Conserved aromatic residues in the transmembrane region VI of the V1a vasopressin receptor differentiate agonist vs. antagonist ligand binding.

Despite their opposite effects on signal transduction, the nonapeptide hormone arginine-vasopressin (AVP) and its V1a receptor-selective cyclic peptide antagonist d(CH2)5[Tyr(Me)2]AVP display homologous primary structures, differing only at residues 1 and 2. These structural similarities led us to hypothesize that both ligands could interact with the same binding pocket in the V1a receptor. To determine receptor residues responsible for discriminating binding of agonist and antagonist ligands, we performed site-directed mutagenesis of conserved aromatic and hydrophilic residues as well as nonconserved residues, all located in the transmembrane binding pocket of the V1a receptor. Mutation of aromatic residues of transmembrane region VI (W304, F307, F308) reduced affinity for the d(CH2)5[Tyr(Me)2]AVP and markedly decreased affinity for the unrelated strongly hydrophobic V1a-selective nonpeptide antagonist SR 49059. Replacement of these aromatic residues had no effect on AVP binding, but increased AVP-induced coupling efficacy of the receptor for its G protein. Mutating hydrophilic residues Q108, K128 and Q185 in transmembrane regions II, III and IV, respectively, led to a decrease in affinity for both agonists and antagonists. Finally, the nonconserved residues T333 and A334 in transmembrane region VII, controlled the V1a/V2 binding selectivity for both nonpeptide and cyclic peptide antagonists. Thus, because conserved aromatic residues of the V1a receptor binding pocket seem essential for antagonists and do not contribute at all to the binding of agonists, we propose that these residues differentiate agonist vs. antagonist ligand binding.

Fluorescent pseudo-peptide linear vasopressin antagonists: design, synthesis, and applications.

Fluoresceinyl and rhodamyl groups have been coupled by an amide link to side-chain amino groups at positions 1, 6, and 8 of pseudo-peptide linear vasopressin antagonists (Manning et al. Int. J. Pept. Protein Res. 1992, 40, 261-267) through different positions on the fluorophore, to give tetraethylrhodamyl-DTyr(Me)-Phe-Gln-Asn-Arg-Pro-Arg-Tyr-NH2 (2), 4-HOPh(CH2)2CO-DTyr(Me)-Phe-Gln-Asn-Lys(5-carboxyfl uoresceinyl)-Pro-A rg-NH2 (4), 4-HOPh(CH2)2CO-DTyr(Me)-Phe-Gln-Asn-Lys(5- or 6-carboxytetramethylrhodamyl)-Pro-Arg-NH2 (5, 6), 4-HOPh(CH2)2CO-DTyr(Me)-Phe-Gln-Asn-Arg-Pro-Lys(5- or 6- carboxyfluoresceinyl)-NH2 (8, 9), and 4-HOPh(CH2)2CO-DTyr(Me)-Phe-Gln-Asn-Arg-Pro-Lys(5- or 6- carboxytetramethylrhodamyl)-NH2 (10, 11). The closer to the C-terminus the fluorophore, the higher the affinities of the fluorescent derivatives for the human vasopressin V1a receptor transfected in CHO cells. The compound 10 has a Ki of 70 pM, as determined by competition experiments with [125I]-4-HOPhCH2CO-DTyr(Me)-Phe-Gln-Asn-Arg-Pro-Arg-NH2. It showed a good selectivity for human V1a receptor versus human OT (Ki = 1.2 nM), human vasopressin V1b (Ki approximately 27 nM), and human vasopressin V2 (Ki > 5000 nM) receptor subtypes. All fluorescent analogues were antagonists as shown by the inhibition of vasopressin induced inositol phosphate accumulation. These fluorescent ligands are efficient for labeling cells expressing the human V1a receptor subtype, as shown by flow cytofluorometric experiments or fluorescence microscopy. They are also appropriate tools for structural analysis of the vasopressin receptors by fluorescence.

Identification of residues responsible for the selective binding of peptide antagonists and agonists in the V2 vasopressin receptor.

