Effects of glucose and diabetes on binding of naloxone and dihydromorphine to opiate receptors in mouse brain.

The effects of glucose and diabetes on the high-affinity lofentanil-displaceable opiate-receptor binding in mouse brain membranes were studied to determine if the attenuation of opiate actions by hyperglycemia previously observed in our laboratory was due to a modification of receptor affinity or number. With membranes from normal ICR mice, glucose (100-400 mg/dl) caused small but significant concentration-dependent decreases in receptor affinities for [3H]naloxone and [3H]dihydromorphine, both in the absence and presence of 20 mM NaCl, without changing the maximum number of binding sites. Fructose and the nonmetabolizable sugar 3-O-methylglucose had intermediate effects on naloxone affinity in the presence of NaCl that were not significantly different from control or from the effect of glucose. Similar results were obtained with brain membranes from streptozocin-induced diabetic mice. The binding affinity for [3H]naloxone in the presence of NaCl was not affected by the induction of diabetes in ICR mice via streptozocin or in spontaneously diabetic (db/db) C57BL/KsJ mice compared with their nondiabetic (m+/m+) littermates. These results indicate that the previously observed attenuation of opiate effects by glucose may be partly due to a glucose-induced decrease in opiate-receptor affinity. However, the much greater attenuation of morphine by fructose in vivo cannot be explained by this mechanism.

Elevated CSF beta-endorphin immunoreactivity in Rett's syndrome: report of 158 cases and comparison with leukemic children.

Because some symptoms of Rett's syndrome are suggestive of excessive endogenous opioid activity, we measured the levels of beta-endorphin-like immunoreactivity in lumbar CSF from 158 affected female patients and from 13 female controls. The mean (+/- SE) control level of beta-endorphin immunoreactivity in CSF was 35.3 +/- 2.8 pg/ml (range, 23 to 48 pg/ml), whereas those with Rett's syndrome had a mean level of 95.3 +/- 3.6 pg/ml (range, 31 to 293 pg/ml). The levels of beta-endorphin immunoreactivity in initial CSF samples exceeded the control range in 90% of the patients with Rett's syndrome. The mean beta-endorphin immunoreactivity was also elevated in CSF from leukemic children (119.2 +/- 16.9 pg/ml; range, 40 to 159 pg/ml), relative to the control group. These results are consistent with the hypothesis that some symptoms of Rett's syndrome may be associated with excessive endogenous opioid levels in the CNS.

Unequal opiate cross-tolerance to morphine in the locomotor-activation model in the mouse.

Dose-response relationships for the opiate-induced stimulation of locomotion in mice were determined for etorphine, fentanyl, levorphanol, lofentanil and morphine, both before and after the subcutaneous implantation of a morphine pellet for 3 days. In non-tolerant mice, the relative potencies of these drugs compared to morphine paralleled those reported for other in vivo models of the actions of opiates. The most potent was lofentanil (ED50 = 3.8 micrograms/kg), which was approx. 6000 times more potent than morphine (ED50 = 24.2 mg/kg). A tolerance-induced 22-fold increase in the ED50 for morphine resulted in a similar cross-tolerance to levorphanol, but there was less cross-tolerance to fentanyl (4-fold), lofentanil (5-fold) and etorphine (7-fold). The smaller cross-tolerances of etorphine and lofentanil to morphine were not accompanied by changes in the levels of [3H]etorphine or [3H]lofentanil in brain, induced by morphine pellets, although the bound fraction of [3H]lofentanil in brain was slightly decreased (11-15%). The implications of the phenomenon of unequal cross-tolerance for the mechanism of tolerance at the opiate mu receptor are discussed.

Effect of intrathecal morphine on the fate of glucose. Comparison with effects of insulin and xanthan gum in mice.

