Truncation of the porcine calcitonin receptor cytoplasmic tail inhibits internalization and signal transduction but increases receptor affinity

A series of mutant porcine calcitonin receptors with progressively truncated carboxy termini have been expressed in COS and HEK 293 cells. All forms of the receptor, including those totally lacking the cytoplasmic tail, were able to bind 125I-labeled salmon calcitonin. However, removal of C-terminal domains resulted in multiple functional changes in the receptor. First, compared with the wild type receptor, affinity of binding of salmon calcitonin was increased for truncated receptors, whether determined in intact transfected cells or in cell membranes. Second, internalization of the ligand-receptor complex was greatly attenuated for mutants truncated by 44 or 83 amino acids but not for an intermediate form truncated by 63 amino acids. Third, truncation affected signal transduction, which for the porcine calcitonin receptor occurs by generation of intracellular cAMP and Ca2+. The magnitude of adenylate cyclase responses was much reduced for the same mutants defective in internalization. Under conditions where expression of each receptor form was approximately equal, the magnitude of intracellular Ca2+ responses was decreased by C-terminal truncation. These results draw attention to the functional significance of the cytoplasmic tail of the porcine calcitonin receptor and suggest intramolecular interactions between the carboxy terminus and other receptor domains and/or cellular regulatory elements.     

Agonist-induced endocytosis and recycling of the gonadotropin-releasing hormone receptor: effect of beta-arrestin on internalization kinetics

This study examined the dynamics of endocytotic and recycling events associated with the GnRH receptor, a unique G protein-coupled receptor (GPCR) without the intracellular carboxyl-terminal tail, after agonist stimulation, and investigated the role of beta-arrestin in this process. Subcellular location of fluorescently labeled epitope-tagged GnRH receptors stably expressed in HEK 293 cells was monitored by confocal microscopy, and the receptor/ligand internalization process was quantified using radioligand binding and ELISA. Agonist stimulation resulted in reversible receptor redistribution from the plasma membrane into the cytoplasmic compartment, and colocalization of internalized GnRH receptors with transferrin receptors was observed. Internalization experiments for the GnRH receptor and another GPCR possessing a carboxy-terminal tail, the TRH receptor, showed that the rate of internalization for the GnRH receptor was much slower than for the TRH receptor when expressed in both HEK 293 and COS-7 cells. TRH receptor internalization could be substantially increased by coexpression with beta-arrestin in COS-7 cells, while GnRH receptor internalization was not affected by coexpression with beta-arrestin in either cell type. Coexpression of the GnRH receptor with the dominant negative beta-arrestin (319-418) mutant did not affect its ability to internalize, and activated GnRH receptors did not induce time-dependent redistribution of beta-arrestin/green fluorescent protein to the plasma membrane. However, the beta-arrestin mutant impaired the internalization of the TRH receptor, and activated TRH receptors induced the beta-arrestin/green fluorescent protein translocation. This study demonstrates that, despite having no intracellular carboxy-terminal tail, the GnRH receptor undergoes agonist-stimulated internalization displaying distinctive characteristics described for other GPCRs that internalize via a clathrin-dependent mechanism and recycle through an acidified endosomal compartment. However, our data indicate that the GnRH receptor may utilize a beta-arrestin-independent endocytotic pathway.     

The cytoplasmic tails of protease-activated receptor-1 and substance P receptor specify sorting to lysosomes versus recycling

The G protein-coupled receptor (GPCR) for thrombin, protease-activated receptor-1 (PAR1), is activated when thrombin cleaves its amino-terminal exodomain. The irreversibility of this proteolytic mechanism raises the question of how desensitization and resensitization are accomplished for thrombin signaling. PAR1 is phosphorylated, uncoupled from signaling, and internalized after activation like classic GPCRs. However, unlike classic GPCRs, which internalize and recycle, activated PAR1 is sorted to lysosomes. To identify the signals that specify the distinct sorting of PAR1, we constructed chimeras between PAR1 and the substance P receptor. Wild-type substance P receptor internalized and recycled after activation; PAR1 bearing the cytoplasmic tail of the substance P receptor (P/S) behaved similarly. By contrast, wild-type PAR1 and a substance P receptor bearing the cytoplasmic tail of PAR1 (S/P) sorted to lysosomes after activation. Consistent with these observations, PAR1 and the S/P chimera were effectively down-regulated by their respective agonists as assessed by both receptor protein levels and signaling. Substance P receptor and the P/S chimera showed little down-regulation. These data suggest that the cytoplasmic tails of PAR1 and substance P receptor specify their distinct intracellular sorting patterns after activation and internalization. Moreover, by altering the trafficking fates of PAR1 and substance P receptor, one can dictate the efficiency with which a cell maintains responsiveness to PAR1 or substance P receptor agonists over time.     

