Photoactivatable and photolabile pharmacophores: lessons learned from capsaicin†

IF 3.1 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

RSC Chemical Biology Pub Date : 2025-07-19 DOI:10.1039/D5CB00124B

Nils Imse, Lucia Rojas, Cristina Gil Herrero, Sebastian Thallmair, JeongSeop Rhee and Nadja A. Simeth

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Abstract

Light-controlled molecules have become valuable tools for studying biological systems offering an unparalleled control in space and time. Specifically, the remote-controllable (de)activation of small molecules is attractive both to study molecular processes from a fundamental point of view and to develop future precision therapeutics. While pronounced changes through light-induced cleavage of photolabile protecting groups and the accompanying liberation of bioactive small molecules have become a highly successful strategy, approaches that focus solely on the revert process, i.e. the photochemical deactivation of bioactive agents, are sparse. In this work, we studied whether a given bioactive compound could be made photolability by structural design. We thus used the example of capsaicinoids, which control the transient receptor potential cation channel subfamily V member 1 (TRPV1), to generate both suitable light activation and deactivation strategies.

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光激活和光稳定的药效团：辣椒素的经验教训。

光控分子已经成为研究生物系统的宝贵工具，提供了无与伦比的空间和时间控制。具体来说，小分子的远程控制（去激活）对于从基础角度研究分子过程和开发未来的精确治疗都具有吸引力。虽然通过光诱导的可光性保护基团的裂解和伴随的生物活性小分子的释放引起的明显变化已经成为一种非常成功的策略，但仅关注恢复过程（即生物活性物质的光化学失活）的方法很少。在这项工作中，我们研究了一个给定的生物活性化合物是否可以通过结构设计来制备光性。因此，我们以控制瞬时受体电位阳离子通道亚家族V成员1 （TRPV1）的辣椒素为例，产生了合适的光激活和失活策略。

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