Hm1 muscarinic cholinergic receptor internalization requires a domain in the third cytoplasmic loop

Structural and functional requirements for agonist-induced internalization of the human platelet-activating factor receptor

The receptor for platelet-activating factor (PAF) is a member of the G-protein-coupled receptor family. To study the structural elements and mechanisms involved in the internalization of human PAF receptor (hPAFR), we used the following mutants: a truncated mutant in the C-terminal tail of the receptor (Cys317 --> Stop) and mutations in the (D/N)P(X)2,3Y motif (Asp289 --> Asn,Ala and Tyr293 --> Phe,Ala). Chinese hamster ovary cells expressing the Cys317 --> Stop mutant exhibited a marked reduction in their capacity to internalize PAF, suggesting the existence of determinants important for endocytosis in the last 26 amino acids of the cytoplasmic tail. Substitution of Asp289 to alanine abolished both internalization and G-protein coupling, whereas substitution of Tyr293 to alanine abolished coupling but not internalization. Inhibition or activation of protein kinase C did not significantly affect the internalization process. Receptor sequestration and ligand uptake was, at least in part, blocked by concanavalin A and blockers of endocytosis mediated by clathrin-coated pits. Our data suggest that the internalization of a G-protein-coupled receptor and coupling to a G-protein can be two independent events. Moreover, the C terminus tail of hPAFR, but not the putative internalization motifs, may be involved in the internalization of hPAFR.

Mutations of the conserved DRS motif in the second intracellular loop of the gonadotropin-releasing hormone receptor affect expression, activation, and internalization

The GnRH receptor is an unusual member of the G protein-coupled receptor (GPCR) superfamily with several unique features. One of these is a variant of the conserved DRY motif that is located at the junction of the third transmembrane domain and the second intracellular (2i) loop of most GPCRs. In the GnRH receptor, the Tyr residue of the conserved triplet is replaced by Ser, giving a DRS sequence. The aspartate and arginine residues of the triplet are highly conserved in almost all GPCRs. The functional importance of these residues was evaluated in wild type and mutant GnRH receptors expressed in COS-7 cells. Mutants in which Asp138 was replaced by Asn or Glu were poorly expressed, but showed significantly increased internalization and exhibited augmented inositol phosphate generation to maximal agonist stimulation compared with the wild type receptor. In contrast, receptors in which Arg139 was substituted with Gln, Ala, or Ser showed reduced internalization, and the GnRH-induced inositol phosphate response for the Arg139Gln mutant was significantly impaired in proportion to its low expression level. Replacing Ser140 with Ala affected neither internalization nor signal transduction. The role of the polar amino acids at the C terminus of the 2i loop was evaluated in two additional mutants (Ser151Ala, Ser153Ala, and Ser151Ala, Ser153Ala, Lys154Gln, Glu156Gln). Both of these mutants exhibited agonist-induced inositol phosphate responses similar to that of the wild type receptor, but showed increased receptor internalization. This mutational analysis indicates that the conserved Asp and Arg residues in the DRY/S triplet make important contributions to the structural integrity of the receptor and influence receptor expression, agonist-induced activation, and internalization.

Receptor-mediated endocytosis of angiotensin II in rat myometrial cells

The events involved in the processing of the angiotensin II (Ang II)-receptor complex were studied in primary cultures of rat myometrial cells. Ang II bound to rat myometrial cells in a specific, time- and temperature-dependent fashion. Pretreatment with cycloheximide did not interfere with binding up to 3 hr, but inhibited increases in binding observed over longer periods. The [3H]Ang II binding to intact cells was inhibited by dithiothreitol (DTT), and the rank order of potency of Ang II and nonpeptide antagonists to inhibit the [3H]Ang II binding was Ang II > Losartan >> PD 123319 or CGP 42112B, indicating the presence of the AT1 receptor type. Whereas most of the [3H]Ang II binding at 4 degrees was susceptible to acid or pronase treatment, binding at 35 degrees was resistant to both treatments, suggesting an internalization of the Ang II-receptor complex. Phenylarsine oxide (PAO) and N-ethylmaleimide (NEM) caused a concentration-dependent inhibition when the binding assay was performed at 35 degrees, but no effect was observed at 4 degrees, indicating that these agents did not alter cell-surface binding but actually prevented the internalization process. Simultaneous treatment with 1 mM DTT or beta-mercaptoethanol prevented the inhibitory effect of NEM, but only DTT could prevent the inhibition caused by PAO, indicating that two closely located sulfhydryl groups must be involved in the internalization process. Chloroquine (100 microM) inhibited the [3H]Ang II dissociation from cells, and monensin (25 microM) induced a 30% inhibition of [3H]Ang II binding (35 degrees, 3 hr), suggesting endosomal processing of the Ang II-receptor complex with receptor recycling to the cell surface. These results indicate that Ang II binding to AT1 receptors in rat myometrial cells is followed by internalization of the Ang II-receptor complex and recycling of the receptor to the cell surface.

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.

Ligand-induced internalization of cholecystokinin receptors. Demonstration of the importance of the carboxyl terminus for ligand-induced internalization of the rat cholecystokinin type B receptor but not the type A receptor

Internalization of a variety of different heptahelical G protein-coupled receptors has been shown to be influenced by a number of different structural determinants of the receptors, including the carboxyl terminus. To investigate the role of the carboxyl terminus of cholecystokinin (CCK) receptors in receptor internalization, the rat wild type (WT) CCK-A receptor (WT CCKAR) and the rat WT CCK-B receptor (WT CCKBR) were truncated after amino acid residue 399 (CCKAR Tr399) and 408 (CCKBR Tr408), thereby deleting the carboxyl-terminal 45 and 44 residues, respectively. All WT and mutant CCK receptors were stably expressed in NIH/3T3 cells. Internalization of the CCKAR Tr399 was not significantly different from the WT CCKAR. In contrast, internalization of the CCKBR Tr408 was decreased to 26% compared with the WT CCKBR internalization of 92%. The mutation of all 10 serine and threonine residues (as potential phosphorylation sites) in the carboxyl terminus of the CCKBR to alanines (mutant CCKBR DeltaS/T) could account for the majority of this effect (39% internalization). All mutant receptors displayed similar ligand binding characteristics, G protein coupling, and signal transduction as their respective WT receptors, indicating that the carboxyl termini are not necessary for these processes. Thus, internalization of the CCKBR, unlike that of the CCKAR, depends on the carboxyl terminus of the receptor. These results suggest that, despite the high degree of homology between CCKAR and CCKBR, the structural determinants that mediate the interaction with the endocytic pathway reside in different regions of the receptors.

