Agonist-mediated downregulation of G alpha i via the alpha 2-adrenergic receptor is targeted by receptor-Gi interaction and is independent of receptor signaling and regulation.

One mechanism of long-term agonist-promoted desensitization of alpha2AR function is downregulation of the cellular levels of the alpha subunit of the inhibitory G protein, Gi. In transfected CHO cells expressing the human alpha2AAR, a 40.1 +/- 3.3% downregulation of Galphai2 protein occurred after 24 h of exposure of the cells to epinephrine, which was not accompanied by a decrease in Galphai2 mRNA. The essential step that targets Gi for degradation by agonist occupancy of the receptor was explored using mutated alpha2AAR lacking specific structural or functional elements. These consisted of 5HT1A receptor and beta2AR sequences substituted at residues 113-149 of the second intracellular loop and 218-235 and 355-371 of the N- and C-terminal regions of the third intracellular loop (altered Gi and Gs coupling), deletion of Ser296-299 (absent GRK phosphorylation), and substitution of Cys442 (absent palmitoylation and receptor downregulation). Of these mutants, only those with diminished Gi coupling displayed a loss of agonist-promoted Gi downregulation, thus excluding Gs coupling and receptor downregulation, palmitoylation, and phosphorylation as necessary events. Furthermore, coupling-impaired receptors consisting of mutations in the second or third loops ablated Gi downregulation, suggesting that a discreet structural motif of the receptor is unlikely to represent a key element in the process. While pertussis toxin ablated Gi downregulation, blocking downstream intracellular consequences of alpha2AAR activation or mimicking these pathways by heterologous means failed to implicate cAMP/adenylyl cyclase, phospholipase C, phospholipase D, or MAP kinase pathways in alpha2AAR-mediated Gi downregulation. Taken together, agonist-promoted Gi downregulation requires physical alpha2AAR-Gi interaction which targets Gi for degradation in a manner that is independent of alpha2AAR trafficking, regulation, or second messengers.

Phosphorylation and functional desensitization of the alpha2A-adrenergic receptor by protein kinase C.

We have investigated the potential for protein kinase C (PKC) to phosphorylate and desensitize the alpha2A-adrenergic receptor (alpha2AAR). In whole-cell phosphorylation studies, recombinantly expressed human alpha2AAR displayed an increase in phosphorylation after short-term exposure to 100 nM phorbol 12-myristate-13-acetate (PMA) that was blocked by preincubation with a PKC inhibitor. This increase in receptor phosphorylation over basal amounted to 172 +/- 40% in COS-7 cells and 201 +/- 40% in Chinese hamster ovary cells. In permanently transfected Chinese hamster fibroblast cells, PKC activation by brief exposure of the cells to PMA resulted in a marked desensitization of alpha2AAR function, amounting to a 68 +/- 4% decrease in the maximal agonist (UK14304)-stimulated intracellular calcium release. Such desensitization was blocked by the PKC inhibitor bisindolylmaleimide I and was not evoked by an inactive phorbol ester. The desensitization of this agonist response was not caused by PKC-mediated augmentation of G protein-coupled receptor kinase activity, because PMA-promoted desensitization of a mutated alpha2AAR that lacked G protein-coupled receptor kinase phosphorylation sites was identical to that of wild-type alpha2AAR. To test whether PKC phosphorylation is a mechanism by which alpha2AAR can be regulated by other receptors, the alpha1bAR was co-expressed with the alpha2AAR in Chinese hamster ovary cells. Upon selective activation of alpha1bAR, the function of alpha2AAR underwent a 53 +/- 5% desensitization. Thus, cellular events that result in PKC activation promote phosphorylation of the alpha2AAR and lead to substantial desensitization of receptor function. This heterologous regulation also represents a mechanism by which rapid crosstalk between the alpha2AAR and other receptors can occur.

Role of beta ARK in long-term agonist-promoted desensitisation of the beta 2-adrenergic receptor.

