Recycling of 5''-nucleotidase in a rat hepatoma cell line.

Intracellular movement of cell surface 5'-nucleotidase was studied in H4S cells, a rat hepatoma cell line. Surface labelled cells were incubated for various periods at 37 degrees C and treated with neuraminidase at 0 degrees C. Removal of sialic acid residues from glycoproteins results in a change of their isoelectric points. Analysis with isoelectric focusing was then used to distinguish between cell surface and intracellular 5'-nucleotidase. Incubation of 125I-surface-labelled cells at 37 degrees C resulted in a gradual decrease of labelled 5'-nucleotidase at the plasma membrane until, at 60 to 90 min, a steady state was reached with 52% of the label on the cell surface and 48% intracellular. Pretreatment of the cells with the weak base primaquine had no influence on this distribution while at the same time uptake of iron via the transferrin receptor was inhibited. Using immunoelectron microscopy 5'-nucleotidase was found on the cell surface, in multivesicular endosomes and the Golgi complex. Preincubation of the cells in the presence of cycloheximide caused a reduction of labelling in the Golgi complex, whereas the label in the other compartments was retained. These results lead to the conclusion that 5'-nucleotidase does not recycle through the Golgi complex and that in contrast to the transferrin receptor the recycling of 5'-nucleotidase is not inhibited by primaquine.     

Parvovirus infection of cells by using variants of the feline transferrin receptor altering clathrin-mediated endocytosis, membrane domain localization, and capsid-binding domains

The feline and canine transferrin receptors (TfRs) bind canine parvovirus to host cells and mediate rapid capsid uptake and infection. The TfR and its ligand transferrin have well-described pathways of endocytosis and recycling. Here we tested several receptor-dependent steps in infection for their role in virus infection of cells. Deletions of cytoplasmic sequences or mutations of the Tyr-Thr-Arg-Phe internalization motif reduced the rate of receptor uptake from the cell surface, while polar residues introduced into the transmembrane sequence resulted in increased degradation of transferrin. However, the mutant receptors still mediated efficient virus infection. In contrast, replacing the cytoplasmic and transmembrane sequences of the feline TfR with those of the influenza virus neuraminidase (NA) resulted in a receptor that bound and endocytosed the capsid but did not mediate viral infection. This chimeric receptor became localized to detergent-insoluble membrane domains. To test the effect of structural virus receptor interaction on infection, two chimeric receptors were prepared which contained antibody-variable domains that bound the capsid in place of the TfR ectodomain. These chimeric receptors bound CPV capsids and mediated uptake but did not result in cell infection. Adding soluble feline TfR ectodomain to the virus during that uptake did not allow infection.     

Stimulation of receptor-mediated low density lipoprotein endocytosis in neuraminidase-treated cultured bovine aortic endothelial cells

Sialic acids, occupying a terminal position in cell surface glycoconjugates, are major contributors to the net negative charge of the vascular endothelial cell surface. As integral membrane glycoproteins, LDL receptors also bear terminal sialic acid residues. Pretreatment of near-confluent, cultured bovine aortic endothelial cells (BAEC) with neuraminidase (50 mU/ml, 30 min, 37 degrees C) stimulated a significant increase in receptor-mediated 125I-LDL internalization and degradation relative to PBS-treated control cells. Binding studies at 4 degrees C revealed an increased affinity of LDL receptor sites on neuraminidase-treated cells compared to control BAEC (6.9 vs. 16.2 nM/10(6) BAEC) without a change in receptor site number. This enhanced LDL endocytosis in neuraminidase-treated cells was dependent upon the enzymatic activity of the neuraminidase and the removal of sialic acid from the cell surface. Furthermore, enhanced endocytosis due to enzymatic alteration of the 125I-LDL molecules was excluded. In contrast to BAEC, neuraminidase pretreatment of LDL receptor-upregulated cultured normal human fibroblasts resulted in an inhibition of 125I-LDL binding, internalization, and degradation. Specifically, a significant inhibition in 125I-LDL internalization was observed at 1 hr after neuraminidase treatment, which was associated with a decrease in the number of cell surface LDL receptor sites. Like BAEC, neuraminidase pretreatment of human umbilical vein endothelial cells resulted in enhanced receptor-mediated 125I-LDL endocytosis. These results indicate that sialic acid associated with either adjacent endothelial cell surface molecules or the endothelial LDL receptor itself may modulate LDL receptor-mediated endocytosis and suggest that this regulatory mechanism may be of particular importance to endothelial cells.     

