EC:2.7.10.1 - FACTA Search

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Query: EC:2.7.10.1 (ERK)
95,504 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Dopamine D(2) and D(3) receptors (D(2)R/D(3)R), which have similar structural architecture as well as functional similarities, are expressed in the same brain dopaminergic neurons. It is intriguing that two receptor proteins with virtually the same functional roles are expressed in the same neuron. Recently we have shown that D(2)R and D(3)R possess different regulatory processes including intracellular trafficking properties, which implies that they might employ different signaling mechanisms for regulation of the same cellular processes. Here we studied the signaling pathways of ERK activation mediated by D(2)R and D(3)R in HEK-293 cells and corroborated them with concomitant studies in COS-7 cells and C6 cells. Our results show that Src, phosphatidylinositol 3-kinase, and atypical protein kinase C were commonly involved in D(2)R-/D(3)R-mediated ERK activation. However, beta-arrestin and sequestration of D(2)R/D(3)R were found not to be involved. ERK activations mediated by D(3)R, but not D(2)R, were blocked by betaARK-CT, AG1478 epidermal growth factor receptor (EGFR) inhibitor, and by dominant negative mutants of Ras and Raf, suggesting the involvement of the Gbetagamma(i) pathway. The alpha-subunit of G(o) (Galpha(o)) was able to couple with D(3)R to mediate ERK activation. We conclude that D(3)R mainly utilizes the betagamma pathway of G(i) protein, which involves the transactivation of EGFR in HEK-293 cells. In contrast, the alpha-subunit of the G(i) protein plays a main role in D(2)R-mediated ERK activation. Our study suggests one example of intricate cellular regulations in the brain, that is, dopaminergic neurons could regulate ERK activity more flexibly through alternative usage of either the D(2)R or D(3)R pathway depending on the cellular situation.
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PMID:Comparative studies of molecular mechanisms of dopamine D2 and D3 receptors for the activation of extracellular signal-regulated kinase. 1510 43

The orexin-1 receptor interacts with beta-arrestin-2 in an agonist-dependent manner. In HEK-293T cells, these two proteins became co-internalized into acidic endosomes. Truncations from the C-terminal tail did not prevent agonist-induced internalization of the orexin-1 receptor or alter the pathway of internalization, although such mutants failed to interact with beta-arrestin-2 in a sustained manner or produce its co-internalization. Mutation of a cluster of three threonine and one serine residue at the extreme C-terminus of the receptor greatly reduced interaction and abolished co-internalization of beta-arrestin-2-GFP (green fluorescent protein). Despite the weak interactions of this C-terminally mutated form of the receptor with beta-arrestin-2, studies in wild-type and beta-arrestin-deficient mouse embryo fibroblasts confirmed that agonist-induced internalization of this mutant required expression of a beta-arrestin. Although without effect on agonist-mediated elevation of intracellular Ca2+ levels, the C-terminally mutated form of the orexin-1 receptor was unable to sustain phosphorylation of the MAPKs (mitogen-activated protein kinases) ERK1 and ERK2 (extracellular-signal-regulated kinases 1 and 2) to the same extent as the wild-type receptor. These studies indicate that a single cluster of hydroxy amino acids within the C-terminal seven amino acids of the orexin-1 receptor determine the sustainability of interaction with beta-arrestin-2, and indicate an important role of beta-arrestin scaffolding in defining the kinetics of orexin-1 receptor-mediated ERK MAPK activation.
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PMID:The sustainability of interactions between the orexin-1 receptor and beta-arrestin-2 is defined by a single C-terminal cluster of hydroxy amino acids and modulates the kinetics of ERK MAPK regulation. 1568 63

Dysregulation of dopamine receptors (DARs) is believed to contribute to Parkinson disease (PD) pathology. G protein-coupled receptors (GPCR) undergo desensitization via activation-dependent phosphorylation by G protein-coupled receptor kinases (GRKs) followed by arrestin binding. Using quantitative Western blotting, we detected profound differences in the expression of arrestin2 and GRKs among four experimental groups of nonhuman primates: (1) normal, (2) parkinsonian, (3) parkinsonian treated with levodopa without or (4) with dyskinesia. Arrestin2 and GRK6 expression was significantly elevated in the MPTP-lesioned group in most brain regions; GRK2 was increased in caudal caudate and internal globus pallidus. Neither levodopa-treated group differed significantly from control. The only dyskinesia-specific change was an elevation of GRK3 in the ventral striatum of the dyskinetic group. Changes in arrestin and GRK expression in the MPTP group were accompanied by enhanced ERK activation and elevated total ERK expression, which were also reversed by L-DOPA. The data suggest the involvement of arrestins and GRKs in Parkinson disease pathology and the effects of levodopa treatment.
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PMID:L-DOPA reverses the MPTP-induced elevation of the arrestin2 and GRK6 expression and enhanced ERK activation in monkey brain. 1568 61

