A comparison of morphine-induced locomotor activity and mesolimbic dopamine release in C57BL6, 129Sv and DBA2 mice

Inbred mouse strains show marked variations in morphine-induced locomotion and reward behaviors. As increases in mesolimbic dopamine release and locomotion have been implicated as being critical aspects of drug-seeking and reward-related behaviors, the present study sought to determine the relationship between morphine-induced changes in locomotion and mesolimbic dopamine release. Freely moving microdialysis of the ventral striatum was performed in mouse strains chosen on the basis of their documented differences in locomotor and reward response to morphine (C57BL6 and DBA2) and use in the production of genetically modified mice (129Sv). Both C57BL6 and 129Sv mice showed significant increases in locomotion and ventral striatal extracellular dopamine levels following subcutaneous morphine administration (3 mg/kg), with the former strain showing the largest increase in both parameters. Ventral striatal extracellular DA levels increased in DBA2 mice to a similar extent as 129Sv mice following morphine administration, despite this strain showing no locomotor response. Intra-strain analysis found no correlation between morphine-induced locomotion and mesolimbic dopamine release in any of the strains studied. Thus, no universal relationship between morphine-induced mesolimbic dopamine release and locomotion exists between, and particularly within, inbred mouse strains. Furthermore, morphine-induced increases in mesolimbic activity correlate negatively with the rewarding potential of morphine described in previously reported conditioned place preference studies.     

Effects of morphine and methionine-enkephalin on the smooth muscle tonus and the contraction induced by transmural stimulation in the carp (Cyprinus carpio) intestinal bulb

The effects of morphine and methionine-enkephalin (met-enkephalin) on the smooth muscle tonus and the contraction induced by transmural stimulation were investigated in the isolated intestinal bulb of carp in vitro. Morphine (30 nM-3 microM) and met-enkephalin (3 nM-5 microM) caused dose-dependent non-sustained contraction. Naloxone (10 nM) inhibited the contraction induced by morphine or met-enkephalin in a competitive manner. Tetrodotoxin (400 nM) or atropine (500 nM) did not inhibit the contraction induced by morphine or met-enkephalin. Cooling of the bath fluid from 20 to 10 degrees C decreased nicotine- and transmural stimulation-induced contraction. But met-enkephalin-induced contraction was not affected. Transmural stimulation-induced contraction (3 Hz) was not affected by pretreatment with morphine, met-enkephalin or naloxone. The results demonstrated that morphine or met-enkephalin caused contraction of the smooth muscle directly through the activation of opiate receptors on the smooth muscle cells and neither morphine nor met-enkephalin regulated the cholinergic neurotransmission presynaptically.     

Hyperthermia induced by morphine administration to the VTA of the rat brain: an effect dissociable from morphine-induced reward and hyperactivity

Morphine action at opiate receptors in the ventral tegmental area (VTA) of the rat brain has been implicated in the production of increased locomotor activity and in morphine's rewarding properties. In the present experiments, bilateral administration of morphine (18 micrograms tapped into the tips of 28 gauge cannulae) into the VTA resulted in an increase in body temperature in rats. This effect was both reversed and blocked by a systemic injection of the opiate receptor blocker, naloxone, suggesting that it was due to morphine action at opiate receptors. The neuroleptic, pimozide, injected systemically four hours prior to morphine administration completely blocked the increased locomotor activity but had no effect on the hyperthermia. These data demonstrate that the hyperthermia was not brought about by the increased physical activity. Furthermore, these results suggest that while morphine-induced reward and increased locomotor activity may be mediated by an interaction of morphine and the ascending mesolimbic dopamine system, the hyperthermia is not. In an additional experiment, the effect of systemic injections of the central neurotransmitter receptor antagonists, scopolamine, phenoxybenzamine, and methergoline, on the hyperthermia induced by morphine in the VTA was investigated. Only the serotonin antagonist, methergoline, attenuated the hyperthermia.     

