Centrosome positioning independently of microtubule-based forces

The regulation of centrosome position is central to the establishment of polarized cell functions. This process is thought to rely on the generation of mechanical forces along microtubules, the balance of which determines centrosome position. By studying these forces in adherent cells in culture, we found that neither pushing nor pulling forces propagate along microtubules to the centrosome. Inhibiting dyneins or disassembling microtubules did not disrupt the maintenance of the centrosome at the center of the cell. In contrast, the actomyosin contractile network appears to be responsible for the generation of a centripetal flow that drives the centrosome towards the center of the cell independently of the microtubules. Furthermore, we found that centering of the centrosome depends more on the reorganization of cell shape around the centrosome than on an effective centrosome displacement throughout the cytoplasm. Interestingly, despite their lack of mechanical role, microtubules appear to direct this remodeling of cell shape. This revised view of centrosome positioning offers a new perspective for understanding the establishment of cell polarity.