Glucagon-induced desensitization of adenylyl cyclase in primary cultures of chick hepatocytes. Evidence for multiple pathways

Chick hepatocytes in primary culture have been used to study the homologous and heterologous pathways of glucagon-induced desensitization of adenylyl cyclase. Scatchard analysis and guanine nucleotide effects on dissociation kinetics indicate that the initial phase of homologous desensitization, an increase in low affinity glucagon receptors due to the rapid uncoupling of the receptor from Gs, is essentially complete within 5 min. These receptors recouple within 20 min upon removal of glucagon. Upon prolonged (2 h or more) exposure of hepatocytes to glucagon, disappearance of low affinity receptors from cell surface membranes constitutes the second phase of homologous desensitization. Recovery of these lost and presumably internalized receptors requires more than 12 h following the removal of glucagon but is not dependent on new protein synthesis. The heterologous phase of desensitization is slower, requiring 20-30 min of glucagon treatment to reach completion. Stimulation of adenylyl cyclase by hormonal and nonhormonal effectors is similarly reduced, indicating a common defect in this desensitized state. Agonist occupancy of other hormone receptors coupled to adenylyl cyclase in hepatocytes, such as beta-adrenergic, prostaglandin E1, and vasoactive intestinal peptide, results in heterologous desensitization. Heterologous desensitization is rapidly reversed (within 30 min) upon partial removal of glucagon, under conditions allowing the maintenance of the homologously desensitized state. Neither onset of nor recovery from heterologous desensitization requires protein synthesis. These data indicate that homologous and heterologous desensitization occurs by independent mechanisms. Homologous desensitization involves uncoupling of the glucagon receptor from Gs, followed by removal of these uncoupled receptors from the cell surface. Heterologous desensitization represents a second level of cellular control of hormonal responsiveness to be turned on when the cell is subjected to prolonged hormonal stimulation and withdrawn when hormone levels are lowered.     

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.     

Dynamics of interleukin-6 internalization and degradation in rat hepatocytes.

We have investigated the dissociation, internalization, and degradation of 125I-interleukin-6 (125I-IL-6) by primary rat hepatocytes. Temperature shift experiments following saturation binding of 125I-IL-6 to cell surface receptors in hepatocytes showed a rapid loss of surface-bound 125I-IL-6 (t1/2 = 15 min), concomitant with a rapid rise in internalized radiolabeled ligand. After reaching a maximum by 30 min at 37 degrees C, the level of internalized 125I-IL-6 decreased with time and appeared in the culture media in a non-trichloroacetic acid-precipitable (degraded) state. The addition of the lysosomotropic agent chloroquine inhibited this receptor-mediated degradation of IL-6 without affecting ligand internalization. Polyacrylamide gel electrophoresis analysis of internalized 125I-IL-6 confirms these results. Additionally, we show that the IL-6.IL-6 receptor complex is stable, and dissociation of these two molecular species occurs at a pH below 5.0. In contrast to published results, data presented in this study clearly indicate that IL-6 is rapidly internalized and degraded within hepatocytes by a receptor-mediated mechanism.     

Processing of follitropin and its receptor by cultured pig Sertoli cells. Effect of monensin

Immature pig Sertoli cells, cultured in a chemically defined medium, are able to maintain many of their functional characteristics for at least two weeks. This model was used to investigate the binding, internalization and degradation of 125I-labelled human follitropin (hFSH) and the effects of pig FSH (pFSH) on its own receptors. The binding of 125I-labelled hFSH was dependent on time, temperature and concentration. At 4 degrees C, the apparent steady state was reached in 8-12 h and remained constant for at least 24 h, whereas at 33 degrees C the apparent equilibrium was reached in 4-6 h. Thereafter the total binding declined and by 24 h it was less than 50% of the maximum binding. At 33 degrees C the binding for the hormone to its surface receptor was followed by internalization of the hormone (half-life approximately equal to 1 h) and its degradation (half-life approximately equal to 3 h). The receptor-mediated internalization of hFSH was blocked by phenylarsine oxide. In the presence of the ionophore monensin (20 microM) the rates of binding and internalization were not modified but the degradation rate was much lower (half-life approximately equal to 18 h). Thus, in the presence of monensin, maximum binding increased twofold to threefold, and remained constant for 24 h. This increase was mainly due to an increase of the internalized hormone. When Sertoli cells were exposed to pFSH there was a loss of its own receptor, which was both dose-dependent (ED50 = 250 ng/ml) and time-dependent (t 1/2 = 14 h). Cycloheximide did not modify the FSH-induced down-regulation, whereas monensin enhanced the down-regulation process. These results show that FSH, like other ligands, is internalized and degraded by its target cells and indicate that the hormone-mediated down-regulation is related to the internalization process. However, the discrepancy between the rate of internalization and of hormone-induced down-regulation, suggests that some of the internalized receptors are recycled.     

