Irreversible Activation of the Opiate Receptor of Neuroblastoma × Glioma Hybrid Cells by an Alkylating Benzomorphan Derivative

The benozomorphan derivative (-)-2-[2-(p-bromoacetamidophenyl)ethyl]-5,9 alpha-dimethyl-2'-hydroxy-6,7-benzomorphan (BAB), capable of reacting with nucleophilic groups, acts on neuroblastoma X glioma hybrid cells as a potent, irreversible opiate agonist. Its potency in inhibiting the increase in cellular cyclic AMP, evoked by prostaglandin E1, is comparable to that of Leu-enkephalin. This also applies to its capacity to compete with [3H]D-Ala2-Met-enkephalinamide ([3H]DAEA) in binding on cell membrane preparations. The comparatively lower potency of (-)-2-[2-(p-acetamidophenyl)-ethyl]-5,9 alpha-dimethly-2'-hydroxy-5,7-benzomorphan (AB), which differs from BAB in the substitution of the bromoacetamido group by an acetamido group, is of the same order of magnitude as that of morphine. The covalent interaction of BAB with the opiate receptors is deduced from the observations that (1) it is not possible to wash away this compound from the receptors, (2) the potency of BAB in inhibiting the specific binding of [3H]DAEA increases with prolonged preincubation time, and (3) AB behaves as a reversible agonist.     

Characterization of Opioid Receptors Modulating Noradrenaline Release in the Hippocampus of the Rabbit

Noradrenaline (NA) release and its modulation via presynaptic opioid receptors were studied in rabbit hippocampal slices, which were preincubated with [3H]NA, continuously superfused in the presence of 30 microM cocaine and stimulated electrically. The evoked release of [3H]NA was strongly reduced by the preferential kappa-agonists ethylketocyclazocine, dynorphin A1-13, dynorphin A, trans-3,4-dichloro-N-methyl-N-[2-(1-pyrrolidinyl)-cyclohexyl] -benzeneacetamide (U-50,488), and (-)-5,9-dimethyl-2'-OH-2-tetrahydrofurfuryl-6,7-benzomorphan [(-)-MR 2034], whereas (+)-MR 2035 [the (+)-enantiomer of (-)-MR 2034] was ineffective. In contrast, the preferential delta-agonists Leu-enkephalin, Met-enkephalin, and D-Ala2-D-Leu5-enkephalin (DADLE) as well as the mu-agonists morphine, normorphine, D-Ala2-Gly-ol5-enkephalin (DAGO), and beta-casomorphin 1-4 amide (morphiceptin) were much less potent. However, in similar experiments on rat hippocampal slices DAGO (1 microM) was much more potent than ethylketocyclazocine (1 microM) or DADLE (1 microM). (-)-N-(3-furylmethyl)-alpha-noretazocine [(-)-MR 2266], 1 microM, a preferential kappa-antagonist, antagonized the effect of ethylketocyclazocine more potently than (-)-naloxone or (+)-MR 2267 [the (+)-enantiomer of (-)-MR 2266]. Given alone, (-)-MR 2266 slightly and (+)-MR 2267 (1 microM each) greatly enhanced NA release, apparently due to alpha 2-adrenoceptor blockade since their effects were completely abolished in the presence of yohimbine (0.1 microM).(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of thyrotropin releasing hormone and morphine on gastrointestinal transit

The effect of thyrotropin releasing hormone (TRH) alone and in combination with morphine on the gastrointestinal transit was investigated by using the charcoal meal test in mice. The intraperitoneal (IP) administration of TRH decreased the transit when given in a dose of 1.0 mg/kg 10 min prior to the meal. The intracerebroventricular (ICV) administration of TRH (10 μg/mouse) also inhibited the transit when given just prior to the charcoal meal. Subcutaneous (SC) administration of morphine (5, 10 and 20 mg/kg) inhibited gastrointestinal transit in a dose dependent manner. When TRH (1, 3 and 10 mg/kg, IP as well as 0.3 μg, ICV) which had no effect on the transit by itself was combined with morphine (10 mg/kg, SC), an enhancement in the inhibition of the transit was observed. TRH-induced inhibition of the transit was antagonized by naloxone (0.1 mg/kg, SC). It is concluded that TRH inhibits gastrointestinal transit in the mouse possibly via the opiate receptor system.     

