Single depolymerizing and transport kinesins stabilize microtubule ends

ABSTRACT Microtubules are highly dynamic cellular filaments and many intracellular processes like cell division depend on an accurate control of their length. Among other factors, microtubule length is actively modulated by motors from the kinesin superfamily. For example, yeast kinesin-8, Kip3, depolymerizes microtubules in a collective manner by a force- and length-dependent mechanism. However, whether single motors depolymerize or stabilize microtubule ends is unclear. Here, using interference reflection microscopy, we measured the influence of single kinesin motors on the stability of microtubules in an in vitro assay. Surprisingly, using unlabeled, stabilized microtubules, we found that both single kinesin-8 and non-depolymerizing kinesin-1 transport motors stabilized microtubule ends further by reducing the spontaneous microtubule depolymerization rate. Since we observed this effect for two very different kinesins, it implies a more general stabilization mechanism. For Kip3, this behavior is contrary to the collective force-dependent depolymerization activity of multiple motors. The complex, concentration-dependent interaction with microtubule ends provides new insights into the molecular mechanism of kinesin-8 and its regulatory function of microtubule length.