Internalization, recycling, and redistribution of vasopressin receptors in rat hepatocytes

Three hours after isolation, cultured hepatocytes have approximately 150,000 surface vasopressin receptors/cell, and these exhibit a Kd for 125I-vasopressin of 6 nM based on calculation of Koff/Kon, or a Kd of 9.5 nM based on Scatchard plot analysis. After the binding of 125I-vasopressin to its receptor on the hepatocyte surface, this complex is internalized with a t1/2 of 3-6 min. Following this internalization, the number of vasopressin receptors on the cell surface is restored both in vitro and in the isolated perfused liver with a t1/2 of 8-10 min. This restoration is blocked in vitro by incubation of the hepatocytes at 18 degrees C, but not by cycloheximide, suggesting that internalized vasopressin receptors recycle back to the cell surface. Prolonged incubation of hepatocytes with vasopressin results in the loss of greater than 75% of the vasopressin surface binding at concentrations of vasopressin approximately equivalent to its Kd. The binding of vasopressin to cultured hepatocytes 3-5 h after isolation resembles binding to the isolated perfused whole liver with respect to receptor dynamics. During culture for 48 h, however, we observe a progressive loss of hepatocyte surface vasopressin receptors. Concomitant with this reduction in surface receptors with time in culture, there appears to be a marked elevation in intracellular receptors.     

Copper and zinc ions differentially block asialoglycoprotein receptor-mediated endocytosis in isolated rat hepatocytes.

Asialoglycoprotein receptors on hepatocytes lose endocytic and ligand binding activity when hepatocytes are exposed to iron ions. Here, we report the effects of zinc and copper ions on the endocytic and ligand binding activity of asialoglycoprotein receptors on isolated rat hepatocytes. Treatment of cells at 37 degrees C for 2 h with ZnCl2 (0-220 microM) or CuCl2 (0-225 microM) reversibly blocked sustained endocytosis of 125I-asialoorosomucoid by up to 93% (t1/2 = 62 min) and 99% (t1/2 = 54 min), respectively. Cells remained viable during such treatments. Zinc- and copper-treated cells lost approximately 50% of their surface asialoglycoprotein receptor ligand binding activity; zinc-treated cells accumulated inactive asialoglycoprotein receptors intracellularly, whereas copper-treated cells accumulated inactive receptors on their surfaces. Cells treated at 4 degrees C with metal did not lose surface asialoglycoprotein receptor activity. Exposure of cells to copper ions, but not to zinc ions, blocked internalization of prebound 125I-asialoorosomucoid, but degradation of internalized ligand and pinocytosis of the fluid-phase marker Lucifer Yellow were not blocked by metal treatment. Zinc ions reduced diferric transferrin binding and endocytosis on hepatocytes by approximately 33%; copper ions had no inhibitory effects. These findings are the first demonstration of a specific inhibition of receptor-mediated endocytosis by non-iron transition metals.     

Chronic ethanol administration impairs the binding and endocytosis of asialo-orosomucoid in isolated hepatocytes

