Discriminative stimulus properties of stereoisomers of cyclazocine in phencyclidine-trained squirrel monkeys

Squirrel monkeys were trained to discriminate 0.16 mg/kg phencyclidine (PCP) from saline in a two-layer drug discrimination task on a fixed-ratio 32 schedule of food presentation. After reliable discriminative control of lever choice was established, dose-response determinations for generalization to the training dose of PCP were made with several doses of PCP, a racemic mixture of cyclazocine and the pure (+)- and (-)-isomers of cyclazocine. Only PCP and the (+)-isomer produced dose-dependent PCP-appropriate responding. Neither the racemic mixture nor (-)-cyclazocine produced over 25% PCP-appropriate responding at any of the doses tested. (+)-Cyclazocine was eight times less potent than PCP in producing drug-lever appropriate responding. (-)-Cyclazocine was about 30 times more potent than PCP and over 200 times more potent than (+)-cyclazocine in overall response rate suppression. The potency of the racemic mixture for response-rate suppression was consistent with an additive effect of the isomers. Neither the PCP-lever appropriate responding produced by (+)-cyclazocine nor the response-rate suppression produced by (-)-cyclazocine were antagonized by naloxone. Thus, racemic cyclazocine is composed of two isomers with differing behavioral effects. The (-)-isomer is more potent, and the (+)-isomer has more specificity for PCP-like effects.     

Effects of the intracerebroventricular injection of antinociceptive doses of acetylcholine on the stereospecific binding of 3H-dihydromorphine

The antinociceptive effects of intraventricularly administered acetylcholine (ACh) and its congeners have been demonstrated by previous investigators. The opiate receptor binding concept was used in this study to investigate possible correlations between ACh antinociception and its effects on opiate stereospecific binding. ACh $\text{in vitro}$ decreased the stereospecific binding of ³H-dihydromorphine in mouse brain homogenates. Such decrease was also observed in the brain homogenates of mice which had been treated with ACh intracerebroventricularly (i.v.t.). The decrease in the stereospecific binding of ³H-dihydromorphine induced by (i.v.t.) acetylcholine was inhibited by naloxone, atropine, cyclazocine and pentazocine. The $\text{d}$-isomers of cyclazocine and pentazocine were more potent than the $\text{l}$-isomers in antagonizing the inhibitory effects of i.v.t. acetylcholine upon the stereospecific binding of ³H-dihydromorphine to mouse brain homogenates. The same stereospecificity of these two narcotic analgesics in blocking acetylcholine had been previously observed in the tail-flick test. It is suggested that the antinociceptive effects of acetylcholine are related to the inhibition of opiate stereospecific binding, the mechanism of which is yet to be understood.     

Evidence for a supraspinal analgesic effect with cyclazocine and pentazocine

The antinociceptive effect of the benzomorphan class of opioid analgesics have been difficult to measure utilizing some of the standard animal pain models. This may be due, in part, to the sedative and/or motor effects associated with these drugs. In addition, it has been proposed that the major site of action for drugs with agonist activity at the kappa opiate receptor is exclusively at the spinal level opposed to both spinal and supraspinal as with the mu receptor agonists such as morphine. The present study examines the antinociceptive effect of the mixed agonist-antagonists cyclazocine and pentazocine utilizing electrical stimulation of the midbrain reticular formation (MRF) as the aversive stimulus in the rat. Animals were trained to escape MRF stimulation by turning a cylindrical manipulandum. An escape threshold was determined by varying the current intensity according to a modification of the psychophysical method of limits. In addition to the determination of the escape threshold the response latency and strength of response was also measured. Both cyclazocine (0.25-1.0 mg/kg) and pentazocine (2.5-12.5 mg/kg) raised the escape threshold in a dose-dependent manner without any concomitant change in the response latency or strength of response. These data suggest that the observed threshold elevation is due to a specific antinociceptive effect. Since the aversive stimulation was delivered supraspinally, the data also suggest that there are supraspinal mechanisms mediated by kappa receptors responsible for this analgesic effect.     