Monoclonal antibody to enkephalins with binding characteristics similar to opiate receptor

Monoclonal antibodies to enkephalins were established by immunization of mice with met-enkephalin, leu-enkephalin or both. Twenty-three clones with a high titer were classified into 6 types according to the binding properties to enkephalins and their derivatives. Antibody LM 239 showed binding characteristics similar to opiate receptor. It has a very high affinity to enkephalins and their derivatives which have a potent opioid activity, but a low affinity to enkephalin derivatives which devoid of opioid activity. The binding of 3H-met-enkephalin to the antibody was inhibited by naloxone and morphine, although the ID50 values were considerably higher than the Ka values of the alkaloids to opiate receptor.     

Potencies of normorphine and met-enkephalin in the vas deferens of different strains of mice.

The concentration of normorphine causing a 50 per cent inhibition (IC₅₀) of electrically induced twitches in the vas deferens from seven strains of mice varied over a 13-fold range, BALB/cKB being the most, C57BL/6J the least sensitive. There was no significant correlation between the IC₅₀'s of normorphine and met-enkephalin. In the sensitive BALB/cKB mice, both normorphine and met-enkephalin were more effective inhibiting contractions evoked by 0.1 Hz than by 0.01 or 1.2 Hz stimulation. This difference was not observed in the insensitive C57BL/6J mice. Naloxone was purely an antagonist against both normorphine and met-enkephalin in BALB/cKB mice but in low concentration it potentiated the inhibitory effect of both normorphine and met-enkephalin in C57BL/6J mice. Results suggest that qualitative differences in opiate receptors and differences in transmitter release mechanism contribute to the variable sensitivity to morphine of the vas deferens from different strains of mice.     

Effect of met-enkephalin and morphine on gastric secretion and blood flow

The effects of met-enkephalin and morphine on gastric acid and pepsin secretion and gastric mucosal and total blood flow were studied in anaesthetized dogs with an in vivo chambered secretion stomach preparation. It was found that both agents infused intraarterially caused an increase in histamine-induced acid and pepsin secretion and mucosal and total blood flow. The above responses were significantly blocked by naloxone and nalorphine. In the resting stomach both opiates did not induce secretory changes but they increased mucosal and total blood flow. Met-enkephalin and morphine were also effective after intravenous administration. Met-enkephalin but not morphine fails to stimulate acid secretion if given into the portal vein. The likely mechanism of action of opiates on gastric secretion is discussed and a hypothesis of existence of opiate receptors in the gastric wall is presented.     

Dissociation of morphine withdrawal diarrhea and jumping in mice by the peripherally selective opioid antagonist SR 58002 C

Mice were rendered physically dependent by repeated administration of morphine, 25 mg/kg s.c., 5 times daily for 4 days, and on the 5th day, 2 h after the last morphine dose, they were challenged with a s.c. injection of either naloxone, 25 mg/kg, or the peripherally selective opioid antagonist SR 58002 C (N-methyl levallorphan mesilate), 75 mg/kg. Naloxone provoked jumping and diarrhea in all the animals; mice challenged with SR 58002 C presented no significant jumping but a high frequency of withdrawal diarrhea. When naloxone, 12 mg/kg, or SR 58002 C, 50 mg/kg, were given s.c. in combination with repeated morphine as above, mice which had received naloxone with morphine presented virtually no diarrhea or jumping upon naloxone challenge; those repeatedly treated with morphine plus SR 58002 C were substantially protected from naloxone-precipitated diarrhea, but not jumping. These results further support the remarkable selectivity for peripheral opioid receptors of SR 58002 C, even after repeated high-dose treatment, and are strongly consistent with the primary role of a local intestinal mechanism in the development and expression of opioid withdrawal diarrhea in mice. The in vivo dissociation of central and peripheral components of dependence on morphine is illustrated, apparently for the first time.     