Effects of intracellular tyrosine residue mutation and carboxyl terminus truncation on signal transduction and internalization of the rat bradykinin B2 receptor

Presently, little is known of the amino acid motif(s) participating in bradykinin B2 receptor-mediated signal transduction processes. In this report we investigate the potential role of the two existing tyrosine (Tyr) residues in the intracellular regions and the carboxyl terminus in the regulatory function of this receptor. Rat-1 cells, which do not contain detectable bradykinin B2 receptor, were transfected with wild type and mutant receptor cDNAs. Tyr-131 and Tyr-321 were each mutated to corresponding alanine-, serine-, and phenylalanine-containing sequences. The last 34 amino acid residues of the carboxyl terminus were truncated. Rat-1 cells transfected with the mutant forms of the receptor cDNA including the truncated COOH-terminal cDNA all bound [3H]bradykinin with essentially the same Kd of approximately 2.2 nM as cells transfected with the wild type bradykinin B2 receptor. However, mutating Tyr-131 resulted in important changes in bradykinin-stimulated phosphoinositide turnover and arachidonate release. For example, exchanging Tyr-131 for alanine led to an 80% decreased arachidonate release (p < 0.005), 90% decrease in inositol phosphate (IP) accumulation (p < 0.001), with receptor uptake at 15 min remaining essentially unchanged. Mutating the same Tyr to phenylalanine resulted in unchanged bradykinin-stimulated IP accumulation, only a slightly lowered arachidonate release, and unchanged receptor uptake at 15 min. Mutating Tyr-321 to alanine resulted in a very different pattern. There was a small but significant reduction in arachidonate release (p < 0.03) and IP accumulation (p < 0.008) with a large, 30%, increase in receptor uptake at 15 min (p < 0.010). Truncation of a portion of the carboxyl tail also proved meaningful, with a 60% decrease in arachidonate release and an 80% decrease in IP accumulation. The truncation also resulted in a large, 130%, decrease in receptor uptake at 15 min (p < 0.023). Taken together, these results point to Tyr-131 as an important element in determining bradykinin-stimulated arachidonate release and IP accumulation. Tyrosine phosphorylation at this site apparently does not play a major role. Tyr-131, Tyr-321, and the carboxyl tail appear to be important in determining receptor uptake.

The C terminus of the human C5a receptor (CD88) is required for normal ligand-dependent receptor internalization

The biological effects of the potent inflammatory mediator C5a, a complement split product, on human neutrophils and monocytes are limited by the rapid internalization of its specific receptor (C5aR, CD88). The C terminus of the C5aR is phosphorylated after stimulation with C5a of phorbol ester, and this phosphorylation might lead to receptor internalization. In this context, we have studied the effects on C5aR internalization of C5a, phorbol 12-myristate 13-acetate (PMA), the protein kinase inhibitor staurosporine, and pertussis toxin on rat basophilic RBL.2H3 cells stably transfected with the human wild-type or mutant C5aR. C5aR mutants lacked either part of the cytosolic C terminus, including suggested major phosphorylation sites, or a putative phosphorylation motif for protein kinase C in the third cytosolic loop. Additionally, agonist-induced internalization was analyzed on HEK293 cells co-transfected with C5aR and the pertussis toxin-resistant G protein alpha subunit, G alpha 16. Staurosporine-sensitive agonist-dependent C5aR internalization could be detected, suggesting that C5aR phosphorylation, most likely of the C terminus, participates in this type of internalization. In contrast, PMA-induced C5aR internalization seems to be independent of putative phosphorylation sites in either the truncated section of the C terminus or the third cytosolic loop. The phorbol ester-induced C5aR internalization may, therefore, be caused by an indirect and less specific effect of protein kinase C on the internalization machinery. Manipulation of the pertussis toxin-sensitive or -resistant G protein-dependent signal transduction had no effect on ligand-induced internalization.

Functional role of the third cytoplasmic loop in muscarinic receptor dimerization

By means of the expression of two chimeric receptors, alpha2/m3 and m3/alpha2, in which the carboxyl-terminal receptor portions, containing transmembrane (TM) domains VI and VII, were exchanged between the alpha2C adrenergic and the m3 muscarinic receptor, Maggio et al. (Maggio, R., Vogel, Z., and Wess, J. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 3103-31073) demonstrated that G protein-linked receptors are able to interact functionally with each other at the molecular level to form (hetero)dimers. In the present study we tested the hypothesis that interaction between receptors might depend on the presence of a long third intracellular (i3) loop and that shortening this loop could impair the capability of receptors to form dimers. To address this question, we initially created short chimeric alpha2 adrenergic/m3 muscarinic receptors in which 196 amino acids were deleted from the i3 loop (alpha2/m3-short and m3/alpha2-short). Although co-transfection of alpha2/m3 and m3/alpha2 resulted in the appearance of specific binding, the co-expression of the two short constructs (alpha2/m3-short and m3/alpha2-short), either together or in combination, respectively, with m3/alpha2 and alpha2/m3 did not result in any detectable binding activity. In another set of experiments, a mutant m3 receptor, m3/m2(16aa), containing 16 amino acids of the m2 receptor sequence at the amino terminus of the third cytoplasmic loop, which was capable of binding muscarinic ligands but was virtually unable to stimulate phosphatidylinositol hydrolysis, was also mutated in the i3 loop, resulting in the m3/m2(16aa)-short receptor. Although co-transfection of m3/m2(16aa) with a truncated form of the m3 receptor (m3-trunc, containing an in frame stop codon after amino acid codon 272 of the rat m3 sequence) resulted in a considerable carbachol-stimulated phosphatidylinositol breakdown, the co-transfection of m3/m2(16aa)-short with the truncated form of the m3 receptor did not result in any recovery of the functional activity. Thus, these data suggest that intermolecular interaction between muscarinic receptors, involving the exchange of amino-terminal (containing TM domains I-V) and carboxyl-terminal (containing TM domains VI and VII) receptor fragments depends on the presence of a long i3 loop. One may speculate that when alternative forms of receptors with a different length of the i3 loop exist, they could have a different propensity to dimerize.