Agonist-induced sequestration, recycling, and resensitization of platelet-activating factor receptor. Role of cytoplasmic tail phosphorylation in each process

Agonist-induced sequestration, recycling, and resensitization of platelet-activating factor (PAF) receptor were characterized in transfected Chinese hamster ovary cells. Exposure of the cells to PAF led to rapid sequestration of the receptors into the intracellular compartment and desensitization of the response to PAF. The sequestration was inhibited by pretreatments that perturbed the clathrin-mediated pathway. Subsequent removal of PAF by washing with receptor antagonists led to rapid recycling of the sequestered receptors to the cell surface accompanied by resensitization to PAF. To evaluate the potential role of phosphorylation in the receptor cytoplasmic tail during these processes, mutant receptors in which the tails were truncated or substituted, so as to lack serine/threonine residues, were created. PAF phosphorylated the wild-type receptor rapidly and strongly, but the mutants did not. The maximal extent of sequestration of each mutant was lower than that of the wild-type, and one of the substituted mutants showed no sequestration. Furthermore, the sequestration-defective mutant showed evidence of desensitization after agonist stimulation but not resensitization after agonist removal. Thus, agonist-induced phosphorylation of the cytoplasmic tail facilitates but is not essential for receptor sequestration, and sequestration/recycling appears important in receptor resensitization.     

Dissociation of chemotaxis from agonist-induced receptor internalization in a lymphocyte cell line transfected with CCR2B. Evidence that directed migration does not require rapid modulation of signaling at the receptor level

To investigate the role of the carboxyl-terminal region (52 amino acids) of the monocyte chemoattractant protein 1 receptor (CCR2B) in chemotaxis, we created a series of mutants and expressed them in a murine pre-B lymphocyte cell line. Truncation of the cytoplasmic carboxyl tail to 20 amino acids had little or no effect on chemotaxis or signal transduction, but further truncation resulted in marked functional defects. Upon incubation with monocyte chemoattractant protein 1, CCR2B underwent rapid and extensive internalization, and this was impaired progressively as the carboxyl tail was truncated from 52 to 8 amino acids. Mutation of all of the serine and threonine residues in the carboxyl tail to alanine also resulted in markedly impaired receptor internalization but did not affect signaling or chemotaxis. We conclude that the membrane-proximal portion of the cytoplasmic carboxyl tail of CCR2B is critically involved in chemotaxis and signal transduction, but neither phosphorylation of carboxyl serines or threonines nor internalization of the receptor is required for robust chemotaxis.     

Cytoplasmic domain of E-selectin contains a non-tyrosine endocytosis signal

E-selectin is an activation-dependent, endothelial cell-restricted adhesion molecule that is internalized and degraded rapidly once expressed on the cell surface. Tyrosine-containing structural motifs play an important role in the internalization of a number of integral proteins, and the membrane-proximal E-selectin cytoplasmic tyrosine residue (Tyr582) conforms to the endocytosis motif proposed previously. To determine the endocytosis motif in E-selectin, we selectively introduced truncation, substitution, and deletion mutations to the cytoplasmic tail of E-selectin. We analyzed the internalization kinetics of surface-expressed wild-type and mutant E-selectin constructs in transiently transfected Chinese hamster ovary cells using 125I-labeled E-selectin monoclonal antibody (125I-P6E2) in an acid elution assay. Interestingly, truncation immediately membrane proximal to Tyr582 (DeltaDGS construct) did not alter internalization kinetics significantly (DeltaDGS versus wild-type, mean surface half-life = 42 versus 45 min, respectively). Thus, it appears that the tyrosine residues are not required for internalization of E-selectin. Additional analyses indicated that Ser581 was necessary but alone was insufficient for surface E-selectin endocytosis. Thus, we conclude that there exists a novel non-tyrosine-containing endocytosis signal in the cytoplasmic tail which involves Ser581 and residues membrane-proximal to it.     

