A cycloheximide-resistant pool of receptors for asialoglycoproteins and mannose 6-phosphate residues in the Golgi complex of hepatocytes.

Following in vivo administration of cycloheximide (20 mg/kg body weight i.p.) protein synthesis was completely inhibited (99%) in rat liver. No newly synthesized asialoglycoprotein receptor (ASGP-R) could be detected by metabolic labeling. Fluorescence immunocytochemistry of several secretory proteins and plasma membrane proteins, including the receptors for polymeric IgA (IgA-R), demonstrated a rapid loss from the Golgi complex following cycloheximide administration. On the other hand, two membrane proteins, the receptors for ASGP-R and mannose 6-phosphate (MP-R), were not altered in their cellular localization including the Golgi. Using quantitative immunoelectron microscopy with colloidal gold, we found that 2 h and 4 h after cycloheximide administration, the densities of ASGP-R and MP-R in the membranes of the Golgi complex were unaltered compared with control liver. Similarly, there was no significant effect of cycloheximide on the receptor labeling in coated vesicles and compartment of uncoupling receptors and ligands (CURL). These observations are consistent with an involvement of the Golgi and CURL pools of the receptors in intracellular trafficking, endocytosis and receptor recycling.     

Ultrastructural localization of the mannose 6-phosphate receptor in rat liver

An affinity-purified rabbit antibody against rat liver mannose 6- phosphate receptor (MP-R) was prepared. The antibody was directed against a 215 kd-polypeptide and it recognized both ligand-occupied and free receptor. Anti-MP-R was used for immunofluorescence and immunoelectron microscopy of cryosections from rat liver. MP-R was demonstrated in all parenchymal liver cells, but not in endothelial lining cells. MP-R labeling was found at the entire plasma membrane, in coated pits and coated vesicles, in the compartment of uncoupling receptor and ligand, and in the Golgi complex. Lysosomes showed only scarce MP-R label. In double-labeling immunoelectron microscopy, MP-R co-localized with albumin in the Golgi cisternae and in secretory vesicles with lipoprotein particles. Cathepsin D was associated with MP- R in the Golgi cisternae. This finding indicates that MP-R/cathepsin D complexes traverse the Golgi complex on their way to the lysosomes. The possible involvement of CURL in lysosomal enzyme targeting is discussed.     

Membranes of sorting organelles display lateral heterogeneity in receptor distribution

This study describes the distribution of an intrinsic membrane protein, the asialoglycoprotein receptor (ASGP-R) in the trans-Golgi reticulum and compartment of uncoupling receptor and ligand (CURL) of rat liver cells. Using quantitative immunogold electron microscopy and membrane length measurements, we showed lateral nonhomogeneity of receptors in the membranes of trans-Golgi reticulum and CURL, in particular in the membranes of secretory vesicles (identified by their content of albumin and very low density lipoprotein particles) and of CURL vesicles (endosomes), including multivesicular bodies. The characteristic tubulovesicular morphology of both sorting organelles defines the transition of receptor-rich tubular membrane and the receptor-poor limiting membrane of the attached vesicles. There was a direct relationship between the size of the secretory and CURL vesicles and the density of ASGP-Rs in their membranes. Receptor density in the smallest vesicles was similar to that found in adjacent continuous tubules. The larger the vesicles, the less receptor was detectable in their membranes. We propose that the receptor molecules are excluded from the vesicle membranes by dynamic lateral redistribution. Nonrandom receptor distribution in the CURL vesicle membranes was present even at the multivesicular body stage. These observations strongly suggest the existence of barriers to ASGP-R diffusion at the junctions of tubules and vesicles. In addition, our observations suggest that ASGP-Rs are transported to the plasma membrane via a mechanism other than the normal secretory pathway.     

