Characterization of the asialoglycoprotein receptor in a continuous hepatoma line

The asialoglycoprotein receptor has been identified on a continuous human hepatoma cell line, HepG2. This receptor requires Ca2+ for ligand binding and is specific for asialoglycoprotein. There are approximately 150,000 ligand molecules bound/cell at 4 degrees C. These receptors represent a homogeneous population of high affinity binding sites with Kd = 7 X 10(-9) M. From the rate of 125I-ASOR binding at 4 degrees C, kon was 0.95 X 10(6) M-1 min-1. Uptake of 125I-ASOR at 37 degrees C was approximately 0.02 pmol/min/10(6) cells.     

Recycling of the asialoglycoprotein receptor in isolated rat hepatocytes. ATP depletion blocks receptor recycling but not a single round of endocytosis

Continuous endocytosis of 125I-asialo-orosomucoid (ASOR) mediated by the galactosyl receptor in rat hepatocytes is a cyclic process. 125I-ASOR-receptor complexes are internalized, processed, and the ligand is degraded while the receptor is returned to the cell surface for reutilization. Since a true cycle has a thermodynamic requirement for the input of external energy, we examined the effects of changes in intracellular ATP levels on the function of the receptor cycle. Hepatocytes were depleted of ATP to various extents prior to endocytosis by incubating cells at 15 degrees C in the presence of 2 mM NaF and 0-20 mM NaN3. A luciferase-luciferin bioluminescence assay was used to quantitate the amount of cellular ATP. ATP-depleted cells were allowed to bind 125I-ASOR at 0 degrees C, washed through discontinuous Percoll gradients, and only viable cells were isolated and incubated at 37 degrees C to initiate a synchronous single round of endocytosis. The extent of internalization of this surface-bound 125I-ASOR was unaffected by an ATP depletion to less than 1% of the control level. The rate of internalization of surface-bound ligand was unaffected until the ATP levels decreased to 30% or less; at greater than 98% ATP depletion the initial rate decreased by a maximum of 55% and the kinetics became biphasic. In contrast, continuous endocytosis in the presence of excess ASOR was inhibited by only a 25% decline in cellular ATP content and demonstrated a very sharp threshold response to changing ATP levels. Continuous endocytosis, which requires receptor recycling, was completely inhibited when the total cellular ATP level decreased by only 40%. We conclude that the internalization phase of endocytosis is not dependent on ATP but that the processing and/or externalization phases of the complete receptor cycle are either directly or indirectly dependent on ATP and very sensitive to changes in cellular ATP content.     

Monensin inhibits ligand dissociation only transiently and partially and distinguishes two galactosyl receptor pathways in isolated rat hepatocytes

Monensin has been shown to inhibit the dissociation of internalized asialoorosomucoid (ASOR) from galactosyl (Gal) receptors in hepatocytes (Harford et al., J. Cell. Biol., 96:1824, 1983). Examination of the long-term kinetics of dissociation of a single round of surface-bound 125I-ASOR in the presence of monensin revealed, however, that dissociation resumed after a lag of 30-40 min. Dissociation proceeded slowly with apparent first order kinetics (k = 0.006-0.022 min-1) and reached a plateau after 4 h, both in freshly isolated cells in suspension and in cells cultured for 24 h. Only a portion of the ligand bound to surface Gal receptors was capable of dissociating. The degree of dissociation was correlated with the expression of a subpopulation of receptors we have recently designated as state 1 Gal receptors (Weigel et al., Biochem. Biophys. Res. Commun. 140:43, 1986). The recovery and dissociation of a portion of 125I-ASOR-receptor complexes after the lag period is not due to a depletion of monensin, since a second addition of the drug has no affect once dissociation resumes. Furthermore, as assessed by the accumulation of the fluorescent dye acridine orange, cells have not recovered the ability to acidify intracellular compartments during the time that dissociation occurs. The results support a model for the hepatic Gal receptor system, in which there are two functionally different receptor populations, recycling pathways, and ligand processing pathways. Monensin blocks dissociation of 125I-ASOR from receptors in the major pathway completely. In the minor pathway dissociation proceeds to completion only after a lag. In this minor pathway monensin appears to temporarily delay a maturation or translocation process that must occur prior to dissociation. We conclude that the observed dissociation in the presence of monensin cannot be mediated by low pH, or by pH or pNa gradients.     

