Arian Ivec scite author profile

Mechanical forces produced by motor proteins and microtubule dynamics within the mitotic spindle are crucial for the movement of chromosomes and their segregation into the emerging daughter cells. In addition to linear forces, rotational forces are present in the spindle, reflected in the left-handed twisted shapes of microtubule bundles that make the spindle chiral. However, the molecular origins of spindle chirality are unknown. Here we show that spindles are most twisted at the beginning of anaphase, and reveal multiple molecular players involved in spindle chirality. Inhibition of Eg5/kinesin-5 in a non-cancer cell line abolished spindle twist and depletion of Kif18A/kinesin-8 resulted in a right-handed twist, implying that these motors regulate twist likely by rotating the microtubules around one another within the antiparallel overlaps of bridging fibers. Depletion of the crosslinker PRC1 resulted in a right-handed twist, indicating that PRC1 may contribute to the twist by constraining free rotation of microtubules. Overexpression of PRC1 abolished twist, possibly due to increased torsional rigidity of the bundles. Depletion of augmin led to a right-handed twist, suggesting that twist depends on the geometry of microtubule nucleation. Round spindles were more twisted than elongated ones, a notion that we directly tested by compressing the spindle along its axis, which resulted in stronger left-handed twist, indicating a correlation between bending moments and twist. We conclude that spindle twist is controlled by multiple molecular mechanisms acting at different locations within the spindle as well as forces, and propose a potential physiological role of twist in promoting passive mechanical response of the spindle to forces during metaphase.

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Oblique circle method for measuring the curvature and twist of mitotic spindle microtubule bundles

Ivec

Trupinić

Tolić

et al. 2021

Biophysical Journal

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The highly ordered spatial organization of microtubule bundles in the mitotic spindle is crucial for its proper functioning. The recent discovery of twisted shapes of microtubule bundles and spindle chirality suggests that the bundles extend along curved paths in three dimensions, rather than being confined to a plane. This, in turn, implies that rotational forces, i.e., torques, exist in the spindle in addition to the widely studied linear forces. However, studies of spindle architecture and forces are impeded by a lack of a robust method for the geometric quantification of microtubule bundles in the spindle. In this work, we describe a simple method for measuring and evaluating the shapes of microtubule bundles by characterizing them in terms of their curvature and twist. By using confocal microscopy, we obtain three-dimensional images of spindles, which allows us to trace the entire microtubule bundle. For each traced bundle, we first fit a plane and then fit a circle lying in that plane. With this robust method, we extract the curvature and twist, which represent the geometric information characteristic for each bundle. As the bundle shapes reflect the forces within them, this method is valuable for the understanding of forces that act on chromosomes during mitosis.

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The Chirality of the Mitotic Spindle Provides a Mechanical Response to Forces and Depends on Microtubule Motors and Crosslinkers

et al. 2021

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Arian Ivec

Naegleria’s mitotic spindles are built from unique tubulins and highlight core spindle features

The chirality of the mitotic spindle provides a mechanical response to forces and depends on microtubule motors and augmin

The chirality of the mitotic spindle provides a mechanical response to forces and depends on microtubule motors and augmin

Oblique circle method for measuring the curvature and twist of mitotic spindle microtubule bundles

The Chirality of the Mitotic Spindle Provides a Mechanical Response to Forces and Depends on Microtubule Motors and Crosslinkers

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