PP6 regulation of Aurora A-TPX2 limits NDC80 phosphorylation and mitotic spindle size.

Amplification of the mitotic kinase Aurora A or loss of its regulator protein phosphatase 6 (PP6) have emerged as drivers of genome instability. Cells lacking PPP6C, the catalytic subunit of PP6, have amplified Aurora A activity, and as we show here, enlarged mitotic spindles which fail to hold chromosomes tightly together in anaphase, causing defective nuclear structure. Using functional genomics to shed light on the processes underpinning these changes, we discover synthetic lethality between PPP6C and the kinetochore protein NDC80. We find that NDC80 is phosphorylated on multiple N-terminal sites during spindle formation by Aurora A-TPX2, exclusively at checkpoint-silenced, microtubule-attached kinetochores. NDC80 phosphorylation persists until spindle disassembly in telophase, is increased in PPP6C knockout cells, and is Aurora B-independent. An Aurora-phosphorylation-deficient NDC80-9A mutant reduces spindle size and suppresses defective nuclear structure in PPP6C knockout cells. In regulating NDC80 phosphorylation by Aurora A-TPX2, PP6 plays an important role in mitotic spindle formation and size control and thus the fidelity of cell division.

MPS1 localizes to end-on microtubule-attached kinetochores to promote microtubule release.

In eukaryotes, the spindle assembly checkpoint protects genome stability in mitosis by preventing chromosome segregation until incorrect microtubule-kinetochore attachment geometries have been eliminated and chromosome biorientation has been completed. These error correction and checkpoint processes are linked by the conserved Aurora B and MPS1 Ser/Thr kinases.1,2 MPS1-dependent checkpoint signaling is believed to be initiated by kinetochores without end-on microtubule attachments,3,4 including those generated by Aurora B-mediated error correction. The current model posits that MPS1 competes with microtubules for binding sites at the kinetochore.3,4 MPS1 is thought to first recognize kinetochores not blocked by microtubules and then initiate checkpoint signaling. However, MPS1 is also required for chromosome biorientation and correction of microtubule-kinetochore attachment errors.5,6,7,8,9 This latter function, which must require direct interaction with microtubule-attached kinetochores, is not readily explained within the constraints of the current model. Here, we show that MPS1 transiently localizes to end-on attached kinetochores and that this recruitment depends on the relative activities of Aurora B and its counteracting phosphatase PP2A-B56 rather than microtubule-attachment state per se. MPS1 autophosphorylation also regulates MPS1 kinetochore levels but does not determine the response to microtubule attachment. At end-on attached kinetochores, MPS1 actively promotes microtubule release together with Aurora B. Furthermore, in live cells, MPS1 is detected at attached kinetochores before the removal of microtubules. During chromosome alignment, MPS1, therefore, coordinates both the resolution of incorrect microtubule-kinetochore attachments and the initiation of spindle checkpoint signaling.