Transferrin-bound and transferrin free iron uptake by cultured rat astrocytes.

Previously we had demonstrated the presence of transferrin receptor (TfR) on the plasma membrane of cultured rat cortical astrocytes. In this study, we investigated the roles of TfR in transferrin-bound iron (Tf-Fe) as well as transferrin-free iron (Fe II) uptake by the cells. The cultured rat astrocytes were incubated with 1 microM of double-labelled transferrin (125I-Tf-59Fe) in serum- free DMEM F12 medium or 59Fe II in isotonic sucrose solution at 37 degrees C or 4 degrees C for varying times. The cellular Tf-Fe, Tf and Fe II uptake was analyzed by measuring the intracellular radioactivity with gamma counter. The result showed that Tf-Fe uptake kept increasing in a linear manner at least in the first 30-min. In contrast to Tf-Fe uptake, the internalization of Tf into the cells was rapid initially but then slowed to a plateau level after 10 min. of incubation. The addition of either NH4Cl or CH3NH2, the blockers of Tf-Fe uptake via inhibiting iron release from Tf within endosomes, decreased the cellular Tf-Fe uptake but had no significant effect on Tf uptake. Pre-treated cells with trypsin inhibited significantly the cellular uptake of Tf-Fe as well as Tf. These findings suggested that Tf-Fe transport across the membrane of astrocytes is mediated by Tf-TfR endocytosis. The results of transferrin-free iron uptake indicated that the cultured rat cortical astrocytes had the capacity to acquire Fe II. The highest uptake of Fe II occurred at pH 6.5. The Fe II uptake was time and temperature dependent, iron concentration saturable, inhibited by several divalent metal ions, such as Co2+, Zn2+, Mn2+ and Ni2+ and not significantly affected by phenylarsine oxide treatment. These characteristics of Fe II uptake by the cultured astrocytes suggested that Fe II uptake is not mediated by TfR and implied that a carrier-mediated iron transport system might be present on the membrane of the cultured cells.     

Intermediate steps in cellular iron uptake from transferrin. II. A cytoplasmic pool of iron is released from cultured cells via temperature-dependent mechanical wounding

Summary A previous study described a cytoplasmic, transferrin (Tf)-free, iron (Fe) pool that was detected only when cells were mechanically detached from the culture substratum at 4°C, after initial incubation with⁵⁹Fe-¹²⁵I-Tf at 37°C (Richardson and Baker, 1992a). The release of this internalized⁵⁹Fe could be markedly reduced if the cells were treated with proteases or incubated at 37°C prior to detachment. The present study was designed to characterize this Fe pool and understand the mechanism of its release. The results show that cellular⁵⁹Fe release increased linearly as a function of preincubation time with⁵⁹Fe-Tf subsequent to mechanical detachment at 4°C using a spatula. These data suggest that the⁵⁹Fe released was largely composed of end product(s) and was not an “intermediate Fe pool.” When the Fe(II) chelator, dipyridyl (DP), was incubated with⁵⁹Fe-Tf and the cells, it prevented the accumulation of⁵⁹Fe that was released following mechanical detachment at 4°C. Other chelators had much less effect on the proportion of⁵⁹Fe released. Examination of the⁵⁹Fe released showed that after a 4-h preincubation with⁵⁹Fe-Tf, approximately 50% of the⁵⁹Fe was present in ferritin. These data indicate that mechanical detachment of cells at 4°C resulted in membrane disruptions that allow the release of high M, molecules. Moreover, electron microscopy studies showed that detachment of cells from the substratum at 4°C resulted in pronounced membrane damage. In contrast, when cells were detached at 37°C, or at 4°C after treatment with pronase, membrane damage was minimal or not apparent. These results may imply that temperature-dependent processes prevent the release of intracellular contents on membrane wounding, or alternatively, prevent wounding at 37°C. The evidence also indicates that caution is required when interpreting data from expriments where cells have been mechanically detached at 4°C.     

