TY - JOUR
T1 - Mechanically Distinct Microtubule Arrays Determine the Length and Force Response of the Meiotic Spindle
AU - Takagi, Jun
AU - Sakamoto, Ryota
AU - Shiratsuchi, Gen
AU - Maeda, Yusuke T.
AU - Shimamoto, Yuta
N1 - Funding Information:
We thank Dr. Akatsuki Kimura and Dr. Shin’ichi Ishiwata for critical reading of the manuscript and Dr. Tarun Kapoor for providing CC1 reagents. This work was supported by JSPS KAKENHI 16H06166 , 17K19362 , TAKEDA Science Foundation (to Y.S.), Science Research on Innovative Areas “Molecular Engines” 18H05427 (to Y.T.M.), and JSPS Postdoctoral Fellowship (to J.T.).
Publisher Copyright:
© 2019 Elsevier Inc.
PY - 2019/4/22
Y1 - 2019/4/22
N2 - 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.
AB - 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.
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U2 - 10.1016/j.devcel.2019.03.014
DO - 10.1016/j.devcel.2019.03.014
M3 - Article
C2 - 30982663
AN - SCOPUS:85064201681
SN - 1534-5807
VL - 49
SP - 267-278.e5
JO - Developmental Cell
JF - Developmental Cell
IS - 2
ER -