Discovery of novel triazole-based opioid receptor antagonists

We report the computer-aided design, chemical synthesis, and biological evaluation of a novel family of delta opioid receptor (DOR) antagonists containing a 1,2,4-triazole core structure that are structurally distinct from other known opioid receptor active ligands. Among those delta antagonists sharing this core structure, 8 exhibited strong binding affinity (K(i) = 50 nM) for the DOR and appreciable selectivity for delta over mu and kappa opioid receptors (delta/mu = 80; delta/kappa > 200).     

2',6'-Dimethyltyrosine]dynorphin A(1-11)-NH2 analogues lacking an N-terminal amino group: potent and selective kappa opioid antagonists.

Recent studies showed that dermorphin and enkephalin analogues containing two methyl groups at the 2',6'-positions of the Tyr(1) aromatic ring and lacking an N-terminal amino group were moderately potent delta and mu opioid antagonists. These results indicate that a positively charged N-terminal amino group may be essential for signal transduction but not for receptor binding and suggested that its deletion in agonist opioid peptides containing an N-terminal 2',6'-dimethyltyrosine (Dmt) residue may represent a general way to convert them into antagonists. In an attempt to develop dynorphin A (Dyn A)-derived kappa opioid antagonists, we prepared analogues of [Dmt(1)]Dyn A(1-11)-NH2 (1), in which the N-terminal amino group was either omitted or replaced with a methyl group. This was achieved by replacement of Tyr(1) with 3-(2,6-dimethyl-4-hydroxyphenyl)propanoic acid (Dhp) or (2S)-2-methyl-3-(2,6-dimethyl-4-hydroxyphenyl)propanoic acid [(2S)-Mdp]. Compounds were tested in the guinea pig ileum and mouse vas deferens bioassays and in rat and guinea pig brain membrane receptor binding assays. All analogues turned out to be potent kappa antagonists against Dyn A(1-13) and the non-peptide agonist U50,488 and showed only weak mu and delta antagonist activity. The most potent and most selective kappa antagonist of the series was [(2S)-Mdp(1)]Dyn A(1-11)-NH2 (5, dynantin), which showed subnanomolar kappa antagonist potency against Dyn A(1-13) and very high kappa selectivity both in terms of its K(e) values determined against kappa, mu, and delta agonists and in terms of its ratios of kappa, mu, and delta receptor binding affinity constants. Dynantin is the first potent and selective Dyn A-derived kappa antagonist known and may complement the non-peptide kappa antagonists norbinaltorphimine and GNTI as a pharmacological tool in opioid research.     

Effect of N-alkyl and N-alkenyl substituents in noroxymorphindole, 17-substituted-6,7-dehydro-4,5alpha-epoxy-3,14-dihydroxy-6,7:2',3'-indolomorphinans, on opioid receptor affinity, selectivity, and efficacy

The N-alkyl analogues (N-ethyl through N-heptyl), branched N-alkyl chain analogues (N-isopropyl, N-2-methylpropyl, and N-3-methylbutyl), and N-alkenyl analogues ((E)-N-3-methylallyl (crotyl), N-2-methylallyl, and N-3,3-dimethylallyl) were prepared in the noroxymorphindole series (17-substituted-6,7-dehydro-4,5alpha-epoxy-3,14-dihydroxy-6,7:2',3'-indolomorphinans), and the effect of the N-substituent on opioid receptor affinity, selectivity, and efficacy was examined using receptor binding assays, [(35)S]GTPgammaS efficacy determinations, and smooth muscle functional assays (electrically stimulated mouse vas deferens and guinea pig ileum). All of the compounds acted as opioid antagonists, including those with N-substituents which usually confer either weak agonist-antagonist behavior (N-ethyl) or potent opioid agonist activity (N-pentyl) in morphinan-like ligands which interact with the mu-receptor. Several N-substituted noroxymorphindoles were found to be more mu/delta-selective than naltrindole (NTI). The N-2-methylallylnoroxymorphindole, in particular, was found to be more selective than NTI in receptor binding assays (mu/delta = 1700 vs 120; kappa/delta = 810 vs 140), as an antagonist in the GTPgammaS assay (mu/delta = 170 vs 140; kappa/delta = 620 vs 160), and considerably more selective than NTI in the functional assays (mu/delta > 2200 vs 90). It also had high affinity for the delta-opioid receptor (K(i) = 4.7 nM in the binding assay) and high antagonist potency (1.2 nM in the GTPgammaS assay; 8.9 nM in the MVD assay).     