Ligand- and weak base-induced redistribution of asialoglycoprotein receptors in hepatoma cells

The receptor for asialoglycoproteins (ASGPR) was localized in human hepatoma Hep G2 cells by means of quantitative immunoelectron microscopy. Without ligand added to the culture medium, we found 34% of the total cellular receptors on the plasma membrane, 37% in compartment of uncoupling receptor and ligand (CURL), and 21% in a trans-Golgi reticulum (TGR) that was defined by the presence of albumin after immuno-double labeling. A small percent of the ASGPR was associated with coated pits, the Golgi stacks, and lysosomes. After incubation of the cells with saturating concentrations of the ligand asialo-orosomucoid (ASOR), the number of cell surface receptors decreased to 20% of total cellular receptors, whereas the receptor content of CURL increased by a corresponding amount to 50%. The ASGPR content of TGR remained constant. In contrast, after treatment of the cells with 300 microM of the weak base primaquine (PMQ), cell surface ASGPR had decreased dramatically to only 4% of total cellular receptors whereas label in the TGR had increased to 42%. ASGPR labeling of CURL increased only to 47%. The labeling of other organelles remained unchanged. This affect of PMQ was independent of the presence of additional ASOR. Implications for the intracellular pathway of the ASGPR are discussed.     

Intracellular site of asialoglycoprotein receptor-ligand uncoupling: Double-label immunoelectron microscopy during receptor-mediated endocytosis

In rats infused with asialoglycoprotein for 60 min, receptor-mediated endocytosis of the ligand occurred exclusively in hepatic parenchymal cells. We have used double-label immunoelectron microscopy on ultrathin cryosections of rat liver to identify the site at which the asialoglycoprotein receptor and its ligand dissociate following their common endocytosis. Asialoglycoprotein receptor, ligand and clathrin were identified and quantitated by the use of monospecific antibodies followed by gold-protein A complexes. Both receptor and ligand were found associated with the membrane of clathrin-coated vesicles close to the cell surface. We identified other vesicles that contained ligand accumulated within the lumen. The membranes of these latter vesicles contained little receptor, but receptor was concentrated in tubular extensions that were largely free of ligand. We call this organelle CURL (compartment of uncoupling of receptor and ligand). CURL vesicles appear to transform into secondary lysosomes, wherein the ligand is degraded. The tubular vesicles are, we propose, an intermediate in recycling the receptor to the cell surface.     

Morphological analysis of ligand uptake and processing: the role of multivesicular endosomes and CURL in receptor-ligand processing

The receptor-mediated endocytosis and intracellular processing of transferrin and mannose receptor ligands were investigated in bone marrow-derived macrophages, fibroblasts and reticulocytes. Mannosylated bovine serum albumin (BSA) conjugated to colloidal gold (Au-man-BSA) or colloidal gold-transferrin (AuTf) were used to trace ligand processing in these cells. These ligands appeared to be processed by mechanisms similar to those observed previously with other mannose receptor and galactose receptor ligand probes. After uptake via coated pits and coated vesicles, Au-man-BSA appeared in small uncoated vesicles and tubular structures and was transferred to large, sometimes multivesicular endosomes (MVEs), which sometimes had arm-like protrusions reminiscent of CURL (compartment of uncoupling of receptor and ligand) [10, 11]. Initially these structures became increasingly multivesicular, but during longer incubations the inclusion vesicles appeared to disintegrate to leave a denser, amorphous lumen. Inclusion vesicle disintegration may result from the introduction of lysosomal enzymes into these structures. These results suggest a model for differential receptor-ligand and ligand-ligand sorting. As suggested [10, 11] membrane constituents may be recycled to the plasma membrane from the arms of CURL. Receptor-bound ligands, such as transferrin, would also recycle. The luminal contents, including dissociated ligands, other soluble proteins and inclusion vesicles (containing some membrane proteins), would target to lysosomes. This would result in the lysosomal degradation of any membrane proteins that were incorporated in the inclusion vesicle membranes.     

Recycling of the asialoglycoprotein receptor: biochemical and immunocytochemical evidence

