Human transferrin receptor internalization is partially dependent upon an aromatic amino acid on the cytoplasmic domain.

The objective of this work is to identify the elements of the human transferrin receptor that are involved in receptor internalization, intracellular sorting, and recycling. We have found that an aromatic side chain at position 20 on the cytoplasmic portion of the human transferrin receptor is required for efficient internalization. The wild-type human transferrin receptor has a tyrosine at this position. Replacement of the Tyr-20 with an aromatic amino acid does not alter the rate constant of internalization, whereas substitution with the nonaromatic amino acids serine, leucine, or cysteine reduces the internalization rate constant approximately three-fold. These results are consistent with similar studies of other receptor systems that have also documented the requirement for a tyrosine in rapid internalization. The amino terminus of the transferrin receptor is cytoplasmic, with the tyrosine 41 amino acids from the membrane. These two features distinguish the transferrin receptor from the other membrane proteins for which the role of tyrosine in internalization has been examined, because these proteins have the opposite polarity with respect to the membrane and because the tyrosines are located closer to the membrane (within 25 amino acids). The externalization rate for the recycling of the transferrin receptor is not altered by any of these substitutions, demonstrating that the aromatic amino acid internalization signal is not required for the efficient exocytosis of internalized receptor.     

The NPXY internalization signal of the LDL receptor adopts a reverse-turn conformation.

Peptides corresponding to the proposed coated pit internalization signal of the native low density lipoprotein receptor, NPVY, take up in aqueous solution a reverse-turn conformation with the Asn in position i and the Tyr in position i + 3. By contrast, peptides derived from receptors that are defective for endocytosis do not adopt the reverse turn. These internalization-defective receptors include those with a nonaromatic residue substituted for the Tyr and those with Asn----Ala or Pro----Ala substitutions. While the tendency of an Asn-Pro sequence to induce a reverse turn was anticipated, the structural importance of an aromatic residue in position i + 3 was not. The sequences associated with the internalization signal thus appear to play a critical conformational role that is required for endocytosis, probably by enabling binding to adaptor molecules. With the results presented in the accompanying paper on lysosomal acid phosphatase, we now have direct evidence for previous proposals of a general correlation of internalization signals with a turn conformational motif.     

Mutational analysis of the cytoplasmic tail of the human transferrin receptor. Identification of a sub-domain that is required for rapid endocytosis

It has been reported that the sequence Tyr20-X-Arg-Phe23 present within the cytoplasmic tail of the transferrin receptor may represent a tyrosine internalization signal (Collawn, J.F., Stangel, M., Kuhn, L.A., Esekogwu, V., Jing, S., Trowbridge, I.S., and Tainer, J. A. (1990) Cell 63, 1061-1072). However, as Tyr20 is not conserved between species (Alvarez, E., Gironès, N., and Davis, R. J. (1990) Biochem. J. 267, 31-35), the functional role of the putative tyrosine internalization signal is not clear. To address this question, we constructed a series of 32 deletions and point mutations within the cytoplasmic tail of the human transferrin receptor. The effect of these mutations on the apparent first order rate constant for receptor endocytosis was examined. It was found that the region of the cytoplasmic tail that is proximal to the transmembrane domain (residues 28-58) is dispensable for rapid endocytosis. In contrast, the distal region of the cytoplasmic tail (residues 1-27) was found to be both necessary and sufficient for the rapid internalization of the transferrin receptor. The region identified includes Tyr20-X-Arg-Phe23, but is significantly larger than this tetrapeptide. It is therefore likely that structural information in addition to the proposed tyrosine internalization signal is required for endocytosis. To test this hypothesis, we investigated whether a heterologous tyrosine internalization signal (from the low density lipoprotein receptor) could function to cause the rapid endocytosis of the transferrin receptor. It was observed that this heterologous tyrosine internalization signal did not allow rapid endocytosis. We conclude that the putative tyrosine internalization signal (Tyr20-Thr-Arg-Phe23) is not sufficient to determine rapid endocytosis of the transferrin receptor. The data reported here indicate that the transferrin receptor internalization signal is formed by a larger cytoplasmic tail structure located at the amino terminus of the receptor.     