Discriminative stimulus effects of N-allylnormetazocine in rats trained to discriminate a kappa from a sigma agonist

Rats were trained to discriminate ethylketocyclazocine (EKC) from vehicle, phencyclidine (PCP) from vehicle, or ethylketocyclazocine from phencyclidine on a two-lever operant task with a fixed-ratio 30 schedule of food-reinforcement on the appropriate lever. The three groups were tested with the training drugs (i.e., EKC and PCP), N-allylnormetazocine (NANM), and the (+)- and (-)-isomers of N-allylnormetazocine. EKC produced EKC-appropriate responding in the EKC-vehicle group and in the EKC-PCP group; it produced vehicle-appropriate responding in the PCP-vehicle group. Similarly, PCP produced PCP-appropriate responding in the PCP-vehicle group and in the EKC-PCP group but vehicle-appropriate responding in the EKC-vehicle group. The (+)-isomer of NANM produced PCP-appropriate responding in both the PCP-VEH and EKC-PCP groups, whereas the (-)-isomer produced EKC appropriate responding in the EKC-VEH and EKC-PCP groups. The results of this study demonstrate that rats can be trained to discriminate a kappa-agonist from a PCP/sigma-agonist and can differentiate these discriminative stimulus properties of other test compounds. These results also indicate that the (-)-isomer of NANM has kappa-agonist discriminative stimulus properties, whereas PCP/sigma-like effects are produced by the (+)-isomer.     

Naloxone-precipitated jumping in mice pretreated with acute injections of opioids.

Naloxone induced jumping was examined in mice pretreated with single dose of narcotic agonist (morphine, heroin, LAAM, methadone), mixed agonist-antagonist (pentazocine, cyclazocine, buprenorphine), or an enkephalin analog (D-met², pro⁵)-enkephalinamide. Acute sensitization to naloxone, as demonstrated by jumping, was observed after pretreatment with the narcotics, the enkephalin analog, and to a lesser degree after cyclazocine and pentazocine. Mice pretreated with buprenorphine did not jump in response to naloxone. This procedure may be of value in the rapid identification of drugs with a propensity to produce morphine-like physical dependence.     

Affinity of the enantiomers of alpha- and beta-cyclazocine for binding to the phencyclidine and mu opioid receptors

The enantiomers in the alpha and beta series of cyclazocine were evaluated for their ability to bind to phencyclidine (PCP) and mu-opioid receptors in order to determine their receptor selectivity. The affinity of (-)-beta-cyclazocine for the PCP receptor was 1.5 greater than PCP itself. In contrast, (-)-alpha-cyclazocine, (+)-alpha-cyclazocine, and (+)-beta-cyclazocine were 3-, 5- and 138-fold less potent than PCP, respectively. Scatchard analysis of saturable binding of [3H]Tyr-D-Ala-Gly-N-MePhe-Gly-ol (DAMGO) also exhibited a homogeneous population of binding sites with an apparent KD of 1.9 nM and an estimated Bmax of 117 pM. [3H]Tyr-D-Ala-Gly-N-MePhe-Gly-ol (DAMGO) binding studies revealed that (-)-alpha-cyclazocine (KD = 0.48 nM) was 31-, 1020- and 12,600-fold more potent than (-)-beta-cyclazocine, (+)-alpha-cyclazocine and (+)-beta-cyclazocine, respectively, for binding to the mu-opioid receptor. These data show that, although (-)-beta-cyclazocine is a potent PCP receptor ligand consistent with its potent PCP-like discriminative stimulus effects, it shows little selectivity for PCP receptors since it also potently displaces mu-opioid binding. However, these cyclazocine isomers, due to their extraordinary degree of stereoselectivity, may be useful in characterizing the structural requirements for benzomorphans having activity at the PCP receptor.     