To improve our understanding of the functional architecture of G protein-coupled receptors, we have taken advantage of differences among mammalian species in ligand binding to search for the rat versus human selectivity determinants of the V2 vasopressin receptor and of its peptide ligands. Our data indicate that residue 2 of species-selective peptide antagonists such as d(CH2)5-[D-Ile2,Ile4, Tyr-NH29]arginine vasopressin controls their rat versus human selectivity. For species-selective agonists such as desmopressin, residues 1 and 8 modulate the binding selectivity. Among residues different between rat and human V2 receptors, those localized in the upper part of the human V2 receptor have been substituted with their rat V2 homologs. Pharmacological analysis of mutant receptors revealed that residues 202 and 304 fully control the species selectivity of the discriminating antagonists in an independent and additive manner. A third residue (position 100) is necessary to observe an equivalent phenomenon for the discriminating agonists. The substitution of these three residues does not modify the affinity of the nonselective agonists and antagonists. In conclusion, extracellular loops and the top of the transmembrane domains of V2 vasopressin receptors may provide the molecular basis for peptide ligand-binding species selectivity. Very few residues in these regions may control the binding mode of both agonists and antagonists.

Functional studies of twelve mutant V2 vasopressin receptors related to nephrogenic diabetes insipidus: molecular basis of a mild clinical phenotype.

X-linked nephrogenic diabetes insipidus (NDI) is a rare disease with defective renal and extrarenal arginine vasopressin V2 receptor responses due to mutations in the AVPR2 gene in Xq28. To study the cause of loss of function of mutant V2 receptors, we expressed 12 mutations (N55H, L59P, L83Q, V88M, 497CC-->GG, deltaR202, I209F, 700delC, 908insT, A294P, P322H, P322S) in COS-7 cells. Eleven of these, including P322H, were characterized by a complete loss of function, but the mutation P322S demonstrated a mild clinical and in vitro phenotype. This was characterized by a late diagnosis without any growth or developmental delay and a significant increase in urine osmolality after intravenous 1-deamino[D-Arg8]AVP administration. In vitro, the P322S mutant was able to partially activate the Gs/adenylyl cyclase system in contrast to the other V2R mutants including P322H, which were completely inactive in this regard. This showed not only that Pro 322 is important for proper V2R coupling, but also that the degree of impairment is strongly dependent on the identity of the substituting amino acid. Three-dimensional modeling of the P322H and P322S mutant receptors suggested that the complete loss of function of the P322H receptor could be due, in part, to hydrogen bond formation between the His 322 side chain and the carboxyl group of Asp 85, which does not occur in the P322S receptor.

The D136A mutation of the V2 vasopressin receptor induces a constitutive activity which permits discrimination between antagonists with partial agonist and inverse agonist activities.

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.

Two aromatic residues regulate the response of the human oxytocin receptor to the partial agonist arginine vasopressin.

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.

The binding site of neuropeptide vasopressin V1a receptor. Evidence for a major localization within transmembrane regions.

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.

Characterization of a novel, linear radioiodinated vasopressin antagonist: an excellent radioligand for vasopressin V1a receptors.

We report on the pharmacological properties of a potent and selective linear vasopressin (AVP) V1a receptor antagonist HO-Phenylacetyl1-D-Tyr(Me)2-Phe3-Gln4-Asn5-Arg6-Pro7-Arg8-NH2 (HO-LVA). Iodinated on the phenolic substituent at position 1, [125I]-HO-LVA displayed the highest affinity for rat liver V1a receptors (8 pM) ever reported. Furthermore, affinities of HO-LVA and I-HO-LVA for V1b, V2 and oxytocin (OT) receptors was 400- to 1,000-fold lower than for V1a receptors, rendering it a highly selective ligand. Both HO-LVA and its iodinated derivative are V1 antagonists, they potently inhibited AVP-induced inositol-phosphate accumulation in WRK1 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 V1a receptors in rat liver and blood vessel walls. Moreover, several new brain regions expressing V1a receptors could be identified, in addition to those brain regions that were previously identified with other radiolabelled AVP analogues.

Tyr115 is the key residue for determining agonist selectivity in the V1a vasopressin receptor.

Using a three-dimensional model of G protein-coupled receptors (GPCR), we have previously succeeded in docking the neurohypophysial hormone arginine-vasopressin (AVP) into the V1a receptor. According to this model, the hormone is completely embedded in the transmembrane part of the receptor. Only the side chain of the Arg residue at position 8 projects outside the transmembrane core of the receptor and possibly interacts with a Tyr residue located in the first extracellular loop at position 115. Residue 8 varies in the two natural neurohypophysial hormones, AVP and oxytocin (OT); similarly, different residues are present at position 115 in the different members of the AVP/OT receptor family. Here we show that Arg8 is crucial for high affinity binding of AVP to the rat V1a receptor. Moreover, when Tyr115 is replaced by an Asp and a Phe, the amino acids naturally occurring in the V2 and in the OT receptor subtypes, the agonist selectivity of the V1a receptor switches accordingly. Our results indicate that the interaction between peptide residue 8 and the receptor residue at position 115 is not only crucial for agonist high affinity binding but also for receptor selectivity.

