Selective externalization of the transferrin receptor by sheep reticulocytes in vitro. Response to ligands and inhibitors of endocytosis

The transferrin receptor of sheep reticulocytes is released in vesicular form during in vitro incubation of the reticulocytes. A polyclonal antibody against the transferrin receptor slows down the release of the vesicles bearing the receptor, whereas transferrin and calf serum accelerate vesicle release. Vesicle formation and receptor release are inhibited at low temperatures and by the presence of inhibitors of ATP formation. In addition, lysosomotropic agents or transglutaminase inhibitors block receptor externalization. The externalized receptor has the same molecular size and peptide map as the receptor isolated from the membrane, suggesting that an intact receptor is removed and released from the cell. An unidentified peptide of 70 kDa is externalized with the transferrin receptor. Peptide maps show that the 70-kDa species is not a degradation product of the receptor. No function has yet been assigned to the 70-kDa peptide.     

In vitro acylation of the transferrin receptor

In vitro fatty acylation of the transferrin receptor with [3H]tetradecanoate or [3H]tetradecanoyl-CoA has been demonstrated for isolated sheep reticulocyte plasma membranes. Although less than 5% of the receptor was labeled in vitro, the acylated protein could be readily observed after sodium dodecyl sulfate-gel electrophoresis. The acylated transferrin receptor in the reticulocyte membrane was specifically precipitated with a monoclonal antibody and was absent from mature red cell membranes. Incorporation of fatty acid was dependent on ATP, and fatty acid was 5-10 times less effective as an acyl donor than the acyl-CoA derivative, pointing out the strong potential of this reagent for in vitro acylation of membrane proteins. During in vitro maturation of reticulocytes, the receptor is released in vesicles into the incubation medium. Using reticulocytes labeled with [3H]tetradecanoate, it can be shown that the 3H-labeled receptor is transferred from the cells to the vesicles without loss of acyl groups, suggesting that the vesiculation process does not involve deacylation.     

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 $\text{N-}\text{ethylmaleimide}$ 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°C but nearly all that taken up 4°C was released when the cells were subsequently incubated with trypsin plus $\text{N-}\text{ethylmaleimide}$, 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°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.     

Loss of the transferrin receptor during the maturation of sheep reticulocytes in vitro. An immunological approach.

Sheep reticulocyte-specific antiserum absorbed with mature sheep red cells has been used to isolate and identify reticulocyte-specific plasma-membrane proteins and to monitor their loss during incubation in vitro. Specific precipitation of labelled plasma-membrane proteins is obtained when detergent-solubilized extracts of 125I-labelled reticulocyte plasma membranes are incubated with this antiserum and Staphyloccus aureus, but not when mature-cell plasma membranes are treated similarly. During maturation of reticulocytes in vitro (up to 4 days at 37 degrees C), there is a marked decrease in the immunoprecipitable material. The anti-reticulocyte-specific antibodies have been identified as anti-(transferrin receptor) antibodies. By using these antibodies as a probe, the transferrin receptor has been shown to have a subunit molecular weight of 93 000. The data are consistent with reported molecular weights of this receptor and with the proposal that the receptor may exist as a dimer, since [125I]iodotyrosyl-peptide maps of the 93 000- and 186 000-mol.wt. components isolated are shown to be identical. Evidence is presented for the transmembrane nature of the receptor and for the presence of different binding sites for transferrin and these antibodies on the receptor.     

Protein kinase C does not phosphorylate the externalized form of the transferrin receptor.