Phosphorylation of chemoattractant receptors is not essential for chemotaxis or termination of G-protein-mediated responses

In several G-protein-coupled signaling systems, ligand-induced receptor phosphorylation by specific kinases is suggested to lead to desensitization via mechanisms including receptor/G-protein uncoupling, receptor internalization, and receptor down-regulation. We report here that elimination of phosphorylation of a chemoattractant receptor of Dictyostelium, either by site-directed substitution of the serines or by truncation of the C-terminal cytoplasmic domain, completely prevented agonist-induced loss of ligand binding but did not impair the adaptation of several receptor-mediated responses including the activation of adenylyl and guanylyl cyclases and actin polymerization. In addition, the phosphorylation-deficient receptors were capable of mediating chemotaxis, aggregation, and differentiation. We propose that for chemoattractant receptors agonist-induced phosphorylation regulates surface binding activity but other phosphorylation-independent mechanisms mediate response adaptation.     

Gonadotropin-releasing hormone receptors with intracellular carboxyl-terminal tails undergo acute desensitization of total inositol phosphate production and exhibit accelerated internalization kinetics

The mammalian gonadotropin-releasing hormone receptor (GnRH-R) is the only G-protein-coupled receptor (GPCR) in which the intracellular C-terminal tail is completely absent. In contrast to other GPCRs, the GnRH-R does not show rapid desensitization of total inositol (IP) production, and the rates of internalization are exceptionally slow. We investigated whether the incorporation of a cytoplasmic tail into the C terminus of the GnRH-R affects desensitization events and receptor internalization rates. A GnRH-R/TRH-R chimera was created where the intracellular tail of the rat thyrotropin-releasing hormone receptor (TRH-R) was engineered into the C terminus of the rat GnRH-R. Three different rat GnRH-R cDNA stop codon mutations (one for each reading frame) were also made. The GnRH-stimulated IP production of the wild-type rat GnRH-R expressed in either COS-7 or HEK 293 cells did not desensitize even after prolonged stimulation with GnRH. In contrast, the catfish GnRH-R (which does possess an intracellular tail) and the TRH-R rapidly (<10 min) desensitized following agonist stimulation. The GnRH-R/TRH-R chimera also desensitized following treatment with GnRH, resembling the pattern shown by the TRH-R and the catfish GnRH-R. Two of the stop codon mutants did not show desensitization of IP production, and the third mutant with the longest tail was not functional. Internalization experiments showed that the rat GnRH-R had the slowest endocytosis and recycling rates compared with the TRH-R, the catfish GnRH-R, and the chimeric GnRH/TRH-R. This study demonstrates that the addition of a functional intracellular C-terminal tail to the GnRH-R produces rapid desensitization of IP production and significantly increases internalization rates.     

Internalization and homologous desensitization of the GLP-1 receptor depend on phosphorylation of the receptor carboxyl tail at the same three sites

Homologous desensitization and internalization of the GLP-1 receptor correlate with phosphorylation of the receptor in a 33-amino acid segment of the cytoplasmic tail. Here, we identify the sites of phosphorylation as being three serine doublets located at positions 441/442, 444/445, and 451/452. The role of phosphorylation on homologous desensitization was assessed after stable expression in fibroblasts of the wild type or of mutant receptors in which phosphorylation sites were changed in various combinations to alanines. We showed that desensitization, as measured by a decrease in the maximal production of cAMP after a first exposure of the cells to GLP-1, was strictly dependent on phosphorylation. Furthermore, the number of phosphorylation sites correlated with the extent of desensitization with no, intermediate, or maximal desensitization observed in the presence of one, two, or three phosphorylation sites, respectively. Internalization of the receptor-ligand complex was assessed by measuring the rate of internalization of bound [125I]GLP-1 or the redistribution of the receptor to an endosomal compartment after agonist binding. Our data demonstrate that internalization was prevented in the absence of receptor phosphorylation and that intermediate rates of endocytosis were obtained with receptors containing one or two phosphorylation sites. Thus, homologous desensitization and internalization require phosphorylation of the receptor at the same three sites. However, the differential quantitative impairment of these two processes in the single and double mutants suggests different molecular mechanisms controlling desensitization and internalization.     

