The effects of the peptide hormone oxytocin (OT) are mediated by the oxytocin receptor, which is a member of the G-protein-coupled receptor family. Defining differences between the binding of agonists and antagonists to the OTR, at the molecular level, is of fundamental importance to understanding OTR activation and to rational drug design. Previous reports have indicated that the N-terminus of the OTR is required for OT binding. The aim of this study was to identify which individual residues within the N-terminal domain of the human OTR provided these OT binding epitopes. A series of truncated OTRs and mutant receptor constructs with systematic alanine substitution were characterized with respect to their pharmacological profile and intracellular signaling capability. Although a number of residues within the OTR will be required for optimal OT-OTR interaction, our data establish that Arg(34) within the N-terminal domain contributes to high-affinity OT binding. Removal of Arg(34) by truncation or substitution resulted in a 2000-fold decrease in OT affinity. In addition, we show that the arginyl at this locus is required for high-affinity binding of agonists in general. However, the importance of Arg(34) is restricted to agonist interaction with the OTR, as it was not required for binding peptide antagonist or non-peptide antagonist. It is noteworthy that the corresponding Arg in the related rat V(1a) vasopressin receptor is also required for high-affinity agonist binding. This study defines, at the molecular level, the role of the N-terminus of the OTR in high-affinity agonist binding and identifies a key residue for this function.
A fundamental issue in molecular pharmacology is to define how agonist:receptor interaction differs from that of antagonist:receptor. The V(1a) receptor (V(1a)R) is a member of a family of related G-protein-coupled receptors that are activated by the neurohypophysial peptide hormone arginine-vasopressin (AVP). Here we define a short subdomain of the N-terminus of the V(1a)R from Glu(37) to Asn(47) that is an absolute requirement for binding AVP and other agonists. In marked contrast to the situation for agonists, deleting this segment has little or no effect on the binding of either peptide or non-peptide antagonists. In addition, we established that this subdomain was crucial for receptor activation and second messenger generation. The oxytocin receptor (OTR) also binds AVP with high affinity but exhibits a different pharmacological profile to the V(1a)R. Substitution of the N-terminus of the V(1a)R with the corresponding sequence from the OTR generated a chimeric receptor (OTR(N)-V(1a)R). The presence of the OTR N-terminus recovered high affinity agonist binding such that the OTR(N)-V(1a)R possessed almost wild-type V(1a)R pharmacology and signaling. Consequently, a domain within the N-terminus is required for agonist binding but it does not provide the molecular discriminator for subtype-selective agonist recognition. Cotransfection and peptide mimetic studies demonstrated that this N-terminal subdomain had to be contiguous with the receptor polypeptide to be functional. This study establishes that a segment of the V(1a)R N-terminus has a pivotal role in the mechanism of agonist binding and provides molecular insight into key differences between the interaction of agonists and antagonists with a peptide receptor family.
It is fundamentally important to define how agonist-receptor interaction differs from antagonist-receptor interaction. The V1a vasopressin receptor (V1aR) is a member of the neurohypophysial hormone subfamily of G protein-coupled receptors. Using alanine-scanning mutagenesis of the N-terminal juxtamembrane segment of the V1aR, we now establish that Glu54 (1.35) is critical for arginine vasopressin binding. The mutant [E54A]V1aR exhibited decreased arginine vasopressin affinity (1700-fold) and disrupted signaling, but antagonist binding was unaffected. Mutation of Glu54 had an almost identical pharmacological effect as mutation of Arg46, raising the possibility that agonist binding required a mutual interaction between Glu54 and Arg46. The role of these two charged residues was investigated by 1) substituting Glu54; 2) inserting additional Glu/Arg in transmembrane helix (TM) 1; 3) repositioning the Glu/Arg in TM1; and 4) characterizing the reciprocal mutant [R46E/E54R]V1aR. We conclude that 1) the positive/negative charges need to be precisely positioned in this N terminus/TM1 segment; and 2) Glu54 and Arg46 function independently, providing two discrete epitopes required for high-affinity agonist binding and signaling. This study explains why Glu and Arg, part of an -R(X3)L/V(X3)E(X3)L- motif, are conserved at these loci throughout this G protein-coupled receptor subfamily and provides molecular insight into key differences between agonist and antagonist binding requirements.
A Single Residue (Arg46) Located Within the N-Terminus of the V1aVasopressin Receptor Is Critical for Binding Vasopressin But Not Peptide or Nonpeptide Antagonists
A fundamental issue in molecular endocrinology is to define how agonist:receptor interaction differs from antagonist:receptor interaction. The vasopressin V1a receptor (V1aR) is a member of a subfamily of related G protein-coupled receptors that are activated by the hormone AVP or related peptides. The N-terminus of the V1aR has recently been shown to be critical for binding agonists but not antagonists. Using a combination of N-terminally truncated constructs and alanine-scanning mutagenesis, individual residues that provide these agonist-specific binding epitopes have now been identified in this study. Our data establish that a single residue, Arg46, is critical for AVP binding to the V1aR. Systematic substitution revealed that Arg was required at this locus and could not be substituted by Lys, Glu, Leu, or Ala. In contrast, antagonist binding (cyclic or linear, peptide or nonpeptide) was unaffected. Disruption of Arg46 also resulted in defective intracellular signaling. Arginine is conserved at this locus in all members of the neurohypophysial peptide hormone receptor family cloned to date, indicative of a fundamental role in receptor function. In addition to Arg46, the residues Leu42, Gly43, Asp45 form a patch contributing to AVP binding. This study provides molecular insight into the role of the V1aR N-terminus and key differences between agonist and antagonist binding requirements.
