Signal transduction by the human thyrotropin receptor: studies on the role of individual amino acid residues in the carboxyl terminal region of the third cytoplasmic loop.

We observed previously that the carboxyl-terminal region of the third loop of the TSH receptor (amino acid residues 617-625) is important in signal transduction. To analyze this region in more detail, in the present study we used site-directed mutagenesis to substitute, on an individual basis, the seven amino acids previously mutated as a group. These amino acids are either charged residues or potential phosphorylation sites. Six of the mutant TSH receptors with individual amino acid substitutions bound TSH with high affinity and displayed a cAMP response to TSH stimulation similar to the wild-type TSH receptor. The mutant receptor TSH-R-Gly625 (Arg----Gly) did not transduce a signal, but these results are noninformative because of the loss of high affinity TSH binding. The present data indicate that for each of the six informative amino acid substitutions, the individual residues are not critical for signal transduction. A corollary of this conclusion is that in the important carboxyl-terminal region of the third cytoplasmic loop of the TSH receptor multiple amino acid residues function as a unit.     

The second cytoplasmic loop of metabotropic glutamate receptor functions at the third loop position of rhodopsin.

G protein-coupled receptors identified so far are classified into at least three major families based on their amino acid sequences. For the family of receptors homologous to rhodopsin (family 1), the G protein activation mechanism has been investigated in detail, but much less for the receptors of other families. To functionally compare the G protein activation mechanism between rhodopsin and metabotropic glutamate receptor (mGluR), which belong to distinct families, we prepared a set of bovine rhodopsin mutants whose second or third cytoplasmic loop was replaced with either the second or third loop of Gi/Go- or Gq-coupled mGluR (mGluR6 or mGluR1). Among these mutants, the mutants in which the second or third loop was replaced with the corresponding loop of mGluR exhibited no G protein activation ability. In contrast, the mutant whose third loop was replaced with the second loop of Gi/Go-coupled mGluR6 efficiently activated Gi but not Gt: this activation profile is almost identical with those of the mutant rhodopsins whose third loop was replaced with those of the Gi/Go-coupled receptors in family 1 [Yamashita et al. (2000) J. Biol. Chem. 275, 34272-34279]. The mutant whose third loop was replaced with the second loop of Gq-coupled mGluR1 partially retained the Gi coupling ability of rhodopsin, which is in contrast to the fact that all the rhodopsin mutants having the third loops of Gq-coupled receptors in family 1 exhibit no detectable Gi activation. These results strongly suggest that the molecular architectures of rhodopsin and mGluR are different, although the G protein activation mechanism involving the cytoplasmic loops is common.     

Transport-dependent accessibility of a cytoplasmic loop cysteine in the human dopamine transporter

The effect of covalent sulfhydryl modification on dopamine uptake by the human dopamine transporter was determined by rotating disc electrode voltammetry. A transporter construct, X5C, with five mutated cysteines (C90A, C135A, C306A, C319F, and C342A) and the constructs into which the wild-type cysteines were substituted back into X5C, one at a time, all showed nearly normal binding affinity for [(3)H]CFT and for cocaine, but they displayed significant reductions in K(m) and V(max) for DA uptake. Reaction of Cys-90 or Cys-306 with impermeant methanethiosulfonate derivatives enhanced dopamine uptake to a similar extent as the previously observed enhancement of [(3)H]CFT binding caused by the same reaction, suggesting that cocaine may bind preferentially to a conformation in the transport cycle. m-Tyramine increased the rate of reaction of (2-aminoethyl)methanethiosulfonate (MTSEA) with X-A342C, the construct with a cytoplasmic loop residue Cys-342 restored. This m-tyramine-induced increase in reactivity appeared to require the inward transport rather than the outward transport or external binding of m-tyramine, and it was prevented by cocaine. Thus, inward translocation of substrates may involve structural rearrangement of hDAT, which likely exposes Cys-342 to reaction with MTSEA, and Cys-342 may be located on a part of the transporter associated with cytoplasmic gating.     

The cytoplasmic tail of the D1A receptor subtype: identification of specific domains controlling dopamine cellular responsiveness

