N-formyl peptide receptors internalize but do not recycle in the absence of arrestins

Arrestins mediate phosphorylation-dependent desensitization, internalization, and initiation of signaling cascades for the majority of G protein-coupled receptors (GPCRs). Many GPCRs undergo agonist-mediated internalization through arrestin-dependent mechanisms, wherein arrestin serves as an adapter between the receptor and endocytic proteins. To understand the role of arrestins in N-formyl peptide receptor (FPR) trafficking, we stably expressed the FPR in a mouse embryonic fibroblast cell line (MEF) that lacked endogenous arrestin 2 and arrestin 3 (arrestin-deficient). We compared FPR internalization and recycling kinetics in these cells to congenic wild type MEF cell lines. Internalization of the FPR was not altered in the absence of arrestins. Since the FPR remains associated with arrestins following internalization, we investigated whether the rate of FPR recycling was altered in arrestin-deficient cells. While the FPR was able to recycle in the wild type cells, receptor recycling was largely absent in the arrestin double knockout cells. Reconstitution of the arrestin-deficient line with either arrestin 2 or arrestin 3 restored receptor recycling. Confocal fluorescence microscopy studies demonstrated that in arrestin-deficient cells the FPR may become trapped in the perinuclear recycling compartment. These observations indicate that, although the FPR can internalize in the absence of arrestins, recycling of internalized receptors to the cell surface is prevented. Our results suggest a novel role for arrestins in the post-endocytic trafficking of GPCRs.     

Adaptor Protein-2 Interaction with Arrestin Regulates GPCR Recycling and Apoptosis

G protein-coupled receptors (GPCRs) are integral to cellular function in nearly all physiologic and many pathologic processes. GPCR signaling represents an intricate balance between receptor activation, inactivation (desensitization, internalization and degradation) and resensitization (recycling and de novo synthesis). Complex formation between phosphorylated GPCRs, arrestins and an ever-increasing number of effector molecules is known to regulate cellular function. Previous studies have demonstrated that, although N -formyl peptide receptor (FPR) internalization occurs in the absence of arrestins, FPR recycling is arrestin-dependent. Furthermore, FPR stimulation in the absence of arrestins leads to receptor accumulation in perinuclear endosomes and apoptosis. In this study, we show that the interaction of GPCR-bound arrestin with adaptor protein-2 (AP-2) is a critical anti-apoptotic event. In addition, AP-2 associates with the receptor-arrestin complex in perinuclear endosomes and is required for proper post-endocytic GPCR trafficking. Finally, we observed that depletion of endogenous AP-2 results in the initiation of apoptosis upon stimulation of multiple GPCRs, including P2Y purinergic receptors and CXCR2, but not CXCR4. We propose a model in which the abnormal accumulation of internalized GPCR-arrestin complexes in recycling endosomes, resulting from defective arrestin-AP-2 interactions, leads to the specific initiation of aberrant signaling pathways and apoptosis.     

Clathrin-dependent mechanisms of G protein-coupled receptor endocytosis

The heptahelical G protein-coupled receptor (GPCR) family includes approximately 900 members and is the largest family of signaling receptors encoded in the mammalian genome. G protein-coupled receptors elicit cellular responses to diverse extracellular stimuli at the plasma membrane and some internalized receptors continue to signal from intracellular compartments. In addition to rapid desensitization, receptor trafficking is critical for regulation of the temporal and spatial aspects of GPCR signaling. Indeed, GPCR internalization functions to control signal termination and propagation as well as receptor resensitization. Our knowledge of the mechanisms that regulate mammalian GPCR endocytosis is based predominantly on arrestin regulation of receptors through a clathrin- and dynamin-dependent pathway. However, multiple clathrin adaptors, which recognize distinct endocytic signals, are now known to function in clathrin-mediated endocytosis of diverse cargo. Given the vast number and diversity of GPCRs, the complexity of clathrin-mediated endocytosis and the discovery of multiple clathrin adaptors, a single universal mechanism controlling endocytosis of all mammalian GPCRs is unlikely. Indeed, several recent studies now suggest that endocytosis of different GPCRs is regulated by distinct mechanisms and clathrin adaptors. In this review, we discuss the diverse mechanisms that regulate clathrin-dependent GPCR endocytosis.     

