Marie‐Noëlle Balestre

To identify receptor functional domains underlying binding of the neurohypophysial hormones vasopressin (AVP) and oxytocin (OT), we have constructed a three-dimensional (3D) model of the V1a vasopressin receptor subtype and docked the endogenous ligand AVP. To verify and to refine the 3D model, residues likely to be involved in agonist binding were selected for site-directed mutagenesis. Our experimental results suggest that AVP, which is characterized by a cyclic structure, could be completely buried into a 15-20-A deep cleft defined by the transmembrane helices of the receptor and interact with amino acids located within this region. Moreover, the AVP-binding site is situated in a position equivalent to that described for the cationic neurotransmitters. Since all mutated residues are highly conserved in AVP and OT receptors, we propose that the same agonist-binding site is shared by all members of this receptor family. In contrast, the affinity for the antagonists tested, including those with a structure closely related to AVP, is not affected by mutations. This indicates a different binding mode for agonists and antagonists in the vasopressin receptor.

We investigated the mechanisms that regulate the efficacy of agonists in the arginine-vasopressin (AVP)/oxytocin (OT) receptor system. In this paper, we present evidence that AVP, a full agonist of the vasopressin receptors, acts as a partial agonist on the oxytocin receptor. We also found that AVP becomes a full agonist when two aromatic residues of the oxytocin receptor are replaced by the residues present at equivalent positions in the vasopressin receptor subtypes. Our results indicate that these two residues modulate the response of the oxytocin receptor to the partial agonist AVP.

We report on the pharmacological properties of a potent and selective linear vasopressin (AVP) V<sub>1a</sub> receptor antagonist HO-Phenylacetyl1-D-Tyr(Me)2-Phe3-Gln4-Asn5-Arg6-Pro7-Arg8-NH<sub>2</sub> (HO-LVA). Iodinated on the phenolic substituent at position 1, [125I]-HO-LVA displayed the highest affinity for rat liver V<sub>1a</sub> receptors (8 pM) ever reported. Furthermore, affinities of HO-LVA and I-HO-LVA for V<sub>1b</sub>, V<sub>2</sub> and oxytocin (OT) receptors was 400- to 1,000-fold lower than for V<sub>1a</sub> receptors, rendering it a highly selective ligand. Both HO-LVA and its iodinated derivative are V<sub>1a</sub> antagonists, they potently inhibited AVP-induced inositol-phosphate accumulation in WRK<sub>1</sub> cells, and also, although with a much lower potency, the AVP-induced ACTH release from freshly prepared pituitary cells. Using autoradiography [125I]-HO-LVA appeared to be the first radioligand to successfully identify and localize the presence of V<sub>1a</sub> receptors in rat liver and blood vessel walls. Moreover, several new brain regions expressing V<sub>1a</sub> receptors could be identified, in addition to those brain regions that were previously identified with other radiolabelled AVP analogues.

The substitution, in the human V2 vasopressin receptor, of the aspartate at position 136 by alanine leads to agonist-independent activation of this mutant V2 receptor. Pharmacological studies of the D136A V2 receptor helped us in characterizing different V2 receptor antagonists. SR-121463A and OPC-31260, two non-peptide antagonists, behaved as inverse agonists, while two cyclic peptides d(CH2)5[D-Tyr(Et)2,-Val4,Tyr-NH(2)9]AVP and d(CH2)5[D-Ile2,Ile4,Tyr-NH(2)9]AVP known to be V2 antagonists, demonstrated clear partial agonist properties. The finding of a constitutively activated human V2 receptor represents a useful tool in characterizing V2 receptor antagonist ligands.