Abstract

Photoswitches are molecules that change their conformation with light of specific wavelength. These light-regulated molecules can be designed to target ion channels, thus providing a unique tool for precise spatial and temporal control of ion channel functioning. Recently, we have applied a multidisciplinary approach to design, synthesize and functionally characterize two of such photoswitches, azo-NZ1 [Maleeva et al. Br. J. Pharmacol. 2019] and Glyght [Gomila-Juaneda et al. BioRxiv 2019], targeting GABA and glycine receptors, respectively. Using homology modeling and molecular docking, we have provided a molecular explanation of the light-dependent effect of these two photoswitchable ligands, as observed in in vitro electrophysiology experiments and in vivo tadpole behavioral assays. Azo-NZ1 is composed of a nitrazepam moiety merged to an azobenzene photoisomerizable group, yet it has an inhibitory effect on GABAA receptors under visible light and also inhibits benzodiazepine-insensitive GABAC (rho2) receptors. Molecular modeling, combined with electrophysiology and mutagenesis experiments, shows that addition of the sulfonyl azobenzene unexpectedly converts the ligand into a pore blocker. Glyght is also an azobenzene-containing benzodiazepine, yet it acts selectively on glycine receptors as a negative modulator and its inhibitory action increases under UV light. Molecular modeling suggests that Glyght binds to a novel allosteric site located at the interface between the extracellular and transmembrane domains. The two aforementioned photoswitches pave the way towards photomanipulation of inhibitory (gabaergic and glycinergic) neurotransmission, with potential applications in understanding inhibitory circuits in intact animals and in development of drug-based phototherapies.

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