Inhibition of chemoattractant N-formyl peptide receptor trafficking by active arrestins

Recent studies have highlighted the emergence of a class of G protein-coupled receptors that are internalized in an arrestin-independent manner. In addition to demonstrating that the N-formyl peptide receptor belongs in this family, we have recently shown that recycling of the receptor requires the presence of arrestins. To further elucidate mechanisms of arrestin-dependent regulation of G protein-coupled receptor processing, we examined the effects of altering the receptor-arrestin complex on ternary complex formation and cellular trafficking of the N-formyl peptide receptor by studying two active arrestin-2 mutants (truncated arrestin-2 [1-382], and arrestin-2 I386A, V387A, F388A). Complexes between the N-formyl peptide receptor and active arrestins exhibited higher affinity in vitro than the complex between the N-formyl peptide receptor and wild-type arrestin and furthermore were observed in vivo by colocalization studies using confocal microscopy. To assess the effects of these altered interactions on receptor trafficking, we demonstrated that active, but not wild-type, arrestin expression retards N-formyl peptide receptor internalization. Furthermore, expression of arrestin-2 I386A/V387A/F388A but not arrestin-2 [1-382] inhibited recycling of the N-formyl peptide receptor, reflecting an expanded role for arrestins in G protein-coupled receptor processing and trafficking. Whereas the extent of N-formyl peptide receptor phosphorylation had no effect on the inhibition of internalization, N-formyl peptide receptor recycling was restored when the receptor was only partially phosphorylated. These results indicate not only that a functional interaction between receptor and arrestin is required for recycling of certain G protein-coupled receptors, such as the N-formyl peptide receptor, but that the pattern of receptor phosphorylation further regulates this process.     

Arrestins block G protein-coupled receptor-mediated apoptosis

G protein (heterotrimeric guanine nucleotide-binding protein)-coupled receptors (GPCRs) activate numerous cellular signals through the combined actions of G proteins, GPCR kinases, and arrestins. Although arrestins have traditionally been thought of as mediating GPCR desensitization, they have now been shown to play important roles in the internalization, trafficking, and signaling of many GPCRs. We demonstrate that in cells devoid of arrestins, the stimulation of numerous GPCRs including the N-formyl peptide receptor (FPR) initiates rapid cell rounding, annexin V positivity, and caspase activation followed by cell death. The apoptotic response is initiated by G protein signaling and involves activation of phosphoinositide 3-kinase, mitogen-activated protein kinases, and c-Src resulting in cytochrome c release from mitochondria and ultimately caspase 9 and caspase 3 activation. Reconstitution with either arrestin-2 or arrestin-3 is completely sufficient to prevent FPR-mediated apoptosis. Surprisingly, a non-desensitizing and non-internalizing mutant of the FPR is unable to initiate apoptosis, indicating that receptor phosphorylation and internalization, but not solely chronic activation due to a lack of desensitization, are critical determinants for the induction of apoptosis by the FPR. We further demonstrate that this response is not unique to the FPR with numerous additional GPCRs, including the V2 vasopressin, angiotensin II (type 1A), and CXCR2 receptors, capable of initiating apoptosis upon stimulation, whereas GPCRs such as the beta(2)-adrenergic receptor and CXCR4 are not capable of initiating apoptotic signaling. These data demonstrate for the first time that arrestins play a critical and completely unexpected role in the suppression GPCR-mediated apoptosis, which we show is a common consequence of GPCR-mediated cellular activation in the absence of arrestins.     

