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  • A Gradient in Metaphase Tension Leads to a Scaled Cellular Response in Mitosis.

A Gradient in Metaphase Tension Leads to a Scaled Cellular Response in Mitosis.

Developmental cell (2019-02-26)
Soumya Mukherjee, Brian J Sandri, Damien Tank, Mark McClellan, Lauren A Harasymiw, Qing Yang, Laurie L Parker, Melissa K Gardner
ABSTRACT

During mitosis, motor proteins associate with microtubules to exert pushing forces that establish a mitotic spindle. These pushing forces generate opposing tension in the chromatin that connects oppositely attached sister chromatids, which may then act as a mechanical signal to ensure the fidelity of chromosome segregation during mitosis. However, the role of tension in mitotic cellular signaling remains controversial. In this study, we generated a gradient in tension over multiple isogenic budding yeast cell lines by genetically altering the magnitude of motor-based spindle forces. We found that a decreasing gradient in tension led to an increasing gradient in the rates of kinetochore detachment and anaphase chromosome mis-segregration, and in metaphase time. Simulations and experiments indicated that these tension responses originate from a tension-dependent kinetochore phosphorylation gradient. We conclude that the cell is exquisitely tuned to the magnitude of tension as a signal to detect potential chromosome segregation errors during mitosis.