Recycling kinetics and transcytosis of transferrin in primary cultures of bovine brain microvessel endothelial cells

Primary cultures of bovine brain microvessel endothelial cells (BMECs) were used to examine the cycling kinetics of ferrotransferrin (Tf) and to provide evidence for a transcytotic pathway in vitro. Binding of 125I-Tf to BMECs grown on matrix-coated plastic was measured in the presence of saponin to calculate the total number of transferrin receptors (TfRs). Nonlinear regression analysis of the binding isotherm showed that there were 100,000 high-affinity receptors per cell and that expression was maximum at cell confluence. Binding of Tf at 4 degrees C indicated that there was a large intracellular receptor pool comprising 85-90% of the total cellular receptors. Accumulation of Tf at 37 degrees C, inhibited at low temperature and in the presence of metabolic poisons, occurred with an initial rate coefficient of 0.030 min-1 and this decreased by 83% after 60 min. Concomitant accumulation of 59Fe from Tf-59Fe was linear. In the absence of externally added ligand, 80% of the accumulated 125I-Tf was released into the medium with a rate coefficient of 0.017 min-1 and this was inhibited at low temperature. In the presence of the weak base primaquine, the accumulation of Tf and 59Fe and the efflux of Tf were decreased. Moreover, phorbol myristate acetate (PMA) caused a 30% increase in surface TfRs and an 82% increase in Tf accumulation, although the size of the recycling pool remained unchanged. Despite the low numbers of TfR expressed by post-confluent cells, filter-grown BMEC monolayers were used to measure transcytosis of Tf. A small portion of the Tf that was accumulated from the apical side entered a transcytotic pathway. Most of the Tf and all of an accumulated fluid-phase tracer were recycled towards the apical side. These results showed that cultured BMECs cycle Tf-TfR complexes slowly and vectorially and suggested that the large intracellular receptor pool may facilitate steady state accumulation and regulate transcellular transport of iron.     

Transferrin and iron distribution in subcellular fractions of K562 cells in the early stages of transferrin endocytosis.

Iron distribution in subcellular fractions was investigated at different times after a single cohort of 59Fe-125 I-labeled transferrin (Tf) endocytosis in K562 cells. Cell homogenates prepared by hypotonic lysis and deoxyribonuclease (DNAase) treatment were fractionated on Percoll density gradients. Iron-containing components in the postmitochondrial supernatant were further fractionated according to their molecular weight using gel chromatography and membrane filtration. In the initial phases of endocytosis, both iron and Tf were found in the light vesicular fraction. After 3 min the labels diverged, with iron appearing in the postmitochondrial supernatant and Tf in the heavy fraction containing mitochondria, lysosomes and nuclei. Iron released from Tf-containing vesicles appeared both in low- and high-molecular-weight fractions in the postmitochondrial supernatant. After 5 min of endocytosis 59Fe activity in the low-molecular-weight fraction remained constant and 59Fe accumulated in a high-molecular-weight fraction susceptible to desferrioxamine chelation. After 10 min, 59Fe radioactivity in this fraction decreased and a majority of cytosolic 59Fe was found in ferritin. These results do not support the concept of the cytosolic low-molecular-weight iron pool as a kinetic intermediate between transferrin and ferritin iron in K562 cells.     

The kinetics of transferrin endocytosis and iron uptake from transferrin in rabbit reticulocytes