Regulation of N-formyl peptide receptor signaling and trafficking by individual carboxyl-terminal serine and threonine residues

Adaptation, defined as the diminution of receptor signaling in the presence of continued or repeated stimulation, is critical to cellular function. G protein-coupled receptors (GPCRs) undergo multiple adaptive processes, including desensitization and internalization, through phosphorylation of cytoplasmic serine and threonine residues. However, the relative importance of individual and combined serine and threonine residues to these processes is not well understood. We examined this mechanism in the context of the N-formyl peptide receptor (FPR), a well-characterized member of the chemoattractant/chemokine family of GPCRs critical to neutrophil function. To evaluate the contributions of individual and combinatorial serine and threonine residues to internalization, desensitization, and arrestin2 binding, 30 mutant forms of the FPR, expressed in the human promyelocytic U937 cell line, were characterized. We found that residues Ser(328), Ser(332), and Ser(338) are individually critical, and indeed sufficient, for internalization, desensitization, and arrestin2 binding, but that the presence of neighboring threonine residues can inhibit these processes. Additionally, we observed no absolute correlation between arrestin binding and either internalization or desensitization, suggesting the existence of arrestin-independent mechanisms for these processes. Our results suggest C-terminal serine and threonine residues of the FPR represent a combinatorial code, capable of both positively and negatively regulating signaling and trafficking. This study is among the first detailed analyses of a complex regulatory site in a GPCR, and provides insight into GPCR regulatory mechanisms.     

Identification of Receptor Binding-induced Conformational Changes in Non-visual Arrestins

The non-visual arrestins, arrestin-2 and arrestin-3, belong to a small family of multifunctional cytosolic proteins. Non-visual arrestins interact with hundreds of G protein-coupled receptors (GPCRs) and regulate GPCR desensitization by binding active phosphorylated GPCRs and uncoupling them from heterotrimeric G proteins. Recently, non-visual arrestins have been shown to mediate G protein-independent signaling by serving as adaptors and scaffolds that assemble multiprotein complexes. By recruiting various partners, including trafficking and signaling proteins, directly to GPCRs, non-visual arrestins connect activated receptors to diverse signaling pathways. To investigate arrestin-mediated signaling, a structural understanding of arrestin activation and interaction with GPCRs is essential. Here we identified global and local conformational changes in the non-visual arrestins upon binding to the model GPCR rhodopsin. To detect conformational changes, pairs of spin labels were introduced into arrestin-2 and arrestin-3, and the interspin distances in the absence and presence of the receptor were measured by double electron electron resonance spectroscopy. Our data indicate that both non-visual arrestins undergo several conformational changes similar to arrestin-1, including the finger loop moving toward the predicted location of the receptor in the complex as well as the C-tail release upon receptor binding. The arrestin-2 results also suggest that there is no clam shell-like closure of the N- and C-domains and that the loop containing residue 136 (homolog of 139 in arrestin-1) has high flexibility in both free and receptor-bound states.     

Arrestin variants display differential binding characteristics for the phosphorylated N-formyl peptide receptor carboxyl terminus.

The phosphorylation-dependent binding of arrestins to cytoplasmic domains of G protein-coupled receptors (GPCRs) is thought to be a crucial step in receptor desensitization. In some GPCR systems, arrestins have also been demonstrated to be involved in receptor internalization, resensitization, and the activation of signaling cascades. The objective of the current study was to examine binding interactions of members of the arrestin family with the formyl peptide receptor (FPR), a member of the GPCR family of receptors. Peptides representing the unphosphorylated and phosphorylated carboxyl terminus of the FPR were synthesized and bound to polystyrene beads via a biotin/streptavidin interaction. Using fluorescein-conjugated arrestins, binding interactions between arrestins and the bead-bound FPR carboxyl terminus were analyzed by flow cytometry. Arrestin-2 and arrestin-3 bound to the FPR carboxyl-terminal peptide in a phosphorylation-dependent manner, with K(d) values in the micromolar range. Binding of visual arrestin, which binds rhodopsin with high selectivity, was not observed. Arrestin-2-(1--382) and arrestin-3-(1--393), truncated mutant forms of arrestin that display phosphorylation-independent binding to intact receptors, were also observed to bind the bead-bound FPR terminus in a phosphorylation-dependent manner, but with much greater affinity than the full-length arrestins, yielding K(d) values in the 5--50 nm range. Two additional arrestin mutants, which are full-length but display phosphorylation-independent binding to intact GPCRs, were evaluated for their binding affinity to the FPR carboxyl terminus. Whereas the single point mutant, arrestin-2 R169E, displayed an affinity similar to that of the full-length arrestins, the triple point mutant, arrestin-2 I386A/V387A/F388A, displayed an affinity more similar to that of the truncated forms of arrestin. The results suggest that the carboxyl terminus of arrestin is a critical determinant in regulating the binding affinity of arrestin for the phosphorylated domains of GPCRs.     

