Antoni Bautista-Barrufet scite author profile

Light-regulated drugs allow remotely photoswitching biological activity and enable plausible therapies based on small molecules. However, only freely diffusible photochromic ligands have been shown to work directly in endogenous receptors and methods for covalent attachment depend on genetic manipulation. Here we introduce a chemical strategy to covalently conjugate and photoswitch the activity of endogenous proteins and demonstrate its application to the kainate receptor channel GluK1. The approach is based on photoswitchable ligands containing a short-lived, highly reactive anchoring group that is targeted at the protein of interest by ligand affinity. These targeted covalent photoswitches (TCPs) constitute a new class of light-regulated drugs and act as prosthetic molecules that photocontrol the activity of GluK1-expressing neurons, and restore photoresponses in degenerated retina. The modularity of TCPs enables the application to different ligands and opens the way to new therapeutic opportunities.

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A photoswitchable GABA receptor channel blocker

Maleeva

Wutz

Rustler

et al. 2019

British J Pharmacology

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Background and Purpose Anion‐selective Cys‐loop receptors (GABA and glycine receptors) provide the main inhibitory drive in the CNS. Both types of receptor operate via chloride‐selective ion channels, though with different kinetics, pharmacological profiles, and localization. Disequilibrium in their function leads to a variety of disorders, which are often treated with allosteric modulators. The few available GABA and glycine receptor channel blockers effectively suppress inhibitory currents in neurons, but their systemic administration is highly toxic. With the aim of developing an efficient light‐controllable modulator of GABA receptors, we constructed azobenzene‐nitrazepam (Azo‐NZ1), which is composed of a nitrazepam moiety merged to an azobenzene photoisomerizable group. Experimental Approach The experiments were carried out on cultured cells expressing Cys‐loop receptors of known subunit composition and in brain slices using patch‐clamp. Site‐directed mutagenesis and molecular modelling approaches were applied to evaluate the mechanism of action of Azo‐NZ1. Key Results At visible light, being in trans‐configuration, Azo‐NZ1 blocked heteromeric α1/β2/γ2 GABAA receptors, ρ2 GABAA (GABAC), and α2 glycine receptors, whereas switching the compound into cis‐state by UV illumination restored the activity. Azo‐NZ1 successfully photomodulated GABAergic currents recorded from dentate gyrus neurons. We demonstrated that in trans‐configuration, Azo‐NZ1 blocks the Cl‐selective ion pore of GABA receptors interacting mainly with the 2′ level of the TM2 region. Conclusions and Implications Azo‐NZ1 is a soluble light‐driven Cl‐channel blocker, which allows photo‐modulation of the activity induced by anion‐selective Cys‐loop receptors. Azo‐NZ1 is able to control GABAergic postsynaptic currents and provides new opportunities to study inhibitory neurotransmission using patterned illumination.

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Optical Control of Enzyme Enantioselectivity in Solid Phase

et al. 2014

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A lipase was immobilized on transparent agarose microspheres and genetically engineered to specifically anchor photochromic molecules into its catalytic site. Several combinations of azobenzene and spiropyran groups were conjugated to cysteines introduced at different positions near the active center. Light modulated the catalytic properties of the resulting solid bioconjugates, and such modulation depended on both the nature of the photochromic compound and the anchoring position. Covalent anchoring of azobenzene derivatives to the residue 295 of the lipase 2 from Bacillus thermocathenolatus triggered lipase preference for the S isomer under UV light, whereas visible light promoted preference for the R isomer. Molecular dynamics simulations indicate that conjugating photochromic compounds into the catalytic cavity allows manipulating the steric hindrance and binding energy of the substrates, leading to an enantioselective molecular fit in certain cases. Using this approach, we report for the first time the control of enzyme properties using light in the solid phase.

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Photocontrol of Endogenous Glycine Receptors In Vivo

Gomila

Rustler

Maleeva

et al. 2020

Cell Chemical Biology

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Glycine receptors (GlyRs) are indispensable to maintain excitatory/inhibitory balance in neuronal circuits controlling reflex and rhythmic motor behaviors. Here we have developed Glyght, the first GlyR ligand controlled with light. It is selective over other cys-loop receptors, active in vivo, and displays an allosteric mechanism of action. The photomanipulation of glycinergic neurotransmission opens new avenues to understand inhibitory circuits in intact animals, and to develop drug-based phototherapies.

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