Dynorphin B and spinal analgesia: induction of antinociception by the cannabinoids CP55,940, Delta(9)-THC and anandamide.

The endogenous opioid dynorphin B was evaluated for its role in cannabinoid-induced antinociception. Previous work in our laboratory has shown that the synthetic, bicyclic cannabinoid, CP55,940, induces the release of dynorphin B whilst the naturally occurring cannabinoid, Delta(9)-tetrahydrocannabinol (Delta(9)-THC), releases dynorphin A. The dynorphins contribute in part to the antinociceptive effects of both cannabinoids at the level of the spinal cord. The present study compares dynorphin B released from perfused rat spinal cord in response to acute administration of anandamide (AEA), Delta(9)-THC and CP55,940 at two time points, 10 min and 30 min post administration, and attempts to correlate such release with antinociceptive effects of the drugs. Dynorphin B was collected from spinal perfusates of rats pretreated with Delta(9)-THC, CP55,940 or AEA. The supernatant was lyophilized and the concentrations of dynorphin B were measured via radioimmunoassay. At a peak time of antinociception (10 min), CP55,940 and Delta(9)-THC induced significant two-fold increases in the release of dynorphin B. AEA did not significantly release dynorphin B. Upon a 30-min pretreatment with the drugs, no significant dynorphin B release was observed, although antinociceptive effects persisted for CP55,940 and Delta(9)-THC. Previous work indicates that Delta(9)-THC releases dynorphin A while AEA releases no dynorphin A. This study confirms that although all three test drugs produced significant antinociception at 10 min, the endocannabinoid, AEA, does not induce antinociception via dynorphin release. Thus, our data indicate a distinct mechanism which underlies AEA-induced antinociception.

Antisense oligodeoxynucleotides to the kappa1 receptor enhance delta9-THC-induced antinociceptive tolerance.

Delta-9-tetrahydrocannabinol produces potent antinociceptive effects in mice and rats. Evidence exists for an interaction between the cannabinoids and the kappa receptor subtype, kappa1, in the production of antinociception. Data indicate that delta9-THC induces the release of endogenous dynorphins, the ligand(s) for the kappa receptor. It has been demonstrated that antisense oligodeoxynucleotides directed against the kappa1 receptor attenuate the antinociceptive effects of delta9-THC. The exact mechanism for the expression of cannabinoid tolerance is unknown. Bidirectional cross-tolerance between the kappa opioids and delta9-THC implies that a common mechanism may be responsible for tolerance expression. We tested the hypothesis that the kappa1 receptor is involved in tolerance to delta9-THC. Antisense to the kappa1 receptor has been shown to downregulate the kappa receptor. We observed a significant increase in the ED50 for delta9-THC in antisense-, but not mismatch-treated mice, indicating an increase in tolerance to delta9-THC. Such data indicate that a decrease in kappa receptor number may accompany tolerance to delta9-THC.

Antinociceptive activity of intrathecal ketorolac is blocked by the kappa-opioid receptor antagonist, nor-binaltorphimine.

Systemic and intrathecally administered ketorolac produced antinociception in the p-phenylquinone test, but not in the tail-flick or hot-plate tests. Antagonists of the subtypes of opioid receptors were used to evaluate the interaction of ketorolac with these receptors. Intrathecally administered kappa-opioid receptor antagonist nor-binaltorphimine dihydrochloride blocked the antinociceptive effects of systemic ketorolac and intrathecally administered ketorolac. Naloxone and ICI 174,864 failed to block the effects of ketorolac. Activation of nor-binaltorphimine-sensitive receptors appears to be an integral element in the mechanism of antinociception of ketorolac at the spinal level. Ketorolac did not precipitate withdrawal jumping in morphine-tolerant mice demonstrating that ketorolac does not act as a mixed agonist-antagonist at the opioid receptor. We suggest that neuraxial placement of ketorolac may prove useful in the clinical setting for the management of acute pain in humans.