Dmt-Tic opioidmimetic peptides represent a highly potent class of opioid peptide antagonists with greater potency than the nonopioid delta antagonist naltrindole and have potential application as clinical and therapeutic compounds.
Nociceptin (NC) and some of its fragments as well as nociceptin-(1-13)-peptide amide [NC- (1-13)-NH2] and a series of its analogues were prepared and tested in the mouse vas deferens in an attempt to identify the sequences involved in the activation (message) and in the binding (address) of nociceptin to its receptor. The NC receptor that inhibits the electrically evoked twitches of the mouse vas deferens was demonstrated to be distinct from the delta opioid receptor, since naloxone and Dmt-Tic-OH (a selective delta opioid receptor antagonist) block the delta opioid receptor but have no effect on the nociceptin receptor. Results from structure-activity experiments suggest that (a) the entire sequence of NC may not be required for full biological activities, since NC(1-13)-NH2 is as active as NC; (b) fragments of NC have however to be amidated as in NC(1-13)-NH2 in order to be protected from degradation by proteases; (c) cationic residues (as Arg8,12, Lys9,13) appear to play a functional role, since their replacement with Ala in the sequence of NC(1-13)-NH2 leads to inactivity; (d) the N-terminal tetrapeptide Phe-Gly-Gly-Phe is essential for activity: its full length and flexibility appear to be required for NC receptor activation and/or occupation; (e) Phe4 and not Phe1 appears to be the residue involved in receptor activation, since the replacement of Phe1 with Leu has no effect, while that of Phe4 leads to inactivity. Results summarized in this paper indicate that the structural requirements of NC for occupation and activation of its receptor are different from that of opioids, particularly delta agonists.
Analogues of the 2',6'-dimethyl-L-tyrosine (Dmt)-1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid (Tic) pharmacophore were prepared to test the hypothesis that a "spacer" and a third aromatic center in opioid peptides are required to convert a delta-antagonist into ligands with delta-agonist or with mixed delta-antagonist/mu-agonist properties. Potent delta-agonists and bifunctional compounds with high delta- and mu-opioid receptor affinities were obtained by varying the spacer length [none, NH-CH(2), NH-CH(2)-CH(2), Gly-NH-CH(2)] and C-terminal aromatic nucleus [1H-benzimidazole-2-yl, phenyl (Ph) and benzyl groups]. C-terminal modification primarily affected mu-opioid receptor affinities, which increased maximally 1700-fold relative to the prototype delta-antagonist H-Dmt-Tic-NH(2) and differentially modified bioactivity. In the absence of a spacer (1), the analogue exhibited dual delta-agonism (pEC(50), 7.28) and delta-antagonism (pA(2), 7.90). H-Dmt-Tic-NH-CH(2)-1H-benzimidazole-2-yl (Bid) (2) became a highly potent delta-agonist (pEC(50), 9.90), slightly greater than deltorphin C (pEC(50), 9.56), with mu-agonism (pE(50), 7.57), while H-Dmt-Tic-Gly-NH-CH(2)-Bid (4) retained potent delta-antagonism (pA(2), 9.0) but with an order of magnitude less mu-agonism. Similarly, H-Dmt-Tic-Gly-NH-Ph (5) had nearly equivalent high delta-agonism (pEC(50), 8.52) and mu-agonism (pEC(50), 8.59), while H-Dmt-Tic-Gly-NH-CH(2)-Ph (6) whose spacer was longer by a single methylene group exhibited potent delta-antagonism (pA(2), 9.25) and very high mu-agonism (pEC(50), 8.57). These data confirm that the distance between the Dmt-Tic pharmacophore and a third aromatic nucleus is an important criterion in converting Dmt-Tic from a highly potent delta-antagonist into a potent delta-agonist or into ligands with mixed delta- and mu-opioid properties.
[Phe 1 C(CH 2 -NH)Gly 2 ]NC(1-13)NH 2 has been tested in the electrically stimulated guinea pig ileum and mouse vas deferens, two nociceptin sensitive preparations. The new compound showed per se little or no eect in the two tissues, but it displaced to the right the concentration-response curves of nociceptin in a concentration-dependent manner. Reinscheid et al., 1995) to be the endogenous ligand of the opioid-like orphan receptor (ORL-1). Despite the structural homology of NC and its receptor with the peptides and receptors of the opioid family this peptide/receptor system appears to be pharmacologically distinct from the opioids. During the last two years several papers have described new biological eects mediated by NC both in the periphery and in the central nervous system. Such eects were not modi®ed by naloxone or other more selective opioid receptor antagonists and were considered to be mediated by the activation of a speci®c NC receptor (the ORL-1). Lack of selective NC receptor antagonists prevented a de®nitive pharmacological characterization of ORL-1. In 1997, Kobayashi et al. showed that carbetapentane and rimcazole act as antagonists at the NC receptor. However these compounds showed little anity (IC 50 about 10 mM) and, more importantly, they were found to interact also with other functional sites such as s-, m-, and k-opioid receptors and M 1 -muscarinic receptors. Being non selective, they were therefore considered of little utility for receptor characterization.In the present study, we describe the chemical structure and the in vitro pharmacological eects of [Phe
benzimidazol-2-one), either injected intranigrally or given systemically, also elevated striatal dopamine release and facilitated motor activity, confirming that these effects were caused by blockade of endogenous N/OFQ signaling. The inhibitory role played by endogenous N/OFQ on motor activity was additionally strengthened by the finding that mice lacking the NOP receptor gene outperformed wild-type mice on the rotarod. We conclude that NOP receptors in the substantia nigra pars reticulata, activated by endogenous N/OFQ, drive a physiologically inhibitory control on motor behavior, possibly via modulation of the nigrostriatal dopaminergic pathway.
