Abstract
Kinesin-13 proteins depolymerize microtubules in an ATP hydrolysis-dependent manner. The coupling between these two activities remains unclear. Here, we first studied the role of the kinesin-13 subfamily-specific loop 2 and of the KVD motif at the tip of this loop. Shortening the loop, the lysine/glutamate interchange and the additional Val to Ser substitution all led to Kif2C mutants with decreased microtubule-stimulated ATPase and impaired depolymerization capability. We rationalized these results based on a structural model of the Kif2C-ATP-tubulin complex derived from the recently determined structures of kinesin-1 bound to tubulin. In this model, upon microtubule binding Kif2C undergoes a conformational change governed in part by the interaction of the KVD motif with the tubulin interdimer interface. Second, we mutated to an alanine the conserved glutamate residue of the switch 2 nucleotide binding motif. This mutation blocks motile kinesins in a post-conformational change state and inhibits ATP hydrolysis. This Kif2C mutant still depolymerized microtubules and yielded complexes of one Kif2C with two tubulin heterodimers. These results demonstrate that the structural change of Kif2C-ATP upon binding to microtubule ends is sufficient for tubulin release, whereas ATP hydrolysis is not required. Overall, our data suggest that the conformation reached by kinesin-13s upon tubulin binding is similar to that of tubulin-bound, ATP-bound, motile kinesins but that this conformation is adapted to microtubule depolymerization.
Highlights
It is unclear whether microtubule depolymerization by kinesin-13s is coupled with the hydrolysis step of ATP turnover
This mutation blocks motile kinesins in a post-conformational change state and inhibits ATP hydrolysis. This Kif2C mutant still depolymerized microtubules and yielded complexes of one Kif2C with two tubulin heterodimers. These results demonstrate that the structural change of Kif2C-ATP upon binding to microtubule ends is sufficient for tubulin release
This KVD motif is necessary for microtubule depolymerization by kinesin-13s (9 –11) and was shown to point toward the part of tubulin that is at a longitudinal intermolecular interface in microtubules [9, 11]
Summary
It is unclear whether microtubule depolymerization by kinesin-13s is coupled with the hydrolysis step of ATP turnover. A previous study of the monomeric minimal functional domain of human kinesin-13 protein Kif2C has established that Kif2C undergoes autonomous nucleotide exchange in solution and that Kif2C-ATP has remarkably high affinity for curved tubulin These unique properties lead to a proposal that Kif2C starts the microtubule depolymerization process by binding directly to the end of microtubules in the ATP binding state [8]. We performed mutagenesis studies of the monomeric minimal functional domain of Kif2C, based on a structural model of Kif2C-ATP bound to tubulin These results revealed that the KVD motif at the tip of Kif2C loop 2 plays an essential role in the conformational change of Kif2C-ATP upon tubulin binding. Our data provide a clearer view of the microtubule depolymerization mechanism of Kif2C, which is probably universal for all the kinesin-13 proteins
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