Separation Of Sister Chromatids In Anaphase Research Articles

PP 2A delays APC /C‐dependent degradation of separase‐associated but not free securin

The universal triggering event of eukaryotic chromosome segregation is cleavage of centromeric cohesin by separase. Prior to anaphase, most separase is kept inactive by association with securin. Protein phosphatase 2A (PP2A) constitutes another binding partner of human separase, but the functional relevance of this interaction has remained enigmatic. We demonstrate that PP2A stabilizes separase-associated securin by dephosphorylation, while phosphorylation of free securin enhances its polyubiquitylation by the ubiquitin ligase APC/C and proteasomal degradation. Changing PP2A substrate phosphorylation sites to alanines slows degradation of free securin, delays separase activation, lengthens early anaphase, and results in anaphase bridges and DNA damage. In contrast, separase-associated securin is destabilized by introduction of phosphorylation-mimetic aspartates or extinction of separase-associated PP2A activity. G2- or prometaphase-arrested cells suffer from unscheduled activation of separase when endogenous securin is replaced by aspartate-mutant securin. Thus, PP2A-dependent stabilization of separase-associated securin prevents precocious activation of separase during checkpoint-mediated arrests with basal APC/C activity and increases the abruptness and fidelity of sister chromatid separation in anaphase.

Analysis of SUMOylation of topoisomerase IIalpha with Xenopus egg extracts.

Posttranslational protein modification by the Small Ubiquitin-like MOdifiers (SUMO) is involved in many cellular functions including organization of nuclear structures and chromatin, transcriptional regulation, and nucleo-cytoplasmic transport. Both genetic and biochemical studies indicate that the SUMO modification pathway plays an important role in proper cell cycle control, especially in the normal progression of mitosis. DNA topoisomerase II has been shown to be modified by SUMO in budding yeast as well as in vertebrates. We have shown by biochemical analysis using the Xenopus egg extract (XEE) cell-free assay system that DNA topoisomerase IIalpha (Topo IIalpha) is modified by SUMO-2/3 on mitotic chromosomes in the early stages of mitosis. Inhibition of mitotic SUMOylation in the XEE assay system causes aberrant sister chromatid separation in anaphase and alters Topo IIalpha association with chromosomes.

Nuclear Exclusion of Separase Prevents Cohesin Cleavage in Interphase Cells

During mitosis, equal transmission of the duplicated chromosomes demands a strict regulation of separase, which cleaves cohesin and triggers sister chromatid separation in anaphase. Vertebrate separase is inhibited by securin and the inhibitory phosphorylation of separase. However, knockout experiments indicate that securin is dispensable and the inhibitory phosphorylation was observed only in M phase cells. This begs the question how cohesin cleavage by separase is prevented in the absence these two mechanisms. Here we show that separase is excluded from cohesin by the nuclear envelope, which forms in telophase and disassembles in mitosis. The exclusion is achieved passively by its large physical mass and may be backed up by the CRM1-dependent nuclear export. A functional NES motif is identified in separase. We demonstrated that the nuclear envelope is sufficient to prevent active separase from cleaving nuclear cohesin. We propose that the nuclear exclusion is important to prevent cohesin cleavage during interphase in the absence of securin and the phosphorylation inhibition.

Nek2A kinase regulates the localization of numatrin to centrosome in mitosis

Chromosome segregation in mitosis is orchestrated by the kinetochore and spindle microtubules stemming from two centrosomes. Our recent studies demonstrated the importance of Nek2A in faithful chromosome segregation during mitosis. Here, we report that Nek2A regulates the function of numatrin in mitosis. The biochemical interaction between Nek2A and numatrin in mitotic cells was revealed by a set of reciprocal immunoprecipitation experiments using Nek2A and numatrin antibodies, respectively. The interaction is validated by a pull-down assay using recombinant Nek2A and numatrin proteins. Moreover, our immunofluorescence studies demonstrate that numatrin becomes centrosome-associated as the cell enters into mitosis and depart from the centrosome after sister chromatid separation in anaphase. The co-localization of numatrin and Nek2A to the centrosome suggests their interaction with and involvement in centrosome function. Indeed, elimination of Nek2A kinase by siRNA diminished its association with the centrosome. Furthermore, we show that numatrin is phosphorylated by wild type but not kinase-death Nek2A. Our studies suggest that the Nek2A kinase cascade is essential for the localization of numatrin to the centrosome.

