Stoytcho Stoev

Time-resolved FRET between GPCR ligands reveals oligomers in native tissues

G protein-coupled receptor (GPCR) oligomers have been proposed to play critical roles in cell signaling, but confirmation of their existence in a native context remains elusive, as no direct interactions between receptors have been reported. To demonstrate their presence in native tissues, we developed a time-resolved FRET strategy that is based on receptor labeling with selective fluorescent ligands. Specific FRET signals were observed with four different receptors expressed in cell lines, consistent with their dimeric or oligomeric nature in these transfected cells. More notably, the comparison between FRET signals measured with sets of fluorescent agonists and antagonists was consistent with an asymmetric relationship of the two protomers in an activated GPCR dimer. Finally, we applied the strategy to native tissues and succeeded in demonstrating the presence of oxytocin receptor dimers and/or oligomers in mammary gland.

Peptide and non-peptide agonists and antagonists for the vasopressin and oxytocin V1a, V1b, V2 and OT receptors: research tools and potential therapeutic agents☆

Oxytocin (OT) and vasopressin (AVP) mediate their biological actions by acting on four known receptors: The OT (uterine) and the AVP V(1a) (vasopressor), V(1b) (pituitary), V(2) (renal) receptors and a fifth putative AVP V(1c)? (vasodilating) receptor. This presentation will summarize some highlights of the recent progress, in the design and synthesis of selective peptide agonists, antagonists, radioiodinated ligands, fluorescent ligands and bivalent ligands for these receptors. Here we present published and unpublished pharmacological data on the most widely used agonists, antagonists and labelled ligands. The pharmacological properties of promising new selective OT antagonists and V(1b) agonists are also presented. This review should serve as a useful guide for the selection of the most appropriate ligand for a given study. The current status of non-peptide OT and AVP antagonists and agonists is also summarized. The relative merits of peptide and non-peptide AVP and OT agonists and antagonists as: (1) research tools and (2) therapeutic agents will be evaluated. Many of the receptor selective peptide agonists and antagonists from this and other laboratories are far more widely used as pharmacological tools for studies on the peripheral and central effects of OT and AVP than their non-peptide counterparts. In addition to OT and to a lesser extent AVP (pitressin), a number of OT and AVP analogues; such as carbetocin (OT agonist) dDAVP (desmopressin, V(2) agonist), terlipressin (V(1a) agonist), felypressin (V(1a) agonist) and atosiban (Tractocile OT antagonist) are also in clinical use. Despite much early promise, no non-peptide V(1a) or OT antagonists are currently in clinical trials. While a number of orally active non-peptide V(2) antagonists (Vaptans); notably, Tolvaptan, Lixivaptan and Satavaptan, are currently in Phase III clinical trials; to date, only the mixed V(2)/V(1a), antagonist Conivaptan (Vaprisol), has been approved by the US FDA for clinical use (by i.v. administration), for the treatment of euvolemic and hypervolemic hyponatremia in hospitalized patients. Promising new non-peptide V(1b) and OT antagonists, as well as non-peptide V(2) and OT agonists are now in pre-clinical development.

Oxytocin and Vasopressin Agonists and Antagonists as Research Tools and Potential Therapeutics

We recently reviewed the status of peptide and nonpeptide agonists and antagonists for the V1a, V1b and V2 receptors for arginine vasopressin (AVP) and the oxytocin receptor for oxytocin (OT). In the present review, we update the status of peptides and nonpeptides as: (i) research tools and (ii) therapeutic agents. We also present our recent findings on the design of fluorescent ligands for V1b receptor localisation and for OT receptor dimerisation. We note the exciting discoveries regarding two novel naturally occurring analogues of OT. Recent reports of a selective VP V1a agonist and a selective OT agonist point to the continued therapeutic potential of peptides in this field. To date, only two nonpeptides, the V2/V1a antagonist, conivaptan and the V2 antagonist tolvaptan have received Food and Drug Administration approval for clinical use. The development of nonpeptide AVP V1a, V1b and V2 antagonists and OT agonists and antagonists has recently been abandoned by Merck, Sanofi and Pfizer. A promising OT antagonist, Retosiban, developed at Glaxo SmithKline is currently in a Phase II clinical trial for the prevention of premature labour. A number of the nonpeptide ligands that were not successful in clinical trials are proving to be valuable as research tools. Peptide agonists and antagonists continue to be very widely used as research tools in this field. In this regard, we present receptor data on some of the most widely used peptide and nonpeptide ligands, as a guide for their use, especially with regard to receptor selectivity and species differences.