We have investigated the phosphorylation of transferrin receptors both in intact sheep reticulocytes and in isolated plasma membranes. Phosphorylation of the receptor in intact cells or isolated plasma membranes is stimulated by phorbol diesters, suggesting that protein kinase C may be involved. Identical [32P] phosphopeptide tryptic maps are formed in the presence and absence of phorbol diesters. Using heat-treated membranes (which are devoid of endogenous kinase activity) exogenous protein kinase C phosphorylates the same peptides as the endogenous kinase(s). During maturation of reticulocytes to erythrocytes, the transferrin receptor is released to the medium in vesicular form. In cells labelled with [32P]Pi, the released receptor is not labelled with 32P and the exocytosed vesicles do not phosphorylate receptor with [gamma-32P]ATP. The absence of 32P in the released receptor appears to be due to a change in the receptor, since, even in the presence of exogenous protein kinase C, the exocytosed receptor is phosphorylated to approximately 8% of the level obtained with receptors from the plasma membrane. These data suggest that during maturation and externalization the receptor is altered so that it loses its capacity to act as a substrate for exogenous protein kinase C as well as the endogenous kinase(s). This change may be a signal which segregates the receptor for externalization from the receptor pool remaining for transferrin recycling during the final stages of red cell maturation.     

Characterization of transferrin receptor released by K562 erythroleukemia cells

A soluble form of transferrin receptor has been detected in human serum and has been shown recently to be a truncated form of the intact membrane bound receptor. Mechanisms governing the release of transferrin receptor by cells are poorly understood and could be better defined by tissue culture. The present investigation was undertaken to characterize the transferrin receptor released by K562 erythroleukemic cells. In contrast with maturing sheep reticulocytes, which have been shown to release transferrin receptor in small vesicles termed exosomes, we demonstrated, with a monoclonal enzyme-linked immunoassay, that less than 30% of the transferrin receptor released by K562 cells in log phase growth was in a particulate form. The relative amounts of soluble and particulate receptor released to the supernatant did not change significantly during 48 hr of incubation. Soluble receptor was purified by immunoaffinity chromatography. On polyacrylamide gel electrophoresis, its mobility was the same (85 kDa) as that of the truncated monomeric form recently identified in human serum. Further evidence that serum and soluble receptors released by K562 cells are identical was provided by amino acid sequence analysis, which demonstrated that 16 of the first 19 residues of the N-terminal sequence of soluble K562 receptor are homologous with the serum receptor. The remaining three were not identifiable. K562 cells provide a useful in vitro model for studying the production of membrane-bound and soluble forms of released transferrin receptor.     

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.     

Maturation-associated loss and incomplete de novo synthesis of the transferrin receptor in peripheral sheep reticulocytes: response to heme and iron

Hemin, but not iron, in the culture medium stimulates the maturation-associated loss of the transferrin receptor from sheep reticulocytes (t1/2 for loss approximately 6 hr) and its appearance in a population of externalized vesicles. A similar pattern is seen with nucleoside binding (a measure of the nucleoside transporter), where hemin increases the loss of binding activity from the cells during culture, concomitant with an increase in nucleoside binding in the externalized vesicles. Sheep reticulocytes retain the ability to synthesize the transferrin receptor, but the 35S-labeled receptors are not detected in released vesicles. Whereas hemin stimulates the loss of 35S-labeled transferrin receptors from the cell (t1/2 for loss approximately 20 hr), nonheme iron is more effective than heme. This difference in response of native and 35S-labeled receptor to hemin and iron supplements appears to be related to the differences in the two classes of receptors. Although the 35S-labeled receptor binds transferrin and both native and 35S-labeled peptides comigrate after chemical deglycosylation, the 35S-receptor is approximately 2 kD smaller than the native receptor and fails to acquire its complete size even when chased for up to 24 hr. Moreover, the 35S-labeled receptor is not expressed at the cell surface, but is retained in a nonrecycling compartment, where it is insensitive to digestion by trypsin at both 0 degrees C and 37 degrees C.     