One of the best documented systems of receptor-mediated endocytosis is the clearance of asialoglycoproteins (ASGP) from the blood plasma by liver parenchymal cells. There are 200 000-500 000 ligand binding sites per cell, which makes this system favourable for molecular studies of receptor function. By using both biochemical and immunocytochemical approaches, we have obtained evidence for receptor recycling. We have also localized the intracellular site at which the endocytosed receptor and ligand dissociate. The human hepatoma cell Hep G2 contains abundant ASGP receptors (approximately 225 000 per cell). In growing cells approximately 85% of the functional receptors are on the cell surface and the remaining 15% are internal. The maximal rate of ligand uptake in this cell system at 37 degrees C is approximately 30 000 molecules per cell per minute. Each functional receptor can therefore bind and internalize more than 50 ligand molecules during a 6 h period (in the absence of new receptor synthesis), or one ligand each 8 min. To follow both ligand and receptor during their common endocytosis and to visualize the compartment in which the dissociation of ligand from receptor occurs, we have used our recently developed double-labelling immunocytochemical electron microscopic techniques with purified antibodies against ASGP ligand and ASGP receptor. In normal rat hepatocytes, both ligand and receptor are taken up from the sinusoidal cell surface in clathrin-coated vesicles. Both receptor and ligand are associated with the membrane of small clathrin-coated vesicles close to the cell surface. Larger vesicles, farther removed from the surface, contain ligand accumulated within the lumen. The membranes of these larger vesicles contain little receptor, but receptor was concentrated in detached vesiculotubular extensions, which were largely free of ligand. These vesicles represent the compartment of uncoupling of receptor and ligand (CURL) during their common endocytosis. Ligand contained within the vesicle lumen is then transferred to multivesicular bodies and lysosomes; the tubular extensions may carry receptor back to the cell surface.     

Possible pathways for lysosomal enzyme delivery

Immunogold double-labeling and ultrathin cryosections were used to compare the subcellular distribution of albumin, mannose 6-phosphate receptor (MPR), galactosyltransferase, and the lysosomal enzymes cathepsin D, beta-hexosaminidase, and alpha-glucosidase in Hep G2 cells. MPR and lysosomal enzymes were found throughout the stack of Golgi cisternae and in a trans-Golgi reticulum (TGR) of smooth-surfaced tubules with coated buds and vesicles. The trans-Golgi orientation of TGR was ascertained by the co-localization with galactosyltransferase. MPR was particularly abundant in TGR and CURL, the compartment of uncoupling receptors and ligands. Both TGR and CURL also contained lysosomal enzymes, but endogenous albumin was detected in TGR only. The coated buds on TGR tubules contained MPR, lysosomal enzymes, as well as albumin. MPR and lysosomal enzymes were also found in coated pits of the plasma membrane. CURL tubules seemed to give rise to smooth vesicles, often of the multivesicular body type. In CURL, the enzymes were found in the lumina of the smooth vesicles while MPR prevailed in the tubules. These observations suggest a role of CURL in transport of lysosomal enzymes to lysosomes. When the cells were treated with the lysosomotropic amine primaquine, binding of anti-MPR to the cells in culture was reduced by half. Immunocytochemistry showed that MPR accumulated in TGR, especially in coated buds. Since these buds contain endogenous albumin and lysosomal enzymes also, these data suggest that coated vesicles originating from TGR provide for a secretory route in Hep G2 cells and that this pathway is followed by the MPR system as well.     

Trafficking of the epidermal growth factor receptor and transferrin in three hepatocytic endosomal fractions.

Hepatocytes rapidly internalize epidermal growth factor (EGF) and transferrin by receptor-mediated endocytosis. Both EGF and its receptor are thought to be targeted for destruction in lysosomes, leading to down-regulation of the receptor, whereas transferrin, after unloading iron within the cell, is thought to recycle to the cell surface bound to its receptor. Previously, we isolated three endosomal fractions from livers of estradiol-treated rats and examined their roles in cellular trafficking of low density lipoproteins (LDL) and the LDL receptor, which cycles constitutively (Belcher, J. D., Hamilton, R. L., Brady, S. E., Hornick, C. A., J?ckle, S., Schneider, W. J., and Havel, R. J., Proc. Natl. Acad. Sci. U. S. A. (1987) 84, 6785-6789). In the current study we have taken advantage of the distinct trafficking of the EGF receptor and transferrin to evaluate further the functions of these endosome fractions. Intravenous injection of a saturating amount of EGF into estradiol-treated rats induced internalization of a single population of EGF receptors, which rapidly accumulated in the endosome fraction of intermediate density ("compartment of uncoupling of receptor and ligand" (CURL)) and subsequently in the low density endosome fraction (multivesicular bodies (MVBs)). The high density endosome fraction, whose membranes contain a high concentration of recycling receptors (designated receptor-recycling compartment (RRC)), failed to accumulate EGF receptors after injection of EGF. In livers of rats not given exogenous EGF, EGF receptors were found in small but comparable concentrations in RRC, CURL, and MVB membranes, consistent with other evidence that targeting of the EGF receptor to lysosomes is mediated by ligand-induced phosphorylation. Transferrin also accumulated first in CURL and later in MVBs, but it also accumulated rapidly in the RRC fraction, consistent with the proposed function of this fraction in receptor recycling. Since transferrin is not degraded during its endocytic cycle, these observations indicate that apotransferrin and its receptor recycle from late endosomes (MVBs) located at the apical pole of hepatocytes, as well as from early endosomes near the sinusoidal pole.     

