Exploiting metabolic vulnerability in glioblastoma using a brain-penetrant drug with a safe profile

Audrey Burban; Cloe Tessier; Mathieu Larroquette; Joris Guyon; Cloe Lubiato; Mathis Pinglaut; Maxime Toujas; Johanna Galvis; Benjamin Dartigues; Emmanuelle Georget; H. Artee Luchman; Samuel Weiss; David Cappellen; Nathalie Nicot; Barbara Klink; Macha Nikolski; Lucie Brisson; Thomas Mathivet; Andreas Bikfalvi; Thomas Daubon; Ahmad Sharanek

doi:10.1038/s44321-025-00195-6

Exploiting metabolic vulnerability in glioblastoma using a brain-penetrant drug with a safe profile

Audrey Burban, Cloe Tessier, Mathieu Larroquette, Joris Guyon, Cloe Lubiato, Mathis Pinglaut, Maxime Toujas, Johanna Galvis, Benjamin Dartigues, Emmanuelle Georget, H. Artee Luchman, Samuel Weiss, David Cappellen, Nathalie Nicot, Barbara Klink, Macha Nikolski, Lucie Brisson, Thomas Mathivet, Andreas Bikfalvi^*, Thomas Daubon^*Ahmad Sharanek^*

^*Corresponding author for this work

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Abstract

Glioblastoma is one of the most treatment-resistant and lethal cancers, with a subset of self-renewing brain tumour stem cells (BTSCs), driving therapy resistance and relapse. Here, we report that mubritinib effectively impairs BTSC stemness and growth. Mechanistically, bioenergetic assays and rescue experiments showed that mubritinib targets complex I of the electron transport chain, thereby impairing BTSC self-renewal and proliferation. Gene expression profiling and Western blot analysis revealed that mubritinib disrupts the AMPK/p27^Kip1 pathway, leading to cell-cycle impairment. By employing in vivo pharmacokinetic assays, we established that mubritinib crosses the blood-brain barrier. Using preclinical patient-derived and syngeneic models, we demonstrated that mubritinib delays glioblastoma progression and extends animal survival. Moreover, combining mubritinib with radiotherapy or chemotherapy offers survival advantage to animals. Notably, we showed that mubritinib alleviates hypoxia, thereby enhancing ROS generation, DNA damage, and apoptosis in tumours when combined with radiotherapy. Encouragingly, toxicological and behavioural studies revealed that mubritinib is well tolerated and spares normal cells. Our findings underscore the promising therapeutic potential of mubritinib, warranting its further exploration in clinic for glioblastoma therapy.

Original language	English
Article number	5051
Pages (from-to)	469-503
Number of pages	35
Journal	EMBO Molecular Medicine
Volume	17
Issue number	3
Early online date	3 Feb 2025
DOIs	https://doi.org/10.1038/s44321-025-00195-6
Publication status	Published - Mar 2025

Keywords

Hypoxia
Metabolic Reliance
Oxidative Phosphorylation
Radiotherapy
Reactive Oxygen Species

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Burban, A., Tessier, C., Larroquette, M., Guyon, J., Lubiato, C., Pinglaut, M., Toujas, M., Galvis, J., Dartigues, B., Georget, E., Luchman, H. A., Weiss, S., Cappellen, D., Nicot, N., Klink, B., Nikolski, M., Brisson, L., Mathivet, T., Bikfalvi, A., ... Sharanek, A. (2025). Exploiting metabolic vulnerability in glioblastoma using a brain-penetrant drug with a safe profile. EMBO Molecular Medicine, 17(3), 469-503. Article 5051. https://doi.org/10.1038/s44321-025-00195-6