The endocytosis of diferric transferrin and accumulation of its iron by freshly isolated rabbit reticulocytes was studied using 59Fe-125I-transferrin. Internalized transferrin was distinguished from surface-bound transferrin by its resistance to release during treatment with Pronase at 4 degrees C. Endocytosis of diferric transferrin occurs at the same rate as exocytosis of apotransferrin, the rate constants being 0.08 min-1 at 22 degrees C, 0.19 min-1 at 30 degrees C, and 0.45 min-1 at 37 degrees C. At 37 degrees C, the maximum rate of transferrin endocytosis by reticulocytes is approximately 500 molecules/cell/s. The recycling time for transferrin bound to its receptor is about 3 min at this temperature. Neither transferrin nor its receptor is degraded during the intracellular passage. When a steady state has been reached between endocytosis and exocytosis of the ligand, about 90% of the total cell-bound transferrin is internal. Endocytosis of transferrin was found to be negligible below 10 degrees C. From 10 to 39 degrees C, the effect of temperature on the rate of endocytosis is biphasic, the rate increasing sharply above 26 degrees C. Over the temperature range 12-26 degrees C, the apparent activation energy for transferrin endocytosis is 33.0 +/- 2.7 kcal/mol, whereas from 26-39 degrees C the activation energy is considerably lower, at 12.3 +/- 1.6 kcal/mol. Reticulocytes accumulate iron atoms from diferric transferrin at twice the rate at which transferrin molecules are internalized, implying that iron enters the cell while still bound to transferrin. The activation energies for iron accumulation from transferrin are similar to those of endocytosis of transferrin. This study provides further evidence that transferrin-iron enters the cell by receptor-mediated endocytosis and that iron release occurs within the cell.     

Iron uptake from transferrin and transferrin endocytic cycle in Friend erythroleukemia cells

Several aspects of iron metabolism were studied in cultured Friend erythroleukemia cells before and after induction of hemoglobin synthesis by dimethyl sulfoxide. The maximal rate of iron uptake from 59Fe-labeled transferrin, 1.5 X 10(6) atoms of Fe/cell per 30 min in uninduced cells, increased to 3 X 10(6) atoms/cell after 5 days of induction. The increase in iron uptake was not accompanied by a proportional increase in the number of transferrin receptors detected by 125I-labeled transferrin binding, suggesting a more efficient iron uptake by transferrin receptors in induced cells, with the rate of about 26 iron atoms per receptor per hour, compared to 15 atoms in uninduced cells. In agreement with this conclusion are results of the study of cellular 125I or 59Fe labeled transferrin kinetics. In the induced cells transferrin endocytosis and release proceeded with identical rates and all the endocytosed iron was retained inside the cell. On the other hand, transferrin release by uninduced cells was significantly slower and a substantial part of internalized 59Fe was released. On the basis of these results, different efficiency of iron release from internalized transferrin, accompanied by changes in cellular transferrin kinetics, is proposed as one of the factors determining the rate of iron uptake by developing erythroid cells.     

The soluble form of the membrane-bound transferrin homologue, melanotransferrin, inefficiently donates iron to cells via nonspecific internalization and degradation of the protein.

Melanotransferrin (MTf) is a membrane-bound transferrin (Tf) homologue found particularly in melanoma cells. Apart from membrane-bound MTf, a soluble form of the molecule (sMTf) has been identified in vitro[Food, M.R., Rothenberger, S., Gabathuler, R., Haidl, I.D., Reid, G. & Jefferies, W.A. (1994) J. Biol. Chem.269, 3034-3040] and in vivo in Alzheimer's disease. However, nothing is known about the function of sMTf or its role in Fe uptake. In this study, sMTf labelled with 59Fe and 125I was used to examine its ability to donate 59Fe to SK-Mel-28 melanoma cells and other cell types. sMTf donated 59Fe to cells at 14% of the rate of Tf. Analysis of sMTf binding showed that unlike Tf, sMTf did not bind to a saturable Tf-binding site. Studies with Chinese hamster ovary cells with and without specific Tf receptors showed that unlike Tf, sMTf did not donate its 59Fe via these pathways. This was confirmed by experiments using lysosomotropic agents that markedly reduced 59Fe uptake from Tf, but had far less effect on 59Fe uptake from sMTf. In addition, an excess of 56Fe-labelled Tf or sMTf had no effect on 125I-labelled sMTf uptake, suggesting a nonspecific interaction of sMTf with cells. Protein-free 125I determinations demonstrated that in contrast with Tf, sMTf was markedly degraded. We suggest that unlike the binding of Tf to specific receptors, sMTf was donating Fe to cells via an inefficient mechanism involving nonspecific internalization and subsequent degradation.     