We have examined the effect of ethanol administration on receptor-mediated endocytosis of asialo-orosomucoid by isolated hepatocytes. Significantly less ligand was bound, internalized, and degraded by hepatocytes isolated from rats fed an ethanol diet for 5-7 weeks than by cells isolated from chow-fed or pair-fed controls. Reduced binding was shown to be primarily due to a decreased number of cell surface receptors rather than to a lowered affinity of the receptor for its ligand. This reduction in cell surface receptors resulted in a marked inhibition of internalization and degradation of ligand by hepatocytes from the ethanol-fed rats. In addition, a defect in the initial stages of receptor-ligand internalization was also indicated, since less surface-bound ligand was internalized and subsequently degraded in cells from the ethanol-treated animals as compared to controls. Rates of internalization and degradation of internalized ligand were, however, similar for all three groups, suggesting that neither degradation per se nor rate of delivery of internalized ligand to the lysosomes was affected by ethanol feeding. Receptor recycling was impaired in ethanol-fed rats, as indicated by a decrease in the binding site number after stimulation of endocytosis for 120 min when compared to initial binding capacity. Receptor recycling was not impaired in hepatocytes from control animals. These results indicate that chronic ethanol feeding impairs the process of receptor-mediated endocytosis by the liver; the major cause of this impairment appears to be due to a decreased number of cell surface asialoglycoprotein receptors in the ethanol-fed animals, along with a decreased ability of these cells to internalize all of the surface-bound ligand.     

Evidence for the rapid internalization and recycling of lutropin receptors in rat testis Leydig cells.

A study into the binding of 125I-human chorionic gonadotropin (hCG) to the lutropin (LH) receptor in rat testis Leydig cells, and subsequent internalization of the hormone-receptor complex, has been carried out. The results show that there is rapid internalization of the hormone-receptor complex; 240 receptors/cell (from a total of approx. 4000 receptors/cell) were internalized each minute in the first hour after exposure to hCG. Radioactivity was released from the cell 1 h after internalization and was found to be associated with highly degraded hCG. The endocytic process was found to have two temperature-sensitive steps. At 4 degrees C, movement of the hormone-receptor complex inside the cell did not occur, and at 21 degrees C hormone accumulated within the cytoplasm but was not degraded or released from the cell. At 34 degrees C, internalization, degradation and loss of the degraded hormone from the cell occurred. These processes appeared to reach a steady state after 2 h. Even though there is rapid internalization of the hormone-receptor complex following exposure to hCG, the binding sites on the cell surface were maintained for at least 4 h. The number of binding sites on the cell surface was not decreased by a protein synthesis inhibitor but was reduced to undetectable levels by monensin. This compound inhibits acidification of endocytic vesicles, which is known to be an important prerequisite to receptor cycling. It is concluded that, in the rat testis Leydig cells, following binding of hCG to the LH receptor there is rapid internalization of the complex and that recycling of the receptor occurs to the cell surface. This process may be essential in maintaining the capacity of the Leydig cell to bind fresh hormone.     

Amiloride inhibits constitutive internalization and increases the surface number of epidermal growth factor receptors in intact rat hepatocytes

In previous experiments the surface expression of epidermal growth factor (EGF) receptors in freshly isolated rat hepatocytes varied temperature- and time-dependently and was depleted by monensin and cycloheximide in a way suggesting that a subpopulation of these receptors are subject to constitutive cycling (Gladhaug and Christoffersen; 1988). We here report the finding that pretreatment of the hepatocytes with amiloride exerts marked effects on cellular EGF receptor movements. After 2 h incubation with 1 mM amiloride, the receptor level was approximately 270,000 sites/cell surface vs. 140,000 in the untreated cell, with no change in receptor affinity. Amiloride thus stabilized the surface EGF receptor pool at an elevated level. In cells pretreated with amiloride for 60 min, the relative endocytosis decreased from about 2.6 EGF molecules internalized per receptor during 15 min endocytosis in untreated cells to about 1.5 molecules/receptor in amiloride-treated cells. These results suggest that amiloride causes an accumulation of EGF receptors at the hepatocyte surface due to inhibition of constitutive receptor internalization. In addition, it was found that in amiloride-treated hepatocytes the phorbol ester TPA strongly inhibited high-affinity EGF binding without affecting the total surface receptor number. In control cells, TPA did not consistently affect binding. Pretreatment with amiloride prevented surface EGF receptor depletion induced by cycloheximide and puromycin, but it did not significantly inhibit surface receptor depletion caused by monensin. Although the underlying mechanism of the amiloride effect on intracellular receptor trafficking is not clear, the results provide further evidence for a continuous, ligand-independent EGF receptor cycling pathway in hepatocytes.     