Phosphorylation of the beta 2-adrenergic receptor (beta 2AR) is the initial event that underlies rapid agonist-promoted desensitisation. However, the role of phosphorylation in mediating long-term beta 2AR desensitisation is not known. To investigate this possibility, we performed intact cell phosphorylation studies with COS-7 cells transiently expressing an epitope tagged wild-type beta 2AR and found that receptor phosphorylation in cells treated with 1 microM isoproterenol for 24 h was approximately 4-fold over the basal state. This finding suggested that persistent phosphorylation of the receptor might contribute to functional long-term desensitisation which we further explored with mutated beta 2AR lacking the determinants of phosphorylation by the beta AR kinase (beta ARK), PKA or both. In CHW cells expressing the WT beta 2AR, pretreatment with 1 microM isoproterenol for 24 h reduced the isoproterenol-stimulated cAMP response by 82 +/- 5%. Substitution of the PKA sites with alanines had no effect on the extent of desensitisation (77 +/- 6%, P = NS compared to WT). In contrast, desensitisation was only 49 +/- 4% (P < 0.001 compared to WT) when the beta ARK sites were similarly substituted. Removal of both the beta ARK and PKA sites impaired desensitisation to the same extent as the beta ARK mutant. The extent of receptor loss (downregulation) was the same among all of the cell lines used and therefore could not account for the observed differences in desensitisation. Cellular beta ARK activity, assessed by a rhodopsin phosphorylation assay, was equivalent in all cell lines and was unaffected by agonist treatment. PKA activity, however, was dynamically regulated, increasing 4-fold over basal levels after 15 min of isoproterenol and returning to near basal levels after 24 h. The lower level of PKA activity after long-term agonist exposure may therefore have contributed to the apparent lack of effect of removing PKA sites. Nonetheless, long-term desensitisation was clearly attenuated with beta 2AR lacking beta ARK phosphorylation sites. These findings show that in addition to its role in regulating short-term desensitisation, beta ARK-mediated phosphorylation is an important mechanism underlying long-term desensitisation of the beta 2AR as well.

Role of the amino terminus of the third intracellular loop in agonist-promoted downregulation of the alpha2A-adrenergic receptor.

A prominent feature of long-term regulation of the alpha2A-adrenergic receptor (alpha2AAR) is a loss of cellular receptors over time (downregulation). The molecular determinants of downregulation were sought by targeting regions of the receptor involved in G protein coupling and phosphorylation. Mutated receptors, consisting of chimeric substitutions of analogous beta2-adrenergic receptor (beta2AR) and serotonin 5-hydroxytryptamine1A (5-HT1A) receptor sequence into the second intracellular loop (ICL2) (residues 113-149), the amino terminus (residues 218-235) and carboxy terminus (residues 355-371) of ICL3, and a deletion of the beta-adrenergic receptor kinase (betaARK) phosphorylation sites in the third intracellular loop (ICL3) (residues 293-304), were expressed in Chinese hamster ovary (CHO) cells. Wild-type alpha2AAR underwent 31% +/- 3% downregulation after 24 h of exposure to 100 microM epinephrine. Loss of downregulation was observed with some mutants, but this was not related to functional coupling to inhibitory or stimulatory guanine nucleotide regulatory binding proteins (Gi or GS) or to phosphorylation. Rather, any mutant with a substitution of the amino terminus of ICL3 (regardless of whether the substitution was with beta2AR or 5-HT1A sequence) resulted in upregulation. Studies with an inhibitor of protein synthesis indicated that the primary mechanism of downregulation of the alpha2AAR is agonist-promoted degradation of receptor protein which requires a destabilization sequence in the amino terminus of ICL3. Thus, in contrast to other G protein-coupled receptors, in which G protein coupling or phosphorylation are critical for long-term agonist regulation, the alpha2AAR has a specific structural domain distinct from these other functional regions that serves to direct agonist-promoted downregulation.

mu-Opioid agonists stimulate growth hormone secretion in immature rats.

