Regulation of transport of the dopamine D1 receptor by a new membrane-associated ER protein

Many structural determinants for G protein-coupled receptor (GPCR) functions have been defined, but little is known concerning the regulation of their transport from the endoplasmic reticulum (ER) to the cell surface. Here we show that a carboxy-terminal hydrophobic motif, FxxxFxxxF, which is highly conserved among GPCRs, functions independently as an ER-export signal for the dopamine D1 receptor. A newly identified ER-membrane-associated protein, DRiP78, binds to this motif. Overexpression or sequestration of DRiP78 leads to retention of D1 receptors in the ER, reduced ligand binding, and a slowdown in the kinetics of receptor glycosylation. Our results indicate that DRiP78 may regulate the transport of a GPCR by binding to a specific ER-export signal.     

A point mutation in the human melanin concentrating hormone receptor 1 reveals an important domain for cellular trafficking

G protein-coupled receptors (GPCRs) are heptahelical integral membrane proteins that require cell surface expression to elicit their effects. The lack of appropriate expression of GPCRs may be the underlying cause of a number of inherited disorders. There is evidence that newly synthesized GPCRs must attain a specific conformation for their correct trafficking to the cell surface. In this study, we show that a single point mutation in human melanin-concentrating hormone receptor (hMCHR1) at position 255 (T255A), which is located at the junction of intracellular loop 3 and transmembrane domain 6, reduces the hMCHR1 cell surface expression level to 20% of that observed for the wild-type receptor. Most of these mutant receptors are located intracellularly, as opposed to the wild-type receptor, which is located primarily on the cell surface. Immunoprecipitation experiments show that hMCHR1-T255A has reduced glycosylation compared with the wild-type receptor and is associated with the chaperone protein, calnexin, and it colocalizes in the endoplasmic reticulum with KDEL-containing proteins. We also demonstrate that a cell-permeable small molecule antagonist of hMCHR1 can function as a pharmacological chaperone to restore cell surface expression of this and other MCHR1 mutants to wild-type levels. Once rescued, the T255A mutant couples to Gq proteins as efficiently as the wild-type receptor. These data suggest that this single mutation produces an hMCHR1 that folds incorrectly, resulting in its retention in the endoplasmic reticulum, but once rescued to the cell surface can still function normally.     

Co-expression of molecular chaperones does not improve the heterologous expression of mammalian G-protein coupled receptor expression in yeast

The limitations to high-level expression of integral membrane proteins are not well understood. The human A(2)a adenosine receptor (A(2)a) and mouse Substance P receptor (SPR) were individually expressed in S. cerevisiae to identify potential cellular bottlenecks for G-protein coupled receptors. In the yeast system, A(2)a was not N-linked glycosylated but was functional and plasma membrane-localized. A(2)a also contained an intramolecular disulfide bond. Substance P receptor was also not N-linked glycosylated in yeast, but, unlike A(2)a, SPR was intracellularly retained, nonfunctional, and did not appear to contain an intramolecular disulfide bond. Since both receptors contain N-linked glycosylation and disulfide bonds in mammalian systems, machinery responsible for interacting with these modifications was investigated-specifically, the potential interactions between the nascent receptor and ER-resident proteins were explored. The chaperones calnexin and protein disulfide isomerase were co-overexpressed with the GPCRs to determine the effect on total and active yields of A(2)a and SPR, as well as on receptor trafficking. The effect of co-expressing the chaperone BiP on the total yields of A(2)a as well as intracellular fates of both receptors were determined. The co-expression of ER resident proteins did not improve A(2)a yields nor did they restore SPR activity or improve SPR cell surface expression. Taken together, these results indicate that an ER-folding bottleneck does not limit the expression of the mammalian receptors in yeast.     

Dysbindin Promotes the Post-Endocytic Sorting of G Protein-Coupled Receptors to Lysosomes

Background

Dysbindin, a cytoplasmic protein long known to function in the biogenesis of specialized lysosome-related organelles (LROs), has been reported to reduce surface expression of D2 dopamine receptors in neurons. Dysbindin is broadly expressed, and dopamine receptors are members of the large family of G protein-coupled receptors (GPCRs) that function in diverse cell types. Thus we asked if dysbindin regulates receptor number in non-neural cells, and further investigated the cellular basis of this regulation.