NMR study of ligand release from asialoglycoprotein receptor under solution conditions in early endosomes

Asialoglycoprotein receptor (ASGP-R) is an endocytic C-type lectin receptor in hepatocytes that clears plasma glycoconjugates containing a terminal galactose or N-acetylgalactosamine. The carbohydrate recognition domain (CRD) of ASGP-R has three Ca(2+) binding sites (sites 1, 2 and 3), with Ca(2+) at site 2 being directly involved in ligand binding. Following endocytosis, the ligands are released from ASGP-R in endosomes to allow receptor recycling to the cell membrane. Although dissociation of the receptor-ligand complex is mediated by the acidic environment within the mature endosomes, many of these complexes also dissociate in the early time of endocytosis, where pH is approximately neutral. To investigate the mechanism of ligand release from ASGP-R in early endosomes, we examined the binding mode of Ca(2+) and ligands to ASGP-R CRD by NMR. We demonstrate that sites 1 and 2 of ASGP-R are high affinity Ca(2+) binding sites, site 3 is low affinity, and that Ca(2+) ions bind to sites 1 and 2 cooperatively. The pH and Ca(2+) concentration dependences of Ca(2+) binding states indicated that early endosome conditions favor apo-ASGP-R CRD, allowing ligand release. Our results elucidated that the cooperative binding mode of Ca(2+) makes it possible for ASGP-R to be more sensitive to Ca(2+) concentrations in early endosomes, and plays an important role in the efficient release of ligand from ASGP-R. In our proposed mechanism, ASGP-R can rapidly release Ca(2+) and its ligand even at nearly neutral pH. Sequence comparisons of endocytic C-type lectin receptors suggest that this mechanism is common in their family.     

Coated endosomal vesicles: sorting and recycling compartment for transferrin in BHK cells.

We have investigated receptor-mediated endocytosis of transferrin (Tf) in baby hamster kidney (BHK) cells, using fluorescence and electron microscopy, and by carrying out colocalization experiments with clathrin antibodies and a fluorescently tagged glycolipid. Early during internalization, Tf was found in small vesicles (100-150 nm in diameter) located at the cell periphery. The ligand remained associated with such vesicles when the latter concentrated towards the cell center, before ending up in the juxtanuclear area. Throughout this vesicular trafficking pathway, clathrin colocalized with Tf. We conclude that Tf is processed intracellularly via small coated endosomal vesicles (CEV) and is not delivered into large tubular endosomes (CURL; compartment for uncoupling receptors and ligands), typical for ligand trafficking to lysosomes. By determining the kinetics of Tf internalization and by comparing the flow of Tf to that of a fluorescent glycolipid, it can also be concluded that CEVs display sorting and recycling properties, implying that small vesicles can be shed from or fuse with CEVs. Acidic pH does not prevent the formation of CEVs, but their intracellular movement, towards the cell center, is impeded.     

Antibody-induced receptor loss. Different fates for asialoglycoproteins and the asialoglycoprotein receptor in HepG2 cells

