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Vol. 281, Issue 2, 730-737, 1997
Department of Pharmacology and Toxicology, Medical College of
Virginia/Virginia Commonwealth University, Richmond, Virginia
Intrathecal administration of 
9-tetrahydrocannabinol
(9-THC) but not the cannabinoid agonist CP55,940
enhances the antinociception produced by morphine. In addition,
CP55,940- and 9-THC-induced antinociception is blocked
by the kappa opioid antagonist norbinaltorphimine, and
both cannabinoids are cross-tolerant to kappa agonists
but do not act directly at the kappa receptor. Previous
work in our laboratory has implicated dynorphins in the antinociceptive
effects of 9-THC and its enhancement of morphine-induced
antinociception. The goal of the present study was to evaluate the role
of dynorphins in the antinociceptive effects of CP55,940 at the spinal
level. Pretreatment of mice with antisera to dynorphin A(1-17),
dynorphin A(1-8) or 
-neoendorphin, all of which have been shown to
retain specificity for blockade of their respective peptide in
vivo, blocked the antinociceptive effects of
9-THC but not CP55,940. Dynorphin B produced
antinociceptive effects on intrathecal administration to mice. Like
CP55,940, dynorphin B failed to enhance the antinociceptive effects of
morphine, whereas dynorphin A(1-17) and -neoendorphin enhanced the
antinociceptive effects of morphine. Using spinal catheterization of
the rat, CP55,940 administration was shown to produce a significant
release of dynorphin B concurrent with the production of
antinociception. Our data suggest that CP55,940 induces a release of
spinal dynorphin B that contributes at least in part to its
antinociceptive effects in the spinal cord.
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