Sorting mechanisms regulating membrane protein traffic in the apical transcytotic pathway of polarized MDCK cells.

The transcytotic pathway followed by the polymeric IgA receptor (pIgR) carrying its bound ligand (dIgA) from the basolateral to the apical surface of polarized MDCK cells has been mapped using morphological tracers. At 20 degreesC dIgA-pIgR internalize to interconnected groups of vacuoles and tubules that comprise the endosomal compartment and in which they codistribute with internalized transferrin receptors (TR) and epidermal growth factor receptors (EGFR). Upon transfer to 37 degreesC the endosome vacuoles develop long tubules that give rise to a distinctive population of 100-nm-diam cup-shaped vesicles containing pIgR. At the same time, the endosome gives rise to multivesicular endosomes (MVB) enriched in EGFR and to 60-nm-diam basolateral vesicles. The cup-shaped vesicles carry the dIgA/pIgR complexes to the apical surface where they exocytose. Using video microscopy and correlative electron microscopy to study cells grown thin and flat we show that endosome vacuoles tubulate in response to dIgA/pIgR but that the tubules contain TR as well as pIgR. However, we show that TR are removed from these dIgA-induced tubules via clathrin-coated buds and, as a result, the cup-shaped vesicles to which the tubules give rise become enriched in dIgA/pIgR. Taken together with the published information available on pIgR trafficking signals, our observations suggest that the steady-state concentrations of TR and unoccupied pIgR on the basolateral surface of polarized MDCK cells are maintained by a signal-dependent, clathrin-based sorting mechanism that operates along the length of the transcytotic pathway. We propose that the differential sorting of occupied receptors within the MDCK endosome is achieved by this clathrin-based mechanism continuously retrieving receptors like TR from the pathways that deliver pIgR to the apical surface and EGFR to the lysosome.

Analysis of the structural requirements for lysosomal membrane targeting using transferrin receptor chimeras.

The sorting of membrane proteins to the lysosome requires tyrosine- or dileucine-based targeting signals. Recycling receptors have similar signals, yet these proteins seldom enter the latter stages of the endocytic pathway. To determine how lysosomal and internalization signals differ, we prepared chimeric molecules consisting of the cytoplasmic tails of CD3 gamma-chain, lysosomal acid phosphatase, and lysosomal-associated membrane glycoprotein-1, each fused to the transmembrane and extracellular domains of the transferrin receptor (TR). Each chimera was expressed on the cell surface and rapidly internalized. Metabolic pulse-chase experiments showed that the CD3 gamma-chain and lysosomal acid phosphatase chimeras, unlike the lysosomal-associated membrane glycoprotein chimera, were rapidly degraded in a post-Golgi compartment following normal glycosylation. Transplantation of signals from CD3 gamma-chain and lysosomal acid phosphatase into the TR cytoplasmic tail in place of the native signal, Y20TRF23, indicated that each signal was sufficient to promote endocytosis but not lysosomal targeting of the resulting mutant. Transplantation of two CD3 signals at specific sites in the TR cytoplasmic tail or a single tyrosine-based signal in a truncated TR tail, however, was sufficient to promote lysosomal targeting. Our results therefore suggest that the relative position of the signal within the cytoplasmic tail is a critical feature that distinguishes lysosomal targeting signals from internalization signals.

In polarized MDCK cells basolateral vesicles arise from clathrin-gamma-adaptin-coated domains on endosomal tubules.

Human transferrin receptors (TR) and receptors for polymeric immunoglobulins (pIgR) expressed in polarized MDCK cells maintain steady-state, asymmetric distributions on the separate basolateral and apical surfaces even though they are trafficking continuously into and across these cells. The intracellular mechanisms required to maintain these asymmetric distributions have not been located. Here we show that TR and pIgR internalize from both surfaces to a common interconnected endosome compartment that includes tubules with buds coated with clathrin lattices. These buds generate vesicles that carry TR to the basolateral border. The lattices contain gamma-adaptin and are dispersed by treatment with brefeldin A (BFA). Since BFA treatment abrogates the vectorial trafficking of TR in polarized MDCK cells, we propose that the clathrin-coated domains of the endosome tubules contain the polarized sorting mechanism responsible for their preferential basolateral distribution.