Angiotensin II type 1a (AT1a), vasopressin V2, and neurokinin 1 (NK1) receptors are seven-transmembrane receptors (7TMRs) that bind and co-internalize with the multifunctional adaptor protein, beta-arrestin. These receptors also lead to robust and persistent activation of extracellular-signal regulated kinase 1/2 (ERK1/2) localized on endosomes. Recently, the co-trafficking of receptor-beta-arrestin complexes to endosomes was demonstrated to require stable beta-arrestin ubiquitination (Shenoy, S. K., and Lefkowitz, R. J. (2003) J. Biol. Chem. 278, 14498-14506). We now report that lysines at positions 11 and 12 in beta-arrestin2 are specific and required sites for its AngII-mediated sustained ubiquitination. Thus, upon AngII stimulation the mutant beta-arrestin2(K11,12R) is only transiently ubiquitinated, does not form stable endocytic complexes with the AT1aR, and is impaired in scaffolding-activated ERK1/2. Fusion of a ubiquitin moiety in-frame to beta-arrestin2(K11,12R) restores AngII-mediated trafficking and signaling. Wild type beta-arrestin2 and beta-arrestin2(K11R,K12R)-Ub, but not beta-arrestin2(K11R,K12R), prevent nuclear translocation of pERK. These findings imply that sustained beta-arrestin ubiquitination not only directs co-trafficking of receptor-beta-arrestin complexes but also orchestrates the targeting of "7TMR signalosomes" to microcompartments within the cell. Surprisingly, binding of beta-arrestin2(K11R,K12R) to V2R and NK1R is indistinguishable from that of wild type beta-arrestin2. Moreover, ubiquitination patterns and ERK scaffolding of beta-arrestin2(K11,12R) are unimpaired with respect to V2R stimulation. In contrast, a quintuple lysine mutant (beta-arrestin2(K18R,K107R,K108R,K207R,K296R)) is impaired in endosomal trafficking in response to V2R but not AT1aR stimulation. Our findings delineate a novel regulatory mechanism for 7TMR signaling, dictated by the ubiquitination of beta-arrestin on specific lysines that become accessible for modification due to the specific receptor-bound conformational states of beta-arrestin2.
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PMID:Receptor-specific ubiquitination of beta-arrestin directs assembly and targeting of seven-transmembrane receptor signalosomes. 1569 45

beta-Arrestins regulate the functioning of G protein-coupled receptors in a variety of cellular processes including receptor-mediated endocytosis and activation of signaling molecules such as ERK. A key event in these processes is the G protein-coupled receptor-mediated recruitment of beta-arrestins to the plasma membrane. However, despite extensive knowledge in this field, it is still disputable whether activation of signaling pathways via beta-arrestin recruitment entails paired activation of receptor dimers. To address this question, we investigated the ability of different muscarinic receptor dimers to recruit beta-arrestin-1 using both co-immunoprecipitation and fluorescence microscopy in COS-7 cells. Experimentally, we first made use of a mutated muscarinic M(3) receptor, which is deleted in most of the third intracellular loop (M(3)-short). Although still capable of activating phospholipase C, this receptor loses almost completely the ability to recruit beta-arrestin-1 following carbachol stimulation in COS-7 cells. Subsequently, M(3)-short was co-expressed with the M(3) receptor. Under these conditions, the M(3)/M(3)-short heterodimer could not recruit beta-arrestin-1 to the plasma membrane, even though the control M(3)/M(3) homodimer could. We next tested the ability of chimeric adrenergic muscarinic alpha(2)/M(3) and M(3)/alpha(2) heterodimeric receptors to co-immunoprecipitate with beta-arrestin-1 following stimulation with adrenergic and muscarinic agonists. beta-Arrestin-1 co-immunoprecipitation could be induced only when carbachol or clonidine were given together and not when the two agonists were supplied separately. Finally, we tested the reciprocal influence that each receptor may exert on the M(2)/M(3) heterodimer to recruit beta-arrestin-1. Remarkably, we observed that M(2)/M(3) heterodimers recruit significantly greater amounts of beta-arrestin-1 than their respective M(3)/M(3) or M(2)/M(2) homodimers. Altogether, these findings provide strong evidence in favor of the view that binding of beta-arrestin-1 to muscarinic M(3) receptors requires paired stimulation of two receptor components within the same receptor dimer.
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PMID:Paired activation of two components within muscarinic M3 receptor dimers is required for recruitment of beta-arrestin-1 to the plasma membrane. 1576 45