The purpose of the present study was to evaluate the opioid receptor subtype mediating opioid modulation of growth hormone (GH) secretion during ontogeny. The mu-agonist morphine and the kappa agonist U50,488 caused a stimulation and inhibition of GH secretion, respectively, on postnatal day 10. Studies on postnatal days 2, 5, 10, 15 and 20 showed that kappa-inhibition could be observed as early as day 2, but substantial mu-stimulation was not observed until postnatal day 10. Intracerebroventricular (i.c.v.) administration of the mu-selective peptide [D-Ala2-NMe-Phe4-Gly-ol]-enkephalin (DAMGO) elicited a marked rise in GH secretion, while administration of the delta-agonists [D-pen2D-pen5]-enkephalin (DPDPE) or deltorphin II caused only a minor and non-dose-related rise in GH secretion in neonatal rats. The relative importance of mu- and delta-receptors in stimulating GH secretion was also studied in older pups (day 20). i.c.v. administration of DAMGO stimulated GH secretion, while neither DPDPE nor deltorphin II consistently increased GH secretion. Furthermore, peripheral administration of either morphine or the highly selective mu-agonist sufentanil elicited marked GH secretion on postnatal day 20, but only combined administration of the mu-antagonist beta-funaltrexamine (beta-FNA) and the delta-antagonist naltrindole substantially diminished these responses. These results suggest that both mu- and kappa-opioid receptors are involved in the regulation of GH secretion in neonatal rats. While delta-receptors do not play a prominent independent role in this response, they may act synergistically with mu-receptors in producing stimulation.

Chimeric mutagenesis of putative G-protein coupling domains of the alpha2A-adrenergic receptor. Localization of two redundant and fully competent gi coupling domains.

We have investigated potential Gi and Gs coupling domains within the intracellular regions of the alpha2AAR subtype using a series of nine chimeric mutations. The second intracellular loop (ICL2, amino acids 133-149) and the amino- and carboxyl-terminal regions of the third intracellular loop (ICL3, amino acids 218-235 and 355-371, respectively) of the cloned human alpha2AAR were substituted with the analogous sequence from either the Gs-coupled beta2AR or the Gi-coupled serotonin type 1A receptor (5-HT1AR). Mutant and wild type alpha2AAR were stably expressed in Chinese hamster ovary cells and functional coupling of each receptor to Gi and Gs was assessed in membrane adenylyl cyclase assays. Substitution of 5-HT1AR sequence into ICL2 ablated coupling to Gs but not to Gi, whereas substitution of beta2AR sequence significantly depressed coupling to Gi but not to Gs. Thus, the ICL2 of the alpha2AAR contains elements essential for both signaling pathways. Substitution of either the amino- or carboxyl-terminal segments of ICL3 with 5-HT1AR sequence ablated agonist stimulation of adenylyl cyclase activity (without affecting inhibition), suggesting that both domains are necessary for alpha2AAR coupling to Gs. In contrast, individual substitution of beta2AR sequence into ICL3 amino or carboxyl termini had no appreciable effect on Gi coupling. Concomitant substitution of beta2AR sequence into both regions substantially impaired Gi coupling, implying that each is capable of independently supporting functional coupling. Substitution of 5-HT1AR at either locus had no effect on Gi coupling. Thus, for Gs coupling, these two domains within ICL3 are both required for functional coupling. However, for Gi coupling, the alpha2AAR appears to have two distinct regions within ICL3 that are capable of supporting Gi coupling independently. There has been no previous elucidation of a receptor having redundant, fully competent domains for coupling to a single class of G-protein. Such duplicity of functional domains within alpha2AR may suggest strong evolutionary pressure to maintain Gi coupling.

Identification of a Gs coupling domain in the amino terminus of the third intracellular loop of the alpha 2A-adrenergic receptor. Evidence for distinct structural determinants that confer Gs versus Gi coupling.