Signal-dependent trafficking of beta-amyloid precursor protein-transferrin receptor chimeras in madin-darby canine kidney cells.

We have investigated the intracellular trafficking of a chimeric molecule consisting of the cytoplasmic domain of the beta-amyloid precursor protein (APP) and the transmembrane region and external domain of the human transferrin receptor (TR) in Madin-Darby canine kidney cells. Newly synthesized APP-TR chimeras are selectively targeted to the basolateral surface by a tyrosine-dependent sorting signal in the APP cytoplasmic tail. APP-TR chimeras are then rapidly internalized from the basolateral surface and a significant fraction ( approximately 20-30%) are degraded. Morphological studies show that APP-TR chimeras internalized from the basolateral surface are found in tubulo-vesicular endosomal elements, internal membranes of multivesicular bodies, and lysosomes. APP-TR chimeras are also found in 60-nm diameter vesicles previously shown to selectively deliver wild-type TR to the basolateral surface; this result is consistent with the fact that 90% of internalized chimeras that are not degraded are selectively recycled back to the basolateral surface. APP-TR chimeras internalized from the apical surface are selectively transcytosed to the basolateral surface underscoring the importance of basolateral sorting in the endocytic pathway for maintaining the polarized phenotype. Tyr-653, an important element of the YTSI internalization signal in the APP cytoplasmic domain, is required for basolateral sorting in the biosynthetic and endocytic pathways. However, the structural features for basolateral sorting differ from those required for internalization.

Structural requirements for basolateral sorting of the human transferrin receptor in the biosynthetic and endocytic pathways of Madin-Darby canine kidney cells.

In polarized Madin-Darby canine kidney (MDCK) cells, the transferrin receptor (TR) is selectively delivered to the basolateral surface, where it internalizes transferrin via clathrin-coated pits and recycles back to the basolateral border. Mutant tailless receptors are sorted randomly in both the biosynthetic and endocytic pathways, indicating that the basolateral sorting of TR is dependent upon a signal located within the 61-amino acid cytoplasmic domain. To identify the basolateral sorting signal of TR, we have analyzed a series of mutant human TR expressed in MDCK cells. We find that residues 19-41 are sufficient for basolateral sorting from both the biosynthetic and endocytic pathways and that this is the only region of the TR cytoplasmic tail containing basolateral sorting information. The basolateral sorting signal is distinct from the YTRF internalization signal contained within this region and is not tyrosine based. Detailed functional analyses of the mutant TR indicate that residues 29-35 are the most important for basolateral sorting from the biosynthetic pathway. The structural requirements for basolateral sorting of internalized receptors from the endocytic pathway are not identical. The most striking difference is that alteration of G31DNS34 to YTRF impairs basolateral sorting of newly synthesized receptors from the biosynthetic pathway but not internalized receptors from the endocytic pathway. Also, mutations have been identified that selectively impair basolateral sorting of internalized TRs from the endocytic pathway without affecting basolateral sorting of newly synthesized receptors. These results imply that there are subtle differences in the recognition of the TR basolateral sorting signal by separate sorting machinery located within the biosynthetic and endocytic pathways.

Structural requirements for major histocompatibility complex class II invariant chain trafficking in polarized Madin-Darby canine kidney cells.

The invariant chain (Ii) targets major histocompatibility complex class II molecules to an endocytic processing compartment where they encounter antigenic peptides. Analysis of Ii-transferrin receptor chimeras expressed in polarized Madin-Darby canine kidney (MDCK) cells shows that the Ii cytoplasmic tail contains a dihydrophobic basolateral sorting signal, Met16-Leu17, which is recognized in both the biosynthetic and endocytic pathways. Pro15-Met16-Leu17 has previously been identified as one of two dihydrophobic Ii internalization signals active in non-polarized cells. Pro15 is also required for endocytosis in MDCK cells but not for basolateral sorting, indicating that the internalization signal recognized at the plasma membrane is distinct from the sorting signal recognized by basolateral sorting machinery. Another dihydrophobic sequence, Leu7-Ile8, is required for rapid internalization of the chimeric receptors in MDCK cells but not for basolateral sorting, providing further evidence that the structural requirements for basolateral sorting and internalization differ. Deletion analysis suggests that basolateral sorting of newly synthesized Ii-TR chimeras is also mediated by the membrane-proximal region of the Ii cytoplasmic tail. However, this region does not promote polarized basolateral recycling, indicating that the structural requirements for polarized sorting in the biosynthetic and endocytic pathways are not identical.