The surface activity of the same subpopulation of galactosyl receptors on isolated rat hepatocytes is modulated by colchicine, monensin, ATP depletion, and chloroquine

In this study, we characterized and compared the ligand-independent loss of surface galactosyl (Gal) receptor activity on isolated rat hepatocytes treated with monensin, chloroquine, microtubule depolymerizing agents, or NaN3 and NaF at 37 degrees C. Freshly isolated hepatocytes exhibit predominately one subset of surface Gal receptors, termed State 1 receptors (Weigel, P. H., Clarke, B. L., and Oka, J. A. (1986) Biochem. Biophys. Res. Commun. 140, 43-50). During equilibration at 37 degrees C, these cells also express a second subset of Gal receptors at the surface, termed State 2 receptors, and routinely double their total surface Gal receptor activity. Following equilibration at 37 degrees C and then inhibitor treatment, hepatocytes bound 40-60% less 125I-asialoorosomucoid (ASOR) at 4 degrees C than did untreated cells. Treated cells maintained a basal nonmodulated level of surface receptor activity regardless of temperature, perturbant concentration, or incubation time. Loss of surface Gal receptor activity on cells treated with multiple inhibitors simultaneously or sequentially was not additive. Thus, all treatments affected the same subpopulation of surface Gal receptors. None of these inhibitors decreased surface State 1 Gal receptor activity, but all prevented the normal appearance of State 2 Gal receptors on freshly isolated cells during incubation at 37 degrees C. The endocytic capability of residual surface State 1 Gal receptors on inhibitor-treated cells varied depending on the inhibitor. Hepatocytes treated first at 24 degrees C or with colchicine at 37 degrees C internalized greater than 85% of surface-bound 125I-ASOR. In contrast, monensin- or chloroquine-treated cells internalized approximately 50% of surface-bound 125I-ASOR. Azide-treated cells internalized less than 20% of surface-bound 125I-ASOR. We conclude that only surface State 2 Gal receptor activity is sensitive to these various perturbants. State 1 Gal receptor activity is not modulated. These data are consistent with the conclusion that only State 2 Gal receptors constitutively recycle.     

Nonionic detergents increase the stoichiometry of ligand binding to the rat hepatic galactosyl receptor

When digitonin is used to expose intracellular galactosyl (Gal) receptors in isolated rat hepatocytes, only about half of the binding activity for 125I-asialoorosomucoid (ASOR) is found as compared to cells solubilized with Triton X-100. The increased ligand binding in the presence of detergent is not due to a decrease in Kd but could be due either to an increase in the number of ASORs bound per receptor or to exposure of additional receptors. Several experiments support the former explanation. No additional activity is exposed even when 80% of the total cell protein is solubilized with 0.4% digitonin. It is, therefore, unlikely that receptors are in intracellular compartments not permeabilized by digitonin and inaccessible to 125I-ASOR. Digitonin-treated cells are not solubilized by Triton X-100 if they are first treated with glutaraldehyde under conditions that retain specific binding activity. 125I-ASOR binding to these permeabilized/fixed cells increases about 2-fold in the presence of Triton X-100 and a variety of other detergents (e.g., Triton X-114, Nonidet P-40, Brij-58, and octyl glucoside) but not with the Tween series, saponin, or other detergents. When these fixed cells are washed to remove detergent, 125I-ASOR binding decreases almost to the initial level. Affinity-purified Gal receptor linked to Sepharose 4B binds approximately twice as much 125I-ASOR in the presence of Triton X-100 as in its absence. The results suggest that the increase in Gal receptor activity in the presence of nonionic detergents is due to an increase in the valency of the receptor rather than to exposure of additional receptors.     

Recycling of the asialoglycoprotein receptor and the effect of lysosomotropic amines in hepatoma cells

Receptor-mediated uptake and degradation of 125I-asialoorosomucoid (ASOR) in human hepatoma HepG2 cells is inhibited by the lysosomotropic amines chloroquine and primaquine. In the absence of added ligand at 37 degrees C, these amines induce a rapid (t1/2 5.5-6 min) and reversible loss of cell surface 125I-ASOR binding sites as well as a rapid decrease in 125I-ASOR uptake and degradation. There is no effect of these amines on the binding of 125I-ASOR to the cell surface at 4 degrees C or on the rate of internalization of prebound 125I-ASOR. The loss of 125I-ASOR surface binding at 37 degrees C is not attributable to altered affinity of ligand-receptor binding. In the presence of added ligand at 37 degrees C, there is a more rapid (t1/2 2.5-3 min) loss of hepatoma cell surface receptors. In addition, the amines inhibit the rapid return of the internalized receptor to the cell surface. We examined the nature of this loss of 125I-ASOR surface binding sites by following the fate of receptor molecules after biosynthetic labeling and after cell surface iodination. At 37 degrees C, chloroquine and primaquine induce a loss of asialoglycoprotein receptor molecules from the hepatoma cell surface to an internal pool.     