Internalization rates of murine and ovine gonadotropin-releasing hormone receptors

Rates of internalization of the murine GnRH receptor fused via its C-terminus to green fluorescent protein (GnRH-R-GFP) were examined in Chinese hamster ovary cells (CHO cells) and compared to those of native murine GnRH-R in a clonal murine gonadotroph cell line (LbetaT2 cells). The resulting rates of internalization of murine receptors were then compared with those of sheep GnRH-R in ovine gonadotrophs. Cells were incubated with radioiodinated [D-Ala6]GnRH on ice for 4 h to allow binding of the ligand to GnRH-R, then cells were warmed to 37 degrees C to permit internalization. Surface-bound radioligand began to decrease as soon as the cells were warmed and had decreased significantly within 20 min. A steady-state level of surface-bound radioligand was achieved after 60 min in both CHO cells and LbetaT2 cells (38% and 41%, respectively, of initial value; P < 0.05). Internalization of radioligand began immediately after warming the cells to 37 degrees C, and a significant proportion of surface ligand had been internalized by 20 min. A steady-state maximum of internalization was reached after 60 min in both CHO cells and LbetaT2 cells (29% and 28%, respectively, of total cell-associated ligand; P < 0.05). Changes in surface-bound radioligand and internalized radioligand in sheep pituitary cells were similar to those in CHO cells and LbetaT2 cells, but the amount of radioligand internalized after 60 min (40% of total cell-associated ligand) was 1.4 times higher than in CHO cells and LbetaT2 cells (P < 0.05). In a separate experiment, the effect of estradiol on the rate of internalization of GnRH-R in ovine pituitary cells was examined. Although treatment of ovine pituitary cells with estradiol approximately doubled the number of GnRH receptors, it did not alter either the rate or extent of receptor internalization. These results show that rates of internalization of recombinant murine GnRH-R-GFP in CHO cells and native murine and ovine GnRH-R in LbetaT2 cells and in sheep pituitary cells, respectively, are similar, but amounts of ovine GnRH-R internalized are greater than those for murine GnRH-R. Further, the rate of internalization of occupied receptor is similar in gonadotroph and nongonadotroph cells, and the addition of GFP to the C-terminus of the murine GnRH-R does not alter the rate of internalization.     

Kinetics of insulin receptor internalization and recycling in adipocytes. Shunting of receptors to a degradative pathway by inhibitors of recycling

The kinetics of receptor internalization and recycling was directly determined in adipocytes by measuring 125I-insulin binding to total, intracellular, and cell-surface insulin receptors. In the absence of insulin 90% of all receptors were on the cell-surface and 10% were intracellular. Insulin (100 ng/ml) rapidly altered this distribution by translocating surface receptors to the cell-interior through a temperature and energy dependent process. Surface-derived receptors were seen within cells as early as 30 s and accumulated intracellularly at the rate of approximately 20,000/min (t 1/2 = 2.7 min). After 6 min the size of the intracellular receptor pool plateaued (for up to 2 h), with 30% of surface receptors residing within the cell. This plateau was due to the attainment of an equilibrium between receptor uptake and recycling, since removal of insulin (to stop receptor uptake) was followed by both a rapid depletion of intracellular receptors and a a concomitant and stoichiometric reappearance of receptors on the cell-surface. Receptors were efficiently recycled, with little or no net loss observed even after 4 h of insulin treatment; however, recycling could be partially inhibited (approximately 10%) by several agents (e.g. chloroquine and Tris). Tris treatment of adipocytes in the presence of insulin led to 50% loss of surface and total receptors at 2 and 4 h, respectively. Since chloroquine prevented the decrease in total receptors, but not the loss of surface receptors, it appears that Tris impairs recycling by diverting a portion of incoming receptors to a chloroquine-inhibitable degradative site. From these results we conclude that: 1) insulin triggers endocytotic uptake of insulin-receptor complexes; 2) internalized receptors are then rapidly reinserted into the plasma membrane, and the receptors can traverse this recycling pathway within 6 min; 3) prolonged recycling does not normally result in measurable receptor loss, but when receptors are prevented from recycling, they become trapped intracellularly and are shunted to a chloroquine-sensitive degradative pathway; and 4) chloroquine and Tris are only partially effective inhibitors of receptor recycling.     