The amino terminus of GLUT4 functions as an internalization motif but not an intracellular retention signal when substituted for the transferrin receptor cytoplasmic domain

Previous studies have demonstrated that the amino-terminal cytoplasmic domain of GLUT4 contains a phenylalanine-based targeting motif that determines its steady state distribution between the surface and the interior of cells (Piper, R. C., C. Tai, P. Kuleza, S. Pang, D. Warnock, J. Baenziger, J. W. Slot, H. J. Geuze, C. Puri, and D. E. James. 1993. J. Cell Biol. 121:1221). To directly measure the effect that the GLUT4 amino terminus has on internalization and subsequent recycling back to the cell surface, we constructed chimeras in which this sequence was substituted for the amino-terminal cytoplasmic domain of the human transferrin receptor. The chimeras were stably transfected into Chinese hamster ovary cells and their endocytic behavior characterized. The GLUT4-transferrin receptor chimera was recycled back to the cell surface with a rate similar to the transferrin receptor, indicating that the GLUT4 sequence was not promoting intracellular retention of the chimera. The GLUT4-transferrin receptor chimera was internalized at half the rate of the transferrin receptor. Substitution of an alanine for phenylalanine at position 5 slowed internalization of the chimera by twofold, to a level characteristic of bulk membrane internalization. However, substitution of a tyrosine increased the rate of internalization to the level of the transferrin receptor. Neither of these substitutions significantly altered the rate at which the chimeras were recycled back to the cell surface. These results demonstrate that the major function of the GLUT4 amino-terminal domain is to promote the effective internalization of the protein from the cell surface, via a functional phenylalanine-based internalization motif, rather than retention of the transporter within intracellular structures.     

The internalization signal in the cytoplasmic tail of lysosomal acid phosphatase consists of the hexapeptide PGYRHV.

Lysosomal acid phosphatase (LAP) is rapidly internalized from the cell surface due to a tyrosine-containing internalization signal in its 19 amino acid cytoplasmic tail. Measuring the internalization of a series of LAP cytoplasmic tail truncation and substitution mutants revealed that the N-terminal 12 amino acids of the cytoplasmic tail are sufficient for rapid endocytosis and that the hexapeptide 411-PGYRHV-416 is the tyrosine-containing internalization signal. Truncation and substitution mutants of amino acid residues following Val416 can prevent internalization even though these residues do not belong to the internalization signal. It was shown recently that part of the LAP cytoplasmic tail peptide corresponding to 410-PPGY-413 forms a well-ordered beta turn structure in solution. Two-dimensional NMR spectroscopy of two modified LAP tail peptides, in which the single tyrosine was substituted either by phenylalanine or by alanine, revealed that the tendency to form a beta turn is reduced by 25% in the phenylalanine-containing peptide and by approximately 50% in the alanine-containing mutant peptide. Our results suggest, that in the short cytoplasmic tail of LAP tyrosine is required for stabilization of the right turn and that the aromatic ring system of the tyrosine residue is a contact point to the putative cytoplasmic receptor.     

Role of the human transferrin receptor cytoplasmic domain in endocytosis: localization of a specific signal sequence for internalization

