Mannose-specific endocytosis receptor of alveolar macrophages: demonstration of two functionally distinct intracellular pools of receptor and their roles in receptor recycling

Receptor-mediated endocytosis of rat preputial beta-glucuronidase and the glycoconjugate mannose-BSA by rat alveolar macrophages is inhibited by chloroquine and ammonium chloride. We have previously reported that these drugs cause a loss of cell surface binding activity and that they do not inhibit internalization of receptor ligand complexes when incubated with cells at 37 degrees C. In this report we more clearly delineate the intracellular site of weak base inhibition of receptor recycling and the mechanism of that inhibition. From our analysis of the kinetics of ligand transport we conclude that there are two functionally distinct intracellular pools of receptor. One of these, the cycling pool, is not sensitive to the presence of weak bases, and receptor-ligand complexes return from this pool to the cell surface intact. The second pool is responsible for the time-dependent intracellular delivery of ligand to acid vesicles, which is inhibited by weak bases. Chloroquine and ammonium chloride appear to inhibit the dissociation of receptor-ligand complexed in this second pool and thereby the production of free receptors for the continuation of receptor-mediated endocytosis. We examine the internalization and binding of ligand in normal and paraformaldehyde-treated cells and find that these are strongly affected by pH. In particular, the dissociation rate of receptor ligand complexes is enhanced greater than 7.5 fold by lowering the medium pH from 7 to 6. From these results we propose that weak bases raise the pH of acid intracellular compartments, slowing the rate of receptor-ligand dissociation and thereby reducing the cellular pool of free receptors available for further uptake of ligand. In addition, we demonstrate that receptor-ligand complexes cannot return to the cell surface from the amine-sensitive (acid) intracellular pool that led us to call this the nonreleasable pool. This final observation indicates that receptor movements through these two pools are functionally distinct processes.     

Accumulation of epidermal growth factor within cells does not depend on receptor recycling

Quiescent cells seemingly have a constant number of surface epidermal growth factor receptors. However, exposure of cells to agents which interfere with normal protein turnover suggests that these receptors are internalized and degraded with an apparent half-life of ～6 hours. We show that the time course of maximal accumulation of ligand-receptor complexes is not altered under conditions where degradation of the ligand is inhibited, indicating that no degradation occurs during its first hour of exposure to cells. We also conclusively demonstrate that epidermal growth factor receptors are not recycled during the initial uptake of the ligand, and that a component of pinocytosis of this growth factor is dependent on $\text{de}\text{novo}$ protein synthesis.     

Human interferon-gamma is internalized and degraded by cultured fibroblasts

Human interferon-gamma (IFN-gamma) binds specifically and with high affinity to receptors on the surface of cultured fibroblasts (GM-258). At 37 degrees C about 50% of the receptor-bound IFN-gamma was rapidly internalized (t 1/2 = 4-5 min) by these cells. Following an initial lag of 15-30 min, internalized IFN-gamma was continuously degraded over a period of at least 8 h. The total uptake of IFN-gamma over this time period was found to exceed by 5 times the number of occupied IFN receptors present on the surface of these cells, suggesting that either there is a large intracellular pool of IFN-gamma receptors, or that receptors are recycled during the course of incubation. Cycloheximide (100 micrograms/ml) inhibited uptake only after the first 2 h of incubation and then only moderately. It is therefore unlikely that de novo receptor synthesis plays a major role in the observed uptake process. Both sodium azide (15 mM) and methylamine (20 mM) inhibited both the uptake and degradation of IFN-gamma at all times up to 6 h. While uptake was only slightly reduced in the presence of chloroquine (25 microM), degradation was markedly inhibited, suggesting that degradation occurs intracellularly, probably within lysosomes.     

Receptor-mediated endocytosis of ovalbumin by two carbohydrate-specific receptors in rat liver cells. The intracellular transport of ovalbumin to lysosomes is faster in liver endothelial cells than in parenchymal cells.

