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.     

Cell-associated proteoheparan sulfate mediates binding and uptake of thrombospondin in cultured porcine vascular endothelial cells.

[125I]Thrombospondin (TSP) binds to porcine endothelial cells in a specific, saturable and time-dependent fashion and is endocytosed by a receptor-mediated process. The N-terminal heparin-binding domain is necessary for the interaction with the cell surface. Binding and uptake is inhibited by heparin and to a much smaller extent by other vascular glycosaminoglycans. Chemical modification of lysine and arginine residues of TSP, but not treatment of the molecule with neuraminidase, resulted in a pronounced loss of binding at the cell surface. Treatment of cells with heparitinase but not with chondroitin ABC lyase caused inhibition of binding and uptake of TSP. Inhibition of sulfation of proteoglycans on the cell surface by chlorate leads to a dose and time-dependent inhibition of binding and degradation of TSP. In the presence of chlorate, newly synthesized TSP is not incorporated into the cell matrix but mainly released into the culture medium, whereas localization and incorporation of newly synthesized fibronectin is not altered. A cell surface proteoheparan sulfate was identified as TSP binding macromolecule by affinity chromatography. The data emphasize the role of heparan sulfate proteoglycan as a receptor-like molecule for the specific interaction with thrombospondin.     

Evaluation of protein-N-(2-hydroxypropyl)methacrylamide copolymer conjugates as targetable drug carriers. 1. Binding, pinocytic uptake and intracellular distribution of transferrin and anti-transferrin receptor antibody conjugates

The transferrin receptor of human skin fibroblasts was studied as an in vitro model target antigen receptor for interaction with protein-polymer conjugates having potential for targeted drug delivery. Pinocytic uptake of 125I-labelled N-(2-hydroxypropyl)methacrylamide (HPMA) copolymer conjugated to monoclonal antibody B3/25 (specific for the transferrin receptor) or transferrin was up to 9-fold greater than uptake of the parent HPMA copolymer. The ability of these conjugates to bind specifically was confirmed by Scatchard analysis. Pinocytic internalisation was dependent on the molecular mass of the conjugate. Intracellular routing following internalisation was evaluated using density-gradient centrifugation. Unmodified HPMA copolymer was transferred via the endosomal compartment into secondary lysosomes, where, being resistant to degradation, it accumulated. Although the majority of endocytosed transferrin is recycled via the endosome, it was shown that any transferrin reaching the lysosomes was rapidly degraded and low-molecular-weight degradation products were released. Monoclonal antibody B3/25 showed a subcellular distribution consistent with prolongation on the cell surface, followed by internalisation and subcellular trafficking, via endosomes, into the lysosomal compartment, with subsequent degradation. Conjugation of protein to HPMA copolymer increased lysosomal accumulation of polymer up to 9-fold, with no detectable degradation of conjugate. The data presented here have implications regarding clinical potential of protein-HPMA copolymer conjugates designed for lysosomotropic drug delivery.     

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.     

Receptor-mediated endocytosis of transferrin in K562 cells

Human diferric transferrin binds to the surface of K562 cells, a human leukemic cell line. There are about 1.6 X 10(5) binding sites per cell surface, exhibiting a KD of about 10(-9) M. Upon warming cells to 37 degrees C there is a rapid increase in uptake to a steady state level of twice that obtained at 0 degree C. This is accounted for by internalization of the ligand as shown by the development of resistance to either acid wash or protease treatment of the ligand-cell association. After a minimum residency time of 4-5 min, undegraded transferrin is released from the cell. Internalization is rapid but is dependent upon cell surface occupancy; at occupancies of 20% or greater the rate coefficient is maximal at about 0.1-0.2 min-1. In the absence of externally added ligand only 50% of the internalized transferrin completes the cycle and is released to the medium with a rate coefficient of 0.05 min-1. The remaining transferrin can be released from the cell only by the addition of ligand, suggesting a tight coupling between cell surface binding, internalization, and release of internalized ligand. There is a loss of cell surface-binding capacity that accompanies transferrin internalization. At low (less than 50%) occupancy this loss is monotonic with the extent of internalization. Even at saturating levels of transferrin, the loss of surface receptors upon internalization never exceeds 60-70% of the initial binding capacity. This suggests that receptors enter the cell with ligand but are replaced so as to maintain a constant, albeit reduced, receptor number on the cell surface. In the absence of ligand, the cell surface receptor number returns at 37 degrees C. Neither sodium azide nor NH4Cl blocks internalization of ligand. However, they both prevent the release of transferrin from the cell thus halting the transferrin cycle. Excess ligand can overcome the block due to NH4Cl but not azide although the cycle is markedly slower. Iron is delivered to these cells by transferrin at 37 degrees C with a rate coefficient of 0.15 to 0.2 min-1. The iron is released from the transferrin and the majority is found in intracellular ferritin. There is a large internal receptor pool comprising 70 to 80% of the total cell receptors and this may be involved in maintaining the steady state iron uptake.     