Somatostatin receptors in Neuro2A neuroblastoma cells: ligand internalization

1. Receptor-dependent internalization of somatostatin (SRIF) agonists has been a matter of controversy probably because [125I]Tyr11-SRIF-14 is rapidly degraded. We have studied the internalization of a stable somatostatin analogue, [125I]-BIM-23027, in a neuronal cell line, Neuro2A, which natively expresses somatostatin sst2 receptors. 2. Incubation of Neuro2A cells with [125I]-BIM-23027 at 37 degrees C resulted in a time-dependent internalization of the ligand, which reached a maximum at 30 min. Acid-washing showed that cell-surface binding of the ligand accounted for only 34% of total binding at this time. Internalization was dramatically reduced at 15 degrees C. 3. Internalization of [125I]-BIM-23027 was prevented by inclusion of unlabelled somatostatin receptor agonists in a concentration-dependent manner. The IC50 values for inhibition of [125I]-BIM-23027 internalization were approximately 100 fold lower than for inhibition of [125I]-BIM-23027 binding to membrane homogenates but followed the same rank order of potencies. 4. Disruption of G-protein coupling by treatment with pertussis toxin caused a 60% reduction in internalization of ligand. A combination of antimycin (50 nM) and deoxyglucose (50 mM) pretreatment, which leads to a depletion of cellular ATP, decreased internalization of [125I]-BIM-23027 by 66% of control and increased the proportion of surface-bound ligand. Hypertonic sucrose, which prevents clathrin-mediated endocytosis, reversibly abolished the internalization of ligand without increasing the proportion bound at the cell surface. 5. After internalization of [125I]-BIM-23027, approximately half of the ligand was recycled back to the extracellular medium within 20 min at 37 degrees C. This finding suggests that the intracellular content of [125I]-BIM-23027 reaches a steady state which is determined by the rates of both internalization and recycling of the ligand. In contrast to studies in which the internalization of [125I]-Tyr11-SRIF-14 was examined, neither internalized nor recycled [125I]-BIM-23027 was degraded to its component amino acids. 6. These findings indicate that the somatostatin agonist, [125I]-BIM-23027, is internalized in a receptor-dependent manner which involves clathrin-coated pits in Neuro2A cells. Furthermore, much of the internalized ligand is rapidly recycled back to the extracellular medium without undergoing significant degradation.

A database of mutants and effects of site-directed mutagenesis experiments on G protein-coupled receptors

A database system and computer programs for storage and retrieval of information about guanine nucleotide-binding protein (G protein) -coupled receptor mutants and associated biological effects have been developed. Mutation data on the receptors were collected from the literature and a database of mutants and effects of mutations was developed. The G protein-coupled receptor, family A, point mutation database (GRAP) provides detailed information on ligand-binding and signal transduction properties of more than 2130 receptor mutants. The amino acid sequences of receptors for which mutation experiments have been reported were aligned, and from this alignment mutation data may be retrieved. Alternatively, a search form allowing detailed specification of which mutants to retrieve may be used, for example, to search for specific amino acid substitutions, substitutions in specific protein domains or reported biological effects. Furthermore, ligand and bibliographic oriented queries may be performed. GRAP is available on the Internet (URL: http://www-grap.fagmed.uit.no/GRAP/+ +homepage.html) using the World-Wide Web system.

Human muscarinic cholinergic receptor Hm1 internalizes via clathrin-coated vesicles

The mechanism by which muscarinic receptors internalize upon agonist exposure is poorly understood. To determine the endocytic pathways responsible for muscarinic receptor internalization, we have stably transfected human embryonic kidney (HEK 293) cells with the Hm1 (human muscarinic subtype 1) receptor tagged at the amino terminus with the epitope EYMPME. The subcellular location of the receptor was visualized by immunofluorescence confocal microscopy and quantified with the use of binding studies. The receptor redistributed into intracellular compartments following agonist treatment. This process was reversible upon removal of agonist and inhibited by antagonist. Acid treatment of the cells, which disrupts internalization via clathrin-coated vesicles, inhibited carbachol-stimulated internalization. Phorbol 12-myristate 13-acetate, on the other hand, which inhibits caveolae-mediated endocytosis, had no effect on carbachol-induced endocytosis. Double-labeling confocal microscopy was used to characterize the intracellular vesicles containing Hm1 receptor following agonist treatment. The Hm1 receptor was shown to be colocalized with clathrin and alpha-adaptin, a subunit of the AP2 adaptor protein which links endocytosed proteins with clathrin in the intracellular vesicles. In addition, endosomes containing Hm1 also contained the transferrin receptor, which internalizes via clathrin-coated vesicles. In contrast, caveolin, the protein that comprises caveolae, did not colocalize with Hm1 in intracellular vesicles following agonist treatment, indicating that caveolae are not involved in the agonist-induced internalization of Hm1. These results indicate that agonist-induced internalization of the Hm1 receptor occurs via clathrin-coated vesicles in HEK cells.

Pharmacological characterization of desensitization in a human mGlu1 alpha-expressing non-neuronal cell line co-transfected with a glutamate transporter

1. Stimulation of phosphoinositide hydrolysis by human mGlu1 alpha (HmGlu1 alpha) was examined in a non-neuronal cell line (AV12-664) co-expressing both HmGlu1 alpha and a rat glutamate/aspartate transporter (GLAST). 2. Desensitization of HmGlu1 alpha could be elicited by inhibition of the GLAST transporter with the glutamate uptake inhibitor, L-trans-pyrrolidine-2,4-dicarboxylic acid (trans-PDC). Maximal inhibition of HmGlu1 alpha-mediated phosphoinositide hydrolysis was induced upon 24 h pretreatment with trans-PDC. The concentration of glutamate in the extracellular medium also rose significantly in cells pretreated with trans-PDC. Glutamate levels increased upon incubation with trans-PDC in a time-dependent manner, with maximal glutamate levels attained after 24 h incubation with trans-PDC. 3. The time required for desensitization of HmGlu1 alpha by trans-PDC was compared to the time course for desensitization elicited by the direct-acting mGlu receptor agonists, 1-aminocyclopentane-1S,3R-dicarboxylic acid (1S,3R-ACPD) and (R,S)-3,5-dihydroxyphenylglycine (3,5-DHPG). Both direct-acting mGlu receptor agonists elicited desensitization of HmGlu1 alpha more rapidly than did trans-PDC, with maximal inhibition of agonist-induced phosphoinositide hydrolysis upon 12 h pretreatment. Agonist-induced desensitization could be fully reversed upon washout of agonist for 12 h. 4. Both mGlu receptor agonist- and trans-PDC-induced desensitization of HmGlu1 alpha could be blocked by inclusion of (+)-alpha-methyl-4-carboxyphenylglycine (MCPG), an mGlu receptor antagonist, in the pretreatment medium. 5. Agonist-stimulated phosphoinositide hydrolysis by HmGlu1 alpha was found to parallel closely agonist-induced desensitization of HmGlu1 alpha. Thus, the EC50 values for 1S,3R-ACPD- and 3,5-DHPG-stimulated phosphoinositide hydrolysis were similar to the EC50 values for eliciting desensitization of HmGlu1 alpha. 6. These studies demonstrate desensitization of recombinant human mGlu1 alpha receptor in a non-neuronal cell line in which the receptor can be regulated by direct activation or by manipulation of glutamate transporter activity. Desensitization of HmGlu1 alpha was found to be mediated by activation of the receptor since the mGlu receptor antagonist, MCPG, blocked both mGlu receptor agonist- and trans-PDC-induced desensitization of HmGlu1 alpha. Furthermore, agonist-induced desensitization of HmGlu1 alpha was found to parallel receptor-mediated stimulation of phosphoinositide hydrolysis.

