Association of the D2 dopamine receptor third cytoplasmic loop with spinophilin, a protein phosphatase-1-interacting protein.

Signaling through D2 class dopamine receptors is crucial to correct brain development and function, and dysfunction of this system is implicated in major neurological disorders such as Parkinson's disease and schizophrenia. To investigate potential novel mechanisms of D2 receptor regulation, the third cytoplasmic loop of the D2 dopamine receptor was used to screen a rat hippocampal yeast two-hybrid library. Spinophilin, a recently characterized F-actin and protein phosphatase-1-binding protein with a single PDZ domain was identified as a protein that specifically associates with this region of D2 receptors. A direct interaction between spinophilin and the D2 receptor was confirmed in vitro using recombinant fusion proteins. The portion of spinophilin responsible for interacting with the D2 third cytoplasmic loop was narrowed to a region that does not include the actin-binding domain, the PDZ domain, or the coiled-coil. This region is distinct from the site of interaction with protein phosphatase-1, and both D2 receptors and protein phosphatase-1 may bind spinophilin at the same time. The interaction is not mediated via the unique 29-amino acid insert in D2long; both D2long and D2short third cytoplasmic loops interact with spinophilin in vitro and in yeast two-hybrid assays. Expression of D2 receptors containing an extracellular hemagglutinin epitope in Madin-Darby canine kidney cells results in co-localization of receptor and endogenous spinophilin as determined by immunocytochemistry using antibodies directed against spinophilin and the HA tag. We hypothesize that spinophilin is important for establishing a signaling complex for dopaminergic neurotransmission through D2 receptors by linking receptors to downstream signaling molecules and the actin cytoskeleton.     

Coupling of dopamine receptors to G proteins: studies with chimeric D2/D3 dopamine receptors

D₂ and D₃ dopamine receptors belong to the superfamily of G protein-coupled receptors; they share a high degree of homology and are structurally similar. However, they differ from each other in their second messenger coupling properties. Previously, we have studied the differential coupling of these receptors to G proteins and found that while D₂ receptor couples only to inhibitory G proteins, D₃ receptor couples also to a stimulatory G protein, Gs. We aimed to investigate the molecular basis of these differences and to determine which domains in the receptor control its coupling to G proteins. For this purpose four chimeras were constructed, each composed of different segments of the original D₂ and D₃ receptors. We have demonstrated that chimeras with a third cytoplasmic loop of D₂ receptor couple to Gi protein in a pattern characteristic of D₂ receptor. On the other hand chimeras containing a third cytoplasmic loop of D₃ receptor have coupling characteristics like those of D₃ receptor, and they couple also to Gs protein. These findings demonstrate that the third cytoplasmic loop determines and accounts for the coupling of dopamine receptors D₂ and D₃ to G proteins.     

Par-4 links dopamine signaling and depression

Prostate apoptosis response 4 (Par-4) is a leucine zipper containing protein that plays a role in apoptosis. Although Par-4 is expressed in neurons, its physiological role in the nervous system is unknown. Here we identify Par-4 as a regulatory component in dopamine signaling. Par-4 directly interacts with the dopamine D2 receptor (D2DR) via the calmodulin binding motif in the third cytoplasmic loop. Calmodulin can effectively compete with Par-4 binding in a Ca2+-dependent manner, providing a route for Ca2+-mediated downregulation of D2DR efficacy. To examine the importance of the Par-4/D2DR interaction in dopamine signaling in vivo, we used a mutant mouse lacking the D2DR interaction domain of Par-4, Par-4DeltaLZ. Primary neurons from Par-4DeltaLZ embryos exhibit an enhanced dopamine-cAMP-CREB signaling pathway, indicating an impairment in dopamine signaling in these cells. Remarkably, Par-4DeltaLZ mice display significantly increased depression-like behaviors. Collectively, these results provide evidence that Par-4 constitutes a molecular link between impaired dopamine signaling and depression.     