The effect of the iron saturation of transferrin on its binding and uptake by rabbit reticulocytes.

Polyacrylamide-gel electrophoresis in urea was used to prepare the four molecular species of transferrin:diferric transferrin, apotransferrin and the two monoferric transferrins with either the C-terminal or the N-terminal metal-binding site occupied. The interaction of these 125I-labelled proteins with rabbit reticulocytes was investigated. At 4 degrees C the average value for the association constant for the binding of transferrin to reticulocytes was found to increase with increasing iron content of the protein. The association constant for apotransferrin binding was 4.6 X 10(6)M-1, for monoferric (C-terminal iron) 2.5 X 10(7)M-1, for monoferric (N-terminal iron) 2.8 X 10(7)M-1 and for diferric transferrin, 1.1 X 10(8)M-1. These differences in the association constants did not affect the processing of the transferrin species by the cells at 37 degrees C. Accessibility of the proteins to extracellular proteinase indicated that the transferrin was internalized by the cells regardless of the iron content of the protein, since in each case 70% was inaccessible. Cycling of the cellular receptors may also occur in the absence of bound transferrin.     

Relations between the intracellular pathways of the receptors for transferrin, asialoglycoprotein, and mannose 6-phosphate in human hepatoma cells

We compared the intracellular pathways of the transferrin receptor (TfR) with those of the asialoglycoprotein receptor (ASGPR) and the cation-independent mannose 6-phosphate receptor (MPR)/insulin-like growth factor II receptor during endocytosis in Hep G2 cells. Cells were allowed to endocytose a conjugate of horseradish peroxidase and transferrin (Tf/HRP) via the TfR system. Postnuclear supernatants of homogenized cells were incubated with 3,3'-diaminobenzidine (DAB) and H2O2. Peroxidase-catalyzed oxidation of DAB within Tf/HRP-containing endosomes cross-linked their contents to DAB polymer. The cross-linking efficiency was dependent on the intravesicular Tf/HRP concentration. The loss of detectable receptors from samples of cell homogenates treated with DAB/H2O2 was used as a measure of colocalization with Tf/HRP. To compare the distribution of internalized plasma membrane receptors with Tf/HRP, cells were first surface-labeled with 125I at 0 degrees C. After uptake of surface 125I-labeled receptors at 37 degrees C in the presence of Tf/HRP, proteinase K was used at 0 degrees C to remove receptors remaining at the plasma membrane. Endocytosed receptors were isolated by means of immunoprecipitation. 125I-TfR and 125I-ASGPR were not sorted from endocytosed Tf/HRP. 125I-MPR initially also resided in Tf/HRP-containing compartments, however 70% was sorted from the Tf/HRP pathway between 20 and 45 min after uptake. To study the accessibility of total intracellular receptor pools to endocytosed Tf/HRP, nonlabeled cells were used, and the receptors were detected by means of Western blotting. The entire intracellular TfR population, but only 70 and 50% of ASGPR and MPR, respectively, were accessible to endocytosed Tf/HRP. These steady-state levels were reached by 10 min of continuous Tf/HRP uptake at 37 degrees C. We conclude that 30% of the intracellular ASGPR pool is not involved in endocytosis (i.e., is silent). Double-labeling immunoelectron microscopy on DAB-labeled cells showed a considerable pool of ASGPR in secretory albumin-positive, Tf/HRP-negative, trans-Golgi reticulum. We suggest that this pool represents the silent ASGPR that has been biochemically determined. A model of receptor transport routes is presented and discussed.     