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title = "Exploiting metabolic vulnerability in glioblastoma using a brain-penetrant drug with a safe profile",

abstract = "Glioblastoma is one of the most treatment-resistant and lethal cancers, with a subset of self-renewing brain tumour stem cells (BTSCs), driving therapy resistance and relapse. Here, we report that mubritinib effectively impairs BTSC stemness and growth. Mechanistically, bioenergetic assays and rescue experiments showed that mubritinib targets complex I of the electron transport chain, thereby impairing BTSC self-renewal and proliferation. Gene expression profiling and Western blot analysis revealed that mubritinib disrupts the AMPK/p27Kip1 pathway, leading to cell-cycle impairment. By employing in vivo pharmacokinetic assays, we established that mubritinib crosses the blood-brain barrier. Using preclinical patient-derived and syngeneic models, we demonstrated that mubritinib delays glioblastoma progression and extends animal survival. Moreover, combining mubritinib with radiotherapy or chemotherapy offers survival advantage to animals. Notably, we showed that mubritinib alleviates hypoxia, thereby enhancing ROS generation, DNA damage, and apoptosis in tumours when combined with radiotherapy. Encouragingly, toxicological and behavioural studies revealed that mubritinib is well tolerated and spares normal cells. Our findings underscore the promising therapeutic potential of mubritinib, warranting its further exploration in clinic for glioblastoma therapy.",

keywords = "Hypoxia, Metabolic Reliance, Oxidative Phosphorylation, Radiotherapy, Reactive Oxygen Species",

author = "Audrey Burban and Cloe Tessier and Mathieu Larroquette and Joris Guyon and Cloe Lubiato and Mathis Pinglaut and Maxime Toujas and Johanna Galvis and Benjamin Dartigues and Emmanuelle Georget and Luchman, {H. Artee} and Samuel Weiss and David Cappellen and Nathalie Nicot and Barbara Klink and Macha Nikolski and Lucie Brisson and Thomas Mathivet and Andreas Bikfalvi and Thomas Daubon and Ahmad Sharanek",

note = "Funding: This work was supported by grants from Fondation de France N° 00130891 toABu, and N° 00130896 to AS; Canc{\'e}rop{\^o}le GSO N° 2023-E5 to AS;Association pour la Recherche sur les Tumeurs C{\'e}r{\'e}brales N° 283008 to ABu;Institut National du Cancer PLBIO N° 227441 and N° 241284 to TD; and SIRICBRIO-Commucan and plan-cancer N°C24009GS to ABi. AS and ABu weresupported by a fellowship from the Fondation de France. AS is also a recipientof the Marie Sk{\l}odowska-Curie Actions fellowship. CT is a recipient of theNewMoon PhD fellowship (Bordeaux University) and Region Nouvelle-Aquitaine. ML was supported by a PhD fellowship from the Fondation ARC(grant MD-DOC). Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = mar,

doi = "10.1038/s44321-025-00195-6",

language = "English",

volume = "17",

pages = "469--503",

journal = "EMBO Molecular Medicine",

issn = "1757-4676",

publisher = "Springer Science and Business Media Deutschland GmbH",

number = "3",

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Burban, A, Tessier, C, Larroquette, M, Guyon, J, Lubiato, C, Pinglaut, M, Toujas, M, Galvis, J, Dartigues, B, Georget, E, Luchman, HA, Weiss, S, Cappellen, D, Nicot, N, Klink, B, Nikolski, M, Brisson, L, Mathivet, T, Bikfalvi, A, Daubon, T & Sharanek, A 2025, 'Exploiting metabolic vulnerability in glioblastoma using a brain-penetrant drug with a safe profile', EMBO Molecular Medicine, vol. 17, no. 3, 5051, pp. 469-503. https://doi.org/10.1038/s44321-025-00195-6

TY - JOUR

T1 - Exploiting metabolic vulnerability in glioblastoma using a brain-penetrant drug with a safe profile