Identification of agonist binding sites of vasopressin and oxytocin receptors.

The present study aims at delineating residues in the vasopressin/oxytocin receptor family responsible for the high affinity binding of the hormone. Therefore, we have constructed a computer-generated 3 dimensional model of the rat V1a vasopressin receptor subtype which allowed us to propose residues likely to be involved in agonist binding. Among these residues, several are highly conserved in the receptor family. They were selected for site-directed mutagenesis on the basis of putative direct interaction with bound ligands. The present model and experimental results led us to conclude that the hormone is docked in a pocket completely buried in the transmembrane core of the receptor. Large polar residues, such as glutamine and lysine, located in transmembrane regions 2,3,4 and 6 are involved in the binding of the neurohypophysial hormone. Since all the mutated residues are highly conserved in AVP and OT receptors, we propose that the agonist binding site is similar in all members of the receptor family; only minor changes were found in antagonist potencies, suggesting that agonist and antagonist binding sites do not completely overlap.

Molecular basis for agonist selectivity in the vasopressin/oxytocin receptor family.

Vasopressin (AVP) and oxytocin (OT) are two nonapeptides differing at position 3, in the cyclic part of the peptide, and at position 8, in the C-terminal tripeptide. In this study, we have evaluated the interactions between these two positions of the hormones and the oxytocin receptor (OTR), the V1a and the V2 vasopressin receptors. The contribution of these two positions to receptor selectivity was analyzed by using several peptide analogues bearing substitutions at either position 3 or 8. The putative interactions between receptor residues and hormone residues at position 3 and 8 were then deduced by using a three dimensional model of the neurohypophysial hormones docked into their respective receptors. On the basis of this model, we found that the lateral chain of residue 8 might interact with residues located in the first extracellular loop. By using site-directed mutagenesis on the cloned receptors, we identified a non-conserved residue in the first extracellular loop that interacts with the lateral chain of residue 8 in the hormone. We demonstrated that this interaction is crucial for receptor selectivity to the different agonists.

A model for studying regulation of aldosterone secretion: freshly isolated cells or cultured cells?

Practically all studies relating to zona glomerulosa function have been performed either with freshly isolated cells or with cells used after 2 or 3 days in culture. This study compares the step-by-step response (binding, second messenger production and aldosterone response) of isolated glomerulosa cells vs cells maintained in primary culture to the main stimuli of aldosterone secretion. One day in culture induces a decrease of 77 and 65% in the basal level of corticosterone and aldosterone secretions, compared to that observed in freshly isolated cells. In these conditions, the cells become more sensitive to most of their stimuli, but not all: e.g. important differences are noted in the dose-response of aldosterone secretion to adrenocorticotropin (ACTH), which is often shifted to a lower concentration sensitivity in cultured cells. For example, 0.1 nM ACTH stimulates steroid secretion by three-fold in isolated cells while 1 pM ACTH already induces a 25 and nine-fold increase, respectively, in corticosterone and aldosterone output in cultured cells. Moreover, some stimuli such as isoproterenol do not have any effect in isolated cells but do stimulate steroid secretion in cultured cells. In contrast, other stimuli, such as serotonin or DA (via DA2 receptors) act preferentially in freshly isolated cells. The main observation derived from this study is that glomerulosa cells, under appropriate conditions, are able to respond to their main secretagogues even after 4 days in culture. At this time, glomerulosa cells maintain their ultrastructural characteristics and functional properties and, aside from a few exceptions, demonstrate higher sensitivity to their known stimuli.(ABSTRACT TRUNCATED AT 250 WORDS)

Upregulation of V1a vasopressin receptors by glucocorticoids.

