Protein Kinase Activities Associated with Actin Cytoskeleton in Xenopus laevis Oocytes and Eggs

Protein phosphorylation with specific protein kinases plays the key role in the regulation of meiotic maturation of oocytes. However, little is known about the contribution of kinases to the temporal and positional regulation of the cytoskeleton rearrangement in maturing oocytes, including the actin cytoskeleton. In order to study a relationship between the kinase activities and actin cytoskeleton rearrangement, we analyzed protein phosphorylation in the isolated actin cytoskeleton of Xenopus laevis oocytes. Analysis of the full grown oocytes and eggs injected with [-³²P]ATP has revealed phosphorylation of many proteins associated with the actin cytoskeleton and shown the appearance of three additional major phosphoproteins, 20, 43, and 69 kDa, during oocyte maturation. A significant number of these phosphoproteins were also found after incubation of the isolated cytoskeleton with [-³²P]ATP in vitro, thus confirming that the kinases modifying these substrates are also specifically associated with actin. The in vivo and in vitro kinase activities were also stimulated during maturation. Analysis of kinase self-phosphorylation in situ and protein phosphorylation in solutions and substrate containing gels revealed a set of actin-associated kinases, including cAMP- and Ca²⁺-dependent kinases, as well as MAP, p34^cdc2, and tyrosine kinase activities. Their level was the highest in the eggs. The involvement of kinases in the actin cytoskeleton rearrangement during oocyte maturation is discussed.     

Abscission checkpoint control: stuck in the middle with Aurora B

At the end of cell division, the cytoplasmic bridge joining the daughter cells is severed through a process that involves scission of the plasma membrane. The presence of chromatin bridges 'stuck' in the division plane is sensed by the chromosomal passenger complex (CPC) component Aurora B kinase, triggering a checkpoint that delays abscission until the chromatin bridges have been resolved. Recent work has started to shed some light on the molecular mechanism by which the CPC controls the timing of abscission.     

Functional analysis of phosphorylation of the mitotic centromere-associated kinesin by Aurora B kinase in human tumor cells

Mitotic centromere-associated kinesin (MCAK) is the best characterized member of the kinesin-13 family and plays important roles in microtubule dynamics during mitosis. Its activity and subcellular localization is tightly regulated by an orchestra of mitotic kinases, such as Aurora B. It is well known that serine 196 of MCAK is the major phosphorylation site of Aurora B in Xenopus leavis extracts and that this phosphorylation regulates its catalytic activity and subcellular localization. In the current study, we have addressed the conserved phosphorylation site serine 192 in human MCAK to characterize its function in more depth in human cancer cells. Our data confirm that S192 is the major phosphorylation site of Aurora B in human MCAK and that this phosphorylation has crucial roles in regulating its catalytic activity and localization at the kinetochore/centromere region in mitosis. Interfering with this phosphorylation leads to a delayed progression through prometa- and metaphase associated with mitotic defects in chromosome alignment and segregation. We show further that MCAK is involved in directional migration and invasion of tumor cells, and interestingly, interference with the S192 phosphorylation affects this capability of MCAK. These data provide the first molecular explanation for clinical observation, where an overexpression of MCAK was associated with lymphatic invasion and lymph node metastasis in gastric and colorectal cancer patients.     

激光共聚焦显微镜观察小鼠早期胚胎中PKB/Akt对微丝聚合的影响

在本实验中我们用优化的免疫荧光化学法结合激光共聚焦显微技术,观察了微丝在小鼠卵细胞不同期的分布情况及PKB/Akt对小鼠卵母细胞和早期胚胎的微丝聚合的影响。结果显示,在小鼠卵母细胞及早期胚胎中均有微丝的表达,且主要集中在纺锤体处的质膜处、极体及分裂沟处。注射激活型PKB/Akt mRNA能够增强微丝的聚集。相反,注射激酶失活型的PKB/AktmRNA减弱了微丝的聚合。因而我们认为PKB/Akt可以影响小鼠卵细胞和早期胚胎的微丝聚集。     