Receptor-related interactions of opiates with PGE-induced adenylate cyclase in brain

The inhibition by opiates of the PGE2-induced formation of cAMP in slices from rat brain striatum was investigated. A maximal, 3.5-fold increase over the basal level of cAMP was obtained with an EC50 for PGE2 of 3 microM. Opiate agonists of both mu and kappa type were inhibitory. The IC50 values for morphine, levorphanol and ethylketocyclazocine (EKC) were 110 nM, 80 nM and 25 nM, respectively. These values were similar to the potencies of the compounds in displacing stereospecifically bound 3H-etorphine in rat brain membranes. As evidenced by the inactivity of dextrorphan, the inhibition of PGE2-dependent cAMP formation was stereospecific. Also ineffective were the opiate antagonists naloxone, naltrexone and MR 2266. These compounds did, however, reverse the inhibition by agonists, displaying thereby selectivity toward the putative mu and kappa opiates. Thus, the inhibition by morphine was antagonized to a greater degree by naloxone than by MR 2266, and the action of EKC was blocked more effectively by MR 2266 relative to naloxone.     

Stereospecific increase by narcotic antagonists of evoked acetylcholine output in guinea-pig ileum.

In the myenteric plexus-longitudinal muscle preparation of the guinea-pig ileum, naloxone (30–100 nM) increases the output of acetylcholine evoked by electrical field stimulation at 0.017 Hz and to a lesser extent also at 10 Hz. The stereospecific requirements for this effect were studied with three pairs of optical isomers of antagonists of the benzomorphan series. The (−)-isomer of β-9-methyl-5-phenyl-2-allyl-2′-hydroxy-6,7-benzomorphan (GPA 1843) which had no agonist activity, had an effect similar to naloxone whereas the (+)-isomer was inactive in this respect. The (−)-isomer of antagonists with even weak agonist activity gave variable results. It is assumed that naloxone antagonises the action of enkephalin which has been shown to be present in the guinea-pig ileum. It is recommended to establish the stereospecificity of an antagonist action in order to exclude pharmacological effects not due to interaction with opiate receptors.     

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.     

Studies on the mechanism of thyrotropin releasing hormone induced inhibition of gastrointestinal transit

Intracerebral administration of thyrotropin releasing hormone (TRH) inhibited gastrointestinal transit in the mouse as determined by the charcoal meal test. A similar inhibitory effect was produced by morphine administered subcutaneously. TRH enhanced morphine-induced inhibition of gastrointestinal transit. Intracerebral injections of cyclo (His-Pro), a postulated metabolite, did not affect gastrointestinal transit either by itself or that produced by morphine. It is suggested that gastrointestinal transit effects of TRH are not mediated via its conversion to cyclo (His-Pro).     

Characterization of kappa1 and kappa2 opioid binding sites in frog (rana esculenta) brain membrane preparation

The distribution and properties of frog brain kappa-opioid receptor subtypes differ not only from those of the guinea pig brain, but also from that of the rat brain. In guinea pig cerebellum the kappa₁ is the dominat receptor subtype, frog brain contains mainly the kappa₂ subtype, and the distribution of the rat brain subtypes is intermediate between the two others. In competition experiments it has been established that ethylketocyclazocine and N-cyclopropylmethyl-norazidomorphine, which are nonselective kappa-ligands, have relatively high affinities to frog brain membranes. The kappa₂ ligands (Met⁵)enkephalin-Arg⁶-Phe⁷ and etorphine also show high affinities to the frog brain. Kappa₁ binding sites measured in the presence of 5 M /D-Ala²-Leu⁵/enkephalin represent 25–30% of [³H]ethylketocyclazocine binding in frog brain membranes. The kappa₂ subtype in frog brain resembles more to the mu subtype than the delta subtype of opioid receptors, but it differs from the mu subtype in displaying low affinity toward beta-endorphin and /D-Ala²-(Me)Phe⁴-Gly⁵-ol/enkephalin (DAGO). From our data it is evident that the opioid receptor subtypes are already present in the amphibian brain but the differences among them are less pronounced than in mammalian brain.Abbreviations used DAGO /D-Ala²-(Me)Phe⁴-Gly⁵-ol/enkephalin - DALE /D-Ala²-L-Leu⁵/-enkephalin - EKC ethylketocyclazocine - DHM dihydromorphine - CAM N-cyclopropylmethylnorazidomorphine - nor-BNI nor-binaltorphimine - MR2034 (-)-(1R,5R,9R)-5, 9-dimethyl-2 (L-tetrahydrofuryl-2'-hydroxy-6,7benzomorphan) - MR2035 (+)-(1R,5R,9R)-5,9-dimethyl-2 (L-tetrahydrofuryl-2'-hydroxy-6,7-benzomorphan), U50488H=3,4-dichloro-N-/2-(1-pyrrolidinyl) —cyclohexo/-benzene-acetamide - PD117302 trans-N-methyl-N-/2-(1-pyrrolidinyl) — cyclohexyl/-benzo (b) thiophene-4-acetamide     