Endocytosis and intracellular processing of transferrin and colloidal gold-transferrin in rat reticulocytes: demonstration of a pathway for receptor shedding

Endocytosis and intracellular processing of transferrin (Tf) and Tf receptors were examined in rat reticulocytes. Subcellular fractionation revealed that Tf enters a non-lysosomal endocytic compartment with a density between those of plasma membrane and lysosomes. After 20 min of uptake at (37 degrees C) 35 to 40% of cell-associated Tf was contained in this intermediate-density compartment. To test the fidelity of colloidal gold-Tf (AuTf) as a probe for Tf processing, reticulocytes were fractionated after uptake of 131I-Tf and 125I-AuTf. The subcellular distributions of the two ligands were indistinguishable by this method, a result suggesting that AuTf is processed similarly to Tf. Electron microscopy revealed that AuTf entered multivesicular endosomes (MVEs) as well as various small vesicles and tubular structures. In addition MVE exocytosis was observed with discharge of inclusion vesicles and associated AuTf. AuTf was bound to the outside of these vesicles both before and after exocytosis. These data suggest that Tf receptors are shed from developing reticulocytes by incorporation into the limiting membrane of inclusion vesicles, followed by discharge of these vesicles by MVE exocytosis. As further evidence of this process, we isolated inclusion vesicles after their discharge and found them to contain Tf receptors. Moreover, the rate of Tf receptor shedding by inclusion vesicle discharge matches Tf receptor loss rates closely enough to suggest that this is the primary path of receptor loss during reticulocyte development.     

Vesicle formation during reticulocyte maturation. Association of plasma membrane activities with released vesicles (exosomes)

Vesicles are released during the in vitro culture of sheep reticulocytes which can be harvested by centrifugation at 100,000 X g for 90 min. These vesicles contain a number of activities, characteristic of the reticulocyte plasma membrane, which are known to diminish or disappear upon reticulocyte maturation. The activities include acetylcholinesterase, cytochalasin B binding (glucose transporter) nucleoside binding (i.e. nucleoside transporter), Na+-independent amino acid transport, and the transferrin receptor. Enzymes of cytosolic origin are not detectable or are present at low activity in the vesicles. Cultures of whole blood, mature red cells, or white cells do not yield comparable levels of these activities, supporting the conclusion that the activities arise from the reticulocytes. In addition, the lipid composition of the vesicles shows the high sphingomyelin content characteristic of sheep red cell plasma membranes, but not white cell or platelet membranes, also consistent with the conclusion that the vesicles are of reticulocyte origin. It is suggested that vesicle externalization may be a mechanism for shedding of specific membrane functions which are known to diminish during maturation of reticulocytes to erythrocytes.     

The Cellular Regulation of Vesicle Exocytosis by Entamoeba histolytica1,2

ABSTRACT. We studied the cellular regulation of vesicle exocytosis by Entamoeba histolytica utilizing release of endocytosed ¹²⁵iodine (¹²⁵I) labeled tyrosine conjugated dextran; ¹²⁵I-dextran entered the acid pH vesicles of the amebae and was not degraded during these studies. Exocytosis was temperature dependent with 74%, 36%, 4%, and 0% of ¹²⁵I-dextran released after 120 min at 37°C, 31°C, 25°C, and 4°C, respectively (P < 0.01 for each). Exocytosis at 37°C was inhibited by cytochalasin D (10 μg/ml), EDTA (10 mM), or the putative intracellular calcium antagonist TMB-8 (250 μM) (P < 0.01 for each at ≥ 60 min). Calcium ionophore A23187 (1 μM) enhanced exocytosis at 5 and 15 min (P < 0.01). Elevation of vesicle pH with NH₄Cl (10 mM) had no effect on release of ¹²⁵I-dextran; phorbol myristate acetate (10^?6 M) increased exocytosis by 46% at 30 min (P < 0.01). Centrifugation of amebae with target Chinese hamster ovary cells resulted in decreased ¹²⁵I-dextran release into the cell supernatant after 30 and 60 min at 37°C (by 40% and 42%, respectively, P < 0.01); release of ¹²⁵I-dextran returned to control values with addition of 1.0 g% galactose or GalNac but not with mannose or N-acetyl-D-glucosamine. Amebic phagocytosis of serum-exposed latex beads had no effect on release of dextran by amebae (n = 16). Exocytosis of acid pH vesicles by E. histolytica is temperature-, microfilament-, and calcium-dependent, and stimulated by phorbol esters.     

