Generation of thiyl radicals in a spatiotemporal controlled manner by light: Applied for the cis to trans isomerization of unsaturated fatty acids/phospholipids

Thiyl radicals are important reactive sulfur species and can cause cis to trans isomerization on unsaturated fatty acids. However, biocompatible strategies for the controlled generation of thiyl radicals are still lacking. In this work, we report the study of a series of naphthacyl-derived thioether...

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Published in:Redox biology 2025-02, Vol.79, p.103475, Article 103475
Main Authors: Roy, Biswajit, Kojima, Ryota, Shah, Obaed, Shieh, Meg, Das, Eshani, Ezzatpour, Shahrzad, Sato, Emiko, Hirata, Yusuke, Lindahl, Stephen, Matsuzawa, Atsushi, Aguilar, Hector C., Xian, Ming
Format: Article
Language:English
Subjects:
Cis to trans isomerization
Photoreaction
Research Paper
Thioether
Thiyl radicals
Unsaturated fatty acid
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Summary:Thiyl radicals are important reactive sulfur species and can cause cis to trans isomerization on unsaturated fatty acids. However, biocompatible strategies for the controlled generation of thiyl radicals are still lacking. In this work, we report the study of a series of naphthacyl-derived thioethers as photo-triggered thiyl radical precursors. Tertiary naphthacyl thioether was identified to be a suitable template that could be used to produce both aryl and alkyl thiyl radicals under ultraviolet (UV) light or sunlight. The effective cis-to trans-isomerization of unsaturated fatty acid models (methyl oleate, methyl linoleate) and a natural phospholipid (cardiolipin) using these photo-triggered substrates was demonstrated. This reaction was also proved to proceed effectively in cells to produce thiyl radicals and subsequent fatty acid isomerization. Additionally, the most promising thiyl radical precursor showed antiviral activity in a pseudotyped virus model, likely due to disrupting viral lipid membranes upon UV activation. These findings highlight the potential of thiyl radicals for both biochemical and antiviral applications.
ISSN:2213-2317
2213-2317
DOI:10.1016/j.redox.2024.103475