Transport of surface mannose 6-phosphate receptor to the Golgi complex in cultured human cells

The cation-independent mannose 6-phosphate receptor (MPRCI) functions in the packaging of both newly made and extracellular lysosomal enzymes into lysosomes. The subcellular location of MPRCI reflects these two functions; receptor is found in the Golgi complex, in endosomes, and on the cell surface. To learn about the intracellular pathway followed by surface receptor and to study the relationship between the receptor pools, we examined the entry of the surface MPRCI into Golgi compartments that contain sialyltransferase. Sialic acid was removed from surface-labeled K562 cultured human erythroleukemia cells by neuraminidase treatment. When the cells were returned to culture at 37 degrees C, surface MPRCI was resialylated by the cells with a half-time of 1-2 h. Resialylation was inhibited by reduced temperature, a treatment that allows surface molecules to reach endosomes but blocks further transport. These results indicate that surface MPRCI is transported to the sialyltransferase compartment in the Golgi complex. After culture at 37 degrees C, a small fraction (10-20%) of the resialylated receptor was found on the cell surface. Because a similar fraction of the total receptor pool is found on the cell surface, it is likely that cell surface MPRCI mixes with the cellular pool after resialylation. These data also support the idea that extracellular and newly made lysosomal enzymes are transported to lysosomes through a common compartment.     

Structural and functional stability of the mature transferrin receptor from human placenta

The transferrin receptor (TfR) is a N- and O-glycosylated transmembrane protein mediating the cellular iron uptake by binding and internalization of diferric transferrin. In this study, rate constants and dissociation constants of 125I-ferri-transferrin binding to the human TfR were examined dependent on receptor glycan composition, pH, bivalent cations, and temperature. To do so, purified human placental TfR was noncovalently immobilized to polystyrene surfaces and subjected to alterations in various parameters. We found that transferrin binding was clearly dependent on a receptor pretreatment with buffers of various pH in that most of the TfR molecules irreversibly lost transferrin binding activity below pH 6.5. However, the dissociation constant of the remaining active binding sites was not affected. Similarly, we were able to define the thermal stability of the receptor as a function of transferrin binding ability. Binding of transferrin was completely lost provided that the receptor was pretreated at temperatures of at least 65 degrees C. Treatment with EDTA also caused an irreversible loss of transferrin binding activity, indicating that the functionally active conformation of the mature TfR depends on bivalent cations. In order to examine the role of the receptor glycans, we enzymatically removed the sialic acid residues, the hybrid and oligomannosidic N-glycans, or all types of N-glycans. In contrast to the parameters described above, all desialylated and N-deglycosylated TfR variants had exactly the same transferrin binding properties as the native TfR. To assess changes in the secondary structure of the receptor, circular dichroic spectra were recorded from TfR at pH 5.0, from heat pretreated receptor and from deglycosylated TfR. Since the receptor did not exhibit detectable changes in the CD spectrum of the deglycosylated receptor, it can be concluded that the N-linked carbohydrates of the mature, fully processed TfR are not essential for transferrin binding and conformational stability.     

Membrane traffic in animal cells: cellular glycoproteins return to the site of Golgi mannosidase I