Dopamine D2 receptor isoforms expressed in AtT20 cells differentially couple to G proteins to acutely inhibit high voltage-activated calcium channels

The dopamine D2 receptor belongs to the serpentine superfamily of receptors, which have seven transmembrane segments and activate G proteins. D2 receptors are known to be linked, through Galpha(o)- and Galpha(i)-containing G proteins, to several signaling pathways in neuronal and secretory cells, including inhibition of adenylyl cyclase and high voltage-activated Ca2+ channels (HVA-CCs). The dopamine D2 receptor exists in two alternatively spliced isoforms, "long" and "short" (D2L, and D2S, respectively), which have identical ligand binding sites but differ by 29 amino acids in the third intracellular loop, the proposed site for G protein interaction. This has led to the speculation that the two isoforms may interact with different G proteins. We have transfected the AtT20 cell line with either D2L (KCL line) or D2S (KCS line) to facilitate experimentation on the individual isoforms. Both lines show dopamine agonist-dependent inhibition of Q-type HVA-CCs. We combined G protein antisense knock-down studies with multiwavelength fluorescence video microscopy to measure changes in HVA-CC inhibition to investigate the possibility of differential G protein coupling to this inhibition. The initial, rapid, K+ depolarization-induced increase in intracellular Ca2+ concentration is due to influx through HVA-CCs. Our studies reveal that both D2 isoforms couple to Galpha(o) to partially inhibit this influx. However, D2L also couples to Galpha(i)3, whereas D2S couples to Galpha(i)2. These data support the hypothesis of differential coupling of D2 receptor isoforms to G proteins.     

Interactions of GIPC with dopamine D2, D3 but not D4 receptors define a novel mode of regulation of G protein-coupled receptors

The C-terminus domain of G protein-coupled receptors confers a functional cytoplasmic interface involved in protein association. By screening a rat brain cDNA library using the yeast two-hybrid system with the C-terminus domain of the dopamine D(3) receptor (D(3)R) as bait, we characterized a new interaction with the PDZ domain-containing protein, GIPC (GAIP interacting protein, C terminus). This interaction was specific for the dopamine D(2) receptor (D(2)R) and D(3)R, but not for the dopamine D(4) receptor (D(4)R) subtype. Pull-down and affinity chromatography assays confirmed this interaction with recombinant and endogenous proteins. Both GIPC mRNA and protein are widely expressed in rat brain and together with the D(3)R in neurons of the islands of Calleja at plasma membranes and in vesicles. GIPC reduced D(3)R signaling, cointernalized with D(2)R and D(3)R, and sequestered receptors in sorting vesicles to prevent their lysosomal degradation. Through its dimerization, GIPC acts as a selective scaffold protein to assist receptor functions. Our results suggest a novel function for GIPC in the maintenance, trafficking, and signaling of GPCRs.     

A region of the third intracellular loop of the short form of the D2 dopamine receptor dictates Gi coupling specificity

The D2 dopamine receptor has two isoforms, the short form (D2s receptor) and the long form (D2l receptor), which differ by the presence of a 29-amino acid insert in the third cytoplasmic loop. Both the D2s and D2l receptors have been shown to couple to members of the G alpha(i) family of G proteins, but whether each isoform couples to specific G alpha(i) protein(s) remains controversial. In previous studies using G alpha(i) mutants resistant to modification by pertussis toxin (G alpha(i)PT), we demonstrated that the D2s receptor couples selectively to G alpha(i2)PT and that the D2l receptor couples selectively to G alpha(i3)PT (Senogles, S. E. (1994) J. Biol. Chem. 269, 23120-23127). In this study, two point mutations of the D2s receptor were created by random mutagenesis (R233G and A234T). The two mutant D2s receptors demonstrated pharmacological characteristics comparable with those of the wild-type D2s receptor, with similar agonist and antagonist binding affinities. We used human embryonic kidney 293 cells stably transfected with G alpha(i1)PT, G alpha(i2)PT, or G alpha(i3)PT to measure agonist-mediated inhibition of forskolin-stimulated cAMP accumulation before and after pertussis toxin treatment. The two mutant D2s receptors demonstrated a change in G(i) coupling specificity compared with the wild-type D2s receptor. Whereas the wild-type D2s receptor coupled predominantly to G alpha(i2)PT, mutant R233G coupled preferentially to G alpha(i3)PT, and mutant A234T coupled preferentially to G alpha(i1)PT. These results suggest that this region of the third cytoplasmic loop is crucial for determining G(i) protein coupling specificity.     