Methodology/Principal Findings

We used RNA interference to deplete endogenous dysbindin in HEK293 and HeLa cells, then used immunochemical and biochemical methods to assess expression and endocytic trafficking of epitope-tagged GPCRs. Dysbindin knockdown up-regulated surface expression of D2 receptors compared to D1 receptors, as reported previously in neurons. This regulation was not mediated by a change in D2 receptor endocytosis. Instead, dysbindin knockdown specifically reduced the subsequent trafficking of internalized D2 receptors to lysosomes. This distinct post-endocytic sorting function explained the minimal effect of dysbindin depletion on D1 receptors, which recycle efficiently and traverse the lysosomal pathway to only a small degree. Moreover, dysbindin regulated the delta opioid receptor, a more distantly related GPCR that is also sorted to lysosomes after endocytosis. Dysbindin was not required for lysosomal trafficking of all signaling receptors, however, as its depletion did not detectably affect down-regulation of the EGF receptor tyrosine kinase. Dysbindin co-immunoprecipitated with GASP-1 (or GPRASP-1), a cytoplasmic protein shown previously to modulate lysosomal trafficking of D2 dopamine and delta opioid receptors by direct interaction, and with HRS that is a core component of the conserved ESCRT machinery mediating lysosome biogenesis and sorting.

Conclusions/Significance

These results identify a distinct, and potentially widespread function of dysbindin in promoting the sorting of specific GPCRs to lysosomes after endocytosis.     

Role of N-glycan-dependent quality control in the cell-surface expression of the AT1 receptor

Most G protein-coupled receptors (GPCRs) are N-glycosylated proteins but the role of this post-translational modification in GPCR biosynthesis has not been extensively studied. We previously showed that the non-glycosylated AT(1) receptor is inefficiently expressed at the cell surface. In this study, we addressed whether AT(1) interacts with elements of the ER-based quality control processes. Interestingly, non-glycosylated AT(1) receptors associated with the molecular chaperones calnexin and HSP70, suggesting the importance of protein-based interactions between these partners. We also demonstrate that ER mannosidase I participates in the acquisition of mature glycoforms and in the targeting of the AT(1) receptor to the membrane. Taken together, these results indicate that decreased cell-surface expression of the non-glycosylated receptor cannot be attributed to diminished interactions with molecular chaperones and that mannose trimming of the wild-type AT(1) receptor by ER mannosidase I plays a critical role in its cell-surface expression.     

CNIH4 Interacts with Newly Synthesized GPCR and Controls Their Export from the Endoplasmic Reticulum

The molecular mechanisms regulating G protein‐coupled receptors (GPCRs) trafficking from their site of synthesis in the endoplasmic reticulum (ER) to their site of function (the cell surface) remain poorly characterized. Using a bioluminescence resonance energy transfer‐based proteomic screen, we identified a novel GPCR‐interacting protein; the human cornichon homologue 4 (CNIH4). This previously uncharacterized protein is localized in the early secretory pathway where it interacts with members of the 3 family of GPCRs. Both overexpression and knockdown expression of CNIH4 caused the intracellular retention of GPCRs, indicating that this ER‐resident protein plays an important role in GPCR export. Overexpression of CNIH4 at low levels rescued the maturation and cell surface expression of an intracellularly retained mutant form of the β2‐adrenergic receptor, further demonstrating a positive role of CNIH4 in GPCR trafficking. Taken with the co‐immunoprecipitation of CNIH4 with Sec23 and Sec24, components of the COPII coat complex responsible for ER export, these data suggest that CNIH4 acts as a cargo‐sorting receptor, recruiting GPCRs into COPII vesicles .      