The asialoglycoprotein receptor internalizes and recycles independently of the transferrin and insulin receptors

Receptor-mediated endocytosis of specific ligands is mediated through clustering of receptor-ligand complexes in coated pits on the cell surface, followed by internalization of the complex into endocytic vesicles. We show that internalization of asialoglycoprotein by HepG2 hepatoma cells is accompanied by a rapid (t1/2 = 0.5-1 min) depletion of surface asialoglycoprotein receptors. This is followed by a rapid (t1/2 = 2-4 min) reappearance of surface receptors; most of these originate from endocytosed cell-surface receptors. The loss and reappearance of asialoglycoprotein receptors is specific, and depends on prebinding of ligand to its receptor. HepG2 cells also contain abundant receptors for both insulin and transferrin. Endocytosis of asialoglycoprotein and its receptor has no effect on the number of surface binding sites for transferrin or insulin. We conclude that binding of asialoglycoprotein to its surface receptor triggers a rapid and specific endocytosis of the receptor-ligand complex, probably due to a clustering in clathrin-coated pits or vesicles.     

Functional expression of the polymeric immunoglobulin receptor from cloned cDNA in fibroblasts

The polymeric immunoglobulin receptor, a transmembrane protein, is made by a variety of polarized epithelial cells. After synthesis, the receptor is sent to the basolateral surface where it binds polymeric IgA and IgM. The receptor-ligand complex is endocytosed, transported across the cell in vesicles, and re-exocytosed at the apical surface. At some point the receptor is proteolytically cleaved so that its extracellular ligand binding portion (known as secretory component) is severed from the membrane and released together with the polymeric immunoglobulin at the apical surface. We have used a cDNA clone coding for the rabbit receptor and a retroviral expression system to express the receptor in a nonpolarized mouse fibroblast cell line, psi 2, that normally does not synthesize the receptor. The receptor is glycosylated and sent to the cell surface. The cell cleaves the receptor to a group of polypeptides that are released into the medium and co-migrate with authentic rabbit secretory component. Cleavage and release of secretory component do not depend on the presence of ligand. The cells express on their surface 9,600 binding sites for the ligand, dimeric IgA. The ligand can be rapidly endocytosed and then re-exocytosed, all within approximately 10 min. Very little ligand is degraded. At least some of the ligand that is released from the cells is bound to secretory component. The results presented indicate that we have established a powerful new system for analyzing the complex steps in the transport of poly-Ig and the general problem of membrane protein sorting.     

Intracellular fusion of sequentially formed endocytic compartments

A polyclonal anti-fluorescein antibody (AFA) which quenches fluorescein fluorescence has been used to distinguish between two models of intracellular vesicle traffic. These models address the question of whether sequentially endocytosed probes will mix intracellularly or whether they are carried through the cell in a sequential, isolated manner. Using transferrin (Tf) as a recycling receptor marker, we incubated Chinese hamster ovary (CHO) cells with fluorescein-Tf (F-Tf) which is rapidly endocytosed. After the F-Tf was completely cleared from the surface, AFA was added to the incubation medium and entered endocytic compartments by fluid phase endocytosis. Fusion of a vesicle containing AFA with the compartment containing F-Tf results in binding of AFA to fluorescein and the quenching of fluorescein fluorescence. When AFA was added to the culture medium 2 min after clearance of F-Tf from the surface, time dependent fluorescence quenching occurred. After 20 min, 67% saturation of F-Tf with AFA was observed. When the interval between F-Tf clearance and AFA addition was increased to 5 min only 41% saturation of F-Tf was found. These data indicate that there are some compartments which are accessible for mixing with subsequently endocytosed molecules, but the efficiency of mixing falls off rapidly as the interval between pulses is increased. In CHO cells Tf swiftly segregates to a collection of vesicles or tubules in the para-Golgi region, and at steady state most of the F-Tf is in this compartment. Using digital image analysis to quantify quenching in this region, we have found that F-Tf/AFA mixing is occurring either within this compartment or before transferrin enters it.     