STUDIES ON PLANT GROWTH-REGULATING SUBSTANCES

Three synthetic growth-regulating substances, α-(2-naphthoxy)-, α-(2:4-dichloro-phenoxy)- and α-(2:4:5-trichlorophenoxy)-propionic acids, have been resolved into their (+)- and (-)-forms. The physiological activity of these isomers and of the racemic compounds has been investigated using the pea curvature and Avena cylinder test methods of assessment.
The (+)-isomers in each case displayed high activity in both tests, whereas that exhibited by the (-)-isomers was negligible. The racemic compounds showed intermediate activity.
The mode of action of aryloxyalkylcarboxylic acids is discussed in the light of the results presented. These considerations suggest the possibility that the activity of the (+)-isomers might be antagonized by the presence of the corresponding inactive enantiomorphs. Our experiments show that such antagonism does in fact operate.     

The effects of narcotic analgesics and narcotic antagonists on ganglionic transmission in the rat.

The effects of narcotic analgesics, narcotic-antagonist analgesics and narcotic antagonists on ganglionic transmission in the superior cervical ganglia of the rat were studied $\text{in}$$\text{vivo}$ and $\text{in}$$\text{vitro}$. $\text{In}$$\text{vivo}$ administration of morphine, meperidine, methadone, pentazocine or naltrexone blocked ganglionic transmission. Levorphanol, cyclazocine, nalorphine and naloxone had no effect on ganglionic transmission in this procedure. $\text{In}$$\text{vitro}$ studies confirmed the $\text{in}$$\text{vivo}$ results with the exception of levorphanol, cyclazocine and nalorphine, which were also found to block ganglionic transmission $\text{in}$$\text{vitro}$. In both preparations, naloxone did not antagonize the effect of morphine, suggesting that the effects of morphine and the other opiates were nonspecific. Similar potency of $\text{d}$- and $\text{l}$-isomers of pentazocine and cyclazocine support this conclusion. The observation that naltrexone blocked ganglionic transmission, but the other pure narcotic antagonist, naloxone, was inactive is somewhat unique to this test procedure and possibly significant.     

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.     

Sigma binding sites in the brain; an emerging concept for multiple sites and their relevance for psychiatric disorders

An increasing amount of evidence suggests the existence of specific binding sites for psychotomimetic drugs from the opiate-benzomorphan and arylcyclohexylamine series. The sigma binding sites have preferential affinity for the dextrorotatory isomers of certain opiate benzomorphans, such as (+)SKF 10047, (+)cyclazocine and (+)pentazocine and also for some neuroleptics (e.g., haloperidol). The PCP receptor has preferential affinity for phencyclidine (PCP) analogs and other non-competitive N-methyl-D-aspartate (NMDA) receptor antagonists. The physiological significance of the PCP receptor is associated with the blockade of the NMDA type of the glutamate receptor, implying a neuroprotective role of the PCP receptor. However, the significance of the sigma binding sites is less conspicuous. It is not only that drugs from distinct pharmacological classes display a certain degree of affinity for the "sigma/haloperidol" binding sites, but also that drugs which do not induce or block psychotomimetic activity, i.e., (+)3-(3-hydroxyphenyl)-N-(1-propyl) piperidine [(+)3-PPP] and 1,3-di-o-tolyl-guanidine (DTG), display relatively high affinity for the sigma binding sites. The diversity of the compounds which are proposed to interact with the sigma receptors and the variety of the responses elicited by these drugs suggest the existence of sigma receptor subtypes. The finding that the type A of monoamine oxidase (MAO) inhibitors, which are used in treatment of affective disorders, display high affinity for the sigma binding sites suggests their involvement in affective or schizoaffective disorders. Revealing the existence of sigma receptor subtypes may help to elucidate their association with various psychiatric disorders.     

