Issue 29, 2024

Strategic design and development of a siderophore mimic: pioneering anticancer therapy via ROS generation and ferroptosis

Abstract

We designed a tris-catecholate-based siderophore mimic, H6-T-CATL, to selectively chelate iron(III) from mitochondrial cytochromes and other iron-containing proteins within cellular matrices. This strategic sequestration aims to trigger apoptosis or ferroptosis in cancer cells through the glutathione (GSH)-dependent release of reduced iron and subsequent ROS-mediated cytotoxicity. Synthesis of H6-T-CATL involved precise peptide coupling reactions. Using the Fe(III)-porphyrin model (Fe-TPP-Cl), akin to cytochrome c, we studied H6-T-CATL's ability to extract iron(III), yielding a binding constant (Krel) of 1014 for the resulting iron(III) complex (FeIII-T-CATL)3−. This complex readily underwent GSH-mediated reduction to release bioavailable iron(II), which catalyzed Fenton-like reactions generating hydroxyl radicals (˙OH), confirmed by spectroscopic analyses. Our research underscores the potential of H6-T-CATL to induce cancer cell death by depleting iron(III) from cellular metalloproteins, releasing pro-apoptotic iron(II). Evaluation across various cancer types, including normal cells, demonstrated H6-T-CATL's cytotoxicity through ROS production, mitochondrial dysfunction, and activation of ferroptosis and DNA damage pathways. These findings propose a novel mechanism for cancer therapy, leveraging endogenous iron stores within cells. H6-T-CATL emerges as a promising next-generation anticancer agent, exploiting iron metabolism vulnerabilities to induce selective cancer cell death through ferroptosis induction.

Graphical abstract: Strategic design and development of a siderophore mimic: pioneering anticancer therapy via ROS generation and ferroptosis

Supplementary files

Article information

Article type
Paper
Submitted
18 May 2024
Accepted
29 Jun 2024
First published
03 Jul 2024

Dalton Trans., 2024,53, 12119-12127

Strategic design and development of a siderophore mimic: pioneering anticancer therapy via ROS generation and ferroptosis

A. Panwar, A. Lye, D. Musib, A. Upadhyay, I. Karankumar, P. B. Devi, M. Pal, B. Maity and M. Roy, Dalton Trans., 2024, 53, 12119 DOI: 10.1039/D4DT01461H

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