Autoradiographic localization of kappa opiate receptors to deep layers of the cerebral cortex may explain unique sedative and analgesic effects

The pharmacologically defined kappa drug 3H-ethylketazocine (3H-EKC) and 3H-bremazocine bind to unique sites, but also to mu and delta receptors. By displacing mu and delta interactions with morphine and D-Ala2, D-Leu5-enkephalin (DADL) respectively we have visualized selective receptors for 3H-EKC and 3H-bremazocine. These two kappa ligands are localized to sites different from mu and delta receptors labeled with 3H-dihydromorphine (3H-DHM) and 3H-DADL. The highest density and most selective localization of putative kappa receptors occurs in layers V and VI of the cerebral cortex. Cells in these layers project to the thalamus, regulating sensory input to the cortex. These deep cortical kappa receptors may account for the unique sedative and analgesic actions of kappa opiates.     

Antinociceptive effects of [D-Ala2]deltorphin II, a highly selective delta agonist in vivo

The present study has characterized the antinociceptive actions of [D-Ala2]deltorphin II following intracerebroventricular (i.c.v.) administration in the mouse tail-flick test. [D-Ala2]deltorphin II produced dose- and time-related antinociception, with maximal effects at +10 min and significant antinociception which lasted for 40-60 min. [D-Ala2]deltorphin II was 13-fold more potent than i.c.v. [D-Pen2, D-Pen5]enkephalin (DPDPE), a second highly selective delta agonist, and approximately equipotent with i.c.v. morphine in producing antinociception. The antinociceptive effects of i.c.v. [D-Ala2]deltorphin II and DPDPE, but not those of morphine, were antagonized by the selective delta antagonist, ICI 174,864. In contrast, pretreatment with the non-equilibrium mu antagonist, beta-funaltrexamine blocked morphine antinociception, but failed to antagonize [D-Ala2]deltorphin II and DPDPE antinociception. These data indicate that [D-Ala2]deltorphin II produced its antinociceptive effects at a supraspinal delta receptor. [D-Ala2]deltorphin II appears to be the most appropriate delta opioid agonist currently available for studies in vivo and support the involvement of delta receptors in supraspinal antinociception.     

Further evidence that naloxone acts as an inverse opiate agonist: Implications for drug dependence and withdrawaL

To test if naloxone behaved as an inverse agonist rather than as an antagonist we evaluated its responses in guinea-pig ilea with and without morphine (480 nM, 24 h). In control ilea, naloxone (100 nM) had no effect. In morphine-treated ilea, naloxone as a bolus, but not as an infusion, elicited an abstinence response. Preadministration of naloxone blocked the response to subsequent administrations. Similarly, naloxone failed to produce an abstinence response in ilea pretreated with kappa compounds (bremazocine, U50488 or xorphanol 100 nM) or with kinase inhibitors (H7 or H8 30 μM). These findings can be interpreted in the light of the two-state receptor model if naloxone behaves as an inverse agonist: Incubation with morphine increased the active state of receptors making them susceptible to the inverse agonist (naloxone); exposure to naloxone favored the inactive conformation making them insensitive to further administration of naloxone; kappa compounds behaved as antagonists preventing the response to naloxone; and kinase inhibitors interfered with the active conformation making the system insensitive to naloxone. According to this model, dependence can be viewed as an overexpression of the active receptors and withdrawal as an abrupt change from the active to the inactive state.     

Novel ligands for the opioid receptors: synthesis and structure-activity relationships among 5'-aryl and 5'-heteroaryl 17-cyclopropylmethyl-4,5 alpha-epoxypyrido[2',3':6,7]morphinans

