ibited with MLN8237, whereas the H2AT120-ph was mostly restored in CB-INCENPexpressing cells treated with MLN8237, suggesting that Aurora-A regulates H2AT120-ph through recruiting CPC, while Aurora-A regulates H3T3-ph via a CPC-independent pathway in late G2 phase. Aurora-A phosphorylates Haspin and regulates its kinase activity As Aurora-A regulates H3T3-ph through a CPCindependent pathway, it is tempting to assume that Aurora-A directly binds and phosphorylates Haspin to promote H3T3-ph in the nucleus in late G2 phase. As expected, the result from the pull-down assay performed with glutathione S-transferase Aurora-A and maltose-binding protein -Haspin revealed that Aurora-A directly interacted with Haspin in vitro. Data from co-immunoprecipitation with green fluorescent protein -Haspin and FLAG-Aurora-A in HEK293T cells revealed that Aurora-A was associated with Haspin in vivo. Next we sought to explore whether Aurora-A also phosphorylates Haspin directly. A kinase assay was performed using recombinant Aurora-A and GST-fusion Haspin-N, which includes most of the Aurora-B phosphorylation sites . Haspin-N lacks the kinase domain and therefore does not display self-phosphorylating activity. Further, Haspin-N displays same nucleus localization as full-length Haspin does in late G2 phase. Autoradiography results showed that Haspin-N was strongly phosphorylated by Aurora-A. Notably, INK-128 web GST-Haspin-N exhibited super-shift bands after it was incubated with recombinant human Aurora-A , suggesting that Haspin-N was highly phosphorylated by Aurora-A. Additionally, the phosphorylated Haspin-N was separated and analyzed using liquid chromatographymass spectrometry to identify phosphorylation sites. Five Serine sites were detected, and these sites were shown to correspond to Aurora-B phosphorylation sites previously identified in mitotic cells. Co-localization was observed between Aurora-A and GFP-Haspin in the nucleus in G2 phase. Furthermore, the reduced migration-shift band of phosphorylated Haspin in G2 phase after Aurora-A inhibition reveals that Aurora-A phosphorylates Haspin in vivo. Thus these results indicate that Aurora-A directly phosphorylates Haspin at multiple sites that are also phosphorylated by Aurora-B. To investigate whether Aurora-A-mediated phosphorylation is associated with Haspin activity, phosphor-mimic mutant EGFP-Haspin 11E and WT Haspin were used to rescue H3T3-ph level in the presence of Aurora-A inhibitor. EGFP-Haspin 11E showed evidently higher activity in phosphorylating H3T3 than WT Haspin did after Aurora-A was inhibited, which implied that phosphorylation at these PubMed ID:http://www.ncbi.nlm.nih.gov/pubmed/19822663 sites promotes Haspin activity. Moreover, the ability of MBP-Haspin in phosphorylating GST-H3 at Thr3 was considerably enhanced after it was preincubated with WT Aurora-A but not KD-Aurora-A, suggesting that Aurora-A activates Haspin by direct phosphorylation. Altogether, these data suggest that Aurora-A promotes Haspin kinase activity by direct phosphorylation. Aurora-A promotes the interaction between Aurora-B and Haspin in early mitosis As Aurora-A and Aurora-B phosphorylate Haspin at the same sites, we wondered whether these two kinases regulate each other in association with Haspin. Interestingly, the interaction between Aurora-B and Haspin was enhanced if Haspin was phosphorylated by rhAurora-A in vitro before mixing with Aurora-B. Moreover, results from a co-immunoprecipitation assay indicated that the association of Aurora-B with Haspin and Plk1 were
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