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A phase oscillator model of cell cycles reveals nuclear density control in a branched fungal network.

Created on 10 Jul 2026

Authors

Grace A McLaughlin, Benjamin M Stormo, Ameya P Jalihal, Taylor L Pompan, Madhav Mani, Timothy C Elston, Amy S Gladfelter

Published in

Proceedings of the National Academy of Sciences of the United States of America. Volume 123. Issue 28. Pages e2534542123. Jul 14, 2026. Epub Jul 09, 2026.

Abstract

Maintaining an appropriate nuclear-to-cytoplasmic ratio is essential across cell types for physiological function, and mechanisms of size control have been extensively studied in mononucleate cells. Much less is known about how comparable control is achieved in cells where many nuclei share a common cytoplasm, which are seen in many contexts including muscle, placenta, and filamentous fungi. The filamentous fungus Ashbya gossypii forms a branching mycelial network in which individual nuclei divide asynchronously, while the number of nuclei per cell volume (the nuclear density) is tightly controlled. How global regulation of nuclear density coexists with local cell cycle asynchrony remains unclear. To address this we model nuclei as a dividing population of phase oscillators within a branching cell network and parameterize the model with measurements from Ashbya cells. The model demonstrates that asynchrony is required to prevent large density fluctuations that would result from synchronous division, and that introducing a nuclear density checkpoint to the cell cycles leads to synchrony if it is the only mechanism of density control. We find that coupling branch formation to nuclear density both stabilizes nuclear density and prevents the emergence of synchronous cycles. Supporting these predictions, we demonstrate that mutants with branching defects and increased cell cycle synchrony display greater variability in nuclear density. Our results indicate that asynchronous nuclear cycles together with density-responsive branching maintain a constant nuclear density, revealing a strategy for regulating the nuclear-to-cytoplasmic ratio in large multinucleate cells.

PMID:
42424419
Bibliographic data and abstract were imported from PubMed on 10 Jul 2026.

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