Constitutive activation of chimeric m2/m5 muscarinic receptors and delineation of G-protein coupling selectivity domains

To derive structure/function relationships for muscarinic receptor/G-protein coupling, the m2 and m5 muscarinic receptors and a series of m2/m5 chimeras were tested for agonist binding and functional responses in a cellular proliferation/transformation assay. m5, which mediates stimulation of phosphatidylinositol turnover, displayed robust activity in the proliferation assay, whereas m2, which mediates inhibition of adenylyl cyclase, was inactive in the proliferation assay. Chimeras that contained m2 sequences in the i2 or i3 loops had impaired activity or were inactive, respectively. Chimeras that contained m2 segments reaching from the N-terminus to TM2, or from TM6 to the C-terminus, had enhanced activity relative to m5, and a chimera with both of these elements was constitutively activated.

Identification of a region required for subtype-specific agonist-induced sequestration of the m2 muscarinic acetylcholine receptor

When the m1 and m2 muscarinic acetylcholine receptors are transiently expressed in JEG-3 cells, the m2, but not the m1, receptor undergoes agonist-induced sequestration. Both receptors exhibit internalization when expressed in Y1 cells. These results suggest that the m1 and m2 receptors use distinct cellular mechanisms or pathways for agonist-induced internalization and that JEG-3 cells are deficient in the mechanism or pathway used by the m1 receptor. Transfection experiments with chimeric receptors indicate that the specificity for agonist-induced internalization for the m2 receptor lies in the carboxyl-terminal fifth of the receptor. The intracellular carboxyl-terminal tail of the m2 receptor is neither sufficient nor required for the m2-specific sequestration. Site-directed mutagenesis demonstrates that two amino acids in the carboxyl-terminal end of the third cytoplasmic loop of the m2 receptor are required for sequestration in JEG-3 cells. In addition, the sixth transmembrane domain, which is adjacent to this cytoplasmic domain, is also required. Thus, m2-specific agonist-induced sequestration requires sequences both in the carboxyl-terminal end of the third cytoplasmic loop and the adjacent transmembrane domain.

Amino acid side chains that define muscarinic receptor/G-protein coupling. Studies of the third intracellular loop

Amino acids in the third intracellular loops of receptors play pivotal roles in G-protein coupling. To define their structural requirements, we have subjected the N- and C-terminal regions of this loop (Ni3 and Ci3, respectively) of the m5 muscarinic receptor to random saturation mutagenesis. (see Burstein, E. S., Spalding, T. A., Hill-Eubanks, D., and Brann, M. R. (1995) J. Biol. Chem. 270, 3141 3146 and Hill-Eubanks, D., Burstein, E. S., Spalding, T. A., Bräuner-Osborne, H., and Brann, M. R. (1996) J. Biol. Chem. 271, 3058 3065). In the present study, we have extended our analysis of Ni3 by constructing libraries of receptors with all possible amino acid substitutions at the residues we previously identified as functionally important and characterizing their functional phenotypes. Numerous hydrophobic substitutions were well tolerated at Ile216 and Thr220 and caused constitutive activation in two cases, establishing that hydrophobicity is structurally favored at these positions and that many amino acid side chains are compatible with this structural role. Similarly, hydrophobic and polar, but not charged, substitutions were observed at Tyr217, but in contrast to results for Thr220, most substitutions at Tyr217 substantially decreased maximum response and increased the EC50 for carbachol, demonstrating that the specific side chain of residue 217 participates in G-protein coupling. Arg223 allowed the widest range of substitutions of the residues tested, but only basic residues were well tolerated. All other substitutions significantly increased (up to 100-fold) the EC50 for carbachol without significantly affecting maximal response. There were no significant changes in the ligand binding properties of these mutant receptors. We conclude that Ile216 and Thr220 fulfill a structural role, forming the foundation of the G-protein-coupling pocket, whereas Tyr217 and Arg223 contact G-proteins through specific side chain interactions. We propose that G-proteins are recruited to receptors by ionic interactions and that hydrophobic residues participate in activation.

Structure of a G-protein-coupling domain of a muscarinic receptor predicted by random saturation mutagenesis

The third intracellular loop (i3) plays a critical role in the coupling of many receptors to G-proteins. In muscarinic receptor subtypes, the N- and C-terminal regions (Ni3 and Ci3) of this loop are sufficient to direct appropriate G-protein coupling. The relative functional contributions of all amino acids within Ni3 was evaluated by constructing libraries of m5 muscarinic receptors containing random mutations in Ni3 and screening them using high throughput assays based on ligand-dependent transformation of NIH 3T3 cells. In receptors that retained a wild type phenotype, the pattern of functionally tolerated substitutions is consistent with the presence of three turns of an alpha helix extending from the transmembrane domain. All of the amino acid positions that tolerate radical substitutions face away from a conserved hydrophobic face that ends with an arginine, and helix-disrupting proline substitutions were not observed. All of the mutant receptors with significantly compromised phenotypes had amino acid substitutions in residues predicted to form the hydrophobic face. Similar data from the Ci3 region (Burstein, E. S., Spalding, T. A., Hill-Eubanks, D., and Brann, M. R. (1995) J. Biol. Chem. 270, 3141-3146) are consistent with the presence of a single helical turn extending from the transmembrane domain, with an alanine that defines G-protein affinity. Functionally critical residues of Ni3 and Ci3 are predicted to be in close proximity where they form the G-protein-coupling domain.

Desensitization and internalization of the m2 muscarinic acetylcholine receptor are directed by independent mechanisms

The phenomenon of acute desensitization of G-protein-coupled receptors has been associated with several events, including receptor phosphorylation, loss of high affinity agonist binding, receptor:G-protein uncoupling, and receptor internalization. However, the biochemical events underlying these processes are not fully understood, and their contributions to the loss of signaling remain correlative. In addition, the nature of the kinases and the receptor domains which are involved in modulation of activity have only begun to be investigated. In order to directly measure the role of G-protein-coupled receptor kinases (GRKs) in the desensitization of the m2 muscarinic acetylcholine receptor (m2 mAChR), a dominant-negative allele of GRK2 was used to inhibit receptor phosphorylation by endogenous GRK activity in a human embryonic kidney cell line. The dominant-negative GRK2K220R reduced agonist-dependent phosphorylation of the m2 mAChR by approximately 50% and prevented acute desensitization of the receptor as measured by the ability of the m2 mAChR to attenuate adenylyl cyclase activity. In contrast, the agonist-induced internalization of the m2 mAChR was unaffected by the GRK2K220R construct. Further evidence linking receptor phosphorylation to acute receptor desensitization was obtained when two deletions of the third intracellular loop were made which created m2 mAChRs that did not become phosphorylated in an agonist-dependent manner and did not desensitize. However, the mutant mAChRs retained the ability to internalize. These data provide the first direct evidence that GRK-mediated receptor phosphorylation is necessary for m2 mAChR desensitization; the likely sites of in vivo phosphorylation are in the central portion of the third intracellular loop (amino acids 282-323). These results also indicate that internalization of the m2 receptor is not a key event in desensitization and is mediated by mechanisms distinct from GRK phosphorylation of the receptor.