Regulation of Sister Chromatid Cohesion between Chromosome Arms

Sister chromatid separation in anaphase depends on the removal of cohesin complexes from chromosomes [1]. In vertebrates, the bulk of cohesin is already removed from chromosome arms during prophase and prometaphase [2, 3], whereas cohesin remains at centromeres until metaphase, when cohesin is cleaved by the protease separase [3, 4]. In unperturbed mitoses, arm cohesion nevertheless persists throughout metaphase and is principally sufficient to maintain sister chromatid cohesion [5]. How arm cohesion is maintained until metaphase is unknown. Here we show that small amounts of cohesin can be detected in the interchromatid region of metaphase chromosome arms. If prometaphase is prolonged by treatment of cells with microtubule poisons, these cohesin complexes dissociate from chromosome arms, and arm cohesion is dissolved. If cohesin dissociation in prometaphase-arrested cells is prevented by depletion of Plk1 or inhibition of Aurora B, arm cohesion is maintained. These observations imply that, in unperturbed mitoses, small amounts of cohesin maintain arm cohesion until metaphase. When cells lacking Plk1 and Aurora B activity enter anaphase, chromatids lose cohesin. This loss is prevented by proteasome inhibitors, implying that it depends on separase activation. Separase may therefore be able to cleave cohesin at centromeres and on chromosome arms.

Cohesin release is required for sister chromatid resolution, but not for condensin-mediated compaction, at the onset of mitosis.

The establishment of metaphase chromosomes is an essential prerequisite of sister chromatid separation in anaphase. It involves the coordinated action of cohesin and condensin, protein complexes that mediate cohesion and condensation, respectively. In metazoans, most cohesin dissociates from chromatin at prophase, coincident with association of condensin. Whether loosening of cohesion at the onset of mitosis facilitates the compaction process, resolution of the sister chromatids, or both, remains unknown. We have found that the prophase release of cohesin is completely blocked when two mitotic kinases, aurora B and polo-like kinase (Plx1), are simultaneously depleted from Xenopus egg extracts. Condensin loading onto chromatin is not affected under this condition, and rod-shaped chromosomes are produced that show an apparently normal level of compaction. However, the resolution of sister chromatids within these chromosomes is severely compromised. This is not because of inhibition of topoisomerase II activity that is also required for the resolution process. We propose that aurora B and Plx1 cooperate to destabilize the sister chromatid linkage through distinct mechanisms that may involve phosphorylation of histone H3 and cohesin, respectively. More importantly, our results strongly suggest that cohesin release at the onset of mitosis is essential for sister chromatid resolution but not for condensin-mediated compaction.

Chfr defines a mitotic stress checkpoint that delays entry into metaphase.

Chemicals that target microtubules induce mitotic stress by affecting several processes that occur during mitosis. These processes include separation of the centrosomes in prophase, alignment of the chromosomes on the spindle in metaphase and sister-chromatid separation in anaphase. Many human cancers are sensitive to mitotic stress. This sensitivity is being exploited for therapy and implies checkpoint defects. The known mitotic checkpoint genes, which prevent entry into anaphase when the chromosomes are not properly aligned on the mitotic spindle, are, however, rarely inactivated in human cancer. Here we describe the chfr gene, which is inactivated owing to lack of expression or by mutation in four out of eight human cancer cell lines examined. Normal primary cells and tumour cell lines that express wild-type chfr exhibited delayed entry into metaphase when centrosome separation was inhibited by mitotic stress. In contrast, the tumour cell lines that had lost chfr function entered metaphase without delay. Ectopic expression of wild-type chfr restored the cell cycle delay and increased the ability of the cells to survive mitotic stress. Thus, chfr defines a checkpoint that delays entry into metaphase in response to mitotic stress.

Control of metaphase-anaphase progression by proteolysis: cyclosome function regulated by the protein kinase A pathway, ubiquitination and localization.

