Abstract
Monastrol is a small, cell-permeable molecule that arrests cells in mitosis by specifically inhibiting Eg5, a member of the Kinesin-5 family. We have used steady-state and presteady-state kinetics as well as equilibrium binding approaches to define the mechanistic basis of S-monastrol inhibition of monomeric human Eg5/KSP. In the absence of microtubules (Mts), the basal ATPase activity is inhibited through slowed product release. In the presence of microtubules, the ATPase activity is also reduced with weakened binding of Eg5 to microtubules during steady-state ATP turnover. Monastrol-treated Eg5 also shows a decreased relative affinity for microtubules under equilibrium conditions. The Mt.Eg5 presteady-state kinetics of ATP binding and the subsequent ATP-dependent isomerization are unaffected during the first ATP turnover. However, monastrol appears to stabilize a conformation that allows for reversals at the ATP hydrolysis step. Monastrol promotes a dramatic decrease in the observed rate of Eg5 association with microtubules, and ADP release is slowed without trapping the Mt.Eg5.ADP intermediate. We propose that S-monastrol binding to Eg5 induces a stable conformational change in the motor domain that favors ATP re-synthesis after ATP hydrolysis. The aberrant interactions with the microtubule and the reversals at the ATP hydrolysis step alter the ability of Eg5 to generate force, thereby yielding a nonproductive Mt.Eg5 complex that cannot establish or maintain the bipolar spindle.
Highlights
Accurate segregation of replicated chromosomes during cell division depends on the correct assembly and proper maintenance of the bipolar spindle
The results presented here reveal an altered ATPase mechanism in which reversals occurred at the ATP hydrolysis step, the affinity of the Mt1⁄7Eg5S complex was compromised, and ADP release was slowed
We propose that the Eg5 ATP hydrolysis conformation is stabilized by monastrol (Species 3, Fig. 9) such that reversals at this step become energetically favorable
Summary
Accurate segregation of replicated chromosomes during cell division depends on the correct assembly and proper maintenance of the bipolar spindle (reviewed in Refs. 1–15). By comparing the monastrol-treated Eg5 crystal structure (Eg5S1⁄7ADP)1 [23] to the Eg51⁄7ADP structure [32], monastrol appears to induce dramatic conformational changes throughout the catalytic core, including transformation of the insertion loop (L5) of helix ␣2 and the neck-linker/ switch II cluster without considerably altering the structure of the nucleotide-binding site [23]. How these conformational changes alter the ATPase mechanism of Eg5 and disturb force generation by the Mt1⁄7Eg5 complex is not well understood. Monastrol promotes an ineffective Mt1⁄7Eg5S complex that cannot generate the force required to establish and maintain the bipolar mitotic spindle for chromosome segregation
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