Yixian Zheng

A Ran signalling pathway mediated by the mitotic kinase Aurora A in spindle assembly

The activated form of Ran (Ran-GTP) stimulates spindle assembly in Xenopus laevis egg extracts, presumably by releasing spindle assembly factors, such as TPX2 (target protein for Xenopus kinesin-like protein 2) and NuMA (nuclear-mitotic apparatus protein) from the inhibitory binding of importin-α and -β. We report here that Ran-GTP stimulates the interaction between TPX2 and the Xenopus Aurora A kinase, Eg2. This interaction causes TPX2 to stimulate both the phosphorylation and the kinase activity of Eg2 in a microtubule-dependent manner. We show that TPX2 and microtubules promote phosphorylation of Eg2 by preventing phosphatase I (PPI)-induced dephosphorylation. Activation of Eg2 by TPX2 and microtubules is inhibited by importin-α and -β, although this inhibition is overcome by Ran-GTP both in the egg extracts and in vitro with purified proteins. As the phosphorylation of Eg2 stimulated by the Ran-GTP–TPX2 pathway is essential for spindle assembly, we hypothesize that the Ran-GTP gradient established by the condensed chromosomes is translated into the Aurora A kinase gradient on the microtubules to regulate spindle assembly and dynamics.

A Mitotic Lamin B Matrix Induced by RanGTP Required for Spindle Assembly

Mitotic spindle morphogenesis is a series of highly coordinated movements that lead to chromosome segregation and cytokinesis. We report that the intermediate filament protein lamin B, a component of the interphase nuclear lamina, functions in spindle assembly. Lamin B assembled into a matrix-like network in mitosis through a process that depended on the presence of the guanosine triphosphate–bound form of the small guanosine triphosphatase Ran. Depletion of lamin B resulted in defects in spindle assembly. Dominant negative mutant lamin B proteins that disrupt lamin B assembly in interphase nuclei also disrupted spindle assembly in mitosis. Furthermore, lamin B was essential for the formation of the mitotic matrix that tethers a number of spindle assembly factors. We propose that lamin B is a structural component of the long-sought-after spindle matrix that promotes microtubule assembly and organization in mitosis.

Ran stimulates spindle assembly by altering microtubule dynamics and the balance of motor activities.

The guanosine tri-phosphatase Ran stimulates assembly of microtubule spindles. However, it is not known what aspects of the microtubule cytoskeleton are subject to regulation by Ran in mitosis. Here we show that Ran–GTP stimulates microtubule assembly by increasing the rescue frequency of microtubules three- to eightfold. In addition to changing microtubule dynamics, Ran–GTP also alters the balance of motor activities, partly as a result of an increase in the amount of motile Eg5, a plus-end-directed microtubule motor that is essential for spindle formation. Thus, Ran regulates multiple processes that are involved in spindle assembly.

A new function for the γ-tubulin ring complex as a microtubule minus-end cap

Microtubule nucleation from centrosomes involves a lockwasher-shaped protein complex containing γ-tubulin, named the γ-tubulin ring complex (γTuRC). Here we investigate the mechanism by which the γTuRC nucleates microtubules, using a direct labelling method to visualize the behaviour of individual γTuRCs. A fluorescently-labelled version of the γTuRC binds to the minus ends of microtubules nucleated in vitro. Both γTuRC-mediated nucleation and binding of the γTuRC to preformed microtubules block further minus-end growth and prevent microtubule depolymerization. The γTuRC therefore acts as a minus-end-capping protein, as confirmed by electron-microscopic examination of gold-labelled γTuRCs. These data support a nucleation model for γTuRC function that involves capping of microtubules.

Chromosome Alignment and Segregation Regulated by Ubiquitination of Survivin

Proper chromosome segregation requires the attachment of sister kinetochores to microtubules from opposite spindle poles to form bi-oriented chromosomes on the metaphase spindle. The chromosome passenger complex containing Survivin and the kinase Aurora B regulates this process from the centromeres. We report that a de-ubiquitinating enzyme, hFAM, regulates chromosome alignment and segregation by controlling both the dynamic association of Survivin with centromeres and the proper targeting of Survivin and Aurora B to centromeres. Survivin is ubiquitinated in mitosis through both Lys48 and Lys63 ubiquitin linkages. Lys63 de-ubiquitination mediated by hFAM is required for the dissociation of Survivin from centromeres, whereas Lys63 ubiquitination mediated by the ubiquitin binding protein Ufd1 is required for the association of Survivin with centromeres. Thus, ubiquitinaton regulates dynamic protein-protein interactions and chromosome segregation independently of protein degradation.

