Full-length dimeric MCAK is a more efficient microtubule depolymerase than minimal domain monomeric MCAK.

MCAK belongs to the Kinesin-13 family, whose members depolymerize microtubules rather than translocate along them. We defined the minimal functional unit of MCAK as the catalytic domain plus the class specific neck (MD-MCAK), which is consistent with previous reports. We used steady-state ATPase kinetics, microtubule depolymerization assays, and microtubule.MCAK cosedimentation assays to compare the activity of full-length MCAK, which is a dimer, with MD-MCAK, which is a monomer. Full-length MCAK exhibits higher ATPase activity, more efficient microtubule end binding, and reduced affinity for the tubulin heterodimer. Our studies suggest that MCAK dimerization is important for its catalytic cycle by promoting MCAK binding to microtubule ends, enhancing the ability of MCAK to recycle for multiple rounds of microtubule depolymerization, and preventing MCAK from being sequestered by tubulin heterodimers.

Kinetochore-spindle microtubule interactions during mitosis.

The kinetochore is a proteinaceous structure that assembles onto centromeric DNA and mediates chromosome attachment to microtubules during mitosis. This description is deceivingly simple: recent proteomic studies suggest that the diminutive kinetochores of Saccharomyces cerevisiae are comprised of at least 60 proteins organized into as many as 14 different subcomplexes. Many of these proteins, such as the centromeric histone variant CENP-A, and entire subcomplexes, such as the Ndc80(Hec1) complex, are conserved from yeast to humans despite the diverse nature of the DNA sequences on which they assemble. There have recently been advances in our understanding of the molecular basis of how kinetochores establish dynamic attachments to spindle microtubules, and how these attachments are correctly oriented to ensure segregation of sister chromatids to daughter cells.

Mitotic spindle assembly and chromosome segregation: refocusing on microtubule dynamics.

The quest to find the underlying mechanisms of mitosis has taken many turns, which have largely been directed by the development of sensitive microscopes, enhanced microtubule-labeling techniques, advances in tubulin biochemistry, and genome-wide surveys to find the molecular "missing pieces" to the puzzle. Much of the work over the past decade has focused on the role of molecular motors in producing the necessary forces for spindle assembly and chromosome segregation. Recently, there has been a resurgence in research directed at understanding the intricate regulation of microtubule dynamics and organization during mitosis. This comes in part from the identification of new proteins involved in microtubule regulation as well as advances in fluorescence imaging that allow visualization of mitotic processes that previously have never been observed.

Aurora B phosphorylates centromeric MCAK and regulates its localization and microtubule depolymerization activity.

BACKGROUND: Sister kinetochores must bind microtubules in a bipolar fashion to equally segregate chromosomes during mitosis. The molecular mechanisms underlying this process remain unclear. Aurora B likely promotes chromosome biorientation by regulating kinetochore-microtubule attachments. MCAK (mitotic centromere-associated kinesin) is a Kin I kinesin that can depolymerize microtubules. These two proteins both localize to mitotic centromeres and have overlapping mitotic functions, including regulation of microtubule dynamics, proper chromosome congression, and correction of improper kinetochore-microtubule attachments. RESULTS: We show that Aurora B phosphorylates and regulates MCAK both in vitro and in vivo. Specifically, we mapped six Aurora B phosphorylation sites on MCAK in both the centromere-targeting domain and the neck region. Aurora B activity was required to localize MCAK to centromeres, but not to spindle poles. Aurora B phosphorylation of serine 196 in the neck region of MCAK inhibited its microtubule depolymerization activity. We found that this key site was phosphorylated at centromeres and anaphase spindle midzones in vivo. However, within the inner centromere there were pockets of both phosphorylated and unphosphorylated MCAK protein, suggesting that phosphate turnover is crucial in the regulation of MCAK activity. Addition of alpha-p-S196 antibodies to Xenopus egg extracts or injection of alpha-p-S196 antibodies into cells caused defects in chromosome positioning and/or segregation. CONCLUSIONS: We have established a direct link between the microtubule depolymerase MCAK and Aurora B kinase. Our data suggest that Aurora B both positively and negatively regulates MCAK during mitosis. We propose that Aurora B biorients chromosomes by directing MCAK to depolymerize incorrectly oriented kinetochore microtubules.