The Caenorhabditis elegans D2-like dopamine receptor DOP-2 physically interacts with GPA-14, a Gαi subunit

Dopaminergic inputs are sensed on the cell surface by the seven-transmembrane dopamine receptors that belong to a superfamily of G-protein-coupled receptors (GPCRs). Dopamine receptors are classified as D1-like or D2-like receptors based on their homology and pharmacological profiles. In addition to well established G-protein coupled mechanism of dopamine receptors in mammalian system they can also interact with other signaling pathways. In C. elegans four dopamine receptors (dop-1, dop-2, dop-3 and dop-4) have been reported and they have been implicated in a wide array of behavioral and physiological processes. We performed this study to assign the signaling pathway for DOP-2, a D2-like dopamine receptor using a split-ubiquitin based yeast two-hybrid screening of a C. elegans cDNA library with a novel dop-2 variant (DOP-2XL) as bait. Our yeast two-hybrid screening resulted in identification of gpa-14, as one of the positively interacting partners. gpa-14 is a G?? coding sequence and shows expression overlap with dop-2 in C. elegans ADE deirid neurons. In-vitro pull down assays demonstrated physical coupling between dopamine receptor DOP-2XL and GPA-14. Further, we sought to determine the DOP-2 region necessary for GPA-14 coupling. We generated truncated DOP-2XL constructs and performed pair-wise yeast two-hybrid assay with GPA-14 followed by in-vitro interaction studies and here we report that the third intracellular loop is the key domain responsible for DOP-2 and GPA-14 coupling. Our results show that the extra-long C. elegans D2-like receptor is coupled to gpa-14 that has no mammalian homolog but shows close similarity to inhibitory G-proteins. Supplementing earlier investigations, our results demonstrate the importance of an invertebrate D2-like receptor's third intracellular loop in its G-protein interaction.     

The Caenorhabditis elegans D2-like dopamine receptor DOP-2 physically interacts with GPA-14, a Gαi subunit

ABSTRACT: Dopaminergic inputs are sensed on the cell surface by the seven-transmembrane dopamine receptors that belong to a superfamily of G-protein-coupled receptors (GPCRs). Dopamine receptors are classified as D1-like or D2-like receptors based on their homology and pharmacological profiles. In addition to well established G-protein coupled mechanism of dopamine receptors in mammalian system they can also interact with other signaling pathways. In C. elegans four dopamine receptors (dop-1, dop-2, dop-3 and dop-4) have been reported and they have been implicated in a wide array of behavioral and physiological processes. We performed this study to assign the signaling pathway for DOP-2, a D2-like dopamine receptor using a split-ubiquitin based yeast two-hybrid screening of a C. elegans cDNA library with a novel dop-2 variant (DOP-2XL) as bait. Our yeast two-hybrid screening resulted in identification of gpa-14, as one of the positively interacting partners. gpa-14 is a Gα coding sequence and shows expression overlap with dop-2 in C. elegans ADE deirid neurons. In-vitro pull down assays demonstrated physical coupling between dopamine receptor DOP-2XL and GPA-14. Further, we sought to determine the DOP-2 region necessary for GPA-14 coupling. We generated truncated DOP-2XL constructs and performed pair-wise yeast two-hybrid assay with GPA-14 followed by in-vitro interaction studies and here we report that the third intracellular loop is the key domain responsible for DOP-2 and GPA-14 coupling. Our results show that the extra-long C. elegans D2-like receptor is coupled to gpa-14 that has no mammalian homolog but shows close similarity to inhibitory G-proteins. Supplementing earlier investigations, our results demonstrate the importance of an invertebrate D2-like receptor's third intracellular loop in its G-protein interaction.     