Regulation of murine plasmacytoma transferrin receptor expression and G1 traversal by plasmacytoma cell growth factor

Many plasmacytomas arising in BALB/c mice require a specific, macrophage-derived growth factor in order to proliferate in vitro. Since transferrin receptor expression is normally regulated by tissue-specific growth factors and because expression of these receptors is required for cell proliferation, we examined the interaction of plasmacytoma growth factor (PCT-GF) on transferrin receptor expression and cell cycle progression in several PCT-GF-dependent and independent plasmacytoma cell lines maintained in vitro. We found that removal of PCT-GF results in a rapid and specific loss of transferrin receptor expression with concomitant G1 arrest in early G1. The time required for G1 arrest to become maximal correlates closely to the initial level of surface transferrin receptor expression and the rate of decay following removal of PCT-GF. The calcium channel blocker diltiazem interferes with the ability of PCT-GF to maintain transferrin receptor expression in PCT-GF-dependent cell lines and causes a G1 arrest of the cell population. When added to a PCT-GF-independent cell line, diltiazem also inhibited transferrin receptor expression and caused G1 arrest. Thus, both PCT-GF-dependent and -independent plasmacytoma cell lines require transferrin receptor expression for growth. In factor dependent cell lines, transferrin receptor expression requires exogenous PCT-GF, while in factor-independent cells, transferrin receptor expression is constitutive. In both cell types, intracellular calcium levels may play a role in receptor expression.     

Demonstration of two distinct transferrin receptor recycling pathways and transferrin-independent receptor internalization in K562 cells

The endocytosis and recycling of the human transferrin receptor were evaluated by several experimental modalities in K562 cells perturbed with 10(-5) M monensin. The work presented is an extension of a previous study demonstrating both complete inhibition of release of internalized human transferrin and a 50% reduction in the number of cell surface transferrin binding sites in K562 cells treated with monensin (Stein, B. S., Bensch, K. G., and Sussman, H. H. (1984) J. Biol. Chem. 259, 14762-14772). The data directly reveal the existence of two distinct transferrin receptor recycling pathways. One pathway is monensin-sensitive and is felt to represent recycling of transferrin receptors through the Golgi apparatus, and the other pathway is monensin-resistant and most likely represents non-Golgi-mediated transferrin receptor recycling. A transferrin-free K562 cell culture system was developed and used to demonstrate that cell surface transferrin receptors can be endocytosed without antecedent ligand binding, indicating that there are factors other than transferrin binding which regulate receptor internalization. Evidence is presented suggesting that two transferrin receptor recycling pathways are also operant in K562 cells under ligand-free conditions, signifying that trafficking of receptor into either recycling pathway is not highly ligand-dependent.     

Constitutive traffic of melanocortin-4 receptor in Neuro2A cells and immortalized hypothalamic neurons

Melanocortin-4 receptor (MC4R) is a G protein-coupled receptor (GPCR) that binds alpha-melanocyte-stimulating hormone (alpha-MSH) and has a central role in the regulation of appetite and energy expenditure. Most GPCRs are endocytosed following binding to the agonist and receptor desensitization. Other GPCRs are internalized and recycled back to the plasma membrane constitutively, in the absence of the agonist. In unstimulated neuroblastoma cells and immortalized hypothalamic neurons, epitopetagged MC4R was localized both at the plasma membrane and in an intracellular compartment. These two pools of receptors were in dynamic equilibrium, with MC4R being rapidly internalized and exocytosed. In the absence of alpha-MSH, a fraction of cell surface MC4R localized together with transferrin receptor and to clathrin-coated pits. Constitutive MC4R internalization was impaired by expression of a dominant negative dynamin mutant. Thus, MC4R is internalized together with transferrin receptor by clathrin-dependent endocytosis. Cell exposure toalpha-MSH reduced the amount of MC4R at the plasma membrane by blocking recycling of a fraction of internalized receptor, rather than by increasing its rate of endocytosis. The data indicate that, in neuronal cells, MC4R recycles constitutively and that alpha-MSH modulates MC4R residency at the plasma membrane by acting at an intracellular sorting step.     