Iron and transferrin distribution in reticulocytes incubated with heme synthesis inhibitors

A high level of non-heme iron (either labelled or unlabelled) in mitochondria, ferritin and low-molecular-weight pool of reticulocytes was induced by preincubation with isonicotinic acid hydrazide or penicillamine together with either ⁵⁹Fe- or ⁵⁶Fe-labelled transferrin. Addition of apotransferrin during reincubation of ⁵⁹Fe-labelled reticulocytes was accompanied by the transfer of ⁵⁹Fe from low-molecular-weight pool to transferrin, which was found in the reticulocyte cytosol both free and bound to a carrier. Similarly, when cells were reincubated with ¹²⁵I-labelled transferrin, more ¹²⁵I-labelled radioactivity was found, in both free and carrier-bound transferrin peaks, in reticulocytes with a high level of low-molecular-weight cold iron than in control ones. These results suggest that transferrin enters reticulocytes takes up iron from low-molecular-weight pool.     

Exosome formation during maturation of mammalian and avian reticulocytes: evidence that exosome release is a major route for externalization of obsolete membrane proteins

We have assessed whether exosome formation is a significant route for loss of plasma membrane functions during sheep reticulocyte maturation in vitro. Although the recovery of transferrin binding activity in exosomes is at best approximately 25-30% of the lost activity, recoveries of over 50% of the lost receptor can be obtained if 125I-labelled transferrin receptor is measured using an that receptor instability may contribute to the less than quantitative recovery of the transferrin receptor. Significantly higher (75-80%) levels of the nucleoside transporter can be recovered in exosomes during red cell maturation using 3H-nitrobenzylthioinosine binding to measure the nucleoside transporter. These data suggest that exosome formation is a major route for removal of plasma membrane proteins during reticulocyte maturation and plasma membrane remodelling. We have also shown that both in vivo and in vitro, embryonic chicken reticulocytes form exosomes which contain the transferrin receptor. Thus, exosome formation is not restricted to mammalian red cells, but also occurs in red cells, which retain organelles, such as nuclei and mitochondria, into the mature red cell stage.     

Incorporation of myristate and palmitate into the sheep reticulocyte transferrin receptor: evidence for identical sites of labeling

The ability of sheep reticulocytes and plasma membranes isolated from them to incorporate fatty acids into the transferrin receptor has been examined using both [3H]palmitate and [3H]myristate. Both fatty acids, when incorporated into the transferrin receptor, can be released by treating the protein with 1 M hydroxylamine at pH 7.0. After treatment of the 3H-acylated receptor with borohydride, an 3H-labeled alcohol is released, suggesting that the receptor-bound fatty acid is in thioester linkage. With both [3H]myristate and [3H]palmitate, Cleveland maps from immunoprecipitates of the transferrin receptor labeled in intact cells and isolated membranes show that identical peptides are labeled. No evidence was obtained for qualitatively different labeling with the two fatty acids. In intact reticulocytes, incorporation of [3H]palmitate into the transferrin receptor is approximately 3.5 times greater than the incorporation of [3H]myristate from equivalent concentrations of the labeled fatty acids. However, in isolated reticulocyte plasma membranes, there is much less difference between palmitate and myristate incorporation (with ATP) or between their acyl-CoA derivatives. The reason for the discrepancy between cells and membranes is unknown but may be due to the presence in intact cells of more than one enzyme for activating the fatty acids. Acylation of the receptor in isolated plasma membranes is fourfold greater with the CoA derivatives than with the free fatty acids. The fatty acid activating enzyme(s) as well as the acyltransferase(s) appear to be membrane bound in reticulocytes.     