Iron and gallium increase iron uptake from transferrin by human melanoma cells: further examination of the ferric ammonium citrate-activated iron uptake process

Previously we showed that preincubation of cells with ferric ammonium citrate (FAC) resulted in a marked increase in Fe uptake from both (59)Fe-transferrin (Tf) and (59)Fe-citrate (D.R. Richardson, E. Baker, J. Biol. Chem. 267 (1992) 13972-13979; D.R. Richardson, P. Ponka, Biochim. Biophys. Acta 1269 (1995) 105-114). This Fe uptake process was independent of the transferrin receptor and appeared to be activated by free radicals generated via the iron-catalysed Haber-Weiss reaction. To further understand this process, the present investigation was performed. In these experiments, cells were preincubated for 3 h at 37 degrees C with FAC or metal ion solutions and then labelled for 3 h at 37 degrees C with (59)Fe-Tf. Exposure of cells to FAC resulted in Fe uptake from (59)Fe-citrate that became saturated at an Fe concentration of 2.5 microM, while FAC-activated Fe uptake from Tf was not saturable up to 25 microM. In addition, the extent of FAC-activated Fe uptake from citrate was far greater than that from Tf. These results suggest a mechanism where FAC-activated Fe uptake from citrate may result from direct interaction with the transporter, while Fe uptake from Tf appears indirect and less efficient. Preincubation of cells with FAC at 4 degrees C instead of 37 degrees C prevented its effect at stimulating (59)Fe uptake from (59)Fe-Tf, suggesting that an active process was involved. Previous studies by others have shown that FAC can increase ferrireductase activity that may enhance (59)Fe uptake from (59)Fe-Tf. However, there was no difference in the ability of FAC-treated cells compared to controls to reduce ferricyanide to ferrocyanide, suggesting no change in oxidoreductase activity. To examine if activation of this Fe uptake mechanism could occur by incubation with a range of metal ions, cells were preincubated with either FAC, ferric chloride, ferrous sulphate, ferrous ammonium sulphate, gallium nitrate, copper chloride, zinc chloride, or cobalt chloride. Stimulation of (59)Fe uptake from Tf was shown (in order of potency) with ferric chloride, ferrous sulphate, ferrous ammonium sulphate, and gallium nitrate. The other metal ions examined decreased (59)Fe uptake from Tf. The fact that redox-active Cu(II) ion did not stimulate Fe uptake while redox-inactive Ga(III) did, suggests a mechanism of transporter activation not solely dependent on free radical generation. Indeed, the activation of Fe uptake appears dependent on the presence of the Fe atom itself or a metal ion with atomic similarities to Fe (e.g. Ga).     

Effect of iron chelators on the transferrin receptor in K562 cells

Delivery of iron to K562 cells by diferric transferrin involves a cycle of binding to surface receptors, internalization into an acidic compartment, transfer of iron to ferritin, and release of apotransferrin from the cell. To evaluate potential feedback effects of iron on this system, we exposed cells to iron chelators and monitored the activity of the transferrin receptor. In the present study, we found that chelation of extracellular iron by the hydrophilic chelators desferrioxamine B, diethylenetriaminepentaacetic acid, or apolactoferrin enhanced the release from the cells of previously internalized 125I-transferrin. Presaturation of these compounds with iron blocked this effect. These chelators did not affect the uptake of iron from transferrin. In contrast, the hydrophobic chelator 2,2-bipyridine, which partitions into cell membranes, completely blocked iron uptake by chelating the iron during its transfer across the membrane. The 2,2-bipyridine did not, however, enhance the release of 125I-transferrin from the cells, indicating that extracellular iron chelation is the key to this effect. Desferrioxamine, unlike the other hydrophilic chelators, can enter the cell and chelate an intracellular pool of iron. This produced a parallel increase in surface and intracellular transferrin receptors, reaching 2-fold at 24 h and 3-fold at 48 h. This increase in receptor number required ongoing protein synthesis and could be blocked by cycloheximide. Diethylenetriaminepentaacetic acid or desferrioxamine presaturated with iron did not induce new transferrin receptors. The new receptors were functionally active and produced an increase in 59Fe uptake from 59Fe-transferrin. We conclude that the transferrin receptor in the K562 cell is regulated in part by chelatable iron: chelation of extracellular iron enhances the release of apotransferrin from the cell, while chelation of an intracellular iron pool results in the biosynthesis of new receptors.     