Wild-type and mutant human transferrin receptors have been expressed in chicken embryo fibroblasts using a helper-independent retroviral vector. The internalization of mutant human transferrin receptors, in which all but four of the 61 amino acids of the cytoplasmic domain had been deleted, was greatly impaired. However, when expressed at high levels, such "tailless" mutant receptors could provide chicken embryo fibroblasts with sufficient iron from diferric human transferrin to support a normal rate of growth. As the rate of recycling of the mutant receptors was not significantly different from wild-type receptors, an estimate of relative internalization rates could be obtained from the distribution of receptors inside the cell and on the cell surface under steady-state conditions. This analysis and the results of iron uptake studies both indicate that the efficiency of internalization of tailless mutant receptors is approximately 10% that of wild-type receptors. Further studies of a series of mutant receptors with different regions of the cytoplasmic domain deleted suggested that residues within a 10-amino acid region (amino acids 19-28) of the human transferrin receptor cytoplasmic domain are required for efficient endocytosis. Insertion of this region into the cytoplasmic domain of the tailless mutant receptors restored high efficiency endocytosis. The only tyrosine residue (Tyr 20) in the cytoplasmic domain of the human transferrin receptor is found within this 10-amino acid region. A mutant receptor containing glycine instead of tyrosine at position 20 was estimated to be approximately 20% as active as the wild-type receptor. We conclude that the cytoplasmic domain of the transferrin receptor contains a specific signal sequence located within amino acid residues 19-28 that determines high efficiency endocytosis. Further, Tyr 20 is an important element of that sequence.     

A tyrosine motif in the cytoplasmic domain of mason-pfizer monkey virus is essential for the incorporation of glycoprotein into virions

Mason-Pfizer monkey virus (M-PMV) encodes a transmembrane (TM) glycoprotein with a 38-amino-acid-long cytoplasmic domain. After the release of the immature virus, a viral protease-mediated cleavage occurs within the cytoplasmic domain, resulting in the loss of 17 amino acids from the carboxy terminus. This maturational cleavage occurs between a histidine at position 21 and a tyrosine at position 22 in the cytoplasmic domain of the TM protein. We have demonstrated previously that a truncated TM glycoprotein with a 21-amino-acid-long cytoplasmic tail showed enhanced fusogenicity but could not be incorporated into virions. These results suggest that postassembly cleavage of the cytoplasmic domain removes a necessary incorporation signal and activates fusion activity. To investigate the contribution of tyrosine residues to the function of the glycoprotein complex and virus replication, we have introduced amino acid substitutions into two tyrosine residues found in the cytoplasmic domain. The effects of these mutations on glycoprotein biosynthesis and function, as well as on virus infectivity, have been examined. Mutation of tyrosine 34 to alanine had little effect on glycoprotein function. In contrast, substitutions at tyrosine 22 modulated fusion activity in either a positive or negative manner, depending on the substituting amino acid. Moreover, any nonaromatic substitution at this position blocked glycoprotein incorporation into virions and abolished infectivity. These results demonstrate that M-PMV employs a tyrosine signal for the selective incorporation of glycoprotein into budding virions. Antibody uptake studies show that tyrosine 22 is part of an efficient internalization signal in the cytoplasmic domain of the M-PMV glycoprotein that can also be positively and negatively influenced by changes at this site.     

Phosphorylation of the epidermal growth factor receptor at threonine 654 inhibits ligand-induced internalization and down-regulation

To assess the functional significance of phosphorylation of the epidermal growth factor (EGF) receptor at Thr654, we compared the effects of 12-O-tetradecanoyl-13-acetate (TPA) on ligand-induced internalization and down-regulation between wild-type and mutant receptors that contain an alanine substitution at position 654. Activation of protein kinase C with TPA blocked EGF-induced internalization and down-regulation of Thr654 receptors and inhibited in vivo tyrosine kinase activity by 80%. TPA did not inhibit transferrin receptor internalization or constitutive EGF receptor internalization, suggesting that protein kinase C activation inhibits only the ligand-induced process. Inhibition by TPA of induced internalization, down-regulation, and kinase activity required threonine at position 654 since full-length Ala654 EGF receptors were significantly resistant to TPA inhibition of these ligand-induced activities. However, C'-terminal truncation further enhanced this resistance to TPA inhibition. The EGF-dependent internalization of kinase-inactive receptors truncated at residue 1022 was also impaired by TPA in Thr654 receptors, but not in Ala654 receptors, indicating that phosphorylation at Thr654 also interferes with tyrosine kinase-independent receptor activities. We conclude that the dominant regulatory effect of protein kinase C on the EGF receptor is mediated through phosphorylation at Thr654 which effectively inactivates the receptor. The submembrane region of the EGF receptor appears to regulate transmission of conformational information from the extracellular ligand-binding site to the cytoplasmic kinase and regulatory domains.     