1. The uptake of ovalbumin (OVA) in rat liver parenchymal cells (PC) and non-parenchymal cells was studied in vivo and in vitro in order to compare the cellular expression of glycoprotein receptors and the kinetics of intracellular transport of ligand endocytosed by these receptors. 2. Ovalbumin was labelled with 125I or with 125I-tyramine-cellobiose (125I-TC). By using 125I-TC-OVA the labelled degradation products were trapped in the cells. 3. 125I-TC-OVA was rapidly cleared from blood mainly by receptor-mediated uptake in the liver. At 30 min after injection, 50% of the ligand was recovered in the liver. The endothelial cells (EC) and the PC were the predominant cell types responsible for uptake. 4. The uptake in PC was strongly inhibited by asialo-orosomucoid (AOM), but not by mannan, indicating that the uptake in these cells was mediated by the galactose receptor and not by the mannose receptor. This finding is compatible with the observation that a proportion of the OVA contains terminal galactose residues in the carbohydrate moiety. 5. In vitro uptake of OVA in cultured EC was saturable and inhibited by mannan, mannose, fructose, N-acetylglucosamine, EDTA or monensin, but not by galactose or AOM. The uptake of OVA in these cells was therefore mediated by the mannose receptor. 6. To label the organelles involved in endocytosis in PC and EC, 125I-TC-OVA was injected intravenously together with an excess of either AOM or mannan. In this way the labelled ligand could be directed selectively to EC or PC respectively. Subcellular fractionation of total liver in sucrose and Nycodenz gradients revealed that in EC the intracellular transport of OVA is so fast that endocytosed ligand accumulates and thus increases the density of the lysosomes. Conversely, in PC transfer of ligand is slower, with the result that accumulation of undegraded ligand in the lysosomes does not occur. These findings are interpreted to mean that in EC the rate-limiting step of handling of endocytosed ligand is intralysosomal degradation, whereas in PC the rate-limiting step is transport of ligand to the lysosomes. 7. Altogether, these findings suggest that endocytosis of OVA by the liver EC and PC is mediated by mannose and galactose receptors respectively, and that the kinetics of intracellular transport of OVA differ in the two cell types.     

Recycling of the hepatic asialoglycoprotein receptor in isolated rat hepatocytes. Receptor-ligand complexes in an intracellular slowly dissociating pool return to the cell surface prior to dissociation

We recently reported that the dissociation of internalized receptor-125I-asialo-orosomucoid (ASOR) complexes by isolated hepatocytes is a biphasic process; most complexes dissociate rapidly but 25-50% dissociate slowly (Oka, J. A., and Weigel, P. H. J. Biol. Chem. 258, 10253-10262). Cells were allowed to endocytose a pulse of surface-bound 125I-ASOR, and were washed and then incubated at 37 degrees C in the presence or absence of ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA). Without EGTA, very little intact ASOR appeared in the medium. With EGTA present, a large amount of intracellular ligand appeared undegraded in the medium in a time-dependent manner. N-Acetylgalactosamine, but not ASOR, in the medium also caused release of intact 125I-ASOR. Within 15 min, more than 50% and by completion at least 80% of the internalized ligand in the slow dissociation compartment was released into the medium. If cells containing internalized ligand were incubated at 37 degrees C for increasing times before the addition of EGTA, then progressively less ligand accumulated in the medium. Experiments at 18 degrees C, a temperature at which neither degradation nor slow dissociation occurred, demonstrated that in the presence of EGTA the intracellular free 125I-ASOR pool did not change. The amount of receptor-bound ligand in the slowly dissociating pool decreased and the amount of intact ligand in the medium increased by essentially equal amounts. The temperature dependence for the return of internal 125I-ASOR to the cell surface was similar to that for endocytosis, with a cut-off temperature of about 12 degrees C. We conclude that a normal part of the endocytic process involves the return of receptor-ligand complexes to the cell surface from an internal slowly dissociating pool. This might reflect either an obligatory step or a reversible statistically random step in the endocytic/recycling pathway.     

Expression of haptoglobin receptors in human hepatoma cells.

The uptake of radio-labeled hemoglobin-haptoglobin complex (Hb-Hp) by human hepatoma PLC/PRF/5 and HepG2 cells was investigated in an attempt to characterize the uptake process and intracellular transport. Human hepatoma cells took up Hb-Hp in a receptor-mediated manner. Scatchard analysis of binding revealed that PLC/PRF/5 and HepG2 cells exhibited about 21,000 and 63,000 haptoglobin receptors/cell, with a dissociation constant (Kd) of 8.0 and 17 nM, respectively. Human hepatocytes in primary culture also expressed about 84,000 receptors/cells, with a Kd of 7.4 nM. The hemoglobin-haptoglobin complex was internalized and subsequently the internalized Hb-Hp was slowly degraded in the cells. Preincubation of the cells with Hb-Hp resulted in a decrease in binding of the radioactive Hb-Hp to the cell surface, and was accompanied with an accumulation of intracellular receptors. The uptake of Hb-Hp by the cells was not inhibited by 100 microM chloroquine or by 10 mM methylamine, but was inhibited by 50 microM monodansylcadaverine. Hemoglobin-heme taken up by the cells induced microsomal heme oxygenase. Thus, human hepatoma PLC/PRF/5 and HepG2 cells can take up Hb-Hp by haptoglobin receptor-mediated endocytosis and Hb-Hp probably causes translocation of the haptoglobin receptors from the cell surface to the cell interior where they can be degraded. The internalized heme-moiety of hemoglobin can regulate the expression of heme oxygenase.     