Glucagon receptor recycling: role of carboxyl terminus, beta-arrestins, and cytoskeleton

Glucagon receptor (GR) activity and expression are altered in several diseases, including Type 2 diabetes. Previously, we investigated the mechanism of GR desensitization and internalization. The present study focused on the fate of internalized GR. Using both hamster hepatocytes and human embryonic kidney (HEK)-293 cells, we showed that internalized GR recycled to the plasma membrane within 30-60 min following stimulation of the cells with 100 nM glucagon. In HEK-293 cells and during recycling, GR colocalized with Rab4, Rab11, beta-arrestin1, beta-arrestin2, and actin filaments, in the cytosolic and/or perinuclear domains. Glucagon treatment triggered redistribution of actin filaments from the plasma membrane to the cytosol. GR coimmunoprecipitated with beta-actin in both hepatocytes and HEK-293 cells. Downregulation of beta-arrestin1 and beta-arrestin2 or disruption of the cytoskeleton inhibited recycling, but not internalization of GR. Deletion of the GR carboxyl-terminal 70 amino acids abolished internalization of GR in response to glucagon while deletion of the last 40 amino acids only did not affect GR internalization and recycling. After exposure of the cells to either high concentrations or prolonged duration of glucagon, GR colocalized with lysosomes. GR degradation was inhibited by lysosomal, but not proteosomal, inhibitors. In conclusion, GR recycles through Rab4- and Rab11- positive vesicles. The actin cytoskeleton, beta-arrestin1, beta-arrestin2, and the receptor's carboxyl terminus are involved in recycling. Prolonged stimulation with glucagon targets GR for degradation in lysosomes. Therefore, the present study provides a better understanding of the GR recycling mechanism, which could become useful in the treatment of certain diseases, including diabetes.     

Association of 125I-nerve growth factor with PC12 pheochromocytoma cells. Evidence for internalization via high-affinity receptors only and for long-term regulation by nerve growth factor of both high- and low-affinity receptors

Association of 125I-nerve growth factor (NGF) with PC12 pheochromocytoma cells was studied. Surface-bound and internalized NGF were distinguished by differential release of the former at low pH, high salt. Binding to the surface was rapid; at 0.2 nM (5 ng/ml) 125I-NGF, this was near-maximal within 5 min. Internalization, in contrast, did not start until about 2 min after NGF exposure and, thereafter, proceeded linearly for at least 1/2-1 h. By the latter time, approximately 75% of total bound NGF was within rather than on the surface of the cells. Binding versus concentration experiments indicated two distinct classes of surface binding sites. For both naive cells and cells treated with NGF for at least a week (primed cells), about 7% of the receptors had an apparent binding constant of about 0.3 nM; the remaining sites half-saturated at approximately 4 nM NGF. The number of each type of site was 3--4-fold higher/mg of protein in primed cells. For both naive and primed cultures, internalization appeared to be mediated by a single class of uptake sites which half-saturated at about 0.3 nM. The maximal rate of uptake by primed cells (200 fmol/h/mg protein) was about twice that for naive cells. Light and electron microscopic autoradiography indicated that the density of binding was substantially higher in primed cultures and that this increase took place over a time course of days to weeks. These findings suggest that NGF brings about long-term increases in its own high- and low-affinity surface receptors, but is internalized only via the high-affinity sites.     

Rapid constitutive internalization and externalization of epidermal growth factor receptors in isolated rat hepatocytes. Monensin inhibits receptor externalization and reduces the capacity for continued endocytosis of epidermal growth factor

It was previously demonstrated that freshly isolated rat hepatocytes can internalize severalfold more epidermal growth factor (EGF) molecules than the number of surface EGF receptors, suggesting extensive reutilization of receptors during endocytosis (Gladhaug, I. P. & Christoffersen, T. (1987) Eur. J. Biochem. 164, 267-275). The present report attempts to explore the pathways involved in the externalization of EGF receptors. Incubation of hepatocytes at 37 degrees C in the absence of ligand increased the surface receptor pool by 50-100% within 45 min. Pretreatment with monensin inhibited the turnover of the surface EGF receptor pool by 50-60% within 10 min and blocked the temperature-dependent externalization of receptors. Cycloheximide caused a slower attenuation of the surface receptor pool, whereas tunicamycin and chloroquine did not significantly affect the exchange of receptor pools. Monensin reduced the surface receptor pool and the endocytic uptake in corresponding proportions, without affecting the internalization of prebound EGF. Endocytic uptake was unaffected by chloroquine and slightly reduced by cycloheximide. The internalization of unoccupied receptors and the endocytosis of prebound EGF followed similar kinetics (t1/2 approximately 5 min), suggesting that unoccupied receptors are internalized at a rate comparable to that of occupied receptors. The results suggest that there is a rapid turnover of the surface pool of EGF receptors with constitutive internalization of unoccupied surface receptors and externalization of internal receptors. This is consistent with, but does not prove, a true recycling of the EGF receptors in the hepatocytes. The monensin-sensitive externalization pathway determines the capacity for continued endocytosis of EGF.     