Localization of the signal for rapid internalization of the bovine cation-independent mannose 6-phosphate/insulin-like growth factor-II receptor to amino acids 24-29 of the cytoplasmic tail.

The signal for the rapid internalization of the cation-independent mannose 6-phosphate/insulin-like growth factor-II receptor has been previously localized to the inner half of the 163-amino acid cytoplasmic tail, including tyrosine 24 and tyrosine 26 (Lobel, P., Fujimoto, K., Ye, R. D., Griffiths, G., and Kornfeld, S. (1989) Cell 57, 787-796). To define this signal more precisely, we generated a series of truncation and substitution mutants and analyzed them for their ability to mediate the endocytosis of extracellular lysosomal enzymes. Mutant receptors containing cytoplasmic domains of 29 or more amino acids functioned normally in endocytosis whereas a mutant receptor with a 28-amino acid cytoplasmic domain was internalized extremely slowly. Alanine scanning of the region between amino acids 19 and 30 identified tyrosine 26 and valine 29 as the most important residues for rapid receptor internalization. Tyrosine 24 and lysine 28 also contributed to the signal while the other amino acids were not critical. The tyrosine residues could be substituted with phenylalanines with no loss of activity, indicating the requirement for an aromatic residue in these positions rather than tyrosine specifically. Conservative substitutions of arginine or histidine for lysine 28 also preserved the internalization signal. These results indicate that the sequence Tyr-Lys-Tyr-Ser-Lys-Val serves as the internalization signal for the mannose 6-phosphate/insulin-like growth factor-II receptor. The crucial elements of this sequence are present in the cytoplasmic tails of a number of other membrane receptors and proteins known to undergo rapid internalization.     

A point mutation in the cytoplasmic domain of the transferrin receptor inhibits endocytosis.

The rate of receptor-mediated endocytosis of diferric 125I-transferrin by Chinese-hamster ovary cells expressing human transferrin receptors was compared with the rate measured for cells expressing hamster transferrin receptors. It was observed that the rate of endocytosis of the human transferrin receptor was significantly higher than that for the hamster receptor. In order to examine the molecular basis for the difference between the observed rates of endocytosis, a cDNA clone corresponding to the cytoplasmic domain of the hamster receptor was isolated. The predicted primary sequence of the cytoplasmic domain of the hamster transferrin receptor is identical with that of the human receptor, except at position 20, where a tyrosine residue in the human sequence is replaced with a cysteine residue. To test the hypothesis that this structural change in the receptor is related to the difference in the rate of internalization, we used site-directed mutagenesis to examine the effect of the replacement of tyrosine-20 with a cysteine residue in the human transferrin receptor. It was observed that the substitution of tyrosine-20 with cysteine caused a 60% inhibition of the rate of iron accumulation by cells incubated with [59Fe]diferric transferrin. No significant difference between the rate of internalization of the mutant (cysteine-20) human receptor and the hamster receptor was observed. Thus the substitution of tyrosine-20 with a cysteine residue can account for the difference between the rate of endocytosis of the human and hamster transferrin receptors.     