Kappa opioid agonists as targets for pharmacotherapies in cocaine abuse

Kappa opioid receptors derive their name from the prototype benzomorphan, ketocyclazocine (1a) which was found to produce behavioral effects that were distinct from the behavioral effects of morphine but that were antagonized by the opioid antagonist, naltrexone. Recent evidence suggests that agonists and antagonists at kappa opioid receptors may modulate the activity of dopaminergic neurons and alter the neurochemical and behavioral effects of cocaine. Kappa agonists blocked the effects of cocaine in squirrel monkeys in studies of cocaine discrimination and scheduled-controlled responding. Studies in rhesus monkeys suggested that kappa opioids may antagonize the reinforcing effects of cocaine. These studies prompted the synthesis and evaluation of a series of kappa agonists related to the morphinan, L-cyclorphan (3a) and the benzomorphan, L-cyclazocine (2). We describe the synthesis and preliminary evaluation of a series of morphinans, structural analogs of cyclorphan 3a-c, the 10-keto morphinans 4a and b, and the 8-keto benzomorphan 1b, structurally related to ketocyclazocine (1a). In binding experiments L-cyclorphan (3a), the cyclobutyl (3b), the tetrahydrofurfuryl 3c and the 10-keto 4b analogs had high affinity for mu (mu), delta (delta) and kappa (kappa) opioid receptors. Both 3a and 3b were more selective for the kappa receptor than the mu receptor. However, 3b was 18-fold more selective for the kappa receptor in comparison to the delta receptor, while cyclorphan (3a) had only a 4-fold greater affinity for the kappa receptor in comparison to the delta receptor. The cyclobutyl compound 3b was found to have significant mu agonist properties, while 3a was a mu antagonist. All compounds were also examined in the mouse tail flick and writhing assay. Compounds 3a and 3b were kappa agonists. Correlating with the binding results, compound 3a had some delta agonist properties, while 3b was devoid of any activity at the delta receptor. In addition, compounds 3a and 3b had opposing properties at the mu opioid receptor. The cyclobutyl compound 3b was found to have significant mu agonist properties, while 3a was a mu antagonist.     

Chronic administration of morphine and naltrexone up-regulate mu-opioid binding sites labeled by [3H][D-Ala2,MePhe4,Gly-ol5]enkephalin: further evidence for two mu-binding sites

A variety of data support the hypothesis of an opiate receptor complex composed of distinct, yet interacting mu and delta binding sites (termed mu cx and delta cx to indicate binding sites 'in the complex'), in addition to independent mu and delta binding sites, termed mu ncx and delta ncx, to indicate binding sites 'not in the complex'. Ligand binding studies using membranes and slide-mounted sections of rat brain support the hypothesis that the irreversible mu-antagonist beta-funaltrexamine (FNA) selectively alkylates the opiate receptor complex, altering the binding of mu agonists to the mu cx binding site and the binding of [3H][D-Ala2,D-Leu5]enkephalin to the delta cx site. Previous studies demonstrated that the chronic administration of morphine to rats selectively 'upregulates' the opiate receptor complex. In contrast, the chronic administration of naltrexone upregulates several types of opioid receptors, including kappa, the delta ncx binding site, and multiple binding sites labeled by mu agonists. A prediction based upon these observations is that, using [3H][D-Ala2,MePhe4,Gly-ol5]enkephalin to label mu binding sites, chronic morphine should upregulate only the mu cx binding site, whereas chronic naltrexone should additionally up-regulate the mu ncx binding site. In this study we test and confirm this hypothesis, using sensitivity to FNA to define the mu cx binding site. The implications of these data for models of the opioid receptors and the mechanism(s) of tolerance and dependence are discussed.     