WRK1 cells (a rat mammary tumor cell line) exhibit a vasopressinergic receptor of V1a subtype tightly coupled to phospholipase C. Addition of dexamethasone to the culture medium principally potentiated the vasopressin-sensitive accumulation of inositol phosphates and to a lesser extent the NaF-sensitive phospholipase C activity. On the opposite, such treatment was without effect on the basal level of intracellular inositol phosphates or on bradykinin- or serotonin-sensitive phosphoinositide metabolisms. Glucocorticoid receptors were probably involved in these actions since dexamethasone was found to be more potent than aldosterone or corticosterone. Dexamethasone treatment also increased the number of vasopressin binding sites without affecting its affinity for vasopressin or other specific vasopressin analogues. These results strongly suggest that dexamethasone principally acts at the vasopressin receptor level by affecting its synthesis and/or the translation of its mRNA and also affects the G protein that couples the V1a receptor to the phospholipase C. These results explain how glucocorticoids may regulate the transduction mechanisms involved in vasopressin actions on WRK1 cells. They provide explanations for understanding the cross talk between adrenal steroids and hormones, which mobilize intracellular calcium.

Fluorescent peptide hormones: development of high affinity vasopressin analogues.

Highly potent and specific peptide hormone analogues with fluorescent reporter groups are current research goals. Until now, however, only moderately potent analogues have been described. We report here several types of vasopressin (VP) analogues with different fluorophores attached to the peptide. In a first series, fluorophores were attached to the free epsilon amino function of [des-amino1-lysine8]VP (dLVP), producing agonistic analogues. In a second series, reporter groups were added to the N-terminal of open-chain antagonist structures. The biological activities of these analogues were assessed by two different sets of experiments: 1) The measurement of their binding affinities towards the V1a-vasopressin receptor subtype from WRK1 cells or rat liver membrane preparations; 2) Their ability to stimulate the phospholipase C activity in WRK1 cells. As expected, a simple acylation of fluorophores to dLVP resulted in a considerable loss of affinity. If however, the Lys8 side chain was extended through double Schiff-base formation with glutaraldehyde-ethylenediamine followed by reduction to an aminoalkyl aminoalkylamine, single fluorophores could be added without loss of affinity compared to VP. The open-chain analogues, on the other hand, while displaying weak affinity, nevertheless exhibited pure antagonistic behavior.

Mechanisms involved in the interaction of dopamine with angiotensin II on aldosterone secretion in isolated and cultured rat adrenal glomerulosa cells.

In a previous study, we have shown that freshly isolated glomerulosa cells possess dopamine (DA) receptors from both DA-1 and DA-2 subclasses, whereas in cultured conditions, cells exhibit dopamine receptors from the DA-1 subclass only. In the present work, we have studied the effect of DA on angiotensin-stimulated glomerulosa cells in these two experimental conditions. Our results demonstrate that in isolated cells, angiotensin II (AT) stimulates inositol phosphate accumulation, calcium influx and steroid secretion. Treatment with pertussis toxin completely blocks AT-stimulated steroid secretion and calcium influx and partially reduces inositol phosphate accumulation. DA alone has no effect on cAMP accumulation. However, in the presence of a specific DA-1 antagonist (SCH 23390), DA reduces intracellular cAMP content. Similarly, DA-like pertussis toxin produces the same inhibitory effects on AT-stimulated cells. The combined influence of DA and pertussis toxin is not additive suggesting that a 'Gi' GTP-binding protein is involved in the DA action. Specific DA antagonists indicate that these inhibitory processes are mediated through the DA-2 receptor subtype. DA may act by decreasing the intracellular calcium concentration since it reduces AT-stimulated Ca2+ influx and that both phospholipase C (PLC) and steroid accumulation are calcium dependent. Yet a direct inhibitory coupling between the DA-2 receptor and PLC may represent a second alternative since DA inhibitory effects are always present when calcium influx is artificially increased or decreased. In cultured cells, we observe an additive effect of DA and AT on aldosterone secretion, which is the result of additive interactions of the second messengers involved, namely cAMP for dopamine and inositol phosphates for angiotensin II. From these studies, we conclude that DA may exert a more versatile effect on aldosterone secretion than previously suspected.

Involvement of protein kinase C in the coupling between the V1 vasopressin receptor and phospholipase C in rat glomerulosa cells: effects on aldosterone secretion.