1 Nociceptin (orphanin FQ) is a novel neuropeptide capable of inducing a variety of biological actions via activation of a speci®c G-protein coupled receptor. However, the lack of a selective nociceptin receptor antagonist has hampered our understanding of nociceptin actions and the role of this peptide in pathophysiological states. As part of a broader programme of research, geared to the identi®cation and characterization of nociceptin receptor ligands, we report that the novel peptide [Nphe 1 ]nociceptin(1-13)NH 2 acts as the ®rst truly selective and competitive nociceptin receptor antagonist and is devoid of any residual agonist activity. ]nociceptin(1-13)NH 2 is also active in vivo, where it prevents the pronociceptive and antimorphine actions of intracerebroventricularly applied nociceptin, measured in the mouse tail withdrawal assay. Moreover, [Nphe 1 ]nociceptin(1-13)NH 2 produces per se a dose dependent, naloxone resistant antinociceptive action and, at relatively low doses, potentiates morphine-induced analgesia. 4 Collectively our data indicate that [Nphe 1 ]nociceptin(1-13)NH 2 , acting as a nociceptin receptor antagonist, may be the prototype of a new class of analgesics.
The delta opioid antagonist H-Dmt-Tic-OH (2',6'-dimethyl-L-tyrosyl-1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid) exhibits extraordinary delta receptor binding characteristics [Ki delta = 0.022 nM; Ki mu/Ki delta = 150,000] and delta antagonism (pA2 = 8.2; Ke = 5.7 nM). A change in chirality of Dmt at C alpha (1, 2, 6, 8, 10, 13) curtailed delta receptor parameters, while replacement of its alpha-amino function by a methyl group (3) led to inactivity; Tyr-Tic analogues 4 and 11 weakly interacted with delta receptors. N-Alkylation of H-Dmt-Tic-OH and H-Dmt-Tic-Ala-OH with methyl groups produced potent delta-opioid ligands with high delta receptor binding capabilities and enhanced delta antagonism: (i) N-Me-Dmt-Tic-OH 5 had high delta opioid binding (Ki delta = 0.2 nM), elevated delta antagonism on mouse vas deferens (MVD) (pA2 = 8.5; Ke = 2.8 nM), and nondetectable mu activity with guinea pig ileum (GPI). (ii) N,N-Me2-Dmt-Tic-OH (12) was equally efficacious in delta receptor binding (Ki delta = 0.12 nM; Ki mu/Ki delta = 20000), but delta antagonism rose considerably (pA2 = 9.4; Ke = 0.28 nM) with weak mu antagonism (pA2 = 5.8; Ke = 1.58 microM; GPI/MVD = 1:5640). N-Me-(9) and N,N-Me2-Dmt-Tic-Ala-OH (15) also augmented delta opioid receptor binding, such that 15 demonstrated high affinity (Ki delta = 0.0755 nM) and selectivity (Ki mu/Ki delta = 20132) with exceptional antagonist activity on MVD (pA2 = 9.6; Ke = 0.22 nM) and weak antagonism on GPI (pA2 = 5.8; Ke = 1.58 microM; GPI/MVD = 1:7180). Although the amidated dimethylated dipeptide analogue 14 had high Ki delta (0.31 nM) and excellent antagonist activity (pA2 = 9.9; Ke = 0.12 nM), the increased activity toward mu receptors in the absence of a free acid function at the C-terminus revealed modest delta selectivity (Ki mu/Ki delta = 1655) and somewhat comparable bioactivity (GPI/MVD = 4500). Thus, the data demonstrate that N,N-(Me)2-Dmt-Tic-OH (12) and N,N-Me2-Dmt-Tic-Ala-OH (15) retained high delta receptor affinities and delta selectivities and acquired enhanced potency in pharmacological bioassays on MVD greater than that of other peptide or non-peptide delta antagonists.
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