Independent regulation of human neutrophil chemotactic receptors after activation

The fluoresceinated chemotactic factors, C5a, formyl-methionyl-leucyl-phenylalanyl-lysine (FMLPL), and casein were used in conjunction with flow cytometry to examine chemotactic factor receptor expression on polymorphonuclear leukocytes (PMN) activated with phorbol myristate acetate (PMA), C5a, or formyl-methionyl-leucyl-phenylalanine. Activation with PMA resulted in a dose-dependent increase in binding of fluorescein-labeled (FL)-casein and (FL-FMLPL) over the range of PMA concentrations from 0.5 to 50 ng/ml. In contrast, activation of PMN with PMA resulted in a dose-dependent decrease in FL-C5a binding, and activation with concentrations above 5 ng/ml resulted in a complete loss of binding. This loss of binding was not caused by inactivation of the ligand or prevented by the addition of superoxide dismutase and catalase or protease inhibitors. Furthermore, incubation of PMN with supernatants from PMN stimulated to degranulate did not reduce the availability of C5a receptors. This pattern of increased FMLPL and casein binding with decreased C5a binding was also observed with cytochalasin B-pretreated PMN that were stimulated with chemotactic factors. Parallel studies of superoxide anion generation demonstrated that PMA-treated PMN were still responsive to formyl-methionyl-leucyl-phenylalanine, but not to C5a. These data demonstrate that the activation of PMN up-regulates formyl peptide and casein receptors whereas C5a receptors are down-regulated under similar conditions.     

Removal of human polymorphonuclear leukocyte surface sialic acid inhibits reexpression (or recycling) of formyl peptide receptors. A possible explanation for its effect on formyl peptide-induced polymorphonuclear leukocyte chemotaxis

Removal of surface sialic acid specifically inhibits human polymorphonuclear leukocyte (PMN) chemotactic responses to N-formyl-methionyl-leucyl-phenylalanine (FMLP). Neuraminidase-treated (NT)-PMN bound and internalized [3H]FMLP (used as receptor marker) as well as normal PMN. NT-PMN, however, retained more [3H]FMLP-associated radioactivity than normal PMN. Subcellular fractionation studies demonstrated that NT-PMN retained more sedimentable (100,000 X G for 180 min) [3H]FMLP-associated radioactivity within light Golgi-containing fractions than normal PMN. Furthermore, NT-PMN exhibited a defect in their ability to reexpress (or recycle) a population of FMLP receptors. Abnormal receptor recycling was associated with inhibition of FMLP-induced PMN chemotaxis. Thus, it appears that recycling of formyl peptide receptors may be necessary for optimal PMN chemotactic responses to FMLP. We postulate that removal of PMN surface sialic acid inhibits FMLP-induced PMN chemotaxis by blocking the reexpression (or recycling) of a population of formyl peptide receptors, perhaps by preventing trafficking of desialated receptors through a light Golgi pathway.     

Polymorphonuclear leukocytes cap a derivative of wheat germ agglutinin upon stimulation with formyl peptide and C5a but not leukotriene B4

Previously, we reported that a derivative of wheat germ agglutinin (termed WGA-D) specifically inhibits human polymorphonuclear leukocyte (PMN) chemotaxis to FMLP by blocking reexpression (or recycling) of formyl peptide receptors. WGA-D (? formyl peptide receptor probe) binds to a protein on the PMN membrane that exhibits the same m.w. as the formyl peptide receptor. Since clustering (i.e., capping) of ligand-receptor complexes most likely precedes their internalization, we examined the ability of normal and stimulated PMN to cap fluoresceinated WGA-D. We found that, in contrast to capping of fluoresceinated Con A, PMN cap WGA-D in a chemotactic factor-specific fashion. Fluoresceinated WGA-D (5.0 to 20 micrograms/ml) alone did not induce either PMN shape changes (i.e., activation) or capping. Both FMLP (1 to 1000 nM) and human C5a (0.1 to 1.0 nM) induced PMN to polarize and to cap bound WGA-D, in a concentration-dependent fashion. Interestingly, leukotriene B4 (LTB4) (5.0 nM), while inducing the same degree of PMN polarization as FMLP (100 nM) and C5a (0.5 nM), failed to induce PMN to cap bound WGA-D. In contrast, FMLP (100 nM), C5a (0.5 nM), and LTB4 (5.0 nM) induced PMN to cap bound fluoresceinated Con A (10 micrograms/ml) to the same extent. The effect of suboptimal concentrations of FMLP and C5a on capping of WGA-D by PMN was additive. LTB4 did not enhance either FMLP or C5a-induced capping of WGA-D by PMN. Also, FMLP and C5a (but not LTB4) were capable of inducing both desensitization and cross-desensitization of WGA-D capping by PMN. Studies using rhodamine-labeled WGA-D and a fluoresceinated analog of FMLP revealed that both capped to the same place on the PMN membrane. Thus, the data suggest that WGA-D binds to a site on the PMN membrane that is either the FMLP receptor or very closely associated with it.     