alpha2-Adrenergic receptors (alpha 2AR) functionally couple not only to Gi but also to Gs. We investigated the amino-terminal portion of the third intracellular loop of the human alpha 2AAR (alpha 2C10) for potential Gs coupling domains using site-directed mutagenesis and recombinant expression in several different cell types. A deletion mutant and four chimeric receptors consisting of the alpha 2AAR with the analogous sequence from the 5-HT1A receptor (a Gi-coupled receptor) and the beta 2AR (a Gs-coupled receptor) were expressed in Chinese hamster ovary cells, Chinese hamster fibroblasts, or COS-7 cells and examined for their ability to mediate stimulation or inhibition of membrane adenylyl cyclase activity or whole cell cAMP accumulation. In stably expressing Chinese hamster ovary cells, deletion of amino acids 221-231, which are in close proximity to the fifth transmembrane domain, eliminated alpha 2C10-mediated stimulation of adenylyl cyclase activity, while alpha 2C10-mediated inhibition was only moderately affected. This suggested that this region is important for Gs coupling, prompting construction of the chimeric receptor mutants. Substitution of amino acids 218-235 with 5-HT1A receptor sequence entirely ablated agonist-promoted Gs coupling, as compared with a 338 +/- 29% stimulation of adenylyl cyclase activity observed with the wild-type alpha 2C10. In contrast, Gi coupling for this mutant remained fully intact (57 +/- 2% versus 52 +/- 1% inhibition for wild-type alpha 2C10). Similar substitution with beta 2AR sequence had no effect on Gi coupling but did reduce Gs coupling. Two additional mutated alpha 2C10 containing smaller substitutions of the amino-terminal region with 5-HT1A receptor sequence at residues 218-228 or 229-235 were then studied. While Gi coupling remained intact with both mutants, Gs coupling was ablated in the former but not the latter mutant receptor. Similar results were obtained using transfected Chinese hamster fibroblasts (which exclusively display alpha 2AR-Gi coupling) and COS-7 cells (which exclusively display alpha 2AR-Gs coupling). Thus, a critical determinant for Gs coupling is contained within 11 amino acids (218-228) of the amino-terminal region of the third intracellular loop localized directly adjacent to the fifth transmembrane domain. Taken together, these studies demonstrate the presence of a discrete structural determinant for agonist-promoted alpha 2AR-Gs coupling, which is distinct and separable from the structural requirements for alpha 2AR-Gi coupling.

Four consecutive serines in the third intracellular loop are the sites for beta-adrenergic receptor kinase-mediated phosphorylation and desensitization of the alpha 2A-adrenergic receptor.

During short term agonist exposure, the alpha 2A-adrenergic receptor (alpha 2AAR) undergoes rapid functional desensitization caused by phosphorylation of the receptor by the beta-adrenergic receptor kinase (beta ARK). This signal quenching is similar in nature to that found with a number of G-protein coupled receptors in which agonist-promoted desensitization is due to beta ARK phosphorylation; like these other receptors, the precise molecular determinants of the receptor required for beta ARK phosphorylation are not known. To delineate such a motif in the human alpha 2AAR (alpha 2C10), we constructed six mutated receptors consisting of deletions or substitutions of Ser-296-299 in the EESSSS sequence of the third intracellular loop of the receptor. These were expressed in Chinese hamster ovary and COS-7 cells, and agonist-promoted desensitization and receptor phosphorylation were assessed. Deletion of the EESSSS sequence and substitution of alanine for all four serines resulted in a total loss of phosphorylation and desensitization. Mutant receptors that retained two of the original serines (AASS and SSAA) underwent agonist-promoted phosphorylation of 55 +/- 7% and 57 +/- 8% of the phosphorylation found for wild type alpha 2C10. Additional substitution mutants (SSSA and SAAA) underwent 77 +/- 1% and 27 +/- 4% of wild type phosphorylation, respectively. Thus, substitution of alanine for each additional serine decreased overall phosphorylation as compared with wild type alpha 2C10 by approximately 25%, which is consistent with all 4 serines being phosphorylated. Mutated receptors that only partially phosphorylated (as compared with wild type) failed to undergo agonist-promoted desensitization. Thus, beta ARK-mediated phosphorylation of alpha 2C10 occurs at Ser-296-299 in the third intracellular loop, and this represents the critical step in rapid agonist-promoted desensitization. A number of other G-protein coupled receptors that undergo desensitization have a sequence motif similar to that which we have found for beta ARK-mediated phosphorylation of alpha 2C10, suggesting that these receptors may also be substrates for beta ARK.

The palmitoylated cysteine of the cytoplasmic tail of alpha 2A-adrenergic receptors confers subtype-specific agonist-promoted downregulation.