Binding, internalization, and intracellular processing of protein ligands. Derivation of rate constants by computer modeling

Information about ligand binding, dissociation, internalization, and intracellular processing and about receptor turnover, processing, and insertion into the membrane is contained in the time-dependent changes in concentrations of membrane-associated and internalized ligand. Single experiments similar in design to those typically performed for Scatchard analyses of binding data conducted at physiological temperature and in the absence of inhibitors of ligand-receptor complex internalization and degradation can provide kinetic data sufficient to permit derivation of all the respective rate constants by numerical methods. We developed an analytical solution of the kinetic model which assumes that all of these processes follow first order kinetics. The model represents interactions of surface receptors (R)s, the surface ligand-receptor complex (LR)s and internalized receptor-ligand complex (LR)I: d[R]S/dt = Vr - kt[R]S - ka[L] [R]S + kd [LR]S; d[LR]S/dt = ka[L] [R]S - kd[LR]S - ke[LR]S; d[LR]I/dt = ke[LR]S - kh[LR]I; Vr is the constant rate of insertion of receptors into the membrane, kt is the internalization rate constant for free receptors, ka and kd are association and dissociation rate constants for ligand-surface receptor interaction, ke is the internalization rate constant for ligand-receptor complexes, and kh is the intracellular ligand decomposition rate constant. The interaction of radioiodinated human recombinant interferon-alpha 2a with the human alveolar lung carcinoma cell line, A549, was adequately accounted for by the model. The rate constants, numerically derived from time-dependent concentrations of surface-bound and internalized ligand of other systems taken from the literature, were in agreement with values of these rate constants individually measured by steady-state experiments. In cases where the fate of internalized radioactivity was more complex than assumed by the model, the parameters ka, kt, (kd + ke) and Vr could be derived from the time dependence of [LR]S.     

Internalization and processing of transferrin and the transferrin receptor in human carcinoma A431 cells

The binding and subsequent intracellular processing of transferrin and transferrin receptors was studied in A431 cells using 125I-transferrin and a monoclonal antibody to the receptor (ATR) labeled with 125I and gold colloid. Using 125I-transferrin we have shown that, whereas at 37 degrees C uptake proceeded linearly for up to 60 min, most of the ligand that was bound was internalized and then rapidly returned to the incubation medium undegraded. At 37 degrees C, the intracellular half- life of the most rapidly recycled transferrin was 7.5 min. 125I-ATR displayed the same kinetics of uptake but following its internalization at 37 degrees C, it was partially degraded. At 22 degrees C and below, the intracellular degradation of 125I-ATR was selectively inhibited and as a result it accumulated intracellularly. Electron microscopy of conventional thin sections and of whole-cell mounts was used to follow the uptake and processing of transferrin receptors labeled with ATR- gold colloid complexes. Using a pulse-chase protocol, the intracellular pathway followed by internalized ATR gold-receptor complexes was outlined in detail. Within 5 min at 22 degrees C the internalized complexes were transferred from coated pits on the cell surface to a system of narrow, branching cisternae within the peripheral cytoplasm. By 15 min they reached larger, more dilated elements that, in thin section, appeared as irregular profiles containing small (30-50-nm diam) vesicles. By 30 min, the gold complexes were located predominantly within typical spherical multivesicular bodies lying in the peripheral cytoplasm, and by 40-60 min, they reached a system of cisternal and multivesicular body elements in the juxtanuclear area. At 22 degrees C, no other compartments became labeled but if they were warmed to 37 degrees C the gold complexes were transferred to lysosome- like elements. Extracting ATR-gold complexes with Triton X after a 30- min chase at 22 degrees C and purifying them on Sepharose-transferrin indicated that the internalized complexes remained bound to the transferrin receptor during their intracellular processing.     