Receptor-mediated endocytosis of transferrin and recycling of the transferrin receptor in rat reticulocytes

At 4 degrees C transferrin bound to receptors on the reticulocyte plasma membrane, and at 37 degrees C receptor-mediated endocytosis of transferrin occurred. Uptake at 37 degrees C exceeded binding at 4 degrees C by 2.5-fold and saturated after 20-30 min. During uptake at 37 degrees C, bound transferrin was internalized into a trypsin- resistant space. Trypsinization at 4 degrees C destroyed surface receptors, but with subsequent incubation at 37 degrees C, surface receptors rapidly appeared (albeit in reduced numbers), and uptake occurred at a decreased level. After endocytosis, transferrin was released, apparently intact, into the extracellular space. At 37 degrees C colloidal gold-transferrin (AuTf) clustered in coated pits and then appeared inside various intracellular membrane-bounded compartments. Small vesicles and tubules were labeled after short (5-10 min) incubations at 37 degrees C. Larger multivesicular endosomes became heavily labeled after longer (20-35 min) incubations. Multivesicular endosomes apparently fused with the plasma membrane and released their contents by exocytosis. None of these organelles appeared to be lysosomal in nature, and 98% of intracellular AuTf was localized in acid phosphatase-negative compartments. AuTf, like transferrin, was released with subsequent incubation at 37 degrees C. Freeze-dried and freeze-fractured reticulocytes confirmed the distribution of AuTf in reticulocytes and revealed the presence of clathrin-coated patches amidst the spectrin coating the inner surface of the plasma membrane. These data suggest that transferrin is internalized via coated pits and vesicles and demonstrate that transferrin and its receptor are recycled back to the plasma membrane after endocytosis.     

Iron transport from sepharose-bound transferrin

To ascertain whether transferrin need enter the reticulocyte to deliver its iron after the association of transferrin with the cell membrane, {¹²⁵I, ⁵⁹Fe-}labeled transferrin was covalently bound to Sepharose beads. Iron uptake from Sepharose-bound transferrin into rabbit reticulocytes was about 9% that from free transferrin while heme synthesis was more efficient at nearly 19%. Similar results were obtained with murine transferrin and murine reticulocytes.These results indicate that the entrance of transferrin inside the cell is not an obligatory step in the process of iron uptake in rabbit and murine reticulocytes.     

Electron microscopic evidence for externalization of the transferrin receptor in vesicular form in sheep reticulocytes

Using ferritin-labeled protein A and colloidal gold-labeled anti-rabbit IgG, the fate of the sheep transferrin receptor has been followed microscopically during reticulocyte maturation in vitro. After a few minutes of incubation at 37 degrees C, the receptor is found on the cell surface or in simple vesicles of 100-200 nm, in which the receptor appears to line the limiting membrane of the vesicles. With time (60 min or longer), large multivesicular elements (MVEs) appear whose diameter may reach 1-1.5 micron. Inside these large MVEs are round bodies of approximately 50-nm diam that bear the receptor at their external surfaces. The limiting membrane of the large MVEs is relatively free from receptor. When the large MVEs fuse with the plasma membrane, their contents, the 50-nm bodies, are released into the medium. The 50-nm bodies appear to arise by budding from the limiting membrane of the intracellular vesicles. Removal of surface receptor with pronase does not prevent exocytosis of internalized receptor. It is proposed that the exocytosis of the approximately 50-nm bodies represents the mechanism by which the transferrin receptor is shed during reticulocyte maturation.     