A series of pyridomorphinans possessing an aryl (10a-s) or heteroaryl (11a-h) substituent at the 5'-position of the pyridine ring of 17-cyclopropylmethyl-4,5 alpha-epoxypyrido[2',3':6,7]morphinan was synthesized and evaluated for binding and functional activity at the opioid delta, mu, and kappa receptors. All of these pyridomorphinans bound with higher affinity at the delta site than at mu or kappa sites. The binding data on isomeric compounds revealed that there exists greater bulk tolerance for substituents placed at the o-position of the phenyl ring than at m- or p-positions. Among the ligands examined, the 2-chlorophenyl (10l), 2-nitrophenyl (10n), 2-pyridyl (11a), and 4-quinolinyl (11g) compounds bound to the delta receptor with subnanomolar affinity. Compound 10c with the p-tolyl substituent displayed the highest mu/delta selectivity (ratio=42) whereas compound 10l with the 2-chlorophenyl substituent displayed the highest kappa/delta selectivity (ratio=23). At 10 microM concentration, the in vitro functional activity determined using [(35)S]GTP-gamma-S binding assays showed that all of the compounds were antagonists devoid of any significant agonist activity at the delta, mu, and kappa receptors. Antagonist potency determinations of three selected ligands revealed that the p-tolyl compound 10c is a potent delta selective antagonist. In the [(35)S]GTP-gamma-S assays this compound had a functional antagonist K(i) value of 0.2, 4.52, and 7.62 nM at the delta, mu, and kappa receptors, respectively. In the smooth muscle assays 10c displayed delta antagonist potency with a K(e) value of 0.88 nM. As an antagonist, it was 70-fold more potent at the delta receptors in the MVD than at the mu receptors in the GPI. The in vitro delta antagonist profile of this pyridomorphinan 10c resembles that of the widely used delta selective antagonist ligand naltrindole.     

Effects of selective opioid agonists on feline colonic transit.

The mu agonist morphine and the non-specific opioid antagonist naloxone both may accelerate feline colonic transit; the effects of morphine are dose dependent. Kappa and delta receptor function was studied in the present work. Colonic transit of a radionuclide marker instilled into the cecum was quantitated for 6 hr in a crossover study. The delta agonist [D-Pen2,D-pen5]enkephalin (1 mg/kg, i.m.) prolonged the cecum and ascending colon half-emptying time by 337% (P less than 0.05), and delayed the progression of the geometric center over time. The kappa agonist U-50,488 (1 mg/kg, i.m.) had no apparent effect on the cecum and ascending colon, but delayed filling of the descending colon. Loperamide, an antidiarrheal agent, also delayed colonic transit. Thus, selective opioid agonists have both site and functional differences in their effect on feline colonic transit.     

Pyrrolo- and pyridomorphinans: Non-selective opioid antagonists and delta opioid agonists/mu opioid partial agonists

Opioid ligands have found use in a number of therapeutic areas, including for the treatment of pain and opiate addiction (using agonists) and alcohol addiction (using antagonists such as naltrexone and nalmefene). The reaction of imines, derived from the opioid ligands oxymorphone and naltrexone, with Michael acceptors leads to pyridomorphinans with structures similar to known pyrrolo- and indolomorphinans. One of the synthesized compounds, 5e, derived from oxymorphone had substantial agonist activity at delta opioid receptors but not at mu and/or kappa opioid receptors and in that sense profiled as a selective delta opioid receptor agonist. The pyridomorphinans derived from naltrexone and naloxone were all found to be non-selective potent antagonists and as such could have utility as treatments for alcohol abuse.     

Tramadol reduces the 5-HTP-induced head-twitch response in mice via the activation of mu and kappa opioid receptors

Tramadol, an atypical opioid analgesic, stimulates both opiatergic and serotonergic systems. Here we have investigated the effect of tramadol in mice on 5-hydroxyptrytophan (5-HTP)-induced head twitch response (HTR), which is an animal model for the activation of the CNS 5-HT(2A) receptors in mice. Tramadol attenuated 5-HTP-induced HTR in a dose-dependent manner as morphine. Furthermore, the nonselective opioid receptor antagonists, naloxone and diprenorphine (M5050), reversed the effect of tramadol on 5-HTP-induced HTR dose-dependently. Interestingly, in contrast to the selective delta opioid receptor antagonist NTI, beta-FNA, a selective mu receptor antagonist, and nor-BNI, a selective kappa opioid receptor antagonist, antagonized the attenuation of 5-HTP-induced HTR by tramadol. In conclusion, administration of tramadol systemically inhibits 5-HTP-induced HTR in mice by activating opiatergic system in the CNS. Our findings show that mu and kappa opioid receptors, but not delta opioid receptor, play an important role in the regulation of serotonergic function in the CNS.     