Separate intracellular pathways for insulin receptor recycling and insulin degradation in isolated rat adipocytes

To gain insight into the sequence of events that follow endocytotic uptake of insulin receptor complexes, we have examined the interrelationship between the degradative pathway of the insulin ligand and the recycling pathway of the insulin receptor. Tris(hydroxymethyl)aminomethane and other nonamphoteric amines were found to selectively impair insulin receptor recycling while leaving the insulin-degradative pathway intact. In contrast, low concentrations of the lysosomotropic agent chloroquine markedly inhibited intracellular insulin degradation but had little or no affect on the recycling of internalized receptors. Thus, we conclude: (1) that insulin dissociates from its receptor after endocytotic uptake and both receptor and ligand follow a separate intracellular pathway; and (2) that receptor recycling and insulin degradation can be selectively inhibited by Tris and chloroquine, respectively, highlighting the potential usefulness of these agents as intracellular probes in the study of receptor-ligand metabolism.     

Proteasomes regulate the duration of erythropoietin receptor activation by controlling down-regulation of cell surface receptors

The binding of erythropoietin (Epo) to its receptor leads to the transient phosphorylation of the Epo receptor (EpoR) and the activation of intracellular signaling pathways. Inactivation mechanisms are simultaneously turned on, and Epo-induced signaling pathways return to nearly basal levels after 30-60 min of stimulation. We show that proteasomes control these inactivation mechanisms. In cells treated with the proteasome inhibitors N-Ac-Leu-Leu-norleucinal (LLnL) or lactacystin, EpoR tyrosine phosphorylation and activation of intracellular signaling pathways (Jak2, STAT5, phosphatidylinositol 3-kinase) were sustained for at least 2 h. We show that this effect was due to the continuous replenishment of the cell surface pool of EpoRs in cells treated with proteasome inhibitors. Proteasome inhibitors did not modify the internalization and degradation of Epo.EpoR complexes, but they allowed the continuous replacement of the internalized receptors by newly synthesized receptors. Proteasome inhibitors did not modify the synthesis of EpoRs, but they allowed their transport to the cell surface. N-Ac-Leu-Leu-norleucinal, but not lactacystin, also inhibited the degradation of internalized Epo.EpoR complexes, most probably through cathepsin inhibition. The internalized EpoRs were not tyrosine-phosphorylated, and they did not activate intracellular signaling pathways. Our results show that the proteasome controls the down-regulation of EpoRs in Epo-stimulated cells by inhibiting the cell surface replacement of internalized EpoRs.     

Is movement of mannose 6-phosphate-specific receptor triggered by binding of lysosomal enzymes?

Mannose 6-phosphate-specific receptors with an apparent molecular mass of 215,000 are present in fibroblasts at the cell surface and in intracellular membranes. The cell surface receptors mediate endocytosis of exogenous lysosomal enzymes and exchange with the intracellular receptors, which function in the sorting of endogenous lysosomal enzymes. In the present study, several methods independent of receptor ligands were designed in order to examine the exchange of receptors under conditions where receptor-ligand complexes do not dissociate (weak bases and monensin) or where receptor-ligand complexes are not formed due to absence of endogenous ligands as a result of inhibition of protein synthesis. Weak bases and monensin reduce the concentration of receptors at the cell surface by 20-30% and free cell surface receptors were replaced by occupied receptors. The latter continued to be exchanged with internal ligand-occupied receptors and the rates of the exchange were similar to the control values. The exchange of receptors between the cell surface and internal membranes was also not affected when the receptor ligands were depleted from the transport compartments by treating the cells with cycloheximide for up to 10 h. We conclude from these results that movement of mannose 6-phosphate-specific receptors along the endocytosis and sorting pathways is constitutive and not triggered by binding or dissociation of ligands.     