Discovery and design of novel and selective vasopressin and oxytocin agonists and antagonists: the role of bioassays.

Synthetic oxytocin and vasopressin agonists and antagonists have become important tools for research and were instrumental in the identification of the four known receptor subtypes, V1a, V2, V1b (V3) and oxytocin, of these peptide hormones. However, the relative lack of receptor selectivity, particularly of the antagonists, has limited their usefulness as experimental probes and their potential as therapeutic agents. We now present some findings from our continuing studies aimed at the design of more selective oxytocin and vasopressin agonists and antagonists and a structure‐activity relationship update on our recently discovered novel hypotensive vasopressin peptides. Bioassays have been, and continue to be, of critical importance in leading to the discovery of the novel agonists, antagonists and hypotensive peptides reported here. This paper highlights three main aspects of these studies. (1) Replacement of the tyrosine2 and/or phenylalanine3 residues in the V2 agonist deamino,[Val4,D‐Arg8]arginine‐vasopressin (dVDAVP)by thienylalanine resulted in selective V2 agonists with strikingly high potencies. However, the peptide solutions were unstable and lost activity over time. These highly potent V2 agonists, which are devoid of vasopressor activity, are promising leads for improving drugs for treating diabetes insipidus, enuresis and coagulation disorders. (2) Diaminopropionic acid and diaminobutyric acid substitution at position‐5 in oxytocin and in V1a antagonists yielded, respectively, the first specific antagonist for the oxytocin receptor, desGly‐NH2,d(CH2)5[D‐Trp2, Thr4, Dap5]OVT and the first specific antagonist for the vasopressin V1a receptor, d(CH2)5[Tyr(Me)2, Dab5]AVP. The availability of single receptor subtype‐specific or selective antagonists will enhance our ability to delineate receptor functions. Utilising these new receptor specific probes, we were able to show thatthe uterotonic action of vasopressin is mediated principally by oxytocin and not by V1a receptors. (3) Replacement of the phenylalanine8 residue in the V1a/V2/oxytocin antagonist, d(CH2)5[D‐Tyr(Et)2, Val4]AVP, with arginine3 yielded the novel, selective, hypotensive vasopressin peptide, d(CH2)5[D‐Tyr(Et)2, Arg3, Val4]AVP (Peptide I). Bioassay characterisations of Peptide I show that its vasodepressor action is independent of the peripheral autonomic, bradykinin, nitric oxide and prostaglandin systems and is not mediated by the known classical oxytocin and vasopressin receptors. These findings suggest the existence of a new vasopressin receptor subtype that may be relevant to the vasodilating action of vasopressin in regional vascular beds. Iodinatable hypotensive peptides have been synthesised and could be developed as markers for the putative new receptor. Ongoing structure‐activity relationship studies on Peptide I have led to more potent and selective hypotensive peptides for use as new research tools and as leads for the development of a new class of antihypertensive agents.

The Discovery of Novel Vasopressin V1b Receptor Ligands for Pharmacological, Functional and Structural Investigations