Most guanine nucleotide binding protein (G protein)-coupled receptors have a conserved cysteine in the C-terminal cytoplasmic tail near the seventh transmembrane spanning region. This cysteine is known to be palmitoylated in rhodopsin, the beta 2-adrenergic receptor (beta 2AR) and the alpha 2A-adrenergic receptor (alpha 2AAR). For the beta 2AR, this cysteine has been shown to be important for stimulatory G protein (Gs) coupling and agonist-promoted desensitization. For the alpha 2AAR (human alpha 2 C10) palmitoylation occurs at Cys-442, but it is not known what function such fatty acid acylation subserves. The closely related alpha 2CAR subtype denoted alpha 2C4 lacks a cysteine in this region and has different G-protein-coupling characteristics and agonist regulatory properties as compared to alpha 2C10. To assess the role of the palmitoylcysteine in alpha 2AR function, we constructed a mutated alpha 2C10 having a phenylalanine (the analogous amino acid in the alpha 2C4 in this position) substituted for Cys-442, denoted alpha 2C10(Phe-442), and expressed this along with wild-type alpha 2C10 and alpha 2C4 in CHO cells. Functional coupling to inhibitory G protein (Gi) and to Gs was identical between wild-type alpha 2C10 and alpha 2C10(Phe-442). Agonist-promoted desensitization of both the Gi and Gs-mediated pathways was also found to be unaffected by this mutation. Cellular trafficking induced by agonist exposure was evaluated by delineation of intracellular (sequestered) versus cell surface receptors and by determination of net receptor loss. Mutation of Cys-442 did not alter the extent or rate of agonist-promoted sequestration induced by agonists or the recovery from sequestration. However, the downregulation of receptor number after prolonged agonist exposure was completely abolished by this mutation and converted alpha 2C10 to an alpha 2C4 phenotype in regard to this adaptive response. Another mutated alpha 2C10, in which Cys-442 was replaced by alanine, also failed to downregulate. Thus, the function of this cytoplasmic palmitoylcysteine is distinctly different between the alpha 2AR and other G-protein-coupled receptors such as the beta 2AR and rhodopsin, and this suggests that this molecular attribute may subserve diverse roles among members of this family of receptors. For the alpha 2ARs, this may represent an evolved feature that provides for differing needs for regulation of the alpha 2C10 and alpha 2C4 subtypes by agonist.

Contribution of ligand structure to activation of alpha 2-adrenergic receptor subtype coupling to Gs.

Recently, we have demonstrated that alpha 2-adrenergic receptors (alpha 2AR) functionally couple not only to Gi but also to Gs. This alpha 2AR-Gs coupling was subtype selective, in that the degree of alpha 2AR-Gs (but not -Gi) coupling was different between alpha 2AR subtypes. It is not known whether the determinants of this subtype selectively are found within the ligand-binding region of the receptor or within the intracellular G protein-coupling domains of the individual subtypes. We therefore expressed the three cloned human alpha 2AR (alpha 2C10, alpha 2C4, and alpha 2C2) in Chinese hamster ovary cells and studied the contribution of the ligand-binding domain to functional Gi versus Gs coupling, by determining the ability of various agonists (catecholamines, imidazolines, and azepines) to elicit alpha 2AR-mediated inhibition and stimulation of adenylyl cyclase activity. Isolation of Gi and Gs responses was accomplished by incubating cells with cholera or pertussis toxin, respectively. Although each compound was found to be a full agonist for alpha 2AR-Gi coupling, the efficacy of these agonists to elicit alpha 2AR-Gs coupling was markedly different, not only among drugs but also among the three alpha 2AR subtypes. The most notable differences occurred with the imidazoline agonists. Specifically, oxymetazoline stimulated adenylyl cyclase activity 210 +/- 17% for alpha 2C2 and 22 +/- 2.6% for alpha 2C10 and displayed no stimulation for alpha 2C4. UK-14304 stimulated adenylyl cyclase activity 240 +/- 16% for alpha 2C10, 160 +/- 14% for alpha 2C4, and 86 +/- 9% for alpha 2C2. Overall, the rank order of efficacy of these agonists to elicit stimulation of adenylyl cyclase activity by alpha 2C10 was epinephrine = norepinephrine = UK-14304 > BHT-933 > BHT-920 > oxymetazoline. For alpha 2C4 the rank was epinephrine = norepinephrine = UK-14304, with oxymetazoline, BHT-920, and BHT-933 not eliciting any stimulation. For alpha 2C2 the rank was epinephrine = norepinephrine > oxymetazoline > UK-14304 = BHT-920 > BHT-933. Thus, the coupling of alpha 2AR subtypes to Gs occurs with endogenous catecholamines as well as multiple synthetic agonists, and the degree of Gs coupling is highly dependent on the structure of the agonist. Also, compounds that act as full agonists for Gi coupling are not necessarily full agonists for Gs coupling.

Human alpha 2-adrenergic receptor subtype distribution: widespread and subtype-selective expression of alpha 2C10, alpha 2C4, and alpha 2C2 mRNA in multiple tissues.