An investigation of the role of kappa opiate receptor agonists in the initiation of feeding

A large body of evidence has suggested a role for the endogenous opiates and their receptors in the regulation of appetite. In this study we have examined the relative effects of ketocyclazocine (KC), cyclazocine and ethylketocyclazocine, all putative kappa opiate receptor agonists, and morphine, a putative mu receptor agonist, on food consumption. All the kappa agonists induced feeding when administered at 8 AM as did morphine. KC failed to induce feeding during the nocturnal feeding period (2000 and 0200 hours) and morphine suppressed feeding at these times. KC and morphine suppressed starvation induced feeding when food was made available immediately after injection and had no effect when food was presented 2 and 4 hours after injection. High doses of naloxone (5 mg/kg) suppressed KC induced feeding while actually enhancing high dose morphine (25 mg/kg) induced feeding. Repeated injections of KC or morphine for 5 days resulted in enhancement of the feeding response with initiation of feeding occuring earlier. Taken together with the studies showing that the endogenous kappa ligand, dynorphin, enhabces feeding the most parsimonious interpretation of these studies is that kappa agonists are endogenous initiators of feeding and that kappa receptors are maximally saturated at times of food deprivation and during spontaneous feeding. The mu (or one of the other) opiate receptors inhibit feeding due to their sedative effect and antagonism of this effect leads to enhancement of the feeding response. It is postulated that kappa opiate receptors represent an important component of the natural feeding drive.     

Beta-adrenergic receptors: stereospecificity and lack of affinity for catechols

Studies of adenylate cyclase activity in rat liver, heart and fat cell microsomal preparations and in turkey and rat erythrocyte ghosts indicate that β-adrenergic receptors exhibit very strict stereospecificity for (?)-catecholamines. (+)-Isomers of active catecholamines and inactive catechol compounds do not inhibit the β-adrenergic-mediated stimulation of adenylate cyclase and thus do not interact with specific receptors. However, very high concentrations (above 10^?4 M) of (?)- and (+)-isomers, as well as of biologically inactive non-catecholamine catechols (e.g., pyrocatechol, dihydroxymandelic acid), inhibit in a nonspecific manner the basal, hormone (catecholamine, glucagon)- and NaF-stimulated adenylate cyclase activity. Studies with propranolol suggest that the low activity (0.1 to 1%) of (+)-isomers of norepinephrine can be explained by contamination with the (?)-isomer. The activity of soterenol, a potent non-catechol β-adrenergic agonist, is uninfluenced by (+)-catecholamines or catechols. It is concluded that the binding of ³H-labeled catecholamines to a variety of cells, microsomes and membranes as described in various previous studies cannot represent specific receptor interactions. Binding to receptors must demonstrate strict stereospecificity and must not be affected by unrelated catechol substances.     

Effects of GABA(A) compounds on mCPP drug discrimination in rats

Male Long-Evans rats were trained to discriminate mCPP (1.4 mg/kg, i.p.) from saline, using a two-lever, food-reinforced operant task. The GABA(A) antagonist, bicuculline (0.16-0.64 mg/kg), partially substituted for mCPP, whereas the benzodiazepine antagonist, flumazenil (1-10 mg/kg), and the benzodiazepine inverse agonist, Ro 15-4513 (0.25-2.5 mg/kg), failed to substitute for mCPP. Bicuculline produced no change in response rate, whereas Ro 15-4513 dose-dependently decreased responding. Flumazenil produced a small increase in response rates. Flumazenil (10 mg/kg), Ro 15-4513 (1.25 mg/kg), and the benzodiazepine agonists alprazolam (0.64 mg/kg) and diazepam (5 mg/kg) full agonist all failed to block the mCPP discriminative stimulus. When given in combination with mCPP, Ro15-4513 and alprazolam both produced lower response rates than did mCPP alone, whereas flumazenil and diazepam did not significantly alter response rates. These findings provide evidence that GABA(A) antagonists modulate the discriminative stimulus effects of mCPP, but that these effects are not mediated by activity at the benzodiazepine site.     

