Self-assembled ruthenium and osmium nanosystems display a potent anticancer profile by interfering with metabolic activity

Mickaël Marloye; Haider Inam; Connor J. Moore; Tyler R. Mertens; Aude Ingels; Marilin Koch; Michal O. Nowicki; Véronique Mathieu; Justin R. Pritchard; Samuel G. Awuah; Sean E. Lawler; Franck Meyer; François Dufrasne; Gilles Berger

doi:10.1039/d2qi00423b

Self-assembled ruthenium and osmium nanosystems display a potent anticancer profile by interfering with metabolic activity

Mickaël Marloye, Haider Inam, Connor J. Moore, Tyler R. Mertens, Aude Ingels, Marilin Koch, Michal O. Nowicki, Véronique Mathieu, Justin R. Pritchard, Samuel G. Awuah, Sean E. Lawler, Franck Meyer, François Dufrasne, Gilles Berger

Research output: Contribution to journal › Article › peer-review

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Abstract

We disclose novel amphiphilic ruthenium and osmium complexes that auto-assemble into nanomedicines with potent antiproliferative activity by inhibition of mitochondrial respiration. The self-assembling units were rationally designed from the [M(p-cymene)(1,10-phenanthroline)Cl]PF₆ motif (where M is either Ru^II or Os^II) with an appended C₁₆ fatty chain to achieve high cellular activity, nano-assembling and mitochondrial targeting. These amphiphilic complexes block cell proliferation at the sub-micromolar range and are particularly potent towards glioblastoma neurospheres made from patient-derived cancer stem cells. A subcutaneous mouse model using these glioblastoma stem cells highlights one of our C₁₆ Os^II nanomedicines as highly successful in vivo. Mechanistically, we show that they act as metabolic poisons, strongly impairing mitochondrial respiration, corroborated by morphological changes and damage to the mitochondria. A genetic strategy based on RNAi gave further insight on the potential involvement of microtubules as part of the induced cell death. In parallel, we examined the structural properties of these new amphiphilic metal-based constructs, their reactivity and mechanism.

Original language	English (US)
Journal	Inorganic Chemistry Frontiers
DOIs	https://doi.org/10.1039/d2qi00423b
State	Accepted/In press - 2022

All Science Journal Classification (ASJC) codes

Inorganic Chemistry

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10.1039/d2qi00423b

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Marloye, M., Inam, H., Moore, C. J., Mertens, T. R., Ingels, A., Koch, M., Nowicki, M. O., Mathieu, V., Pritchard, J. R., Awuah, S. G., Lawler, S. E., Meyer, F., Dufrasne, F., & Berger, G. (Accepted/In press). Self-assembled ruthenium and osmium nanosystems display a potent anticancer profile by interfering with metabolic activity. Inorganic Chemistry Frontiers. https://doi.org/10.1039/d2qi00423b

@article{a2ea182ff68c425bbbae343aa4600346,

title = "Self-assembled ruthenium and osmium nanosystems display a potent anticancer profile by interfering with metabolic activity",

abstract = "We disclose novel amphiphilic ruthenium and osmium complexes that auto-assemble into nanomedicines with potent antiproliferative activity by inhibition of mitochondrial respiration. The self-assembling units were rationally designed from the [M(p-cymene)(1,10-phenanthroline)Cl]PF6 motif (where M is either RuII or OsII) with an appended C16 fatty chain to achieve high cellular activity, nano-assembling and mitochondrial targeting. These amphiphilic complexes block cell proliferation at the sub-micromolar range and are particularly potent towards glioblastoma neurospheres made from patient-derived cancer stem cells. A subcutaneous mouse model using these glioblastoma stem cells highlights one of our C16 OsII nanomedicines as highly successful in vivo. Mechanistically, we show that they act as metabolic poisons, strongly impairing mitochondrial respiration, corroborated by morphological changes and damage to the mitochondria. A genetic strategy based on RNAi gave further insight on the potential involvement of microtubules as part of the induced cell death. In parallel, we examined the structural properties of these new amphiphilic metal-based constructs, their reactivity and mechanism.",

author = "Micka{\"e}l Marloye and Haider Inam and Moore, {Connor J.} and Mertens, {Tyler R.} and Aude Ingels and Marilin Koch and Nowicki, {Michal O.} and V{\'e}ronique Mathieu and Pritchard, {Justin R.} and Awuah, {Samuel G.} and Lawler, {Sean E.} and Franck Meyer and Fran{\c c}ois Dufrasne and Gilles Berger",