ßarrestin1-biased agonism at human δ-opioid receptor by peptidic and alkaloid ligands

We have previously reported on the differential regulation of the human δ-opioid receptor (hDOR) by alkaloid (etorphine) and peptidic (DPDPE and deltorphin I) ligands, in terms of both receptor desensitization and post-endocytic sorting. Since ßarrestins are well known to regulate G protein-coupled receptors (GPCRs) signaling and trafficking, we therefore investigated the role of ßarrestin1 (the only isoform expressed in our cellular model) in the context of the hDOR. We established clonal cell lines of SK-N-BE cells over-expressing ßarrestin1, its dominant negative mutant (ßarrestin1^319-418), and shRNA directed against endogenous ßarrestin1. Interestingly, both binding and confocal microscopy approaches demonstrated that ßarrestin1 is required for hDOR endocytosis only when activated by etorphine. Conversely, functional experiments revealed that ßarrestin1 is exclusively involved in hDOR desensitization promoted by the peptides. Taken together, these results provide substantial evidence for a ßarrestin1-biased agonism at hDOR, where ßarrestin1 is differentially involved during receptor desensitization and endocytosis depending on the ligand.     

Differential roles of arrestin-2 interaction with clathrin and adaptor protein 2 in G protein-coupled receptor trafficking

The non-visual arrestins, arrestin-2 and arrestin-3, play a critical role in regulating the signaling and trafficking of many G protein-coupled receptors (GPCRs). Molecular insight into the role of arrestins in GPCR trafficking has suggested that arrestin interaction with clathrin, beta(2)-adaptin (the beta-subunit of the adaptor protein AP2), and phosphoinositides contributes to this process. In the present study, we have attempted to better define the molecular basis and functional role of arrestin-2 interaction with clathrin and beta(2)-adaptin. Site-directed mutagenesis revealed that the C-terminal region of arrestin-2 mediated beta(2)-adaptin and clathrin interaction with Phe-391 and Arg-395 having an essential role in beta(2)-adaptin binding and LIELD (residues 376-380) having an essential role in clathrin binding. Interestingly, arrestin-2-R169E, an activated form of arrestin that binds to GPCRs in a phosphorylation-independent manner, has significantly enhanced binding to beta(2)-adaptin and clathrin. This suggests that receptor-induced conformational changes in the C-terminal tail of arrestin-2 will likely play a major role in mediating arrestin interaction with clathrin-coated pits. In an effort to clarify the role of these interactions in GPCR trafficking we generated arrestin mutants that were completely and selectively defective in either clathrin (arrestin-2-DeltaLIELD) or beta(2)-adaptin (arrestin-2-F391A) interaction. Analysis of these mutants in COS-1 cells revealed that arrestin/clathrin interaction was essential for agonist-promoted internalization of the beta(2)-adrenergic receptor, while arrestin/beta(2)-adaptin interaction appeared less critical. Arrestin-2 mutants defective in both clathrin and beta(2)-adaptin binding functioned as effective dominant negatives in HEK293 cells and significantly attenuated beta(2)-adrenergic receptor internalization. These mutants should prove useful in better defining the role of arrestins in mediating receptor trafficking.     

