrin receptor monoclonal antibody (OX-26) to the surface of fat cells. The basis of this effect of insulin was examined by investigating the number of transferrin receptors in membrane fractions isolated from disrupted fat cells. Two methods were employed. First the binding isotherm of diferric 125I-transferrin to the isolated membranes was studied. Second, the membranes were solubilized with detergent, and the number of transferrin receptors was measured by immunoblotting using the monoclonal antibody OX-26. It was observed that insulin treatment of intact fat cells resulted in an increase in the number of transferrin receptors located in the isolated plasma membrane fraction of the disrupted fat cells. Furthermore, the increase in the number of plasma membrane transferrin receptors was associated with a concomitant decrease in the transferrin receptor number in a low density microsome fraction previously shown to consist of intracellular membranes. This redistribution of transferrin receptors between cellular membrane fractions in response to insulin is remarkably similar to the regulation by insulin of glucose transporters and type II insulin-like growth factor receptors. We conclude that insulin stimulates fat cell iron uptake by a mechanism that may involve the redistribution of transferrin receptors from an internal membrane compartment (low density microsomes) to the cell surface (plasma membrane).     

Co-migration and internalization of transferrin and its receptor on K562 cells

The incorporation of iron into human cells involves the binding of diferric transferrin to a specific cell surface receptor. We studied the process of endocytosis in K562, a human erythroid cell line, by using tetramethylrhodamine isothiocyanate-labeled transferrin (TRITC- transferrin) and fluorescein isothiocyanate-labeled Fab fragments of goat antireceptor IgG preparation (FITC-Fab-antitransferrin receptor antibody). Because the antireceptor antibody and transferrin bind to different sites on the transferrin receptor molecule it was possible to simultaneously and independently follow ligand and receptor. At 4 degrees C, the binding of TRITC-transferrin or FITC-Fab antitransferrin receptor antibody exhibited diffuse membrane fluorescence. At 20 degrees C, the binding of TRITC-transferrin was followed by the rapid formation of aggregates. However, the FITC-Fab antitransferrin receptor did not show similar aggregation at 20 degrees C unless transferrin was present. In the presence of transferrin, the FITC-Fab antitransferrin receptor antibody formed aggregates at the same sites and within the same time period as TRITC transferrin, indicating co-migration. Although the diffuse surface staining of either label was removed by proteolysis, the larger aggregates were not susceptible to enzyme degradation, indicating that they were intracellular. The internal location of the aggregates was also demonstrated using permeabilized cells that had been preincubated with transferrin and fixed with 4% paraformaldehyde. These cells showed aggregated receptor in the interior of the cell when reacted with fluorescein-labeled antibody to the receptor. This indicated that the transferrin and the transferrin receptor co-internalize and migrate to the same structures within the cell.     

3'-Azido-3'-deoxythymidine reduces the rate of transferrin receptor endocytosis in K562 cells.

K562 cells, exposed for at least 24 h to 5 microM 3'-azido-3'-deoxythymidine (AZT), gave rise to an overall increase in the number of cell surface transferrin binding receptors (18-20%). This effect was ascertained either with binding experiments by using 125I-transferrin and with immunoprecipitation by using a specific monoclonal antibody against the transferrin receptor. At higher AZT concentrations (20 and 40 microM), a further increase was found, that is, up to 23% by binding experiments and up to 110% by immunoprecipitation. However, Scatchard analysis of the binding data indicated that although the number of cell surface transferrin receptors increased, the affinity of transferrin for its receptor did not change (Ka=4.0x108 M). Surprisingly, immunoprecipitation of total receptor molecules showed that the synthesis of receptor was not enhanced by the drug treatment. The effect of AZT on transferrin internalization and receptor recycling was also investigated. In this case, data indicated that the increase in the number of receptors at the cell surface was probably due to a slowing down of endocytosis rate rather than to an increased recycling rate of the receptor to cell surface. In fact, the time during which half the saturated amount of transferrin had been endocytosed (t1/2) was 2.15 min for control cells and 3.41, 3.04, and 3.74 min for 5, 20, and 40 microM AZT-treated cells, respectively. Conversely, recycling experiments did not show any significant differences between control and treated cells. A likely mechanism through which AZT could interfere with the transferrin receptor trafficking, together with the relevance of our findings, is extensively discussed.     

Characterization of the human transferrin receptor produced in a baculovirus expression system

Recombinant human transferrin receptor has been produced in a baculovirus expression system. Magnetic particles coated with an anti-transferrin receptor monoclonal antibody were used to immunoselect virus-infected Sf9 insect cells expressing the human transferrin receptor on their cell surface. Recombinant virus containing the human transferrin receptor cDNA was then plaque-purified from these cells. Biosynthetic labeling studies of infected cells showed that the human transferrin receptor is one of the major proteins made 2-3 days postinfection. The recombinant receptor made in insect cells is glycosylated and is also posttranslationally modified by the addition of a fatty acid moiety. However, studies with tunicamycin and endoglycosidases H and F showed that the oligosaccharides displayed on the recombinant receptor differ from those found on the naturally occurring receptor in human cells. As a consequence, the human receptor produced in the baculovirus system has an Mr of 82,000 and is smaller in size than the authentic receptor. About 30% of human transferrin receptors made in insect cells do not form intermolecular disulfide bonds, but are recognized by the anti-transferrin receptor antibody, B3/25, and bind specifically to a human transferrin-Sepharose column. Binding studies using 125I-labeled human transferrin showed that insect cells infected with the recombinant virus expressed an average of 5.8 +/- 0.9 X 10(5) transferrin receptors (Kd = 63 +/- 9 nM) on their cell surface. Thus, the human transferrin receptor produced in insect cells is biologically active and appears suitable for structural and functional studies.