Pharmacological characterization of the novel nonpeptide orphanin FQ/nociceptin receptor agonist Ro 64-6198: rapid and reversible desensitization of the ORL1 receptor in vitro and lack of tolerance in vivo.

The novel nonpeptide orphanin FQ/nociceptin (OFQ/N) ligand [(1S,3aS)-8-(2,3,3a,4,5,6-hexahydro-1H-phenalen-1-yl)-1-phenyl-1,3,8-triaza-spiro[4.5]decan-4-one] (Ro 64-6198) was characterized in vitro and in vivo for its agonistic potential. Ro 64-6198 was 130- to 3500-fold selective for the OFQ/N receptor (ORL1) compared with opiate receptors. In the cAMP inhibition assay, Ro 64-6198 was a full agonist at the ORL1 and a partial agonist at the mu opiate receptor. When human embryonic kidney 293 cells stably expressing the human ORL1 receptor were pre-exposed (30 min) to either OFQ/N or Ro 64-6198, the ability of both agonists to inhibit forskolin-mediated cAMP accumulation was strongly reduced, indicating a functional desensitization of the second messenger cascade. However, acidic washes of OFQ/N-exposed cells fully restored the sensitivity of the ORL1 receptor for agonists. In contrast, the cAMP response in Ro 64-6198-exposed cells remained impaired after acidic washes, suggesting sustained receptor internalization at 30 min. In agreement with this finding, the number of cell-surface ORL1 receptors was significantly reduced after Ro 64-6198 pre-exposure, and this effect could be blocked with high sucrose concentrations. When Ro 64-6198 was chronically administered to rats, no signs of tolerance to its anxiolytic-like effects were detected following 15 days of daily drug exposure. In agreement with the behavioral results, Ro 64-6198 was able to reduce brain ORL1 binding sites in both acutely and chronically treated rats. Full recovery of ORL1 binding sites was observed 24 h after Ro 64-6198 administration with a t1/2 of approximately 5.5 h. These data show that nonpeptide agonists at the ORL1 receptor have a good clinical potential as anxiolytics without causing tolerance.

125I-Antisauvagine-30: a novel and specific high-affinity radioligand for the characterization of corticotropin-releasing factor type 2 receptors.

Corticotropin-releasing factor (CRF) receptors type 1 (CRF(1)) and type 2 (CRF(2)) differ from each other in their pharmacological properties. The human and ovine CRF versions bind to CRF(1) receptors with significantly higher affinity than to CRF(2) receptors. Recently antisauvagine-30, an N-terminally truncated version of the CRF analog sauvagine, was characterized as a specific antagonist to mouse CRF(2B). We have synthesized the radiolabeled version (125)I-antisauvagine-30 and tested it for its affinity at human CRF(1) (hCRF(1)), hCRF(2A), Xenopus CRF(1) (xCRF(1)) and xCRF(2) receptors. In control binding studies (125)I-labeled hCRF, sauvagine and astressin were also bound to these receptors. (125)I-antisauvagine-30 exclusively bound to hCRF(2A) and xCRF(2) but not to hCRF(1) and xCRF(1) receptors. (125)I-antisauvagine-30 binding to hCRF(2A) and xCRF(2) receptors was saturable and of high affinity (hCRF(2A): K(d)=125 pM; xCRF(2): K(d)=1.1 nM). In displacement binding experiments using (125)I-antisauvagine-30 as radioligand several CRF analogs bound to hCRF(2A) and xCRF(2) receptors with similar rank orders as reported with other CRF radioligands. Finally, preliminary studies using (125)I-antisauvagine-30 binding to membrane homogenates prepared from different rat brain structures showed that the peptide bound specifically to brain areas expressing CRF(2) receptors. These data demonstrate that (125)I-antisauvagine-30 is the first high-affinity ligand to specifically label CRF(2) receptors.

Different binding modes of amphibian and human corticotropin-releasing factor type 1 and type 2 receptors: evidence for evolutionary differences.

The binding characteristics of corticotropin-releasing factor (CRF) type 1 (CRF(1)) and type 2 (CRF(2)) receptors from human (hCRF(1) and hCRF(2alpha)) and Xenopus (xCRF(1) and xCRF(2)) were compared using four different (125)I-labeled CRF analogs, the agonists (125)I-CRF and (125)I-sauvagine, and the antagonists (125)I-astressin ((125)I-AST) and (125)I-antisauvagine-30 ((125)I-aSVG). The hCRF(2alpha) and xCRF(2) receptors bound all four radioligands with different affinities, whereas hCRF(1) did not bind (125)I-aSVG, and xCRF(1) bound neither (125)I-sauvagine nor (125)I-aSVG. Competitive binding studies using unlabeled agonists and antagonists with hCRF(1) and hCRF(2alpha) receptors revealed that most agonists exhibited higher affinity in displacing agonist radioligands compared with displacement of antagonist radioligands. Exceptions were the agonists human and rat urocortin, which displayed high-affinity binding in the presence of either (125)I-labeled agonist or antagonist ligands. In contrast, the affinities of antagonists were independent of the nature of the radioligand. We also found that, in contrast to the mammalian CRF receptors, the affinity of ligand binding to xCRF(1) and xCRF(2) receptors strongly depended on the nature of the radioligand used for competition. For xCRF(1), competitors showed different rank order binding profiles with (125)I-CRF compared with (125)I-AST as the displaceable ligand. Similarly, binding of competitors to the xCRF(2) receptor showed markedly different profiles with (125)I-CRF as the competed ligand compared with the other radioligands. These data demonstrate that amphibian CRF receptors have distinctly different binding modes compared with their mammalian counterparts.

Evidence for the abundant expression of arginine 185 containing human CRF(2alpha) receptors and the role of position 185 for receptor-ligand selectivity.

The abundance of a histidine residue at position 185 (His(185)) of the human corticotropin-releasing factor (CRF) type 2 alpha receptor (hCRF(2alpha)) was investigated. His(185) has only been reported in hCRF(2); CRF(2) proteins from other species and all CRF(1) receptors encode an arginine (Arg(185)) at the corresponding position. Cloning of partial and full-length hCRF(2) cDNAs from a variety of neuronal and peripheral tissues revealed the existence of receptor molecules encoding Arg(185) only. Sequence analysis of the hCRF(2) gene verified the existence of Arg(185) also on genomic level. Full-length cDNAs encoding either the His(185) (R2H(185)) or the Arg(185) (R2R(185)) variants of hCRF(2alpha) were stably expressed in HEK293 cells and tested for ligand binding properties. In displacement studies R2H(185) and R2R(185) displayed a similar substrate specificity, human and rat urocortin, and the peptide antagonists astressin and alpha-helical CRF((9-41)) were bound with high affinity whereas human and ovine CRF were low-affinity ligands. Significant differences were observed for sauvagine and urotensin I, which bound with 3-fold (sauvagine) and 9-fold (urotensin I) higher affinity to R2R(185). These data indicate that hCRF(2), like all vertebrate CRF(1) and CRF(2) proteins encodes an arginine residue at the junction between extracellular domain 2 and transmembrane domain 3 and that this amino acid plays a role for the discrimination of some CRF peptide ligands.