Differential affinities of visual arrestin, beta arrestin1, and beta arrestin2 for G protein-coupled receptors delineate two major classes of receptors

Visual arrestin, betaarrestin1, and betaarrestin2 comprise a family of intracellular proteins that desensitize G protein-coupled receptors (GPCRs). In addition, betaarrestin1 and betaarrestin2 target desensitized receptors to clathrin-coated pits for endocytosis. Whether arrestins differ in their ability to interact with GPCRs in cells is not known. In this study, we visualize the interaction of arrestin family members with GPCRs in real time and in live cells using green fluorescent protein-tagged arrestins. In the absence of agonist, visual arrestin and betaarrestin1 were found in both the cytoplasm and nucleus of HEK-293 cells, whereas betaarrestin2 was found only in the cytoplasm. Analysis of agonist-mediated arrestin translocation to multiple GPCRs identified two major classes of receptors. Class A receptors (beta2 adrenergic receptor, mu opioid receptor, endothelin type A receptor, dopamine D1A receptor, and alpha1b adrenergic receptor) bound betaarrestin2 with higher affinity than betaarrestin1 and did not interact with visual arrestin. In contrast, class B receptors (angiotensin II type 1A receptor, neurotensin receptor 1, vasopressin V2 receptor, thyrotropin-releasing hormone receptor, and substance P receptor) bound both betaarrestin isoforms with similar high affinities and also interacted with visual arrestin. Switching the carboxyl-terminal tails of class A and class B receptors completely reversed the affinity of each receptor for the visual and non-visual arrestins. In addition, exchanging the betaarrestin1 and betaarrestin2 carboxyl termini reversed their extent of binding to class A receptors as well as their subcellular distribution. These results reveal for the first time marked differences in the ability of arrestin family members to bind GPCRs at the plasma membrane. Moreover, they show that visual arrestin can interact in cells with GPCRs other than rhodopsin. These findings suggest that GPCR signaling may be differentially regulated depending on the cellular complement of arrestin isoforms and the ability of arrestins to interact with other cellular proteins.     

Regulation of N-Formyl Peptide Receptor Signaling and Trafficking by Arrestin-Src Kinase Interaction

Arrestins were originally described as proteins recruited to ligand-activated, phosphorylated G protein-coupled receptors (GPCRs) to attenuate G protein-mediated signaling. It was later revealed that arrestins also mediate GPCR internalization and recruit a number of signaling proteins including, but not limited to, Src family kinases, ERK1/2, and JNK3. GPCR-arrestin binding and trafficking control the spatial and temporal activity of these multi-protein complexes. In previous reports, we concluded that N-formyl peptide receptor (FPR)-mediated apoptosis, which occurs upon receptor stimulation in the absence of arrestins, is associated with FPR accumulation in perinuclear recycling endosomes. Under these conditions, inhibition of Src kinase and ERK1/2 prevented FPR-mediated apoptosis. To better understand the role of Src kinase in this process, in the current study we employed a previously described arrestin-2 (arr2) mutant deficient in Src kinase binding (arr2-P91G/P121E). Unlike wild type arrestin, arr2-P91G/P121E did not inhibit FPR-mediated apoptosis, suggesting that Src binding to arrestin-2 prevents apoptotic signaling. However, in cells expressing this mutant, FPR-mediated apoptosis was still blocked by inhibition of Src kinase activity, suggesting that activation of Src independent of arrestin-2 binding is involved in FPR-mediated apoptosis. Finally, while Src kinase inhibition prevented FPR-mediated-apoptosis in the presence of arr2-P91G/P121E, it did not prevent FPR-arr2-P91G/P121E accumulation in the perinuclear recycling endosome. On the contrary, inhibition of Src kinase activity mediated the accumulation of activated FPR-wild type arrestin-2 in recycling endosomes without initiating FPR-mediated apoptosis. Based on these observations, we conclude that Src kinase has two independent roles following FPR activation that regulate both FPR-arrestin-2 signaling and trafficking.     

Characterization of RANTES- and aminooxypentane-RANTES-triggered desensitization signals reveals differences in recruitment of the G protein-coupled receptor complex.