Receptor-mediated endocytosis of epidermal growth factor by hepatocytes in the perfused rat liver: ligand and receptor dynamics

We have used biochemical and morphological techniques to demonstrate that hepatocytes in the perfused liver bind, internalize, and degrade substantial amounts of murine epidermal growth factor (EGF) via a receptor-mediated process. Before ligand exposure, about 300,000 high-affinity receptors were detectable per cell, displayed no latency, and co-distributed with conventional plasma membrane markers. Cytochemical localization using EGF coupled to horseradish peroxidase (EGF-HRP) revealed that the receptors were distributed along the entire sinusoidal and lateral surfaces of hepatocytes. When saturating concentrations of EGF were perfused through a liver at 35 degrees C, ligand clearance was biphasic with a rapid primary phase of 20,000 molecules/min per cell that dramatically changed at 15-20 min to a slower secondary phase of 2,500 molecules/min per cell. During the primary phase of uptake, approximately 250,000 molecules of EGF and 80% of the total functional receptors were internalized into endocytic vesicles which could be separated from enzyme markers for plasma membranes and lysosomes on sucrose gradients. The ligand pathway was visualized cytochemically 2-25 min after EGF-HRP internalization and a rapid transport from endosomes at the periphery to those in the Golgi apparatus-lysosome region was observed (t 1/2 approximately equal to 7 min). However, no 125I-EGF degradation was detected for at least 20 min. Within 30 min after EGF addition, a steady state was reached which lasted up to 4 h such that (a) the rate of EGF clearance equaled the rate of ligand degradation (2,500 molecules/min per cell); (b) a constant pool of undegraded ligand was maintained in endosomes; and (c) the number of accessible (i.e., cell surface) receptors remained constant at 20% of initial values. By 4 h hepatocytes had internalized and degraded 3 and 2.3 times more EGF, respectively, than the initial number of available receptors, even in the presence of cycloheximide and without substantial loss of receptors. All of these results suggest that EGF receptors are internalized and that their rate of recycling to the surface from intracellular sites is governed by the rate of entry of ligand and/or receptor into lysosomes.     

Equilibrium model for insulin-induced receptor down-regulation. Regulation of insulin receptors in differentiated BC3H-1 myocytes

The mechanism of insulin-induced down-regulation of surface membrane insulin receptors was studied in the muscle cell line BC3H-1. Down-regulation for the differentiated myocytes is dose- and time-dependent with a half-maximum response at 0.5 nM insulin and a maximum decrease of 50% in the number of surface insulin receptors following exposure to 20 nM insulin for 18 h at 37 degrees C, as confirmed by Scatchard analysis. These receptors were fully recoverable upon lysis of the down-regulated myocyte with Triton X-100, demonstrating that down-regulation is mediated solely by insulin-induced receptor internalization without detectable receptor degradation. Phospholipase C treatment of intact down-regulated cells and Triton X-100 treatment after subcellular fractionation showed that no cryptic or masked receptors were detectable within the plasma membrane. Insulin-induced receptor internalization was dependent upon cellular energy production, protein synthesis, and endocytosis, but was insensitive to agents which primarily affect lysosomal, cytoskeletal, or transglutaminase activities. The magnitude of insulin-induced down-regulation and the kinetics of down-regulation and recovery of cell surface receptors indicate that the surface and internal receptor pools are in dynamic equilibrium with each other. The kinetic data are accommodated by separate internalization rate constants for the unoccupied (0.01 h-1) and occupied (0.11 h-1) surface receptors and a single recycling rate constant (0.11 h-1) for the internalized receptors. This model also explains the previous apparently paradoxical finding in several other systems that down-regulation is more sensitive to hormone than hormone-receptor binding under physiologic conditions. Down-regulation in BC3H-1 myocytes, therefore, appears to be mediated solely by an insulin-induced increase in the receptor internalization rate constant and a consequent shift in the dynamic equilibrium between the surface and internalized receptor pools, resulting in a 50% decrease in the number of cell surface receptors. In other systems where the internalized hormone receptor is a substrate for rapid degradation, the essential role of this shift in mediating the down-regulation process may be obscured.     