Secretion and degradation of lipoprotein lipase in cultured adipocytes. Binding of lipoprotein lipase to membrane heparan sulfate proteoglycans is necessary for degradation

Equilibrium-binding data of highly purified 125I-labeled avian lipoprotein lipase to cultured avian adipocytes demonstrate the presence of a class of high affinity binding sites. Analysis of the binding function yielded an association constant of 0.62 x 10(8)M-1 and a maximum binding capacity of 2.1 micrograms/60-mm dish. From a time course of dissociation of 125I-lipoprotein lipase from adipocytes at 4 degrees C, a dissociation rate constant of 6.1 x 10(-5)s-1 was obtained. Pretreatment of cells with heparinase and heparitinase resulted in a quantitative suppression of the high affinity binding component, establishing that lipoprotein lipase is bound to cell surface heparan sulfate proteoglycans. At 37 degrees C, cell surface-bound 125I-lipoprotein lipase is internalized and either degraded or recycled to the medium. The degradation rate constant for 125I-lipoprotein lipase was estimated to be 0.78 h-1. The degradation rate constant was reduced 6-fold when cells were exposed to 100 microM chloroquine, indicating that most of the degradation occurs within the lysosomal compartment. By using cells that had been pulsed with Trans35S-label for 1 h, it was demonstrated that acute treatment with endoglycosidases for up to 1 h resulted in a new lipoprotein lipase secretion rate which was 6-fold higher than that of control cells. Degradation of newly synthesized lipoprotein lipase was essentially blocked 30 min after the initiation of the chase. In other studies it was observed that there were no additive effects of chloroquine and either endoglycosidase or heparin treatment on total lipoprotein lipase levels (intracellular, cell surface, and medium) in adipocyte cultures. These experiments support the hypothesis that the release of lipoprotein lipase from its receptor prevents its internalization and degradation and enhances enzyme efflux from the adipocyte. A new model of lipoprotein lipase secretion in cultured adipocytes is proposed: Newly synthesized lipoprotein lipase is transported to the cell surface where it binds to specific heparan sulfate proteoglycan receptors. The enzyme is either released to the medium or internalized via the receptor, in which case the enzyme is degraded or recycled to the cell surface. Major determinants of enzyme efflux from the cell surface include the number and integrity of receptors, the association constant of the enzyme-receptor complex, and the presence in the medium of competing molecules with high affinity for lipoprotein lipase. In this model, modulation of lipoprotein lipase degradation rate may be a significant mechanism for acute regulation of enzyme efflux independent of changes in the rate of enzyme synthesis.     

Cohort movement of different ligands and receptors in the intracellular endocytic pathway of alveolar macrophages

The rate of movement of different receptors and ligands through the intracellular endocytic apparatus was studied in alveolar macrophages. Cells were exposed to iodinated alpha-macroglobulin-protease complexes, mannose terminal glycoproteins, diferric transferrin, and maleylated proteins. By use of the diaminobenzidine density shift procedure, we demonstrated that these ligands were internalized into the same endocytic vesicle. We then compared the rates of transfer to the lysosome or recycling to the cell surface of different ligands/receptors contained in the same endosome. We found that although the rate constant for degradation was ligand specific, the lag time prior to the initiation of degradation was the same for all three ligands. We also found that molecules taken up nonspecifically by fluid-phase pinocytosis had the same lag time prior to degradation as ligands internalized via receptor-mediated endocytosis. These data suggest that different molecules within the same endocytic compartment are transferred to the lysosome (or degradative compartment) at the same rate. We measured the rate of return of receptors to the cell surface by either inactivating surface receptors by protease treatment at 0 degrees C, or by incubating cells with saturating amounts of nonradioactive ligand at 37 degrees C. We then measured the rate of appearance of "new" receptors on the cell surface. Using these approaches, we found that three different receptors were transferred from internal pools to the cell surface at the same rate. The rate of transfer was independent of whether receptors were initially occupied or unoccupied. Our observations indicate that receptor/ligands, once inside alveolar macrophages, are transported by vesicles which transfer their contents as a cohort from one compartment to another. The rate of movement of these receptors is determined by the movement of vesicles and is independent of their content.     

Evidence that the hepatic asialoglycoprotein receptor is internalized during endocytosis and that receptor recycling can be uncoupled from endocytosis at low temperature

Rat hepatocytes in the continuous presence of [³H]asialo-orosomucoid quickly establish a steady state number of free and occupied surface receptors and rate of endocytosis. These values do not change even though many times more glycoprotein is internalized than there are surface receptors per cell. However, when cells endocytose only one round of surface bound [³H]asialo-orosomucoid at 37°C the internalization of glycoprotein is about 5 times faster than the increase of functional receptors on the cell surface. At 18°C new surface receptors appear at only 6% of the rate of internalization of pre-bound asialoglycoprotein. The results suggest that reutilization of asialoglycoprotein receptors is preferentially inhibited at low temperature and that receptor-ligand complexes enter the cell.     