note = "Funding Information: M. M. thanks V{\'e}ronique Megalizzi and Michel Gelbcke for helpful discussions and guidance on the analysis of video microscopy experiments, the team of the Analytical Platform of the Faculty of Pharmacy (ULB) for the record of MS spectra and the team of G-time laboratory (ULB) for the ICP-MS experiments. We would also like to thank Dr Tomoko Sengoku and Mr Michael Alstott for the support with our redox metabolism experiments, supported by the shared resource(s) of the University of Kentucky Markey Cancer Center (P30CA177558). This research was partially funded by NCI R50 CA243706-02 for MON, NCI R01 CA258421-01 for SGA, by the F{\'e}d{\'e}ration Wallonie-Bruxelles (EG/MA/JCD/CBV 19-24) for M. M. and by the Belgian Brain Tumor Support (BBTS) for V. M.; G. B. was the recipient of an FRS-FNRS award. Publisher Copyright: {\textcopyright} 2022 The Royal Society of Chemistry",

year = "2022",

doi = "10.1039/d2qi00423b",

language = "English (US)",

journal = "Inorganic Chemistry Frontiers",

issn = "2052-1545",

publisher = "Royal Society of Chemistry",

}

TY - JOUR

T1 - Self-assembled ruthenium and osmium nanosystems display a potent anticancer profile by interfering with metabolic activity

AU - Marloye, Mickaël

AU - Inam, Haider

AU - Moore, Connor J.

AU - Mertens, Tyler R.

AU - Ingels, Aude

AU - Koch, Marilin

AU - Nowicki, Michal O.

AU - Mathieu, Véronique

AU - Pritchard, Justin R.

AU - Awuah, Samuel G.

AU - Lawler, Sean E.

AU - Meyer, Franck

AU - Dufrasne, François

AU - Berger, Gilles

N1 - Funding Information: M. M. thanks Véronique Megalizzi and Michel Gelbcke for helpful discussions and guidance on the analysis of video microscopy experiments, the team of the Analytical Platform of the Faculty of Pharmacy (ULB) for the record of MS spectra and the team of G-time laboratory (ULB) for the ICP-MS experiments. We would also like to thank Dr Tomoko Sengoku and Mr Michael Alstott for the support with our redox metabolism experiments, supported by the shared resource(s) of the University of Kentucky Markey Cancer Center (P30CA177558). This research was partially funded by NCI R50 CA243706-02 for MON, NCI R01 CA258421-01 for SGA, by the Fédération Wallonie-Bruxelles (EG/MA/JCD/CBV 19-24) for M. M. and by the Belgian Brain Tumor Support (BBTS) for V. M.; G. B. was the recipient of an FRS-FNRS award. Publisher Copyright: © 2022 The Royal Society of Chemistry

PY - 2022

Y1 - 2022

N2 - We disclose novel amphiphilic ruthenium and osmium complexes that auto-assemble into nanomedicines with potent antiproliferative activity by inhibition of mitochondrial respiration. The self-assembling units were rationally designed from the [M(p-cymene)(1,10-phenanthroline)Cl]PF6 motif (where M is either RuII or OsII) with an appended C16 fatty chain to achieve high cellular activity, nano-assembling and mitochondrial targeting. These amphiphilic complexes block cell proliferation at the sub-micromolar range and are particularly potent towards glioblastoma neurospheres made from patient-derived cancer stem cells. A subcutaneous mouse model using these glioblastoma stem cells highlights one of our C16 OsII nanomedicines as highly successful in vivo. Mechanistically, we show that they act as metabolic poisons, strongly impairing mitochondrial respiration, corroborated by morphological changes and damage to the mitochondria. A genetic strategy based on RNAi gave further insight on the potential involvement of microtubules as part of the induced cell death. In parallel, we examined the structural properties of these new amphiphilic metal-based constructs, their reactivity and mechanism.

AB - We disclose novel amphiphilic ruthenium and osmium complexes that auto-assemble into nanomedicines with potent antiproliferative activity by inhibition of mitochondrial respiration. The self-assembling units were rationally designed from the [M(p-cymene)(1,10-phenanthroline)Cl]PF6 motif (where M is either RuII or OsII) with an appended C16 fatty chain to achieve high cellular activity, nano-assembling and mitochondrial targeting. These amphiphilic complexes block cell proliferation at the sub-micromolar range and are particularly potent towards glioblastoma neurospheres made from patient-derived cancer stem cells. A subcutaneous mouse model using these glioblastoma stem cells highlights one of our C16 OsII nanomedicines as highly successful in vivo. Mechanistically, we show that they act as metabolic poisons, strongly impairing mitochondrial respiration, corroborated by morphological changes and damage to the mitochondria. A genetic strategy based on RNAi gave further insight on the potential involvement of microtubules as part of the induced cell death. In parallel, we examined the structural properties of these new amphiphilic metal-based constructs, their reactivity and mechanism.

UR - http://www.scopus.com/inward/record.url?scp=85129588356&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85129588356&partnerID=8YFLogxK

U2 - 10.1039/d2qi00423b

DO - 10.1039/d2qi00423b

M3 - Article

C2 - 36311556

AN - SCOPUS:85129588356

SN - 2052-1545

JO - Inorganic Chemistry Frontiers

JF - Inorganic Chemistry Frontiers

ER -

Self-assembled ruthenium and osmium nanosystems display a potent anticancer profile by interfering with metabolic activity

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