Two mechanisms are involved in the process of iron-uptake by rat reticulocytes

The iron uptake by red cell precursors has been studied in the presence of the carboxylic ionophore monensin, which achieves a concentration dependent inhibition of iron uptake, without influencing the transferrin uptake. It seems that two mechanisms are involved: Iron is released from endocytosed transferrin by acid vesicles. Iron is released from surface-receptor-bound transferrin at the plasma membrane, without internalization of the transferrin receptor complex.     

Kinetics of internalization and recycling of transferrin and the transferrin receptor in a human hepatoma cell line. Effect of lysosomotropic agents

Growing HepG2 cells contain 50,000 functional surface transferrin-binding sites (Ciechanover, A., Schwartz, A.L., and Lodish, H.F. (1983) Cell 32,267-275) and 100,000 intracellular sites. At saturating concentrations of [59Fe]transferrin, and under conditions in which protein synthesis is blocked, iron uptake is linear for several hours at a rate of 9,500 transferrin molecules/cell/min. Thus, each receptor must recycle a ligand, on the average, each 15.8 min. Surface-bound transferrin is rapidly endocytosed (t1/2 = 3.5 min). All of the iron remains within the cell, while the apotransferrin is rapidly (t1/2 = 5.0 min) secreted into the medium. Previously, we showed (Dautry-Varsat, A., Ciechanover, A., and Lodish, H.F. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 2258-2262) that exposure of a ferrotransferrin-receptor complex to medium of pH less than 5.0 results in dissociation of iron, but that apotransferrin remains bound to its receptor. If the pH is raised to 7.0, such as would occur when an acidic intracellular vesicle fuses with the plasma membrane, apotransferrin is very rapidly dissociated (t1/2 = 17 s at 37 degrees C) from its receptor. Taken together, these results indicate that transferrin remains bound to its receptor throughout the endocytic cycle. In the present study, we have directly measured all the kinetic parameters involved in the transferrin receptor cycle. They are similar to those of the asialoglycoprotein receptor in the same cell line, and can be described by a simple kinetic model. In the presence of lysosomotropic agents, ferrotransferrin binds to its surface receptor and is internalized normally. However, iron is not dissociated from transferrin, and ferrotransferrin recycles back to the cell surface and is secreted into the medium. We conclude that the low pH in endocytic vesicles is essential for the dissociation of iron from transferrin and its delivery to the cell, but is not required for recycling of transferrin, and presumably of its receptor.     

Fate of the sea urchin egg receptor for sperm following fertilization

The sea urchin egg receptor for sperm is a 350 kDa glycoprotein containing a large extracellular domain that contains the sperm binding site, a transmembrane domain and a short COOH- terminal intracellular domain. During oogenesis, the receptor protein is first detected in Golgi-associated vesicles and cortical granules. Not until the egg is mature does the receptor appear on the cell surface; at this stage the intact receptor is found in approximately equal quantities on the egg cell surface and in cortical granules. As a potentially unique type of receptor, we were interested in its fate following fertilization. Several techniques have revealed that, following sperm binding, the amount of receptor markedly decreases. Using western blot analysis as well as direct measurement of the receptor protein, it was found that the membrane-bound form of the receptor rapidly disappeared following sperm binding to the egg, with only 3% of the receptor remaining after 30 s. Analysis by immupoelectron microscopy revealed that 30 s after sperm binding, 30% of the initial level of receptor was present. This remaining 30% was found mostly within the perivitelline space formed by the raised fertilization envelope. The disparity between these two sets of results (i.e. 3 vs 30%) is most likely accounted for by the exocytosis of receptor molecules from cortical granules; this fraction of the receptor would have been lost during isolation of the membrane-bound form of the receptor. Thus, unlike other cell surface receptors, the sea urchin egg receptor for sperm is not endocytosed and recycled following ligand binding. Rather, it disappears, presumably as a result of proteolysis. Transiently, the cortical granule form of the receptor is found released into the perivitelline space where it may bind to sperm and thereby prevent polyspermy. Despite the apparent secretion of this form of the receptor, experiments with antibodies to the extracellular and intracellular domains indicate that the receptors in cortical granules and in the plasmic membrane are similar, if not identical.     

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.     