Total cellular activity and distribution of a subpopulation of galactosyl receptors in isolated rat hepatocytes are differentially affected by microtubule drugs,monensin, low temperature,and chloroquine

We studied the effects of low temperature (20–37°C), monensin, chloroquine, and microtubule drugs on the cellular distribution and activity of galactosyl (Gal) receptors in isolated rat hepatocytes. After equilibration at 37°C, hepatocytes were incubated at 37°C, 31°C, 25°C, or 20°C or treated with or without inhibitors at 37°C in the absence of ligand. The cells were then assayed at 4°C for ¹²⁵I-asialo-orosomucoid binding, to measure receptor activity, or ¹²⁵I-anti-Gal receptor IgG binding, to measure receptor protein. Surface or total (surface and intracellular) Gal receptor activity and protein were measured on intact or digitonin-permeabilized cells, respectively. These inhibitors fell into two categories. Type I inhibitors (sub-37°C temperatures or colchicine) induced receptor redistribution but not inactivation. Treated cells lost up to 40% of surface Gal receptor activity and protein. Lost surface receptors were recovered intracellularly with no loss of receptor activity. Type II inhibitors (monensin or chloroquine) induced receptor inactivation but not redistribution. Treated cells lost 50–65% of their surface Gal receptor activity but only ? 15% of their surface receptor protein. These cells lost up to 60% of total cellular Gal receptor activity with no loss of total receptor protein. Of the total inactive Gal receptors, up to 50% and75%, respectively, were present intracellularly in monensin-and chloroquine-treated cells. Loss of ligand binding to permeable treated cells was not due to changes in receptor affinity. A third category, Type III inhibitors (metabolic energy poisons that deplete ATP) induce both Gal receptor redistribution and inactivation (Biochemistry 27:2061, 1988). We conclude that only one of the two previously characterized subpopulations of Gal receptors on hepatocytes, termed State 2 receptors (J Biol Chem 265:629, 1990), recycles constitutively. The activity and distribution of State 2 but not State 1 Gal receptors are differentially affected by these specific drugs or treatments.     

Degradation of asialoglycoproteins mediated by the galactosyl receptor system in isolated hepatocytes. Evidence for two parallel pathways

The ability of rat hepatocytes to degrade internalized surface-bound 125I-asialoorosomucoid (ASOR) was determined by measuring the appearance of acid-soluble radioactivity at 37 degrees C. The degradation kinetics were biphasic in cells previously equilibrated at 37 degrees C for 1 h or cultured for 24 h. Degradation began immediately and was linear for at least 20 min after which the rate increased to a steady state value 3-4 times greater than the initial rate. We previously showed that hepatocytes have two functionally distinct populations of galactosyl receptors that mediate ligand dissociation by two kinetically different pathways (Weigel, P. H., Clarke, B. L., and Oka, J. A. (1986) Biochem. Biophys. Res. Commun. 140, 43-50). The activity of one receptor population, designated State 2 galactosyl receptors, can be reversibly modulated by incubating cells between 22 and 37 degrees C and is not expressed on the surface of freshly isolated cells. When 125I-ASOR was prebound to freshly isolated cells at 4 degrees C and degradation was assessed subsequently at 37 degrees C, the kinetics were monophasic, not biphasic. Degradation of the surface-bound 125I-ASOR began immediately and was greater than 90% complete by 6 h. Freshly isolated cells were incubated at temperatures between 22 and 37 degrees C, chilled to 4 degrees C, allowed to pre-bind 125I-ASOR, and then incubated at 37 degrees C. As the State 2 galactosyl receptor population increased, the kinetics of degradation became progressively more biphasic and the rate of the delayed degradation process increased. This effect could be reversed in cells in culture or in suspension by down-modulating surface receptor activity at temperatures below 37 degrees C; only the degradation process appearing after a 20-min lag was affected. Degradation in both pathways is an apparent first order process with identical rate constants (kappa = 0.006 min-1, t1/2 = 116 min). We conclude that there are two separate pathways by which asialoglycoproteins are degraded. The major "classic" pathway mediated by State 2 galactosyl receptors occurs after a 20-min lag and the minor pathway mediated by State 1 galactosyl receptors begins immediately with no detectable lag.     