Apical and basolateral endosomes of MDCK cells are interconnected and contain a polarized sorting mechanism.

We have evaluated transcytotic routes in MDCK cells for their ability to generate a polarized surface distribution of trafficking proteins by following the intracellular sorting of transferrin receptors (TRs). We find that the selective basolateral expression of TRs is maintained in the face of extensive trafficking between the apical and basolateral surfaces. Biochemical studies of receptors loaded with tracer under conditions approaching steady state indicate that TRs internalized from the two surfaces are extensively colocalized within MDCK cells and that both populations of receptors are selectively delivered to the basolateral surface. Tailless TRs in which the cytoplasmic domain has been deleted display an unpolarized cell surface distribution and recycle in an unpolarized fashion. We show by EM that wild-type receptors internalized from each surface are colocalized within endosomal elements distributed throughout the cytoplasm. By preloading endosomal elements directly accessible from the basolateral surface with transferrin (Tf)-HRP, we show that apically internalized TRs rapidly enter the same compartment. We also show that both transcytosing (apically internalized) and recycling (basolaterally internalized) TRs are delivered to the basolateral border by a distinctive subset of exocytotic, 60-nm-diam vesicles. Together, the biochemical and morphological data show that apical and basolateral endosomes of MDCK cells are interconnected and contain a signal-dependent polarized sorting mechanism. We propose a dynamic model of polarized sorting in MDCK cells in which a single endosome-based, signal-dependent sorting step is sufficient to maintain the polarized phenotype.

Functional analysis of human/chicken transferrin receptor chimeras indicates that the carboxy-terminal region is important for ligand binding.

Chimeric human/chicken transferrin receptors have been constructed using the polymerase chain reaction. Different regions of the 671-residue external domain of the human transferrin receptor were replaced by the corresponding sequences from the chicken transferrin receptor. As chicken transferrin receptors do not bind human transferrin, functional analysis of such chimeric receptors provides an approach to define the ligand-binding site of the human transferrin receptor. Four of 16 chimeric human/chicken transferrin receptors expressed in chick embryo fibroblasts were efficiently transported to the plasma membrane and displayed on the cell surface. Studies of the four chimeric receptors indicated that binding of human transferrin was abolished if the carboxy terminal 192 amino acids of the human transferrin receptor (residues 569-760) were replaced with the corresponding region from the chicken transferrin receptor. Further, a chimeric receptor in which the carboxy-terminal 72 residues were derived from the chicken transferrin receptor exhibited a 16-fold decrease in binding affinity for human transferrin. In contrast, analysis of the other two chimeric receptors showed that 340 amino acids of the human transferrin receptor external domain more proximal to the transmembrane region (residues 151-490) could be replaced with the corresponding region from the chicken transferrin receptor without loss of high-affinity ligand binding. In contrast, two mAbs against the human transferrin receptor external domain, B3/25 and D65.3, that do not compete with transferrin binding, do not bind the chimeric transferrin receptors in which the membrane proximal part is replaced by chicken sequences, while they do bind the two other chimeric transferrin receptors with high affinity. These data indicate that sequence differences in the carboxy-terminal region of human and chicken transferrin receptor external domains are important for the species specificity of transferrin binding and imply that this portion of the human transferrin receptor is critical for ligand binding.

Transmembrane domain of CD44 is required for its detergent insolubility in fibroblasts.

