Mitotic slippage causes nuclear instability in polyploid cells

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The study compared different routes to whole-genome duplication (including mitotic slippage, cytokinesis failure, and endoreplication) under physiological and non-physiological conditions to determine whether polyploidization pathway affects resulting polyploid cell behavior. The key finding was that only mitotic slippage produced widespread nuclear abnormalities, termed nuclear instability, characterized by highly variable nuclear deformations. Mechanistically, the authors linked this instability to softer nuclei driven by high histone H3 phosphorylation in G1 that alters chromatin compaction and increases vulnerability to microtubule-driven deformation, leading to local nuclear reorganization, altered 3D genome organization, and changes in gene expression. A limitation noted by the paper is that it frames effects around the polyploid cells generated by these specific cell-cycle routes rather than a comprehensive survey across all polyploid contexts. This paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

Whole-genome duplication (WGD), leading to polyploidy can arise in physiological and pathological contexts 1–5 . WGD can occur via non-canonical cell cycles such as mitotic slippage, cytokinesis failure or endoreplication 1,3 . Whether the routes to WGD influence the behaviour of the resulting polyploid cells remains unclear. Here, we compared these routes under both physiological and non-physiological conditions. Remarkably, only mitotic slippage led to widespread nuclear abnormalities defined by highly variable nuclear deformations that we termed nuclear instability. Mechanistically, we found that these nuclei were softer - due to high levels of histone 3 phosphorylation in G1 altering chromatin compaction - and thus more vulnerable to microtubule-driven deformations. The resulting nuclear instability leads to local nuclear reorganisation and changes in 3D genome organisation impacting ultimately gene expression. Importantly, we observed similar nuclear instability in megakaryocytes, which are physiological polyploid cells that we show here to be generated by mitotic slippage, providing a molecular mechanism for their atypical nuclear architecture 6,7 . In striking contrast, nuclear shape was stable in different physiological polyploid cells generated by cytokinesis failure and endoreplication. Overall, our findings highlight that the route towards WGD matters and that mitotic slippage uniquely destabilizes nuclear architecture, with implications for both physiology and disease.
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Abstract Whole-genome duplication (WGD), leading to polyploidy can arise in physiological and pathological contexts1–5. WGD can occur via non-canonical cell cycles such as mitotic slippage, cytokinesis failure or endoreplication1,3. Whether the routes to WGD influence the behaviour of the resulting polyploid cells remains unclear. Here, we compared these routes under both physiological and non-physiological conditions. Remarkably, only mitotic slippage led to widespread nuclear abnormalities defined by highly variable nuclear deformations that we termed nuclear instability. Mechanistically, we found that these nuclei were softer - due to high levels of histone 3 phosphorylation in G1 altering chromatin compaction - and thus more vulnerable to microtubule-driven deformations. The resulting nuclear instability leads to local nuclear reorganisation and changes in 3D genome organisation impacting ultimately gene expression. Importantly, we observed similar nuclear instability in megakaryocytes, which are physiological polyploid cells that we show here to be generated by mitotic slippage, providing a molecular mechanism for their atypical nuclear architecture6,7. In striking contrast, nuclear shape was stable in different physiological polyploid cells generated by cytokinesis failure and endoreplication. Overall, our findings highlight that the route towards WGD matters and that mitotic slippage uniquely destabilizes nuclear architecture, with implications for both physiology and disease. Competing Interest Statement The authors have declared no competing interest. Footnotes This version of the manuscript has been revised to update our model based on new data we got.

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