Late mitotic functions of Aurora kinases

The coordination between late mitotic events such as poleward chromosome motion, spindle elongation, DNA decondensation, and nuclear envelope reformation (NER) is crucial for the completion of chromosome segregation at the anaphase-telophase transition. Mitotic exit is driven by a decrease of Cdk1 kinase activity and an increase of PP1/PP2A phosphatase activities. More recently, Aurora kinases have also emerged as master regulators of late mitotic events and cytokinesis. Aurora A is mainly associated with spindle poles throughout mitosis and midbody during telophase, whereas Aurora B re-localizes from centromeres in early mitosis to the spindle midzone and midbody as cells progress from anaphase to the completion of cytokinesis. Functional studies, together with the identification of a phosphorylation gradient during anaphase, established Aurora B as a major player in the organization of the spindle midzone and in the spatiotemporal coordination between chromosome segregation and NER. Aurora A has been less explored, but a cooperative role in spindle midzone stability has also been proposed, implying that both Aurora A and B contribute to accurate chromosome segregation during mitotic exit. Here, we review the roles of the Aurora kinases in the regulation of late mitotic events and discuss how they work together with other mitotic players to ensure an error-free mitosis.     

Cdc14 and condensin control the dissolution of cohesin-independent chromosome linkages at repeated DNA

Chromosome segregation is triggered by the cleavage of cohesins by separase. Here we show that in budding yeast separation of the ribosomal DNA (rDNA) and telomeres also requires Cdc14, a protein phosphatase known for its role in mitotic exit. Cdc14 shares this role with the FEAR network, which activates Cdc14 during early anaphase, but not the mitotic exit network, which promotes Cdc14 activity during late anaphase. We further show that CDC14 is necessary and sufficient to promote condensin enrichment at the rDNA locus and to trigger rDNA segregation in a condensin-dependent manner. We propose that Cdc14 released by the FEAR network mediates the partitioning of rDNA by facilitating the localization of condensin thereto. This dual role of the FEAR network in initiating mitotic exit and promoting chromosome segregation ensures that exit from mitosis is coupled to the completion of chromosome segregation.     

MEN,destruction and separation: mechanistic links between mitotic exit and cytokinesis in budding yeast

Cellular events must be executed in a certain sequence during the cell division in order to maintain genome integrity and hence ensure a cell's survival. In M phase, for instance, chromosome segregation always precedes mitotic exit (characterized by mitotic kinase inactivation via cyclin destruction); this is then followed by cytokinesis. How do cells impose this strict order? Recent findings in budding yeast have suggested a mechanism whereby partitioning of chromosomes into the daughter cell is a prerequisite for the activation of mitotic exit network (MEN). So far, however, a regulatory scheme that would temporally link the initiation of cytokinesis to the execution of mitotic exit has not been determined. We propose that the requirement of MEN components for cytokinesis, their translocation to the mother–daughter neck and triggering of this translocation by inactivation of the mitotic kinase may be the three crucial elements that render initiation of cytokinesis dependent on mitotic exit. BioEssays 24: 659–666, 2002. © 2002 Wiley Periodicals, Inc.     

Coordinating cell polarity with cell division in space and time

Decisions of when and where to divide are crucial for cell survival and fate, and for tissue organization and homeostasis. The temporal coordination of mitotic events during cell division is essential to ensure that each daughter cell receives one copy of the genome. The spatial coordination of these events is also crucial because the cytokinetic furrow must be aligned with the axis of chromosome segregation and, in asymmetrically dividing cells, the polarity axis. Several recent papers describe how cell shape and polarity are coordinated with cell division in single cells and tissues and begin to unravel the underlying molecular mechanisms, revealing common principles and molecular players. Here, we discuss how cells regulate the spatial and temporal coordination of cell polarity with cell division.     

Nucleolar segregation lags behind the rest of the genome and requires Cdc14p activation by the FEAR network

In order to transmit a full genetic complement cells must ensure that all chromosomes are accurately split and distributed during anaphase. Chromosome XII in S. cerevisiae contains the site of nucleolar assembly, a 1-2Mb array of rDNA genes named RDN1. Cdc14p is a conserved phosphatase, essential for anaphase progression and mitotic exit, which is kept inactive at the nucleolus until mitosis. In early anaphase, the FEAR network (Cdc Fourteen Early Anaphase Release) promotes the transient and partial release of Cdc14p from the nucleolus. The putative role of Cdc14p released by the FEAR network is thought to be the stimulation of full Cdc14p release by activation of the GTPase-driven signaling cascade (the Mitotic Exit Network or MEN) that ensures mitotic exit. Here, we show that nucleolar segregation is spatially separated and temporally delayed from the rest of the genome. Nucleolar segregation occurs during mid-anaphase and coincides with the FEAR release of Cdc14p. Inactivation of FEAR delays nucleolar segregation until late anaphase, demonstrating that one function of the FEAR network is to promote segregation of repetitive nucleolar chromatin during mid-anaphase.     