Down-modulation of the G-protein-coupled estrogen receptor, GPER, from the cell surface occurs via a trans-Golgi-proteasome pathway

GPER is a G_s-coupled seven-transmembrane receptor that has been linked to specific estrogen binding and signaling activities that are manifested by plasma membrane-associated enzymes. However, in many cell types, GPER is predominately localized to the endoplasmic reticulum (ER), and only minor amounts of receptor are detectable at the cell surface, an observation that has caused controversy regarding its role as a plasma membrane estrogen receptor. Here, we show that GPER constitutively buds intracellularly into EEA-1+ endosomes from clathrin-coated pits. Nonvisual arrestins-2/-3 do not co-localize with GPER, and expression of arrestin-2 dominant-negative mutants lacking clathrin- or β-adaptin interaction sites fails to block GPER internalization suggesting that arrestins are not involved in GPER endocytosis. Like β1AR, which recycles to the plasma membrane, GPER co-traffics with transferrin+, Rab11+ recycling endosomes. However, endocytosed GPER does not recycle to the cell surface, but instead returns to the trans-Golgi network (TGN) and does not re-enter the ER. GPER is ubiquitinated at the cell surface, exhibits a short half-life (t_½ <1 h), and is protected from degradation by the proteasome inhibitor, MG132. Disruption of the TGN by brefeldin A induces the accumulation of endocytosed GPER in Rab11+ perinuclear endosomes and prevents GPER degradation. Our results provide an explanation as to why GPER is not readily detected on the cell surface in some cell types and further suggest that TGN serves as the checkpoint for degradation of endocytosed GPER.     

Lactoferrin-binding sites at the surface of HT29-D4 cells. Comparison with transferrin

The binding of 125I-lactoferrin to HT29-D4 cells, a clone of HT29 cells, was studied and compared to the binding of 125I-transferrin to the same cells. The binding of the two iron-transport proteins is saturable and reversible suggesting the presence of specific receptors for each protein. Scatchard analysis suggests the existence of binding sites for lactoferrin with the relatively high equilibrium dissociation constant, Kd1 of 408 nM. Additionally, the cell is capable of binding large amounts of lactoferrin with very low affinity, probably in a non-receptor intermediate fashion. The dissociation constant of transferrin and its receptor was calculated 9.29 nM which corresponds well to values found in the literature. In contrast to lactoferrin, the cell was capable of binding only low amounts of transferrin in a non-receptor intermediate fashion. After chemical crosslinking of lactoferrin to the cell surface, the radiolabeled lactoferrin was found in a complex of molecular mass 300 kDa. Crosslinking of transferrin resulted in a complex of much higher molecular mass. These data clearly show a binding site for lactoferrin different from the transferrin receptor. Only if competition experiments were performed with a high molar excess of both ligand proteins did a small percentage of either of the two ligands crossreact with the receptor for the other, possibly due to a structural similarity of the two glycoproteins.     

Iron metabolism in BeWo chorion carcinoma cells. Transferrin-mediated uptake and release of iron

Growing human choriocarcinoma BeWo b24 cells contain 1.5 X 10(6) functional cell surface transferrin binding sites and 2.0 X 10(6) intracellular binding sites. These cells rapidly accumulate iron at a rate of 360,000 iron atoms/min/cell. During iron uptake the transferrin and its receptor recycle at least each 19 min. The accumulated iron is released from the BeWo cells at a considerable rate. The time required to release 50% of previously accumulated iron into the extracellular medium is 30 h. This release process is cell line-specific as HeLa cells release very little if any iron. The release of iron by BeWo cells is stimulated by exogenous chelators such as apotransferrin, diethylenetriaminepenta-acetic acid, desferral, and apolactoferrin. The time required to release 50% of the previously accumulated iron into medium supplemented with chelator is 15 h. In the absence of added chelators iron is released as a low molecular weight complex, whereas in the presence of chelator the iron is found complexed to the chelator. Uptake of iron is inhibited by 250 microM primaquine or 2.5 microM monensin. However, the release of iron is not inhibited by these drugs. Intracellular iron is stored bound to ferritin. A model for the release of iron by BeWo cells and its implication for transplacental iron transport is discussed.     

Quiescent lymphocytes express intracellular transferrin receptors

Both quiescent and concanavalin A stimulated murine splenic lymphocytes were examined for the expression of surface and intracellular binding sites for the serum glycoprotein transferrin. Transferrin binding activity was observed on the surface of mitogen stimulated cells only. When soluble detergent extracts of both populations were studied, quiescent lymphocytes were shown to contain a significant pool of non-surface exposed, intracellular receptors which was approximately 20% of the total receptor complement of proliferating cells. Because the ratio of surface to intracellular binding sites was dramatically increased following mitogen stimulation, the regulation of transferrin receptor expression during this process may involve a substantial alteration in its subcellular distribution in addition to the well documented increase in number of binding sites.