The recycling of cellular glycoproteins to the site of Golgi mannosidase I, an enzyme of asparagine-linked oligosaccharide synthesis, was studied in K562 human erythroleukemia cells. Cells were metabolically labeled in the presence of deoxymannojirimycin, a reversible inhibitor of Golgi mannosidase I. This generates glycoproteins with immature oligosaccharides in their normal locations. Transport to the mannosidase I compartment was then assessed by testing for the conversion of oligosaccharides into mature forms during reculture without deoxymannojirimycin. Transferrin receptor (TfR) was acted on by mannosidase I during reculture, suggesting that it returned to the region of the Golgi complex where this enzyme resides. The slow rate of this transport (t1/2 greater than 6 h) implies that it is probably different than TfR movement during transferrin internalization (t1/2 = 10-20 min) and TfR transport to the sialyltransferase compartment in the Golgi complex (t1/2 = 2-3 h) (Snider, M. D., and O. C. Rogers, 1985, J. Cell Biol., 100:826-834). The total cell glycoprotein pool was also transported to the mannosidase I compartment with a half-time of 4 h. Because this transport is 5-10 times faster than the rate of de novo glycoprotein synthesis in these cells, it is likely that most of the glycoprotein traffic through the Golgi complex is composed of recycling molecules.     

Desialylation of surface receptors as a new dimension in cell signaling

Terminal sialic acid residues are found in abundance in glycan chains of glycoproteins and glycolipids on the surface of all live cells forming an outer layer of the cell originally known as glycocalyx. Their presence affects the molecular properties and structure of glycoconjugates, modifying their function and interactions with other molecules. Consequently, the sialylation state of glycoproteins and glycolipids has been recognized as a critical factor modulating molecular recognitions inside the cell, between the cells, between the cells and the extracellular matrix, and between the cells and certain exogenous pathogens. Until recently sialyltransferases that catalyze transfer of sialic acid residues to the glycan chains in the process of their biosynthesis were thought to be mainly responsible for the creation and maintenance of a temporal and spatial diversity of sialylated moieties. However, the growing evidence suggests that in mammalian cells, at least equally important roles belong to sialidases/neuraminidases, which are located on the cell surface and in intracellular compartments, and may either initiate the catabolism of sialoglycoconjugates or just cleave their sialic acid residues, and thereby contribute to temporal changes in their structure and functions. The current review summarizes emerging data demonstrating that mammalian neuraminidase 1, well known for its lysosomal catabolic function, is also targeted to the cell surface and assumes the previously unrecognized role as a structural and functional modulator of cellular receptors.     

A trans Golgi-derived exocytic coated vesicle can contain both newly synthesized cholinesterase and internalized transferrin

We used a cholinesterase-mediated density shift protocol to investigate the movement of internalized transferrin (Tf) through endo- and exocytic coated vesicles (CVs) in the perfused rat liver. Upon internalization, exogenous 125I-Tf was found in endocytic CVs but not in cholinesterase-containing (i.e., exocytic) CVs (0-40 min). Between 1 and 2 hr, 125I-Tf began to appear in exocytic CVs. The origin of the exocytic CV was further investigated. After perfusion of the liver with asialotransferrin, the exocytic CVs were shown to contain resialylated Tf, indicating that the trans Golgi was the origin of this class of CVs. The resialylated Tf accumulated in the extracellular medium with kinetics very similar to the time course for appearance of Tf in cholinesterase-containing, exocytic CVs, suggesting that these CVs are directly involved in the transfer of material from the trans Golgi to the cell surface.     

Activation of protein kinase C accelerates internalization of transferrin receptor but not of major histocompatibility complex class I, independent of their phosphorylation status.

Phosphorylation of membrane glycoproteins has often been invoked as a determinant of receptor internalization and receptor trafficking in a more general sense. Here we have studied the trafficking of major histocompatibility complex (MHC) Class I molecules and transferrin receptor (Tfr) related to their phosphorylation status in the human lymphoblastoid cell line JY. High resolution isoelectric focusing (IEF) allows the visualization of phosphorylated and non-phosphorylated protein species simultaneously, using protein backbone-labeling. Analysis on IEF was combined with a neuraminidase protection assay, in which sialic acid modification of the N-linked glycans present on Tfr and Class I molecules is used as a reporter group for cell surface expression. Phosphorylation of Class I heavy chains and Tfr was induced by exposure of cells to the phorbol ester tetradecanoyl phorbol acetate. We show that 1) phosphorylation of MHC Class I molecules is restricted to the cell surface fraction, 2) phosphorylation of MHC Class I molecules by protein kinase C (PKC) is not correlated with their internalization, as no internalization of Class I molecules, phosphorylated or non-phosphorylated, could be detected, 3) the initial rate, but not the final extent of the internalization of Tfr is affected by activation of PKC, and 4) phosphorylated Tfr behaves in a manner identical to non-phosphorylated Tfr in terms of internalization. The effect of activation of PKC on internalization of Tfr therefore most likely takes place at the level of the internalization machinery. Our data concerning the internalization of MHC Class I molecules contrast with earlier studies describing constitutive internalization in the B lymphoblastoid cell line A 46 and in HPB-ALL cells.     