Effects of hyperosmolarity on ligand processing and receptor recycling in the hepatic galactosyl receptor system

Binding, endocytosis, and degradation of asialo-orosomucoid (ASOR) mediated by the galactosyl (Gal) receptor were examined in isolated rat hepatocytes in complete media supplemented with an osmolite. The specific binding of 125I-ASOR to cells at 4 degrees C was unaffected by up to 0.4 M sucrose or NaCl. Unlike sucrose or NaCl, mannitol stimulated 125I-ASOR binding at low concentrations but inhibited binding at higher concentrations. Continuous internalization at 37 degrees C, which requires receptor recycling, was completely blocked at 0.2 M sucrose or 0.15 M NaCl, corresponding in each case to a total osmolality of about 550 mmol/kg. This effect was reversed and endocytic function was restored by washing the cells, indicating that cell viability was unaffected. The rate of degradation of internalized 125I-ASOR was also inhibited by increasing sucrose concentrations. This inhibition is due to a block in the delivery of ligand to lysosomes and not an effect on degradation per se. In the presence of 0.2 M sucrose, the rate and extent of endocytosis of surface-bound 125I-ASOR were, respectively, 33.0 +/- 8.1% and 69.4 +/- 10.5% (n = 8) of the control without sucrose. Under these conditions, the dissociation of internalized receptor-ASOR complexes was completely inhibited. When sucrose was added, the effect on the endocytosis of surface-bound 125I-ASOR was virtually immediate. Previous studies showed that about 40% of the surface-bound 125I-ASOR which is internalized can return to the cell surface still bound to receptor (Weigel and Oka: J Biol Chem 259:1150, 1984). If 0.2 M sucrose was added after endocytosis occurred, 125I-ASOR still returned to the cell surface, although the rate and extent of return were inhibited by more than 50%. Interestingly, hyperosmolarity is the only treatment we have found which can reversibly inhibit, although only partially, the endocytosis of surface-bound 125I-ASOR.     

Cell surface distribution and intracellular fate of asialoglycoproteins: a morphological and biochemical study of isolated rat hepatocytes and monolayer cultures

A combination of biochemistry and morphology was used to demonstrate that more than 95 percent of the isolated rat hepatocytes prepared by collagenase dissociation of rat livers retained the pathway for receptor-mediated endocytosis of asialoglycoproteins (ASGPs). Maximal specific binding of (125)I-asialoorosomucoid ((125)I-ASOR) to dissociated hepatocytes at 5 degrees C (at which temperature no internalization occurred) averaged 100,000-400,000 molecules per cell. Binding, uptake, and degredation of (125)I- ASOR at 37 degrees C occurred at a rate of 1 x 10(6) molecules per cell over 2 h. Light and electron microscopic autoradiography (LM- and EM-ARG) of (125)I-ASOR were used to visualize the surface binding sites at 5 degrees C and the intracellular pathway at 37 degrees C. In the EM-ARG experiments, ARG grains corresponding to (125)I-ASOR were distributed randomly over the cell surface at 5 degrees C but over time at 37 degrees C were concentrated in the lysosome region. Cytochemical detection of an ASOR-horseradish peroxidase conjugate (ASOR-HRP) at the ultrastructural level revealed that at 5 degrees C this specific ASGP tracer was concentrated in pits at the cell surface as well as diffusely distributed along the rest of the plasma membrane. Such a result indicates that redistribution of ASGP surface receptors had occurred. Because the number of surface binding sites of (125)I-ASOR varied among cell preparations, the effect of collagenase on (125)I-ASOR binding was examined. When collagenase-dissociated hepatocytes were re-exposed to collagenase at 37 degrees C, 10-50 percent of control binding was observed. However, by measuring the extent of (125)I-ASOR binding at 5 degrees C in the same cell population before and after collagenase dissociation, little reduction in the number of ASGP surface receptors was found. Therefore, the possibility that the time and temperature of the cell isolations allowed recovery of cell surface receptors following collagenase exposure was tested. Freshly isolated cells, dissociated cells that were re-exposed to collagenase, and perfused livers exposed to collagenase without a Ca(++)-free pre-perfusion, were found to bind 110-240 percent more(125)I-ASOR after 1 h at 37 degrees C that they did at 0 time. This recovery of surface ASGP binding activity occurred in the absence of significant protein synthesis (i.e., basal medium or 1 mM cycloheximide). Suspensions of isolated, unpolarized hepatocytes were placed in monolayer culture for 24 h and confluent cells were demonstrated to reestablish morphologically distinct plasma membrane regions analogous to bile canalicular, lateral, and sinusoidal surfaces in vivo. More than 95 percent of these cells maintained the capacity to bind, internalize, and degrade (125)I-ASOR at levels comparable to those of the freshly isolated population. ASOR-HRP (at 5 degrees C) was specifically bound to all plasma membrane surfaces of repolarized hepatocytes (cultured for 24 h) except those lining bile canalicular-like spaces. Thus, both isolated, unpolarized hepatocytes and cells cultured under conditions that promote morphological reestablishment of polarity maintain the pathway for receptor- mediated endocytosis of ASGPs.     