Depletion of centromeric MCAK leads to chromosome congression and segregation defects due to improper kinetochore attachments.

The complex behavior of chromosomes during mitosis is accomplished by precise binding and highly regulated polymerization dynamics of kinetochore microtubules. Previous studies have implicated Kin Is, unique kinesins that depolymerize microtubules, in regulating chromosome positioning. We have characterized the immunofluorescence localization of centromere-bound MCAK and found that MCAK localized to inner kinetochores during prophase but was predominantly centromeric by metaphase. Interestingly, MCAK accumulated at leading kinetochores during congression but not during segregation. We tested the consequences of MCAK disruption by injecting a centromere dominant-negative protein into prophase cells. Depletion of centromeric MCAK led to reduced centromere stretch, delayed chromosome congression, alignment defects, and severe missegregation of chromosomes. Rates of chromosome movement were unchanged, suggesting that the primary role of MCAK is not to move chromosomes. Furthermore, we found that disruption of MCAK leads to multiple kinetochore-microtubule attachment defects, including merotelic, syntelic, and combined merotelic-syntelic attachments. These findings reveal an essential role for Kin Is in prevention and/or correction of improper kinetochore-microtubule attachments.

The microtubule-destabilizing kinesin XKCM1 is required for chromosome positioning during spindle assembly.

Xenopus kinesin catastrophe modulator-1 (XKCM1) is a Kin I kinesin family member that uses the energy of ATP hydrolysis to depolymerize microtubules. We demonstrated previously that XKCM1 is essential for mitotic-spindle assembly in vitro and acts by regulating microtubule dynamics as a pure protein, in extracts and in cells. A portion of the XKCM1 pool is specifically localized to centromeres during mitosis and may be important in chromosome movement. To selectively analyze the function of centromere-bound XKCM1, we generated glutathione-S-transferase (GST) fusion proteins containing the N-terminal globular domain (GST-NT), the centrally located catalytic domain (GST-CD), and the C-terminal alpha-helical tail (GST-CT) of XKCM1. The GST-NT protein targeted to centromeres during spindle assembly, suggesting that the N-terminal domain of XKCM1 is sufficient for centromere localization. Addition of GST-NT prior to or after spindle assembly replaced endogenous XKCM1, indicating that centromere targeting is a dynamic process. Loss of endogenous XKCM1 from centromeres caused a misalignment of chromosomes on the metaphase plate without affecting global spindle structure. These results suggest that centromere bound XKCM1 has an important role in chromosome positioning on the spindle.

The microtubule-destabilizing kinesin XKCM1 regulates microtubule dynamic instability in cells.

The dynamic activities of cellular microtubules (MTs) are tightly regulated by a balance between MT-stabilizing and -destabilizing proteins. Studies in Xenopus egg extracts have shown that the major MT destabilizer during interphase and mitosis is the kinesin-related protein XKCM1, which depolymerizes MT ends in an ATP-dependent manner. Herein, we examine the effects of both overexpression and inhibition of XKCM1 on the regulation of MT dynamics in vertebrate somatic cells. We found that XKCM1 is a MT-destabilizing enzyme in PtK2 cells and that XKCM1 modulates cellular MT dynamics. Our results indicate that perturbation of XKCM1 levels alters the catastrophe frequency and the rescue frequency of cellular MTs. In addition, we found that overexpression of XKCM1 or inhibition of KCM1 during mitosis leads to the formation of aberrant spindles and a mitotic delay. The predominant spindle defects from excess XKCM1 included monoastral and monopolar spindles, as well as small prometaphase-like spindles with improper chromosomal attachments. Inhibition of KCM1 during mitosis led to prometaphase spindles with excessively long MTs and spindles with partially separated poles and a radial MT array. These results show that KCM1 plays a critical role in regulating both interphase and mitotic MT dynamics in mammalian cells.