Survivin mutant (Surv-DD70, 71AA) disrupts the interaction of Survivin with Aurora B and causes multinucleation in HeLa cells

Survivin is associated with Aurora B, inner centromere protein (INCENP), and borealin to form a chromosomal passenger complex that plays multiple roles during cell division. We used mutational analysis to study interaction of Survivin with Aurora B and the effect of this interaction on cell division. A Survivin mutant with the terminal domain deleted (Survivin 1-107) bound Aurora B as efficiently as Survivin wild type. This indicated that the proximal BIR domain of Survivin was responsible for Survivin binding to Aurora B. Survivin mutants (Surv-R18A, Surv-D53A, and Sur-KK78, and 79AA) all bound to Aurora B efficiently, but mutation in the conserved amino acid residues of the acidic patch on Survivin (Surv-DD70, 71AA) abolished the direct interaction of Survivin and Aurora B. The Survivin mutant (Surv-DD70, 71AA) localized diffusely in metaphase and failed to successfully accumulate in the midbody during cytokinesis. Furthermore, over-expression of the Survivin mutant (Surv-DD70, 71AA) severely disturbed cytokinesis, resulting in multinucleation in HeLa cell. This indicated that the direct interaction of Survivin and Aurora B was critical for the correct location of Survivin and the function of the Survivin complex in cell division.     

Phosphorylation of Myosin II-interacting Guanine Nucleotide Exchange Factor (MyoGEF) at Threonine 544 by Aurora B Kinase Promotes the Binding of Polo-like Kinase 1 to MyoGEF

We previously reported that phosphorylation of myosin II-interacting guanine nucleotide exchange factor (MyoGEF) by polo-like kinase 1 (Plk1) promotes the localization of MyoGEF to the central spindle and increases MyoGEF activity toward RhoA during mitosis. In this study we report that aurora B-mediated phosphorylation of MyoGEF at Thr-544 creates a docking site for Plk1, leading to the localization and activation of MyoGEF at the central spindle. In vitro kinase assays show that aurora B can phosphorylate MyoGEF. T544A mutation drastically decreases aurora B-mediated phosphorylation of MyoGEF in vitro and in transfected HeLa cells. Coimmunoprecipitation and in vitro pulldown assays reveal that phosphorylation of MyoGEF at Thr-544 enhances the binding of Plk1 to MyoGEF. Immunofluorescence analysis shows that aurora B colocalizes with MyoGEF at the central spindle and midbody during cytokinesis. Suppression of aurora B activity by an aurora B inhibitor disrupts the localization of MyoGEF to the central spindle. In addition, T544A mutation interferes with the localization of MyoGEF to the cleavage furrow and decreases MyoGEF activity toward RhoA during mitosis. Taken together, our results suggest that aurora B coordinates with Plk1 to regulate MyoGEF activation and localization, thus contributing to the regulation of cytokinesis.     

Novel Features of the Light Chain of Microtubule-associated Protein MAP1B: Microtubule Stabilization,Self Interaction,Actin Filament Binding,and Regulation by the Heavy Chain

Previous studies on the role of microtubule-associated protein 1B (MAP1B) in adapting microtubules for nerve cell-specific functions have examined the activity of the entire MAP1B protein complex consisting of heavy and light chains and revealed moderate effects on microtubule stability. Here we have analyzed the effects of the MAP1B light chain in the absence or presence of the heavy chain by immunofluorescence microscopy of transiently transfected cells. Distinct from all other MAPs, the MAP1B light chain–induced formation of stable but apparently flexible microtubules resistant to the effects of nocodazole and taxol. Light chain activity was inhibited by the heavy chain. In addition, the light chain was found to harbor an actin filament binding domain in its COOH terminus. By coimmunoprecipitation experiments using epitope-tagged fragments of MAP1B we showed that light chains can dimerize or oligomerize. Furthermore, we localized the domains for heavy chain–light chain interaction to regions containing sequences homologous to MAP1A. Our findings assign several crucial activities to the MAP1B light chain and suggest a new model for the mechanism of action of MAP1B in which the heavy chain might act as the regulatory subunit of the MAP1B complex to control light chain activity.