The PICALM Protein Plays a Key Role in Iron Homeostasis and Cell Proliferation

The ubiquitously expressed phosphatidylinositol binding clathrin assembly (PICALM) protein associates with the plasma membrane, binds clathrin, and plays a role in clathrin-mediated endocytosis. Alterations of the human PICALM gene are present in aggressive hematopoietic malignancies, and genome-wide association studies have recently linked the PICALM locus to late-onset Alzheimer's disease. Inactivating and hypomorphic Picalm mutations in mice cause different degrees of severity of anemia, abnormal iron metabolism, growth retardation and shortened lifespan. To understand PICALM's function, we studied the consequences of PICALM overexpression and characterized PICALM-deficient cells derived from mutant fit1 mice. Our results identify a role for PICALM in transferrin receptor (TfR) internalization and demonstrate that the C-terminal PICALM residues are critical for its association with clathrin and for the inhibitory effect of PICALM overexpression on TfR internalization. Murine embryonic fibroblasts (MEFs) that are deficient in PICALM display several characteristics of iron deficiency (increased surface TfR expression, decreased intracellular iron levels, and reduced cellular proliferation), all of which are rescued by retroviral PICALM expression. The proliferation defect of cells that lack PICALM results, at least in part, from insufficient iron uptake, since it can be corrected by iron supplementation. Moreover, PICALM-deficient cells are particularly sensitive to iron chelation. Taken together, these data reveal that PICALM plays a critical role in iron homeostasis, and offer new perspectives into the pathogenesis of PICALM-associated diseases.     

Disparity between expression of transferrin receptor ligand binding and non-ligand binding domains on human lymphocytes

We compared transferrin receptor (TfR) expression on human peripheral blood lymphocytes (PBL) activated by phorbol myristate acetate (PMA) or L-phytohemagglutinin (LPHA) using two techniques: (1) 125I-iron-saturated transferrin (FeTf) binding, (2) reactivity with monoclonal anti-TfR antibodies--OKT9 and B3/25. These monoclonal antibodies do not block FeTf binding, and therefore bind to TfR domains separate from the ligand binding site. Unstimulated PBL bound fewer than 1,000 molecules of 125I-FeTf per cell, and less than 5% of cells expressed TfR antigens detected by OKT9 or B3/25. 125I-FeTf binding and antibody binding increased in parallel on LPHA-activated PBL. After exposure to LPHA for 72 hr, 125I-FeTf binding increased 100-fold to 10(5) molecules per cell and greater than 50% of cells expressed TfR antigens. By contrast, PMA activation of PBL markedly increased binding of OKT9 and B3/25 but not the binding of 125I-FeTf. Cell surface expression of TfR antigens seen by OKT9 and B3/25 did not differ between LPHA- and PMA-activated PBL. However, after 72 hr with PMA, 125I-FeTf binding increased only 6-fold and consistently remained at less than 10(4) molecules per cell. Therefore, PMA induced a disparity between expression of TfR ligand binding domains and immunological domains at the cell surface. Cell proliferation assessed by fluorescent DNA analysis was similar in cultures stimulated by LPHA or PMA. These data indicate that lymphoid cells may possess a mechanism for modulating TfR expression in which down-regulation of FeTf binding occurs without receptor internalization. Alternatively, it is possible that this observation may reflect a membrane perturbation effect of PMA.     

Insulin regulation of protein traffic in rat adipose cells.