AU - Burban, Audrey

AU - Tessier, Cloe

AU - Larroquette, Mathieu

AU - Guyon, Joris

AU - Lubiato, Cloe

AU - Pinglaut, Mathis

AU - Toujas, Maxime

AU - Galvis, Johanna

AU - Dartigues, Benjamin

AU - Georget, Emmanuelle

AU - Luchman, H. Artee

AU - Weiss, Samuel

AU - Cappellen, David

AU - Nicot, Nathalie

AU - Klink, Barbara

AU - Nikolski, Macha

AU - Brisson, Lucie

AU - Mathivet, Thomas

AU - Bikfalvi, Andreas

AU - Daubon, Thomas

AU - Sharanek, Ahmad

N1 - Funding: This work was supported by grants from Fondation de France N° 00130891 toABu, and N° 00130896 to AS; Cancéropôle GSO N° 2023-E5 to AS;Association pour la Recherche sur les Tumeurs Cérébrales N° 283008 to ABu;Institut National du Cancer PLBIO N° 227441 and N° 241284 to TD; and SIRICBRIO-Commucan and plan-cancer N°C24009GS to ABi. AS and ABu weresupported by a fellowship from the Fondation de France. AS is also a recipientof the Marie Skłodowska-Curie Actions fellowship. CT is a recipient of theNewMoon PhD fellowship (Bordeaux University) and Region Nouvelle-Aquitaine. ML was supported by a PhD fellowship from the Fondation ARC(grant MD-DOC). Publisher Copyright: © The Author(s) 2025.

PY - 2025/3

Y1 - 2025/3

N2 - Glioblastoma is one of the most treatment-resistant and lethal cancers, with a subset of self-renewing brain tumour stem cells (BTSCs), driving therapy resistance and relapse. Here, we report that mubritinib effectively impairs BTSC stemness and growth. Mechanistically, bioenergetic assays and rescue experiments showed that mubritinib targets complex I of the electron transport chain, thereby impairing BTSC self-renewal and proliferation. Gene expression profiling and Western blot analysis revealed that mubritinib disrupts the AMPK/p27Kip1 pathway, leading to cell-cycle impairment. By employing in vivo pharmacokinetic assays, we established that mubritinib crosses the blood-brain barrier. Using preclinical patient-derived and syngeneic models, we demonstrated that mubritinib delays glioblastoma progression and extends animal survival. Moreover, combining mubritinib with radiotherapy or chemotherapy offers survival advantage to animals. Notably, we showed that mubritinib alleviates hypoxia, thereby enhancing ROS generation, DNA damage, and apoptosis in tumours when combined with radiotherapy. Encouragingly, toxicological and behavioural studies revealed that mubritinib is well tolerated and spares normal cells. Our findings underscore the promising therapeutic potential of mubritinib, warranting its further exploration in clinic for glioblastoma therapy.

AB - Glioblastoma is one of the most treatment-resistant and lethal cancers, with a subset of self-renewing brain tumour stem cells (BTSCs), driving therapy resistance and relapse. Here, we report that mubritinib effectively impairs BTSC stemness and growth. Mechanistically, bioenergetic assays and rescue experiments showed that mubritinib targets complex I of the electron transport chain, thereby impairing BTSC self-renewal and proliferation. Gene expression profiling and Western blot analysis revealed that mubritinib disrupts the AMPK/p27Kip1 pathway, leading to cell-cycle impairment. By employing in vivo pharmacokinetic assays, we established that mubritinib crosses the blood-brain barrier. Using preclinical patient-derived and syngeneic models, we demonstrated that mubritinib delays glioblastoma progression and extends animal survival. Moreover, combining mubritinib with radiotherapy or chemotherapy offers survival advantage to animals. Notably, we showed that mubritinib alleviates hypoxia, thereby enhancing ROS generation, DNA damage, and apoptosis in tumours when combined with radiotherapy. Encouragingly, toxicological and behavioural studies revealed that mubritinib is well tolerated and spares normal cells. Our findings underscore the promising therapeutic potential of mubritinib, warranting its further exploration in clinic for glioblastoma therapy.

KW - Hypoxia

KW - Metabolic Reliance

KW - Oxidative Phosphorylation

KW - Radiotherapy

KW - Reactive Oxygen Species

UR - http://www.scopus.com/inward/record.url?scp=85217994083&partnerID=8YFLogxK

UR - https://pubmed.ncbi.nlm.nih.gov/39901019/

U2 - 10.1038/s44321-025-00195-6

DO - 10.1038/s44321-025-00195-6

M3 - Article

C2 - 39901019

AN - SCOPUS:85217994083

SN - 1757-4676

VL - 17

SP - 469

EP - 503

JO - EMBO Molecular Medicine

JF - EMBO Molecular Medicine

IS - 3

M1 - 5051

ER -

Exploiting metabolic vulnerability in glioblastoma using a brain-penetrant drug with a safe profile

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Keywords

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