Discrete mapping of brain Mu and delta opioid receptors using selective peptides: quantitative autoradiography, species differences and comparison with kappa receptors

The opioid peptides, [3H]DAGO and [3H]DPDPE, bound to rat and guinea pig brain homogenates with a high, nanomolar affinity and to a high density of mu and delta receptors, respectively. [3H]DAGO binding to mu receptors was competitively inhibited by unlabelled opioids with the following rank order of potency: DAGO greater than morphine greater than DADLE greater than naloxone greater than etorphine much greater than U50488 much greater than DPDPE. In contrast, [3H]DPDPE binding to delta receptors was inhibited by compounds with the following rank order of potency: DPDPE greater than DADLE greater than etorphine greater than dynorphin(1-8) greater than naloxone much greater than U50488 much greater than DAGO. These profiles were consistent with specific labelling of the mu and delta opioid receptors, respectively. In vitro autoradiographic techniques coupled with computer-assisted image analyses revealed a discrete but differential anatomical localization of mu and delta receptors in the rat and guinea pig brain. In general, mu and delta receptor density in the rat exceeded that in the guinea pig brain and differed markedly from that of kappa receptors in these species. However, while mu receptors were distributed throughout the brain with "hotspots" in the fore-, mid- and hindbrain of the two rodents, the delta sites were relatively diffusely distributed, and were mainly concentrated in the forebrain with particularly high levels within the olfactory bulb (OB), n. accumbens and striatum. Notable regions of high density of mu receptors in the rat and guinea pig brain were the accessory olfactory bulb, striatal "patches" and "streaks," amygdaloid nuclei, ventral hippocampal subiculum and dentate gyrus, numerous thalamic nuclei, geniculate bodies, central grey, superior and inferior colliculi, solitary and pontine nuclei and s. nigra. Tissues of high delta receptor concentration included, OB (external plexiform layer), striatum, n. accumbens, amygdala and cortex (layers I-II and V-VI). Delta receptors in the guinea pig were, in general, similarly distributed to the rat, but in contrast to the latter, the hindbrain regions such as the thalamus, geniculate bodies, central grey and superior and inferior colliculi of the guinea pig were apparently more enriched than the rat. These patterns of mu and delta site distribution differed dramatically from that of the kappa opioid sites in these species studied with the peptide [125I]dynorphin(1-8).     

Opioid control of the ruminant stomach motility: functional importance of mu, kappa and delta receptors

In sheep, the subcutaneous (SC) or intracerebroventricular (ICV) administration of the mu-type opioid agonists, fentanyl and morphine, evokes a blockade of the cyclic contractions of the reticulum. A similar inhibition of forestomach motility was recorded following the administration of the two enkephalin analogs, D-Ala2-Met5-enkephalinamide (DAMA) and D-Ala2-D-Leu5-enkephalin (DADLE) which are mixed mu - delta opioid agonists. In contrast, the reticular contractions were enhanced by the SC or ICV administration of the kappa type agonist, ethylketazocine (EKC) and U - 50 488 H. The proximal duodenum motor activity was transiently increased resulting in the occurrence of a phase III-like activity by these opioid agonists, regardless of the subtypes. The effects of the opioid agonists on reticular motility were prevented by the injection of naloxone but not by the quaternary parent compound methylnaloxone which does not cross the blood-brain barrier. The duodenal motor effects elicited by the opioid agonists were antagonized by both naloxone and methylnaloxone. The results suggest that the inhibition of the ruminant stomach motility is centrally mediated by mu - delta type opioid agonists and are consistent with opposite effects from kappa type opioid agonists. The stimulatory effect of peptide and non-peptide opioid agonists on the duodenum may result in part from direct opioid receptor-mediated actions on smooth muscle.     

Ligands for opioid and sigma-receptors improve cardiac electrical stability in rat models of post-infarction cardiosclerosis and stress.

The effects of the extremely selective mu-opioid receptor agonist, [D-Arg2,Lys4]-dermorphin-(1-4)-amide (DALDA), the mu-opioid receptor agonist morphine, the mu/delta agonist D-Ala2, Leu5, Arg6-enkephalin (dalargin), the kappa-opioid receptor agonist spiradoline, and the sigma1-receptor antagonist DuP 734 on ventricular fibrillation threshold (VFT) was investigated in an experimental post-infarction cardiosclerosis model and an immobilization stress-induced model in rats. Both models produced a significant decrease in VFT. The postinfarction cardiosclerosis-induced decrease in VFT was significantly reversed by intravenous administration of dalargin (0.1 mg/kg), DALDA (0.1 mg/kg), or morphine HCl (1.5 mg/kg). Pretreatment with naloxone (0.2 mg/kg) completely eliminated the increase in cardiac electrical stability produced by DALDA. Both spiradoline (8 mg/kg, i.p.) and DuP 734 (1 mg/kg, i.p.) produced a significant increase in VFT in rats with post-infarction cardiosclerosis. This effect of spiradoline was blocked by nor-binaltorphimine. The immobilization stress-induced decrease in VFT was significantly reversed by administration of either DALDA, spiradoline or DuP 734. In conclusion, activation of either mu- or kappa1-opioid receptors or blockade of sigma1-receptors reversed the decrease in VFT in both cardiac compromised models. Since DALDA and dalargin essentially do not cross blood brain barriers, their effects on VFT may be mediated through peripheral mu-opioid receptors.     