Carboxyl-terminal domains determine internalization and recycling characteristics of bombesin receptor chimeras

To investigate the role of the carboxy terminus in the regulation of the bombesin (BN) receptor, we constructed two chimeric receptors with carboxyl termini transferred from either m3 muscarinic cholinergic (m3 ACh) (BMC) or cholecystokinin A (CCKA) (BCC) receptors and expressed them in Chinese hamster ovary cells. Previous studies showed that agonist treatment caused rapid internalization of CCKA but not m3 ACh receptors in these cells. In the current study we conducted separate analyses of ligand and receptor internalization and analyzed receptor recycling. Ligand internalization was assessed using acid washing. BN and CCKA receptors internalized ligand with 80 +/- 3 and 85 +/- 7% in an acid-resistant compartment at equilibrium. Ligand internalization of chimeric receptors generally assumed the properties of the donor receptors. Thus, BCC receptors internalized ligand to a similar extent as wild-type CCKA receptors (75 +/- 3%), whereas, BMC receptors showed reduced ligand internalization (38 +/- 1%). Receptor internalization was more directly assessed by determining agonist-induced loss of surface binding. BN and CCKA receptors were largely internalized (56 +/- 8 and 50 +/- 7%, respectively). BCC receptors were also extensively internalized (82 +/- 3%). In contrast, BMC receptors were minimally internalized (22 +/- 8%). Receptor recycling was assessed as recovery from agonist induced loss of binding. BN, CCKA, and BMC receptors showed rapid recycling. In contrast, BCC receptors did not recycle. These data indicate that carboxyl-terminal structures determine both internalization of ligand-receptor complexes and subsequent receptor recycling.

Influence of second and third cytoplasmic loops on binding, internalization, and coupling of chimeric bombesin/m3 muscarinic receptors

In order to investigate the molecular basis for differences in the characteristics of bombesin (Bn) and m3 muscarinic cholinergic (m3 ACh) receptors, chimeric Bn receptors possessing cytoplasmic domains from the m3 ACh receptor were produced. The receptors were expressed in CHO-K1 cells and binding, structural, and signal transduction characteristics were analyzed. Cell lines bearing chimeric Bn receptors possessing m3 ACh receptor domains in place of either the second cytoplasmic loop (BM2L), the third cytoplasmic loop (BM3L), or both loops (BM23L) each bound 125I-bombesin with a single affinity that was approximately the same as that of the Bn receptor (5-10 nM). However, Bn receptors possessing the m3 ACh third cytoplasmic loop were severely affected in other respects. Internalization of ligand in Bn and BM2L cells was rapid and extensive (> 80% of bound 125I-bombesin was acid-resistant). In contrast, internalization was dramatically reduced in BM3L and BM23L cells (approximately 20% of bound 125I-bombesin was acid-resistant). In Bn or BM2L cells 10 nM bombesin stimulated approximately 10-fold increases in phosphatidylinositol hydrolysis. Activation of Bn receptors also induced an increase in arachidonic acid release (478 +/- 32% of control, n = 3) and large increases in intracellular Ca2+. In contrast, in BM3L or BM23L cells, bombesin had no significant effect on phosphatidylinositol hydrolysis. Furthermore, BM3L receptor activation did not increase arachidonic acid release. However, BM3L and BM23L cells showed a small increase in intracellular Ca2+ at high concentrations of bombesin. These data indicate that the third cytoplasmic loop alone, or together with the second cytoplasmic loop, was not sufficient to transfer the characteristics of G protein interaction between m3 ACh and bombesin receptors. Furthermore, for the Bn receptor, ligand internalization does, whereas formation of the high affinity binding state does not, appear to require activation of G proteins.

Agonist-induced loss of ligand binding is correlated with phosphorylation of cAR1, a G protein-coupled chemoattractant receptor from Dictyostelium

The parallel agonist-induced phosphorylation, alteration in electrophoretic mobility, and loss of ligand binding of a guanine nucleotide-binding regulatory protein (G protein)-coupled chemoattractant receptor from Dictyostelium (cAR1) depend upon a cluster of five C-terminal domain serine residues (Caterina, M. J., Hereld, D., and Devreotes, P.N. (1995) J. Biol. Chem. 270, 4418-4423). Analysis of mutants lacking combinations of these serines revealed that either Ser303 or Ser304 is required; mutants lacking both serines are defective in all of these responses. Interestingly, several mutants, including those substituted at only Ser299, Ser302, or Ser303 or at non-serine positions within the third cytoplasmic loop, displayed an unstable mobility shift; the alteration was rapidly reversed upon cAMP removal. These mutants also exhibited subnormal extents of loss of ligand binding, which is assessed after removal of the ligand. For the wild-type receptor, we found that the stability of phosphorylation depends upon the concentration and duration of agonist pretreatment. This suggests that, following phosphorylation of Ser303 or Ser304, cAR1 undergoes a further transition (EC50 approximately 140 nM, t 1/2 approximately 4 min) to a relatively phosphatase-resistant state. We used this insight to show that, under all conditions tested, the extent of loss of binding is correlated with the fraction of cAR1 in the altered mobility form. We discuss possible relationships between cAR1 phosphorylation and loss of ligand binding.

Activating and inactivating mutations in N- and C-terminal i3 loop junctions of muscarinic acetylcholine Hm1 receptors

The N- and C-terminal junctions of the third intracellular loop (i3) of G protein-coupled receptors play a role in the coupling process. We had previously constructed two triple point alanine mutants of the i3 junction of the muscarinic Hm1 receptor, W209A/I211A/Y212A and E360A/K362A/T366A, which are defective in mediating carbachol stimulation of phosphatidylinositol (PI) turnover (Moro, O., Lameh, J., Högger, P., and Sadée, W. (1993) J. Biol. Chem. 268, 22273-22276). Each of the corresponding six single point mutations were constructed to determine residues crucial to receptor coupling. Mutants W209A and T366A were similar to or only slightly less effective than wild type Hm1 in stimulating PI turnover. In the N-terminal junction, I211A and Y212A were defective in coupling, and I211A was even more defective than the corresponding triple mutant. Therefore, the triple mutation compensated at least partially for the effect of these two single point mutations. In the C-terminal i3 loop junction, mutant K362A was again more strongly defective than the corresponding triple mutant. In contrast, mutation E360A was found to be activating, leading to elevated PI turnover in the absence of agonist and sensitization toward carbachol activation. Activating mutations in the C-terminal i3 loop junction have been reported previously for the adrenergic receptors, but E360A represents the first muscarinic receptor with substantial basal activity. The effects of the single point mutations observed in this study were not readily predictable from similar mutations from closely related G protein-coupled receptors despite sequence conservation in the i3 loop junctions. Our results caution against defining precise coupling domains in these regions by mutagenesis results.