Subtype-specific intracellular trafficking of alpha2-adrenergic receptors

The three alpha2-adrenergic receptor subtypes (alpha2a, alpha2b, and alpha2c) are highly homologous G protein-coupled receptors. These receptors all couple to pertussis toxin-sensitive G proteins and have relatively similar pharmacological properties. To further explore functional differences between these receptors, we used immunocytochemical techniques to compare the ability of the three alpha2-receptor subtypes to undergo agonist-mediated internalization. The alpha2a-receptor does not internalize after agonist treatment. In contrast, we observed that the alpha2b-receptor is able to undergo agonist-induced internalization and seems to follow the same endosomal pathway used by the beta2-adrenergic receptor. Attempts to examine internalization of the alpha2c-receptor were complicated by the fact that the majority of the alpha2c receptor resides in the endoplasmic reticulum and cis/media Golgi and there is relatively little cell surface localization. Nevertheless, we were able to detect some internalization of the alpha2c-receptor after prolonged agonist treatment. However, we observed no significant movement of alpha2c-receptor from the intracellular pool to the plasma membrane during a 4-hr treatment of cells with cycloheximide, suggesting that these cells are unable to process alpha2c-receptors in the same way they process the alpha2a or alpha2b subtypes.     

A leucine-based determinant in the epidermal growth factor receptor juxtamembrane domain is required for the efficient transport of ligand-receptor complexes to lysosomes

Ligand binding causes the epidermal growth factor (EGF) receptor to undergo accelerated internalization with eventual degradation in lysosomes. The goal of this study was to investigate the molecular basis of endocytic sorting, focussing on post-internalization events. We have identified a sequence located between amino acid residues 675 and 697, encompassing a dileucine motif at residues 679 and 680, that enhances endosome-to-lysosome transport when conformational restraints in the EGF receptor carboxyl terminus are removed by truncation. The same dileucine motif is also necessary for efficient lysosomal transport of ligand-occupied full-length EGF receptors. A L679A,L680A substitution diminished the degradation of occupied full-length EGF receptors without affecting internalization but had a significant effect on recycling. Rapid recycling of mutant receptors resulted in reduced intracellular retention of occupied EGF receptors and delayed down-regulation of cell surface receptors. We propose that the L679A,L680A substitution acts primarily to impair transport of ligand-receptor complexes through an early endosomal compartment, diverting occupied receptors to a recycling compartment at the expense of incorporation into lysosome transport vesicles. We also found that mutant receptors with truncations at the distal half of tyrosine kinase domain (residues 809-957) were not efficiently delivered to the cell surface but were destroyed in an endoplasmic reticulum-associated degradative pathway.     

A determinant in the cytoplasmic tail of the cation-dependent mannose 6-phosphate receptor prevents trafficking to lysosomes

The bovine cation-dependent mannose 6-phosphate receptor (CD-MPR) is a type 1 transmembrane protein that cycles between the trans-Golgi network, endosomes, and the plasma membrane. When the terminal 40 residues were deleted from the 67-amino acid cytoplasmic tail of the CD-MPR, the half-life of the receptor was drastically decreased and the mutant receptor was recovered in lysosomes. Analysis of additional cytoplasmic tail truncation mutants and alanine-scanning mutants implicated amino acids 34-39 as being critical for avoidance of lysosomal degradation. The cytoplasmic tail of the CD-MPR was partially effective in preventing the lysosomal membrane protein Lamp1 from entering lysosomes. Complete exclusion required both the CD-MPR cytoplasmic tail and transmembrane domain. The transmembrane domain alone had just a minor effect on the distribution of Lamp1. These findings indicate that the cytoplasmic tail of the CD-MPR contains a signal that prevents the receptor from trafficking to lysosomes. The transmembrane domain of the CD-MPR also contributes to this function.     