The kappa-opioid receptor from human placenta: hydrodynamic characteristics and evidence for its association with a G protein

The kappa nature of opioid binding sites in a brush border membrane (BBM) fraction from human placenta has been confirmed: these sites display considerably higher apparent affinity (KI = 1.2 nM) for the kappa selective ligand U-50488 than they do for the mu and delta selective ligands [D-Ala2, MePhe4, Glyol5] enkephalin (KI = 1.5-2 microM) and [D-Thr2, Leu5] enkephalyl-Thr (KI = 10-15 microM), respectively. The BBM fraction from human placenta was incubated either with the agonist 3H-etorphine or with the antagonist 3H-diprenorphine and subsequently solubilized with digitonin. The solubilized macromolecular radioactivity was found to behave as a homogeneous entity both in molecular exclusion chromatography (app. rs = 6.1 nm) and in linear sucrose gradients (app. S20.w = 12 S). Two lines of evidence indicated that the placental kappa opioid receptor is capable of interacting with a guanine nucleotide regulatory (G) protein: (i) equilibrium binding of the agonist 3H-etorphine in the BBM fraction was clearly inhibited by 5'-guanylylimidodiphosphate (Gpp(NH)p), especially in the presence of Na+ ions while binding of the antagonist 3H-diprenorphine was significantly less so and (ii) the sedimentation velocity of the kappa opioid receptor was decreased down to about 10 S when the BBM fraction was prelabeled with radioligand in the presence of Gpp(NH)p prior to its solubilization with digitonin. The G protein that mediates the effect of Gpp(NH)p might be neither Gs nor Gi since no adenylate cyclase activity could be demonstrated in the BBM fraction from human placenta.     

Opioid receptor agonists in the rabbit colon: comparison of in vivo and in vitro studies

Myoelectrical activity was recorded in the proximal and distal colon of rabbits using chronically implanted electrodes. The motility in both the proximal and distal colon was inhibited by the intravenous (IV) administration of the following opioid agonists for mu receptors: morphine and fentanyl, kappa receptors: ethylketazocine (EKC) and U 50 488 H, and delta receptors: D-Ala2 D-Leu5-enkephalin (DADLE) and D-Ser2 Leu-enkephalin-Thr6 (DSLET). In contrast, the myoelectric activity in the distal colon was increased during the infusion of an endogenous kappa opioid agonist, dynorphin (DYN). All of these effects were prevented by naloxone pretreatment. During in vitro studies using extraluminal force transducers, fentanyl, U 50 488 H and DSLET inhibited spontaneous contractions of the proximal colon, but U 50 488 H and DSLET caused a substantial increase in the motility of the distal colon. The observed motor responses in the proximal and distal colon following opioid agonist administration indicate that the control of these two intestinal segments may be different. It is suggested that the stimulatory effect of dynorphin on the distal colon is peripherally-mediated while inhibition of the whole colon by opioid agonists regardless of subtypes seems to be centrally-mediated.     