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.     

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.     

Cloned neuropeptide Y (NPY) Y1 and pancreatic polypeptide Y4 receptors expressed in Chinese hamster ovary cells show considerable agonist-driven internalization, in contrast to the NPY Y2 receptor.

Guinea-pig neuropeptide Y1 and rat pancreatic polypeptide Y4 receptors expressed in Chinese hamster ovary cells were internalized rapidly upon attachment of selective peptide agonists. The Y1 and Y2, but not the Y4, receptor also internalized the nonselective neuropeptide Y receptor agonist, human/rat neuropeptide Y. The internalization of guinea-pig neuropeptide Y2 receptor expressed in Chinese hamster ovary cells was small at 37 degrees C, and essentially absent at or below 15 degrees C, possibly in connection to the large molecular size of the receptor-ligand complexes (up to 400 kDa for the internalized fraction). The rate of intake was strongly temperature dependent, with essentially no internalization at 6 degrees C for any receptor. Internalized receptors were largely associated with light, endosome-like particulates. Sucrose dose-dependently decreased the internalization rate for all receptors, while affecting ligand attachment to cell membrane sites much less. Internalization of the Y1 and the Y4 receptors could be blocked, and that of the Y2 receptor significantly inhibited, by phenylarsine oxide, which also unmasked spare cell-surface receptors especially abundant for the Y2 subtype. The restoration of Y1 and Y4 receptors after agonist peptide pretreatment was decreased significantly by cycloheximide and monensin. Thus, in Chinese hamster ovary cells the Y1 and Y4 receptors have much larger subcellular dynamics than the Y2 receptor. This differential could also hold in organismic systems, and is comparable with the known differences in internalization of angiotensin, bradykinin, somatostatin and opioid receptor subtypes.     

Monensin inhibits recycling of macrophage mannose-glycoprotein receptors and ligand delivery to lysosomes.

Binding studies with cells that had been permeabilized with saponin indicate that alveolar macrophages have an intracellular pool of mannose-specific binding sites which is about 4-fold greater than the cell surface pool. Monensin, a carboxylic ionophore which mediates proton movement across membranes, has no effect on binding of ligand to macrophages but blocks receptor-mediated uptake of 125I-labelled beta-glucuronidase. Inhibition of uptake was concentration- and time-dependent. Internalization of receptor-bound ligand, after warming to 37 degrees C, was unaffected by monensin. Moreover, internalization of ligand in the presence of monensin resulted in an intracellular accumulation of receptor-ligand complexes. The monensin effect was not dependent on the presence of ligand, since incubation of macrophages with monensin at 37 degrees C without ligand resulted in a substantial decrease in cell-surface binding activity. However, total binding activity, measured in the presence of saponin, was much less affected by monensin treatment. Removal of monensin followed by a brief incubation at pH 6.0 and 37 degrees C, restored both cell-surface binding and uptake activity. Fractionation experiments indicate that ligands enter a low-density (endosomal) fraction within the first few minutes of uptake, and within 20 min transfer to the lysosomal fraction has occurred. Monensin blocks the transfer from endosomal to lysosomal fraction. Lysosomal pH, as measured by the fluorescein-dextran method, was increased by monensin in the same concentration range that blocked ligand uptake. The results indicate that monensin blockade of receptor-mediated endocytosis of mannose-terminated ligands by macrophages is due to entrapment of receptor-ligand complexes and probably receptors in the pre-lysosomal compartment. The inhibition is linked with an increase in the pH of acid intracellular vesicles.     