The trafficking of lymphocyte populations is a complex process controlled by a vast array of molecules. In this process, cells must be able to sense small changes in chemoattractant gradients. Migration through a chemotactic gradient probably employs an on-off mechanism in which chemokine receptor desensitization, internalization, and recycling may be important steps. This multistep process requires the coordinated action of many factors, including G protein-coupled receptor kinases, arrestins, clathrin, and GTP-hydrolyzing proteins such as dynamin. In this report, we show that RANTES and its derivative, aminooxypentane (AOP)-RANTES, a potent RANTES antagonist as well as an inhibitor of HIV-1 infection, both promote CCR5 desensitization involving G protein-coupled receptor kinases-2 and beta-arrestin equally well. An important difference between the two molecules is that (AOP)-RANTES is more efficient than RANTES in promoting Ser/Thr phosphorylation of the receptor and association of G protein-coupled receptor kinases-2, beta-arrestin, and clathrin to the CCR5. After stimulation with either ligand, we observe rapid, transient association of dynamin to CCR5, implicating this protein in receptor sensitization, but this association is faster and longer-lasting following (AOP)-RANTES stimulation. In summary, we show that chemokine receptor internalization takes place through the formation of clathrin vesicles and involves dynamin activity. We provide compelling evidence that the differences between RANTES and (AOP)-RANTES in G alpha i activation condition subsequent signaling events, including internalization and receptor recycling.     

Ascidian arrestin (Ci-arr), the origin of the visual and nonvisual arrestins of vertebrate.

Arrestin is one of the key proteins for the termination of G protein signaling. Activated G protein-coupled receptors (GPCRs) are specifically phosphorylated by G protein-coupled receptor kinases (GRKs) and then bind to arrestins to preclude the receptor/G protein interaction, resulting in quenching of the following signal transduction. Vertebrates possess two types of arrestin; visual arrestin expressed exclusively in photoreceptor cells in retinae and pineal organs, and beta-arrestin, which is expressed ubiquitously. Unlike visual arrestin, beta-arrestin contains the clathrin-binding domain at the C-terminus, responsible for the agonist-induced internalization of GPCRs. Here, we isolated a novel arrestin gene (Ci-arr) from the primitive chordate, the ascidian Ciona intestinalis larvae. The deduced amino acid sequence suggests that Ci-Arr be closely related to vertebrate arrestins. Interestingly, this arrestin has the feature of both visual and beta-arrestin. Whereas the expression of Ci-arr was restricted to the photoreceptors in the larvae similarly to visual arrestin, the gene product, containing the clathrin-binding domain, promoted the GPCR internalization in HEK293tsA201 cells similarly to beta-arrestin. The phylogenetic tree shows that Ci-Arr is branched from a common root of visual and beta-arrestins. Southern analysis suggests that the Ciona genome contains only one gene for the arrestin family. These results suggest that the visual and beta-arrestin genes were generated by the duplication of the prototypical arrestin gene like Ci-arr in the early evolution of vertebrates.     

The nature of the arrestin x receptor complex determines the ultimate fate of the internalized receptor

The vast majority of G protein-coupled receptors are desensitized by a uniform two-step mechanism: phosphorylation of an active receptor followed by arrestin binding. The arrestin x receptor complex is then internalized. Internalized receptor can be recycled back to the plasma membrane (resensitization) or targeted to lysosomes for degradation (down-regulation). The intracellular compartment where this choice is made and the molecular mechanisms involved are largely unknown. Here we used two arrestin2 mutants that bind with high affinity to phosphorylated and unphosphorylated agonist-activated beta 2-adrenergic receptor to manipulate the receptor-arrestin interface. We found that mutants support rapid internalization of beta 2-adrenergic receptor similar to wild type arrestin2. At the same time, phosphorylation-independent arrestin2 mutants facilitate receptor recycling and sharply reduce the rate of receptor loss, effectively protecting beta 2-adrenergic receptor from down-regulation even after very long (up to 24 h) agonist exposure. Phosphorylation-independent arrestin2 mutants dramatically reduce receptor phosphorylation in response to an agonist both in vitro and in cells. Interestingly, co-expression of high levels of beta-adrenergic receptor kinase restores receptor down-regulation in the presence of mutants to the levels observed with wild type arrestin2. Our data suggest that unphosphorylated receptor internalized in complex with mutant arrestins recycles faster than phosphoreceptor and is less likely to get degraded. Thus, targeted manipulation of the characteristics of an arrestin protein that binds to a G protein-coupled receptors can dramatically change receptor trafficking and its ultimate fate in a cell.     