Drug-Induced Up-Regulation of Dopamine D2 Receptors on Cultured Cells

Abstract: Ligand-induced up-regulation of recombinant dopamine D2 receptors was assessed using C₆ glioma cells stably expressing the short (415-amino-acid; D2_S) and long (444-amino-acid; D2_L) forms of the receptor. Overnight treatment of C6-D2_L cells with N-propylnorapomorphine (NPA) caused a time- and concentration-dependent increase in the density of receptors, as assessed by the binding of radioligand to membranes prepared from the cells, with no change in the affinity of the receptors for the radioligand. The effect of 10 µM NPA was maximal after 10 h, at which time the density of D2_L receptors was more than doubled. The agonists dopamine and quinpirole also increased the density of D2_L receptors. The receptor up-regulation was not specific for agonists, because the antagonists epidepride, sulpiride, and domperidone caused smaller (30–60%) increases in receptor density. Prolonged treatment with 10 µM NPA desensitized D2_L receptors, as evidenced by a reduced ability of dopamine to inhibit adenylyl cyclase, whereas treatment with sulpiride was associated with an enhanced responsiveness to dopamine. The magnitude of NPA-induced receptor up-regulation in each of four clonal lines of C6-D2_L cells (mean increase, 80%) was greater than in all four lines of C6-D2_S cells (33%). Inactivation of pertussis toxin-sensitive G proteins had no effect on the basal density of D2_L receptors or on the NPA-induced receptor up-regulation. Treatment with 5 µg/ml of cycloheximide, on the other hand, decreased the basal density of receptors and attenuated, but did not prevent, the NPA-induced increase. Chimeric D1/D2 receptors were used to identify structural determinants of dopamine receptor regulation. Treatment with the D1/D2 agonist NPA decreased the density of D1 and chimeric CH4 and CH3 receptors. The latter two receptors have D1 sequence from the amino-terminus to the amino-terminal end of transmembrane region (TM) VII and VI, respectively. CH2, with D1 sequence up to the amino-terminal end of TM V, and thus the third cytoplasmic loop of the D2 receptor, was up-regulated by NPA or the D2-selective agonist quinpirole. Quinpirole treatment decreased the density of CH3 and had no effect on CH4 or D1 receptors. The different responses of CH2 and CH3 to agonist treatment suggest a role for TM V and the third cytoplasmic loop in the direction of receptor regulation.     

Evidence that calmodulin binding to the dopamine D2 receptor enhances receptor signaling

The Ca2+ sensor calmodulin (CaM) regulates numerous proteins involved in G protein-coupled receptor (GPCR) signaling. CaM binds directly to some GPCRs, including the dopamine D2 receptor. We confirmed that the third intracellular loop of the D2 receptor is a direct contact point for CaM binding using coimmunoprecipitation and a polyHis pull-down assay, and we determined that the D2-like receptor agonist 7-OH-DPAT increased the colocalization of the D2 receptor and endogenous CaM in both 293 cells and in primary neostriatal cultures. The N-terminal three or four residues of D2-IC3 were required for the binding of CaM; mutation of three of these residues in the full-length receptor (I210C/K211C/I212C) decreased the coprecipitation of the D2 receptor and CaM and also significantly decreased D2 receptor signaling, without altering the coupling of the receptor to G proteins. Taken together, these findings suggest that binding of CaM to the dopamine D2 receptor enhances D2 receptor signaling.     