Internalization of Ia molecules by antigen-presenting B cells is limited

Our data demonstrate that the uptake of surface Ia into an intracellular compartment of B lymphoma or normal spleen cells is limited to about 20% after 2 to 3 h. The extent of internalization does not vary with several types of stimulation, including LPS, phorbol esters, anti-Ig-plus phorbol ester-stimulated EL-4 T cell supernatant, and Con A supernatant. Resting and activated B cells had similar rates of internalization. The rate and extent of uptake of surface Ia molecules into an intracellular compartment was monitored quantitatively through the use of a mAb radiolabeled with 125I. The internalization of Ia molecules was compared to that of transferrin receptor, a receptor that undergoes rapid internalization and recycling and accumulates in a intracellular pool that can be trapped by monensin. The internalization of Ia was not affected by monensin, although its synthetic pathway is disturbed by this drug. The potential use of internalized Ia for formation of T cell-triggering complexes of Ia and Ag fragments is not ruled out by these data, but it appears unlikely that internalization provides the major mechanism permitting Ia interaction with Ag.     

The interaction of small oligomers of complement 3B (C3B) with phagocytes. High affinity binding and phorbol ester-induced internalization by polymorphonuclear leukocytes

The binding of soluble, multimeric ligands of the major cleavage fragment of complement component 3 (C3b) to polymorphonuclear leukocytes (PMN) has been examined. The oligomers bound entirely via complement C3 receptor type 1 (CR1). There was a single affinity of binding (0.65 nM) at 37 degrees C, while this high affinity binding accounted for only a minority of ligand bound at 0 degree C, with the rest showing a 50-100-fold lower affinity. Azide, fluoride, cytochalasin B, and colchicine had no effect on oligomer binding to PMN. Binding of oligomers had no effect on CR1 expression by PMN. C3b oligomers were not spontaneously internalized by PMN, but were internalized in response to phorbol dibutyrate (PDBu). Both CR1 initially present on the PMN plasma membrane and CR1 initially present in the internal pool of receptors were able to participate in PDBu-induced ligand internalization. C3b oligomers attached to the detergent-insoluble cell cytoskeleton during incubation at 37 degrees C, but cytochalasin B did not inhibit PDBu-induced ligand internalization. Internalized ligand was no longer associated with the detergent-insoluble cytoskeleton. These data demonstrate that 1) some CR1 diffusion is required for optimal oligomer binding; 2) high affinity ligand is not a signal for plasma membrane expression of the internal pool of CR1; 3) CR1 cross-linking is not a sufficient signal for endocytosis; and 4) functional CR1 association with the cytoskeleton which occurs at the plasma membrane is not required for ligand internalization.     

Internalization of transforming growth factor-beta and its receptor in BALB/c 3T3 fibroblasts

The fate of 125I-labeled transforming growth factor-beta (125I-TGF beta) after binding to its cells surface receptor has been investigated in BALB/c 3T3 mouse fibroblasts. Binding of 125I-TGF beta to cellular receptors at 4 degrees C is pH-sensitive, being markedly decreased at pH less than 6. Most (approximately 90%) of the 125I-TGF beta bound to cells at 4 degrees C can be removed by a brief treatment with acidic medium but is converted into an acid-resistant state rapidly after shifting the cells to 37 degrees C. Cell-bound 125I-TGF beta is degraded at 37 degrees C and the degradation products are released into the medium. The lysosomotropic bases chloroquine, methylamine, and ammonium and the carboxylic ionophore monensin inhibit the degradation and release of 125I-TGF beta from the cells. Cells allowed to accumulate 125I-TGF beta intracellularly by the action of chloroquine or monensin were treated with the bifunctional agent disuccinimidyl suberate in the presence of detergent Triton X-100; this treatment caused the cross-linking of internalized 125I-TGF beta with the 280-kilodalton TGF beta receptor component. Under conditions in which sustained binding and degradation of saturating 125I-TGF beta concentrations occurs, there is no marked decrease in the binding capacity of the cells even when protein synthesis is blocked with cycloheximide. These results indicate that after TGF beta binding the TGF beta:receptor complex becomes rapidly internalized and that TGF beta is directed towards lysosomes where it is degraded and released. However, the cell surface is replenished with TGF beta receptors recycled after internalization or supplied by a large intracellular pool.     