Na+ modulation, inverse agonism, and anorectic potency of 4-phenylpiperidine opioid antagonists

Differences in the anorectic activity of morphinan (e.g., naltrexone) and 3,4-dimethyl-4-(3-hydroxyphenyl)piperidine (4PP) opioid receptor antagonists have been described. In an attempt to explain these differences, the influence of Na(+) on opioid binding affinity and functional activity of 4PP antagonists was compared to other opioid antagonists. The binding affinities of neutral antagonists were unaffected by the addition of Na(+), whereas that for the peptide, inverse agonist N,N-diallyl-Tyr-Aib-Aib-Phe-Leu-OH (ICI174864) was increased. Similarly, the binding affinities of the 4PP antagonist (3R,4R)-1-((S)-3-hydroxy-3-cyclohexylpropyl)-4-(3-hydroxyphenyl)-3,4-dimethyl-1-piperidine (LY255582) and other 4PP antagonists were increased in the presence of Na(+) with the greatest effects at the delta opioid receptor followed by the mu and kappa opioid receptors, respectively. Similar to ICI174864, 4PP antagonists were found to inhibit basal GTPgamma[(35)S] binding at the delta opioid receptor indicating inverse agonist activity. A correlation was observed between the binding affinities in the presence of Na(+), the inverse agonist potency, and the anorectic potency of 4PP antagonists. These data suggest that 4PP antagonists differ from morphinan antagonists in their inverse agonist activity and suggest a relationship between inverse agonism and anorectic activity.     

Selectivity of ligand binding to opioid receptors in brain membranes from the rat, monkey and guinea pig

Conditions for the equilibrium binding to opioid receptor of [3H]sufentanil (mu selective), [3H][D-Pen2,D-Pen5]enkephalin (delta selective), and [3H]U69,593 (kappa selective) were established in membranes from rat brain cerebrum, monkey cortex, or guinea pig cerebellum. The selectivity index of various opioid alkaloids and peptides in binding to the mu, delta, or kappa opioid receptors was expressed as the ratio of their EC50 values in displacing two selective radiolabeled ligands: [3H]sufentanil/[3H](D-Pen2,D-Pen5)enkephalin (selectivity: mu/delta), [3H]sufentanil/[3H]U69,593 (selectivity: mu/kappa), or [3H][D-Pen2,D-Pen5]enkephalin/[3H]U69,593 (selectivity: delta/kappa). High resolution in binding selectivity was observed: in rat brain the mu/delta selectivity for Tyr-D-Ala-Gly-(Me)Phe-Gly-ol and sufentanil were 0.02 and 0.03, whereas for [D-Pen2,D-Pen5]enkephalin and ICI 174,864 they were 1,200 and 998. Compared to mu opiates, the specific binding of delta and kappa agonists was less sensitive to sodium. The results describe a routinely applicable methodological approach for the assessment of selective ligand binding to the mu, delta and kappa opioid receptors in rodent and monkey brain membranes.     

Investigation of the selectivity of oxymorphone- and naltrexone-derived ligands via site-directed mutagenesis of opioid receptors: exploring the "address" recognition locus

The delta-selective opioid antagonist naltrindole (NTI), as well as the kappa-selective opioid antagonists norbinaltorphimine (norBNI) and 5'-guanidinonaltrindole (GNTI), are derived from naltrexone, a universal opioid antagonist. Previous studies have indicated that extracellular loop III is the key region for discrimination by naltrexone-derived selective ligands between the delta, mu, and kappa opioid receptor types. It has been proposed that selective ligands could bind to all three receptor types if the appropriate portions of the extracellular loops were eliminated. To investigate this possibility, several single-point mutant opioid receptors have been generated with the aim of conferring enhanced affinity of selective ligands for their nonpreferred receptor types. Mutations were made in all three types of opioid receptors with the focus on two positions at the extracellular end of transmembrane regions (TM) VI and VII. It was found that the delta-selective NTI could bind both mu and kappa receptors with significantly enhanced affinity when an aromatic residue in TM VII was replaced with alanine (mu[W318A] and kappa[Y312A]). Similarly, kappa-selective antagonists, norBNI and GNTI, showed enhanced affinity for the mu[W318A] mutant and for both mu and delta receptors when a glutamate residue was incorporated into the extracellular end of TM VI (mu[K303E] and delta[W284E]). These results demonstrate that naltrexone-derived selective ligands achieve their selectivity via a combination of enhanced affinity of the address for a particular subsite along with loss of affinity due to steric interference at nonpreferred types. The results reveal key residues in the "address" recognition locus that contribute to the selectivity of opioid ligands and support the hypothesis that recognition of the naltrexone moiety is essentially the same for all three receptor types.     

Phenylmorphans and analogues: opioid receptor subtype selectivity and effect of conformation on activity.