Molecular characterization of the signal responsible for the targeting of the interleukin 2 receptor beta chain toward intracellular degradation

During receptor-mediated endocytosis, most growth factor receptors are transported to late endocytic compartments and degraded. This process is important to control their expression on the cell surface and requires sorting in early endocytic compartments. Little is known about the mechanisms and the signals involved. We have studied the signal involved in targeting the interleukin 2 receptor beta chain (IL2Rbeta), a member of the cytokine receptor superfamily, toward degradation after internalization. We show that a motif of 8 amino acids in the cytosolic tail of IL2Rbeta is sufficient to target a normally recycling receptor toward degradation. Deletion of this signal strongly impairs IL2Rbeta degradation. Further molecular characterization of the motif shows that it does not resemble the well documented tyrosine and dileucine families of trafficking signals.     

Beta-adrenergic receptor kinase (GRK2) colocalizes with beta-adrenergic receptors during agonist-induced receptor internalization

Rapid regulation of G protein-coupled receptors appears to involve agonist-promoted receptor phosphorylation by G protein-coupled receptor kinases (GRKs). This is followed by binding of uncoupling proteins termed arrestins and transient receptor internalization. In this report we show that the beta-adrenergic receptor kinase (betaARK-1 or GRK2) follows a similar pattern of internalization upon agonist activation of beta2-adrenergic receptors (beta2AR) and that betaARK expression levels modulate receptor sequestration. Stable cotransfected cells expressing an epitope-tagged beta2AR and betaARK-1 show an increased rate and extent of beta2AR internalization compared with cells expressing receptor alone. Moreover, subcellular gradient fractionation studies suggest that betaARK colocalizes with the internalized receptors. In fact, double immunofluorescence analysis using confocal microscopy shows extensive colocalization of beta2AR and betaARK in intracellular vesicles upon receptor stimulation. Our results confirm a functional relationship between receptor phosphorylation and sequestration and indicate that betaARK does not only translocates from the cytoplasm to the plasma membrane in response to receptor occupancy, but shares endocytic mechanisms with the beta2AR. These data suggest a direct role for betaARK in the sequestration process and/or the involvement of receptor internalization in the intracellular trafficking of the kinase.     

Identification of phosphorylation sites in the G protein-coupled receptor for parathyroid hormone. Receptor phosphorylation is not required for agonist-induced internalization

In some G protein-coupled receptors (GPCRs), agonist-dependent phosphorylation by specific GPCR kinases (GRKs) is an important mediator of receptor desensitization and endocytosis. Phosphorylation and the subsequent events that it triggers, such as arrestin binding, have been suggested to be regulatory mechanisms for a wide variety of GPCRs. In the present study, we investigated whether agonist-induced phosphorylation of the PTH receptor, a class II GPCR, also regulates receptor internalization. Upon agonist stimulation, the PTH receptor was exclusively phosphorylated on serine residues. Phosphoamino acid analysis of a number of receptor mutants in which individual serine residues had been replaced by threonine identified serine residues in positions 485, 486, and 489 of the cytoplasmic tail as sites of phosphorylation after agonist treatment. When serine residues at positions 483, 485, 486, 489, 495, and 498 were simultaneously replaced by alanine residues, the PTH receptor was no longer phosphorylated either basally or in response to PTH. The substitution of these serine residues by alanine affected neither the number of receptors expressed on the cell surface nor the ability of the receptor to signal via Gs. Overexpression of GRK2, but not GRK3, enhanced PTH-stimulated receptor phosphorylation, and this phosphorylation was abolished by alanine mutagenesis of residues 483, 485, 486, 489, 495, and 498. Thus, phosphorylation of the PTH receptor by the endogenous kinase in HEK-293 cells occurs on the same residues targeted by overexpressed GRK2. Strikingly, the rate and extent of PTH-stimulated internalization of mutated PTH receptors lacking phosphorylation sites were identical to that observed for the wild-type PTH receptor. Moreover, overexpressed GRK2, while enhancing the phosphorylation of the wild-type PTH receptor, had no affect on the rate or extent of receptor internalization in response to PTH. Thus, the agonist-occupied PTH receptor is phosphorylated by a kinase similar or identical to GRK2 in HEK-293 cells, but this phosphorylation is not requisite for efficient receptor endocytosis.     

