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  • Mechanically Distinct Microtubule Arrays Determine the Length and Force Response of the Meiotic Spindle.

Mechanically Distinct Microtubule Arrays Determine the Length and Force Response of the Meiotic Spindle.

Developmental cell (2019-04-16)
Jun Takagi, Ryota Sakamoto, Gen Shiratsuchi, Yusuke T Maeda, Yuta Shimamoto
ABSTRACT

The microtubule-based spindle is subjected to various mechanical forces during cell division. How the structure generates and responds to forces while maintaining overall integrity is unknown because we have a poor understanding of the relationship between filament architecture and mechanics. Here, to fill this gap, we combine microneedle-based quantitative micromanipulation with high-resolution imaging, simultaneously analyzing forces and local filament motility in the Xenopus meiotic spindle. We find that microtubules exhibit a compliant, fluid-like mechanical response at the middle of the spindle half, being distinct from those near the pole and the equator. A force altering spindle length induces filament sliding at this compliant array, where parallel microtubules predominate, without influencing equatorial antiparallel filament dynamics. Molecular perturbations suggest that kinesin-5 and dynein contribute to the spindle's local mechanical difference. Together, our data establish a link between spindle architecture and mechanics and uncover the mechanical design of this essential cytoskeletal assembly.