The hypoglycemic effect of morphine (40 micrograms) injected intrathecally (i.t.) was studied with regard to disposition of i.v. [14C]glucose and [3H]2-deoxyglucose and was compared with the effects of two other hypoglycemic agents, insulin (1 IU/kg, s.c.) and xanthan gum (50 mg/kg, i.p.). Mice given i.t. morphine or s.c. insulin exhaled a greater amount of 14CO2 from i.v. [14C]glucose than did control mice given i.t. saline, whereas there was less 14CO2 expiration in xanthan-treated mice. In morphine-treated mice there was less 14C in liver, brain and blood, and more 3H in kidney and hindleg muscle than in control mice. Insulin-treated mice had more 14C in muscle, less 14C in liver, brain, kidney and blood, and less 3H in liver and blood. In xanthan-treated mice, levels of both radiolabels were higher in liver, brain and kidney. Much lower glycogen content in muscle and depletion of liver glycogen occurred in morphine-treated mice, compared with control mice. Spinal transection completely inhibited the hypoglycemic effect of morphine, whereas adrenalectomy caused no inhibition. Morphine, insulin and xanthan appear to be acting by different mechanisms, although the hypoglycemic effects of both morphine and insulin appear to be due largely to an increased glucose uptake by muscle.

Effects of diving experience on submersion-induced increases in plasma levels of beta-endorphin in scuba divers.

The submersion of eight male scuba divers in a state of neutral buoyancy for 20 min resulted in a significant increase (mean, 20%) in plasma beta-endorphin immunoreactivity (beta-EIR), and all subjects reported post-submersion feelings of well-being, relaxation or euphoria. The increase in beta-EIR was negatively correlated with age (r = -0.727) and diving experience (r = -0.860), and positively correlated with the amount of air usage during submersion (r = 0.863). Thus, diving experience appears to influence many of the nonsubjective parameters measured.

Antagonism of antinociception in mice by glucose and fructose: comparison of subcutaneous and intrathecal morphine.

Determination of the ED50s of glucose and fructose, administered i.p., for antagonizing the antinociceptive action of morphine (4 mg/kg s.c. or 0.5 micrograms i.t.) and determination of the ED50s for i.t. morphine after i.p. pretreatment with saline, glucose (5 g/kg) or fructose (5 g/kg) in the mouse tail-flick test indicated that fructose was more potent than glucose in antagonizing antinociception after either route or morphine administration. It is concluded that the antagonism of morphine-induced antinociception by glucose and fructose is due to a direct effect of these sugars or their metabolic products within the central nervous system.

Possible hyperendorphinergic pathophysiology of the Rett syndrome.

The Rett syndrome is a postnatal developmental and neurological disorder seen only in girls. Many of the symptoms of this disorder, such as microcephaly, stereotypy, respiratory disturbances and seizures, are analogous to the effects of the administration of beta-endorphin or other opioids in animals. Preliminary reports of elevated beta-endorphin-like immunoreactivity in the cerebrospinal fluid of girls with the Rett syndrome, as well as improvement in some of their symptoms during the administration of the opioid antagonist naltrexone, are suggestive of endorphinergic hyperactivity. Thus, the pathophysiology of the Rett syndrome might involve excessive stimulation of opioid receptors in the central nervous system by beta-endorphin or other endogenous opioids.

Cholinergic agents: antinociception without morphine type dependence in rats.

We have confirmed the work of others showing that loss in body weight is a predictable and consistent sign of opiate withdrawal in rats. Rats that were treated chronically with either oxotremorine or physostigmine displayed no weight loss or other signs of opiate-like withdrawal when the drugs were withdrawn. Furthermore, there was no difference in weight loss between morphine dependent rats substituted with saline and those substituted with either cholinergic drug. However, we did observe an increased mortality among rats substituted with a cholinergic agent compared with saline. Rats infused with a mixture of morphine plus oxotremorine or morphine plus physostigmine showed less weight loss, but not fewer behavioral signs, after the end of the infusion than rats treated only with morphine. It is concluded that the cholinergic agents did not cause a morphine-like physical dependence themselves, but appeared to antagonize to some extent the development or manifestation of opiate dependence.