Contribution of the carboxyl terminus of the VPAC1 receptor to agonist-induced receptor phosphorylation, internalization, and recycling

When exposed to vasoactive intestinal peptide (VIP), the human wild type VPAC1 receptor expressed in Chinese hamster ovary (CHO) cells is rapidly phosphorylated, desensitized, and internalized in the endosomal compartment and is not re-expressed at the cell membrane within 2 h after agonist removal. The aims of the present work were first to correlate receptor phosphorylation level to internalization and recycling, measured by flow cytometry and in some cases by confocal microscopy using a monoclonal antibody that did not interfere with ligand binding, and second to identify the phosphorylated Ser/Thr residues. Combining receptor mutations and truncations allowed identification of Ser250 (in the second intracellular loop), Thr429, Ser435, Ser448 or Ser449, and Ser455 (all in the distal part of the C terminus) as candidates for VIP-stimulated phosphorylation. The effects of single mutations were not additive, suggesting alternative phosphorylation sites in mutated receptors. Replacement of all of the Ser/Thr residues in the carboxyl-terminal tail and truncation of the domain containing these residues completely inhibited VIP-stimulated phosphorylation and receptor internalization. There was, however, no direct correlation between receptor phosphorylation and internalization; in some truncated and mutated receptors, a 70% reduction in phosphorylation had little effect on internalization. In contrast to results obtained on the wild type and all of the mutated or truncated receptors that still underwent phosphorylation, internalization of the severely truncated receptor was reversed within 2 h of incubation in the absence of the agonist. Receptor recovery was blocked by monensin, an endosome inhibitor.     

Kinase activity controls the sorting of the epidermal growth factor receptor within the multivesicular body

We compared the internalization and intracellular sorting of epidermal growth factor receptor (EGF-R) and point mutant kinase-negative EGF-R separately expressed in NIH 3T3 cells lacking endogenous receptor. Both EGF-Rs internalized rapidly, but kinase-negative receptor was surface down-regulated only with monensin or at 20 degrees C. Furthermore, EGF internalized by mutant receptor alone was, in significant proportion, returned to the cell surface undegraded. Hence unlike wild-type receptor, kinase-negative EGF-R recycles. By electron microscopy the early pathways of endocytosis for the two receptors were identical; however, after 10-20 min the pathways diverged at the multivesicular body (MVB). Wild-type EGF-R, destined for degradation, localized to internal vesicles, while kinase-negative EGF-R, destined for recycling, localized to surface membranes of the MVBs and moved to small tubulovesicles. We conclude that sorting of internalized receptor for degradation or recycling can occur through spatial segregation within the MVB, and sorting of EGF-R is controlled by tyrosine kinase activity.     

Internalization of the fibronectin receptor is a constitutive process

Using a monoclonal antibody specific for the hamster fibronectin receptor (FnR), we have demonstrated that a portion of the CHO cell FnR population is constitutively endocytosed. Three independent techniques were used to study the internalization: 1) after saturation binding of an anti-FnR antibody (PB1) to cells at 4 degrees C, internalization was initiated by warming to 37 degrees C, and then acid/salt elution of membrane-bound ligand was used to quantitate the internalized 125I-PB1; 2) cell vesicular traffic was pharmacologically disrupted with monensin or chloroquine, and the subsequent reduction of the cell surface pool of FnR was monitored; and 3) selective immunoprecipitation was used to separate surface and internalized 125I-labeled FnR. These experiments indicate that about 30% of the cell surface FnR is endocytosed with a t1/2 of 7 min and that this internalization occurs regardless of the ligation state of the receptor. Other observations indicate that the larger fraction of the cell surface FnR pool (70-75%) is apparently shed from the cell upon ligation with antibody at 37 degrees C. This process occurs much more slowly than receptor internalization and leads to an overall reduction in the amount of cell surface FnR. Our results suggest physically or chemically distinct populations of FnR, one of which is unavailable for internalization and recycling.     