Oligomerized transferrin receptors are selectively retained by a lumenal sorting signal in a long-lived endocytic recycling compartment

Cross-linking of surface receptors results in altered receptor trafficking in the endocytic system. To better understand the cellular and molecular mechanisms by which receptor cross-linking affects the intracellular trafficking of both ligand and receptor, we studied the intracellular trafficking of the transferrin receptor (TfR) bound to multivalent-transferrin (Tf10) which was prepared by chemical cross-linking of transferrin (Tf). Tf10 was internalized about two times slower than Tf and was retained four times longer than Tf, without being degraded in CHO cells. The intracellular localization of Tf10 was investigated using fluorescence and electron microscopy. Tf10 was not delivered to the lysosomal pathway followed by low density lipoprotein but remained accessible to Tf in the pericentriolar endocytic recycling compartment for at least 60 min. The retained Tf10 was TfR-associated as demonstrated by a reduction in surface TfR number when cells were incubated with Tf10. The presence of Tf10 within the recycling compartment did not affect trafficking of subsequently endocytosed Tf. Retention of Tf10 within the recycling compartment did not require the cytoplasmic domain of the TfR since Tf10 exited cells with the same rate when bound to the wild-type TfR or a mutated receptor with only four amino acids in the cytoplasmic tail. Thus, cross-linking of surface receptors by a multivalent ligand acts as a lumenal retention signal within the recycling compartment. The data presented here show that the recycling compartment labeled by Tf10 is a long-lived organelle along the early endosome recycling pathway that remains fusion accessible to subsequently endocytosed Tf.     

Proper sorting of the cation-dependent mannose 6-phosphate receptor in endosomes depends on a pair of aromatic amino acids in its cytoplasmic tail

The 67-amino acid cytoplasmic tail of the cation-dependent mannose 6-phosphate receptor (CD-MPR) contains a signal(s) that prevents the receptor from entering lysosomes where it would be degraded. To identify the key residues required for proper endosomal sorting, we analyzed the intracellular distribution of mutant forms of the receptor by Percoll density gradients. A receptor with a Trp19 --> Ala substitution in the cytoplasmic tail was highly missorted to lysosomes whereas receptors with either Phe18 --> Ala or Phe13 --> Ala mutations were partially defective in avoiding transport to lysosomes. Analysis of double and triple mutants confirmed the key role of Trp19 for sorting of the CD-MPR in endosomes, with Phe18, Phe13, and several neighboring residues contributing to this function. The addition of the Phe18-Trp19 motif of the CD-MPR to the cytoplasmic tail of the lysosomal membrane protein Lamp1 was sufficient to partially impair its delivery to lysosomes. Replacing Phe18 and Trp19 with other aromatic amino acids did not impair endosomal sorting of the CD-MPR, indicating that two aromatic residues located at these positions are sufficient to prevent the receptor from trafficking to lysosomes. However, alterations in the spacing of the diaromatic amino acid sequence relative to the transmembrane domain resulted in receptor accumulation in lysosomes. These findings indicate that the endosomal sorting of the CD-MPR depends on the correct presentation of a diaromatic amino acid-containing motif in its cytoplasmic tail. Because a diaromatic amino acid sequence is also present in the cytoplasmic tail of other receptors known to be internalized from the plasma membrane, this feature may prove to be a general determinant for endosomal sorting.     