The hyaluronan receptor CD44 is an abundant glycoprotein expressed on a variety of different cell types. In fibroblasts a significant portion of receptor molecules remain in the detergent-insoluble fraction after Triton X-100 extraction. Detergent insolubility of these CD44 molecules has been interpreted to reflect their association with the cytoskeleton. In this study we examined the structural features of CD44 required for its Triton X-100 insolubility in murine fibroblasts. We expressed in L cells the wild-type hematopoietic form of CD44, a mutant CD44 lacking the cytoplasmic domain, and two mutant CD44 molecules with substituted transmembrane domains. Immunofluorescence and cell surface iodination were performed and the detergent extraction profile of the transfected CD44 molecules was determined. No difference in detergent solubility was observed between wild-type and tailless mutant-transfected molecules. However, both CD44 mutants with a heterologous transmembrane domain, derived from either the CD3 zeta chain or CD45, were completely soluble in Triton X-100. These results demonstrate that the transmembrane region but not the cytoplasmic domain of CD44 is required for the detergent-insolubility in these cells. No obvious colocalization of CD44 and actin stress fibers was observed before or after treatment with cytochalasin D, and no change in the detergent extraction profile of wild-type and mutant CD44 molecules was effected by cytochalasin D. In equilibrium density sucrose gradients the Triton-insoluble CD44 component was found in the low density fractions, indicating an association with Triton X-100-insoluble lipids.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of sorting signals in the beta-amyloid precursor protein cytoplasmic domain.

The beta-amyloid precursor protein (APP) is proteolytically processed to generate beta-amyloid protein, the principal protein component of neuropathological lesions characteristic of Alzheimer's disease. To investigate potential sorting signals in the cytoplasmic tail of APP, we transplanted APP cytoplasmic tail sequences into the cytoplasmic tail of the human transferrin receptor (TR) and showed that two sequence motifs from the APP cytoplasmic tail promote TR internalization. One sequence, GYENPTY, is related to the low density lipoprotein receptor internalization signal, FDNPVY, but also involves a critical glycine residue; the other, YTSI, conforms to the 4-residue tyrosine-based internalization signal consensus sequence. Furthermore, a chimeric molecule (APP-TR) consisting of the cytoplasmic domain of APP and the transmembrane and external domains of TR was rapidly internalized enabling the transport of iron into the cell at approximately 50% the rate of wild-type TR. Alanine scanning mutations indicated that the two sequences identified in transplantation experiments were required for internalization of the chimera. Metabolic pulse-chase experiments showed that the APP-TR chimeras were degraded in a post-Golgi membrane compartment within 2-4 h following normal glycosylation. Degradation was partially dependent upon the two internalization signals and was inhibited by ammonium chloride. A fraction of APP-TR chimeras traffic to a degradative endocytic compartment after appearing on the cell surface. Comparison of soluble APP released from cells expressing either full-length human APP or mutant APP with the sequence YENPTY deleted indicated that this sequence is required for sorting of full-length APP along similar trafficking pathways as the APP-TR chimera.

Sorting signals in the MHC class II invariant chain cytoplasmic tail and transmembrane region determine trafficking to an endocytic processing compartment.

Targeting of MHC class II molecules to the endocytic compartment where they encounter processed antigen is determined by the invariant chain (Ii). By analysis of Ii-transferrin receptor (TR) chimera trafficking, we have identified sorting signals in the Ii cytoplasmic tail and transmembrane region that mediate this process. Two non-tyrosine-based sorting signals in the Ii cytoplasmic tail were identified that mediate localization to plasma membrane clathrin-coated pits and promote rapid endocytosis. Leu7 and Ile8 were required for the activity of the signal most distal to the cell membrane whereas Pro15 Met16 Leu17 were important for the membrane-proximal signal. The same or overlapping non-tyrosine-based sorting signals are essential for delivery of Ii-TR chimeras, either by an intracellular route or via the plasma membrane, to an endocytic compartment where they are rapidly degraded. The Ii transmembrane region is also required for efficient delivery to this endocytic processing compartment and contains a signal distinct from the Ii cytoplasmic tail. More than 80% of the Ii-TR chimera containing the Ii cytoplasmic tail and transmembrane region is delivered directly to the endocytic pathway by an intracellular route, implying that the Ii sorting signals are efficiently recognized by sorting machinery located in the trans-Golgi.