The morphine-like (+)-phenylmorphan, the atypical (-)-enantiomer, and some analogues have been tested in receptor binding assays selective for opioid mu 1, mu 2, delta, kappa 1, and kappa 3 receptors. The affinities of all of the compounds except one, including the atypical (-)-phenylmorphan, were greatest for mu 1 and mu 2 receptors. The only exception was the (+)-9 alpha-methyl analogue which had slightly greater affinity for the kappa 1 receptor. The selective receptor binding assays provide evidence that opioids in which the phenyl ring is constrained to be equatorial on the piperidine ring can have considerable affinity for mu receptors. In addition, dose-response curves were determined for (+)- and (-)-phenylmorphan using the mouse tail-flick assay with the (+)-enantiomer found to be about 7 times more potent. Pretreatment with the selective opioid antagonists beta-FNA (mu 1 and mu 2), naloxonazine (mu 1), nor-BNI (kappa 1), and naltrindole (delta) suggests that the antinociceptive activity of both enantiomers is mediated through mu receptors. The pretreatment with naloxonazine, which attenuated the antinociceptive effect, shows that both (+)- and (-)-phenylmorphan are mu 1 agonists while intrathecal administration shows that both are mu 2 agonists. Conformational energy calculations on the compounds were also performed using the MM2-87 program. Consistent with previous conformational results for the phenylmorphans (J. Med. Chem. 1984, 27, 1234-1237), the most potent antinociceptive compounds preferred a particular orientation of the phenyl ring.     

Opioid agonist and antagonist bivalent ligands. The relationship between spacer length and selectivity at multiple opioid receptors

Bivalent ligands containing the oxymorphamine or naltrexamine pharmacophores connected to spacers of varying length were synthesized and evaluated for their selectivity at mu, kappa, and delta opioid receptors. The oxymorphamine bivalent ligands (1-8) behaved as mu agonists on the electrically stimulated guinea pig ileum longitudinal muscle preparation (GPI). The spacer that conferred peak agonist activity in these series contains a total of four glycyl units (n = 2). Binding studies with guinea pig brain membranes showed a qualitatively similar profile at mu receptors as a function of spacer length. Also, delta receptor selectivity increased as the spacer was lengthened. The naltrexamine bivalent ligands (9-13) effectively antagonized the mu receptor agonist morphine in the GPI at the same optimal spacer length (n = 2) as in the agonist series. However, the peak antagonism of ethylketazocine, a kappa receptor agonist, occurred with the bivalent ligand 9 containing the shortest spacer (n = 0), and it was found that 9 is the most selective kappa antagonist in the series. While receptor binding roughly parallels that of kappa antagonist activity in the GPI, no correlation between binding and antagonist activity was observed at mu opioid receptors. The possible significance of these results is discussed.     

Pharmacological properties of a proenkephalin A-derived opioid peptide: BAM 18

BAM 18 is a derivative of the opioid precursor proenkephalin A. Although it exists in rat and guinea-pig brain in relatively high concentrations, its physiological function is presently unknown. In the present study we have determined the opioid receptor selectivity of this peptide using radioligand binding and peripheral tissue bioassay. When selective binding conditions were used, BAM 18 bound to the mu opioid receptor with an affinity three times that of the kappa opioid receptor and over 10 times that of the delta opioid receptors (Ki = 0.29, 0.75, and 3.2 nM respectively). BAM 18 also displayed mixed receptor selectivity in in vitro bioassay. Ke values for naloxone antagonism of BAM 18 agonist activity in the electrically stimulated guinea-pig ileum and the mouse vas deferens were 4.3 and 9.9 nM, respectively. These data indicate that BAM 18 binds to all three opioid receptor subtypes with a selectivity profile of mu greater than kappa greater than delta.     