Ketazocines and morphine: effects on gastrointestinal transit after central and peripheral administration

The mu agonist, morphine, and the prototype kappa agonists, ketocyclazocine and ethylketocyclazocine (EK), were studied for their effects on gastrointestinal transit. Following s.c. administration, both morphine (0.3-3 mg/kg) and ketocyclazocine (0.3-10 mg/kg) antagonized transit of an opaque marker through the small intestines of mice. Morphine (0.1-1 microgram) was also effective after intracerebroventricular (icv) administration in mice whereas ketocyclazocine (0.3-30 micrograms) was not. Similarly, while both morphine (0.3-5 mg/kg) and EK (0.6-10 mg/kg) slowed transit after s.c. injection to rats, only morphine (1-10 micrograms), but not EK (0.3-300 micrograms), was active following icv administration. Icv infusion of the mu benzomorphan, phenazocine (10-100 micrograms), slowed transit in a dose-related manner. These results indicate that there may be an anatomically distinct distribution of receptors for benzomorphan kappa agonists in both the mouse and rat, with these opiate receptors not being located near the lateral cerebral ventricles. The difference in efficacy between morphine and ketazocines in slowing gastrointestinal transit after icv administration to rodents suggests that (a) inactivity in this endpoint is a characteristic of benzomorphan kappa compounds and (b) the model may serve as a useful screen when establishing in vivo profiles of kappa agonists in mice and rats.     

Kappa opiate agonists inhibit Ca2+ influx in rat spinal cord-dorsal root ganglion cocultures. Involvement of a GTP-binding protein

The aim of the present study has been to characterize the regulation by opiates of 45Ca2+ influx in rat spinal cord-dorsal root ganglion cocultures. We have demonstrated that K+-induced depolarization, in the presence of the Ca2+ channel agonist Bay K8644, stimulated Ca2+ influx (3-4-fold) via the dihydropyridine class of voltage-dependent Ca2+ channels. While mu and delta opiates had no effect, kappa opiate agonists (e.g. U50488, dynorphin) profoundly depressed the stimulated Ca2+ influx (86% inhibition at 100 microM U50488). The kappa agonist action was stereospecific and could be reversed by the opiate antagonist naloxone. The inhibition produced by kappa agonists was greatly diminished following pertussis toxin treatment, and this effect was accompanied by toxin-induced ADP-ribosylation of a 40-41-kDa protein. This suggests that kappa opiate receptors are negatively coupled to voltage-dependent Ca2+ channels, via a pertussis toxin-sensitive GTP-binding protein. Basal 45Ca2+ uptake, stimulated by adenylate cyclase activators (forskolin and cholera toxin), was potently inhibited by kappa opiates suggesting that, under conditions of neurohormonal stimulation of adenylate cyclase, kappa receptors are coupled to Ca2+ channels indirectly via the adenylate cyclase complex. In addition, cAMP-independent coupling pathways may also be involved.     

Further studies on opioids and hibernation: delta opioid receptor ligand selectively induced hibernation in summer-active ground squirrels

To examine the possible involvement of multiple opioid receptors in animal hibernation, we infused opioids selective for mu, kappa, and delta opioid receptors into summer-active ground squirrels (Citellus tridecemlineatus). The effects of those opioid treatments on the hibernation induced by HIT (Hibernation Induction Trigger) were also examined. Mu opioids morphine (1.50 mg/kg/day) and morphiceptin (0.82 mg/kg/day) and kappa opioid peptide dynorphin A (0.82 mg/kg/day) did not induce hibernation. On the contrary, morphine, morphiceptin and dynorphin A antagonized HIT-induced hibernation in summer-active ground squirrels. Infusion of delta opioid DADLE (D-Ala2-D-Leu5 enkephalin; 1.50 mg/kg/day), however, induced summer hibernation in a manner comparable to that induced by HIT. It is concluded therefore that delta opioid receptor and its ligand may be intimately involved in animal hibernation. In view of the fact that HIT was obtained from winter hibernating animals and might therefore be responsible for natural hibernation, our results also suggest that naturally occurring mu and kappa opioids may play an important role in the arousal state of hibernation.     

Estimation of the affinity of naloxone at supraspinal and spinal opioid receptors in vivo: studies with receptor selective agonists