Comparison of the kinetics of cycling of the transferrin receptor in the presence or absence of bound diferric transferrin.

The kinetics of cycling of the transferrin receptor in A431 human epidermoid-carcinoma cells was examined in the presence or absence of bound diferric transferrin. In order to investigate the properties of the receptor in the absence of transferrin, the cells were maintained in defined medium without transferrin. It was demonstrated that Fab fragments of a monoclonal anti-(transferrin receptor) antibody (OKT9) did not alter the binding of diferric 125I-transferrin to the receptor or change the accumulation of [59Fe]diferric transferrin by cells. OKT9 125I-Fab fragments were prepared and used as a probe for the function of the receptor. The first-order rate constants for endocytosis (0.16 +/- 0.02 min-1) and exocytosis (0.056 +/- 0.003 min-1) were found to be significantly lower for control cells than the corresponding rate constants for endocytosis (0.22 +/- 0.02 min-1) and exocytosis (0.065 +/- 0.004 min-1) measured for cells incubated with 1 microM-diferric transferrin (mean +/- S.D., n = 3). The cycling of the transferrin receptor is therefore regulated by diferric transferrin via an increase in both the rate of endocytosis and exocytosis. Examination of the accumulation of OKT9 125I-Fab fragments indicated that diferric transferrin caused a marked decrease in the amount of internalized 125I-Fab fragments associated with the cells after 60 min of incubation at 37 degrees C. Diferric transferrin therefore increases the efficiency of the release of internalized 125I-Fab fragments compared with cells incubated without diferric transferrin. These data indicate that transferrin regulates the sorting of the transferrin receptor at the cell surface and within endosomal membrane compartments.     

The role of the transferrin receptor for the activation of human lymphocytes

The proliferative response of peripheral blood mononuclear cells (PBMC) in synthetic serum-free media depends on the presence of sufficient amounts of transferrin (Tf). In the present communication we show that the reduction of Tf concentration in culture media results in a decreased proliferation, whereas lymphokine production and the expression of activation markers (IL-2 receptor; transferrin receptor, (TfR); HLA class II) remain unchanged. To examine whether this effect is due to iron depletion we added iron chelates (ferric citrate, FeCi; ferric nitrilotriacetic acid, FeNTA) which can be internalized by cells without the requirement for Tf. The iron chelates could fully restore the proliferative response even in complete absence of Tf, suggesting that the observed inhibitory effect was indeed caused by iron depletion. Addition of a monoclonal TfR antibody, J 64, also caused a marked inhibition of proliferation of PBMC in regular serum-containing medium as well as in Tf-free synthetic medium; this effect could not be overcome by any of the tested iron chelates. Therefore, growth inhibition caused by J 64 cannot simply be attributed to iron starvation. These data suggest that J 64 may interfere with processes others than iron uptake and that the TfR might confer a necessary promoting signal for lymphocyte proliferation.     

Transferrin uptake and release by reticulocytes treated with proteolytic enzymes and neuraminidase.

The mechanism of transferrin uptake by reticulocytes was investigated using rabbit transferrin labelled with 125I and 59Fe and rabbit reticulocytes which had been treated with trypsin, Pronase or neuraminidase. Low concentrations of the proteolytic enzymes produced a small increase in transferrin and iron uptake by the cells. However, higher concentrations or incubation of the cells with the enzymes for longer periods caused a marked fall in transferrin and iron uptake. This fall was associated with a reduction in the proportion of cellular transferrin which was bound to a cell membrane component solubilized with the non-ionic detergent, Teric 12A9. The effect of trypsin and Pronase on transferrin release from the cells was investigated in the absence and in the presence of N-ethylmaleimide which inhibits the normal process of transferrin release. It was found that only a small proportion of transferrin which had been taken up by reticulocytes at 37 degrees C but nearly all that taken up 4 degrees C was released when the cells were subsequently incubated with trypsin plus N-ethylmaleimide, despite the fact that about 80% of the 59Fe in the cells was released in both instances. Neuraminidase produced no change in transferrin and iron uptake by the cells. These experiments provide evidence that transferrin uptake by reticulocytes requires interaction with a receptor which is protein in nature and that following uptake at 37 degrees C, most of the transferrin is located at a site unavailable to the action of proteolytic enzymes. The results support the hypothesis that transferrin enters reticulocytes by endocytosis.     