The C terminus of the Saccharomyces cerevisiae alpha-factor receptor contributes to the formation of preactivation complexes with its cognate G protein

Binding of the alpha-factor pheromone to its G-protein-coupled receptor (encoded by STE2) activates the mating pathway in MATa yeast cells. To investigate whether specific interactions between the receptor and the G protein occur prior to ligand binding, we analyzed dominant-negative mutant receptors that compete with wild-type receptors for G proteins, and we analyzed the ability of receptors to suppress the constitutive signaling activity of mutant Galpha subunits in an alpha-factor-independent manner. Although the amino acid substitution L236H in the third intracellular loop of the receptor impairs G-protein activation, this substitution had no influence on the ability of the dominant-negative receptors to sequester G proteins or on the ability of receptors to suppress the GPA1-A345T mutant Galpha subunit. In contrast, removal of the cytoplasmic C-terminal domain of the receptor eliminated both of these activities even though the C-terminal domain is unnecessary for G-protein activation. Moreover, the alpha-factor-independent signaling activity of ste2-P258L mutant receptors was inhibited by the coexpression of wild-type receptors but not by coexpression of truncated receptors lacking the C-terminal domain. Deletion analysis suggested that the distal half of the C-terminal domain is critical for sequestration of G proteins. The C-terminal domain was also found to influence the affinity of the receptor for alpha-factor in cells lacking G proteins. These results suggest that the C-terminal cytoplasmic domain of the alpha-factor receptor, in addition to its role in receptor downregulation, promotes the formation of receptor-G-protein preactivation complexes.     

Development of Polyclonal Anti-D2 Dopamine Receptor Antibodies to Fusion Proteins: Inhibition of D2 Receptor–G Protein Interaction

Abstract: Portions of the cDNA encoding the third intracellular loop (i3 loop) of the long and short isoforms of the rat D2 dopamine receptor were subcloned into the vector pNMHUBpoly and expressed in Escherichia coli as fusion proteins. The fusion proteins were gel-purified and used to immunize rabbits for the production of polyclonal anti-receptor antisera. The anti-fusion protein antisera recognized synthetic peptides corresponding to segments of the i3 loops of D2 dopamine receptors in a solid-phase radioimmunoassay. Antisera were tested in an immunoprecipitation assay using the reversible D2 antagonist [¹²⁵I]NCQ 298 and digitonin-solubilized extracts of canine and rat caudate. [¹²⁵I]-NCQ 298 bound reversibly and with high affinity (K_D= 0.14 n M ) to receptors in solubilized extracts enriched by chromatography on heparin-agarose. The anti-UBI-D2i3_L and anti-UBI-D2i3_s antisera were able to immunoprecipitate quantitatively D2 dopamine receptors labeled with [¹²⁵I]NCQ 298 from solubilized rat caudate. The antibodies were tested for their ability to affect the coupling of D2 dopamine receptors to GTP-binding proteins in digitonin-solubilized rat caudate. Both anti-UBI-D2i3_L and anti-UBI-D2i3_s antisera were able to inhibit the high-affinity binding of the agonist N -propylnorapomorphine to digitonin-solubilized rat caudate. These findings indicate that the i3 loop of the D2 dopamine receptor is an important determinant for coupling of the G protein.     

Identification of an interaction between the angiotensin II receptor sub-type AT2 and the ErbB3 receptor, a member of the epidermal growth factor receptor family

To identify the proteins that interact and mediate angiotensin II receptor AT2-specific signaling, a random peptide library was screened by yeast-based Two-Hybrid protein-protein interaction assay technique. A peptide that shared significant homology with the amino acids located between the residues Gly-Xaa-Gly-Xaa-Xaa-Gly721 and Lys742, the residues predicted to be important for ATP binding of the ErbB3 and ErbB2 receptors, was identified to be interacting with the AT2 receptor. The interaction between the human ErbB3 receptor and the AT2 receptor was further confirmed using the cytoplasmic domain (amino acids 671-782) of the human ErbB3 receptor. Moreover, an AT2 receptor peptide that spans the amino acids 226-363, (spans the third ICL and carboxy terminal domain) could also interact with the AT2 receptor in a yeast Two-Hybrid protein-protein interaction assay. Studies using mutated and chimeric AT2 receptors showed that replacing the third intracellular loop (ICL) of the AT2 receptor with that of the AT1 abolishes the interaction between the ErbB3 and the AT2 in yeast Two-Hybrid protein-protein interaction assay. Thus the interaction between the AT2 receptor and the ErbB3 receptor seems to require the region spanning the third ICL and carboxy terminus of the AT2 receptor. Since the third ICL of the AT2 receptor is essential for exerting its inhibitory effects on cell growth, possible involvement of this region in the interaction with the cytoplasmic domain of the ErbB3 receptor suggests a novel signaling mechanism for the AT2 receptor mediated inhibition of cell growth. Furthermore, since both the AT2 and the ErbB3 receptors are expressed during fetal development, we propose that the existence of direct interaction between these two receptors may play a role in the regulation of growth during the initial stages of development.     