The apparent affinity of naloxone at cerebral and spinal sites was estimated using selective mu [D-Ala2, Gly-o15]-enkephalin (DAGO) and delta [D-Pen2, D-Pen5]enkephalin] (DPDPE) opioid agonists in the mouse warm water tail-withdrawal test in vivo; the mu agonist morphine was employed as a reference compound. The approach was to determine the naloxone pA2 using a time-dependent method with both agonist and antagonist given intracerebroventricularly (i.c.v.) or intrathecally (i.th.); naloxone was always given 5 min before the agonist. Complete time-response curves were determined for each agonist at each site in the absence, and in the presence, of a single, fixed i.c.v. or i.th. dose of naloxone. From these i.c.v. or i.th. pairs of time-response curves, pairs of dose-response lines were constructed at various times; these lines showed decreasing displacement with time, indicative of the disappearance of naloxone. The graph of log (dose ratio-1) vs. time was linear with negative slope, in agreement with the time-dependent form of the equation for competitive antagonism. From this plot, the apparent pA2 and naloxone half-life was calculated at each site and against each agonist. The affinity of naloxone was not significantly different when compared between agonists after i.c.v. administration. A small difference was seen between the affinity of i.th. naloxone against DPDPE and DAGO; the i.th. naloxone pA2 against morphine, however, was not different than that for DPDPE and DAGO. The naloxone half-life varied between 6.6 and 16.9 min, values close to those previously reported for this compound. These results suggest that the agonists studied may produce their i.c.v. analgesic effects at the same receptor type or that alternatively, the naloxone pA2 may be fortuitously similar for mu and delta receptors in vivo. Additionally, while the affinity of naloxone appears different for the receptors activated by i.th. DAGO and DPDPE, further work may be necessary before firm conclusions regarding the nature of the spinal analgesic receptor(s) can be drawn.     

Exploration of universal cysteines in the binding sites of three opioid receptor subtypes by disulfide-bonding affinity labeling with chemically activated thiol-containing dynorphin A analogs.

A ligand containing an SNpys group, i.e. 3-nitro-2-pyridinesulfenyl linked to a mercapto (or thiol) group, can bind covalently to a free mercapto group to form a disulfide bond via the thiol-disulfide exchange reaction. This SNpys chemistry has been successfully applied to the discriminative affinity labeling of mu and delta opioid receptors with SNpys-containing enkephalins [Yasunaga, T. et al. (1996) J. Biochem. 120, 459-465]. In order to explore the mercapto groups conserved at or near the ligand binding sites of three opioid receptor subtypes, we synthesized two Cys(Npys)-containing analogs of dynorphin A, namely, [D-Ala2, Cys(Npys)8]dynorphin A-(1-9) amide (1) and [D-Ala2, Cys(Npys)12]dynorphin A-(1-13) amide (2). When rat (mu and delta) or guinea pig (kappa) brain membranes were incubated with these Cys(Npys)-containing dynorphin A analogs and then assayed for inhibition of the binding of DAGO (mu), deltorphin II (delta), and U-69593 (kappa), the number of receptors decreased sharply, depending upon the concentrations of these Cys(Npys)-containing dynorphin A analogs. It was found that dynorphin A analogs 1 and 2 effectively label mu receptors (EC50 = 27-33 nM), but also label delta receptors fairly well (160-180 nM). However, for kappa receptors they showed drastically different potencies as to affinity labeling; i.e., EC50 = 210 nM for analog 1, but 10,000 nM for analog 2. Analog 2 labeled kappa receptors about 50 times more weakly than analog 1. These results suggested that dynorphin A analog 1 labels the Cys residues conserved in mu, delta, and kappa receptors, whereas analog 2 only labels the Cys residues conserved in mu and delta receptors.     

Effect of the anticonvulsant U-54494A on cortical neuron excitability: comparison to the kappa agonist U-50488H.

U-54494A, a 1,2-diamine anticonvulsant, and U-50488H, a structurally related agonist for opiate kappa receptors, were tested for effects on spontaneous and glutamate-evoked firing rates in cerebral cortex of urethane-anesthetized male Sprague-Dawley rats. Iontophoretic application of 1,2-diamines, glutamate diethyl ether (GDEE), or procaine depressed spontaneous and amino acid-induced firing of cortical neurones. With continued ejection of 1,2-diamines or procaine, firing was silenced completely, but GDEE could maintain a partial suppression. A rapid rebound of excitation followed cessation of procaine ejections, but not of other agents. Procaine, but not U-54494A, blocked axonal conduction of rabbit sciatic nerve. Intravenous U-54494A and U-50488H significantly depressed spontaneous firing rates of cortical neurones, but only the U-50488H effects were antagonized by naloxone. It is concluded that U-54494A inhibits neuronal excitability by a mechanism independent of the analgesic kappa receptor. Biochemical and physiological studies have demonstrated that U-54494A and the kappa opioid agonist U-50488H (a structurally related diamine) (1) have anticonvulsant activity (2, 3). U-54494A lacks kappa analgesic and sedative properties, and it has been suggested that the mechanism of action of this compound may be mediated by a subtype of kappa opioid receptor (3). The effects of kappa analgesics on neuronal firing in nociceptive pathways have been described (4, 5). However, no previous electrophysiological studies on U-54494A have been done. Since U-54494A antagonizes amino acid-induced seizures (3), the interactions of this compound with glutamate are of interest. In the present study, the antagonist efficacies of U-54494A and U-50488H for inhibiting spontaneous and 1-glutamate stimulated neurons of the rat prefrontal cerebral cortex were assessed after i.v. and microiontophoretic administration of the compounds. Effects observed with these routes of administration allow the observation of neuronal changes occurring immediately after administration and take advantage of the high temporal resolution provided by the electrophysiological recording techniques of single cells. A preliminary account of portions of this work have been previously disclosed (6).     

