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.     

Transferrin receptor 1

With the discovery that transferrin serves as the iron source for hemoglobin-synthesizing immature red blood cells came the demonstration that a cell surface receptor, now known as transferrin receptor 1, is required for iron delivery from transferrin to cells. (A recently described second transferrin receptor, with as yet poorly understood function, will not be discussed in this brief review.) In succeeding years transferrin receptor 1 was established as a gatekeeper for regulating iron uptake by most cells, and the transferrin-to-cell endocytic pathway characterized in detail. HFE, the protein incriminated in the pathogenesis of hereditary hemochromatosis, a disorder of progressive and toxic iron overload, competes with transferrin for binding to receptor, thereby impeding the uptake of iron from transferrin. Mutation of HFE destroys this competition, thus facilitating access of transferrin and its iron to cells. Availability of the crystal structure of transferrin receptor 1, along with those of transferrin and HFE, opened research on molecular mapping of the transferrin-HFE- transferrin receptor interfaces by correlated synchrotron-generated hydroxyl radical footprinting and cryo-electron microscopy. The emerging challenge is to relate structure to the functional effects of receptor binding on the iron-binding and iron-releasing properties of transferrin within the iron-dependent cell.     

Reconstitution of the transferrin receptor in lipid vesicles. Effect of cholesterol on the binding of transferrin

Purified rabbit reticulocyte transferrin receptors were incorporated into phosphatidylcholine vesicles containing varying amounts of cholesterol. The binding of transferrin to the receptor in the reconstituted vesicles had three distinct characteristics: (1) The binding of transferrin exhibited the two components characteristic of transferrin binding to erythroid cells, a saturable, specific component and a nonsaturable, nonspecific component. (2) Transferrin binding exhibited positive cooperativity at low cholesterol/phospholipid (C/P) molar ratios. However, the cooperativity diminished and then disappeared as the C/P molar ratios were increased to the levels found in circulating red blood cells. (3) The amount of specific transferrin binding to the reconstituted vesicles also decreased as the C/P molar ratio was increased. These results indicate that in the reconstituted system the lipid environment plays a significant role in the expression of transferrin receptors.     

Isolation and characterization of a transferrin binding protein from rat plasma

A transferrin binding protein was isolated from normal rat placenta and from iron-deficient rat plasma using a human transferrin affinity column. The yield of the isolated pure protein from iron-deficient rat plasma was about 0.5 micrograms/ml plasma. The major protein had a molecular mass of 85 kDa and contained carbohydrate. Reduction with mercaptoethanol did not change the molecular mass of the plasma transferrin binding protein whereas the native placental transferrin receptor of 180 kDa was reduced to 90 kDa. The transferrin binding protein reacted with both monoclonal and polyclonal antibodies raised against rat transferrin receptor. Immunoblotting of both normal and iron deficient rat plasma showed that the transferrin binding protein had a molecular mass of 85 kDa. In vitro digestion of purified rat placental transferrin receptor and red blood cells with trypsin provided an identical peptide profile, suggesting that the transferrin binding protein in rat plasma is derived from proteolysis of the extracellular portion of the transferrin receptor of the erythroid tissues.     

The small GTPase RAB10 regulates endosomal recycling of the LDL receptor and transferrin receptor in hepatocytes

The low-density lipoprotein receptor (LDLR) mediates the hepatic uptake of circulating low-density lipoproteins (LDLs), a process that modulates the development of atherosclerotic cardiovascular disease. We recently identified RAB10, encoding a small GTPase, as a positive regulator of LDL uptake in hepatocellular carcinoma cells (HuH7) in a genome-wide CRISPR screen, though the underlying molecular mechanism for this effect was unknown. We now report that RAB10 regulates hepatocyte LDL uptake by promoting the recycling of endocytosed LDLR from RAB11-positive endosomes to the plasma membrane. We also show that RAB10 similarly promotes the recycling of the transferrin receptor, which binds the transferrin protein that mediates the transport of iron in the blood, albeit from a distinct RAB4-positive compartment. Taken together, our findings suggest a model in which RAB10 regulates LDL and transferrin uptake by promoting both slow and rapid recycling routes for their respective receptor proteins.     

