Photoactivatable Metabolic Warheads Enable Precise and Safe Ablation of Target Cells in Vivo

Overview

Journal Nat Commun

Specialty Biology

Date 2021 Apr 23

PMID 33888691

Citations 11

Authors

Sam Benson

Fabio de Moliner

Antonio Fernandez

Erkin Kuru

Nicholas L Asiimwe

Jun-Seok Lee

Lloyd Hamilton

Dirk Sieger

Isabel R Bravo

Abigail M Elliot

Yi Feng

Marc Vendrell

Affiliations

Soon will be listed here.

Abstract

Photoactivatable molecules enable ablation of malignant cells under the control of light, yet current agents can be ineffective at early stages of disease when target cells are similar to healthy surrounding tissues. In this work, we describe a chemical platform based on amino-substituted benzoselenadiazoles to build photoactivatable probes that mimic native metabolites as indicators of disease onset and progression. Through a series of synthetic derivatives, we have identified the key chemical groups in the benzoselenadiazole scaffold responsible for its photodynamic activity, and subsequently designed photosensitive metabolic warheads to target cells associated with various diseases, including bacterial infections and cancer. We demonstrate that versatile benzoselenadiazole metabolites can selectively kill pathogenic cells - but not healthy cells - with high precision after exposure to non-toxic visible light, reducing any potential side effects in vivo. This chemical platform provides powerful tools to exploit cellular metabolic signatures for safer therapeutic and surgical approaches.

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