(+)-3-(3-hydroxyphenyl)-N-(1-propyl)piperidine [(+)-3-PPP] but not (-)-3-PPP produces (+)-N-allylnormetazocine-like (SKF 10,047) discriminative stimuli

In rats trained to discriminate the prototypic sigma receptor agonist, (+)-N-Allylnormetazocine [(+)-N-Allylnormetazocine [(+)-NANM/SKF 10,047], from saline, the (+)- but not the (-)-isomer of 3-(3-hydroxyphenyl)-N-(1-propyl)piperidine (3-PPP) produced (+)-NANM-like discriminative stimuli. (+)-3-PPP binds stereo selectively to the (+)-NANM binding site, but not to the phencyclidine binding site. Additionally, phencyclidine was found to produce (+)-NANM-like discriminative stimuli. Although the 3-PPP isomers were shown to produce changes in central dopaminergic activity (Hjorth et al. Life Sci 37, 673, 1985), the discriminative stimulus properties of (+)-3-PPP are apparently not mediated via the dopaminergic system. This hypothesis is supported by the fact that apomorphine did not produce (+)-NANM-like discriminative stimuli. These stimuli are thus non-dopaminergic and may be due to the (+)-3-PPP actions at the sigma binding site. However, it is possible that (+)-NANM, PCP, and (+)-3-PPP may have common non-sigma pharmacologic properties that account for the similar discriminative stimulus properties of these compounds.     

Interaction of dextrorotatory opioids with phencyclidine recognition sites in rat brain membranes

The potencies of several dextrorotatory opioids, including four pairs of enantiomers, as inhibitors of specific [³H]PCP binding to rat brain synaptic membranes has been determined. Of the compounds tested unlabeled phencyclidine (PCP) was the most potent followed by (?)? cyclazocine > dextrorphan > (+) ketamine > (+) cyclazocine > (+)? SKF10,047 > levorphanol > dextromethorphan > (?) SKF10,047 > (?)? ketamine > (±) pentazocine and > (±) ethylketocyclazocine. The opiate mu receptor ligands, morphine, naloxone and naltrexone were virtually inactive as competitors of specific [³H]PCP binding. Unlike the stereostructural requirements for opiate mu receptors where activity resides predominantly in the levorotatory enantiomers, the present results support the contention that binding to the [³H]PCP labeled recognition site may reside in either the levorotatory or the dextrorotatory enantiomer. The specific binding of [³H]PCP which was defined as total binding minus that occurring in the presence of 10μM dextrorphan was found to be of a high affinity, saturable, reversible and sensitive to thermal degradation. These results suggest that certain dextrorotatory morphian derivatives may prove to be useful probes in further investigations of the molecular characteristics of the [³H]PCP binding site in brain membrane preparations.     

Modulation of Histamine Release in the Rat Brain by K-Opioid Receptors

The opioid modulation of histamine release was studied in rat brain slices labeled with L-[3H]histidine. The K(+)-induced [3H]histamine release from cortical slices was progressively inhibited by the preferential kappa-agonists ketocyclazocine, dynorphin A (1-13), Cambridge 20, spiradoline, U50,488H, and U69,593 in increasing concentrations. In contrast, the mu-agonists morphine, morphiceptin, and Tyr-D-Ala-Gly-(NMe)Phe-Gly-ol (DAGO) were ineffective as were the preferential delta-agonists [D-Ala2,D-Leu5]enkephalin (DA-DLE) and [D-Pen2,D-Pen5]enkephalin (DPDPE). Nor-binaltorphimine (nor-BNI) and MR 2266, two preferential kappa-antagonists, reversed the inhibitory effect of the various kappa-agonists more potently than did naloxone, with mean Ki values of 4 nM and 25 nM, respectively. The effects of ketocyclazocine and naloxone also were seen in slices of rat striatum, another brain region known to contain histaminergic nerve endings. We conclude that kappa-opioid receptors, presumably located on histaminergic axons, control histamine release in the brain. However, nor-BNI and naloxone failed, when added alone, to enhance significantly [3H]histamine release from cerebral cortex or striatum, and bestatin, an aminopeptidase inhibitor, failed to decrease K(+)-evoked [3H]histamine release. These two findings suggest that under basal conditions these kappa-opioid receptors are not tonically activated by endogenous dynorphin peptides. The inhibition of cerebral histamine release by kappa-agonists may mediate the sedative actions of these agents in vivo.     

sigma Receptor ligand-induced up-regulation of the H(+)/peptide transporter PEPT1 in the human intestinal cell line Caco-2.