Transferrin receptor induction is required for human B-lymphocyte activation but not for immunoglobulin secretion

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

The role of the transferrin receptor in human B lymphocyte activation

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

Expression of dihydrotestosterone synthases and androgen receptor in sheep oviduct ampulla and its regulation by estradiol and progesterone

Oviduct ampulla plays an important role in steroid hormone-regulated sperm-oocyte binding in female animals. Although studies have shown that androgen receptor are expressed in many species oviduct, the interaction among androgen receptor (AR), estradiol (E2) and progesterone (P4) in the sheep oviduct have rarely been reported. In this study, we evaluated the localization of two isoforms of dihydrotestosterone (DHT) sythetase enzymes 5α-reductase (5α‐red1, 5α‐red2) and AR in sheep oviduct ampulla by immunohistochemistry and immunofluorescence. Results showed that they were all distributed in oviduct epithelium layer. In epithelial cells, 5α‐red1, 5α‐red2 were expressed in cytoplast and nuclear, but AR were stained in nuclear. We also investigated their expression pattern in the sheep oviduct ampulla at different development stages of follicles (Large follicles stage; hemorrhagium, luteum and albicans of corpus stage) by molecular experiments. We found that 5α‐red1, 5α‐red2 and AR mRNA abundance and protein were expressed highest in corpus albicans stage and lowest in corpus hemorrhagium stage. In vitro, when sheep oviduct ampulla epithelial cells (SOAECs) were cultured and treated with different concentrations of E2/P4 (10^?9–10^?6 M), we found that E2 inhibited the expression of AR mRNA and protein, while P4 promoted this expression. In addition, when the SOAECs were treated with E2 (10^?8 M) and/or its non-selective inhibitor ICI182780 (10^?7 M) as well as with P4 (10^?6 M) and/or its non-specific inhibitor RU486 (10^?5 M), we found that E2 and P4 inhibited and promoted the expression of AR mRNA and proteins, respectively, via their nuclear receptor pathways. This study provides a basic insight for the further research of oviduct epithelium physiological function closely related to androgen.     

Binding and surface exposure characteristics of the gonococcal transferrin receptor are dependent on both transferrin-binding proteins.

Neisseria gonorrhoeae is capable of iron utilization from human transferrin in a receptor-mediated event. Transferrin-binding protein 1 (Tbp1) and Tbp2 have been implicated in transferrin receptor function, but their specific roles in transferrin binding and transferrin iron utilization have not yet been defined. We utilized specific gonococcal mutants lacking Tbp1 or Tbp2 to assess the relative transferrin-binding properties of each protein independently of the other. The apparent affinities of the wild-type transferrin receptor and of Tbp1 and Tbp2 individually were much higher than previously estimated for the gonococcal receptor and similar to the estimates for the mammalian transferrin receptor. The binding parameters of both of the mutants were distinct from those of the parent, which expressed two transferrin-binding sites. Tbp2 discriminated between ferrated transferrin and apotransferrin, while Tbp1 did not. Results of transferrin-binding affinity purification, and protease accessibility experiments were consistent with the hypothesis that Tbp1 and Tbp2 interact in the wild-type strain, although both proteins were capable of binding to transferrin independently when separated in the mutants. The presence of Tbp1 partially protected Tbp2 from trypsin proteolysis, and Tbp2 also protected Tbp1 from trypsin exposure. Addition of transferrin to wild-type but not mutant cells protected Tbp1 from trypsin but increased the trypsin susceptibility of Tbp2. These observations indicate that Tbp1 and Tbp2 function together in the wild-type strain to evoke binding conformations that are distinct from those expressed by the mutants lacking either protein.     

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.     

Primitive series embryonic chick erythrocytes express the transferrin receptor

A monoclonal antibody specific for the chicken transferrin receptor was used to study receptor expression on circulating red cells from chick embryos of different ages. The use of indirect immunofluorescence with this antibody showed that all circulating immature reticulocytes and primitive series erythrocytes--but not erythrocytes from the definitive series--expressed the receptor. In all cells, the protein was synthesized as a 90-95-kD form. The retention of the transferrin receptor (and another proliferation-dependent cell surface protein) contrasted with the behaviour of a series of other developmentally regulated antigens which are lost during maturation of both primitive and definitive series erythroid cells.     

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

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

Characterization of proteins that associate with an unglycosylated form of the transferrin receptor in A431 cells

A protein doublet (Mr = 135,000/130,000) was found to coprecipitate with an unglycosylated form of the transferrin receptor in tunicamycin-treated A431 cells. This doublet is not detected with either a monoclonal or polyclonal antibody to the transferrin receptor on Western blots indicating that these proteins do not interact directly with transferrin receptor antibody. Proteolytic digestion patterns of the individual proteins of the Mr = 135,000/130,000 doublet suggest that they are related to one another and are distinct from the transferrin receptor. Further characterization of these proteins indicates that they form a high molecular weight complex with the unglycosylated but not the glycosylated form of the transferrin receptor. Pulse-chase experiments demonstrate that the proteins post-translationally associate with the receptor.     