Carboxyl-terminal domains in the avian beta 1-adrenergic receptor that regulate agonist-promoted endocytosis

Most G protein-coupled receptors, including the mammalian beta 2-adrenergic receptor, are endocytosed to an intracellular, vesicular compartment upon continued exposure to agonist. The long form of the avian beta 1-adrenergic receptor, which contains a carboxyl-terminal 59-amino acid extension, does not undergo agonist-promoted endocytosis. We constructed and expressed turkey beta 1-adrenergic receptor cDNAs with regularly spaced carboxyl-terminal truncations and studied their agonist-promoted endocytosis. Removal of 34-86 amino acids from the carboxyl terminus of the turkey receptor allowed its efficient endocytosis, with optimal endocytosis observed upon removal of 59 residues. Removal of only 18 residues allowed some endocytosis. A receptor that lacks the entire carboxyl-terminal region (124 residues) was not endocytosed. We also constructed a chimeric hamster beta 2-adrenergic receptor with the added 59-residue carboxyl-terminal domain of the turkey receptor. The chimera was not significantly endocytosed. These data indicate that residues 450-465 in the carboxyl-terminal region of the beta 1-adrenergic receptor can act independently to block agonist-promoted endocytosis and that other carboxyl-terminal structures nearer to the seventh membrane span are required for endocytosis.

Signal transduction and ligand specificity of the human monocyte chemoattractant protein-1 receptor in transfected embryonic kidney cells

We have examined the ligand specificity and signal transduction pathways of a recently cloned receptor for monocyte chemoattractant protein-1 (MCP-1). In human 293 cells stably transfected with the MCP-1 receptor, MCP-1 bound specifically with high affinity (Kd = 260 pM) and induced a rapid mobilization of calcium from intracellular stores. The closely related chemokines MIP-1 alpha, MIP-1 beta, RANTES, interleukin 8 (IL-8), and Gro-alpha were inactive at concentrations as high as 300 nM. Activation of the MCP-1 receptor potently inhibited adenylyl cyclase with an IC50 = 90 pM. Activation of the MIP-1 alpha/RANTES receptor also mediated inhibition of adenylyl cyclase activity but with a different pharmacological profile: MIP-1 alpha (110 pM, IC50), RANTES (140 pM), MIP-1 beta (10 nM), and MCP-1 (820 nM). Mobilization of intracellular calcium and inhibition of adenylyl cyclase were blocked by pertussis toxin, suggesting that the MCP-1 receptor coupled to G alpha i. These results demonstrate that the MCP-1 receptor binds and signals in response to picomolar concentrations of MCP-1 in a highly specific manner. Signaling was manifested as mobilization of intracellular calcium and inhibition of adenylyl cyclase and was mediated by a pertussis toxin-sensitive G-protein(s).

Occupancy of the Dictyostelium cAMP receptor, cAR1, induces a reduction in affinity which depends upon COOH-terminal serine residues

Many G-protein-coupled receptors display a rapid decrease in ligand binding following pretreatment with agonist. cAR1, a cAMP receptor expressed early in the developmental program of Dictyostelium, mediates chemotaxis, activation of adenylyl cyclase, and gene expression changes that bring about the aggregation of 10(5) amoebae to form a multicellular structure. Occupancy of cAR1 by cAMP initiates multiple desensitization processes, one of which is an apparent reduction in binding sites. In transformed cells expressing cAR1 constitutively, Scatchard analyses revealed that this apparent loss of ligand binding is largely due to a significant reduction in the affinity of cAR1 for cAMP. A parallel increase in the dose dependence of cAR1-mediated cAMP uptake was observed. Consistent with these findings, proteolysis of intact cells and immunofluorescence suggested that cAR1 remains on the cell-surface following cAMP treatment. Finally, agonist-induced loss of ligand binding is impaired in cAR1 mutants lacking a cluster of cytoplasmic serine residues, which are targets of cAMP-induced phosphorylation.

Structure-function of muscarinic receptor coupling to G proteins. Random saturation mutagenesis identifies a critical determinant of receptor affinity for G proteins

To derive structure-function relationships for receptor-G protein coupling, libraries were created of human m5 muscarinic acetylcholine receptors (m5) randomly mutated in the C-terminal region of the third intracellular loop. Functional receptors were identified based on their ability to amplify NIH 3T3 cells in a ligand-dependent manner. These receptors either had wild-type phenotypes (Group 1) or were functionally impaired (Group 2). No "activated receptors" were identified. Tolerated substitutions in Group 2 receptors were randomly distributed and frequently included prolines and glycines. In contrast, tolerated substitutions in Group 1 receptors exhibited a periodicity proximal to transmembrane domain 6 were proline and glycine substitutions were not observed. These observations are consistent with a short alpha-helical extension of the C-terminal region of the third intracellular loop from transmembrane domain 6. Mutations at Ala-441 were most commonly associated with impaired function of Group 2 receptors. Twelve point mutations at Ala-441 were tested, and all caused marked increases in EC50 values with little effect on maximal response or agonist binding affinity. These results indicate that Ala-441 is a key determinant of m5 receptor affinity for G proteins and exists within the structural context of a short alpha-helix.

Thr-422 and Tyr-424 residues in the carboxyl terminus are critical for the internalization of the rat neurotensin receptor

In order to identify the amino acid sequences responsible for the internalization of the cloned rat brain neurotensin receptor, we carried out site-directed mutagenesis of the cDNA encoding the receptor followed by expression of the receptor into mammalian COS 7 cells. In cells transfected with the full-length neurotensin receptor, 56% of iodinated neurotensin specifically bound to the cells after 60 min of incubation at 37 degrees C was internalized. Deletions made in the third intracellular loop did not affect receptor internalization. By contrast, internalization was reduced to 5% of total in cells in which almost all the carboxyl-terminal tail of the receptor had been deleted (R392stop). In order to determine which part of the tail was responsible for this effect, several Ser and Thr residues were deleted in the carboxyl cytoplasmic sequence of the receptor. Almost all of these receptors were internalized as efficiently as the wild type. Only the form of the neurotensin receptor truncated at Glu-421 (deletion of the last three residues, TLY) produced a significant decrease in the amount of ligand internalized. Finally, point mutations of Thr-422 and Tyr-424 residues to Gly led to an almost complete loss of ligand internalization demonstrating the involvement of these 2 residues in the internalization process. Replacement of the last three amino acids by the cytoplasmic endocytosis signal of the vesicular stomatitis virus did not restore the efficiency of neurotensin receptor internalization. These biochemical results were confirmed by confocal microscopic analysis. Cell transfected with the wild type receptor showed a temperature-dependent intracellular accumulation of a fluorescent analog of neurotensin, whereas cells transfected with a receptor truncated at the carboxyl terminus showed a clustering of the fluorescent peptide at the cell surface.