We determined the effects of (+)pentazocine, a selective sigma(1) ligand, on the uptake of glycylsarcosine (Gly-Sar) in the human intestinal cell line Caco-2 which expresses the low affinity/high capacity peptide transporter PEPT1. Confluent Caco-2 cells were treated with various concentrations of (+)pentazocine for desired time (mostly 24 hr). The activity of PEPT1 was assessed by measuring the uptake of [(14)C]Gly-Sar in the presence of a H(+) gradient. (+)Pentazocine increased the uptake of [(14)C]Gly-Sar mediated by PEPT1 in a concentration- and time-dependent manner. Kinetic analyses have indicated that (+)pentazocine increased the maximal velocity (V(max)) for Gly-Sar uptake in Caco-2 cells without affecting the Michaelis-Menten constant (K(t)). In addition, semi-quantitative RT-PCR revealed that treatment of (+)pentazocine increased PEPT1 mRNA in Caco-2 cells in a concentration-dependent manner. These data suggest that sigma(1) receptor ligand (+)pentazocine up-regulates PEPT1 in Caco-2 cells at the level of increased mRNA, causing an increase in the density of the transporter protein in the cell membrane.     

IV. Discriminative stimulus effects of narcotics: Evidence for multiple receptor-mediated actions

Results of studies on the discriminative stimulus effects of narcotics are consistent with the hypothesis that multiple receptors mediate the effects of these compounds. In the rat, at least three subsets of discriminative effects exist, although some drugs appear to have effects that transcend more than one subset. The discriminative effects of morphine-like narcotics (μ agonists), for example, are often clearly distinguishable from the discriminative effects produced by κ agonists, such as ketazocine, and from those produced by phencyclidine-like agonists, such as SKF-10,047 and cyclazocine. Cyclazocine, however, has been reported to have discriminative effects in common with morphine (45) and fentanyl (17) and appears to have κ-like, in addition to phencyclidine-like, discriminative effects. The relative ability of pure narcotic antagonists to block the discriminative effects of these compounds also provides evidence for distinct pharmacologic actions of these drugs. In the rat, the discriminative effects of morphine are blocked by doses of naloxone that are considerably smaller than those that are needed to block the discriminative effects of cyclazocine (44). The discriminative effects of phencyclidine are not altered at all by naltrexone (63).     

Naloxone potentiation of apomorphine-induced stereotypic climbing in mice and interaction with mu-, sigma- and kappa-opiate drugs

Pretreatment with the narcotic antagonist naloxone produced a dose-related potentiation of mouse stereotypic climbing behavior induced by the dopaminergic agonist apomorphine. In further experiments, mice were also pretreated with various drugs specific for mu-opiate receptors (morphine), sigma-opiate receptors (N-allylnormetazocine) and kappa-opiate receptors (ketocyclazocine). Doses of morphine that alone did not affect apomorphine-induced climbing antagonized naloxone potentiation of apomorphine. Doses of N-allylnormetazocine that did not influence apomorphine stereotypy also reversed naloxone potentiation of apomorphine. On the other hand, ketocyclazocine alone exerted a behavioral suppressant effect upon apomorphine- induced stereotypic climbing, however, these same doses failed to prevent naloxone potentiation of apomorphine.     

Effects of the R(+)- and S(-)-isomers of beta-adrenoceptor blockers with intrinsic sympathomimetic activity, befunolol and carteolol, on rabbit intraocular pressure.

Effects of the R(+)- and S(-)-isomers of befunolol and carteolol, beta-adrenoceptors with intrinsic sympathomimetic activity, on the rabbit intraocular pressure were tested. The intraocular pressure was decreased by instillation of the R(+)- and S(-)-isomers of befunolol (0.1 and 0.3%) and of carteolol (1.0%) to the eye and attained the minimum level at 60 min. However, 0.3% of the R(+)- and S(-)-isomers of carteolol did not influence the pressure. The corresponding time courses for the intraocular pressure for the R(+)- and S(-)-isomers did not differ, suggesting that in the treatment of glaucoma, the therapeutic advantage of the R(+)-isomers of befunolol and carteolol may be similar to the S(-)-isomers.