A structural comparison of human serum transferrin and human lactoferrin

The transferrins are a family of proteins that bind free iron in the blood and bodily fluids. Serum transferrins function to deliver iron to cells via a receptor-mediated endocytotic process as well as to remove toxic free iron from the blood and to provide an anti-bacterial, low-iron environment. Lactoferrins (found in bodily secretions such as milk) are only known to have an anti-bacterial function, via their ability to tightly bind free iron even at low pH, and have no known transport function. Though these proteins keep the level of free iron low, pathogenic bacteria are able to thrive by obtaining iron from their host via expression of outer membrane proteins that can bind to and remove iron from host proteins, including both serum transferrin and lactoferrin. Furthermore, even though human serum transferrin and lactoferrin are quite similar in sequence and structure, and coordinate iron in the same manner, they differ in their affinities for iron as well as their receptor binding properties: the human transferrin receptor only binds serum transferrin, and two distinct bacterial transport systems are used to capture iron from serum transferrin and lactoferrin. Comparison of the recently solved crystal structure of iron-free human serum transferrin to that of human lactoferrin provides insight into these differences.     

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

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

The role of transferrin in heme transport.

Porphyrin accumulation by proliferating cells, e.g., those associated with cancers or wounds, tends to correlate with increased transferrin receptor density. To determine whether transferrin might be implicated in porphyrin transport, fluorescence and absorption spectroscopy were used to study the interaction of porphyrins with transferrin. A single high-affinity binding site for heme and other porphyrins (Kd approximately 20-25 nM) was detected by fluorescence spectroscopy. Difference spectroscopy revealed three additional heme-binding sites. These sites were distinct from the iron-binding sites: 1) Apotransferrin and diferric transferrin bound porphyrins with equal affinity; 2) 59Fe was not displaced from transferrin by porphyrins. Murine erythroleukemia cells incubated with [59Fe]hemin-[125I]transferrin internalized both labels concomitantly. Accumulation of [59Fe]hemin could be blocked by a 100-fold excess of diferric transferrin but not by apotransferrin. These results indicate that cells can internalize exogenous heme, and possibly porphyrins, bound to transferrin via its receptor.     

Identification and characterization of the transferrin receptor from Neisseria meningitidis

Expression of the meningococcal transferrin receptor, detected by assay with human transferrin conjugated to peroxidase, was regulated by the level of iron in the medium. The transferrin receptor was identified by SDS-PAGE and Western blot analysis, as a 71,000 molecular weight iron-regulated outer membrane protein in Neisseria meningitidis B16B6. Growth studies with iron-deficient cells and competition binding experiments demonstrated that the meningococcal receptor was species-specific for human transferrin. Reciprocal competitive binding experiments and limited proteolysis of intact cells indicated that the transferrin and lactoferrin receptors are distinct.     

The receptor recycling pathway contains two distinct populations of early endosomes with different sorting functions

Receptor recycling involves two endosome populations, peripheral early endosomes and perinuclear recycling endosomes. In polarized epithelial cells, either or both populations must be able to sort apical from basolateral proteins, returning each to its appropriate plasma membrane domain. However, neither the roles of early versus recycling endosomes in polarity nor their relationship to each other has been quantitatively evaluated. Using a combined morphological, biochemical, and kinetic approach, we found these two endosome populations to represent physically and functionally distinct compartments. Early and recycling endosomes were resolved on Optiprep gradients and shown to be differentially associated with rab4, rab11, and transferrin receptor; rab4 was enriched on early endosomes and at least partially depleted from recycling endosomes, with the opposite being true for rab11 and transferrin receptor. The two populations were also pharmacologically distinct, with AlF4 selectively blocking export of transferrin receptor from recycling endosomes to the basolateral plasma membrane. We applied these observations to a detailed kinetic analysis of transferrin and dimeric IgA recycling and transcytosis. The data from these experiments permitted the construction of a testable, mathematical model which enabled a dissection of the roles of early and recycling endosomes in polarized receptor transport. Contrary to expectations, the majority (>65%) of recycling to the basolateral surface is likely to occur from early endosomes, but with relatively little sorting of apical from basolateral proteins. Instead, more complete segregation of basolateral receptors from receptors intended for transcytosis occurred upon delivery to recycling endosomes.