Coupling of multiple opioid receptors to GTPase following selective receptor alkylation in brain membranes

Opioid agonists of the mu, kappa and delta types stimulated low-K_m guanosine triphosphatase (GTPase) in membranes, from the brain of the rat by up to 34%, with potencies the rank order of which corresponded to the respective binding affinities to opioid receptor. In general, kappa ligands stimulated GTPase to a lesser degree than mu or delta opiates. The coupling of a given type of opioid receptor to GTPase was resolved by direct or protective alkylation of the other receptors. Treatment of the membranes with β-funaltrexamine abolished the stimulation of GTPase by sufentanil and levorphanol (mu), but not by bremazocine (kappa) or DSLET (delta). On the other hand, prior incubation with Superfit, an alkylating agent with selectivity for the delta opioid receptor, specifically eliminated the effect of DSLET. Partial alkylation by increasing concentrations of Superfit gradually reduced the extent of stimulation of GTPase by DSLET. The successive treatment of membranes with Superfit and β-funaltrex-amine blocked the actions of DSLET, sufentanil and levorphanol, but had no effect on the stimulation of the GTPase by bremazocine. Selective coupling of an opioid receptor to GTPase was also obtained after incubation of membranes with β-chlornaltrexamine in the presence of protective concentrations of mu, kappa or delta opioid ligands. Alkylation resolved the coupling of the non-selective opiate etorphine: the sum of stimulation of GTPase in the receptor-selective membranes equalled maximal stimulation of enzyme in untreated membranes. Naloxone blocked the stimulation of GTPase by mu, kappa or delta agonists, but ICI-174,864 specifically inhibited the effect of DSLET. The results describe the use of receptor-selective membranes from brain to characterize the coupling of multiple opioid receptors to high-affinity GTPase, the inhibitory binding protein for GTP of the adenylate cyclase complex.     

Opioid Receptors and Signaling on Cells from the Immune System

This review discusses the criteria for determining whether a binding site or functional response is directly mediated by either the mu, delta, or kappa opioid receptors. In 1988, Sibinga and Goldstein published the first review that addressed whether cells from the immune system express opioid receptors. The criteria that they used, namely, structure–activity relationships, stereoselectivity, dose- and concentration-dependence, and saturability are still relevant criteria today for determining if an immunological response is mediated by either the mu, delta or kappa opioid receptors. Radioligand receptor binding studies and functional studies that clearly show the presence of an opioid receptor on immunocytes are presented. Selective agonists and antagonists for the mu, delta, and kappa opioid receptors are discussed, and the need for their use in experiments is emphasized. Conditions used in functional assays are very important. Receptor desensitization and downregulation occur within minutes after the application of an agonist. However, many immunological assays are applying an agonist for days before measuring an immunological effect. The results obtained may reflect changes that are results of receptor desensitization and/or downregulation instead of changes that are observed with acute activation of the receptor. The future of receptor pharmacology lies in the crosstalk and dimerization of G protein-coupled receptors. In transfected systems, opioid receptors have been shown to dimerize with chemokine and cannabinoid receptors, resulting in crosstalk between different types of receptors.     

Rational drug design of selective epsilon opioid receptor agonist TAN-821 and antagonist TAN-1014

Beta-endorphin (beta-EP) is generally classified as a mu and delta opioid receptor agonist but is also an agonist of the epsilon opioid receptor. Although several selective agonists and antagonists for mu, delta, and kappa opioid receptors are known, selective epsilon receptor agonists or antagonists have not been reported for some time. Recently, we designed and synthesized the selective epsilon receptor agonist, 17-(cyclopropylmethyl)-4,5alpha-epoxy-3,6beta-dihydroxy-6,14-endoethenomorphinan-7alpha-[N-methyl-N-phenethyl]carboxamide (TAN-821), and the selective epsilon receptor antagonist, 17-(cyclopropylmethyl)-4,5alpha-epoxy-6beta,21-epoxymethano-3-hydroxy-6,14-endoe-thenomorphinan-7alpha-(N-phenethyl)carboxamide (TAN-1014). TAN-821 stimulated binding of the non-hydrolyzable guanosine 5'-triphosphate analogue, guanosine 5'-(gamma-thio)-triphosphate (GTPgammaS), to the mouse pons/medulla membrane via activation of the epsilon receptor. Moreover, TAN-821 given intracerebroventricularly (i.c.v.) produced marked, long-lasting, and dose-dependent antinociception in tail-flick and hot-plate tests. This antinociception induced by i.c.v. administered TAN-821 was blocked by i.c.v. pretreatment with the epsilon opioid receptor partial agonist beta-EP (1-27), but not the mu opioid receptor antagonist beta-FNA, the delta opioid receptor antagonist NTI, or the kappa opioid receptor antagonist nor-BNI. On the other hand, i.c.v. injection of TAN-1014 alone produced no antinociception, and i.c.v. pretreatment with TAN-1014 attenuated the antinociception induced by i.c.v beta-EP. These results suggest that TAN-821 and TAN-1014 are respectively a selective epsilon receptor agonist and antagonist and that they may be useful tools for investigating the pharmacological properties of the epsilon opioid receptor.     