Various methods reveal that cyclic AMP (cAMP) signalling in cells is compartmentalised. These methods use FRET probes based upon either protein kinase A (PKA) or EPAC, cAMP-gated ion channels, or the selective activation of AKAP-anchored PKA isoforms. The basis of compartmentalisation involves point sources of cAMP generation within sub-domains of the plasma membrane coupled to degradation by spatially segregated, anchored forms of cAMP phosphodiesterases. cAMP-specific phosphodiesterase-4 (PDE4) isoforms play a central role in determining compartmentalisation, as exemplified in cardiac myocytes and T cells. The PKA phosphorylation status of the beta2-adrenoreceptor, and hence its ability to switch its signalling from G(s) to G(i) and thus to activate ERK, is regulated dynamically by the agonist-stimulated recruitment of PDE4 to the receptor in complex with beta-arrestin. The co-receptor CD28 enhances signalling through the T-cell receptor by recruiting a PDE4/beta-arrestin complex, which then attenuates PKA phosphorylation of Csk.
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PMID:Arrestin times for compartmentalised cAMP signalling and phosphodiesterase-4 enzymes. 1578 May 88

Using combined dominant-negative and siRNA (small interfering RNA)-mediated knockdown strategies, the functional importance of specific PDE4 (phosphodiesterase-4) isoforms in modifying signalling through the beta2-AR (beta2-adrenoceptor) has been uncovered. The PDE4D5 isoform preferentially interacts with the signalling scaffold protein beta-arrestin and is thereby recruited to the beta2-AR upon agonist challenge. Delivery of an active PDE to the site of cAMP synthesis at the plasma membrane specifically attenuates the activity of a pool of PKA (protein kinase A) that is tethered to the beta2-AR via AKAP79 (A-kinase anchoring protein 79). The specific functional role of this anchored PKA is to phosphorylate the beta2-AR and allow it to switch its coupling with G(i) and thereby activation of ERK (extracellular-signal-regulated kinase). Our studies uncover a novel facet of the regulation of beta2-AR signalling by showing that beta-arrestin-recruited PDE4 provides the means of desensitizing the agonist-dependent coupling of beta2-AR with G(i) and its consequential activation of ERK.
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PMID:Beta-arrestin-recruited phosphodiesterase-4 desensitizes the AKAP79/PKA-mediated switching of beta2-adrenoceptor signalling to activation of ERK. 1624 12

Physiological effects of beta adrenergic receptor (beta2AR) stimulation have been classically shown to result from G(s)-dependent adenylyl cyclase activation. Here we demonstrate a novel signaling mechanism wherein beta-arrestins mediate beta2AR signaling to extracellular-signal regulated kinases 1/2 (ERK 1/2) independent of G protein activation. Activation of ERK1/2 by the beta2AR expressed in HEK-293 cells was resolved into two components dependent, respectively, on G(s)-G(i)/protein kinase A (PKA) or beta-arrestins. G protein-dependent activity was rapid, peaking within 2-5 min, was quite transient, was blocked by pertussis toxin (G(i) inhibitor) and H-89 (PKA inhibitor), and was insensitive to depletion of endogenous beta-arrestins by siRNA. beta-Arrestin-dependent activation was slower in onset (peak 5-10 min), less robust, but more sustained and showed little decrement over 30 min. It was insensitive to pertussis toxin and H-89 and sensitive to depletion of either beta-arrestin1 or -2 by small interfering RNA. In G(s) knock-out mouse embryonic fibroblasts, wild-type beta2AR recruited beta-arrestin2-green fluorescent protein and activated pertussis toxin-insensitive ERK1/2. Furthermore, a novel beta2AR mutant (beta2AR(T68F,Y132G,Y219A) or beta2AR(TYY)), rationally designed based on Evolutionary Trace analysis, was incapable of G protein activation but could recruit beta-arrestins, undergo beta-arrestin-dependent internalization, and activate beta-arrestin-dependent ERK. Interestingly, overexpression of GRK5 or -6 increased mutant receptor phosphorylation and beta-arrestin recruitment, led to the formation of stable receptor-beta-arrestin complexes on endosomes, and increased agonist-stimulated phospho-ERK1/2. In contrast, GRK2, membrane translocation of which requires Gbetagamma release upon G protein activation, was ineffective unless it was constitutively targeted to the plasma membrane by a prenylation signal (CAAX). These findings demonstrate that the beta2AR can signal to ERK via a GRK5/6-beta-arrestin-dependent pathway, which is independent of G protein coupling.
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PMID:beta-arrestin-dependent, G protein-independent ERK1/2 activation by the beta2 adrenergic receptor. 1628 Mar 23

