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.

Myosin-1a is critical for normal brush border structure and composition.

To develop our understanding of myosin-1a function in vivo, we have created a mouse line null for the myosin-1a gene. Myosin-1a knockout mice demonstrate no overt phenotypes at the whole animal level but exhibit significant perturbations and signs of stress at the cellular level. Among these are defects in microvillar membrane morphology, distinct changes in brush-border organization, loss of numerous cytoskeletal and membrane components from the brush border, and redistribution of intermediate filament proteins into the brush border. We also observed significant ectopic recruitment of another short-tailed class I motor, myosin-1c, into the brush border of knockout enterocytes. This latter finding, a clear demonstration of functional redundancy among vertebrate myosins-I, may account for the lack of a whole animal phenotype. Nevertheless, these results indicate that myosin-1a is a critical multifunctional component of the enterocyte, required for maintaining the normal composition and highly ordered structure of the brush border.

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.

A kinesin switch I arginine to lysine mutation rescues microtubule function.

Switch I and II are key active site structural elements of kinesins, myosins, and G-proteins. Our analysis of a switch I mutant (R210A) in Drosophila melanogaster kinesin showed a reduction in microtubule affinity, a loss in cooperativity between the motor domains, and an ATP hydrolysis defect leading to aberrant detachment from the microtubule. To investigate the conserved arginine in switch I further, a lysine substitution mutant was generated. The R210K dimeric motor has lost the ability to hydrolyze ATP; however, it has rescued microtubule function. Our results show that R210K has restored microtubule association kinetics, microtubule affinity, ADP release kinetics, and motor domain cooperativity. Moreover, the active site at head 1 is able to distinguish ATP, ADP, and AMP-PNP to signal head 2 to bind the microtubule and release mantADP with kinetics comparable with wild-type. Therefore, the structural pathway of communication from head 1 to head 2 is restored, and head 2 can respond to this signal by binding the microtubule and releasing mantADP. Structural modeling revealed that lysine could retain some of the hydrogen bonds made by arginine but not all, suggesting a structural hypothesis for the ability of lysine to rescue microtubule function in the Arg210 mutant.

The ATPase cross-bridge cycle of the Kar3 motor domain. Implications for single head motility.

Kar3 is a minus-end directed microtubule motor involved in meiosis and mitosis in Saccharomyces cerevisae. Unlike Drosophila Ncd, the other well characterized minus-end directed motor that is a homodimer, Kar3 is a heterodimer with a single motor domain and either the associated polypeptides Cik1 or Vik1. Our mechanistic studies with Ncd showed that both motor domains were required for ATP-dependent motor domain detachment from the microtubule. We have initiated a series of experiments to compare the mechanistic requirements for Kar3 motility in direct comparison to Ncd. The results presented here show that the single motor domain of Kar3 (Met(383)-Lys(729)) exhibits characteristics similar to monomeric Ncd. The microtubule-activated steady-state ATPase cycle of Kar3 (k(cat) = 0.5 s(-1)) is limited by ADP release (0.4 s(-1)). Like monomeric Ncd, Kar3 does not readily detach from the microtubule with the addition of MgATP. These results show that the single motor domain of Kar3 is not sufficient for ATP-dependent microtubule dissociation, suggesting that structural elements outside of the catalytic core are required for the cyclic interactions with the microtubule for force generation.

The role of ATP hydrolysis for kinesin processivity.

Conventional kinesin is a highly processive, plus-end-directed microtubule-based motor that drives membranous organelles toward the synapse in neurons. Although recent structural, biochemical, and mechanical measurements are beginning to converge into a common view of how kinesin converts the energy from ATP turnover into motion, it remains difficult to dissect experimentally the intermolecular domain cooperativity required for kinesin processivity. We report here our pre-steady-state kinetic analysis of a kinesin switch I mutant at Arg(210) (NXXSSRSH, residues 205-212 in Drosophila kinesin). The results show that the R210A substitution results in a dimeric kinesin that is defective for ATP hydrolysis and a motor that cannot detach from the microtubule although ATP binding and microtubule association occur. We propose a mechanistic model in which ATP binding at head 1 leads to the plus-end-directed motion of the neck linker to position head 2 forward at the next microtubule binding site. However, ATP hydrolysis is required at head 1 to lock head 2 onto the microtubule in a tight binding state before head 1 dissociation from the microtubule. This mechanism optimizes forward movement and processivity by ensuring that one motor domain is tightly bound to the microtubule before the second can detach.