Improved resolution of (±)-trans-2'-hydroxy-5,9-dimethyl-6,7-benzomorphans

An efficient resolution of (±)-trans-2'-hydroxy-5,9-dimethyl-6,7-benzomorphan has been developed employing (—)-(R)- and (+)-(S)-O-acetylmandelic acids. Measurement of optical rotations on the resolved bases, NMR analyses of diastereomeric urea derivatives, as well as gas chromatographic analyses of diastereomeric amide derivatives indicate a net improvement over previous resolution methodology and an enantiomeric excess ≥ 99%. © 1992 Wiley-Liss, Inc.     

Morphine inhibits TRH-induced intestinal transit increases

The current study examined the effects of intraperitoneal (IP) and intracisternal (IC) administration of the opiate agonist, morphine, and an opioid, central beta-endorphin, on thyrotropin releasing hormone (TRH)-induced small intestinal transit increases. Anesthetized rats, 14-day and older, were studied to determine age-related differences. Results showed that in all age groups IP morphine (2 mg/kg) blocked TRH (15 μg)-induced increases in transit of a charcoal bolus. Morphine 1 μg and beta-endorphin 1 μg administered IC in 0.6 μl failed to block TRH (10 μg)-induced increases in intestinal transit in 14-day-old rats. However, both morphine and beta-endorphin 1 μg IC blocked TRH-induced increases in adult rats. Dose-response studies demonstrated that higher doses (> 1 μg) of morphine IC were required to block TRH-induced increases in preweaning rats.     

A novel kappa agonist inhibits [3H]nimodipine binding to a Ca++ channel receptor protein in rat brain

The novel kappa agonist U50-488H in vitro produced a concentration-dependent decrease (0.25-25 microM) in [3H]nimodipine binding in neuronal P2 fractions [corrected] from rat brain cortex. Kinetic analysis indicates the decrease in binding results from a reduced Bmax with no change in affinity (Kd). The kappa antagonist, MR2266, blocked the decrease in [3H]nimodipine binding to membrane fractions. At equimolar concentrations (25 microM), morphine in vitro had no effect on [3H]nimodipine binding, while U50-488H demonstrated potent inhibition. Further kinetic analysis indicates that the IC50 for U50-488H is 0.5-0.7 microM with a KI by a Dixon plot of 1.5-1.7 microM [corrected]. These results suggest that kappa opiate receptors may be coupled to dihydropyridine receptors and as a result modulate Ca++ entry and neurotransmitter release in brain neurons.     

Effects of a kappa-opioid agonist on adrenocorticotropic and diuretic function in man

Although kappa-opiate receptors represent an important fraction of the total opiate receptor capacity in human brain their endocrine function is unknown. We determined the effects of a kappa-opiate receptor agonist on the secretion of vasopressin, ACTH and cortisol and on diuresis. The racemic benzomorphan kappa agonist MR 2033 or its opiate active (-)-isomer, MR 2034, inhibited the release of cortisol and ACTH in 12 trials in a naloxone reversible manner; plasma levels of vasopressin were not altered. The (+)-isomer, MR 2035, did not affect the secretion of cortisol or ACTH. Surprisingly, in five other subjects large increases were observed in vasopressin, ACTH and cortisol following the kappa-agonist, which were probably elicited indirectly by aversive effects of the opioid. The subjects in whom vasopressin release was not altered by MR 2033 and MR 2034 displayed large decreases in urine osmolality which were not antagonized by naloxone. The opiate inactive (+)-isomer, MR 2035, caused no diuretic response. Subjects in whom vasopressin release was stimulated did not show decreases in urine osmolality indicating that vasopressin is capable of antagonizing the diuretic action of the kappa-agonist. Our data show that a kappa-agonist inhibits secretion of cortisol and ACTH by acting at stereospecific opiate receptors and elicits diuresis by acting at stereospecific, but naloxone-insensitive non-classical opioid receptors. These data support the concept that different types of kappa-receptors can be distinguished in man.     