Rat adipocytes were biotinylated with cell-impermeable reagents, sulfo-N-hydroxysuccinimide-biotin and sulfo-N-hydroxysuccinimide-S-S-biotin in the absence and presence of insulin. Biotinylated and nonbiotinylated populations of the insulin-like growth factor-II/mannose 6-phosphate receptor, the transferrin receptor, and insulin-responsive aminopeptidase were separated by adsorption to streptavidin-agarose to determine the percentage of the biotinylated protein molecules versus their total amount in different subcellular compartments. Results indicate that adipose cells possess at least two distinct cell surface recycling pathways for insulin-like growth factor-II/mannose 6-phosphate receptor (MPR) and transferrin receptor (TfR): one which is mediated by glucose transporter isoform 4(Glut4)-vesicles and another that bypasses this compartment. Under basal conditions, the first pathway is not active, and cell surface recycling of TfR and, to a lesser extent, MPR proceeds via the second pathway. Insulin dramatically stimulates recycling through the first pathway and has little effect on the second. Within the Glut4-containing compartment, insulin has profoundly different effects on intracellular trafficking of insulin-responsive aminopeptidase on one hand and MPR and TfR on the other. After insulin administration, insulin-responsive aminopeptidase is redistributed from Glut4-containing vesicles to the plasma membrane and stays there for at least 30 min with minimal detectable internalization and recycling, whereas MPR and TfR rapidly shuttle between Glut4 vesicles and the plasma membrane in such a way that after 30 min of insulin treatment, virtually every receptor molecule in this compartment completes at least one trafficking cycle to the cell surface. Thus, different recycling proteins, which compose Glut4-containing vesicles, are internalized into this compartment at their own distinctive rates.     

Recruitment of transferrin receptor to immunological synapse in response to TCR engagement

T cell receptor engagement by an APC induces the formation of a highly organized complex of surface receptors and intracellular signaling molecules, known as the immunological synapse, at the site of cell-cell contact. The transferrin receptor (TfR, CD71) is normally present in the plasma membrane and recycling endosomes. In this study, we show that, although the TfR is typically absent from lipid rafts at steady state, stimulation with a mitogenic mixture of anti-CD3 Abs of human Jurkat T cells leads to a rapid compartmentalization of the TfR into lipid rafts accompanying that of CD3epsilon and activated Lck. This change occurs very rapidly and is accompanied by an increase in the surface expression of the TfR, probably by translocation from an internal endosomal pool. TfR recruitment to lipid rafts was also observed in primary T cells treated with mitogenic anti-CD3 Abs and in Jurkat T cell-APC conjugates. The use of beads coated with Abs indicates that the surface and endosomal TfR pools redistribute to the contact site region in response to engagement of CD28 and CD3. In T cell-APC conjugates, the T cell TfR endosomal pool relocates beneath the contact site, whereas surface TfR localizes to the peripheral ring of the immunological synapse. In the presence of specific anti-TfR Abs, the total number of T cell-APC contacts and the percentage of conjugates with CD3 and Lck translocated to the contact site were reduced. Our results therefore suggest the involvement of the TfR in the formation of the immunological synapse.     

Internalization of Ia molecules by antigen-presenting B cells is limited

Our data demonstrate that the uptake of surface Ia into an intracellular compartment of B lymphoma or normal spleen cells is limited to about 20% after 2 to 3 h. The extent of internalization does not vary with several types of stimulation, including LPS, phorbol esters, anti-Ig-plus phorbol ester-stimulated EL-4 T cell supernatant, and Con A supernatant. Resting and activated B cells had similar rates of internalization. The rate and extent of uptake of surface Ia molecules into an intracellular compartment was monitored quantitatively through the use of a mAb radiolabeled with 125I. The internalization of Ia molecules was compared to that of transferrin receptor, a receptor that undergoes rapid internalization and recycling and accumulates in a intracellular pool that can be trapped by monensin. The internalization of Ia was not affected by monensin, although its synthetic pathway is disturbed by this drug. The potential use of internalized Ia for formation of T cell-triggering complexes of Ia and Ag fragments is not ruled out by these data, but it appears unlikely that internalization provides the major mechanism permitting Ia interaction with Ag.     

Role of vesicular traffic in the transport of surface transferrin receptor to the Golgi complex in cultured human cells.