We have previously shown that arginine vasopressin (AVP) possesses specific binding sites on rat adrenal glomerulosa cells and stimulates phosphoinositide breakdown and accumulation of inositol phosphates (IP) and diacylglycerol. Kinetic experiments also revealed that the production of IP declines rapidly under hormonal stimulation, even in the presence of Ca2+ in the external medium. In the present investigation, we studied the effects of a protein kinase C (PKC) activator phorbol ester (PDBu) on AVP-sensitive accumulation of IP. Experiments were conducted on glomerulosa cells cultured for 3 days. Results show that short term preincubation (5-10 min) with PDBu inhibits AVP-stimulated IP accumulation by 50% (ED50 = 2.6 +/- 0.9 nM). PKC most likely acts on the coupling between AVP receptor and the G-protein since PDBu reduces AVP-sensitive phospholipase C but does not alter either NaF-sensitive phospholipase C, AVP binding, or inositol lipid pools. However, after a 1- or 2-h preincubation with AVP or PDBu, a decrease in both IP accumulation and AVP binding capacity is observed. With regard to aldosterone secretion, PDBu alone stimulates hormone output, but when added simultaneously with AVP, it inhibits AVP-stimulated aldosterone secretion by 70%. If cells are allowed a resting period of 14 h after AVP or PDBu treatment, the AVP response (IP accumulation, AVP binding, and aldosterone output) is recovered and even enhanced. All these effects are specific since the inactive phorbol ester 4 alpha PDD is inactive, and staurosporine (a PKC inhibitor) reverses the PDBu effect. AVP stimulates transiently the translocation of PKC from the cytosol to the membrane, suggesting that the effect observed with PDBu reflects the effect of endogenous PKC stimulated by AVP. These results outline the complexities involved during hormonal stimulation and, at the same time, homologous desensitization phenomena. On one hand, acute treatment with PDBu--which induces PKC activation--is able to stimulate aldosterone secretion but at the same time initiate desensitization, since phorbol ester uncouples the AVP receptor from the coupling G protein. This suggests that PKC may participate in the first step of homologous desensitization. On the other hand, a 2-h incubation with PDBu induces a loss of AVP binding sites. This may represent the second step of homologous desensitization. Finally, a long term treatment with PDBu completely inactivates PKC, hence enabling AVP to further stimulate aldosterone secretion.

Dual effects of dopamine in rat adrenal glomerulosa cells.

The effects of dopamine (DA) on cAMP production and aldosterone secretion were compared in freshly isolated cells and in primary cultures of rat adrenal glomerulosa cells. Under isolated conditions, glomerulosa cells exhibited dopamine receptors from DA-1 and DA-2 subclass, whereas in cultured conditions, where cells are very sensitive to their known stimuli, cells only exhibited dopamine receptors from the DA-1 subclass. Moreover, unlike freshly isolated cells, dopamine stimulated both cAMP production and aldosterone secretion in 3-day cultured preparations. These effects were receptor specific since they were completely suppressed by Scherring 23390 (a specific DA-1 antagonist) and were unaffected by a beta-adrenergic antagonist. As in vivo rat adrenal cortex contains DA, we discuss a possible involvement of this neurotransmitter in the regulation of aldosterone secretion.

Involvement of distinct G-proteins in the action of vasopressin on rat glomerulosa cells.

We have previously shown that vasopressin (VP) induces breakdown of membrane phosphoinositides in adrenal glomerulosa cells. In the present study we demonstrate that the accumulation of inositol phosphates (IP) measured in the presence of arginine vasopressin (AVP) is reduced if the cells are incubated in a calcium-free medium. This effect cannot be accounted for by modification of VP binding, reduction of inositol lipid labeling, or stimulation of inositol, 1,4,5,-triphosphate 5-monophosphatase. It mainly affects phospholipase-C activity, since this enzyme is highly sensitive to calcium. Ionomycine and nifedipine, which, respectively, increase and decrease the intracellular calcium concentration, also, respectively, stimulate and inhibit IP accumulation. In membranes prepared from pertussis toxin (IAP)-treated cells, AVP stimulates inositol monophosphate accumulation to the same extent as in membranes derived from untreated cells. However, in intact cells, IAP decreases the inositol monophosphate accumulation. This decrease probably involves calcium influx, since we show that AVP stimulates a unidirectional calcium influx, which is completely blocked by IAP treatment. In rat adrenal glomerulosa cells, the AVP-stimulated secretion of aldosterone is mainly under the control of calcium, since a full inhibition of its secretion is observed under conditions in which the calcium influxes are completely suppressed despite a sustained accumulation of IP (calcium depletion or IAP treatment). Together, these results signify that VP acts on rat glomerulosa cells by two distinct mechanisms: calcium influx, which is IAP sensitive, and phosphoinositide turnover, which is IAP insensitive.