In migrating fibroblasts, recycling receptors are concentrated in narrow tubules in the pericentriolar area, and then routed to the plasma membrane of the leading lamella.

By following the intracellular processing of recycling transferrin receptors and the selective sorting of a-2 macroglobulin in chick embryo fibroblasts, we have shown that the concentration of 60 nm diam tubules which surrounds the centrioles represents a distal compartment on the recycling pathway. In migrating cells transferrin receptor tracers can be loaded into this compartment and then chased to the cell surface. When they emerge the recycling transferrin receptors are distributed over the surface of the leading lamella.

CD45: an emerging role as a protein tyrosine phosphatase required for lymphocyte activation and development.

CD45 is one of the most abundant leukocyte cell surface glycoproteins and is expressed exclusively upon cells of the hematopoietic system. Different isoforms of CD45 are generated by alternative splicing and are expressed in cell type-specific patterns on functional subpopulations of lymphocytes. In a major advance, CD45 was identified as one of the first members of a novel class of enzymes, the protein tyrosine phosphatases (PTPs). This serendipitous discovery linked CD45 to the process of reversible protein tyrosine phosphorylation, a key regulatory mechanism for controlling the growth and division of eukaryotic cells, and provided the impetus for most of the studies described in this review. CD45 is now established as a critical component of the signal transduction machinery of lymphocytes. In particular, evidence from genetic experiments indicates that CD45 plays a pivotal role in antigen-stimulated proliferation of T lymphocytes and in thymic development. Two members of the Src-family of protein tyrosine kinases (PTKs), the p56lck and p59fyn proteins, have been implicated as physiological substrates of CD45, providing an important clue to how the action of this leukocyte-specific PTP might influence signaling by the T cell antigen receptor. Structure-function analysis of CD45 and other PTPs has identified structural features of PTP catalytic domains required for enzymatic activity. However, despite intensive efforts, little is known about how the activity of CD45 is regulated. The external domain of CD45 does not appear to be absolutely required for signal transduction by the T cell receptor, and there is currently no evidence that ligand binding modulates CD45 activity. Analysis of CD45 isoform expression has revealed a hitherto unrecognized plasticity in isoform usage by T cells and other leukocytes, adding to the regulatory complexity of isoform expression.

YTRF is the conserved internalization signal of the transferrin receptor, and a second YTRF signal at position 31-34 enhances endocytosis.

By functional analysis of mutant human transferrin receptors (TR) expressed in chicken embryo fibroblasts, we previously identified a tetrapeptide sequence, Y20TRF23, within the 61-residue cytoplasmic tail as the signal for high-efficiency endocytosis (Collawn, J. F., Stangel, M., Kuhn, L. A., Esekogwu, V., Jing, S., Trowbridge, I.S., and Tainer, J.A. (1990) Cell 63, 1061-1072). It has been inferred from other studies, however, that the TR internalization signal was localized to a much larger region, residues 7 through 26 (Girones, N., Alvarez, E., Seth, A., Lin, I-M., Latour, D.A., and Davis, R.J. (1991) J. Biol. Chem. 266, 19006-19012). Additionally, Tyr20 was reported to not be conserved in the Chinese hamster cytoplasmic tail sequence (Alvarez, E., Girones, N., and Davis, R.J. (1990) Biochem. J. 267, 31-35). In the studies reported here, we examined the effect of insertion of an extra copy of a YTRF sequence at three different locations within the human TR cytoplasmic domain and show that the insertion of another YTRF signal at position 31-34 in the wild-type TR, but not the other two locations, increases the rate of endocytosis 2-fold. Furthermore, introduction of YTRF at position 31-34 in an internalization-defective mutant receptor restores endocytosis to wild-type levels, indicating that YTRF signals at either positions 20-23 or 31-34 are necessary and sufficient to promote TR internalization and function in an independent and additive manner. We also report the complete primary structure of the Chinese hamster TR deduced from its cDNA sequence and show that the Tyr20 as well as the complete YTRF motif is conserved.

Ligand-induced internalization of the epidermal growth factor receptor is mediated by multiple endocytic codes analogous to the tyrosine motif found in constitutively internalized receptors.

