AURKA destruction is decoupled from its activity at mitotic exit but is essential to suppress interphase activity.

Activity of AURKA is controlled through multiple mechanisms including phosphorylation, ubiquitin-mediated degradation and allosteric interaction with TPX2. Activity peaks at mitosis, before AURKA is degraded during and after mitotic exit in a process strictly dependent on the APC/C coactivator FZR1. We used FZR1 knockout cells (FZR1KO) and a novel FRET-based AURKA biosensor to investigate how AURKA activity is regulated in the absence of destruction. We found that AURKA activity in FZR1KO cells dropped at mitotic exit as rapidly as in parental cells, despite absence of AURKA destruction. Unexpectedly, TPX2 was degraded normally in FZR1KO cells. Overexpression of an N-terminal TPX2 fragment sufficient for AURKA binding, but that is not degraded at mitotic exit, caused delay in AURKA inactivation. We conclude that inactivation of AURKA at mitotic exit is determined not by AURKA degradation but by degradation of TPX2 and therefore is dependent on CDC20 rather than FZR1. The biosensor revealed that FZR1 instead suppresses AURKA activity in interphase and is critically required for assembly of the interphase mitochondrial network after mitosis.This article has an associated First Person interview with the first authors of the paper.

hVFL3/CCDC61 is a component of mother centriole subdistal appendages required for centrosome cohesion and positioning.

BACKGROUND: The centrosome regulates cell spatial organisation by controlling the architecture of the microtubule (MT) cytoskeleton. Conversely, the position of the centrosome within the cell depends on cytoskeletal networks it helps organizing. In mammalian cells, centrosome positioning involves a population of MT stably anchored at centrioles, the core components of the centrosome. An MT-anchoring complex containing the proteins ninein and Cep170 is enriched at subdistal appendages (SAP) that decorate the older centriole (called mother centriole) and at centriole proximal ends. Here, we studied the role played at the centrosome by hVFL3/CCDC61, the human ortholog of proteins required for anchoring distinct sets of cytoskeletal fibres to centrioles in unicellular eukaryotes. RESULTS: We show that hVFL3 co-localises at SAP and at centriole proximal ends with components of the MT-anchoring complex, and physically interacts with Cep170. Depletion of hVFL3 increased the distance between mother and daughter centrioles without affecting the assembly of a filamentous linker that tethers the centrioles and contains the proteins rootletin and C-Nap1. When the linker was disrupted by inactivating C-Nap1, hVFL3-depletion exacerbated centriole splitting, a phenotype also observed following depletion of other SAP components. This supported that hVFL3 is required for SAP function, which we further established by showing that centrosome positioning is perturbed in hVFL3-depleted interphase cells. Finally, we found that hVFL3 is an MT-binding protein. CONCLUSIONS AND SIGNIFICANCE: Together, our results support that hVFL3 is required for anchoring MT at SAP during interphase and ensuring proper centrosome cohesion and positioning. The role of the VFL3 family of proteins thus appears to have been conserved in evolution despite the great variation in the shape of centriole appendages in different eukaryotic species.

Chk1 dynamics in G2 phase upon replication stress predict daughter cell outcome.

In human cells, ATR/Chk1 signaling couples S phase exit with the expression of mitotic inducers and prevents premature mitosis upon replication stress (RS). Nonetheless, under-replicated DNA can persist at mitosis, prompting chromosomal instability. To decipher how the DNA replication checkpoint (DRC) allows cells to enter mitosis over time upon RS, we developed a FRET-based Chk1 activity sensor. During unperturbed growth, a basal Chk1 activity level is sustained throughout S phase and relies on replication origin firing. Incremental RS triggers stepwise Chk1 over-activation that delays S-phase, suggesting a rheostat-like role for DRC coupled with the replication machinery. Upon RS, Chk1 is inactivated as DNA replication terminates but surprisingly is reactivated in a subset of G2 cells, which relies on Cdk1/2 and Plk1 and prevents mitotic entry. Cells can override active Chk1 signaling and reach mitosis onset, revealing checkpoint adaptation. Cell division following Chk1 reactivation in G2 results in a p53/p21-dependent G1 arrest, eliminating the daughter cells from proliferation.