The AAA-ATPase Cdc48/p97 Regulates Spindle Disassembly at the End of Mitosis

Spindle disassembly at the end of mitosis is a complex and poorly understood process. Here, we report that the AAA-ATPase Cdc48/p97 and its adapters Ufd1-Npl4, which have a well-established role in membrane functions, also regulate spindle disassembly by modulating microtubule dynamics and bundling at the end of mitosis. In the absence of p97-Ufd1-Npl4 function, microtubules in Xenopus egg extracts remain as monopolar spindles attached to condensed chromosomes after Cdc2 kinase activity has returned to the interphase level. Consequently, interphase microtubule arrays and nuclei are not established. Genetic analyses of Cdc48, the yeast homolog of p97, reveal that Cdc48 is also required for disassembly of mitotic spindles after execution of the mitotic exit pathway. Furthermore, Cdc48/p97-Ufd1-Npl4 directly binds to spindle assembly factors and regulates their interaction with microtubules at the end of mitosis. Therefore, Cdc48/p97-Ufd1-Npl4 is an essential chaperone that regulates transformation of the microtubule structure as cells reenter interphase.

Microtubule nucleation : γ-tubulin and beyond

Centrosomes and their fungal equivalents, spindle pole bodies (SPBs), are the main microtubule (MT)-organizing centers in eukaryotic cells. Several proteins have been implicated in microtubule formation by centrosomes and SPBs, including microtubule-minus-end-binding proteins and proteins that bind along the length or stabilize the plus ends of microtubules. Recent work has improved our understanding of the molecular mechanisms of MT formation. In particular, it has shown that γ-tubulin and its associated proteins play key roles in microtubule nucleation and spindle assembly in evolutionarily distant species ranging from fungi to mammals. Other work indicates that γ-tubulin-mediated microtubule nucleation, although necessary, is not sufficient for mitotic spindle assembly but requires additional proteins that regulate microtubule nucleation independently of centrosomes.

Mouse B-Type Lamins Are Required for Proper Organogenesis But Not by Embryonic Stem Cells

Mice lacking critical structural components of the nucleus, lamin-B intermediate filament proteins, remain viable until birth. B-type lamins, the major components of the nuclear lamina, are believed to be essential for cell proliferation and survival. We found that mouse embryonic stem cells (ESCs) do not need any lamins for self-renewal and pluripotency. Although genome-wide lamin-B binding profiles correlate with reduced gene expression, such binding is not directly required for gene silencing in ESCs or trophectoderm cells. However, B-type lamins are required for proper organogenesis. Defects in spindle orientation in neural progenitor cells and migration of neurons probably cause brain disorganizations found in lamin-B null mice. Thus, our studies not only disprove several prevailing views of lamin-Bs but also establish a foundation for redefining the function of the nuclear lamina in the context of tissue building and homeostasis.

γ-Tubulin complexes and their interaction with microtubule-organizing centers

Gamma-tubulin is as ubiquitous in eukaryotes as alpha- and beta-tubulin. Rather than forming part of the microtubule wall, however, gamma-tubulin is involved in microtubule nucleation. Although gamma-tubulin concentrates at microtubule-organizing centers, it also exists in a cytoplasmic complex whose size and complexity depends on the organism and cell type. In the past year, progress in understanding the functions of gamma-tubulin was made on two fronts: identifying the proteins that interact with gamma-tubulin and identifying the proteins that interact with the gamma-tubulin complex to tether it to the microtubule-organizing center.

Aurora A kinase-coated beads function as microtubule-organizing centers and enhance RanGTP-induced spindle assembly

The roles of the kinase Aurora A (AurA) in centrosome function and spindle assembly have been established in Drosophila, C. elegans, and Xenopus egg extracts . Recently, we have shown that AurA acts downstream of the RanGTPase signaling pathway to stimulate spindle assembly in mitosis . However, it is still not clear whether AurA can stimulate the formation of microtubule organizing centers (MTOC) on its own. Moreover, whether AurA is essential for spindle assembly in the absence of centrosomes has remained unclear . Here, we report the development of functional assays that allow us to show that activation of AurA by TPX2 is essential for Ran-stimulated spindle assembly in the presence or absence of centrosomes. Furthermore, AurA-coated magnetic beads function as MTOCs in the presence of RanGTP in Xenopus egg extracts and RanGTP stimulates AurA to recruit activities responsible for both MT nucleation and organization to the beads. The MTOC function of AurA-coated beads require both MT nucleators and motors. Compared to XMAP215-coated beads , AurA-coated beads increase the rate of bipolar spindle assembly in the presence of RanGTP, and the kinase activity of AurA is essential for the beads to function as MTOCs.