Effects of selective opioid receptor agonists and antagonists during myocardial ischaemia.

The antiarrhythmic activities of 16-methylcyprenorphine (M8008), nor-binaltorphimine (NBT) and naltrexone, which are relatively specific opioid receptor antagonists for delta, kappa and mu receptors, respectively, were examined during the 30 min following coronary artery occlusion in anaesthetised rats. The haemodynamic and electrocardiographic effects of the opioid receptor agonists [D-Ala2,D-Leu5]enkephalin (DADLE) (relatively selective for delta receptors), ICI-204448 (kappa) and glyol (mu) were also investigated over the 30-90 min post ligation period. When administered intravenously 5 min before ligation, M8008 (0.5 mg kg-1 and 2.5 mg kg-1) reduced the number of ventricular ectopic beats but had no effect on the incidence or duration of ventricular fibrillation. NBT and naltrexone were not antiarrhythmic at a dose of 0.5 mg kg-1 but at 2.5 mg kg-1 (a concentration at which both drugs block kappa receptors) the number of ventricular ectopic beats, the incidence of ventricular fibrillation and mortality were all reduced. All of the opioid receptor agonists caused a transient decrease in heart rate and in arterial blood pressure but none exhibited an arrhythmogenic effect. These studies suggest that the delta and kappa opioid receptor antagonists used may be antiarrhythmic as a result of blockade of the action of endogenously released peptides acting on these receptors or that they have a non-specific 'direct' antiarrhythmic action.     

Modulation of mu, delta and kappa opioid receptors in rat brain by metal ions and histidine

The effect of zinc (Zn2+) and several other trace elements was studied on the binding of the opioid receptor agonists [3H] DAGO [( ([Tyr-D-Ala-Gly-Methyl-Phe-Glyol]-enkephalin)a, [3H] DSTLE ([Tyr-D-Ser-Gly-Phe-Leu-Thr]-enkephalin) and [3H] EKC (ethylketocyclazocine), which are specific for the mu, delta and kappa opioid receptors, respectively, in the cerebral cortex of the rat. Physiological concentrations of zinc were inhibitory to mu receptor binding, whereas the delta and kappa receptors were relatively insensitive to this inhibition. Scatchard analysis, using these opioid agonists, revealed curvilinear plots; concentrations of zinc equal to or less than the IC50 (the concentration of cation which caused 50% inhibition of the binding of opioid ligand to its receptor), increased the KD (the dissociation constant) of all three subtypes of receptor, with no effect on the Bmax (the maximum number of binding sites) and abolished the high affinity sites of the delta and kappa receptors. Copper, cadmium and mercury also inhibited the binding of these ligands to their receptors. Histidine was most effective in preventing the inhibitory effects of zinc and copper, whereas it was less effective on cadmium and without any effect on the inhibition caused by mercury. Magnesium and manganese were stimulatory to opioid receptor binding, whereas cobalt and nickel had dual (stimulatory and inhibitory) effects. Non-inhibitory concentrations of zinc significantly decreased the stimulatory effects of magnesium and manganese on the mu and delta receptors, suggesting that part of the effect of zinc was through prevention of the actions of stimulatory cations.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacology of [Tyr1]nociceptin analogs: receptor binding and bioassay studies