At present, molecular cloning and pharmacological studies have delineated three human alpha 2-adrenergic receptor (alpha 2AR) subtypes, alpha 2C10, alpha 2C4, and alpha 2C2. Assignment of the alpha 2AR subtypes to specific functions has been limited by an unclear definition of tissue alpha 2AR expression outside of the central nervous system. It has been suggested that alpha 2C4 expression is confined to the brain, that alpha 2C2 expression is only in the liver and kidney, and that there is nearly ubiquitous expression of alpha 2C10. However, this is based on studies of a limited number of rat tissues or on studies using non-species-specific approaches. Therefore, to define alpha 2C10, alpha 2C4, and alpha 2C2 tissue expression, we used reverse transcription of total RNA isolated from 20 human tissues, followed by amplification of alpha 2AR cDNA using the polymerase chain reaction. This technique provided two advantages: high sensitivity and, with the use of subtype-specific oligonucleotide primers and probes, differentiation between the alpha 2AR subtypes. The tissues studied were aorta, vena cava, heart (epicardium and endocardium), lung, skeletal muscle, liver, pancreas (head and tail), fat (perinephric and subcutaneous), kidney (cortex and medulla), prostate, stomach, ileum, jejunum, colon, adrenal gland, and spleen. We found that the majority of these tissues expressed alpha 2C10, with the exceptions being the head of the pancreas, subcutaneous fat, colon, and spleen. In marked distinction to other studies, however, we found a prolific expression of the alpha 2C4 and alpha 2C2 subtypes. Expression of alpha 2C4 was found in all tissues with the exception of liver, fat, stomach, and colon, and a virtually ubiquitous expression of alpha 2C2 was found, with the exception of epicardium. Of all tissues studied, only colon and subcutaneous fat expressed a single alpha 2AR subtype, which was alpha 2C2. Thus, the alpha 2AR subtypes do not have a confined expression but appear to be widely distributed in humans and display subtype-specific expression in some tissues.

Functional alpha 2-adrenergic receptor-Gs coupling undergoes agonist-promoted desensitization in a subtype-selective manner.

Recently it has become clear that alpha 2-adrenergic receptors (alpha 2AR) functionally couple to Gs as well as Gi, thus inducing a complex modulation of adenylyl cyclase activity. It is unknown whether alpha 2AR-Gs coupling undergoes agonist-promoted desensitization. Therefore, in CHO cells expressing the three cloned human alpha 2AR subtypes (alpha 2C10, alpha 2C4, and alpha 2C2), we assessed the ability of alpha 2AR-mediated stimulation of adenylyl cyclase activity to undergo short-term agonist-promoted desensitization. To isolate alpha 2AR-Gs coupling, cells were pretreated with pertussis toxin, which ablates Gi coupling. Following agonist exposure, both alpha 2C10- and alpha 2C2-mediated stimulation of adenylyl cyclase activity underwent marked desensitization. In distinct contrast, alpha 2C4-mediated stimulation of adenylyl cyclase activity underwent no agonist-promoted desensitization. Thus, alpha 2AR-Gs coupling undergoes agonist-promoted desensitization and does so in a subtype-selective manner.

Subtype-selective desensitization of alpha 2-adrenergic receptors. Different mechanisms control short and long term agonist-promoted desensitization of alpha 2C10, alpha 2C4, and alpha 2C2.