Beta-arrestin, originally identified as a protein that inhibits heterotrimeric guanine nucleotide-binding protein (G protein) coupling to cognate seven-transmembrane receptors [(7TMRs), also known as G protein-coupled receptors (GPCRs)], is currently being appreciated as a positive signaling mediator for various cell surface receptors. Activation of mitogen-activated protein kinases (MAPKs), especially extracellular signal regulated kinases 1 and 2 (ERK1/2), is a hallmark of intracellular signaling resulting from stimulation of various growth factor receptors, as well as 7TMRs. The resulting ERK activity can occur through multiple parallel or converging mechanisms. Using human embryonic kidney 293 (HEK-293) cells as a model system and utilizing RNA interference technology, two distinct pathways of angiotensin II-mediated ERK activation have been uncovered: (i) a G protein-dependent pathway that produces a transient activation of nuclear ERK and (ii) a beta-arrestin-dependent pathway that leads to sustained activation of ERK that is localized to the cytosol and endosomes. The spatial and temporal segregation of ERK activated by G protein and beta-arrestin pathways suggests that the physiological consequences may be different, and thus ligands that selectively stimulate or inhibit one of these pathways may be therapeutically valuable.
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PMID:Angiotensin II-stimulated signaling through G proteins and beta-arrestin. 1630 60

G protein-coupled delta-opioid receptors (DORs) participate in opioid-mediated analgesia, and chronic opioid application is well known to produce tolerance, limiting the therapeutic use of these drugs. To control and eventually avoid the underlying adaptive mechanisms, several cellular functions were examined with regard to their roles in tolerance development. Specific interest focused on DOR internalization, and the relevant findings are reviewed here. In general, DOR endocytosis is accomplished by complex interactions of various determinants, each having distinct roles in this process. For instance, DOR activation by certain opioids has been shown to turn on the machinery of endocytosis, whereas other opioids stimulate the receptors but fail to bring about internalization. In addition, receptor phosphorylation by different kinases was commonly found to promote DOR sequestration, but receptor internalization also occurs without their phosphorylation. A central role in DOR endocytosis is referred to the adaptor proteins arrestin-2 and arrestin-3, which bind to receptors and subsequently cause the formation of clathrin-coated pits to trigger dynamin-controlled endocytosis. Distinct sorting proteins, kinases, and phosphatases determine whether internalized DORs are delivered either for proteolytic degradation or for recycling, although the underlying mechanisms are hence not clear. Despite intensive studies, understanding of DOR sequestration, degradation, and recycling becomes increasingly difficult. However, the phenomenon of cellular desensitization is recognized to correspond to the loss of responsiveness as consequence of DOR internalization and degradation. In contrast, DOR endocytosis is also discussed to promote resensitization of cells to opioids by recycling of internalized DORs. Even stimulation of extracellular signal-regulated protein kinases (ERK 1/2) may be accomplished by DOR sequestration. However, opposite findings, as well as the fact that multiple cellular mechanisms underly receptor desensitization, resensitization, and ERK activation, questions whether DOR internalization is essential for these processes. Further investigations in both the cellular mechanism and the consequences of DOR endocytosis might thus reveal new aspects of opioid-controlled functions.
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PMID:Mechanism and consequences of delta-opioid receptor internalization. 1630 25

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