We have previously shown that transferrin receptor (TfR) recycles from the cell surface through the Golgi complex in K562 human leukemia cells. However, little is known about the transport pathway that carries these receptors to the Golgi complex. To learn more about this transport, we studied the effects of treatments that block specific types of vesicular traffic. K562 cells were cultured in test media and the transport of surface TfR to the Golgi complex was assessed by measuring the entry of asialo-TfR into the sialyltransferase compartment of the Golgi complex. Depletion of cellular potassium, which blocks formation of coated vesicles at the cell surface, stimulated asialo-TfR resialylation by 60% over controls, suggesting that coated vesicle formation is not the rate-limiting step in cell surface-to-Golgi transport. Similarly, culture in sodium-free medium, which blocks transport from endosomes to lysosomes, increased asialo-TfR resialylation by 40%, arguing that lysosomes do not lie on the transport pathway. In contrast, incubation of cells in hypertonic medium, which blocks many vesicular transport steps, inhibited TfR resialylation by 40%, confirming the importance of vesicular traffic in transport of asialo-TfR from the cell surface to the Golgi complex. These results are consistent with two possible pathways for cell surface-to-Golgi transport. Receptor could be transported via an endosomal intermediate, with the rate-limiting step occurring at a post-endosomal site. Alternatively, receptor could be transported directly to the Golgi via a pathway that does not involve endosomes.     

Binding to the transferrin receptor is required for endocytosis of HFE and regulation of iron homeostasis

HFE, the protein that is mutated in hereditary haemochromatosis, binds to the transferrin receptor (TfR). Here we show that wild-type HFE and TfR localize in endosomes and at the basolateral membrane of a polarized duodenal epithelial cell line, whereas the primary haemochromatosis HFE mutant, and another mutant with impaired TfR-binding ability accumulate in the ER/Golgi and at the basolateral membrane, respectively. Levels of the iron-storage protein ferritin are greatly reduced and those of TfR are slightly increased in cells expressing wild-type HFE, but not in cells expressing either mutant. Addition of an endosomal-targeting sequence derived from the human low-density lipoprotein receptor (LDLR) to the TfR-binding-impaired mutant restores its endosomal localization but not ferritin reduction or TfR elevation. Thus, binding to TfR is required for transport of HFE to endosomes and regulation of intracellular iron homeostasis, but not for basolateral surface expression of HFE.     

Macrophage colony-stimulating factor differentially regulates low density lipoprotein and transferrin receptors

Endocytosis mediated by both LDL receptors (LDLRs) and transferrin receptors (TfRs) occurs in clathrin-coated pits and requires specific tyrosine-based internalization sequences located in the cytoplasmic domain of these receptors. Internalization of these receptors is mediated by endocytic proteins that interact with the internalization domains. We previously showed that macrophage colony-stimulating factor (M-CSF) rapidly increases LDLR-dependent uptake and metabolism of LDL. To study the mechanism by which M-CSF regulates LDL uptake, we compared the effect of M-CSF on the internalization of LDL and transferrin (Tf). Our results show that M-CSF substantially increased the rate of LDLR internalization without increasing LDLR localization on the cell surface. In contrast, M-CSF treatment of macrophages rapidly increased the localization of TfR to the cell surface but did not alter the relative rate of Tf internalization. Moreover, M-CSF regulated TfR and LDLR via the activation of distinct signaling pathways. Recruitment of TfR to the cell surface was attenuated by phosphatidylinositol 3-kinase inhibitors, whereas stimulated LDL uptake was inhibited by the serine/threonine phosphatase inhibitor okadaic acid. Taken together, our results indicate that M-CSF differentially regulates receptors that undergo endocytosis and that increased LDL uptake results from a selective increase in the rate of LDLR internalization.     

