KHS101 disrupts energy metabolism in human glioblastoma cells and reduces tumor growth in mice

Euan S. Polson; Verena Kuchler; Christopher Abbosh; Edith Ross; Ryan Mathew; Hester A. Beard; Bárbara da Silva; Andrew N. Holding; Stéphane Ballereau; Eulashini Chuntharpursat‐Bon; Jennifer M. Williams; Hollie B. S. Griffiths; Hao Shao; Anjana Patel; Adam J. Davies; Alastair Droop; Paul Chumas; Susan Short; Mihaela Lorger; Jason E. Gestwicki; Lee D. Roberts; Robin S. Bon; Simon J. Allison; Shoutian Zhu; Florian Markowetz; Heiko Wurdak

doi:10.1126/scitranslmed.aar2718

KHS101 disrupts energy metabolism in human glioblastoma cells and reduces tumor growth in mice

Euan S. Polson(University of Leeds), Verena Kuchler(University of Leeds), Christopher Abbosh(University of Leeds), Edith Ross(University of Cambridge), Ryan Mathew(Leeds General Infirmary), Hester A. Beard(University of Leeds), Bárbara da Silva(University of Leeds), Andrew N. Holding(University of Cambridge), Stéphane Ballereau(University of Cambridge), Eulashini Chuntharpursat‐Bon(University of Leeds), Jennifer M. Williams(University of Leeds), Hollie B. S. Griffiths(University of Huddersfield), Hao Shao(Institute for Neurodegenerative Disorders), Anjana Patel(University of Leeds), Adam J. Davies(University of Leeds), Alastair Droop(University of Leeds), Paul Chumas(Leeds General Infirmary), Susan Short(University of Leeds), Mihaela Lorger(University of Leeds), Jason E. Gestwicki(Institute for Neurodegenerative Disorders), Lee D. Roberts(University of Leeds), Robin S. Bon(University of Leeds), Simon J. Allison(University of Huddersfield), Shoutian Zhu(California Institute for Biomedical Research), Florian Markowetz(University of Cambridge), Heiko Wurdak(University of Leeds)

Science Translational Medicine

August 15, 2018

10.1126/scitranslmed.aar2718

Cited by 78Open Access

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Abstract

Pharmacological inhibition of uncontrolled cell growth with small-molecule inhibitors is a potential strategy for treating glioblastoma multiforme (GBM), the most malignant primary brain cancer. We showed that the synthetic small-molecule KHS101 promoted tumor cell death in diverse GBM cell models, independent of their tumor subtype, and without affecting the viability of noncancerous brain cell lines. KHS101 exerted cytotoxic effects by disrupting the mitochondrial chaperone heat shock protein family D member 1 (HSPD1). In GBM cells, KHS101 promoted aggregation of proteins regulating mitochondrial integrity and energy metabolism. Mitochondrial bioenergetic capacity and glycolytic activity were selectively impaired in KHS101-treated GBM cells. In two intracranial patient-derived xenograft tumor models in mice, systemic administration of KHS101 reduced tumor growth and increased survival without discernible side effects. These findings suggest that targeting of HSPD1-dependent metabolic pathways might be an effective strategy for treating GBM.

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