Loss of surface galactosyl receptor activity on isolated rat hepatocytes induced by monensin or chloroquine requires receptor internalization via a clathrin coated pit pathway

We studied the effect of hyperosmotic inhibition of the clathrin coated pit cycle on the monensin- and chloroquine-dependent loss of surface galactosyl (Gal) receptor activity on isolated rat hepatocytes. Cells treated for 60 min without ligand at 37 degrees C with 25 microM monensin or 300 microM chloroquine in normal medium (osmolality congruent to 275 mmol/kg) bound 40-60% less 125I-asialo-orosomucoid (ASOR) at 4 degrees C than untreated cells. Cells exposed to monensin or chloroquine retained progressively more surface Gal receptor activity, however, when the osmolality of the medium was increased above 400 mmol/kg (using sucrose as osmolite) 10 min prior to and during drug treatment. Cells pretreated for 10 min with hyperosmolal media (600 mmol/kg) alone internalized less than or equal to 10% of surface-bound 125I-ASOR. Thus, the ligand-independent loss of surface Gal receptor activity on monensin- and chloroquine-treated hepatocytes requires internalization of constitutively recycling receptors via a coated pit pathway.     

Sorting of endocytosed transferrin and asialoglycoprotein occurs immediately after internalization in HepG2 cells

After receptor-mediated uptake, asialoglycoproteins are routed to lysosomes, while transferrin is returned to the medium as apotransferrin. This sorting process was analyzed using 3,3'-diaminobenzidine (DAB) cytochemistry, followed by Percoll density gradient cell fractionation. A conjugate of asialoorosomucoid (ASOR) and horseradish peroxidase (HRP) was used as a ligand for the asialoglycoprotein receptor. Cells were incubated at 0 degree C in the presence of both 131I-transferrin and 125I-ASOR/HRP. Endocytosis of prebound 125I-ASOR/HRP and 131I-transferrin was monitored by cell fractionation on Percoll density gradients. Incubation of the cell homogenate in the presence of DAB and H2O2 before cell fractionation gave rise to a density shift of 125I-ASOR/HRP-containing vesicles due to HRP-catalyzed DAB polymerization. An identical change in density for 125I-transferrin and 125I-ASOR/HRP, induced by DAB cytochemistry, is taken as evidence for the concomitant presence of both ligands in the same compartment. At 37 degrees C, sorting of the two ligands occurred with a half-time of approximately 2 min, and was nearly completed within 10 min. The 125I-ASOR/HRP-induced shift of 131I-transferrin was completely dependent on the receptor-mediated uptake of 125I-ASOR/HRP in the same compartment. In the presence of a weak base (0.3 mM primaquine), the recycling of transferrin receptors was blocked. The cell surface transferrin receptor population was decreased within 6 min to 15% of its original size. DAB cytochemistry showed that sorting between endocytosed 131I-transferrin and 125I-ASOR/HRP was also blocked in the presence of primaquine. These results indicate that transferrin and asialoglycoprotein are taken up via the same compartments and that segregation of the transferrin-receptor complex and asialoglycoprotein occurs very efficiently soon after uptake.     