Studies on the mechanism of transferrin iron uptake by rat reticulocytes

Mechanism of transferrin iron uptake by rat reticulocytes was studied using ⁵⁹Fe- and ¹²⁵I-labelled rat transferrin. Whereas more than 80% of the reticulocyte-bound ⁵⁹Fe was located in the cytoplasmic fraction, only 25–30% of ¹²⁵I-labelled transferrin was found inside the cells. As shown by the presence of acetylcholine esterase, 10–15% of the cytoplasmic ¹²⁵I-labelled transferrin might have been derived from the contamination of this fraction by the plasma membrane fragments. Electron microscopic autoradiography indicated 26% of the cell-bound ¹²⁵I-labelled transferrin to be inside the reticulocytes. Both the electron microscopic and biochemical studies showed that the rat reticulocytes endocytosed their plasma membrane independently of transferrin. Sepharose-linked transferrin was found to be capable of delivering ⁵⁹Fe to the reticulocytes. Our results suggest that penetration of the cell membrane by transferrin is not necessary for the delivery of iron and that, although it might make a contribution to the cellular iron uptake, internalization of transferrin reflects endocytotic activity of the reticulocyte cell membrane.     

Two mechanisms of iron uptake from transferrin by melanoma cells. The effect of desferrioxamine and ferric ammonium citrate.

The effects of ferric ammonium citrate (FAC) and desferrioxamine (DFO) on iron (Fe), and transferrin (Tf) uptake have been investigated using SK-MEL-28 human melanoma cells, which express the Tf homologue, melanotransferrin, in high concentrations. Previously we demonstrated two separate Fe uptake mechanisms from Tf, viz. a specific process mediated by the transferrin receptor (TfR) and a nonspecific process (Richardson, D. R., and Baker, E. (1990) Biochim. Biophys. Acta 1053, 1-12). Cells exposed to DFO demonstrated up-regulation of the TfR with a concurrent increase in the rate of Fe uptake. Desferrioxamine also stimulated the nonspecific process of Fe uptake, resulting in a further increase in accumulation of Fe over Tf after saturation of the specific TfR. Ferric ammonium citrate had two effects. First, it resulted in down-regulation of the TfR. Second, and paradoxically, it markedly stimulated the rate of Fe uptake from Tf by the nonspecific process without increasing the rate of nonspecific Tf uptake. These data conclusively demonstrate that two entirely different mechanisms of iron uptake from Tf exist in melanoma cells and that ferric ammonium citrate may be a useful experimental tool to further characterize the specific and nonspecific mechanisms of Fe uptake from Tf.     

Brefeldin A enhances receptor-mediated transcytosis of transferrin in filter-grown Madin-Darby canine kidney cells.

The effects of brefeldin A (BFA) on transferrin (Tf) transcellular transport, Tf receptor (TfR) distribution, and TfR-mediated endocytosis in filter-grown Madin-Darby canine kidney (MDCK) cells were studied. BFA (1.6 micrograms/ml) markedly enhanced the transcytosis of 125I-labeled Tf (125I-Tf) in both apical-to-basal and basal-to-apical directions; yet, BFA did not enhance the transcytosis of either native horseradish peroxidase (HRP) or membrane-bound HRP-poly(L-lysine) conjugates. Furthermore, this enhanced transcytosis of 125I-Tf was abolished either by competition with excess unlabeled Tf or by incubation at temperatures less than or equal to 25 degrees C. In addition, BFA treatment to MDCK cells: (a) increased 125I-Tf specific binding to the apical membrane and decreased 125I-Tf specific binding to the basal membrane; (b) decreased TfR recycling at the basolateral membrane; (c) altered the apical/basolateral distribution of TfRs in favor of the apical side; and (d) markedly increased 59Fe extraction, but not transcytosis, from apically endocytosed 59Fe-loaded Tf. These effects are consistent with a model in which BFA alters the traffic pattern of internalized Tf by decreasing basolateral TfR recycling, while diverting the nonrecycled fraction to the apical side of the cell. Our results indicate that, unlike the reported inhibition of polymeric IgA transcytosis (Hunziker, W., Whitney, J. A., and Mellman, I. (1991) Cell 67, 617-627), BFA can enhance the transcytosis of Tf in MDCK cells. Thus, by altering the intracellular traffic of ligand-receptor complexes, BFA can elicit either a decrease or an increase in transcytosis depending on the nature of the intracellular receptor processing.     