In this study the rat D1A receptor (wild-type, WT) and truncation mutants thereof, are utilized to delineate specific cytoplasmic tail (CT) domains responsible for regulating ligand binding and receptor-mediated adenylyl cyclase activation. In human embryonic kidney (HEK) cells, all truncation mutants of the D1A receptor (Delta425, Delta379, Delta351) display cell surface localization and express at high but different receptor numbers. Binding studies suggest that residues located between Cys(351) and Asp(425) may serve to restrain the agonist binding conformation of the D1A receptor. This contention is supported by the observation that the constitutive activation of Delta351 is significantly increased in comparison with WT, Delta425 and Delta379. Furthermore, we demonstrate that the extent of dopamine-mediated maximal activation of adenylyl cyclase is significantly augmented in cells expressing Delta351 when compared with WT or mutants harboring shorter truncations. These results suggest that in addition to restraining receptor conformation, determinants located downstream of Cys(351) may act as negative regulators of the G protein coupling efficiency and adenylyl cyclase activation. Interestingly, all truncated receptors used in the present study display a decrease in dopamine potency when compared with WT. We show that inhibition of protein kinase A (PKA) activity leads also to a reduction in dopamine potency in cells expressing WT but not Delta351 receptors. These results hint at a potential previously unanticipated role for PKA in facilitating D1A receptor coupling efficiency in HEK cells. Overall, the present study has uncovered specific CT domains involved in regulating discrete aspects of the D1A receptor signaling.     

Agonist versus antagonist action of ATP at the P2Y4 receptor is determined by the second extracellular loop

UTP is a potent full agonist at both the human P2Y(4) (hP2Y(4)) and rat P2Y(4) (rP2Y(4)) receptor. In contrast, ATP is a potent full agonist at the rP2Y(4) receptor but is a similarly potent competitive antagonist at the hP2Y(4) receptor. To delineate the structural determinants of agonism versus antagonism in these species homologues, we expressed a series of human/rat P2Y(4) receptor chimeras in 1321N1 human astrocytoma cells and assessed the capacity of ATP and UTP to mobilize intracellular Ca(2+). Replacement of the NH(2) terminus of the hP2Y(4) receptor with the corresponding region of the rP2Y(4) receptor resulted in a receptor that was activated weakly by ATP, whereas replacement of the second extracellular loop (EL2) of the hP2Y(4) receptor with that of the rP2Y(4) receptor yielded a chimeric receptor that was activated fully by UTP and near fully by ATP, albeit with lower potencies than those observed at the rP2Y(4) receptor. These potencies were increased, and ATP was converted to a full agonist by replacing both the NH(2) terminus and EL2 in the hP2Y(4) receptor with the corresponding regions from the rP2Y(4) receptor. Mutational analysis of the five divergent amino acids in EL2 between the two receptors revealed that three amino acids, Asn-177, Ile-183, and Leu-190, contribute to the capacity of EL2 to impart ATP agonism. Taken together, these results suggest that the second extracellular loop and the NH(2) terminus form a functional motif that plays a key role in determining whether ATP functions as an agonist or antagonist at mammalian P2Y(4) receptors.     

Chromosomal localization of the human D3 dopamine receptor gene

Summary A novel dopamine D₃ receptor gene that may be involved in psychiatric diseases has recently been characterized. It has been assigned to chromosome 3 by hybridization with a D₃ receptor probe to human sorted chromosomes, and localized to band 3q 13.3 by in situ hybridization.     

Multiple residues in the second extracellular loop are critical for M3 muscarinic acetylcholine receptor activation

Recent studies suggest that the second extracellular loop (o2 loop) of bovine rhodopsin and other class I G protein-coupled receptors (GPCRs) targeted by biogenic amine ligands folds deeply into the transmembrane receptor core where the binding of cis-retinal and biogenic amine ligands is known to occur. In the past, the potential role of the o2 loop in agonist-dependent activation of biogenic amine GPCRs has not been studied systematically. To address this issue, we used the M(3) muscarinic acetylcholine receptor (M3R), a prototypic class I GPCR, as a model system. Specifically, we subjected the o2 loop of the M3R to random mutagenesis and subsequently applied a novel yeast genetic screen to identity single amino acid substitutions that interfered with M3R function. This screen led to the recovery of about 20 mutant M3Rs containing single amino acid changes in the o2 loop that were inactive in yeast. In contrast, application of the same strategy to the extracellular N-terminal domain of the M3R did not yield any single point mutations that disrupted M3R function. Pharmacological characterization of many of the recovered mutant M3Rs in mammalian cells, complemented by site-directed mutagenesis studies, indicated that the presence of several o2 loop residues is important for efficient agonist-induced M3R activation. Besides the highly conserved Cys(220) residue, Gln(207), Gly(211), Arg(213), Gly(218), Ile(222), Phe(224), Leu(225), and Pro(228) were found to be of particular functional importance. In general, mutational modification of these residues had little effect on agonist binding affinities. Our findings are therefore consistent with a model in which multiple o2 loop residues are involved in stabilizing the active state of the M3R. Given the high degree of structural homology found among all biogenic amine GPCRs, our findings should be of considerable general relevance.     