A new competition assay for the solubilized hepatic galactosyl receptor

The present method of quantitating soluble asialoglycoprotein (galactosyl) receptor activity relies on the selective precipitation of receptor-ligand complexes to allow separation from free ligand. To provide an alternative to selective precipitation procedures, a simple and rapid method to assay for detergent-solubilized galactosyl receptor activity has been developed which uses permeabilized, fixed cells as a source of immobilized solid-phase receptors. Isolated rat hepatocytes were treated with digitonin to make available the internal as well as the external receptors. The permeable cells were also treated with glutaraldehyde to prevent further protein loss during subsequent exposure to detergents such as Triton X-100. The permeable/fixed cells, which retained about 70% of their total 125I-asialo-orosomucoid (125I-ASOR)-binding activity, with 89% specific binding, were insoluble even in 0.5% Triton X-100 and were easily pelleted. The permeable/fixed cells can be prepared in advance and stored frozen for months. A detergent extract of receptor is mixed with a constant amount of both 125I-ASOR and permeable/fixed cells. Soluble active receptors compete with immobilized receptors on the treated cell for binding of the 125I-ASOR. The assay is reproducible, linear over a broad range of soluble receptor concentration, and can quantitate receptor activity from as few as 10(5) hepatocytes. A modified purification procedure for the rat hepatic galactosyl receptor using this competition assay is also described.     

The two isotypes of the human insulin receptor (HIR-A and HIR-B) follow different internalization kinetics.

Human insulin receptor (HIR) is expressed in two isoforms which differ in the C-terminal end of the alpha-subunit (HIR-A = -12 aa, HIR-B = +12 aa). We studied internalization kinetics of HIR-A and HIR-B in Rat1 fibroblasts. Internalized receptors were quantified by 125I-insulin binding after cell trypsinisation and solubilization, surface receptors were determined by 125I-insulin binding to intact cells and by chemical crosslinking with B26-125I-insulin. HIR-A and HIR-B show different kinetics of receptor internalization. While in HIR-A cells the maximum of internalization (approx. 65% of total) is reached after 10 min followed by a high recycling rate (approx. 80% of internalized receptors after 20 min), the internalization in HIR-B cells reaches a maximum (approx. 60% of total) after 15 min without detectable recycling within 30 min. The data show that the different alpha-subunits of both receptor types determine different velocities of internalization and determine whether a fast recycling occurs.     

Synthesis and characterization of N-hydroxysuccinimide ester chemical affinity derivatives of asialoorosomucoid that covalently cross-link to galactosyl receptors on isolated rat hepatocytes

We have developed chemical affinity reagents for the hepatic galactosyl receptor. Asialoorosomucoid (ASOR) was derivatized with five homobifunctional N-hydroxysuccinimide (NHS) ester cross-linkers. NHS/ASOR derivatives were synthesized, purified, and applied within 10 min to isolated rat hepatocytes at 4 degrees C. Specific binding of these 125I-labeled derivatives was approximately 90% in the presence of either EGTA or excess ASOR. Specific cross-linking assessed by the resistance of specifically bound NHS/125I-ASOR to release by EGTA, was 50-75% of the specifically bound ligand. The extent of specific cross-linking correlated with the average number of NHS groups per ASOR and was controlled by varying the molar ratio of cross-linker to ASOR during the synthesis. Cross-linking proceeded rapidly at 4 degrees C as a first-order process (k = 0.25 min-1, t1/2 = 2.8 min). After being cross-linked with any of the NHS/125I-ASOR derivatives, cells were washed with EGTA, solubilized in Triton X-100, and analyzed by SDS-PAGE and autoradiography. Major bands were observed at Mr congruent to 84K, 93K, and 105K corresponding to the expected size of 1:1 adducts between NHS/ASOR (Mr congruent to 41.3K) and the three subunits of the receptor, Mr congruent to 43K, 50K, and 60K. The three subunits, rat hepatic lectin (RHL) 1, 2, and 3, were labeled in the ratio of about 1.0:1.2:1.0, respectively. After cross-linking, a polyclonal goat antibody to the receptor immunoprecipitated up to 100% of the specifically cross-linked NHS/125I-ASOR. Preimmune IgG immunoprecipitated less than 1% of the radiolabeled ligand. Cell surface receptors were cross-linked to NHS-ASOR, extracted with Triton X-100, immunoprecipitated with anti-orosomucoid-Sepharose, and subjected to Western blot analysis. By use of anti-sera specific for RHL 1 or RHL 2/3 (from K. Drickamer), cross-linked complexes of Mr congruent to 85K or approximately 90-115K, respectively, were detected as were un-cross-linked native subunits. The ratio of free to cross-linked subunits was approximately 10:1 for RHL 1 and approximately 0.5:1 for RHL 2/3. We conclude that all three receptor subunits can cross-link to ligand. We propose a model in which the native receptor is a heterohexamer composed of four subunits of RHL 1 and two subunits of RHL 2 and/or RHL 3.     