Release of iron from endosomes is an early step in the transferrin cycle

Transferrin bound to K 562 cells at 4 degrees C was internalized quickly on temperature shift to 37 degrees C. Endosomes were isolated according to two different procedures. The endosome fraction was shown to be heterogeneous and consisted of two vesicle populations, differing in density properties and iron content. Iron was partially released from endosomes to the supernatant after 3 and 5 min endocytosis. Isolated endosomes, still capable of internal acidification, did not release iron on incubation with ATP. However, endosomes did release iron on incubation with the iron chelator pyridoxal-isonicotinoyl hydrazone. Gel-filtration of solubilized endosomes demonstrated the presence of the transferrin-transferrin receptor complexes, free transferrin and free low molecular weight iron.     

Role of transferrin in iron transport between maternal and fetal circulations of a perfused lobule of human placenta

The transfer of iron between the maternal and fetal circulations of an isolated perfused lobule of term human placenta was investigated using 125I-labelled or 59Fe-labelled diferric transferrin. There was negligible transplacental transfer of intact transferrin whereas nearly 4 per cent of the added 59Fe was transferred into the fetal circulation after 2 h, where it became associated with fetal transferrin. Over 20 per cent of the added 59Fe radioactivity was sequestered within the placental tissue during this period, associated with transferrin, ferritin and other uncharacterized molecules. This suggests an important role for an intracellular pool in regulating transfer. The presence of 10 mM chloroquine in the maternal circulation substantially reduced tissue accumulation of 59Fe and totally inhibited transfer to the fetus. It is concluded that the initial stages of iron transfer to the fetus involve the internalization of maternal iron-saturated transferrin bound to membrane receptors by receptor-mediated endocytosis, which can be inhibited by the drug chloroquine. Subsequently, the transplacental transfer of iron to the fetus does not involve the concomitant movement of transferrin.     

The uptake of inorganic iron complexes by human melanoma cells

The human melanoma cell line, SK-MEL-28, expresses high levels of melanotransferrin. The uptake of inorganic iron (Fe) complexes compared to transferrin-bound Fe by these cells has been investigated to determine whether melanotransferrin has a role in Fe uptake. The mechanisms of Fe uptake have been characterised using 59Fe complexes of citrate, nitrilotriacetate, desferrioxamine, and 59Fe added to Eagle's minimum essential medium (MEM) and compared with human transferrin (Tf) labelled with 59Fe and iodine-125. Iron uptake from the Fe complexes of citrate, nitrilotriacetate and MEM were similar, and far greater than that from Tf at the same Fe concentration (2.5 microM). Ammonium chloride and a monoclonal antibody to the transferrin receptor (42/6), had no effect on the uptake of Fe from inorganic Fe complexes, suggesting that receptor-mediated endocytosis of Tf was not involved. The monoclonal antibody, 96.5, specific for melanotransferrin did not alter total Fe uptake but slightly increased the proportion of Fe internalised, possibly due to the modulation of the antigen by the antibody. However, from the time required for modulation to occur (approximately 2 h), the small increase in internalisation observed and the fact that no increase in total cell Fe occurred, it is suggested that melanotransferrin has little role in Fe uptake.