Proper positioning of the cleavage furrow requires α-actinin to regulate the specification of different populations of microtubules.

Proper positioning of the cleavage furrow is essential for successful cell division. The mitotic spindle, which consists of dynamic astral microtubules and stable equatorial microtubules is responsible for this process. However, little is known about how microtubules are regulated in a time- and region-dependent manner. Here, we show that α-actinin-regulated cortical actin filament integrity is crucial to specify different populations of microtubules during cell division in mammalian cells. Depletion of α-actinin caused aberrant recruitment of centralspindlin, but not aurora B or PRC1, to the tips of astral microtubules, leading to a stable association of astral microtubules with the cortex and induction of ectopic furrowing. Depletion of α-actinin also caused impaired assembly of midzone microtubules, leading to a failure of relocation of aurora B to midzone. Our findings unveil an unexpected yet crucial role for an actin crosslinking protein in the regulation of the localization of the microtubule-associated cytokinetic regulator.

The Nitrosopumilus maritimus CdvB, but not FtsZ, assembles into polymers.

Euryarchaeota and Crenarchaeota are two major phyla of archaea which use distinct molecular apparatuses for cell division. Euryarchaea make use of the tubulin-related protein FtsZ, while Crenarchaea, which appear to lack functional FtsZ, employ the Cdv (cell division) components to divide. Ammonia oxidizing archaeon (AOA) Nitrosopumilus maritimus belongs to another archaeal phylum, the Thaumarchaeota, which has both FtsZ and Cdv genes in the genome. Here, we used a heterologous expression system to characterize FtsZ and Cdv proteins from N. maritimus by investigating the ability of these proteins to form polymers. We show that one of the Cdv proteins in N. maritimus, the CdvB (Nmar_0816), is capable of forming stable polymers when expressed in fission yeast. The N. maritimus CdvB is also capable of assembling into filaments in mammalian cells. However, N. maritimus FtsZ does not assemble into polymers in our system. The ability of CdvB, but not FtsZ, to polymerize is consistent with a recent finding showing that several Cdv proteins, but not FtsZ, localize to the mid-cell site in the dividing N. maritimus. Thus, we propose that it is Cdv proteins, rather than FtsZ, that function as the cell division apparatus in N. maritimus.

Domain analysis of alpha-actinin reveals new aspects of its association with F-actin during cytokinesis.

alpha-Actinin is a rod-shaped actin cross-linking protein composed of actin binding domain, spectrin-like repeats of the central rod domain and the EF-hand domain. Cytokinesis in mammalian cells involves remodeling of equatorial actin filaments (F-actin) mediated by alpha-actinin. However, it remains unknown how alpha-actinin interacts with F-actin at the cleavage furrow. To address this question, we have conducted functional analysis of the mutant that either lacks the ability to cross-link F-actin (ABD) or to bind to F-actin (DeltaABD). We found that equatorial localization of alpha-actinin requires both its F-actin binding and cross-linking activities. Unexpectedly, we also found that overexpression of DeltaABD-GFP but not ABD-GFP frequently caused accelerated cytokinesis and ectopic furrowing similar to those observed in cells depleted of alpha-actinin. Immunofluorescence revealed that overexpression of DeltaABD-GFP caused displacement of endogenous alpha-actinin and a decrease in the density of F-actin throughout the entire cortex. Biochemical experiments showed that DeltaABD was able to form heterodimers with endogenous alpha-actinin. These results suggest that the central rod spectrin-like repeats of alpha-actinin is sufficient for its dimerization in vivo. Our findings uncover previously unappreciated functions of the alpha-actinin domains in a cell.

The Greatwall kinase safeguards the genome integrity by affecting the kinome activity in mitosis.

Progression through mitosis is balanced by the timely regulation of phosphorylation and dephosphorylation events ensuring the correct segregation of chromosomes before cytokinesis. This balance is regulated by the opposing actions of CDK1 and PP2A, as well as the Greatwall kinase/MASTL. MASTL is commonly overexpressed in cancer, which makes it a potential therapeutic anticancer target. Loss of Mastl induces multiple chromosomal errors that lead to the accumulation of micronuclei and multilobulated cells in mitosis. Our analyses revealed that loss of Mastl leads to chromosome breaks and abnormalities impairing correct segregation. Phospho-proteomic data for Mastl knockout cells revealed alterations in proteins implicated in multiple processes during mitosis including double-strand DNA damage repair. In silico prediction of the kinases with affected activity unveiled NEK2 to be regulated in the absence of Mastl. We uncovered that, RAD51AP1, involved in regulation of homologous recombination, is phosphorylated by NEK2 and CDK1 but also efficiently dephosphorylated by PP2A/B55. Our results suggest that MastlKO disturbs the equilibrium of the mitotic phosphoproteome that leads to the disruption of DNA damage repair and triggers an accumulation of chromosome breaks even in noncancerous cells.

CoA synthase regulates mitotic fidelity via CBP-mediated acetylation.

The temporal activation of kinases and timely ubiquitin-mediated degradation is central to faithful mitosis. Here we present evidence that acetylation controlled by Coenzyme A synthase (COASY) and acetyltransferase CBP constitutes a novel mechanism that ensures faithful mitosis. We found that COASY knockdown triggers prolonged mitosis and multinucleation. Acetylome analysis reveals that COASY inactivation leads to hyper-acetylation of proteins associated with mitosis, including CBP and an Aurora A kinase activator, TPX2. During early mitosis, a transient CBP-mediated TPX2 acetylation is associated with TPX2 accumulation and Aurora A activation. The recruitment of COASY inhibits CBP-mediated TPX2 acetylation, promoting TPX2 degradation for mitotic exit. Consistently, we detected a stage-specific COASY-CBP-TPX2 association during mitosis. Remarkably, pharmacological and genetic inactivation of CBP effectively rescued the mitotic defects caused by COASY knockdown. Together, our findings uncover a novel mitotic regulation wherein COASY and CBP coordinate an acetylation network to enforce productive mitosis.

The Tumor Suppressor Cdkn3 Is Required for Maintaining the Proper Number of Centrosomes by Regulating the Centrosomal Stability of Mps1.

Supernumerary centrosomes promote the assembly of abnormal spindles in many human cancers. The observation that modest changes in the centrosomal levels of Mps1 kinase can cause centrosome overduplication in human cells suggests the existence of a regulatory system that may tightly control its centrosomal stability. Here, we show that Cdkn3, a Cdk-associated phosphatase, prevents Mps1-mediated centrosome overduplication. We identify Cdkn3 as a direct binding partner of Mps1. The interaction between Mps1 and Cdkn3 is required for Mps1 to recruit Cdkn3 to centrosomes. Subsequently, Mps1-bound Cdkn3 forms a regulatory system that controls the centrosomal levels of Mps1 through proteasome-mediated degradation and thereby prevents Mps1-mediated centrosome overduplication. Conversely, knockdown of Cdkn3 stabilizes Mps1 at centrosomes, which promotes centrosome overduplication. We suggest that Mps1 and Cdkn3 form a self-regulated feedback loop at centrosomes to tightly control the centrosomal levels of Mps1, which prevents centrosome overduplication in human cells.