Opioid control of oxytocin secretion: evidence of distinct regulatory actions of two opiate receptor types

Stress induced oxytocin (OT) secretion was measured in female rats following treatment with various opiate antagonists selective for different types of opiate receptor. Naloxone (mu selective) and MR2266 BS (kappa selective) potentiated the OT response to an emotional stress (1 min. immobilization) whereas the delta selective antagonist ICI 154129 was without effect. Similarly, naloxone and MR2266 BS, but not ICI 154129, potentiated the response to a physical stress (i.p. hypertonic saline). A dose response comparison of the actions of naloxone and MR2266 BS revealed that naloxone was most effective in potentiating the immobilization response whereas MR2266 BS elicited greater responses than naloxone when administered prior to hypertonic saline. The results indicate that the opioid regulation of stress induced OT secretion is primarily mediated via mu and kappa opiate receptor types, the two types differentially regulating the OT response to two different stressors.     

Effect of opioid agonist-antagonist interaction on morphine dependence in rats

Morphine dependence was induced by treatment with morphine-admixed food (0.25mg/g of food) for 7 days. Withdrawal was precipitated by injecting naloxone (0.5mg/kg, s.c.). Rats treated with morphine exhibited body weight loss upon the naloxone injection. When morphine-dependent rats were injected subcutaneously with morphine, codeine, meperidine and pentazocine 30 min before the naloxone injection, these drugs significantly suppressed the naloxone-precipitated loss of body weight in a dose-dependent manner. However, body weight loss induced through coadministration of naloxone and Mr-2266 BS were not suppressed by morphine pretreatment. These results suggest that opioids protect against naloxone-precipitated loss of body weight, and that mu and kappa opiate receptors play an important role in the protection against naloxone-precipitated withdrawal.     

Endogenous nitric oxide modulates morphine-induced constipation.

Administration of morphine in mice causes inhibition of the gastrointestinal transit of a charcoal meal. Morphine-induced constipation in mice seems to depend predominantly on action(s) on the central nervous system since N-methyl morphine, a quaternary derivative, inhibits intestinal transit only when administered intracerebroventricularly (i.c.v.). L- but not D-arginine, given intraperitoneally, reversed the constipation induced by both morphine and its quaternary analogue. L-arginine was ineffective when given i.c.v. and did not reverse atropine-induced constipation. These results suggest that L-arginine preferentially modulates opioid-induced constipation through a stereospecific and peripheral action(s). It is possible that the effect of L-arginine is achieved by increasing the amount of nitric oxide released by non-adrenergic, non-cholinergic nerves in the gut. Thus, L-arginine may represent a useful agent for the treatment of undesirable constipation associated with the use of narcotic analgesics.     

In vivo studies with ICI 154,129, a putative delta receptor antagonist

We studied the in vivo pharmacology of ICI 154,129, a new antagonist that is claimed to show selectivity for delta opiate receptors. At s.c. doses of 30 and 100 mg/kg, ICI 154,129 had no marked effect on the gastrointestinal transit of a charcoal meal in mice. In this test, ICI 154,129 reversed the inhibitory action of metkephamid (a proposed delta receptor agonist) but not that of levorphanol. ICI 154,129 was proconvulsant in the mouse picrotoxin potentiation test; the dose-response curve had a low ceiling and was biphasic. Naloxone (1 mg/kg, s.c.) enhanced the proconvulsant action of ICI 154,129 (40 mg/kg, s.c.) by an unknown mechanism.     

Reversal of the effects of centrally-administered morphine on colonic motility in dogs by the benzodiazepine receptor antagonist RO 15-1788

The effects of intravenous (i.v.) and intracerebroventricular (i.c.v.) administration of morphine on jejunal and colonic motility were investigated in conscious dogs chronically prepared with strain gage transducers and compared to those of i.c.v. DAGO, a highly selective opiate mu agonist. Morphine i.v. (100 micrograms/kg) and i.c.v. (10 micrograms/kg) administered 3 hrs after a meal stimulated colonic motility for 3-5 hrs and induced a phase 3 on the jejunum, which appeared after a 15-60 min delay following i.c.v. administration. These effects were reproduced by DAGO administration at doses of 2 micrograms/kg i.v. and 0.2 micrograms/kg i.c.v. The effects of i.v., but not those of i.c.v., morphine and DAGO on jejunal and colonic motility were blocked by a previous administration of naloxone (100 micrograms/kg i.v.). The colonic stimulation but not the jejunal phase 3 induced by i.c.v. morphine and DAGO were blocked by RO 15-1788 (1 mg/kg i.v.), a selective benzodiazepine antagonist. The colonic stimulation induced by i.v. morphine or DAGO was not modify by i.v. RO 15-1788. It is concluded that i.c.v. administration of mu agonist involved benzodiazepine but not opiate receptors to stimulate colonic motility in dogs.     