Long-term enhancement of morphine hypalgesia as a result of periodic blockade of opiate receptors using naloxone

A significant enhancement of the analgetic effect of morphine (6 mg/kg, subcutaneously; tail withdrawal reflex at 60 degrees C) was observed in rats 3-4 hours after single naloxone (1 mg/kg) administration. Periodical naloxone injection (0.5 mg/kg, subcutaneously, 3 times per day at 3.5-hour intervals for 3 days) led to a prominent and long-term (testing on the 20th and 105th hour after the last naloxone administration) enhancement of morphine analgesia (2.6 mg/kg subcutaneously) and insignificant inhibition of stress analgesia during two-hour immobilization of animals. These modifications of morphine and stress analgetic effects are considered a result of adaptive changes of opiate receptors after their blockade.     

Evidence for intrinsic regulation of met-enkephalin-immunoreactivity in gastroenteropancreatic tissues of the rat

In a study whether gastrointestinal endogenous opioids can be modified by vagal denervation or by pharmacological application of an opiate, we examined met-enkephalin-immunoreactivity in gastrointestinal tissue in rats with and without truncal vagotomy and with and without subcutaneously implanted morphine pellets. The immunoreactivity of the tissue extracts gave dose-response lines in the radioimmunoassay for met-enkephalin which were near parallel to that for the standard. On Sephadex chromatography the met-enkephalin immunoreactivity eluted at a position similar to synthetic met-enkephalin. Tissue concentration of met-enkephalin immunoreactivity was not significantly different from the respective control after vagotomy and after morphine treatment. Total gastric met-enkephalin immunoreactive content increased significantly after vagotomy in line with gastric hypertrophy occurring after vagotomy without a drainage procedure. From these results it is concluded that met-enkephalin immunoreactivity in the rat gastrointestinal tract is regulated intrinsically, it is neither altered by vagal denervation nor by exogenous opiate administration.     

Evidence contradicting the notion that gonadal hormones regulate brain opiate receptors

Castration of male rats has been reported to increase brain opiate receptors by nearly 100%. We assayed brain opiate receptors with both naloxone and met-enkephalin, but found no effect of gonadectomy on the Kd or Bmax for either ligand in male or female mice or in male rats. Experiments were performed with 2 strains of mice and 3 strains of rats; mice were gonadectomized 1–7 weeks and rats were castrated 3 weeks before assay. Both washed and unwashed brain membrane preparations were used. Administration of testosterone or estrogen to intact male or female mice did not alter opiate receptors. Castration did not affect the strain or age and brain-region differences found for naloxone binding in male rats.     

Intracerebral beta-endorphin, met-enkephalin and morphine: kindling of seizures and handling-induced potentiation of epileptiform effects

The effects of repeated infusion of small, initially subconvulsive amounts of beta-endorphin, met-enkephalin or morphine sulfate into the amygdala and hippocampus were investigated. beta-endorphin and met-enkephalin evoked epileptiform spiking when infused into the posterior amygdala or ventral hippocampus. Morphine evoked epileptiform spiking when infused into the anterior amygdala. Naloxone blocked or terminated the spiking. Repetition of the infusions led to the gradual development of bilateral generalized convulsions by beta-endorphin and met-enkephalin and to the development of tolerance to morphine. An unexpected observation was that handling, immobilization or conspecific threat potentiated the epileptiform effects of beta-endorphin and morphine in many cases. These results suggest that endogenous opiate mechanisms might play a role in convulsive seizures and that stressful stimuli can exacerbate opiate seizures.     

Evidence for sedative effects of low doses of morphine in mice involving receptors insensitive to naloxone

Low doses of morphine (0.30–2.5 mg/kg) decrease in a dose-dependent manner spontaneous climbing behaviour in mice. This effect is not modified by administration of naloxone at doses up to 1.25 mg/kg. These morphine doses do not modify the locomotor activity but, when they are associated with naloxone (0.5 mg/kg), an obvious inhibition occurs. In rats, a hyperactivity follows the akinesia produced by a morphine administration (10 mg/kg). This hyperactivity is changed into a significant hypokinesia when the animals are treated with naloxone (0.05 mg/kg). These results might reveal a dual effect of low doses of morphine, the excitatory effect of morphine being antagonized by naloxone whereas no action on the sedative effect is observed.     