NPXY, a sequence often found in cytoplasmic tails, is required for coated pit-mediated internalization of the low density lipoprotein receptor

Rapid internalization of the cell surface low density lipoprotein (LDL) receptor requires the first 22 amino acids of the cytoplasmic domain (residues 790-811), which must include an aromatic residue at position 807. In the human LDL receptor, this position is part of a tetrameric sequence, NPVY. A similar tetramer, NPXY (where X stands for any amino acid), is conserved in LDL receptors from six species (including Xenopus laevis) and in two members of the LDL receptor gene family, human LDL receptor-related protein and rat GP330. To determine whether the NPXY sequence is necessary for coated pit-mediated internalization, we used oligonucleotide-directed mutagenesis to substitute alanines for individual amino acids in the cytoplasmic tail of the human LDL receptor. Substitution of alanine for Asn804, Pro805, or Tyr807 (but not Val806) markedly reduced internalization. Only one other amino acid in the cytoplasmic 22-mer (Phe802) was important for internalization. A review of published data revealed NPXY sequences in cytoplasmic domains of at least 10 other cell surface proteins, including tyrosine kinase-linked receptors of the epidermal growth factor and insulin receptor family, the beta-subunits of three integrin receptors, and the amyloid A4 precursor protein. This occurrence is much more frequent than would be expected by chance alone. The possibility of a conditional role for the NPXY sequence in ligand-independent internalization of these proteins is discussed.     

Transplanted LDL and mannose-6-phosphate receptor internalization signals promote high-efficiency endocytosis of the transferrin receptor.

The internalization signals of several constitutively recycling receptors have recently been identified as regions of four or six amino acids that include an aromatic residue, usually tyrosine. Here, we show that transplanted signals from the low density lipoprotein receptor (LDLR) and cation-independent mannose-6-phosphate receptor (Man-6-PR) promote rapid internalization of the transferrin receptor (TR), directly establishing that recognition signals are interchangeable, self-determined structural motifs and that signals from type I membrane proteins are active in a type II receptor. We also show that the chemical and spatial patterns of critical residues in both four- and six-residue internalization motifs are consistent with a tight turn structure. A six-residue LDLR signal is needed for activity in TR, suggesting that an amino-terminal aromatic side chain is obligatory. In contrast, the carboxy-terminal aromatic side chain in the TR signal can be replaced by a large hydrophobic residue. Thus, internalization signals apparently require an aromatic amino-terminal residue and either an aromatic or large hydrophobic carboxy-terminal residue rather than a conserved tyrosine per se. Consistent with this conclusion, predicted internalization signals from the poly-Ig receptor, YSAF, and asialoglycoprotein receptor (ASGPR) subunit H1, YQDL, also promote internalization of TR.     

Ligand-induced internalization and increased cell calcium are mediated via distinct structural elements in the carboxyl terminus of the epidermal growth factor receptor.

Signals that can mediate ligand-induced receptor internalization and calcium regulation are present in a 48-amino acid "calcium-internalization" domain in the C' terminus of the epidermal growth factor (EGF) receptor. The basis of calcium and internalization regulation signalled by this 48-amino acid sequence was analyzed using deletion and substitution mutant receptors. Cells expressing truncated receptors containing either the NH2- or COOH-terminal portion of the 48-residue domain displayed high affinity EGF-dependent endocytosis and receptor down-regulation. These endocytosis-competent EGF receptor mutants that lacked any autophosphorylation site were unable to increase the concentration of intracellular calcium. To investigate the role of self-phosphorylation in EGF-induced calcium mobilization, phenylalanine was substituted for the single autophosphorylated tyrosine residue in this region of an internalization-competent truncated receptor. The receptor-mediated calcium response was abolished, while ligand-dependent receptor internalization was unimpaired. These results demonstrate that EGF-dependent receptor endocytosis and calcium mobilization are separate events. Tyrosine self-phosphorylation is required for increased [Ca2+]i, while structural features distinct from autophosphorylation are required for receptor internalization.     