We have recently shown that the alpha 2C10 adrenergic receptor (AR) undergoes short term agonist-promoted desensitization, mediated by phosphorylation of sites in the third intracellular loop. There is significant divergence in the third loop amino acid sequences between alpha 2C10 and the other subtypes, alpha 2C4 and alpha 2C2. We therefore explored the mechanisms of alpha 2AR subtype desensitization by expressing each human subtype in Chinese hamster ovary cells and subjecting them to short and long term epinephrine exposures. After 30 min of agonist exposure, alpha 2C10 and alpha 2C2 displayed desensitization characterized by rightward shifts in the curves for epinephrine-mediated inhibition of adenylyl cyclase (EC50 = alpha 2C10, 0.24 +/- 0.02 microM increasing to 1.1 +/- 0.1 microM; alpha 2C2, 1.3 +/- 0.3 increasing to 2.6 +/- 0.3 microM). Coincident with alpha 2C10 and alpha 2C2 desensitizations were decreases in agonist high affinity binding. In contrast, alpha 2C4 underwent no functional desensitization after short term agonist exposure, nor were there any changes in agonist high affinity binding. Agonist-promoted receptor sequestration was clearly greater with alpha 2C10 (approximately 26%) and alpha 2C2 (approximately 35%) as compared to alpha 2C4 (approximately 12%), but such sequestration did not play a significant role in short term desensitization, as blockade with concanavalin A had no effect on desensitization patterns. In contrast to these findings, all alpha 2AR subtypes underwent desensitization after prolonged (24 h) agonist exposure. However, alpha 2C10 and alpha 2C2 displayed substantially more desensitization (approximately 20-fold increase in EC50) as compared to alpha 2C4 (approximately 5-fold increase). The primary mechanism of desensitization during long term agonist exposure was found to be a decrease in the amount of cellular Gi, which was equivalent in magnitude in cells expressing all three subtypes. However, in addition to a decrease in Gi, alpha 2C10 and alpha 2C2 underwent down-regulation of receptor levels during long term agonist exposure, while alpha 2C4 did not. Given that all three subtypes bind endogenous catecholamines with high affinity and inhibit adenylyl cyclase efficiently, the significance of multiple subtypes has heretofore been obscure. Our results show that alpha 2AR undergo subtype-selective desensitization to agonists and suggest that alpha 2AR subtypes may have evolved to meet differing needs for adaptive regulation.

Simultaneous coupling of alpha 2-adrenergic receptors to two G-proteins with opposing effects. Subtype-selective coupling of alpha 2C10, alpha 2C4, and alpha 2C2 adrenergic receptors to Gi and Gs.

Coupling of the three alpha 2-adrenergic receptor (alpha 2AR) subtypes to Gi and Gs was studied in membranes from transfected CHO cells. We observed that in the presence of low concentrations of the alpha 2AR agonist UK-14304, alpha 2C10 mediated inhibition of adenylyl cyclase activity, whereas at high concentrations of agonist, alpha 2C10 mediated stimulation of adenylyl cyclase activity. We considered that this biphasic response was due to the coupling of alpha 2C10 to both Gi and Gs. To isolate functional Gs and Gi coupling, cells were treated with pertussis toxin or cholera toxin in doses sufficient to fully ADP-ribosylate the respective G-proteins. Following treatment with cholera toxin, agonists elicited only alpha 2C10-mediated inhibition (approximately 50%) of adenylyl cyclase while after pertussis toxin treatment, agonists elicited only alpha 2C10-mediated stimulation (approximately 60%) of adenylyl cyclase. Incubation of membranes with antisera directed against the carboxyl-terminal portion of Gs alpha blocked this functional alpha 2AR.Gs coupling to the same extent as that found for beta 2AR.Gs coupling. In addition to functional Gs coupling, we also verified direct, agonist-dependent, physical coupling of alpha 2AR to Gs alpha. In agonist-treated membranes, an agonist-receptor-Gs alpha complex was immunoprecipitated with a specific alpha 2C10 antibody, and the Gs component identified by both western blots using Gs alpha antibody, and cholera toxin mediated ADP-ribosylation. Due to the differences in primary amino acid structure in a number of regions of the alpha 2AR subtypes, we investigated whether G-protein coupling was subtype-selective, using UK-14304 and cells with the same alpha 2AR expression levels (approximately 5 pmol/mg). Coupling to Gi was equivalent for alpha 2C10, alpha 2C4, and alpha 2C2: 53.4 +/- 8.8% versus 54.9 +/- 1.0% versus 47.6 +/- 3.5% inhibition of adenylyl cyclase, respectively. In marked contrast, distinct differences in coupling to Gs were found between the three alpha 2AR subtypes: stimulation of adenylyl cyclase was 57.9 +/- 6.3% versus 30.7 +/- 1.1% versus 21.8 +/- 1.7% for alpha 2C10, alpha 2C4, and alpha 2C2, respectively. Thus, alpha 2AR have the potential to couple physically and functionally to both Gi and Gs; for Gi coupling we found a rank order of alpha 2C10 = alpha 2C4 = alpha 2C2, while for Gs coupling, alpha 2C10 greater than alpha 2C4 greater than alpha 2C2.