Potencies of diazepam metabolites in rats trained to discriminate diazepam.

The dose-response relationships of diazepam and several of its metabolites were determined in rats trained to discriminate diazepam (3 mg/kg) from saline in a two-lever operant choice task. Generalization of the diazepam stimulus was found to occur with temazepam and oxazepam, which were nearly equipotent with diazepam, and also with desmethyldiazepam, which was about half as potent as diazepam. The hydroxylated metabolites, 4'-hydroxydiazepam and 4'-hydroxydesmethyldiazepam were inactive in doses up to 12 mg/kg. These results show that some diazepam metabolites are quite potent behaviorally and indicate the possibility that these metabolites may contribute to the pharmacological effect of diazepam in vivo.

Cardiovascular effects of delta 9- and delta 9(11)-tetrahydrocannabinol and their interaction with epinephrine.

The administration of delta-9-tetrahydrocannabinol (delta 9-THC, 0.078-5.0 mg/kg, i.v.) to rats anesthetized with pentobarbital caused as much as a 50% decrease in mean arterial blood pressure, heart rate and respiratory rate in a dose-dependent manner. Delta-9(11)-tetrahydrocannabinol (delta 9(11)-THC) was approximately 8-fold less potent than delta 9-THC in its hypotensive effect and had smaller effects on heart and respiratory rates that were not dose-related at doses below 5 mg/kg. Alternate injections of epinephrine (2 micrograms/kg) with vehicle and increasing cannabinoid doses (1.25-5.0 mg/kg) indicated a potentiation of both the duration of the pressor effect and the magnitude of the reflex bradycardic effect of epinephrine by both delta 9- and delta 9(11)-THC. Epinephrine also produced arrhythmias in rats receiving cannabinoids, but not in rats receiving alternate injections of vehicle. It is concluded that both cannabinoids have adverse effects on the cardiovascular system and adverse interactions with epinephrine in rats anesthetized with pentobarbital.

Antagonism of the morphine-induced locomotor activation of mice by fructose: comparison with other opiates and sugars, and sugar effects on brain morphine.

The mouse locomotor activation test of opiate action in a 2+2 dose parallel line assay was used in a repeated testing paradigm to determine the test, opiate and hexose specificities of a previously reported antagonism of morphine-induced antinocociception by hyperglycemia. In opiate specificity studies, fructose (5 g/kg, i.p.) significantly reduced the potency ratio for morphine and methadone, but not for levorphanol, meperidine or phenazocine when intragroup comparisons were made. In intergroup comparisons, fructose significantly reduced the potencies of levorphanol and phenazocine, but not methadone or meperidine. In hexose/polyol specificity studies, tagatose and fructose significantly reduced the potency ratio for morphine, whereas glucose, galactose, mannose and the polyols, sorbitol and xylitol, caused no significant decrease in potency. Fructose, tagatose, glucose and mannose (5 g/kg, i.p.) were tested for effects on brain morphine levels 30 min after morphine (60 min after sugar), and all four sugars significantly increased brain morphine relative to saline-pretreated controls. It is concluded that the antagonism of morphine by acute sugar administration shows specificity for certain sugars and occurs despite sugar-induced increases in the distribution of morphine to the brain. Furthermore, the effects of fructose show an opiate specificity similar to that of glucose on antinociception observed previously in our laboratory, except that methadone was also significantly inhibited in the present study, when a repeated-testing experimental design was used.

Stereoselective effect of morphine on antinociception and endogenous opioid peptide levels in plasma but not cerebrospinal fluid of dogs.

