Impact of cell cycle on repair of ruptured nuclear envelope and sensitivity to nuclear envelope stress in glioblastoma

Kamikawa, Yasunao; Wu, Zhiliang; Nakazawa, Naozo; Ito, Taichi; Saito, Atsushi; Imaizumi, Kazunori

doi:10.1038/s41420-023-01534-7

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2024

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Cited by 4 publications

References 41 publications

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Intricate Synergy of Mechanical and Biochemical Cues in the Transmigration of Cancer Cells Across the Endothelium

Mierke

2024

Interdisciplinary Cancer Research

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Intricate Synergy of Mechanical and Biochemical Cues in the Transmigration of Cancer Cells Across the Endothelium

Mierke

2024

Interdisciplinary Cancer Research

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VPS4B orchestrates response to nuclear envelope stress by regulating ESCRT-III dynamics in glioblastoma

Wu,

Omura,

Saito

et al. 2024

Nucleus

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The Nuclear envelope (NE) is frequently challenged by mechanical stimuli involving cells passing through a tight space and such stress is known as “NE stress.” Various factors that cooperate to repair the NE have been identified, including endosomal sorting complex required for transport-III (ESCRT-III). Recently, vacuolar protein sorting 4 homolog B (VPS4B) has been reported to modulate the recycling of ESCRT-III during NE repair, but the regulatory mechanism remains unclear. Our previous study revealed that U251MG cells, derived from the glioblastoma (GBM), exhibited nuclear deformation followed by DNA damage upon mechanical NE stress while these phenotypes were not observed in U87MG, another GBM-derived cell line. Here, we found that VPS4B expression was lower in U251MG than in U87MG. Our functional analysis demonstrated that insufficient VPS4B triggers an inadequate response to NE stress and that VPS4B regulates the dynamics of ESCRT-III, uncovering the mechanism underlying the NE stress response in GBM.

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Probing nanomechanics by direct indentation using Nanoendoscopy-AFM reveals the nuclear elasticity transition in cancer cells

Ichikawa,

Kono,

Kudo

et al. 2024

Preprint

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During cancer invasion and metastasis, the mechanical properties of the nucleus change significantly, with reduced elasticity enhancing nuclear deformability to aid cell migration through tight spaces. Traditional methods of measuring nuclear elasticity, such as using bead-attached cantilevers on cells or isolated nuclei, are limited because they also measure the elasticity of surrounding structures like cell membranes and cytoskeletons. In this study, we used a Nanoendoscopy-atomic force microscope (AFM) with a nanoneedle probe to directly measure nuclear elasticity in living cells. Our findings show that nuclear elasticity increases with serum depletion but decreases when serum-starved cells are treated with TGF-beta, which induces epithelial-mesenchymal transition (EMT). While levels of nuclear lamins remained stable, epigenetic changes indicated that chromatin compaction is linked to shifts in nuclear elasticity. We propose that changes in nuclear elasticity during cancer progression are associated with alterations in chromatin structure

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Impact of cell cycle on repair of ruptured nuclear envelope and sensitivity to nuclear envelope stress in glioblastoma

Cited by 4 publications

References 41 publications

Intricate Synergy of Mechanical and Biochemical Cues in the Transmigration of Cancer Cells Across the Endothelium

Intricate Synergy of Mechanical and Biochemical Cues in the Transmigration of Cancer Cells Across the Endothelium

VPS4B orchestrates response to nuclear envelope stress by regulating ESCRT-III dynamics in glioblastoma

Probing nanomechanics by direct indentation using Nanoendoscopy-AFM reveals the nuclear elasticity transition in cancer cells

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