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Abstract

Objective

The cannabinoid cannabidiol has established antiseizure effects in drug-resistant epilepsies such as Dravet syndrome and Lennox–Gastaut syndrome. Amorfrutin 2, honokiol, and magnolol are structurally similar to cannabinoids (cannabis-like drugs) but derive from non-cannabis plants. We aimed to study the antiseizure potential of these compounds in various mouse seizure models. In addition, we aimed to characterize their molecular pharmacology at cannabinoid CB₁ and CB₂ receptors and at T-type calcium channels, which are known targets of the cannabinoids.

Methods

Brain and plasma pharmacokinetic profiles were determined. Antiseizure activity was assessed against hyperthermia-induced seizures in a Scn1a
^+/−
mouse model of Dravet syndrome. We then elaborated on the most promising compounds in the maximal electroshock (MES) test in mice and the Gabrb3
^+/D120N
mouse model of Lennox–Gastaut syndrome. Fluorescence-based assays were used to examine modulatory activity at cannabinoid CB₁ and CB₂ receptors and T-type calcium channel subtypes Ca_V3.1, Ca_V3.2, and Ca_V3.3 overexpressed in mammalian cells. Automated patch-clamp electrophysiology was then used to confirm inhibitory activity on Ca_V3.1, Ca_V3.2, and Ca_V3.3 channels.

Results

Magnolol and honokiol had high brain-to-plasma ratios (3.55 and 7.56, respectively), unlike amorfrutin 2 (0.06). Amorfrutin 2 and magnolol but not honokiol significantly increased the body temperature threshold at which Scn1a
^+/−
mice had a generalized tonic–clonic seizure. Both amorfrutin 2 and magnolol significantly decreased the proportion of mice exhibiting hindlimb extension in the MES test. Furthermore, magnolol reduced the number and duration of atypical absence seizures in Gabrb3
^+/D120N
mice. The three compounds inhibited all T-type calcium channel subtypes but were without specific activity at cannabinoid receptors.

Significance

We show for the first time that amorfrutin 2 and magnolol display novel antiseizure activity in mouse drug-resistant epilepsy models. Our results justify future drug discovery campaigns around these structural scaffolds that aim to develop novel antiseizure drugs for intractable epilepsies.