Press Release

Publication
21.10.2019

Identification of a ferroptosis suppressor protein allows for new anticancer treatment approach

A team of researchers lead by Helmholtz Zentrum München and the University of Würzburg identified an enzyme as a novel and strong inhibitor of ferroptosis, the iron dependent form of cell death: ferroptosis suppressor protein-1, short FSP1. This protein is expressed in a variety of cancer cell lines and therefore represents an attractive drug target for cancer treatment. In fact, the first FSP1 inhibitor described in the researchers’ study published in Nature sensitizes tumor cells to ferroptosis, providing the rationale for the development of stratified combination therapies.

Image: Localization of FSP1 in green, cell nucleus in yellow, endoplasmic reticulum in magenta. @ Rudolf Virchow Centre for Experimental Biomedicine University Würzburg

Development of drug resistance to chemotherapy represents a major clinical problem for the treatment of a variety of tumor entities. Metabolic alternations, epithelial to mesenchymal transition and immune evasion are some of the processes involved, which have been recently linked to an acquired sensitivity towards ferroptosis. So called “persister” cancer cells withstand conventional therapies and lead to tumor relapse. Interestingly, some persister cells are known to develop a strong dependency on glutathione peroxidase 4 (GPX4), the established regulator of ferroptosis. So far, GPX4 has been considered the sole enzymatic system in mammalian cells that can efficiently reduce and thereby detoxify peroxides in phospholipid bilayers by using the tripeptide glutathione, the most abundant natural antioxidant in mammalian cells.

FSP1 is a strong anti-ferroptotic gene expressed in most cancer cells

In order to unravel novel ways of using ferroptosis for cancer treatment researchers investigated the mystery of why certain cancer cells are resistant to ferroptosis despite expressing ACSL4 – a strong predictive marker for ferroptosis sensitivity (Doll et al Nat Chem Biol 2017). The team of researchers including Dr. Sebastian Doll and Dr. Marcus Conrad, both from the Institute of Developmental Genetics at Helmholtz Zentrum München, as well as Dr. Florencio Porto Freitas and Dr. José Pedro Friedmann Angeli from the University of Würzburg (Rudolf Virchow Center) performed a robust genetic suppressor screen using a cDNA library from a ferroptosis resistant breast cancer cell line. This screen led to the identification of FSP1, previously erroneously annotated as AIFM2 (Apoptosis Inducing Factor Mitochondria Associated 2), as a strong anti-ferroptotic gene.

FSP1 fully complements the loss of GPX4, the hitherto only known enzyme efficiently preventing lipid peroxidation and associated ferroptosis. Determining the biochemical function of FSP1, the researchers found that inhibition of lipid peroxidation depends on the presence of ubiquinone (also known as coenzyme Q10).

“The mechanism by which FSP1 protects cells from ferroptosis is unique and novel. FSP1 keeps ubiquinone in its reduced state and by this, ubiquinone protects membranes from radical driven lipid peroxidation. Ultimately, we found that this mechanism prevents the execution signal of ferroptosis,” explains Dr. Friedmann Angeli.

“In a next step, we screened approx. 10,000 drug-like compounds in a phenotypic cell-based screen and target-based validation assay and identified iFSP1 as the first FSP1 inhibitor,” says Dr. Bettina Proneth from the team at Helmholtz Zentrum München.

Dr. Sebastian Doll first author of the study further states: “Since we found that FSP1 is expressed in most cancer cell lines, novel FSP1 inhibitors have the potential to be further developed as anticancer drugs.”

Significant impulse for future ferroptosis-based cancer therapies

With this study, the team of researchers described an until now unknown mechanism of how to protect cells from lipid peroxidation induced ferroptotic cell death. Moreover, they showed that this system can provide strong resistance towards known ferroptosis inducing drugs. They further provided an explanation for the long-sought riddle why cells have large amounts of extra-mitochondrial ubiquinone.

“This study has widespread implications. It asks for the development of novel and target-based ferroptosis inducers, suggests the development of FSP1 as a biomarker for future ferroptosis-based therapies and seeks the re-evaluation of ubiquinone as a powerful anti-ferroptotic agent,” concludes Dr. Marcus Conrad.

Cancer therapy is often highly effective in the initial phase of treatment, but in many cases the patients’ tumor stops responding. As certain therapy-resistant tumors and those undergoing dedifferentiation evolve into a ferroptosis-sensitive state, pro-ferroptotic treatment paradigms based on inhibition of FSP1, GPX4 or a combination thereof ask to be translated into clinical applications in the future.

Munich in the center of international research

This research was funded by Helmholtz Zentrum München’s Development Grant for FSP1 inhibitors (2018) and the Deutsche Forschungsgemeinschaft. The study initiated at Helmholtz Zentrum München and developed in close collaboration with Rudolf-Virchow-Zentrum at Würzburg University, counted with important contributions from Cardiff University, University of Ottawa, Imperial College London and the University of California, Berkeley.

Original Publication:
Doll et al., 2019: FSP1 is a glutathione-independent ferroptosis suppressor. Nature, DOI: 10.1038/s41586-019-1707-0

As German Research Center for Environmental Health, Helmholtz Zentrum München pursues the goal of developing personalized medical approaches for the prevention and therapy of major common diseases such as diabetes mellitus, allergies and lung diseases. To achieve this, it investigates the interaction of genetics, environmental factors and lifestyle. The Helmholtz Zentrum München has about 2,500 staff members and is headquartered in Neuherberg in the north of Munich. Helmholtz Zentrum München is a member of the Helmholtz Association, a community of 19 scientific-technical and medical-biological research centers with a total of about 37,000 staff members. 

Rising life expectancy is causing an increase in age-related, but also sociological and environmental, influences on the genes. The Institute of Developmental Genetics (IDG) examines these changes in genetic material. In the Mouse Genetics group, genetic animal models are developed to investigate various diseases. These models are analyzed in the Disease Modelling research group in order to identify gene functions and cell processes and evaluate the influence of the environment and aging processes. The group focuses on the examination of neurological and psychiatric diseases.

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