Abstract
Morphine and its derivatives play inevitably important role in the μ-opioid receptor (MOR) targeted antinociception. A structure-activity relationship study is presented for novel and known orvinol and thevinol derivatives with varying 3-O, 6-O, 17-N and 20-alkyl substitutions starting from agonists, antagonists and partial agonists. In vitro competition binding experiments with [3H]DAMGO showed low subnanomolar affinity to MOR. Generally, 6-O-demethylation increased the affinity toward MOR and decreased the efficacy changing the pharmacological profile in some cases. In vivo tests in osteoarthritis inflammation model showed significant antiallodynic effects of thevinol derivatives while orvinol derivatives did not. The pharmacological character was modelled by computational docking to both active and inactive state models of MOR. Docking energy difference for the two states separates agonists and antagonists well while partial agonists overlapped with them. An interaction pattern of the ligands, involving the interacting receptor atoms, showed more efficient separation of the pharmacological profiles. In rats, thevinol derivatives showed antiallodynic effect in vivo. The orvinol derivatives, except for 6-O-desmethyl-dihydroetorfin (2c), did not show antiallodynic effect.
Highlights
In this study we report the biochemical characterization of 6-Odesmethyl-orvinols and 20R-phenethyl-orvinols/thevinols having extremely high potency at m-opioid receptor (MOR)
The results show that the ligands can be classified to their known pharmacological groups using docking energies and related measures, albeit with significant overlap (Fig. 6A)
Neither binding affinities nor pharmacological features could be directly related to particular organic functional groups
Summary
The 17-Nsubstituent serves as an acknowledged pharmacological switch between agonists and antagonists being methyl or cyclopropylmethyl, respectively It is highly ambiguous within this class of opioids, regarding that 17-N-cyclopropylmethyl derivative can be full agonist as well [28,29] which may be a consequence of the bigger size of these opiates resulting in a more complex interaction pattern with the receptor. Antagonist to predict pharmacological activities using the inactive receptor state [30]
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