Ubiquitin-mediated proteolysis is fundamental to cell cycle progression. In the fission yeast Schizosaccharomyces pombe, a mitotic cyclin (Cdc13), a key cell cycle regulator, is degraded for exiting mitosis, while Cut2 has to be destroyed for the onset of sister chromatid separation in anaphase. Ubiquitination of these proteins requires the special destruction box (DB) sequences locating in their N-termini and the large, 20S complex called the anaphase-promoting complex or cyclosome. Here we show that cyclosome function during metaphase-anaphase progression is regulated by the protein kinase A (PKA) inactivation pathway, ubiquitination of the cyclosome subunit, and cellular localization of the target substrates. Evidence is provided that the cyclosome plays pleiotropic roles in the cell cycle: mutations in the subunit genes show a common anaphase defect, but subunit-specific phenotypes such as in G1/S or G2/M transition, septation and cytokinesis, stress response and heavy metal sensitivity, are additionally produced, suggesting that different subunits take distinct parts of complex cyclosome functions. Inactivation of PKA is important for the activation of the cyclosome for promoting anaphase, perhaps through dephosphorylation of the subunits such as Cut9 (Apc6). Cut4 (Apc1), the largest subunit, plays an essential role in the assembly and functional regulation of the cyclosome in response to cell cycle arrest and stresses. Cut4 is highly modified, probably by ubiquitination, when it is not assembled into the 20S cyclosome. Sds23 is implicated in DB-mediated ubiquitination possibly through regulating de-ubiquitination, while Cut8 is necessary for efficient proteolysis of Cdc13 and Cut2 coupled with cytokinesis. Unexpectedly, the timing of proteolysis is dependent on cellular localization of the substrate. Cdc13 enriched along the spindle disappears first, followed by decay of the nuclear signal, whereas Cut2 in the nucleus disappears first, followed by decline in the spindle signal during metaphase-anaphase progression.

Faithful anaphase is ensured by Mis4, a sister chromatid cohesion molecule required in S phase and not destroyed in G1 phase.

The loss of sister chromatid cohesion triggers anaphase spindle movement. The budding yeast Mcd1/Scc1 protein, called cohesin, is required for associating chromatids, and proteins homologous to it exist in a variety of eukaryotes. Mcd1/Scc1 is removed from chromosomes in anaphase and degrades in G1. We show that the fission yeast protein, Mis4, which is required for equal sister chromatid separation in anaphase is a different chromatid cohesion molecule that behaves independent of cohesin and is conserved from yeast to human. Its inactivation in G1 results in cell lethality in S phase and subsequent premature sister chromatid separation. Inactivation in G2 leads to cell death in subsequent metaphase-anaphase progression but missegregation occurs only in the next round of mitosis. Mis4 is not essential for condensation, nor does it degrade in G1. Rather, it associates with chromosomes in a punctate fashion throughout the cell cycle. mis4 mutants are hypersensitive to hydroxyurea (HU) and UV irradiation but retain the ability to restrain cell cycle progression when damaged or sustaining a block to replication. The mis4 mutation results in synthetic lethality with a DNA ligase mutant. Mis4 may form a stable link between chromatids in S phase that is split rather than removed in anaphase.

Frontier questions about sister chromatid separation in anaphase

Sister chromatid separation in anaphase is an important event in the cell's transmission of genetic information to a descendent. It has been investigated from different aspects: cell cycle regulation, spindle and chromosome dynamics within the three-dimensional cell architecture, transmission fidelity control and cellular signaling. Integrated studies directed toward unified understanding are possible using multidisciplinary methods with model organisms. Ubiquitin-dependent proteolysis, protein dephosphorylation, an unknown function by the TPR repeat proteins, chromosome transport by microtubule-based motors and DNA topological change by DNA topoisomerase II are all necessary for progression from metaphase to anaphase. Chromosome condensation, mitotic kinetochore function and spindle formation require a larger number of proteins, which are prerequisites for successful sister chromatid separation. Factors that help to retain sister chromatid connection after replication and prevent premature separation remain to be determined. Although sister chromatid separation occurs in anaphase, gene functions in other cell cycle stages also ensure the progression of correct chromatid separation.

The self-destructive personality of a cell cycle in transition

The transition from G 1 to S phase, sister chromatid separation in anaphase, and the exit from mitosis are driven by the destruction of cell cycle regulatory proteins by distinct ubiquitin-dependent proteolytic pathways. The components and targets of these key degradation pathways are now becoming clear. Genetic and biochemical dissections of these extremely specific and well regulated destruction pathways are providing fundamental insights into the mechanisms of control of the cell division cycle.