Receptor-mediated endocytosis of tissue-type plasminogen activator by the human hepatoma cell line Hep G2

Receptor-mediated endocytosis of tissue-type plasminogen activator (t-PA) was characterized with the human hepatoma cell line Hep G2. At 4 degrees C binding of 125I-t-PA to Hep G2 cells is rapid, specific, saturable, and reflective of a homogeneous population of 76,000 high-affinity surface sites per cell (Kd = 3.7 nM). The kinetics of 125I-t-PA binding to its receptor are characterized by rate constants for association (k1 = 1.2 x 10(6) min-1 M-1) and dissociation (k-1 = 0.001 min-1). A specific glycosylation pattern does not appear to be required for binding. Binding does not appear to be mediated by other recognized hepatic receptor systems. At 37 degrees C a single cohort of bound 125I-t-PA molecules disappears rapidly from the cell surface. Ligand then accumulates intracellularly. Thereafter, the intracellular concentration of ligand declines simultaneously with the release of ligand degradation products into the media. In the continued presence of 125I-t-PA at 37 degrees C the concentration of cell-associated ligand plateaus after 30 min with the concomitant appearance of low molecular weight 125I-labeled fragments in the media. Cumulative degradation then increases linearly with time. Under steady state conditions half-maximal ligand uptake and degradation is 26.6 nM and maximal rate of catabolism is 1.2 pmol/10(6) cells/h. At saturating ligand concentrations uptake and degradation by Hep G2 cells continue linearly for at least 6 h even in the absence of protein synthesis. During this period the cumulative ligand uptake exceeds the total cellular capacity of binding sites, consistent with receptor recycling. We conclude that t-PA clearance in human Hep G2 cells involves ligand binding, uptake, and degradation mediated by a novel high-capacity, high-affinity specific receptor system.     

Vanadate modulates the activity of a subpopulation of asialoglycoprotein receptors on isolated rat hepatocytes: active surface receptors are internalized and replaced by inactive receptors

In the absence of ligand, sodium vanadate causes a time- and dose-dependent loss of up to approximately 50% of the surface galactosyl receptor (GalR) activity in rat hepatocytes at 37 degrees C. The effect on total (surface plus intracellular) GalR activity is also dependent on exposure time and vanadate concentration. At less than 1 mM, vanadate induces a transient decrease and then partial recovery of cell surface GalR activity. At greater than 3 mM vanadate, surface GalR activity decreases rapidly (t1/2 approximately 2 min). Lost surface activity is initially recovered in digitonin-permeabilized cells, indicating that active surface GalRs redistribute to the cell interior. However, an antibody assay for GalR protein showed that although surface activity decreased, there was no decrease in surface receptor protein. The active intracellular GalRs then slowly inactivate over 30-60 min. With 8 mM vanadate, the loss of both surface and total cellular GalR activity is more rapid and coincident; no lag is observed. Maximal activity loss, however, was still only approximately 50%. Again, no net change was seen in the distribution of GalR protein between the cell surface and the interior. These results indicate that vanadate causes active GalRs to move from the surface to the inside and be replaced by inactive receptors moving from the inside to the cell surface. The Gal receptor system is comprised of two functionally different receptor subpopulations that operate via two distinct intracellular pathways. Only the State 2 GalRs, which recycle constitutively, are sensitive to modulation by vanadate. Consistent with this, vanadate inhibits the endocytosis of 125I-asialoorosomucoid (ASOR) only partially. The rate of uptake and the steady state level of ASOR intracellular accumulation were maximally inhibited by 50 and 70%, respectively, at 0.2 mM vanadate. The rate and extent of degradation of 125I-ASOR were also inhibited by 50-70%. Residual ASOR uptake and degradation is accounted for by the minor vanadate-resistant State 1 Gal receptor pathway.     

Differential effects of leupeptin, monensin and colchicine on ligand degradation mediated by the two asialoglycoprotein receptor pathways in isolated rat hepatocytes.

