Molecular pharmacology
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Molecular pharmacology · Feb 2013
Molecular dissection of lubeluzole use-dependent block of voltage-gated sodium channels discloses new therapeutic potentials.
Lubeluzole, which acts on various targets in vitro, including voltage-gated sodium channels, was initially proposed as a neuroprotectant. The lubeluzole structure contains a benzothiazole moiety [N-methyl-1,3-benzothiazole-2-amine (R-like)] related to riluzole and a phenoxy-propranol-amine moiety [(RS)-1-(3,4-difluorophenoxy)-3-(piperidin-1-yl)propan-2-ol (A-core)] recalling propranolol. Both riluzole and propranolol are efficient sodium channel blockers. ⋯ Thus, lubeluzole likely binds to the local anesthetic receptor through its phenoxy-propranol-amine moiety, with consequent use-dependent behavior. Nevertheless, compared with other known sodium channel blockers, lubeluzole adds a third pharmacophoric point through its benzothiazole moiety, which greatly enhances high-affinity binding and use-dependent block. If sufficient isoform specificity can be attained, the huge use-dependent block may help in the development of new sodium channel inhibitors to provide pharmacotherapy for membrane excitability disorders, such as myotonia, epilepsy, or chronic pain.
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Receptors and channels that underlie nociceptive signaling constitute potential sites of intervention for treatment of chronic pain states. The kainate receptor family of glutamate-gated ion channels represents one such candidate set of molecules. ⋯ Pharmacological inhibition or genetic ablation of kainate receptor activity reduces pain behaviors in a number of animal models of chronic pain, and small clinical trials have been conducted using several orthosteric antagonists. This review will cover kainate receptor function and participation in pain signaling as well as the pharmacological studies supporting further consideration as potential targets for therapeutic development.