The human asialoglycoprotein receptor (ASGP-R) is a membrane glycoprotein which participates in receptor-mediated endocytosis and delivery of its ligands to lysosomes for degradation. In order to examine the pathways and mechanisms responsible for the turnover and degradation of the ASGP-R we have followed the fate of the ASGP-R in HepG2 cells during exposure to anti-receptor antibody as well as inhibitors of lysosomal processing and receptor recycling. Incubation of cells at 37 degrees C with anti-ASGP-R antibody results in the rapid (t 1/2 30 min) loss of mature 46,000-Da ASGP-R (control, t 1/2 20 h). This process requires whole IgG, since Fab fragments do not induce loss of receptor. Furthermore, this antibody-induced loss is specific, since incubation with antibody to the transferrin receptor does not alter cellular ASGP-R content. Of note, weak bases (e.g. primaquine) abrogate this antibody-induced loss of ASGP-R. Inhibitors of lysosomal proteases (EC64 and leupeptin) do not alter this antibody-mediated loss. Furthermore, this effect occurs at 18 degrees C, a temperature at which delivery of ligand to the lysosome is blocked. Thus, the present observations suggest a unique pathway for antibody-induced ASGP-R loss which is distinct from the pathway of lysosomal delivery of ligand.     

Triacylglycerol hydrolysis in isolated hepatic endosomes.

Three endosomal compartments including the compartment for uncoupling receptor and ligand (CURL), multivesicular bodies (MVB), and a putative recycling fraction (retrosomes) were isolated from rat liver homogenates fifteen minutes after a bolus injection of very low density lipoprotein (VLDL) was delivered into a femoral vein. Assays for enzyme markers indicate a minimal contamination with either lysosomes or Golgi. The increase in specific activity of the radiolabeled ligand (VLDL) during the isolation procedure from homogenate to MVB, demonstrates a 200-250-fold purification of this organelle. All three fractions have the ability to catabolize triacylglycerol substrate both as triolein and as VLDL triacylglycerol. Furthermore, incubation of isolated endosomes following injection of endogenously labeled VLDL demonstrate their ability to hydrolyze VLDL triacylglycerol in situ. Three distinct lipolytic pH optima were found at pH 5.5, 7.1, and 8.6. The effects of serum, MgCl2, CaCl2, NaCl, sodium dodecyl sulfate, bile acids, and antibody to hepatic triacylglycerol lipase on the individual endosome fractions demonstrated distinct lipolytic activities in the different compartments. Results indicate that both an endosomal neutral lipase as well as hepatic triacylglycerol lipase make a significant contribution to lipolytic processing of endocytosed lipoproteins prior to their resecretion of further processing in hepatic lysosomes.     

A multicompartmental model of fluid-phase endocytosis in rabbit liver parenchymal cells.

Fluid-phase endocytosis was studied in isolated rabbit liver parenchymal cells by using 125I-poly(vinylpyrrolidone) (PVP) as a marker. First, uptake of 125I-PVP by cells was determined. Also, cells were loaded with 125I-PVP for 20, 60 and 120 min, and release of marker was monitored for 120-220 min. Then we used the Simulation, Analysis and Modeling (SAAM) computer program and the technique of model-based compartmental analysis to develop a mechanistic model for fluid-phase endocytosis in these cells. To fit all data simultaneously, a model with three cellular compartments and one extracellular compartment was required. The three kinetically distinct cellular compartments are interpreted to represent (1) early endosomes, (2) a prelysosomal compartment equivalent to the compartment for uncoupling of receptor and ligand (CURL) and/or multivesicular bodies (MVB), and (3) lysosomes. The model predicts that approx. 80% of the internalized 125I-PVP was recycled to the medium from the early-endosome compartment. The apparent first-order rate constant for this recycling was 0.094 min-1, thus indicating that an average 125I-PVP molecule is recycled in 11 min. The model also predicts that recycling to the medium occurs from all three intracellular compartments. From the prelysosomal compartment, 40% of the 125I-PVP molecules are predicted to recycle to the medium and 60% are transferred to the lysosomal compartment. The average time for recycling from the prelysosomal compartment to the medium was estimated to be 66 min. For 125I-PVP in the lysosomal compartment, 0.3%/min was transferred back to the medium. These results, and the model developed to interpret the data, predict that there is extensive recycling of material endocytosed by fluid-phase endocytosis to the extracellular environment in rabbit liver parenchymal cells.     