We have shown that degradation of asialo-orosomucoid (ASOR) in isolated rat hepatocytes occurs by two different intracellular pathways [Clarke, Oka & Weigel (1987) J. Biol. Chem. 262, 17384-17392] mediated by two subpopulations of cell surface galactosyl (Gal) receptors, designated State 1 or State 2 receptors. In the present study, several inhibitors were tested for their effects on ligand degradation by the State 1 or State 2 pathway. Leupeptin, monensin and chloroquine completely inhibited degradation of 125I-labelled ASOR in both pathways. Dose-response studies showed, however, that the State 2 pathway was more sensitive to leupeptin or monensin than the State 1 pathway. No differences were observed with chloroquine. For example, the onset of inhibition in the State 2 and State 1 pathways occurred at about 0.05 and 0.3 microM-leupeptin respectively, a 6-fold difference. At 3.5 microM-monensin, 125I-ASOR degradation in the State 2 pathway was completely blocked, whereas degradation in the State 1 pathway was essentially unaffected. Colchicine was observed to give the largest differential sensitivity between the two pathways. The State 2 degradation pathway was about 30-fold more sensitive to colchicine than the State 1 pathway. Lumicolchicine had no affect. The onset of inhibition of the rate of 125I-ASOR degradation in the State 2 and State 1 pathways occurred at approximately 0.1 and 3.0 microM-colchicine respectively. At very high concentrations (greater than 0.1 mM), the State 1 pathway could be completely inhibited. We conclude that intracellular 125I-ASOR processing or delivery to degradative compartments in both the State 1 and State 2 Gal receptor pathways requires low pH. Ligand delivery to the degradative compartment does not require microtubules in the State 1 pathway, consistent with the very rapid onset of degradation in this pathway. The State 2 degradation pathway does require microtubules.     

Comparison of the kinetics of cycling of the transferrin receptor in the presence or absence of bound diferric transferrin.

The kinetics of cycling of the transferrin receptor in A431 human epidermoid-carcinoma cells was examined in the presence or absence of bound diferric transferrin. In order to investigate the properties of the receptor in the absence of transferrin, the cells were maintained in defined medium without transferrin. It was demonstrated that Fab fragments of a monoclonal anti-(transferrin receptor) antibody (OKT9) did not alter the binding of diferric 125I-transferrin to the receptor or change the accumulation of [59Fe]diferric transferrin by cells. OKT9 125I-Fab fragments were prepared and used as a probe for the function of the receptor. The first-order rate constants for endocytosis (0.16 +/- 0.02 min-1) and exocytosis (0.056 +/- 0.003 min-1) were found to be significantly lower for control cells than the corresponding rate constants for endocytosis (0.22 +/- 0.02 min-1) and exocytosis (0.065 +/- 0.004 min-1) measured for cells incubated with 1 microM-diferric transferrin (mean +/- S.D., n = 3). The cycling of the transferrin receptor is therefore regulated by diferric transferrin via an increase in both the rate of endocytosis and exocytosis. Examination of the accumulation of OKT9 125I-Fab fragments indicated that diferric transferrin caused a marked decrease in the amount of internalized 125I-Fab fragments associated with the cells after 60 min of incubation at 37 degrees C. Diferric transferrin therefore increases the efficiency of the release of internalized 125I-Fab fragments compared with cells incubated without diferric transferrin. These data indicate that transferrin regulates the sorting of the transferrin receptor at the cell surface and within endosomal membrane compartments.     

Insulin receptor recycling in vascular endothelial cells. Regulation by insulin and phorbol ester

Endothelial cell insulin receptors mediate the transcytosis of insulin from luminal to abluminal cell surface. We have investigated the kinetics of insulin receptor translocation by immunoprecipitation of radiolabeled receptors at various times before and after trypsin treatment of intact endothelial cells. Insulin receptors were constitutively internalized with t1/2 = 18 +/- 2 min and were recycled to the cell surface. Insulin stimulated receptor internalization and externalization rates 2.6- and 2.4-fold, respectively. Changes in cell-surface binding of 125I-insulin were consistent with the receptor translocation rates observed in surface-labeling experiments. Phorbol myristate acetate (PMA) treatment increased the rate of insulin-stimulated receptor externalization 1.7-fold. PMA treatment increased the constitutive externalization rate 3.5-fold without affecting the constitutive internalization rate, suggesting that recycling might occur via a mobilization of receptors from intracellular sites in a manner independent of internalization rate. Analysis of the intracellular distribution of receptors by 125I-insulin binding and immunogold electron microscopy revealed that less than one-third of the total insulin receptor pool resided on the cell surface. In summary, endothelial cell insulin receptors are constitutively recycled, and internalization and externalization rates are increased by receptor occupancy and PMA treatment.