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Chromosome mis-segregation triggers cell cycle arrest through a mechanosensitive nuclear envelope checkpoint

Solène Hervé, Andrea Scelfo, Gabriele Bersano Marchisio, Marine Grison, Kotryna Vaidžiulytė, Marie Dumont, Annapaola Angrisani, Adib Keikhosravi, Gianluca Pegoraro, Mathieu Deygas, G. Nader, Anne‐Sophie Macé, Matteo Gentili, Alice Williart, Nicolas Manel, Matthieu Piel, Yekaterina A. Miroshnikova, Daniele Fachinetti

2025Nature Cell Biology38 citationsDOIOpen Access PDF

Abstract

Errors during cell division lead to aneuploidy, which is associated with genomic instability and cell transformation. In response to aneuploidy, cells activate the tumour suppressor p53 to elicit a surveillance mechanism that halts proliferation and promotes senescence. The molecular sensors that trigger this checkpoint are unclear. Here, using a tunable system of chromosome mis-segregation, we show that mitotic errors trigger nuclear deformation, nuclear softening, and lamin and heterochromatin alterations, leading to rapid p53/p21 activation upon mitotic exit in response to changes in nuclear mechanics. We identify mTORC2 and ATR as nuclear deformation sensors upstream of p53/p21 activation. While triggering mitotic arrest, the chromosome mis-segregation-induced alterations of nuclear envelope mechanics provide a fitness advantage for aneuploid cells by promoting nuclear deformation resilience and enhancing pro-invasive capabilities. Collectively, this work identifies a nuclear mechanical checkpoint triggered by altered chromatin organization that probably plays a critical role in cellular transformation and cancer progression. Hervé, Scelfo et al. show that chromosome mis-segregation induces mTORC2- and ATR-mediated p53 activation through a mechanosensitive checkpoint at the nuclear envelope triggered by altered heterochromatin content and increased nuclear membrane tension.

Topics & Concepts

LaminCell biologyMitosisBiologyCell cycle checkpointSpindle checkpointNuclear laminaMitotic catastropheG2-M DNA damage checkpointChromatinMechanosensitive channelsCell divisionCell cycleGeneticsCellNuclear proteinSpindle apparatusDNAReceptorGeneNucleusTranscription factorIon channelNuclear Structure and FunctionRNA Research and SplicingGenomics and Chromatin Dynamics
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