Interaction of cytosolic adaptor proteins with neuronal apolipoprotein E receptors and the amyloid precursor protein

Apolipoprotein E, alpha2-macroglobulin, and amyloid precursor protein (APP) are involved in the development of Alzheimer's disease. All three proteins are ligands for the low density lipoprotein (LDL) receptor-related protein (LRP), an abundant neuronal surface receptor that has also been genetically linked to Alzheimer's disease. The cytoplasmic tails of LRP and other members of the LDL receptor gene family contain NPxY motifs that are required for receptor endocytosis. To investigate whether these receptors may have functions that go beyond ligand internalization, e.g. possible roles in cellular signaling, we searched for proteins that might interact with the cytoplasmic tails of the receptors. A family of adaptor proteins containing protein interaction domains that can interact with NPxY motifs has previously been described. Using yeast 2-hybrid and protein coprecipitation approaches in vitro, we show that the neuronal adaptor proteins FE65 and mammalian Disabled bind to the cytoplasmic tails of LRP, LDL receptor, and APP, where they can potentially serve as molecular scaffolds for the assembly of cytosolic multiprotein complexes. FE65 contains two distinct protein interaction domains that interact with LRP and APP, respectively, raising the possibility that LRP can modulate the intracellular trafficking of APP. Tyrosine-phosphorylated mammalian Disabled can recruit nonreceptor tyrosine kinases, such as src and abl, to the cytoplasmic tails of the receptors to which it binds, suggesting a molecular pathway by which receptor/ligand interaction on the cell surface could generate an intracellular signal.     

Replacement of threonine 394 by alanine facilitates internalization and resensitization of the rat mu opioid receptor

Signaling of G protein-coupled receptors is terminated by phosphorylation of intracellular serine and threonine residues. Resensitization of these receptors requires internalization and subsequent dephosphorylation. We have recently shown that the resensitization rate of the rat micro opioid receptor (MOR) isoforms MOR1 and MOR1B is mainly determined by the amino acid composition of their alternatively spliced C-terminal tails. Upon agonist stimulation, MOR1B passes through an accelerated cycle of receptor endocytosis and reactivation, which in turn promotes a greater resistance to agonist-induced desensitization, as compared with MOR1. Given the fact that MOR1B lacks only one putative phosphorylation site (T394 of MOR1), we replaced this threonine by an alanine and stably expressed the wild-type MOR1 and its T394A mutant in mouse neuroblastoma Neuro2a cells. We show that during prolonged [D-Ala2, MePhe4, Gly5-ol]enkephalin exposure (5 h), the T394A receptor mutant desensitized at a slower rate than MOR1. In contrast, T394A is more rapidly removed from the cell surface than MOR1, as determined by flow cytometry using epitope-tagged receptors. This fast internalization was followed by immediate resensitization of T394A during 20 min of agonist removal while the wild-type MOR1 remained inactive. Similar to MOR1B, rapid internalization and reactivation of T394A may explain its delayed desensitization. These findings suggest that T394 represents a negative regulatory signal for MOR1 internalization. Furthermore, phosphorylation of this threonine residue may influence the time course of micro opioid receptor resensitization.     

Truncated V2 vasopressin receptors as negative regulators of wild-type V2 receptor function

Accumulating evidence suggests that G protein-coupled receptors (GPCRs) can form dimeric or oligomeric arrays. Based on this concept, we have tested the hypothesis that truncated GPCRs can act as negative regulators of wild-type receptor function. Using the GS-coupled V2 vasopressin receptor as a model system, we systematically analyzed the ability of N- and C-terminal V2 receptor fragments to interfere with the activity of the wild-type V2 receptor coexpressed in COS-7 cells. Several N-terminal V2 receptor truncation mutants were identified that strongly inhibited the function (as determined in cAMP and radioligand binding assays) and cell surface trafficking of the coexpressed full-length V2 receptor. However, these truncation mutants did not interfere with the function of other GS-coupled receptors such as the D1 dopamine and the beta2-adrenergic receptors. Dominant negative effects were only observed with mutant receptors that contained at least three transmembrane domains. In addition, immunoblotting experiments showed that all V2 receptor truncation mutants displaying dominant negative activity (but not those mutant receptors lacking this activity) were able to form heterodimers with the full-length V2 receptor, suggesting that complex formation between mutant and wild-type V2 receptors underlies the observed inhibition of wild-type receptor function. Given the high degree of structural homology shared by all GPCRs, our findings should also be applicable to other members of this receptor superfamily.