Voltage-sensitivity at the human dopamine D2S receptor is agonist-specific

Recently, we and others have shown that agonist potencies at some, but not all, G protein-coupled receptors are voltage-sensitive. Several of those studies employed electrophysiology assays in Xenopus oocytes with G protein-coupled potassium channels as a readout. Using this assay, we have now obtained evidence that voltage-sensitivity at the dopamine D_2S receptor is agonist-specific. Whereas the potency of dopamine at the D_2S receptor is decreased by depolarization, the potencies of β-phenethylamine, p- and m-tyramine are voltage-insensitive. Furthermore, both monohydroxylated and non-hydroxylated N,N-dipropyl-2-aminotetralin compounds are voltage-sensitive. Differential activation of G protein subtypes or differential ratios between effector and active G protein do not underlie this agonist-selective voltage-sensitivity. This is the first demonstration of voltage-sensitive and voltage-insensitive behaviour of different agonists acting via the same receptor.     

A novel constitutively active mutation in the second cytoplasmic loop of metabotropic glutamate receptor

G protein-coupled receptors have a common structural motif of seven transmembrane alpha-helices and are classified into different families showing no sequence similarity. Extensive studies have been conducted on the structure-function relationship in family 1 receptors, but those in other families have not been well studied. In this study, to investigate the molecular basis leading to the G protein activation by metabotropic glutamate receptor (mGluR), the member of family 3, we searched for the amino acid residues responsible for the G protein activation in the second cytoplasmic loop, which was thought to be the main G protein binding region. Analyses of the systematical mutations of Gi/Go-coupled mGluR8 revealed the presence of a constitutively active mutation in the C-terminal region of the second loop. The corresponding mutation in the second loop of Gq-coupled mGluR1 also exhibited high agonist-independent activity. These results indicate that there is a common constitutive active mutation site regardless of mGluR subtypes, suggesting that the structural change of the junction between the second cytoplasmic loop and helix IV is strongly linked to the formation of the active state.     

Amphotropic murine leukemia virus entry is determined by specific combinations of residues from receptor loops 2 and 4

Pit2 is the human receptor for amphotropic murine leukemia virus (A-MuLV); the related human protein Pit1 does not support A-MuLV entry. Interestingly, chimeric proteins in which either the N-terminal or the C-terminal part of Pit2 was replaced by the Pit1 sequence all retained A-MuLV receptor function. A possible interpretation of these observations is that Pit1 harbors sequences which can specify A-MuLV receptor function when presented in a protein context other than Pit1, e.g., in Pit1-Pit2 hybrids. We reasoned that such Pit1 sequences might be identified if presented in the Neurospora crassa protein Pho-4. This protein is distantly related to Pit1 and Pit2, predicted to have a similar membrane topology with five extracellular loops, and does not support A-MuLV entry. We show here that introduction of the Pit1-specific loop 2 sequence conferred A-MuLV receptor function upon Pho-4. Therefore, we conclude that (i) a functional A-MuLV receptor can be constructed by combining sequences from two proteins each lacking A-MuLV receptor function and that (ii) a Pit1 sequence can specify A-MuLV receptor function when presented in another protein context than that provided by Pit1 itself. Previous results indicated a role of loop 4 residues in A-MuLV entry, and the presence of a Pit2-specific loop 4 sequence was found here to confer A-MuLV receptor function upon Pho-4. Moreover, the introduction of a Pit1-specific loop 4 sequence, but not of a Pit2-specific loop 4 sequence, abolished the A-MuLV receptor function of a Pho-4 chimera harboring the Pit1-specific loop 2 sequence. Together, these data suggest that residues in both loop 2 and loop 4 play a role in A-MuLV receptor function. A-MuLV is, however, not dependent on the specific Pit2 loop 2 and Pit2 loop 4 sequences for entry; rather, the role played by loops 2 and 4 in A-MuLV entry can be fulfilled by several different combinations of loop 2 and loop 4 sequences. We predict that the residues in loops 2 and 4, identified in this study as specifying A-MuLV receptor function, are to be found among those not conserved among Pho-4, Pit1, and Pit2.     

Alternative transcripts of the rat and human dopamine D3 receptor

A cDNA for the rat dopamine D3 receptor containing a 113 bp deletion has been isolated. The segment deleted, encompassing the first extracellular loop and third transmembrane domain, alters the reading frame, introducing 19 amino acids not found in the full length receptor followed by a premature stop codon. This novel mRNA encodes a 109 amino acid protein containing two putative transmembrane domains. A similar variant cDNA for the human D3 receptor has also been identified.     

Vpu-induced degradation of CD4: requirement for specific amino acid residues in the cytoplasmic domain of CD4.