Two series of nociceptin (NC)-related peptides with or without replacement of the N-terminal Phe by Tyr have been investigated in an attempt to obtain compounds that interact with the NC receptor (ORL1) and classic opioid receptors. When tested for their ability to displace [3H]NCNH2 ([3H]nociceptin amide; ORL1 sites) or the selective opioid receptor ligands [3H]DAMGO (mu), [3H]deltorphin II (delta) and [3H]U69593 (kappa) from their respective binding sites in guinea-pig brain membranes, [Tyr1]NCNH2 and [Tyr1]NC(1-13)NH2 showed high affinities (Ki 2nM and 5 nM, respectively) for ORL1 and approximately tenfold lower potency for mu (32nM and 44nM) and kappa sites (42 nM and 48 nM). They also interacted, but with low potency (Ki 410 nM and 310 nM) with delta sites. Shorter fragments as [Tyr1]NC(1-9)NH2 and [Tyr1]NC(1-5)NH2 were found to be inactive on ORL1, delta and kappa sites, and extremely weak (Ki 2224 nM and 4228 nM, respectively) on mu. Results of bioassays performed on the guinea-pig ileum (ORL1 and mu receptors), mouse vas deferens (ORL1 and delta receptors), and rabbit vas deferens (kappa receptor) confirmed (at least partially) the data of the binding by showing that [Tyr1]NC analogs interact with functional ORL1 as well as with classic opioid receptors. [Tyr1]NCNH2 and [Tyr1]NC(1-13)NH2 behaved as mixed ORL1/opioid receptor agonists showing similar affinities as the control NC sequence while [Tyr1]NC(1-9)NH2 and [Tyr1]NC(1-5)NH2 were inactive on ORL1 receptors but maintained some activities on opioid receptors: their effects were prevented by naloxone. The results of this study indicate that the replacement of Phe1 by Tyr in NC leads to compounds which bind both the ORL1 and mu/kappa receptors and may represent new promising agents for use in peripheral organs.     

Design and synthesis of novel hydrazide-linked bifunctional peptides as delta/mu opioid receptor agonists and CCK-1/CCK-2 receptor antagonists

A series of hydrazide-linked bifunctional peptides designed to act as agonists for delta/mu opioid receptors and antagonists for CCK-1/CCK-2 receptors was prepared and tested for binding to both opioid and CCK receptors and in functional assays. SAR studies in the CCK region examined the structural requirements for the side chain groups at positions 1', 2', and 4' and for the N-terminal protecting group, which are related to interactions not only with CCK, but also with opioid receptors. Most peptide ligands that showed high binding affinities (0.1-10 nM) for both delta and mu opioid receptors generally showed lower binding affinities (micromolar range) at CCK-1 and CCK-2 receptors, but were potent CCK receptor antagonists in the GPI/LMMP assay (up to Ke = 6.5 nM). The results indicate that it is reasonable to design chimeric bifunctional peptide ligands for different G-protein coupled receptors in a single molecule.     

Three-dimensional quantitative structure-activity relationships and activity predictions of human TRPV1 channel antagonists: comparative molecular field analysis and comparative molecular similarity index analysis of cinnamides

3D-QSAR models for human TRPV1 channel antagonists were developed based on comparative molecular field analysis (CoMFA) and comparative molecular similarity analysis (CoMSIA), using a training set of 61 cinnamide TRPV1 antagonists and tested on an independent test set of 47 antagonists. Molecular alignment procedure included weights for both internal energy and atom-to-atom matching against a reference or probe. Sensitivity of results on partial charge assignments was explored using multiple charge sets. AM1-BCC charge assignments gave better results for both CoMFA and CoMSIA models. For the best CoMFA model, the statistics are, r2 = 0.96, q2 = 0.58, n = 61 for the training set and r2 = 0.50, n = 47 for the test set. For the best CoMSIA model, the statistics are r2 = 0.95, q2 = 0.57, n = 61 for the training set and r2 = 0.48, n = 47 for the test set. These models are consistent with the proposed binding modes and interactions of known activators of the TRPV1 channel such as capsaicin, in a structural model of the TM3/4 helical region of TRPV1.     

No evidence for G-protein-coupled epsilon receptor in the brain of triple opioid receptor knockout mouse

Pharmacological approaches have defined the epsilon receptor as a beta-endorphin-preferring opioid receptor, described in rat vas deferens and in brain of several species. Only three opioid receptors-mu, delta and kappa-have been cloned and the existence of this additional subtype as a distinct protein remains controversial. Recently, the mouse brain epsilon receptor was detected in a G protein activation assay, as mediating residual beta-endorphin activity following pharmacological blockade of mu, delta and kappa receptors. To clarify whether this site is independent from mu, delta and kappa receptors, we performed beta-endorphin-induced [(35)S]GTPgammaS binding using mice lacking these three receptors (triple knockout mice). We tested both pons-medulla and whole brain preparations. beta-Endorphin strongly stimulated [(35)S]GTPgammaS binding in wild-type membranes but had no detectable effect in membranes from triple knockout mice. We conclude that the brain epsilon site involves mu, delta and/or kappa receptors, possibly coupled to nonclassical G proteins.