Recycling of photoaffinity-labeled insulin receptors in rat adipocytes. Dissociation of insulin-receptor complexes is not required for receptor recycling

We have used an iodinated, photoreactive analog of insulin, 125I-B2(2-nitro-4-azidophenylacetyl)-des-PheB1-insulin, to covalently label insulin receptors on the cell surface of isolated rat adipocytes. Following internalization of the labeled insulin-receptor complexes at 37 degrees C, we measured the rate and extent of recycling of these complexes using trypsin to distinguish receptors on the cell surface from those inside the cell. The return of internalized photoaffinity-labeled receptors to the cell surface was very rapid at 37 degrees C proceeding with an apparent t 1/2 of 6 min. About 95% of the labeled receptors present in the cell 20 min after the initiation of endocytosis returned to the cell surface by 40 min. Recycling was slower at 25 and 16 degrees C compared to 37 degrees C and essentially negligible at 12 degrees C or in the presence of energy depleters. Addition of excess unlabeled insulin had no effect on the recycling of photoaffinity-labeled insulin receptor complexes, whereas monensin, chloroquine, and Tris partially inhibited this process. These data indicate that dissociation of insulin from internalized receptors is not necessary for insulin receptor recycling. Furthermore, agents which have been shown to prevent vesicular acidification inhibit the recycling of insulin receptors by a mechanism other than prevention of ligand dissociation.     

Continuous internalization of tumor necrosis factor receptors in a human myosarcoma cell line

The cell dynamics of the receptor for tumor necrosis factor (TNF) were examined in TNF-sensitive KYM cells derived from human myosarcoma. With receptor synthesis inhibited by cycloheximide, the half-life of the surface TNF receptor was 2 h in the absence of TNF and 30 min in its presence, suggesting that the TNF receptor is non-recycling and that its internalization is accelerated by TNF. During cell incubation with TNF receptor degradation suppressed by chloroquine, the number of surface TNF receptors remained approximately constant, but the total number of surface and internal TNF receptors increased gradually, at 3 h reaching 1.5 times the initial number, thus suggesting continuous synthesis, externalization, internalization, and degradation of the TNF receptor in the absence of cycloheximide. On cell incubation with 125I-TNF, the intracellular quantity of the pulse-labeled TNF-receptor complex promptly increased, reaching a maximum at 20 min, and then gradually declined, thus confirming that the TNF receptor is internalized as a TNF-receptor complex in the presence of TNF. During incubations with protein synthesis suppressed by cycloheximide following surface TNF receptor digestion by trypsin, TNF receptors reappeared on the cell surface, increasing in number to a peak at 60 min and gradually decreasing, and cells previously exposed to cycloheximide with or without TNF showed no recurrence of surface TNF receptors, suggesting that the TNF receptor is non-recycling. The results of the study thus suggest that the TNF receptor is continuously internalized and degraded intracellularly by lysosomes without being recycled regardless of the presence or absence of TNF and, further, that its internalization is accelerated when it is part of the TNF-receptor complex.     

Modulation of interleukin 2 internalization and interleukin 2-dependent cell growth by antireceptor antibodies

The growth factor interleukin 2 (IL2) binds to and is internalized together with high-affinity surface receptors present on lymphoid cells. This endocytosis thus results in down-regulation of the receptors. However, it is not known if the internalization is relevant to the induction of cell growth. In the present study a rat monoclonal antibody to the P55 chain of the IL2 receptor was used to examine the role of receptor internalization in the IL2-dependent autocrine human tumor T cell line IARC 301. When given alone, this antibody did not inhibit IL2 binding, internalization, or IL2-dependent cell proliferation. However, crosslinking by anti-rat immunoglobulins, which did not affect binding of the growth factor, inhibited both IL2 internalization and cell proliferation. Besides offering a novel means for the specific inhibition of the uptake of IL2 bound to IL2 high-affinity receptors, the results are compatible with the association of this receptor-ligand uptake to the growth stimulation by IL2.     

