Long-Range Repulsion Between Chromosomes in Mammalian Oocyte Spindles

TL;DR

This study reveals long-range repulsive forces between chromosomes in mammalian oocyte spindles, driven by the nematic liquid crystal behavior of microtubules, affecting chromosome organization and segregation.

Contribution

It uncovers a novel long-range repulsion mechanism between chromosomes mediated by microtubule nematic fields in large spindles, integrating materials physics with cell biology.

Findings

Chromosomes are spatially anti-correlated in mouse oocyte spindles.

Microtubule network behaves as a nematic liquid crystal.

Deformation of the nematic field causes long-range chromosome repulsion.

Abstract

During eukaryotic cell division, a microtubule-based structure called the spindle exerts forces on chromosomes, thereby organizing and segregating them Extensive work demonstrates that the forces acting parallel to the spindle axis, including those responsible for separating sister chromatids, are generated by microtubule polymerization and depolymerization, and molecular-motors. In contrast, little is known about the forces acting perpendicular to the spindle axis, which determine the configuration of chromosomes at the metaphase plate, and thus impact nuclear localization and rates of segregation errors. Here, we use quantitative live-cell microscopy to show that metaphase chromosomes are spatially anti-correlated in mouse oocyte spindles, indicating the existence of hitherto unknown long-range forces acting perpendicular to the spindle axis. We explain this observation by first demonstrating that the spindle's microtubule network behaves as a nematic liquid crystal, and then arguing that deformation of the nematic field around embedded chromosomes causes long-range repulsion between them. Our work highlights the surprising relevance of materials physics in understanding the structure, dynamics, and mechanics of cellular structures, and presents a novel and potentially generic mode of chromosome organization in large spindles.