Aberrant replication timing induces defective chromosome condensation in Drosophila ORC2 mutants

BACKGROUND: The accurate duplication and packaging of the genome is an absolute prerequisite to the segregation of chromosomes in mitosis. To understand the process of cell-cycle chromosome dynamics further, we have performed the first detailed characterization of a mutation affecting mitotic chromosome condensation in a metazoan. Our combined genetic and cytological approaches in Drosophila complement and extend existing work employing yeast genetics and Xenopus in vitro extract systems to characterize higher-order chromosome structure and function. RESULTS: Two alleles of the ORC2 gene were found to cause death late in larval development, with defects in cell-cycle progression (delays in S-phase entry and metaphase exit) and chromosome condensation in mitosis. During S-phase progression in wild-type cells, euchromatin replicates early and heterochromatin replicates late. Both alleles disrupted the normal pattern of chromosomal replication, with some euchromatic regions replicating even later than heterochromatin. Mitotic chromosomes were irregularly condensed, with the abnormally late replicating regions of euchromatin exhibiting the greatest problems in mitotic condensation. CONCLUSIONS: The results not only reveal novel functions for ORC2 in chromosome architecture in metazoans, they also suggest that the correct timing of DNA replication may be essential for the assembly of chromatin that is fully competent to undergo mitotic condensation.     

Dependence of Chs2 ER export on dephosphorylation by cytoplasmic Cdc14 ensures that septum formation follows mitosis

Cytokinesis, which leads to the physical separation of two dividing cells, is normally restrained until after nuclear division. In Saccharomyces cerevisiae, chitin synthase 2 (Chs2), which lays down the primary septum at the mother-daughter neck, also ensures proper actomyosin ring constriction during cytokinesis. During the metaphase-to-anaphase transition, phosphorylation of Chs2 by the mitotic cyclin-dependent kinase (Cdk1) retains Chs2 at the endoplasmic reticulum (ER), thereby preventing its translocation to the neck. Upon Cdk1 inactivation at the end of mitosis, Chs2 is exported from the ER and targeted to the neck. The mechanism for triggering Chs2 ER export thus far is unknown. We show here that Chs2 ER export requires the direct reversal of the inhibitory Cdk1 phosphorylation sites by Cdc14 phosphatase, the ultimate effector of the mitotic exit network (MEN). We further show that only Cdc14 liberated by the MEN after completion of chromosome segregation, and not Cdc14 released in early anaphase by the Cdc fourteen early anaphase release pathway, triggers Chs2 ER exit. Presumably, the reduced Cdk1 activity in late mitosis further favors dephosphorylation of Chs2 by Cdc14. Thus, by requiring declining Cdk1 activity and Cdc14 nuclear release for Chs2 ER export, cells ensure that septum formation is contingent upon chromosome separation and exit from mitosis.     

Basic mechanism of eukaryotic chromosome segregation

We now have firm evidence that the basic mechanism of chromosome segregation is similar among diverse eukaryotes as the same genes are employed. Even in prokaryotes, the very basic feature of chromosome segregation has similarities to that of eukaryotes. Many aspects of chromosome segregation are closely related to a cell cycle control that includes stage-specific protein modification and proteolysis. Destruction of mitotic cyclin and securin leads to mitotic exit and separase activation, respectively. Key players in chromosome segregation are SMC-containing cohesin and condensin, DNA topoisomerase II, APC/C ubiquitin ligase, securin-separase complex, aurora passengers, and kinetochore microtubule destabilizers or regulators. In addition, the formation of mitotic kinetochore and spindle apparatus is absolutely essential. The roles of principal players in basic chromosome segregation are discussed: most players have interphase as well as mitotic functions. A view on how the centromere/kinetochore is formed is described.     