Characterization of G protein-coupled receptor regulation in antisense mRNA-expressing cells with reduced arrestin levels.

Previous studies with overexpressing wild-type or dominant negative nonvisual arrestins have established a role for these proteins in beta2-adrenergic receptor (beta2AR) internalization, desensitization, and resensitization. To validate and extend such findings, we employed an antisense strategy to target the nonvisual arrestins, arrestin-2 and arrestin-3, and determined the associated effects on the regulation of G protein-coupled receptor (GPCR) signaling. HEK293 cells stably expressing antisense constructs targeting arrestin-2 exhibited a selective reduction (approximately 50%) in arrestin-2 levels, while arrestin-3 antisense constructs resulted in reductions (>/=50%) in both arrestin-2 and arrestin-3 levels. Initial analysis of these cells demonstrated that a reduced level of arrestin expression resulted in a significant decrease in the extent of agonist-induced internalization of exogenously expressed beta2ARs, but had no effect on internalization of either m2 or m3 muscarinic acetylcholine receptors. Additional characterization involved assessing the role of arrestins in the regulation of endogenous GPCRs in these cells. Reduced arrestin levels significantly decreased the rate of endogenous beta2AR internalization, desensitization, and resensitization. Further analysis demonstrated that the desensitization of endogenous A2b adenosine and prostaglandin E2-stimulated receptors was also attenuated in cells with reduced arrestin levels. The effects on the beta2-adrenergic, A2b adenosine, and PGE2-stimulated receptors were similar among cell lines that exhibited either a selective reduction in arrestin-2 levels or a reduction in both arrestin-2 and -3 levels. These findings establish the utility of antisense approaches in the examination of arrestin-mediated GPCR regulation.     

Arrestin 3 mediates endocytosis of CCR7 following ligation of CCL19 but not CCL21

Internalization of ligand bound G protein-coupled receptors, an important cellular function that mediates receptor desensitization, takes place via distinct pathways, which are often unique for each receptor. The C-C chemokine receptor (CCR7) G protein-coupled receptor is expressed on naive T cells, dendritic cells, and NK cells and has two endogenous ligands, CCL19 and CCL21. Following binding of CCL21, 21 +/- 4% of CCR7 is internalized in the HuT 78 human T cell lymphoma line, while 76 +/- 8% of CCR7 is internalized upon binding to CCL19. To determine whether arrestins mediated differential internalization of CCR7/CCL19 vs CCR7/CCL21, we used small interfering RNA (siRNA) to knock down expression of arrestin 2 or arrestin 3 in HuT 78 cells. Independent of arrestin 2 or arrestin 3 expression, CCR7/CCL21 internalized. In contrast, following depletion of arrestin 3, CCR7/CCL19 failed to internalize. To examine the consequence of complete loss of both arrestin 2 and arrestin 3 on CCL19/CCR7 internalization, we examined CCR7 internalization in arrestin 2(-/-)/arrestin 3(-/-) murine embryonic fibroblasts. Only reconstitution with arrestin 3-GFP but not arrestin 2-GFP rescued internalization of CCR7/CCL19. Loss of arrestin 2 or arrestin 3 blocked migration to CCL19 but had no effect on migration to CCL21. Using immunofluorescence microscopy, we found that arrestins do not cluster at the membrane with CCR7 following ligand binding but cap with CCR7 during receptor internalization. These are the first studies that define a role for arrestin 3 in the internalization of a chemokine receptor following binding of one but not both endogenous ligands.     