The cytoplasmic tail of the G-protein-coupled receptor for parathyroid hormone and parathyroid hormone-related protein contains positive and negative signals for endocytosis

The present studies were done to evaluate the role of the cytoplasmic tail of the G-protein-coupled receptor for parathyroid hormone (PTH) and PTH-related protein (PTHrP) in the endocytosis of agonist-occupied receptors. PTH/PTHrP receptor mutants progressively truncated from the C terminus were expressed in COS-7 cells, and their ability to internalize 125I-PTHrP(1-34)amide was determined. Most of the C-terminal tail (91 of 127 residues) could be deleted without affecting internalization. However, further truncation removing residues 475-494 resulted in a 50-60% decrease in ligand internalization. A mutant with an internal deletion of these 20 amino acids showed a similar reduction in internalization, confirming the presence of a positive endocytic signal. No additional positive signals were found in the membrane-proximal region of the tail. However, alanine mutagenesis of the membrane-proximal residues 459-461 (EVQ-->AAA) resulted in a mutant PTH/PTHrP receptor displaying a 40% increase in ligand endocytosis, indicating that EVQ functions as a negative signal. Treatment of COS-7 cells with hypertonic sucrose (to disrupt clathrin lattices) markedly suppressed (by > 80%) PTH/PTHrP receptor internalization. These results demonstrate the presence of both positive and negative endocytic signals in the membrane-proximal cytoplasmic tail of the PTH/PTHrP receptor and suggest that these signals regulate the ability of the receptor to accumulate in clathrin-coated pits.

Role of carboxyl tail of the rat angiotensin II type 1A receptor in agonist-induced internalization of the receptor

Binding of angiotensin II (Ang II) to its receptor type 1A (AT1A) is known to trigger its internalization. We studied the role of cytosolic segments of AT1A in the internalization, and obtained results indicating a functional role of the cytosolic carboxyl terminal tail of AT1A in the internalization. Deletion of 50 amino acids from the carboxyl terminus abolished the receptor internalization. Deletion mutants lacking 13 and 32 amino acid residues in the carboxyl terminal cytosolic region were internalized to the same extent as wild type AT1A; however, internalization of a mutant lacking the last 42 residues was partially suppressed. Thus, residues 310 through 327 were shown to be essential for the internalization. We propose that a short domain in the cytoplasmic tail (residues 310 to 327) may play a dominant role in the agonist-induced receptor internalization of AT1A. Our results also suggest that the molecular determinants of the AT1A receptor involved in receptor internalization are distinct from those participating in the desensitization process.

Down-regulation and desensitization of the muscarinic M1 and M2 receptors in transfected fibroblast B82 cells

Murine fibroblast cell lines stably transfected with the rat muscarinic m1 or m2 receptor genes were used to study the homologous regulation of the muscarinic M1 or M2 receptors. The cells were pretreated with the muscarinic receptor agonists, (+)-cismethyl-dioxolane, carbachol, 2,8-dimethyl-3-methylene-1-oxa-8-aza-spiro- [4,5]decane ((+) or (-)-YM796) or the muscarinic receptor antagonist atropine for up to 24 h. Our study has demonstrated that the muscarinic receptor nonselective full agonist, (+)-cismethyl-dioxolane, induced the down-regulation of both the muscarinic M1 and the M2 receptors in association with desensitization of the receptor-mediated functions. The muscarinic M1 receptors are down-regulated without significant receptor internalization while the muscarinic M2 receptors are more sensitive to down-regulation than the muscarinic M1 receptors because of significant internalization of the muscarinic M2 receptors in our system. The muscarinic M1 receptor partial agonist, (-)-YM796 induced less down-regulation and no significant desensitization of the muscarinic M1 receptors with no substantial effect on the muscarinic M2 receptor density or function.

Internalization of the rat AT1a and AT1b receptors: pharmacological and functional requirements

The capacity of the angiotensin II (AngII) agonist [Sar1]AngII, the antagonist [Sar1-Ile8]AngII and the non-peptidic antagonist DuP753 to undergo receptor internalization were studied in Chinese hamster ovary cells expressing rat AngII type 1a or 1b receptors (AT1a or AT1b) or a mutant of AT1a (Asn74) unable to couple G-protein. In this expression system, the ligand-induced internalization of rat AT1a and AT1b are similar. Moreover, peptidic ligands, either the agonist or antagonist, induce a significant internalization of AT1 receptors, but the non-peptidic antagonist DuP753 is far less potent. Finally, the normal internalization of the mutant Asn74 demonstrates that receptor activation and G-protein coupling are not required for AT1a internalization.

Deletion analysis of the m4 muscarinic acetylcholine receptor. Molecular determinants for activation of but not coupling to the Gi guanine-nucleotide-binding regulatory protein regulate receptor internalization

In order to investigate whether coupling to and/or activation of guanine-nucleotide-binding proteins (G proteins) is involved in agonist-induced internalization of m4 muscarinic acetylcholine receptors (mAChRs), a deletion mutant [des-(264-394)mAChR] was constructed that lacks a substantial portion of the putative third intracellular loop. The wild-type receptor and des-(264-394)mAChR stably expressed in Chinese hamster ovary cells in essentially comparable amounts, exhibited identical antagonist-binding affinities. Consistent with the reported importance of the third cytoplasmic loop for Gi protein activation, the des-(264-394)mAChR showed a drastically reduced potential to mediate agonist-induced inhibition of adenylyl cyclase. In contrast, the ability of the mutant receptor to couple to Gi proteins was not impaired, as demonstrated by a similar guanine-nucleotide-sensitive and pertussis-toxin-sensitive high-affinity agonist-receptor binding for both mAChRs. In contrast, des-(264-394)mAChR was hardly able to stimulate the GTPase activity of G proteins, suggesting impaired activation of Gi proteins rather than ineffective coupling to Gi proteins. Internalization of wild-type receptor and des-(264-394)mAChR was observed with similar agonist concentrations and showed similar maximal values. However, des-(264-394)mAChR displayed a significantly reduced rate of receptor internalization. A similar attenuation of wild-type mAChR internalization was obtained upon pertussis toxin treatment. In conclusion, our data provide evidence that the molecular determinants of the m4 mAChR involved in Gi-protein coupling and activation are not identical and that activation of, but not coupling to, Gi proteins regulates m4 mAChR internalization.