The regulatory mechanisms of export trafficking of G protein-coupled receptors

G protein-coupled receptors (GPCRs) are a superfamily of cell-surface receptors that regulate a variety of cell functions by responding to a myriad of ligands. The magnitude of the response elicited by a ligand is dictated by the level of receptor available at the plasma membrane. GPCR expression levels at the cell surface are a balance of three highly regulated, dynamic intracellular trafficking processes, namely export, internalization and degradation. This review will cover recent advances in understanding the mechanism underlying GPCR export trafficking by focusing on specific motifs required for ER export and the role of the Ras-like Rab1 GTPase and glycosylation in regulating ER–Golgi-cell-surface transport. The manifestation of diseases due to the disruption of GPCR export is also discussed.     

Regulation of G‐Protein Coupled Receptor Traffic by an Evolutionary Conserved Hydrophobic Signal

Plasma membrane (PM) expression of G‐protein coupled receptors (GPCRs) is required for activation by extracellular ligands; however, mechanisms that regulate PM expression of GPCRs are poorly understood. For some GPCRs, such as alpha2c‐adrenergic receptors (α_2c‐ARs), heterologous expression in non‐native cells results in limited PM expression and extensive endoplasmic reticulum (ER) retention. Recently, ER export/retentions signals have been proposed to regulate cellular trafficking of several GPCRs. By utilizing a chimeric α_2a/α_2c‐AR strategy, we identified an evolutionary conserved hydrophobic sequence (ALAAALAAAAA) in the extracellular amino terminal region that is responsible in part for α_2c‐AR subtype‐specific trafficking. To our knowledge, this is the first luminal ER retention signal reported for a GPCR. Removal or disruption of the ER retention signal dramatically increased PM expression and decreased ER retention. Conversely, transplantation of this hydrophobic sequence into α_2a‐ARs reduced their PM expression and increased ER retention. This evolutionary conserved hydrophobic trafficking signal within α_2c‐ARs serves as a regulator of GPCR trafficking.     

Mechanisms of the anterograde trafficking of GPCRs: Regulation of AT1R transport by interacting proteins and motifs

Anterograde cell surface transport of nascent G protein‐coupled receptors (GPCRs) en route from the endoplasmic reticulum (ER) through the Golgi apparatus represents a crucial checkpoint to control the amount of the receptors at the functional destination and the strength of receptor activation‐elicited cellular responses. However, as compared with extensively studied internalization and recycling processes, the molecular mechanisms of cell surface trafficking of GPCRs are relatively less defined. Here, we will review the current advances in understanding the ER‐Golgi‐cell surface transport of GPCRs and use angiotensin II type 1 receptor as a representative GPCR to discuss emerging roles of receptor‐interacting proteins and specific motifs embedded within the receptors in controlling the forward traffic of GPCRs along the biosynthetic pathway.      

Interaction of gamma-COP with a transport motif in the D1 receptor C-terminus

Truncations at the carboxyl termini of G protein-coupled receptors result in defective receptor biogenesis and comprise a number of inherited disorders. In order to evaluate the structural role of the C-terminus in G protein-coupled receptor biogenesis, we generated a series of deletion and substitution mutations in the dopamine D1 receptor and visualized receptor subcellular localization by fusion to a green fluorescent protein. Alanine substitutions of several hydrophobic residues within the proximal C-terminus resulted in receptor transport arrest in the ER. Agonist binding and coupling to adenylyl cyclase was also abolished. In contrast, substitutions conserving C-terminal hydrophobicity produced normal cell surface receptor expression, binding, and stimulatory function. A mechanism for the role of the C-terminus in D1 receptor transport was investigated by searching for candidate protein interactions. The D1 receptor was found to co-precipitate and associate in vitro directly with the gamma-subunit of the COPI coatomer complex. In vitro pull-down assays confirmed that only the D1 C-terminus is required for COPI association, and that identical mutations causing disruption of receptor transport to the cell surface also disrupted binding to COPI. Furthermore, conservative mutations in the D1 C-terminus restored COPI association just as they restored cell surface transport. These results suggest that association between the coatomer complex and hydrophobic residues within the proximal C-terminus of the D1 receptor may serve an important role in receptor transport.     