Regulation by phorbol esters of asialoglycoprotein and transferrin receptor distribution and ligand affinity in a hepatoma cell line

We have investigated the simultaneous regulation of cell surface distribution and ligand binding of the asialoglycoprotein (ASGP) receptor and the transferrin receptor in a hepatoma cell line by phorbol esters. One hour exposure to phorbol esters causes a redistribution of both receptors to the cell interior as shown by radioligand binding at 4 degrees C and selective immunoprecipitation from the plasma membrane. This effect is temperature- and dose-dependent and is not seen with 4-alpha-phorbol, an inactive tumor promoter. The mechanism and kinetics of the ASGP receptor response to phorbol esters appears to differ from that of the transferrin receptor in this cell line. Within the first 10 min there is a decrease in binding of iodinated ligands for both receptors to the HepG2 cell surface. For the transferrin receptor this results from a net internalization of receptor molecules from the plasma membrane pool, while for the ASGP receptor this decrease is accounted for by a 3.5-fold reduction in ligand binding affinity (6.6 X 10(-8) M to 24.0 X 10(-8) M), with essentially no change in the number of ASGP receptors recoverable from the plasma membrane pool by immunoprecipitation. The altered affinity of the ASGP-R is transient; the Kd returns to control levels by 20 min of continued exposure to the agent. The transferrin receptor shows no change in binding affinity during the course of exposure to phorbol esters. ASGP receptors in cells exposed to phorbol esters for 1 h maintain their competence to deliver exogenous ligand to intracellular sites of degradation and to participate in the recycling pathway of receptor-mediated endocytosis, although at a lower rate than in control cells. We conclude that under identical conditions phorbol esters modulate the binding capacity of two receptors at the cell surface by separate mechanisms. Furthermore, the transient nature of the altered ASGP-R binding affinity suggests that at least two mechanisms, receptor redistribution as well as decreased binding affinity, are operative in the modulation of ASGP-R cell surface binding during the first hour of exposure to the phorbol esters.     

Diffusion-limited forward rate constants in two dimensions. Application to the trapping of cell surface receptors by coated pits.

A variety of receptors are known to aggregate in specialized cell surface structures called coated pits, prior to being internalized when the coated pits close off. At 37 degrees C on human fibroblasts, as well as on other cell types, a recycling process maintains a constant number of coated pits on the cell surface. In this paper, we explore implications for receptor aggregation and internalization of the two types of recycling models that have been proposed for the maintenance of the coated pit concentration. In one model, coated pits alternate between accessible and inaccessible states at fixed locations on the cell surface, while in the other model, coated pits recycle to random locations on the cell surface. We consider receptors that are randomly inserted in the membrane, move by pure diffusion with diffusion coefficient D, and are instantly and irreversibly trapped when they reach a coated pit boundary (the diffusion limit). For such receptors, we calculate for each of the two models: the mean time tau to reach a coated pit, the forward rate constant k+ for the interaction of a receptor with a coated pit, and the fraction phi of receptors aggregated in coated pits. We show that for the parameters that characterize coated pits on human fibroblasts, the way in which coated pits return to the surface has a negligible effect on the values of tau, k+, and phi for mobile receptors, D greater than or equal to 1.0 X 10(-11) cm2/s, but has a substantial effect for "immobile" receptors, D much less than 1 X 10(-11) cm2/s. We present numerical examples to show that it may be possible to distinguish between these models if one can monitor slowly diffusing receptors (D less than 1 X 10(-11) cm2/s) on cells whose coated pits have relatively short lifetimes (less than or equal to 1 min). Finally, we show that for the low-density lipoprotein (LDL) receptor on human fibroblasts (D = 4.5 X 10(-11) cm2/s), the predicted and observed values of K+ and phi are in close agreement. Therefore, even for slowly diffusing LDL receptor, unaided diffusion as the transport mechanism of receptors to coated pits is consistent with measured rates of LDL internalization.     

Reply to Claudio Cobelli and Gianna Toffolo,identifiability from parameter bounds. Structural and numerical aspects. Math. Biosci. 71:237–243 (1984)

We present an analysis of receptor mediated endocytosis which includes the following elements: ligand binding to receptors, interaction of the ligand-receptor complex with coated pits, internalization of coated pit contents, recycling of receptors, and degradation of ligand. The model accounts quantitatively for epidermal growth factor binding and clustering in coated pits at 4°C, for its internalization and degradation at 37°C, and for EGF receptor down-regulation. Steady state analysis of the model indicates that the slope and intercept of a Scatchard plot are functions of the kinetic parameters of the endocytic loop and do not necessarily reflect the affinity and number of receptors in metabolically active cells. Moreover, the model predicts that for homogeneous receptors, a Scatchard plot can be either linear or nonlinear, depending on the concentration of proteins in coated pits which interact with ligand-receptor complexes. A slight generalization of the model in which phorbol ester-receptor complexes compete with EGF-receptor complexes for the same coated pit proteins provides a quantitative explanation for the loss of the high affinity portion of the EGF Scatchard plot subsequent to preincubation with phorbol esters. This explanation leads to the prediction of a local homology between a portion of the phorbol ester receptor sequence and a portion of the EGF receptor sequence.     