Agonist-dependent AT(4) receptor internalization in bovine aortic endothelial cells

Recent studies have characterized a specific binding site for the C-terminal 3-8 fragment of angiotensin II (Ang IV). In the present study we looked at the internalization process of this receptor on bovine aortic endothelial cells (BAEC). Under normal culture conditions, BAEC efficiently internalized (125)I-Ang IV as assessed by acid-resistant binding. Internalization of (125)I-Ang IV was considerably decreased after pretreatment of cells with hyperosmolar sucrose or after pretreatment of BAEC with inhibitors of endosomal acidification such as monensin or NH(4)Cl. About 50% of internalized (125)I-Ang IV recycled back to the extracellular medium during a 2 h incubation at 37 degrees C. (125)I-Ang IV remained mostly intact during the whole process of internalization and recycling as assessed by thin layer chromatography. As expected, internalization of (125)I-Ang IV was completely abolished by divalinal-Ang IV, a known AT(4) receptor antagonist. Interestingly, (125)I-divalinal-Ang IV did not internalize into BAEC. These results suggest that AT(4) receptor undergoes an agonist-dependent internalization and recycling process commonly observed upon activation of functional receptors.     

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.     

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.     

The dynamin-dependent, arrestin-independent internalization of 5-hydroxytryptamine 2A (5-HT2A) serotonin receptors reveals differential sorting of arrestins and 5-HT2A receptors during endocytosis

5-Hydroxytryptamine 2A (5-HT2A) receptors, a major site of action of clozapine and other atypical antipsychotic medications, are, paradoxically, internalized in vitro and in vivo by antagonists and agonists. The mechanisms responsible for this paradoxical regulation of 5-HT2A receptors are unknown. In this study, the arrestin and dynamin dependences of agonist- and antagonist-mediated internalization were investigated in live cells using green fluorescent protein (GFP)-tagged 5-HT2A receptors (SR2-GFP). Preliminary experiments indicated that GFP tagging of 5-HT2A receptors had no effect on either the binding affinities of several ligands or agonist efficacy. Likewise, both the native receptor and SR2-GFP were internalized via endosomes in vitro. Experiments with a dynamin dominant-negative mutant (dynamin K44A) demonstrated that both agonist- and antagonist-induced internalization were dynamin-dependent. By contrast, both the agonist- and antagonist-induced internalization of SR2-GFP were insensitive to three different arrestin (Arr) dominant-negative mutants (Arr-2 V53D, Arr-2-(319-418), and Arr-3-(284-409)). Interestingly, 5-HT2A receptor activation by agonists, but not antagonists, induced greater Arr-3 than Arr-2 translocation to the plasma membrane. Importantly, the agonist-induced internalization of 5-HT2A receptors was accompanied by differential sorting of Arr-2, Arr-3, and 5-HT2A receptors into distinct plasma membrane and intracellular compartments. The agonist-induced redistribution of Arr-2 and Arr-3 into intracellular vesicles and plasma membrane compartments distinct from those involved in 5-HT2A receptor internalization implies novel roles for Arr-2 and Arr-3 independent of 5-HT2A receptor internalization and desensitization.     

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.     

Effect of monensin on receptor recycling during continuous endocytosis of asialoorosomucoid

The binding of asialoglycoproteins to their liver cell receptor results in internalization of the ligand-receptor complex. These complexes rapidly appear in intracellular compartments termed endosomes whose acidification results in ligand-receptor dissociation. Ligand and receptor subsequently segregate: ligand is transported to lysosomes and is degraded while receptor recycles to the cell surface. The proton ionophore monensin prevents acidification of endosomes and reversibly inhibits this acid-dependent dissociation of ligand from receptor. The present study determined the effect of monensin treatment of short-term cultured rat hepatocytes on cell-surface-receptor content, determined both by their binding activity and immunologically, following continuous endocytosis of asialoorosomucoid. Inclusion of 5 microM monensin in the incubation medium reduced the number of immunologically detectable cell-surface receptors by 20% in the absence of ligand. During continuous endocytosis of asialoorosomucoid, inclusion of monensin resulted in a 30-40% reduction of cell-surface receptor detectable either by ligand binding or immunologically. These results suggest that the reduced liver-cell-surface content of receptor in monensin is due to intracellular trapping of ligand-receptor complexes. The reduction of surface receptor during monensin incubation in the absence of ligand suggests that "constitutive recycling" of plasma membrane components also requires intracellular acidification.     

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.