An arginyl in the N‐terminus of the V1a vasopressin receptor is part of the conformational switch controlling activation by agonist
Defining how the agonist-receptor interaction differs from that of the antagonist-receptor and understanding the mechanisms of receptor activation are fundamental issues in cell signalling. The V 1a vasopressin receptor (V 1a R) is a member of a family of related G-protein coupled receptors that are activated by neurohypophysial peptide hormones, including vasopressin (AVP). It has recently been reported that an arginyl in the distal N-terminus of the V 1a R is critical for binding agonists but not antagonists. To determine specific features required at this locus to support high affinity agonist binding and second messenger generation, Arg46 was substituted by all other 19 encoded amino acids. Our data establish that there is an absolute requirement for arginyl, as none of the [R46X]V 1a R mutant constructs supported high affinity agonist binding and all 19 had defective signalling. In contrast, all of the mutant receptors possessed wildtype binding for both peptide and nonpeptide antagonists. The ratio of K i to EC 50 , an indicator of efficacy, was increased for all substitutions. Consequently, although [R46X]V 1a R constructs have a lower affinity for agonist, once AVP has bound all 19 are more likely than the wildtype V 1a R to become activated. Therefore, in the wildtype V 1a R, Arg46 constrains the inactive conformation of the receptor. On binding AVP this constraint is alleviated, promoting the transition to active V 1a R. Our findings explain why arginyl is conserved at this locus throughout the evolutionary lineage of the neurohypophysial peptide hormone receptor family of G-protein coupled receptors. . The receptors that mediate the effects of these hormones are G-protein coupled receptors (GPCRs) and include the isotocin receptor, the mesotocin receptor, the oxytocin receptor (OTR), the vasotocin receptor and three subtypes of vasopressin receptor: V 1a , V 1b and V 2 (V 1a R, V 1b R and V 2 R respectively). In addition to the characteristic architecture of GPCRs [2], the neurohypophysial peptide hormone receptors exhibit certain conserved sequence motifs and share related pharmacologies (reviewed in [3][4][5][6]). This has allowed these receptors to be classified as a subfamily of GPCRs.The V 1a R mediates a plethora of responses to AVP in addition to the well-characterized vasopressor effect [3]. Consequently, this receptor subtype is widely distributed and generates nearly all of the physiological actions of AVP with the notable exceptions of antidiuresis (V 2 R) and adrenocorticotropic hormone secretion (V 1b R). This has been the stimulus for the development of a range of V 1a R antagonists, initially peptides [7] and more recently nonpeptides [8,9]. Although agonists and antagonists exhibit competitive binding to the V 1a R, only agonists promote the active receptor conformation with subsequent second messenger generation. Understanding how the agonistreceptor interaction differs from that of the antagonistreceptor and defining the mechanisms of receptor activation are fundamental issues in cel...
GPCRs (G-protein-coupled receptors) are a large family of structurally related proteins which mediate their effects by coupling to G-proteins. The V(1a)R (V(1a) vasopressin receptor) is a member of a family of related GPCRs that are activated by vasopressin {AVP ([Arg(8)]vasopressin)}, OT (oxytocin) and related peptides. These receptors are members of a subfamily of Family A GPCRs called the neurohypophysial peptide hormone receptor family. GPCRs exhibit a conserved tertiary structure comprising a bundle of seven TM (transmembrane) helices linked by alternating ECLs (extracellular loops) and ICLs (intracellular loops). The cluster of TM helices is functionally important for ligand binding, and, furthermore, activation of GPCRs involves movement of these TM helices. Consequently, it might be assumed that the extracellular face of GPCRs is composed of peptide linkers that merely connect important TM helices. However, using a systematic mutagenesis approach and focusing on the N-terminus and the second ECL of the V(1a)R, we have established that these extracellular domains fulfil a range of important roles with respect to GPCR signalling, including agonist binding, ligand selectivity and receptor activation.
A fundamental issue in molecular pharmacology is to define how agonist-receptor interaction differs from that of antagonist-receptor interaction. The V 1a vasopressin receptor (V 1a R) is a member of a family of related G-protein-coupled receptors (GPCRs) that are activated by vasopressin, oxytocin (OT) and related peptides. A segment of the N-terminus that was required for agonist binding, but not antagonist binding, was identified by characterizing truncated V 1a R constructs. Site-directed mutagenesis revealed that a single residue (Arg 46 ) was critical for agonist binding and receptor activation. The N-terminus of the related OT receptor (OTR) could recover agonist binding in a chimaeric OTR N -V 1a R construct. Furthermore, Arg 34 of the human OTR, which corresponds to Arg 46 of the rat V 1a R, provided agonist-specific binding epitopes in the OTR, indicating a conserved function of this locus throughout this GPCR subfamily. Mutation of Arg 46 revealed that high-affinity agonist binding had an absolute requirement for arginine at this position.
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