Pupillary effects of leucine and methionine enkephalin in rats after intraperitoneal administration

Changes in pupil size after peripheral administration of met-enkephalin, leu-enkephalin, or morphine were studied in the rat. With a simple pupillographic technique, the pupil diameter of male, S.D. rats (250–300 g) was measured by a series of photographs taken every 60 sec for at least 45 min after the last drug injection. Morphine (8 mg/kg, SC) caused mydriasis characterized by rapid and marked fluctuations of pupil size. Mydriasis also occurred after leu-enkephalin (5 and 10 mg/kg, IP) and met-enkephalin (20 mg/kg, IP). Both peptides induced morphine-like fluctuations. When given 15 min after morphine, leu-enkephalin (5 and 10 mg/kg) increased the mydriatic effect of morphine from 172 percent of control to 224 and 272 percent, respectively. Met-enkephalin (20 mg/kg, but not 10 mg/kg) also enhanced the mydriatic response of morphine, to 244 percent of control. These interactions appear to represent simple addition rather than potentiation. The effects of both peptides were reversed by naloxone (1 mg/kg, SC), suggesting an opiate receptor interaction for the pupillary effects of the enkephalins. The rat pupil thus provides one of the few in vivo models permitting quantification of enkephalin action after parenteral administration.     

A behavioral role for enkephalins in regulating locomotor activity in the insect Leucophaea maderae: evidence for high affinity kappa-like opioid binding sites

D'-Ala-2 met-5-enkephalinamide application to the cerebral ganglia of Leucophaea maderae results in a decrease in locomotor activity. The opiate antagonist, naloxone, can block this effect as well as the depressant effect of morphine on locomotor activity. D-Ala-2,leu-5-enkephalinamide and dynorphin enhance locomotor activity following their topical application to the cerebral ganglia. This effect also can be antagonized by concomitant naloxone treatment. Benzomorphans were the most potent ligands tested in their ability to displace [3H]D'-ala-2,met-5-enkephalinamide whereas mu and delta ligands were by comparison less potent. These results suggest the presence of kappa-like opioid receptors in Leucophaea cerebral ganglia. The kappa ligands also are potent in enhancing locomotor activity in addition to being weakly antagonized by naloxone. Again, these results indicate the presence of multiple-opiate receptor types in invertebrates.     

Alteration of brain stem auditory evoked potentials after intracerebroventricular administration of met-enkephalin in rabbits.

Brainstem auditory evoked potentials (BAEPs) were elicited by binaural click stimulation and recorded from the rabbits with chronically implanted electrodes and a cannula for intracerebroventricular injection (i.c.v.). 400 BAEPs were averaged off line. The registration was carried out before and after i.c.v. injection of met-enkephalin (2.5 or 25 nmol), naloxone (20 micrograms), or i.v. injection of morphine (1.0, 2.0, 5.0 mg/kg b.w.). Enkephalin caused shortening of interpeak latency time, naloxone caused its lengthening, while the effect of morphine was not unidirectional. Enkephalin caused increase in the surface area below the negative peaks located in the range of 4.5-7.5 ms from the first positive peak, naloxone caused its decrease while the effect of morphine was also in this respect not unidirectional. It is concluded that opiate receptors are involved in the modulation of the auditory brainstem responses.     

Changes in total and free tryptophan levels in serum following acute morphine administration in arthritic rats

In ‘arthritic’ rats a decrease in total tryptophan and an increase in free tryptophan levels was observed in serum after morphine administration (10 mg kg, s.c.). These changes were maximum within 15 and 30 min after injection.A decrease in total and an increase in free tryptophan levels in serum were observed 30 min after naloxone administration (1 mg/kg, i.m.).An increase in tryptophan and 5-hydroxyindoleacetic acid levels was also observed in the brain after morphine and naloxone.These observations suggest that the rise in 5-hydroxytryptamine synthesis provoked by morphine may be partly related to an increase in the availability of tryptophan from blood. However, the analgesia induced by the opiate appears unlikely to be directly related to this effect.     