Tracking the opioid receptors on the way of desensitization

Opioid receptors belong to the super family of G-protein coupled receptors (GPCRs) and are the targets of numerous opioid analgesic drugs. Prolonged use of these drugs results in a reduction of their effectiveness in pain relief also called tolerance, a phenomenon well known by physicians. Opioid receptor desensitization is thought to play a major role in tolerance and a lot of work has been dedicated to elucidate the molecular basis of desensitization. As described for most of GPCRs, opioid receptor desensitization involves their phosphorylation by kinases and their uncoupling from G-proteins realized by arrestins. More recently, opioid receptor trafficking was shown to contribute to desensitization. In this review, our knowledge on the molecular mechanisms of desensitization and recent progress on the role of opioid receptor internalization, recycling or degradation in desensitization will be reported. A better understanding of these regulatory mechanisms would be helpful to develop new analgesic drugs or new strategies for pain treatment by limiting opioid receptor desensitization and tolerance.     

GPCR desensitization: Acute and prolonged phases

G protein-coupled receptors (GPCRs) transduce a wide array of extracellular signals and regulate virtually every aspect of physiology. While GPCR signaling is essential, overstimulation can be deleterious, resulting in cellular toxicity or uncontrolled cellular growth. Accordingly, nature has developed a number of mechanisms for limiting GPCR signaling, which are broadly referred to as desensitization, and refer to a decrease in response to repeated or continuous stimulation. Short-term desensitization occurs over minutes, and is primarily associated with β-arrestins preventing G protein interaction with a GPCR. Longer-term desensitization, referred to as downregulation, occurs over hours to days, and involves receptor internalization into vesicles, degradation in lysosomes and decreased receptor mRNA levels through unclear mechanisms. Phosphorylation of the receptor by GPCR kinases (GRKs) and the recruitment of β-arrestins is critical to both these short- and long-term desensitization mechanisms. In addition to phosphorylation, both the GPCR and β-arrestins are modified post-translationally in several ways, including by ubiquitination. For many GPCRs, receptor ubiquitination promotes degradation of agonist-activated receptors in the lysosomes. Other proteins also play important roles in desensitization, including phosphodiesterases, RGS family proteins and A-kinase-anchoring proteins. Together, this intricate network of kinases, ubiquitin ligases, and adaptor proteins orchestrate the acute and prolonged desensitization of GPCRs.     

Dissociation of beta-arrestin from internalized bradykinin B2 receptor is necessary for receptor recycling and resensitization

Beta-arrestins are multifunctional adaptors that bind agonist-activated G protein-coupled receptors (GPCRs), mediate their desensitization and internalization, and control the rate at which receptors recycle back at the plasma membrane ready for subsequent stimulation. The activation of the bradykinin (BK) type 2 receptor (B2R) results in the rapid desensitization and internalization of the receptor. Little is known, however, about the role of beta-arrestin in regulating the intracellular trafficking and the resensitization of the B2R. Using confocal microscopy, we show that BK stimulation of COS-7 cells expressing B2R induces the colocalization of the agonist-activated receptor with beta-arrestin into endosomes. Fluorescent imaging and ligand binding experiments also reveal that upon agonist removal, beta-arrestin rapidly dissociates from B2R into endosomes, and that receptors return back to the plasma membrane, fully competent for reactivating B2R signaling as measured by NO production upon a second BK challenge. However, when the receptor is mutated in its C-terminal domain to increase its avidity for beta-arrestin, B2R remains associated with beta-arrestin into endosomes, and receptors fail to recycle to the plasma membrane postagonist wash. Similarly, the recycling of receptors is prevented when a beta-arrestin mutant exhibiting increased avidity for agonist-bound GPCRs is expressed with B2R. Stabilizing receptor/beta-arrestin complexes into endosomes results in the dampening of the BK-mediated NO production. These results provide evidence for the involvement of beta-arrestin in the intracellular trafficking of B2R, and highlight the importance of receptor recycling in reestablishing B2R signaling.