Transferrin receptor internalization sequence YXRF implicates a tight turn as the structural recognition motif for endocytosis

Using detailed functional studies on 24 human transferrin receptor mutants, we identified YXRF as the internalization sequence. Provided that at least 7 residues separate this tetrapeptide from the transmembrane region, changing the tetrapeptide position within the TR cytoplasmic domain does not reduce internalization activity. Thus, any conformational determinant for internalization must be localized to the YXRF sequence. Twenty-eight tetrapeptide analogs of YXRF, found by an unbiased search of all known three-dimensional protein structures, significantly favored tight turns similar to a type I turn. Of the ten tetrapeptides most closely related to YXRF, eight were surface exposed and had tight-turn conformations, as were four of five tetrapeptides with sequences related to the low density lipoprotein receptor internalization motif, NPXY. The internalization sequences of both receptors contain aromatic residues with intervening hydrogen-bonding residues. Thus, two distinct internalization sequences favor a common structural chemistry and implicate an exposed tight turn as the recognition motif for high efficiency endocytosis.     

Endocytosis of the transferrin receptor requires the cytoplasmic domain but not its phosphorylation site

The transferrin receptor (TR) mediates cellular iron uptake by bringing about the endocytosis of transferrin. We investigated whether the cytoplasmic domain of 65 N-terminal amino acids or phosphorylated sites within this domain constitute a structure that is required for TR endocytosis. To test this hypothesis, we modified the cytoplasmic serine residues or introduced a deletion of 36 amino acids by in vitro mutagenesis of a cDNA expression vector for human TR. Upon expression in transfected mouse Ltk- cells, both the wild-type and phosphorylation site mutant receptors mediated transferrin internalization, whereas the truncated receptor did not. These results provide evidence that the cytoplasmic domain, or part of it, is essential for internalization of the TR, but argue against a role for receptor phosphorylation in endocytosis.     

Deletions in the cytoplasmic domain of the polymeric immunoglobulin receptor differentially affect endocytotic rate and postendocytotic traffic

We have examined the function of the cytoplasmic domain of the polymeric immunoglobulin receptor (pIg-R) by producing two separate deletions in the cytoplasmic domain of the pIg-R, expressing the mutant receptors in polarized MDCK cells, and analyzing each for their effects on receptor and ligand traffic. Deletion of the C-terminal 30 amino acids (726-755) reduces the rate of internalization of receptor-bound ligand from the basolateral surface. However, this mutation has no effect on delivery of receptor from the Golgi to the basolateral surface or the post-endocytotic traffic of receptor and ligand. Mutation of a tyrosine at position 734 to serine produces a receptor with a similar phenotype. If residues 670-707 are deleted from the middle of the cytoplasmic domain, both basolateral delivery and internalization are unaffected. However, unlike wild type, after endocytosis from the basolateral surface, both receptor and ligand are largely degraded. We reported previously that deletion of the entire cytoplasmic domain prevents the basolateral delivery of newly synthesized receptor (Mostov, K.E., de Bruyn Kops, A., and Deitcher, D.L. (1986) Cell 47, 359-364). In contrast, the mutants reported here are delivered to the basolateral surface, suggesting that only residues 653-669 and/or 708-725 are necessary for basolateral delivery. Thus, different deletions in the cytoplasmic domain of the pIg-R can produce mutant receptors which alter different aspects of receptor traffic.     

Multiple autophosphorylation sites of the epidermal growth factor receptor are essential for receptor kinase activity and internalization. Contrasting significance of tyrosine 992 in the native and truncated receptors.