E-rosette formation at 37 °C: Analysis with monoclonal OKT antibodies

When cultured in the presence of PHA, a proportion of human peripheral blood mononuclear cells acquires the capacity to form E rosettes with sheep erythrocytes that are resistant to incubation at 37 °C. The nature of this 37 °C stable E-rosette formation was investigated using a panel of monoclonal OKT antibodies directed to human T-lymphocyte surface antigens. OKT11A antibody, at a concentration of 0.2–0.4 μg/ml, markedly blocked 37 °C E rosetting. OKT1, OKT3, OKT4, OKT6, and OKT8 antibodies, when tested at 10 μg/ml, show no such inhibiting activity. Quantitative studies with ¹²⁵I-labeled OKT11A indicated that the antibody interacted strongly with both 37 °C E-rosetting and nonrosetting cells, the association constant being 1.6–2.0 × 10⁹M^?1. However, on the average, a threefold higher concentration of OKT11A receptor sites was found on 37 °C E-rosette-forming cells (14.8 × 10⁴ sites/cell) than on nonrosetting cells (4.8 × 10⁴ sites/cell). Our data suggest that 37 °C E-rosette formation is governed by a lymphocyte surface determinant recognized by OKT11A antibody. “Overexpression” of OKT11A antigenic sites on a proportion of PHA-stimulated lymphocytes may explain their capacity to form 37 °C stable E-rosettes.     

Mobilization of iron from endocytic vesicles. The effects of acidification and reduction

The factors necessary to dissociate iron from transferrin in endocytic vesicles and to mobilize the iron across the vesicle membrane were studied in a preparation of endocytic vesicles markedly enriched in transferrin-transferrin receptor complexes isolated from rabbit reticulocytes. Vesicles were prepared with essentially fully saturated transferrin by incubating the reticulocytes with the protonophore carbonyl cyanide 4-(trifluoromethoxy)phenylhydrazone prior to incubation with 59Fe, 125I-transferrin with or without fluorescein isothiocyanate labeling. Initiation of acidification by the addition of ATP was sufficient to achieve dissociation of 59Fe from transferrin with a rate constant of 0.054 +/- 0.06 s-1. Mobilization of 59Fe out of the vesicles required, besides ATP, the addition of a reductant with 1 mM ascorbate, allowing approximately 60% mobilization at 10 min with a rate constant of 0.0038 +/- 0.0006 s-1. An NADH:ferricyanide reductase activity could be demonstrated in the vesicles with an activity of 7.1 x 10(-9) mol of NADH reduced per min/mg of vesicle protein. Both dissociation and mobilization were inhibited by N-ethylmaleimide, carbonyl cyanide 4-(trifluoromethoxy)phenylhydrazone, and monensin. Mobilization, but not dissociation, was inhibited by the permeant Fe(II) chelator alpha,alpha'-dipyridyl. The Fe(III) chelators deferoxamine, diethylenetriaminepentaacetic acid, and apotransferrin did not promote mobilization of dissociated iron in the absence of a reductant. This study establishes the basis for the cellular incorporation of iron through the endocytic pathway in which the endocytic vesicle membrane utilizes, in a sequential way, an acidification system, an iron reduction system, and an Fe(II) transporter system.     

An evaluation of lysosomal enzyme leakage as a factor influencing the behaviour of transformed cells.

The effect of concanavalin A on transferrin and iron uptake by reticulocytes was determined using rabbit reticulocytes and rabbit transferrin labelled with ⁵⁹Fe and ¹²⁵I and concanavalin A (ConA) labelled with ¹³¹I. In concentrations of 50–200 μg/ml ConA markedly inhibited iron uptake but did not inhibit transferrin uptake or release from the cells. ConA was itself taken up by rabbit blood cells in a manner similar to that of transferrin except that the uptake was not specific for reticulocytes but occurred also with mature erythrocytes. The inhibition of iron uptake by concanavalin and the uptake of concanavalin by the cells were both inhibited by α-methyl-d-mannoside. It is concluded that the effects observed were due to the binding of concanavalin to glycoproteins of the cell membrane, either by a direct interaction with transferrin receptors or by the production of a non-specific change in the structure of the membrane.