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Glioblastoma stem cells resist cuproptosis with circadian variation of copper levels
Fanen Yuan, Xujia Wu, Huairui Yuan, Donghai Wang, Tengfei Huang, Po Zhang, Hailong Mi, Weichi Wu, Suchet Taori, Priscilla Chan, Kenji Miki, Maged T. Ghoche, Linjie Zhao, Kalil G. Abdullah, Steve A. Kay, Qiulian Wu, Jeremy N. Rich
Fanen Yuan, Xujia Wu, Huairui Yuan, Donghai Wang, Tengfei Huang, Po Zhang, Hailong Mi, Weichi Wu, Suchet Taori, Priscilla Chan, Kenji Miki, Maged T. Ghoche, Linjie Zhao, Kalil G. Abdullah, Steve A. Kay, Qiulian Wu, Jeremy N. Rich
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Research Article Cell biology Neuroscience Oncology

Glioblastoma stem cells resist cuproptosis with circadian variation of copper levels

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Abstract

Cuproptosis involves accumulation of intracellular copper that triggers mitochondrial lipoylated protein aggregation and destabilization of iron–sulfur cluster proteins, leading to cell death. Pharmacologic induction of cuproptosis has been proposed as a cancer therapy. Here, we find that glioblastoma (GBM) stem cells (GSCs) displayed relative resistance to cuproptosis with circadian variation of intracellular copper levels. CRISPR screening of copper regulators under concurrent treatment with copper ionophore or clock disruption revealed dependency on ATPase copper transporting alpha (ATP7A). Circadian control of copper homeostasis was mediated by the core clock transcription factor, brain and muscle ARNT-like 1 (BMAL1). In turn, ATP7A promoted tumor cell growth through regulation of fatty acid desaturation. Copper levels negatively fed back into the circadian circuitry through sequestosome 1/p62–mediated lysosomal degradation of BMAL1. Targeting the circadian clock or fatty acid desaturation augmented cuproptosis antitumor effects. Crosstalk between the core circadian clock and copper sustains GSCs, reshaping fatty acid metabolism and promoting drug resistance, which may inform development of combination therapies for GBM.

Authors

Fanen Yuan, Xujia Wu, Huairui Yuan, Donghai Wang, Tengfei Huang, Po Zhang, Hailong Mi, Weichi Wu, Suchet Taori, Priscilla Chan, Kenji Miki, Maged T. Ghoche, Linjie Zhao, Kalil G. Abdullah, Steve A. Kay, Qiulian Wu, Jeremy N. Rich

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Figure 4

The core clock regulates ATP7A and copper levels.

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The core clock regulates ATP7A and copper levels.
(A and B) qPCR analysi...
(A and B) qPCR analysis of ATP7A, BMAL1, and CLOCK expression at 6-hour intervals in synchronized GSC387 and DGC387 cells. sh, shRNA. (C and D) qPCR and Western blot of ATP7A expression in GSC387 and GSC3565 after BMAL1 knockdown (shBMAL1.689, shBMAL1.1536). (E and F) Western blot of ATP7A in GSCs treated with SHP656 or at 12-hour intervals following BMAL1 knockdown. (G) ICP-MS analysis of copper, iron, and zinc in GSC387 and GSC3565 after BMAL1 knockdown. (H) Live-cell copper imaging of synchronized GSC3565-shCONT and GSC3565-shBMAL1 cells at 12-hour intervals (100 nM dexamethasone). Relative fluorescence intensity was quantified. Scale bar: 20 μm. In A, B, and H, rhythmicity was analyzed using the JTK_CYCLE algorithm (P < 0.05 considered significant). One-way ANOVA with multiple comparisons was used for C and G. **P < 0.01, ***P < 0.001, ****P < 0.0001.

Copyright © 2026 American Society for Clinical Investigation
ISSN: 0021-9738 (print), 1558-8238 (online)

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