Abstract
The mitotic spindle in the fission yeast
is a single bundle of microtubules which elongates to segregate the chromosomes during anaphase B. The mechanical properties of the spindle and the forces driving its elongation remain poorly defined. Here, we analyzed how spindles react to mechanical and genetic perturbations to uncover their mechanical properties. Treatment of cells with osmotic oscillations and blue light led to a consistent phenotype of spindle buckling and breakage in mid-anaphase. The stalling of pole separation and reduced rates of spindle elongation indicated that spindles elongate and buckle under increased mechanical load. The structural integrity of the bent spindles was dependent on Ase1 (PRC1), while the spindle elongation rate was dependent on motor proteins Klp9 (kinesin-6) and Cut7 (kinesin-5). Modeling of bent spindle shapes revealed that most spindles behave mechanically as a beam in which the midzone region is 1-2 times as rigid than the rest of the beam. Upon reaching a threshold size, bent spindles broke at a specific fragile site near the edge of the spindle midzone. Our findings in this simple fission yeast spindle are relevant to the mechanics of more complex metazoan spindles. [Media: see text].