G protein-mediated mitogen-activated protein kinase activation by two dopamine D2 receptors

Two isoforms of dopamine D2 receptor, D2L (long) and D2S (short), differ by the insertion of 29 amino acids specific to D2L within the putative third intracellular loop of the receptor, which appears to be important in selectivity for G-protein coupling. We have generated D2L- and D2S-expressing Chinese hamster ovary (CHO) cells, and regulation of the mitogen-activated protein kinase (MAPK) pathway was examined in these cells. Both D2L and D2S mediated a rapid and transient activation of MAPK with dominant activation of p42-kDa MAPK. Pertussis toxin treatment completely abrogated stimulation of MAPK mediated by D2L and D2S, demonstrating that both receptors couple to pertussis toxin-sensitive G proteins in this signaling. Stimulation of MAPK mediated by both D2L and D2S receptor was markedly attenuated by coexpression of the C-terminus of beta-adrenergic receptor kinase (betaARKct), which selectively inhibits Gbetagamma-mediated signal transduction. Further analysis of D2L- and D2S-mediated MAPK activation demonstrated that D2L-mediated MAPK activation was not significantly affected by PKC depletion or partially affected by genistein. In contrast, D2S-mediated MAPK activation was potentially inhibited by PKC depletion and genistein was capable of completely inhibiting D2S-mediated MAPK activation. Together, these results suggest that D2L- and D2S-mediated MAPK activation is predominantly Gbetagamma subunit-mediated signaling and that protein kinase C and tyrosine phosphorylations are involved in these signaling pathways.     

Dynamic modelling of the binding of substances to the conserved membrane-adjacent heptapeptide of the 15-residue C-terminal cytoplasmic fragment of mammalian dopamine D2 receptors

Dynamic modelling was carried out on the binding in water of several substances to the conserved membrane-adjacent heptapeptide of the 15-residue C-terminal cytoplasmic fragment (C-tail) of mammalian dopamine D2 receptors, PheAsnIleGluPheArgLys. Particularly important in the establishment of binding pockets for ligands were the carboxyl, phenyl, guanidino, and ε-amino groups of the last 4 residues. A broad array of chemical structures was found to be potentially capable of binding to this site, among which were dopamine, dopamine D2 receptor agonists and antagonists, GABA, muscimol, GABA_B receptor agonists and antagonists, homocarnosine, and carnosine. Since the C-tail is critical for G protein binding, it is suggested that many naturally-occurring and synthetic substances may be modulators of activation of G proteins by G-coupled receptors. Special issue dedicated to Dr. Kinya Kuriyama.     

Differential role of the carboxy-terminus of the A2B adenosine receptor in stimulation of adenylate cyclase, phospholipase Cβ, and interleukin-8

In human mast cells and microvascular endothelial cells, the A_2B adenosine receptor controls at least three independent signaling pathways, i.e., Gs-mediated stimulation of adenylate cyclase, Gq-mediated stimulation of phospholipase Cβ, and Gs/Gq-independent upregulation of IL-8. Functional analysis of cells transfected with full-length and truncated receptor constructs revealed that the A_2B receptor C-terminus is important for coupling to Gs and Gq proteins. Removal of the entire cytoplasmic portion in the A_2B receptor C-terminus rendered it incapable of stimulating adenylate cyclase and phospholipase Cβ. Conversely, removal of the distal 16 amino acids facilitated signal transduction from the receptor to the downstream Gs but not Gq proteins. However, the A_2B receptor C-terminus is not essential for upregulation of IL-8. Analysis of chimeric A_2A/A_2B receptors demonstrated that only chimeras containing the third intracellular loop of the A_2B receptor mediated agonist-dependent IL-8 reporter stimulation, suggesting that this domain is important for upregulation of IL-8.     