Until recently, pharmacological studies dealing with vasopressin receptor isoforms were severely hampered by the lack of selective agonists or antagonists that recognize the pituitary V1b vasopressin receptor. By contrast, many selective vasopressin‐related compounds are available for characterization of the vasopressor (V1a) or antidiuretic (V2) vasopressin receptor subtypes. Recently, SSR149415, a selective nonpeptide molecule, was discovered with nanomolar affinity for mammalian V1b receptors and good selectivity for the other vasopressin and oxytocin receptor isoforms. This molecule exhibits potent antagonist properties both in vitro and in vivo. We also designed synthetic peptides derived from [deaminocysteine1,arginine8]vasopressin (dAVP), modified in position 4 by various amino acid residues. Some of these, d[cyclohexylalanine4]AVP or d[lysine4]AVP, have a high affinity and an excellent selectivity for the human V1b receptor subtype. However, they exhibit a mixed V1b/V2 pharmacological profile for the rat vasopressin receptor isoforms. Whatever the species considered, these peptides behave as agonists both in bioassays performed in vitro and in vivo. The d[cyclohexylalanine4]AVP was tritiated and represents the first selective radiolabelled ligand available for studying the human V1b receptors. The discovery of these new selective V1b agonists and V1b antagonist allows an accurate pharmacological characterization of all the vasopressin receptor isoforms. As emphasized in this review, attention to the vasopressin and oxytocin receptor species differences is of critical importance in studies with all vasopressin and oxytocin ligands.

Potent V2 vasopressin antagonists with structural changes at their C-terminals

A variety of structural changes were made in the C-terminals of four potent antidiuretic (V2) antagonists. The parent analogs were all derivatives of [1-(beta-mercapto-beta,beta-cyclopentamethylenepropionic acid)]arginine-vasopressin, d(CH2)5AVP, namely d(CH2)5[D-Phe2,Ile4]AVP, d(CH2)5[D-Ile2,Ile4]AVP, d(CH2)5[D-Tyr(Et)2, Val4]AVP and d(CH2)5[D-Tyr(Et)2,Ile4]AVP. A number of amino acid amides were substituted for the C-terminal 9-glycinamide without reducing their V2-antagonistic potencies in rats. Many non-amino acid structures were also tolerated at the C-terminals of these antagonists and this end of these peptides can be prolonged without interfering with antagonistic potencies. Such altered V2-antagonists may be useful for the development of radioactive ligands, affinity labels and in affinity columns for studies on antidiuretic receptors. These C-terminal modifications also provide useful information for the further development of potent and specific V2-antagonists which can be valuable pharmacological tools and also promise to become useful clinically for the treatment of excessive water retention.

Position Three in Vasopressin Antagonist Tolerates Conformationally Restricted and Aromatic Amino Acid Substitutions: A Striking Contrast with Vasopressin Agonists

We report the solid‐phase synthesis and some pharmacological properties of 12 position three modified analogues (peptides 1–12) of the potent non‐selective antagonist of the antidiuretic (V2‐receptor), vasopressor (V1a‐receptor) responses to arginine vasopressin (AVP) and of the uterine contracting (OT‐receptor) responses to oxytocin (OT), [1(‐β mercapto‐β,β‐pentamethy lenepropionic acid)‐2‐O‐ethyl‐d‐tyrosine 4‐valine] arginine vasopressin [d(CH2)5D‐Tyr(Et) 2VAVP] (A) and two analogues of (B) (peptides 13,14), the 1,2,3,4‐tetrahydroisoquinoline‐3‐carboxylic acid3 (Tic3) analogue of (A). Peptides 1–12 have the following substituents at position three in (A): (1) Pro; (2) Oic; (3) Atc; (4) D‐Atc; (5) Aic; (6) D‐Phe; (7) Ile; (8) Leu; (9) Tyr; (10) Trp; (11) Hphe; (12) [HO]Tic; Peptide (13) is the Tyr‐NH2 9 analogue of (B): Peptide (14) is the D‐Cys 6 analogue of (B). All 14 new peptides were evaluated for agonistic and antagonistic activities in in vivo V2 and V1a assays and in in vitro (no Mg2+) n oxytocic assays. With the exception of the D‐Phe3 peptide (No. 6), which exhibits very weak V2 agonism (…0.0017 u/mg), none of the remaining 13 peptides exhibit any agonistic activities in these assays. In striking contrast to their deleterious effects on agonistic activities in AVP, the Pro3, Oic3, Tyr3, Trp3 and Hphe3 substitutions in (A) are very well tolerated, leading to excellent retention of V2, V1a and OT antagonistic potencies. All are more potent as V2 antagonists than the Ile3 and Leu3 analogues of (A). The Tyr‐NH29 and D‐Cys6 substitutions in (B) are also well tolerated. The anti‐V2 pA2 values of peptides 1–5 and 7–14 are as follows (1) 7.77±0.03; (2) 7.41± 0.05; (3) 6.86±0.02; (4) 5.66±0.09; (5) …5.2; (7) 7.25± 0.08; (8) 6.82±0.06; (9) 7.58±0.05; (10) 7.61±0.08; (11) 7.59±0.07; (12) 7.20±0.05; (13) 7.57±0.1; (14) 7.52± 0.06. All analogues antagonize the vasopressor responses to AVP, with anti‐V 1a pA2 values ranging from 5.62 to 7.64, and the in vitro responses to OT, with anti‐OT pA2 values ranging from 5.79 to 7.94. With an anti‐V2 potency of 7.77±0.03, the Pro3 analogue of (A) is surprisingly equipotent with (A), (anti‐V2 pA2=7.81±0.07). These findings clearly indicate that position three in AVP V2/V1a antagonists, in contrast to position three in AVP agonists, is much more amenable to structural modification than had heretofore been anticipated. Furthermore, the surprising retention of V2 antagonism exhibited by the Pro3, Oic3, Tyr3, Trp3 and Hphe3 analogues of (A), together with the excellent retention of V2 antagonism by the Tyr‐NH29 and D‐Cys6 analogues of (B) are promising new leads to the design of potent and possibly orally active V2 antagonists for use as pharmacological tools and/or as radioiodinatable ligands and for development as potential therapeutic agents for the treatment of the hyponatremia caused by the syndrome of the inappropriate secretion of the antidiuretic hormone (SIADH).