Morphine releases endogenous opioids into the circulation of dogs. To test the stereospecificity of this effect, as well as to determine whether morphine also releases endogenous opioids centrally, which might be involved in its antinociceptive action, the effects of (-)-morphine sulfate (10 mg/kg, sc) or (+)-morphine hydrobromide on antinociception in a dog tail-flick test, on semi-quantified morphine-induced signs of salivation, emesis, defecation and ataxia, and on the plasma and cerebrospinal fluid (CSF) levels of endogenous opioid peptides were studied. Plasma and CSF levels of immunoreactive beta-endorphin (i-BE), met-enkephalin (i-ME), leu-enkephalin (i-LE), and dynorphin (i-DY) were quantified by radioimmunoassay in octadecylsilyl-silica cartridge extracts. Immunoreactive morphine (i-M) levels were measured in unextracted samples. (-)-Morphine treatment significantly increased antinociception, morphine-induced signs, i-M levels in plasma and CSF, and i-BE, i-ME, and i-LE levels in plasma, but not CSF. Levels of i-DY remained constant in plasma and CSF. (+)-Morphine treatment did not alter any of these parameters, indicating that the effects of morphine on nociception, behavioral signs, and plasma endogenous opioids in dogs were stereoselective. It is concluded that morphine does not cause an increase in immunoreactive endogenous opioid peptides in the CSF at the time of its peak antinociceptive effect.

Comparison of the ability of opioid analgesics to increase endogenous opioid-like activity in the cerebrospinal fluid of rabbits.

We have previously demonstrated that the acute administration of morphine increases the level of endogenous substances, which have antinociceptive activity, in cerebrospinal fluid (CSF). The present study was conducted to determine whether other opioid analgesics exert a similar effect. CSF was withdrawn from the cisterna magna of anesthetized rabbits before and after s.c. injections of meperidine, pentazocine, levorphanol and methadone, and was bioassayed for opioid-like activity in the mouse tail-flick and phenylquinone writhing tests. The opioid-like activity of CSF taken 60 min after meperidine (50 mg/kg) was significantly increased in both bioassays, and the CSF level of meperidine was insufficient to account for this effect. Pentazocine (25-75 mg/kg) also significantly increased opioid-like activity in rabbit CSF, but the effects of methadone (5-10 mg/kg) and levorphanol (20 mg/kg) were less marked. Dextrorphan (20 mg/kg), diazepam (10 mg/kg) and pentobarbital (20 mg/kg) administration did not significantly increase opioid-like activity in CSF. It is concluded that the antinociceptive action of some opioid analgesics in rabbits may be mediated in part by the release of endogenous antinociceptive substances.

Effects of hyperbaric simulation of scuba diving pressure on plasma beta-endorphin.

In contrast to our previous studies on the submersion of scuba divers in a state of neutral buoyancy, neither plasma beta-endorphin-like immunoreactivity (beta-EIR) nor affective feelings were significantly changes in scuba divers by mimicking diving pressures of 2 feet (0.6 m) and 50 feet (15.2 m) for 20 min in a hyperbaric chamber. It is concluded that the submersion-induced increase in plasma beta-EIR and accompanying changes in affect reported previously are not due solely to changes in pressure.

Is intracellular sodium involved in the mechanism of tolerance to opioid drugs?

Recent studies indicate that one of the more likely mechanisms of opioid tolerance could involve a decrease in the efficiency with which agonists can induce coupling of their specific binding sites in neuronal membranes to the activation (or deactivation) of an effector system. Reports of sodium-induced decreases in opioid receptor agonist binding and in the size of ligand/receptor complexes, as well as modulation of opioid activity by manipulation of sodium in vivo, indicate that sodium might play a physiological role in modulating opioid receptor function. Reports of morphine-induced systemic sodium retention in animals, as well as morphine-induced increases in brain intracellular sodium and decreases in brain Na+, K(+)-ATPase activity, indicate that the development of tolerance may be accompanied by changes in the disposition of sodium. The direction of these sodium- and morphine-induced changes is consistent with the hypothesis that an increase in intracellular sodium could participate in the mechanism(s) of opioid tolerance development.