Mu and delta receptors: their role in analgesia in the differential effects of opioid peptides on analgesia

Utilizing the mouse tail-flick assay, the rank order of analgesic potency for various opioids (i.c.v.) is beta h-endorphin greater than D-Ala2-D-Leu5-enkephalin greater than morphine greater than D-Ala2-met-enkephalinamide much greater than met-enkephalin much greater than leu-enkephalin. Assuming mu receptor mediation of analgesia, there is an affinity and analgesic potency (ie: D-Ala2-Leu5-enkephalin has 1/7 the affinity of morphine for the mu receptor but is 18X more potent as an analgesic). Additionally, sub-analgesic doses of various opioid peptides have opposite effects on analgesic responses. Leu-enkephalin, D-Ala2-D-Leu5-enkephalin or beta h-endorphin potentiate morphine or D-Ala2-met-enkephalinamide analgesia whereas met-enkephalin or D-Ala2-met-enkephalinamide antagonize opioid-induced analgesia. Using the enkephalins as the prototypic delta ligands (100 fold selective) and based on their effects on analgesia, we suggest that Leu-enkephalin-like peptides interact with the delta receptor as an "agonist" to facilitate and met-enkephalin-like peptides as an "antagonist" to attenuate analgesia. Given the biochemical evidence of a coupling between mu and delta receptors, we suggest that the mechanism of facilitation or attenuation of analgesia by the enkephalins is a direct in vivo consequence of this coupling. Further, the analgesic potencies of various opioid ligands can be better correlated to the combination of their simultaneous occupancy of mu and delta receptors.     

14-beta-Methyl-8-oxacyclorphan (BC-3016), a morphinan derivative with high affinity for kappa opioid receptor: comparison with dynorphin-A(1-13)

14-beta-Methyl-8-oxacyclorphan (BC-3016) was tested for its ability to depress the electrically evoked contractions of the guinea pig ileum (GPI) and of the mouse vas deferens (MVD) and to compete with the binding of prototype ligands selective for kappa-, mu-, or delta-opioid receptors in membrane preparations of rat brain and guinea pig cerebellum. BC-3016 was a very potent agonist in the GPI and MVD preparations, with ID50 of 0.7 and 31 nM, respectively. The activity of levorphanol, a standard alkaloid related to BC-3016, was much lower in both assays with ID50 values of 44 and 86 nM, respectively. Conversely, the activity of BC-3016 was quite comparable to that of dynorphin-A(1-13) in both preparations. In the GPI assay, a putative kappa-receptor antagonist, MR-2266, was 6.6 and 5.5 times more potent than naloxone in blocking the activity of BC-3016 and dynorphin-A(1-13), respectively. BC-3016 was also very potent in displacing bound [3H]ethylketocyclazocine ([3H]EKC) to membrane preparations of the guinea pig cerebellum, a brain component containing predominantly kappa-opioid receptors (Ki of 0.58 nM). Its potency in the displacement of the bound mu-ligand, 3H-labelled (D-Ala2,MePhe4,Gly-OH5)-enkephalin ([3H]DAGO), to rat brain homogenates was somewhat lower (Ki of 0.8 nM) but still high when compared with its ability to displace the delta-ligand, 3H-labelled (D-Ser2, Thr6)-Leu-enkephalin ([3H]DSLET) to rat brain homogenates (Ki of 4.45 nM). The affinity of BC-3016 for the opioid receptor was 2.1-fold higher than that of U-50488H, a selective kappa-opioid ligand.(ABSTRACT TRUNCATED AT 250 WORDS)