ANKRD13C acts as a molecular chaperone for G protein-coupled receptors

Although the mechanisms that regulate folding and maturation of newly synthesized G protein-coupled receptors are crucial for their function, they remain poorly characterized. By yeast two-hybrid screening, we have isolated ANKRD13C, a protein of unknown function, as an interacting partner for the DP receptor for prostaglandin D(2). In the present study we report the characterization of this novel protein as a regulator of DP biogenesis and trafficking in the biosynthetic pathway. Co-localization by confocal microscopy with an endoplasmic reticulum (ER) marker, subcellular fractionation experiments, and demonstration of the interaction between ANKRD13C and the cytoplasmic C terminus of DP suggest that ANKRD13C is a protein associated with the cytosolic side of ER membranes. Co-expression of ANKRD13C with DP initially increased receptor protein levels, whereas siRNA-mediated knockdown of endogenous ANKRD13C decreased them. Pulse-chase experiments indicated that ANKRD13C can promote the biogenesis of DP by inhibiting the degradation of newly synthesized receptors. However, a prolonged interaction between ANKRD13C and DP resulted in ER retention of misfolded/unassembled forms of the receptor and to their proteasome-mediated degradation. ANKRD13C also regulated the expression of other GPCRs tested (CRTH2, thromboxane A(2) (TPα), and β2-adrenergic receptor), whereas it did not affect the expression of green fluorescent protein, GRK2 (G protein-coupled receptor kinase 2), and VSVG (vesicular stomatitis virus glycoprotein), showing specificity toward G protein-coupled receptors. Altogether, these results suggest that ANKRD13C acts as a molecular chaperone for G protein-coupled receptors, regulating their biogenesis and exit from the ER.     

Mechanisms of pharmacological rescue of trafficking-defective hERG mutant channels in human long QT syndrome

Long QT syndrome type 2 is caused by mutations in the human ether-a-go-go-related gene (hERG). We previously reported that the N470D mutation is retained in the endoplasmic reticulum (ER) but can be rescued to the plasma membrane by hERG channel blocker E-4031. The mechanisms of ER retention and how E-4031 rescues the N470D mutant are poorly understood. In this study, we investigated the interaction of hERG channels with the ER chaperone protein calnexin. Using coimmunoprecipitation, we showed that the immature forms of both wild type hERG and N470D associated with calnexin. The association required N-linked glycosylation of hERG channels. Pulse-chase analysis revealed that N470D had a prolonged association with calnexin compared with wild type hERG and E-4031 shortened the time course of calnexin association with N470D. To test whether the prolonged association of N470D with calnexin is due to defective folding of mutant channels, we studied hERG channel folding using the trypsin digestion method. We found that N470D and the immature form of wild type hERG were more sensitive to trypsin digestion than the mature form of wild type hERG. In the presence of E-4031, N470D became more resistant to trypsin even when its ER-to-Golgi transport was blocked by brefeldin A. These results suggest that defective folding of N470D contributes to its prolonged association with calnexin and ER retention and that E-4031 may restore proper folding of the N470D channel leading to its cell surface expression.     

"In vivo" intraneuronal trafficking of G protein coupled receptors in the striatum: regulation by dopaminergic and cholinergic environment