Receptor-mediated endocytosis in Xenopus oocytes. I. Characterization of the vitellogenin receptor system

We have investigated the vitellogenin (VTG) receptor system in Xenopus oocytes since these cells are specialized for endocytosis. Oocytes have between 0.2 and 3 X 10(11) receptors per 1-mm cell. There is only a single class of receptors of low affinity (1.3 X 10(-6) M at 22 degrees C and 2-4 X 10(-6) M at 0 degree C), but high specificity (less than 5% nonspecific binding at 2 X 10(-6) M). The specific internalization rate of the VTG receptor (around 2 X 10(-3) s-1) is first order, highly variable, and at the upper end of the range of values reported for mammalian cells. The receptor association rate constant (9.6 X 10(2) M-1 s-1) is extremely low although the dissociation rate constant was immeasurable. Calcium is required for VTG binding, and low pH does not dissociate the VTG-receptor complex. Monensin treatment at 100 microM caused the loss of surface receptors with a t1/2 of 3 h and the accumulation of internalized ligand in a "pre-lysosomal" endocytic compartment. Conversely, the recovery of surface VTG receptors that were removed with trypsin occurred with a t1/2 of about 2 h. These observations indicate that oocytes have very large intracellular pools of receptors and that although surface receptors are internalized on the time scale of minutes, the intracellular pool is recycled on the time scale of hours.     

Intracellular insulin-receptor dissociation and segregation in a rat fibroblast cell line transfected with a human insulin receptor gene

The cellular processing of insulin and insulin receptors was studied using a rat fibroblast cell line that had been transfected with a normal human insulin receptor gene, expressing approximately 500 times the normal number of native fibroblast insulin receptors. These cells bind and internalize insulin normally. Biochemical assays based on the selective precipitation by polyethylene glycol of intact insulin-receptor complexes but not of free intracellular insulin were developed to study the time course of intracellular insulin-receptor dissociation. Fibroblasts were incubated with radiolabeled insulin at 4 degrees C, and internalization of insulin-receptor complexes was initiated by warming the cells to 37 degrees C. Within 2 min, 90% of the internalized radioactivity was composed of intact insulin-receptor complexes. The total number of complexes reached a maximum by 5 min and decreased rapidly thereafter with a t 1/2 of approximately 10 min. There was a distinct delay in the appearance, rate of rise, and peak of intracellular free and degraded insulin. The dissociation of insulin from internalized insulin-receptor complexes was markedly inhibited by monensin and chloroquine. Furthermore, chloroquine markedly increased the number of cross-linkable intracellular insulin-receptor complexes, as analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis autoradiography. These findings suggest that acidification of intracellular vesicles is responsible for insulin-receptor dissociation. Physical segregation of dissociated intracellular insulin from its receptor was monitored, based on the ability of dissociated insulin to rebind to receptor upon neutralization of acidic intracellular vesicles with monensin. The results are consistent with the view that segregation of insulin and receptor occurs 5-10 min after initiation of dissociation. These studies demonstrate the intracellular itinerary of insulin-receptor complexes, including internalization, dissociation of insulin from the internalized receptor within an acidified compartment, segregation of insulin from the receptor, and subsequent ligand degradation.     

A constitutively active mutant of the human lutropin receptor (hLHR-L457R) escapes lysosomal targeting and degradation

Using biochemical and imaging approaches, we examined the postendocytotic fate of the complex formed by human choriogonadotropin (hCG) and a constitutively active mutant of the human lutropin receptor (hLHR-L457R) found in a boy with precocious puberty and Leydig cell hyperplasia. After internalization, some of the complex formed by the hLHR-wild type (hLHR-wt) and hCG recycles to the cell surface, and some is found in lysosomes where the hormone is degraded. In contrast, the complex formed by the hLHR-L457R and hCG is not routed to the lysosomes, most of it is recycled to the cell surface and hormone degradation is barely detectable. For both, hLHR-wt and -L457R, there is an hCG-induced loss of cell surface receptors that accompanies internalization but this loss cannot be prevented by leupeptin. The removal of recycling motifs of the hLHR by truncation of the C-terminal tail at residue 682 greatly enhances the lysosomal accumulation of the hormone-receptor complexes formed by the hLHR-wt or the L457R mutant, the degradation of the internalized hormone, and the loss of cell surface receptors. The degradation of the hormone internalized by these mutants as well as the loss of cell surface receptors is largely prevented by leupeptin. These results highlight a previously unrecognized complexity in the postendocytotic trafficking of the hLHR and document a clear difference between the properties of the constitutively active mutant and the agonist-activated hLHR-wt. This lack of lysosomal degradation of the L457R mutant could contribute to its constitutive activity by prolonging the duration of signaling.