Ligand-induced internalization of epidermal growth factor (EGF) receptors via a high affinity saturable pathway requires sequences located in the carboxyl terminus distal to the tyrosine kinase domain. Three regions were found to contain endocytic motifs as defined by their ability to restore internalization function to EGF receptors truncated at the distal border of the kinase domain at residue 958. Deletional analysis identified the sequence 996QQGFF as essential for function of the region encompassing residues 993-1022. QQGFF and the deduced sequence of the region encompassing residues 973-991 (973FYRAL) could effectively replace the endogenous endocytic code of the transferrin receptor (YTRF). FYRAL and YTRF were less active than QQGFF when substituted into region 993-1022 of the EGF receptor, but a synthetic sequence (NNAYF), predicted to have structural features of a tight turn, effectively replaced QQGFF for EGF receptor internalization. Whereas EGF receptor sequences functioned effectively in the transferrin receptor, function of these sequences in the EGF receptor was strictly dependent on intrinsic tyrosine kinase activity as demonstrated kinetically and by immunofluorescence using semithin cryosections. Ligand-dependent endocytosis and down-regulation of the EGF receptor thus require multiple sequence motifs that are exchangeable between ligand-dependent and -independent receptors, but that require intrinsic tyrosine kinase activity for function in the context of the EGF receptor.

Rate of 59Fe uptake into brain and cerebrospinal fluid and the influence thereon of antibodies against the transferrin receptor.

Uptake of 59Fe from blood into brains of anaesthetized rats and mice has been studied by intravenous infusion of [59Fe]ferrous ascorbate or of 59Fe-transferrin, the results not being significantly different. Uptakes in the rat were linear with time, but increased at longer times in the mouse. Transfer constants, K(in) (in ml/g/h x 10(3)), for cerebral hemispheres were 5.2 in the adult rat and 5.6 in the mouse. These K(in) values corresponded to 59Fe influxes of 145 and 322 pmol/g/h, respectively. 59Fe uptake into the mouse brain occurred in the following order: cerebellum > brainstem > frontal cerebral cortex > parietal cortex > occipital cortex > hippocampus > caudate nucleus. In genetically hypotransferrinaemic mice, 59Fe uptake into brain was 80-95 times greater than in To strain mice. Pretreatment of young rats and mice with monoclonal antibodies to transferrin receptors, i.e., the anti-rat immunoglobulin G OX 26 and the anti-mouse immunoglobulin M RI7 208, inhibited 59Fe uptake into spleen by 94% and 98%, respectively, indicating saturation of receptors. The antibodies reduced 59Fe uptake into rat brain by 35-60% and that into mouse brain by 65-85%. Although a major portion of iron transport across the blood-brain barrier is normally transferrin-mediated, non-transferrin-bound iron readily crosses it at low serum transferrin levels.

Structural requirements for high efficiency endocytosis of the human transferrin receptor.

Wild-type and mutant human transferrin receptors (TR) have been expressed in chicken embryo fibroblasts using a helper-independent retroviral vector. By functional studies of the mutant TRs, we have identified the tetrapeptide sequence, YXRF, in the cytoplasmic tail of the receptor as the internalization signal required for high efficiency endocytosis and shown that transplanted internalization signals from the low density lipoprotein receptor (LDLR) and the cation-independent mannose-6-phosphate receptor (Man-6-PR) are able to promote rapid internalization of the human TR. A six-residue LDLR signal, FDNPVY, is required for activity in TR, whereas a four-residue Man-6-PR signal, YSKV, is sufficient. These data indicate that internalization signals are interchangeable self-determined structural motifs and that signals from type I membrane proteins are active in a type II receptor. Putative internalization signals in the cytoplasmic tails of other receptors and membrane proteins can be identified based on the sequence patterns of the LDLR, Man-6-PR, and TR signals. Two such putative four-residue internalization signals, one from the poly-Ig receptor and one from the asialoglycoprotein receptor, were tested for activity by transplantation into TR and were found to promote high efficiency internalization. These results suggest that an exposed tight turn is the conformational motif for high efficiency endocytosis.