We have studied "in vivo" neurochemically identified striatal neurons to analyze the localisation and the trafficking of dopamine and acetylcholine G protein coupled receptors (GPCR) (D1R, D2R, m2R and m4R) under the influence of neurotransmitter environment. We have identified receptors in tissue sections through immunohistochemical detection at the light and electron microscopic level. We have identified receptors in normal animals and after acute and chronic stimulations. We have quantified receptors through image analysis at the electron microscopic level in relation to various subcellular compartments. Our results demonstrate that, in normal conditions, GPCRs are mostly associated with plasma membrane of the striatal neurons, mostly at extra-synaptic sites. In certain instances (m4R; D2R), receptors have prominent localisation inside the rough endoplasmic reticulum. Our results also show that two distinct receptors for a same neurotransmitter may have distinct subcellular localisation in a same neuronal population (m2R versus m4R) and that the same neurotransmitter receptor (m4R) can have distinct localisation in distinct neuronal populations (cytoplasm versus cell surface). After acute stimulation, cell surface receptors undergo dramatic subcellular changes that involve plasma membrane depletion, internalisation in endosomes and in multivesicular bodies. Such changes are reversible after the end of the stimulation and are blocked by antagonist action. Chronic stimulation also provokes changes in subcellular localisation with specific pattern: plasma membrane depletion, and exaggerated storage of receptors in rough endoplasmic reticulum and eventually Golgi complex (D1R; m2R and m4R). Decreasing chronic receptor stimulation reverses such changes. These results demonstrate that, "in vivo", in the striatum, GPCRs undergo complex intraneuronal trafficking under the influence of neurochemical environment in conditions that dramatically modulate the number of cell surface receptors available for interaction with neurotransmitters or drugs. This confirms that "in vivo", the trafficking and the subcellular compartmentalization of GPCRs may contribute to regulate neuronal sensitivity and neuronal interactions in physiological, experimental and pathological conditions, including in therapeutic conditions.     

Membrane targeting of ATP-sensitive potassium channel. Effects of glycosylation on surface expression

Oligosaccharides play significant roles in trafficking, folding, and sorting of membrane proteins. Sulfonylurea receptors (SURx), members of the ATP binding cassette family of proteins, associate with the inward rectifier Kir6.x to form ATP-sensitive potassium channels (K(ATP)). These channels are found on the plasma membrane in many tissues and play a pivotal role in synchronizing electrical excitability with cell metabolic state. Trafficking defects resulting from three independent SUR1 mutations involved in the disease persistent hyperinsulinemic hypoglycemia of infancy have been described. Two of these mutations displayed notable decreases in glycosylation. Here we have investigated the relationship between the two N-linked glycosylation sites (Asn(10) and Asn(1050)) and SUR1 trafficking. Using patch clamp analysis, surface biotinylation, and immunofluorescence microscopy, we demonstrate a significant decrease in surface expression of SUR1 single or double glycosylation site mutants (N10Q,N1050Q) when co-expressed with Kir6.2. Additionally, we show prominent retention within the ER of the SUR1 double glycosylation mutant under the same conditions. Further investigation revealed that mutation of the ER retention signal was able to partially restore surface expression of the SUR1 double glycosylation mutant. These studies suggest that SUR1 glycosylation is a key element for the proper trafficking and surface expression of K(ATP) channels.     

The molecular chaperone calnexin is expressed on the surface of immature thymocytes in association with clonotype-independent CD3 complexes.

Immature thymocytes express clonotype-independent CD3 complexes that, when engaged by anti-CD3 antibodies, can signal CD4-CD8- thymocytes to differentiate into CD4+CD8+ cells. Clonotype-independent CD3 complexes consist of CD3 components associated with an unknown 90 kDa surface protein. We now report the surprising finding that this 90 kDa surface protein is the molecular chaperone calnexin, an integral membrane protein previously thought to reside only in the endoplasmic reticulum (ER). We found that calnexin-CD3 complexes escaping to the cell surface utilize interchain associations distinct from those utilized by calnexin-CD3 complexes remaining within the ER. Specifically, we demonstrate that carbohydrate-mediated luminal domain interactions that are necessary for formation of most internal calnexin-CD3 complexes destined to be expressed on the cell surface, and we provide evidence that cytoplasmic domain interactions between calnexin and CD3 epsilon chains mask calnexin's ER retention signal, permitting calnexin and associated proteins to escape ER retention. Thus, the present study demonstrates that partial T cell antigen receptor complexes can escape the ER of immature thymocytes in association with their molecular chaperone to be expressed at low levels on the cell surface where they may function as a signaling complex to regulate thymocyte maturation.     

RACK1 regulates the cell surface expression of the G protein-coupled receptor for thromboxane A(2).