The role of epidermal growth factor (EGF) receptor autophosphorylation sites in the regulation of receptor functions has been studied using cells transfected with mutant EGF receptors. Simultaneous point mutation of 4 tyrosines (Y1068, Y1086, Y1148, Y1173) to phenylalanine, as well as removal of these sites by truncation of the carboxyl-terminal 123 amino acid residues, resulted in reduced receptor phosphorylation of an in vivo specific substrate phospholipase C-gamma 1 to less than 50% compared to the wild-type receptor. The internalization rate constant Ke was also significantly lower in these mutants (0.15/min) compared to cells transfected with wild-type receptor (0.27/min). Additional mutation of tyrosine 992 to phenylalanine in the truncated receptor mutant (Dc-123F) further decreased the receptor internalization rate to a minimal level (ke = 0.07-0.10/min), equivalent to the ke measured for cells expressing kinase-negative receptor (A721). Moreover, tyrosine kinase activity of the Dc-123F receptor toward phospholipase C-gamma 1, compared to wild-type receptor, was reduced by 90%. Taken together, these results show that EGF receptor lacking five autophosphorylation sites functions similar to a kinase-negative receptor. Mutation of tyrosine residue Y992 alone in the context of full length EGF receptor, however, did not affect receptor internalization or kinase activity toward phospholipase C-gamma 1. These data indicate that tyrosine 992 is critical for substrate phosphorylation and internalization only in the context of the truncated receptor, and that minor autophosphorylation sites, such as Y992, may act as compensatory regulatory sties in the absence of the major EGF receptor autophosphorylation sites.     

Endosome acidification and receptor trafficking: bafilomycin A1 slows receptor externalization by a mechanism involving the receptor's internalization motif.

To examine the relationship between endosome acidification and receptor trafficking, transferrin receptor trafficking was characterized in Chinese hamster ovary cells in which endosome acidification was blocked by treatment with the specific inhibitor of the vacuolar H(+)-ATPase, bafilomycin A1. Elevating endosome pH slowed the receptor externalization rate to approximately one-half of control but did not affect receptor internalization kinetics. The slowed receptor externalization required the receptor's cytoplasmic domain and was largely eliminated by substitutions replacing either of two aromatic amino acids within the receptor's cytoplasmic YTRF internalization motif. These results confirm, using a specific inhibitor of the vacuolar proton pump, that proper endosome acidification is necessary to maintain rapid recycling of intracellular receptors back to the plasma membrane. Moreover, receptor return to the plasma membrane is slowed in the absence of proper endosome acidification by a signal-dependent mechanism involving the receptor's cytoplasmic tyrosine-containing internalization motif. These results, in conjunction with results from other studies, suggest that the mechanism for clustering receptors in plasma membrane clathrin-coated pits may be an example of a more general mechanism that determines the dynamic distribution of membrane proteins among various compartments with luminal acidification playing a crucial role in this process.     

Endocytosis and recycling of varicella-zoster virus Fc receptor glycoprotein gE: internalization mediated by a YXXL motif in the cytoplasmic tail.

Varicella-zoster virus (VZV) encodes a cell surface Fc receptor, glycoprotein gE. VZV gE has previously been shown to display several features common to nonviral cell surface receptors. Most recently, VZV gE was reported to be tyrosine phosphorylated on a dimeric form (J. K. Olson, G. A. Bishop, and C. Grose, J. Virol. 71:110-119, 1997). Thereafter, attention focused on the ability of VZV gE to undergo receptor-mediated endocytosis. The current transient transfection studies demonstrated by confocal microscopy and internalization assays that VZV gE was endocytosed when expressed in HeLa cells. Endocytosis of gE was shown to be dependent on clathrin-coated vesicle formation within the cells. Subsequent colocalization studies showed that endocytosis of VZV gE closely mimicked endocytosis of the transferrin receptor. The gE cytoplasmic tail and more specifically tyrosine residue 582 were determined by mutagenesis studies to be important for efficient internalization of the protein; this tyrosine residue is part of a conserved YXXL motif. The amount of gE internalized at any given time reached a steady state of 32%. In addition, like the transferrin receptor, internalized gE recycled to the cell surface. The finding of gE endocytosis provided insight into earlier documentation of gE serine/threonine and tyrosine phosphorylation, since these phosphorylation events may serve as sorting signals for internalized receptors. Taken together with the previous discovery that both human and simian immunodeficiency virus envelope proteins can undergo endocytosis, the gE findings suggest that endocytosis of envelope components may be a posttranslational regulatory mechanism among divergent families of enveloped viruses.