Receptors compete for adaptors found in plasma membrane coated pits.

An affinity matrix of LDL receptor cytoplasmic tails binds the HA-II 100/50/16 kd complexes found in plasma membrane coated pits. Other receptors (or their cytoplasmic domains), which are localized in coated pits during endocytosis, inhibit this binding. This includes an 8 residue peptide containing tyrosine, corresponding to the cytoplasmic portion of a mutant influenza haemagglutinin. In contrast, the equivalent peptide lacking tyrosine (like the tail of the native haemagglutinin, a protein excluded from coated pits) does not compete. These results imply that the HA-II complex has a recognition site for a common signal, probably involving a tyrosine residue, carried by the LDL receptor and competing receptors also found in plasma membrane coated pits. The HA-II complex therefore fulfils the role of an 'adaptor', the name proposed for the structural units which mediate the binding of clathrin to receptors in coated vesicles. Another related complex, the HA-I adaptor, which is restricted to Golgi coated pits, probably does not recognize the 'tyrosine signal' on the LDL receptor tail. The HA-I adaptor is likely to contain a recognition site for a different signal carried by receptors, e.g. the mannose-6-phosphate receptor, which are found in Golgi coated pits.     

Effect of membrane flow on the capture of receptors by coated pits. Theoretical results.

Coated pits trap cell surface receptors and mediate their internalization. Once internalized, many receptors recycle back to the cell surface. When recycled receptors are inserted into the plasma membrane, they move until they are again trapped in coated pits. The mechanisms for moving receptors from their insertion sites to coated pits are unknown. Unaided diffusion as the transport mechanism is consistent with the observed kinetics of receptor recycling. Another candidate for the transport mechanism is convection. For receptors that recycle to random positions on the cell surface, or to restricted regions about coated pits, we assess the importance of convective flow in the transport of receptors to coated pits. First we consider local flows set up by the formation of coated pits and their transformation into coated vesicles. As coated pits form and round into coated vesicles, surrounding membrane is drawn inward, creating flows directed toward the coated pit centers. We show that unless the lifetime of a coated pit is very short, 10 s or less, such local flows have a negligible effect on the time it takes receptors to reach coated pits. We also show that they are unlikely to be the mechanism that keeps receptors that have reached coated pits trapped within coated pits until they are internalized. Finally we calculate the mean time tau for a diffusing receptor to reach a coated pit in the presence of membrane flow that is constant in magnitude and direction, as may occur on moving cells. We show that for typical membrane flow velocities, tau can be reduced significantly from its value in the absence of flow. For example, a velocity v = 2.8 micron/min cuts the mean transport time in half.     

Sorting and recycling of cell surface receptors and endocytosed ligands: the asialoglycoprotein and transferrin receptors

With few exceptions, receptor-mediated endocytosis of specific ligands is mediated through clustering of receptor-ligand complexes in coated pits on the cell surface, followed by internalization of the complex into endocytic vesicles. During this process, ligand-receptor dissociation occurs, most probably in a low pH prelysosomal compartment. In most cases the ligand is ultimately directed to the lysosomes, wherein it is degraded, while the receptor recycles to the cell surface. We have studied the kinetics of internalization and recycling of both the asialoglycoprotein receptor and the transferrin receptor in a human hepatoma cell line. By employing both biochemical and morphological/immunocytochemical approaches, we have gained some insight into the complex mechanisms which govern receptor recycling as well as ligand sorting and targeting. We can, in particular, explain why transferrin is exocytosed intact from the cells, while asialoglycoproteins are degraded in lysosomes. We have also localized the intracellular site at which endocytosed receptor and ligand dissociate.