Sequestration of muscarinic cholinergic receptors in permeabilized neuroblastoma cells

The feasibility of using a permeabilized preparation of human SH-SY-5Y neuroblastoma cells for studies of muscarinic acetylcholine receptor (mAChR) sequestration has been evaluated. Exposure of cells permeabilized with digitonin, streptolysin-O, or the alpha-toxin from Staphylococcus aureus to oxotremorine-M (Oxo-M) for 30 min resulted in a 25-30% reduction in the number of cell surface mAChRs, as monitored by the loss of N[3H]methylscopolamine ([3H]NMS) binding sites. The corresponding value for intact cells was 40%. For cells permeabilized with 20 microM digitonin, the Oxo-M-mediated reduction in [3H]NMS binding was time (t1/2 approximately 5 min) and concentration (EC50 approximately 10 microM) dependent and was agonist specific (Oxo-M > bethanechol = arecoline = pilocarpine). In contrast, no reduction in total mAChR number, as monitored by the binding of [3H]quinuclidinyl benzilate, occurred following Oxo-M treatment. The loss of [3H]NMS sites observed in the presence of Oxo-M was unaffected by omission of either ATP or Ca2+, both of which are required for stimulated phosphoinositide hydrolysis, but could be inhibited by the inclusion of guanosine 5'-O-(2-thiodiphosphate). mAChRs sequestered in response to Oxo-M addition were unmasked when the cells were permeabilized in the presence of higher concentrations of digitonin (80 microM).(ABSTRACT TRUNCATED AT 250 WORDS)

Routes of delivery of muscarinic acetylcholine receptors to the plasma membrane in NG108-15 cells

1. We have examined the routes of delivery of muscarinic acetylcholine receptors to the plasma membrane in unstimulated and agonist-stimulated NG108-15 cells. Delivery of receptors to the plasma membrane was measured by irreversible alkylating receptors already at the cell surface with propylbenzilylcholine mustard (PrBCM) and then following the recovery of binding of the polar radioligand [3H]-N-methylscopolamine ([3H]-NMS) in intact cells. 2. In unstimulated cells, recovery of [3H]-NMS binding after 2 h of incubation at 37 degrees C was 30% of binding in control cells. Binding affinity of [3H]-NMS was unchanged. In cells that had been pre-exposed to carbachol (0.5 mM) for 30 min, initial [3H]-NMS binding was reduced by 38% but recovery of binding was increased from 30% to 43% of control binding. 3. When the cells were pre-incubated for 1 h with the protein synthesis inhibitor cycloheximide (20 micrograms ml-1), recovery of [3H]-NMS binding was reduced by similar extents in unstimulated (30% to 9%) and carbachol-stimulated (43% to 19%) cells. Incubation of the cells at 20 degrees C instead of 37 degrees C reduced recovery of [3H]-NMS binding from 30% to 9% in unstimulated cells and from 43% to 23% in carbachol-stimulated cells. 4. Depletion of cellular ATP by addition of antimycin (50 nM) and deoxyglucose (50 mM), reduced recovery of binding to 12% in unstimulated cells and to 6% in carbachol-stimulated cells. 5. These results indicate that in unstimulated NG108-15 cells, delivery of muscarinic receptors to the plasma membrane is almost exclusively through the synthetic pathway. In agonist-stimulated cells,receptor sequestration into an intracellular compartment (probably endosomes) occurs. Under these circumstances, delivery of receptors to the plasma membrane along the synthetic route is unaffected but an additional route of delivery (recycling) now operates.

Location of agonist-dependent-phosphorylation sites in the third intracellular loop of muscarinic acetylcholine receptors (m2 subtype)

Muscarinic acetylcholine receptors (mAChR, human m2 subtype) expressed in Sf9 (Spodoptera frugiperda) cells using the baculovirus system were purified and subjected to phosphorylation by a mAChR kinase, which was partially purified from porcine cerebrum. Two bands with apparent molecular masses of 59 kDa and 39 kDa as determined by SDS/PAGE were found to be phosphorylated in an agonist-dependent manner. Both bands were labeled by the irreversible muscarinic ligand [3H]propylbenzilylcholine mustard. Molecular masses of the [32P]phosphorylated or [3H]propylbenzilylcholine-mustard-labeled bands decreased following treatment with N-glycanase. The 59-kDa and 39-kDa bands were converted to 52-kDa and 32-kDa bands, respectively, indicating that both the 59-kDa and 39-kDa bands contain the amino-terminal region where glycosylation sites are present. The ratio of incorporated [32P]phosphate and bound [3H]propylbenzilylcholine mustard was essentially the same for the 59-kDa and 39-kDa bands, indicating that all the phosphorylation sites reside in the sequence of 39 kDa from the amino-terminal region. The amounts of incorporated [32P]phosphate were estimated to be 10-11/receptor, with 7-8 serine and 3-4 threonine, but no phosphorylated tyrosine residues. Further treatment of [32P]phosphorylated or [3H]propylbenzilylcholine-mustard-labeled receptors with V8 protease indicated that the phosphorylation sites were not present in 30-kDa amino-terminal segment. These results indicate that the phosphorylation sites are localized in the range 30-39 kDa from the amino terminus, which consists of primarily the central part of the third intracellular loop. Consistent with this conclusion, a fusion protein containing glutathione S-transferase linked to a peptide corresponding to residues 227-324 of the central part of the third intracellular loop was found to be phosphorylated by the mAChR kinase in a heparin-sensitive manner.

From receptor internalization to nuclear translocation. New targets for long-term pharmacology

Receptors involved in intercellular communication at the cell surface share the capacity to desensitize through molecular and cellular mechanisms. Cellular desensitization is a rapid and dynamic process whereby membrane receptors internalize in response to an excess of agonists. The internalized receptors may recycle rapidly or undergo down-regulation when following a degradative pathway. However, receptor internalization does not necessarily mean degradation; it also represents the initial step of a retrograde signalling system whereby an "interiorized" message, the ligand-receptor complex, can be transported in contrast to second messengers, along axons or in the cytoplasm leading to long-term effects in the nucleus. Such "third messengers" have to undergo nuclear translocation to serve as transcriptional regulators in the control of gene expression. The "third messengers" are thus cytoplasmic proteins, including the receptor itself, which may be associated with internalized vesicles and released by mechanisms which have not yet been elucidated. They represent already good targets for the development of new drugs, and multi-targeting and synergistic approaches are likely to increase their usefulness.

Agonist-induced muscarinic cholinergic receptor internalization, recycling and degradation in cultured neuronal cells. Cellular mechanisms and role in desensitization

Short-term incubation of intact neuronal cells with muscarinic cholinergic agonists resulted in a rapid decrease of the specific binding of [3H]methylscopolamine to cell surface receptors indicative of receptor internalization. The agonists induced the internalization of both the muscarinic receptor subtypes coupled to adenylyl cyclase and those coupled to phosphoinositide turnover. Receptor internalization, which was inhibited at 0-4 degrees and by depletion of intracellular K+, is thought to occur through coated pits formation and was rapidly reversible. Receptor recycling did not imply protein synthesis. Down-regulation of muscarinic receptors occurred slowly in the presence of agonists, needed intact cytoskeleton (demonstrated by the inhibitory effect of colchicine) and involved lysosomal activity. Both receptor internalization and down-regulation were prevented by muscarinic receptor antagonists. Receptor internalization and down-regulation are agonist-induced cellular mechanisms that with receptor phosphorylation and uncoupling, may induce desensitization. These processes may contribute to complex intracellular regulatory processes and may be involved in some of the long-term effects of neurotransmitters (mainly neuropeptides and growth hormones) or drugs.