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.     

Uptake and transport of glucagon by rat liver: evidence for transcytotic pathway

Summary The binding of¹²⁵I-glucagon to the cell surface and the pathway of intracellular transport of this hormone by rat hepatocytes in vivo were studied by light and EM autoradiography. Radiolabeled glucagon injected into the blood stream was taken up predominantly by the hepatocytes. Negligible radioactivity was found to be associated with other cell types such as endothelial or Kupffer cells. Our results indicate that at early time points after injection glucagon has been preferentially interacting with the sinusoidal domain of the hepatocytes and found to be associated with coated pits and uncoated vesicles corresponding to endosomes. At 15–20 min time intervals glucagon grains were found within hepatocyte interior. Later, at 30 min after injection glucagon grains accumulate in the Golgi-lysosomal region of hepatocyte often in close proximity to the opening of the bile canaliculi. Accordingly a portion of internalized¹²⁵I-glucagon was found to be released into the bile thereby indicating that a transcytotic pathway may be involved in this peptide's clearance process.     

The influence of transferrin binding to L2C guinea pig leukemic lymphocytes on the endocytosis cycle kinetics of its receptor

The parameters regulating the internalization and recycling of transferrin-specific receptors were determined in guinea pig leukemic B lymphocytes, in the absence or presence of ligand. We show that after the cells were purified, 45-56% of the total receptors were on the cell surface. In the absence of transferrin, unoccupied receptors are quickly internalized (rate constant, 0.12 min-1) whereas their recycling is much slower (rate constant, 0.026 min-1). This difference between endocytosis and recycling rates leads to a balanced receptor distribution with only 22% of the total receptors outside after incubation of the cells for 20-30 min at 37 degrees C. The internalization rate of occupied receptors, measured in the presence of transferrin is faster (rate constant, 0.21 min-1) than that of unoccupied receptors calculated in the absence of transferrin (0.12 min-1; see above). On the other hand, mere binding of transferrin to its receptor, without internalization, arrested by cytoplasm acidification, is sufficient to induce a large increase (by a factor of seven) in the recycling rate of unoccupied internal receptors from 0.026 min-1 to 0.17 min-1. Thus, in these lymphocytes, transferrin mobilizes internal receptors by modifying the kinetic rates of internalization and recycling, leading to a new equilibrium between external and internal receptors.     

Subcellular trafficking of guanylyl cyclase/natriuretic peptide receptor-A with concurrent generation of intracellular cGMP

Atrial natriuretic peptide (ANP) activates guanylyl cyclase/natriuretic peptide receptor-A (GC-A/NPRA), which lowers blood pressure and blood volume. The objective of the present study was to visualize internalization and trafficking of enhanced GFP (eGFP)-tagged NPRA (eGFP–NPRA) in human embryonic kidney-293 (HEK-293) cells, using immunofluorescence (IF) and co-immunoprecipitation (co-IP) of eGFP–NPRA. Treatment of cells with ANP initiated rapid internalization and co-localization of the receptor with early endosome antigen-1 (EEA-1), which was highest at 5 min and gradually decreased within 30 min. Similarly, co-localization of the receptor was observed with lysosome-associated membrane protein-1 (LAMP-1); however, after treatment with lysosomotropic agents, intracellular accumulation of the receptor gradually increased within 30 min. Co-IP assays confirmed that the localization of internalized receptors occurred with subcellular organelles during the endocytosis of NPRA. Rab 11, which was used as a recycling endosome (Re) marker, indicated that ∼20% of receptors recycled back to the plasma membrane. ANP-treated cells showed a marked increase in the IF of cGMP, whereas receptor was still trafficking into the intracellular compartments. Thus, after ligand binding, NPRA is rapidly internalized and trafficked from the cell surface into endosomes, Res and lysosomes, with concurrent generation of intracellular cGMP.