D2 dopamine receptor expression and trafficking is regulated through direct interactions with ZIP

We have used the yeast two-hybrid system to identify protein kinase C-zeta interacting protein (ZIP) as a novel interacting protein for the D(2) dopamine receptor (DAR). This interaction was identified by screening a rat brain cDNA library using the third intracellular loop of the D(2) DAR as bait. A partial-length cDNA encoding ZIP was isolated and characterized as specifically interacting with the third intracellular loop of the D(2) DAR, but not with the third intracellular loops of other DAR subtypes. Biochemical confirmation of the ZIP-D(2) DAR interaction was obtained by expressing the full-length ZIP and D(2) DAR proteins in mammalian cells and demonstrating that they could be co-immunoprecipitated. We further showed that ZIP and the D(2) DAR could be co-immunoprecipitated from endogenous brain tissues. Immunohistochemical analyses further revealed that ZIP and the D(2) DAR were extensively co-localized within numerous neurons in various brain regions. ZIP exists as three protein isoforms of varying length, which are derived from alternative RNA splicing. All three isoforms were found to interact with the D(2) DAR, which allowed for the delineation of the receptor interacting domain to within 38 residues of ZIP. Functionally, over-expression of ZIP was found to result in decreased expression of the D(2) DAR with a corresponding decrease in receptor modulation of cAMP accumulation. Confocal microscopy revealed that ZIP over-expression also lead to an intracellular accumulation of D(2) DAR protein in lysosome compartments. These results suggest that ZIP can physically interact with the D(2) DAR leading to increased intracellular trafficking to lysosomes with subsequent down-regulation of receptor expression and function.     

RGS2 binds directly and selectively to the M1 muscarinic acetylcholine receptor third intracellular loop to modulate Gq/11alpha signaling

RGS proteins serve as GTPase-activating proteins and/or effector antagonists to modulate Galpha signaling events. In live cells, members of the B/R4 subfamily of RGS proteins selectively modulate G protein signaling depending on the associated receptor (GPCR). Here we examine whether GPCRs selectively recruit RGS proteins to modulate linked G protein signaling. We report the novel finding that RGS2 binds directly to the third intracellular (i3) loop of the G(q/11)-coupled M1 muscarinic cholinergic receptor (M1 mAChR; M1i3). This interaction is selective because closely related RGS16 does not bind M1i3, and neither RGS2 nor RGS16 binds to the G(i/o)-coupled M2i3 loop. When expressed in cells, RGS2 and M1 mAChR co-localize to the plasma membrane whereas RGS16 does not. The N-terminal region of RGS2 is both necessary and sufficient for binding to M1i3, and RGS2 forms a stable heterotrimeric complex with both activated G(q)alpha and M1i3. RGS2 potently inhibits M1 mAChR-mediated phosphoinositide hydrolysis in cell membranes by acting as an effector antagonist. Deletion of the N terminus abolishes this effector antagonist activity of RGS2 but not its GTPase-activating protein activity toward G(11)alpha in membranes. These findings predict a model where the i3 loops of GPCRs selectively recruit specific RGS protein(s) via their N termini to regulate the linked G protein. Consistent with this model, we find that the i3 loops of the mAChR subtypes (M1-M5) exhibit differential profiles for binding distinct B/R4 RGS family members, indicating that this novel mechanism for GPCR modulation of RGS signaling may generally extend to other receptors and RGS proteins.