Discovery of novel selective hypotensive vasopressin peptides that exhibit little or no functional interactions with known oxytocin/vasopressin receptors

1 Arginine‐vasopressin (VP) has both vasoconstricting and vasodilating action. We report here the discovery of four novel selective hypotensive VP analogues: d(CH2)5[D‐Tyr(Et)2,Arg3,Val4]AVP; d(CH2)5[D‐Tyr(Et)2,Lys3,Val4]AVP and their iodinatable Tyr‐NH29 analogues. 2 Bioassays in rats for activities characteristic of neurohypophysial peptides showed that the four VP peptides possessed little or no V1a, V2 or oxytocin (OT) receptor agonistic or antagonistic activities. 3 In anaesthetized rats, these peptides (0.05–0.10 mg kg−1 i.v.) elicited a marked fall in arterial blood pressure. 4 Blockade of cholinoceptors, adrenoceptors and bradykinin B2 receptors, and inhibition of prostaglandin synthesis had little effect on their vasodepressor action. 5 Classical V1a, V2 and OT receptor antagonists did not block the vasodepressor response. 6 L‐NAME, 0.2 mg kg−1 min−1, markedly suppressed the hypotensive response to ACh but not the vasodepressor response to the hypotensive VP peptides. However, the duration of the vasodepressor response was shortened. Very high doses of L‐NAME attenuated both the vasodepressor response and the duration of action. 7 These findings indicate that the vasodepressor action of these VP peptides is independent of the peripheral autonomic, bradykinin and PG systems and is not mediated by the known classical OT/VP receptors. NO does not appear to have an important role in their vasodepressor action. 8 The discovery of these novel VP peptides could lead to the development of new tools for the investigation of the complex cardiovascular actions of VP and the introduction of a new class of hypotensive agents. The two iodinatable hypotensive VP peptides could be radiolabelled as potential markers for the localization of the receptor system involved.

Design, synthesis, and pharmacological characterization of fluorescent peptides for imaging human V1b vasopressin or oxytocin receptors.

Among the four known vasopressin and oxytocin receptors, the specific localization of the V1b isoform is poorly described because of the lack of selective pharmacological tools. In an attempt to address this need, we decided to design, synthesize, and characterize fluorescent selective V1b analogues. Starting with the selective V1b agonist [deamino-Cys(1),Leu(4),Lys(8)]vasopressin (d[Leu(4),Lys(8)]VP) synthesized earlier, we added blue, green, or red fluorophores to the lysine residue at position 8 either directly or by the use of linkers of different lengths. Among the nine analogues synthesized, two exhibited very promising properties. These are d[Leu(4),Lys(Alexa 647)(8)]VP (3) and d[Leu(4),Lys(11-aminoundecanoyl-Alexa 647)(8)]VP (9). They remained full V1b agonists with nanomolar affinity and specifically decorated the plasma membrane of CHO cells stably transfected with the human V1b receptor. These new selective fluorescent peptides will allow the cellular localization of V1b or OT receptor isoforms in native tissues.