We used the yeast two-hybrid system to screen for proteins that interact with the C-terminus of the beta isoform of the thromboxane A(2) receptor (TPbeta). This screen identified receptor for activated C-kinase 1 (RACK1) as a new TPbeta-interacting protein. Here, we show that RACK1 directly binds to the C-terminus and the first intracellular loop of TPbeta. The TPbeta-RACK1 association was further confirmed by co-immunoprecipitation studies in HEK293 cells and was not modulated by stimulation of the receptor. We observed that cell surface expression of TPbeta was increased when RACK1 was overexpressed, while it was inhibited when endogenous RACK1 expression was knocked down by small interfering RNA. Confocal microscopy confirmed the impaired cell surface expression of TPbeta and suggested that the receptors remained predominantly localized in the endoplasmic reticulum (ER) in RACK1-depleted cells. Confocal microscopy also revealed that a transient TPbeta-RACK1 association takes place in the ER. The effect of RACK1 on receptor trafficking to the cell surface appears to be selective to some G protein-coupled receptors (GPCRs) because inhibition of RACK1 expression also affected cell surface targeting of the angiotensin II type 1 receptor and CXCR4 but not of beta(2)-adrenergic and prostanoid DP receptors. Our data demonstrate for the first time a direct interaction between RACK1 and a GPCR and identify a novel role for RACK1 in the regulation of the transport of a membrane receptor from the ER to the cell surface.     

RACK1 Regulates the Cell Surface Expression of the G Protein-Coupled Receptor for Thromboxane A2

We used the yeast two-hybrid system to screen for proteins that interact with the C-terminus of the β isoform of the thromboxane A₂ receptor (TPβ). This screen identified receptor for activated C-kinase 1 (RACK1) as a new TPβ-interacting protein. Here, we show that RACK1 directly binds to the C-terminus and the first intracellular loop of TPβ. The TPβ–RACK1 association was further confirmed by co-immunoprecipitation studies in HEK293 cells and was not modulated by stimulation of the receptor. We observed that cell surface expression of TPβ was increased when RACK1 was overexpressed, while it was inhibited when endogenous RACK1 expression was knocked down by small interfering RNA. Confocal microscopy confirmed the impaired cell surface expression of TPβ and suggested that the receptors remained predominantly localized in the endoplasmic reticulum (ER) in RACK1-depleted cells. Confocal microscopy also revealed that a transient TPβ–RACK1 association takes place in the ER. The effect of RACK1 on receptor trafficking to the cell surface appears to be selective to some G protein-coupled receptors (GPCRs) because inhibition of RACK1 expression also affected cell surface targeting of the angiotensin II type 1 receptor and CXCR4 but not of β₂-adrenergic and prostanoid DP receptors. Our data demonstrate for the first time a direct interaction between RACK1 and a GPCR and identify a novel role for RACK1 in the regulation of the transport of a membrane receptor from the ER to the cell surface.     

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 Single Conserved Leucine Residue on the First Intracellular Loop Regulates ER Export of G Protein‐Coupled Receptors

The intrinsic structural determinants for export trafficking of G protein‐coupled receptors (GPCRs) have been mainly identified in the termini of the receptors. In this report, we determined the role of the first intracellular loop (ICL1) in the transport from the endoplasmic reticulum (ER) to the cell surface of GPCRs. The α_2B‐adrenergic receptor (AR) mutant lacking the ICL1 is unable to traffic to the cell surface and to initiate signaling measured as ERK1/2 activation. Mutagenesis studies identify a single Leu48 residue in the ICL1 modulates α_2B‐AR export from the ER. The ER export function of the Leu48 residue can be substituted by Phe, but not Ile, Val, Tyr and Trp, and is unlikely involved in correct folding or dimerization of α_2B‐AR in the ER. Importantly, the isolated Leu residue is remarkably conserved in the center of the ICL1s among the family A GPCRs and is also required for the export to the cell surface of β₂‐AR, α_1B‐AR and angiotensin II type 1 receptor. These data indicate a crucial role for a single Leu residue within the ICL1 in ER export of GPCRs.