Cik1 targets the minus-end kinesin depolymerase kar3 to microtubule plus ends.

Kar3, a Saccharomyces cerevisiae Kinesin-14, is essential for karyogamy and meiosis I but also has specific functions during vegetative growth. For its various roles, Kar3 forms a heterodimer with either Cik1 or Vik1, both of which are noncatalytic polypeptides. Here, we present the first biochemical characterization of Kar3Cik1, the kinesin motor that is essential for karyogamy. Kar3Cik1 depolymerizes microtubules from the plus end and promotes robust minus-end-directed microtubule gliding. Immunolocalization studies show that Kar3Cik1 binds preferentially to one end of the microtubule, whereas the Kar3 motor domain, in the absence of Cik1, exhibits significantly higher microtubule lattice binding. Kar3Cik1-promoted microtubule depolymerization requires ATP turnover, and the kinetics fit a single exponential function. The disassembly mechanism is not microtubule catastrophe like that induced by the MCAK Kinesin-13s. Soluble tubulin does not activate the ATPase activity of Kar3Cik1, and there is no evidence of Kar3Cik1(.)tubulin complex formation as observed for MCAK. These results reveal a novel mechanism to regulate microtubule depolymerization. We propose that Cik1 targets Kar3 to the microtubule plus end. Kar3Cik1 then uses its minus-end-directed force to depolymerize microtubules from the plus end, with each tubulin-subunit release event tightly coupled to one ATP turnover.

Drosophila Nod protein binds preferentially to the plus ends of microtubules and promotes microtubule polymerization in vitro.

Nod, a nonmotile kinesin-like protein, plays a critical role in segregating achiasmate chromosomes during female meiosis. In addition to localizing to oocyte chromosomes, we show that functional full-length Nod-GFP (Nod(FL)-GFP) localizes to the posterior pole of the oocyte at stages 9-10A, as does kinesin heavy chain (KHC), a plus end-directed motor. This posterior localization is abolished in grk mutants that no longer maintain the microtubule (MT) gradient in the oocyte. To test the hypothesis that Nod binds to the plus ends of MTs, we expressed and purified both full-length Nod (Nod(FL)) and a truncated form of Nod containing only the motor-like domain (Nod318) from Escherichia coli and assessed their interactions with MTs in vitro. Both Nod(FL) and Nod318 demonstrate preferential binding to the ends of the MTs, displaying a strong preference for binding to the plus ends. When Nod318-GFP:MT collision complexes were trapped by glutaraldehyde fixation, the preference for binding to plus ends versus minus ends was 17:1. Nod(FL) and Nod318 also promote MT polymerization in vitro in a time-dependent manner. The observation that Nod is preferentially localized to the plus ends of MTs and stimulates MT polymerization suggests a mechanism for its function.

Vik1 modulates microtubule-Kar3 interactions through a motor domain that lacks an active site.

Conventional kinesin and class V and VI myosins coordinate the mechanochemical cycles of their motor domains for processive movement of cargo along microtubules or actin filaments. It is widely accepted that this coordination is achieved by allosteric communication or mechanical strain between the motor domains, which controls the nucleotide state and interaction with microtubules or actin. However, questions remain about the interplay between the strain and the nucleotide state. We present an analysis of Saccharomyces cerevisiae Kar3/Vik1, a heterodimeric C-terminal Kinesin-14 containing catalytic Kar3 and the nonmotor protein Vik1. The X-ray crystal structure of Vik1 exhibits a similar fold to the kinesin and myosin catalytic head, but lacks an ATP binding site. Vik1 binds more tightly to microtubules than Kar3 and facilitates cooperative microtubule decoration by Kar3/Vik1 heterodimers, and yet allows motility. These results demand communication between Vik1 and Kar3 via a mechanism that coordinates their interactions with microtubules.

A structural model for monastrol inhibition of dimeric kinesin Eg5.

Eg5 or KSP is a homotetrameric Kinesin-5 involved in centrosome separation and assembly of the bipolar mitotic spindle. Analytical gel filtration of purified protein and cryo-electron microscopy (cryo-EM) of unidirectional shadowed microtubule-Eg5 complexes have been used to identify the stable dimer Eg5-513. The motility assays show that Eg5-513 promotes robust plus-end-directed microtubule gliding at a rate similar to that of homotetrameric Eg5 in vitro. Eg5-513 exhibits slow ATP turnover, high affinity for ATP, and a weakened affinity for microtubules when compared to monomeric Eg5. We show here that the Eg5-513 dimer binds microtubules with both heads to two adjacent tubulin heterodimers along the same microtubule protofilament. Under all nucleotide conditions tested, there were no visible structural changes in the monomeric Eg5-microtubule complexes with monastrol treatment. In contrast, there was a substantial monastrol effect on dimeric Eg5-513, which reduced microtubule lattice decoration. Comparisons between the X-ray structures of Eg5-ADP and Eg5-ADP-monastrol with rat kinesin-ADP after docking them into cryo-EM 3-D scaffolds revealed structural evidence for the weaker microtubule-Eg5 interaction in the presence of monastrol.

Mechanistic analysis of the Saccharomyces cerevisiae kinesin Kar3.

Kar3 is a minus-end-directed microtubule motor that is implicated in meiotic and mitotic spindle function in Saccharomyces cerevisiae. To date, the only truncated protein of Kar3 that has been reported to promote unidirectional movement in vitro is GSTKar3. This motor contains an NH2-terminal glutathione S-transferase (GST) tag followed by the Kar3 sequence that is predicted to form an extended alpha-helical coiled-coil. The alpha-helical domain leads into the neck linker and COOH-terminal motor domain. Kar3 does not homodimerize with itself but forms a heterodimer with either Cik1 or Vik1, both of which are non-motor polypeptides. We evaluated the microtubule-GSTKar3 complex in comparison to the microtubule-Kar3 motor domain complex to determine the distinctive mechanistic features required for GSTKar3 motility. Our results indicate that ATP binding was significantly faster for GSTKar3 than that observed previously for the Kar3 motor domain. In addition, microtubule-activated ADP release resulted in an intermediate that bound ADP weakly in contrast to the Kar3 motor domain, suggesting that after ADP release, the microtubule-GSTKar3 motor binds ATP in preference to ADP. The kinetics also showed that GST-Kar3 readily detached from the microtubule rather than remaining bound for multiple ATP turnovers. These results indicate that the extended alpha-helical domain NH2-terminal to the catalytic core provides the structural transitions in response to the ATPase cycle that are critical for motility and that dimerization is not specifically required. This study provides the foundation to define the mechanistic contributions of Cik1 and Vik1 for Kar3 force generation and function in vivo.