Effects of Opiates on High-Affinity Ca2+,Mg2+-ATPase in Brain Membrane Subfractions

The effect of a single administration of morphine sulfate (15 mg/kg, s.c. or 30 mg/kg, i.p., 30 min) on Ca2+-stimulated Mg2+-dependent ATPase activity was investigated in synaptosomal plasma membranes (SPM) prepared from rat cortex. Morphine produced a significant decrease in Ca2+,Mg2+-ATPase activity in synaptosomal fractions (SPM 1 + 2) known to contain a high density of opiate receptors and calmodulin-dependent Ca2+,Mg2+-ATPase. However, in another subpopulation (SPM 3) that contains fewer opiate receptors and less enzyme activity, no such decrease in the enzyme activity was observed after the opiate administration. The decrease in Ca2+,Mg2+-ATPase activity seen in SPM 1 + 2 was specifically antagonized by the opiate antagonist naloxone hydrochloride (2 mg/kg, s.c.) when given 15 min before morphine administration. Mg2+-ATPase was not altered either by morphine or by a naloxone-morphine combination. These findings give further evidence for the role of intracellular Ca2+ in mediating many of the acute effects of opiates.     

Regulation of gastrointestinal function by multiple opioid receptors

Agonist and antagonist drugs possessing selectivity for individual types of opioid receptors have been employed in vitro and in vivo to determine the mechanisms by which opioids regulate gastrointestinal functions. Selective mu opioid agonists given by intracerebroventricular (i.c.v.) injection, by intrathecal (i.t.) injection, or by peripheral (s.c. or i.v.) injection in rats or mice decreased gastrointestinal transit and motility, inhibited gastric secretion, and suppressed experimentally-induced diarrhea. Selective delta agonists, by contrast, inhibited gastrointestinal transit after i.t., but not after i.c.v. or s.c. administration. Delta agonists also did not alter gastric secretion after i.c.v. or s.c. injection. However, delta agonists exhibited antidiarrheal effects after i.c.v., i.t., or s.c. administration. Kappa agonists given i.c.v. had no effect on gastrointestinal transit in rats or mice or on gastric secretion in rats, but exhibited antidiarrheal effects in mice. The kappa agonist U-50, 488H given peripherally increased gastric acid secretion. Different types of opioid receptors in different anatomical sites influence differently gastrointestinal motility and propulsion, gastric secretion, and mucosal transport. Brain, spinal cord, enteric neural and smooth muscle opioid receptors represent chemosensitive sites for regulation of gastrointestinal function.     

Inhibitory effect of intracerebroventricularly-administered [D-Arg(2), beta-Ala(4)]-dermorphin (1-4) on gastrointestinal transit

The inhibitory effect of intracerebroventricularly-administered [D-Arg(2), beta-Ala(4)]-dermorphin (1-4) (TAPA), a highly selective mu(1)-opioid receptor agonist, on mouse gastrointestinal transit was compared with that of morphine and [D-Ala(2), N-methyl-Phe(4), Gly(5)-ol]-enkephalin (DAMGO). When administered intracerebroventricularly 5 min before the oral injection of charcoal meal, TAPA (10-100 pmol), morphine (0.25-4 nmol), and DAMGO (20-80 pmol) dose-dependently inhibited gastrointestinal transit of charcoal. The inhibitory effect of each mu-opioid receptor agonist was completely antagonized by naloxone, a nonselective opioid receptor antagonist. The inhibitory effects of morphine and DAMGO were significantly antagonized by both beta-funaltrexamine, a selective mu-opioid receptor antagonist, and naloxonazine, a selective mu(1)-opioid receptor antagonist. In contrast, the inhibitory effect of TAPA was not affected at all by beta-funaltrexamine, naloxonazine, nor-binaltorphimine (a selective kappa-opioid receptor antagonist), or naltrindole (a selective delta-opioid receptor antagonist). These results suggest that the inhibitory effect of TAPA on gastrointestinal transit may be mediated through an opioid receptor mechanism different from that of morphine and DAMGO.