An investigation of position 3 in arginine vasopressin with aliphatic, aromatic, conformationally-restricted, polar and charged amino acids.

We report the solid‐phase synthesis and some pharmacological properties of 23 new analogs of arginine vasopressin (AVP) which have the Phe3 residue replaced by a broad variety of amino acids. Peptides 1–9 have at position 3: (1) the mixed aromatic/aliphatic amino acid thienylalanine (Thi) and the aliphatic amino acids; (2) cyclohexylalanine (Cha); (3) norleucine (Nle); (4) Leu; (5) norvaline (Nva); (6) Val; (7) alpha‐aminobutyric acid (Abu); (8) Ala; (9) Gly. Peptides 10–23 have at position 3: the aromatic amino acids, (10) homophenylalanine (Hphe); (11) Tyr; (12) Trp; (13) 2‐naphthylalanine (2‐Nal); the conformationally‐restricted amino acids (14) Pro; (15) 2‐aminotetraline‐2‐carboxylic acid (Atc); the polar amino acids (16) Ser; (17) Thr; (18) Gln; and the charged amino acids (19) Asp; (20) Glu; (21) Arg; (22) Lys; (23) Orn. All 23 new peptides were evaluated for agonistic and, where appropriate, antagonistic activities in in vivo antidiuretic (V2‐receptor) and vasopressor (V1a‐receptor) assays and in in vitro (no Mg2+) oxytocic assays. The corresponding potencies (units/mg) in these assays for AVP are: 323±16; 369±6 and 13.9±0.5. Peptides 1–9 exhibit the following potencies (units/mg) in these three assays: (1) 379±14; 360±9; 36.2±1.9; (2) 294±21; 73.4±2.7; 0.33±0.02; (3) 249±28; 84.6±4.3; 4.72±0.16; (4) 229±19; 21.4±0.6; 2.1±0.2; (5) 134±5; 31.2±0.9; 28.4±0.2; (6) 114±9; 45.3±2.3; 11.3±1.6; (7) 86.7±2.5; 4.29±0.13; 0.45±0.03; (8) 15.5±1.5; 0.16±0.01; ∼0.02; (9) 3.76±0.03; <0.02; in vitro oxytocic agonism was not detected. These data show that the aliphatic amino acids Cha, Nle, Leu, Nva and Val are well‐tolerated at position 3 in AVP with retention of surprisingly high levels of antidiuretic activity. Peptides 2–9 exhibit significant gains in both antidiuretic/vasopressor (A/P) and antidiuretic/oxytocic (A/O) selectivities relative to AVP. [Thi3]AVP appears to be a more potent antidiuretic and oxytocic agonist than AVP and is equipotent with AVP as a vasopressor agonist. The antidiuretic potencies of peptides 10–23 exhibit drastic losses relative to AVP. They range from a low of 0.018±0.001 units/mg for the Lys3 analog (peptide 22) to a high of 24.6±4.6 units/mg for the Hphe3 analog (peptide 10). Their vasopressor potencies are also drastically reduced. These range from a low of <0.002 units/mg for peptide 22 to a high of 8.99±0.44 units/mg for the Atc3 analog (peptide 15). Peptides 10–23 exhibit negligible or undetectable in vitro oxytocic agonism. The findings on peptides 10–23 show that position 3 in AVP is highly intolerant of changes with aromatic, conformationally‐restricted, polar and charged amino acids. Furthermore, these findings are in striking contrast to our recent discovery that position 3 in the potent V2/V1a/OT antagonist d(CH2)5d‐Tyr(Et)2VAVP tolerates a broad latitude of structural change at position 3 with many of the same amino acids, to give excellent retention of antagonistic potencies. The data on peptides 1–4 offer promising clues to the design of more potent and selective AVP V2 agonists. Copyright