Two functions have been attributed to the product of the human immunodeficiency virus type 1 vpu open reading frame: it increases virion release from infected cells and induces rapid degradation of CD4 shortly after its synthesis. In the absence of Vpu, newly synthesized gp160 and CD4 associate in the endoplasmic reticulum (ER), forming a complex whose further maturation is blocked and which is eventually degraded. In studies using NL4-3-based expression vectors, it has been previously shown that Vpu induces the release of gp160 from the complex that it forms with CD4 in the ER. This release, which appears to be due to the rapid degradation of CD4 induced by Vpu, allows gp160 to transit to the Golgi, where it matures further. We investigated which regions of CD4 are important for its susceptibility to Vpu-induced degradation by transfecting HeLa cells with isogenic vpu-positive and vpu-negative proviruses and vectors expressing various truncated or mutated CD4 molecules. The results suggested that the cytoplasmic domain of CD4 contains a determinant lying within amino acids 418 to 425 that is critical for susceptibility to Vpu-induced degradation. Neither the phosphorylation sites in the cytoplasmic domain nor the Lck interaction region was required for the effect. Vpu-induced degradation was specific for CD4, since CD8, even when retained in the ER, was not degraded. In addition, under conditions of high-level Vpu expression, CD4 degradation could be observed in the absence of gp160 or other means of retaining CD4 in the ER.     

Internalisation of the mu-opioid receptor by endomorphin-1 and leu-enkephalin is dependant on aromatic amino acid residues

The opioid receptor system in the central nervous system controls a number of physiological processes, most notably pain. However, most opioids currently available have a variety of side-effects as well as exhibiting tolerance. Tolerance is most likely to be a complex phenomenon, however, the role of receptor internalisation is thought to play a crucial role. In this study, we examined the role of aromaticity in ligand-mediated receptor internalisation of the mu-opioid receptor (MOPR). These studies show that the amount of receptor internalisation may be dependant on the amphiphilicity of the ligand. Specifically, deletion of the C-terminus aromatic residues of endomorphin 1, particularly tryptophan reduces receptor-mediated internalisation whilst the addition of tryptophan within the enkephalin sequence increases receptor internalisation and decreases tolerance.     

Modification of amino acid residues in human serum albumin by myeloperoxidase

Myeloperoxidase is released from stimulated polymorphonuclear leukocytes at inflammatory loci. Besides its bactericidal activity, it interacts with human serum albumin that is essential for the endothelial uptake of myeloperoxidase and its contribution in regulation of the blood vessel tonus. Here, we investigated which kinds of modification dominate in the albumin protein by the myeloperoxidase-hydrogen peroxide system at physiological pH. In the presence of chloride, bromide, and nitrite, the myeloperoxidase-hydrogen peroxide system caused an oxidation, bromination, and nitrosylation/nitration of eight amino acid residues of albumin as detected by fragment analysis of tryptic digests with matrix-assisted laser desorption/ionisation time-of-flight mass spectrometry. An oxygen was incorporated into the methionines Met147, Met353, and Met572 as well as into the tryptophan Trp238. In the case of methionine residues, this oxygen was derived from the water phase as shown using 18O-enriched water. Nitrosylation/nitration was observed at the tryptophan Trp238 and the tyrosines Tyr162, Tyr425, and Tyr476 according to the mass shift of 29 Da and 45 Da. The incorporation of one or two bromines was found into the tyrosines Tyr425 and Tyr476. We did not observe any chlorination of albumin fragments. Thus, myeloperoxidase modifies in multiple ways amino acid residues in human serum albumin.     

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.     

Role of the second extracellular loop of human C3a receptor in agonist binding and receptor function

The C3a anaphylatoxin receptor (C3aR) is a G protein-coupled receptor with an unusually large second extracellular loop (e2 loop, approximately 172 amino acids). To determine the function of this unique structure, chimeric and deletion mutants were prepared and analyzed in transfected RBL-2H3 cells. Whereas replacement of the C3aR N-terminal segment with that from the human C5a receptor had minimal effect on C3a binding, substitution of the e2 loop with a smaller e2 loop from the C5a receptor (C5aR) abolished binding of 125I-C3a and C3a-stimulated calcium mobilization. However, as much as 65% of the e2 loop sequence (amino acids 198-308) may be removed without affecting C3a binding or calcium responses. The e2 loop sequences adjacent to the transmembrane domains contain multiple aspartate residues and are found to play an important role in C3a binding based on deletion mutagenesis. Replacement of five aspartate residues in the e2 loop with lysyl residues significantly compromised both the binding and functional capabilities of the C3a receptor mediated by intact C3a or by two C3a analog peptides. These data suggest a two-site C3a-C3aR interaction model similar to that established for C5a/C5aR. The anionic residues near the N and C termini of the C3aR e2 loop constitute a non-effector secondary interaction site with cationic residues in the C-terminal helical region of C3a, whereas the C3a C-terminal sequence LGLAR engages the primary effector site in C3aR.