In vivo electrochemical studies of rat striatal dopamine and serotonin release after morphine

The effect of the reference opiate, morphine (d-morphine-sulfate), on endogenously released striatal dopamine and serotonin was studied in male, adult, anesthetized Sprague-Dawley rats. The intraperitoneal administration of morphine produced a biphasic effect on striatal dopamine release. A significant increase in the dopamine signal was seen in the first hour after drug administration; a significant decrease in the dopamine signal was seen in the second and third hour after drug administration. On the other hand, the effect of morphine on striatal serotonin release was monophasic. Morphine significantly increased serotonin release from rat striatum. The effect lasted three hours after morphine administration, i.e., the effect persisted significantly throughout the study. These data show a simultaneous opiate-dopaminergic and opiate-serotonergic interaction in rat striatum. These data further extend studies which have suggested that the pharmacological mechanism of action of morphine may have its etiology in the concurrent modulation of more than one neurotransmitter.     

Antagonism by nalmefene of systemic and intrathecal morphine-induced analgesia in mice

Nalmefene is an orally active opiate antagonist structurally related to naloxone and naltrexone. In this study using two different strains of mice (Swiss Cox and ICR), the antagonist activity of nalmefene given subcutaneously (sc) was quantified by determination of the apparent pA2 values against the antinociceptive activity (tail flick and hot plate tests) of morphine given sc or intrathecally (lumbar spinal cord). The apparent pA2 values (constrained to a slope of -1) were 8.06 (7.79-8.33) in Swiss Cox mice and 7.81 (7.62-8.00) in ICR mice in the tail flick test with sc morphine. These values were larger than the corresponding value for naloxone in ICR mice, 7.35 (7.10-7.60). The hot plate test provided similar results: the apparent pA2 values for nalmefene with sc morphine were 8.14 (7.89-8.39) in Swiss Cox mice and 7.81 (7.65-7.97) in ICR mice, values which were different from naloxone 7.33 (7.23-7.42) in ICR mice. Apparent pA2 values for nalmefene with intrathecal morphine were not different from those for naloxone in the tail flick test. Thus, these sets of results suggest that it may be worthwhile to further determine whether systemic nalmefene might possibly possess an advantage over naloxone in antagonizing systemic side effects of morphine arising from local spinal morphine administration.     

Presynaptic Dopaminergic Function in the Nucleus Accumbens Following Chronic Opiate Treatment and Precipitated Withdrawal

Naloxone treatment at three days following implantation of pellets containing morphine base increased uptake of tritiated dopamine by the nucleus accumbens but did not alter efflux of tritiated dopamine by the nucleus accumbens or tritiated norepinephrine by the hippocampus. At six days following placement of pellets containing morphine base, withdrawal score was increased after treatment with either saline or naloxone, indicating that animals were undergoing spontaneous opiate withdrawal. Fractional efflux of tritiated dopamine was decreased at this time point following intermittent stimulation with 317 and 1000 M 4-aminopyridine, for striatal slices obtained from animals pretreated with either saline or naloxone. For the nucleus accumbens at six days after placement of morphine pellets, similar decreases in the efflux of tritiated dopamine were only observed in slices obtained from naloxone treated animals. Fractional dopamine efflux was also diminished after in vitro exposure to rising concentrations of 4-aminopyridine, amphetamine, or cocaine for tissue obtained from the nucleus accumbens, but not for slices from the striatum at six days following morphine pellet implantation. In conclusion, deficits in dopamine efflux by the nucleus accumbens occur at a time when animals are undergoing spontaneous opiate withdrawal at six days following morphine pellet implantation, but do not occur at an earlier time point when withdrawal is precipitated by naloxone treatment. These deficits are apparent for brain slices obtained from the striatum or nucleus accumbens after exposure to rising concentrations of different in vitro treatments, with tissue obtained from the nucleus accumbens being more sensitive than the striatum to dopamine efflux produced by a wider range of treatments.