Characterization of the Interaction between Diferric Transferrin and Transferrin Receptor 2 by Functional Assays and Atomic Force Microscopy

Transferrin receptor 2 (TfR2), a homologue of the classical transferrin receptor 1 (TfR1), is found in two isoforms, α and β. Like TfR1, TfR2α is a type II membrane protein, but the β form lacks transmembrane portions and therefore is likely to be an intracellular protein. To investigate the functional properties of TfR2α, we expressed the protein with FLAG tagging in transferrin-receptor-deficient Chinese hamster ovary cells. The association constant for the binding of diferric transferrin (Tf) to TfR2α is 5.6 × 10⁶ M^− 1, which is about 50 times lower than that for the binding of Tf to TfR1, with correspondingly reduced rates of iron uptake. Evidence for Tf internalization and recycling via TfR2α without degradation, as in the TfR1 pathway, was also found. The interaction of TfR2α with Tf was further investigated using atomic force microscopy, a powerful tool used for investigating the interaction between a ligand and its receptor at the single-molecule level on the living cell surface. Dynamic force microscopy reveals a difference in the interactions of Tf with TfR2α and TfR1, with Tf-TfR1 unbinding characterized by two energy barriers, while only one is present for Tf-TfR2. We speculate that this difference may reflect Tf binding to TfR2α by a single lobe, whereas two lobes of Tf participate in binding to TfR1. The difference in the binding properties of Tf to TfR1 and TfR2α may help account for the different physiological roles of the two receptors.     

Internalization efficiency of the transferrin receptor.

Quantitative ultrastructural and biochemical methods have allowed us to obtain a coherent set of data on the internalization efficiency of the transferrin receptor (TfR). In confluent cell cultures we find that (1) the initial internalization rate of transferrin is approximately 10% per minute, and (2) around 10% of cell-surface TfRs are present in coated pits. From these data a lifetime of coated pits of ca. 1 min is derived. Furthermore, we show that coated pits constitute 1.1-1.4% of the plasma membrane area in confluent cell cultures. Thus, the TfR is concentrated six- to ninefold in coated pits compared to resident plasma membrane proteins. Moreover, we show that the concentration of TfRs in coated pits is cell density dependent, since only around 5% of the receptors are present in coated pits in low-density cultures. Correspondingly, the internalization of TfRs in high-density cell cultures is roughly twice as efficient as that in low-density cell cultures. The reduced TfR internalization efficiency at low cell density is accounted for by a concomitant decrease to 0.55% in the relative surface area occupied by coated pits.     

Influenza C virus uses 9-O-acetyl-N-acetylneuraminic acid as a high affinity receptor determinant for attachment to cells

Identification of the receptor-destroying enzyme of influenza C virus as a specific neuraminate O-acetylesterase has suggested that 9-O-acetyl-N-acetylneuraminic acid is an essential component of the cell surface receptor of influenza C virus (Herrler, G., Rott, R., Klenk, H.-D., Muller, H.-P., Shukla, A. K., and Schauer, R. (1985) EMBO (Eur. Mol. Biol. Organ.) J. 4, 1503-1506). In this report, three common sialic acids, N-acetylneuraminic acid (NeuAc), N-glycollylneuraminic acid (NeuGc), and 9-O-acetyl-N-acetylneuraminic acid (9-O-Ac-NeuAc) were compared for their ability to mediate attachment of influenza A, B, and C viruses to cells. Human asialoerythrocytes were resialylated to contain the three sialic acids in defined sequence on glycoprotein carbohydrate groups using purified sialyltransferases and corresponding CMP-sialic acid donor substrates. While influenza C virus failed to agglutinate native cells or resialylated cells containing NeuAc and NeuGc, resialylated cells containing 9-O-Ac-NeuAc in three different sialyloligosaccharide sequences were agglutinated in high titer. In contrast, most representative influenza A and B viruses examined preferentially agglutinated cells containing NeuAc and NeuGc and failed to agglutinate cells containing 9-O-Ac-NeuAc. Cells containing 9-O-Ac-NeuAc were sensitive to the action of influenza C virus neuraminate O-acetylesterase which converts 9-O-Ac-NeuAc to NeuAc. This treatment abolished agglutination by influenza C while making the cells agglutinable by several influenza A and B viruses. Finally, the ability of influenza C virus to agglutinate the erythrocytes of various species correlated with the presence of 9-O-Ac-NeuAc. The results provide direct evidence that influenza C virus utilizes 9-O-acetyl-N-acetylneuraminic acid as the primary receptor determinant for attachment to cell surface receptors.