Mutual Dependence of Mob1 and the Chromosomal Passenger Complex for Localization during Mitosis

The spatial and temporal coordination of chromosome segregation with cytokinesis is essential to ensure that each daughter cell receives the correct complement of chromosomal and cytoplasmic material. In yeast, mitotic exit and cytokinesis are coordinated by signaling cascades whose terminal components include a nuclear Dbf2-related family kinase and a noncatalytic subunit, Mps one binding (Mob) 1. There are five human Mob1 isoforms, all of which display redundant localization patterns at the spindle poles and kinetochores in early mitosis, and the spindle midzone during cytokinesis. Mob1 shares similar localization patterns to Polo-like kinase (Plk1) and the chromosomal passenger complex (CPC), and although depletion of Plk1 resulted in a loss of Mob1 from the spindle poles, Mob1 recruitment to kinetochores was unaffected. Conversely, disruption of CPC signaling resulted in a loss of Mob1 from kinetochores without disrupting recruitment to the spindle poles. In Mob1-depleted cells, the relocalization of the CPC and mitotic kinesin-like protein (MKLP) 2 to the spindle midzone was delayed during early anaphase, and as a consequence, the midzone recruitment of MKLP1 also was affected. Together, these results suggest that Mob1 and the other mammalian orthologues of the mitotic exit network regulate mitotic progression by facilitating the timely mobilization of the CPC to the spindle midzone.     

Phosphatases: providing safe passage through mitotic exit

The mitosis-to-interphase transition involves dramatic cellular reorganization from a state that supports chromosome segregation to a state that complies with all functions of an interphase cell. This process, termed mitotic exit, depends on the removal of mitotic phosphorylations from a broad range of substrates. Mitotic exit regulation involves inactivation of mitotic kinases and activation of counteracting protein phosphatases. The key mitotic exit phosphatase in budding yeast, Cdc14, is now well understood. By contrast, in animal cells, it is now emerging that mitotic exit relies on distinct regulatory networks, including the protein phosphatases PP1 and PP2A.     

Incomplete sister chromatid separation of long chromosome arms

Chromosome segregation ensures the equal partitioning of chromosomes at mitosis. However, long chromosome arms may pose a problem for complete sister chromatid separation. In this paper we report on the analysis of cell division in primary cells from field vole Microtus agrestis, a species with 52 chromosomes including two giant sex chromosomes. Dual chromosome painting with probes specific for the X and the Y chromosomes showed that these long chromosomes are prone to mis-segregate, producing DNA bridges between daughter nuclei and micronuclei. Analysis of mitotic cells with incomplete chromatid separation showed that reassembly of the nuclear membrane, deposition of INner CENtromere Protein (INCENP)/Aurora B to the spindle midzone and furrow formation occur while the two groups of daughter chromosomes are still connected by sex chromosome arms. Late cytokinetic processes are not efficiently inhibited by the incomplete segregation as in a significant number of cell divisions cytoplasmic abscission proceeds while Aurora B is at the midbody. Live-cell imaging during late mitotic stages also revealed abnormal cell division with persistent sister chromatid connections. We conclude that late mitotic regulatory events do not monitor incomplete sister chromatid separation of the large X and Y chromosomes of Microtus agrestis, leading to defective segregation of these chromosomes. These findings suggest a limit in chromosome arm length for efficient chromosome transmission through mitosis.Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.     

The role of Cdh1p in maintaining genomic stability in budding yeast

Cdh1p, a substrate specificity factor for the cell cycle-regulated ubiquitin ligase, the anaphase-promoting complex/cyclosome (APC/C), promotes exit from mitosis by directing the degradation of a number of proteins, including the mitotic cyclins. Here we present evidence that Cdh1p activity at the M/G(1) transition is important not only for mitotic exit but also for high-fidelity chromosome segregation in the subsequent cell cycle. CDH1 showed genetic interactions with MAD2 and PDS1, genes encoding components of the mitotic spindle assembly checkpoint that acts at metaphase to prevent premature chromosome segregation. Unlike cdh1delta and mad2delta single mutants, the mad2delta cdh1delta double mutant grew slowly and exhibited high rates of chromosome and plasmid loss. Simultaneous deletion of PDS1 and CDH1 caused extensive chromosome missegregation and cell death. Our data suggest that at least part of the chromosome loss can be attributed to kinetochore/spindle problems. Our data further suggest that Cdh1p and Sic1p, a Cdc28p/Clb inhibitor, have overlapping as well as nonoverlapping roles in ensuring proper chromosome segregation. The severe growth defects of both mad2delta cdh1delta and pds1delta cdh1dDelta strains were rescued by overexpressing Swe1p, a G(2)/M inhibitor of the cyclin-dependent kinase, Cdc28p/Clb. We propose that the failure to degrade cyclins at the end of mitosis leaves cdh1delta mutant strains with abnormal Cdc28p/Clb activity that interferes with proper chromosome segregation.     

A non-proteolytic function of separase links the onset of anaphase to mitotic exit

Separase is a protease that triggers chromosome segregation at anaphase onset by cleaving cohesin, the chromosomal protein complex responsible for sister chromatid cohesion. After anaphase, cells exit from mitosis; that is, they complete downregulation of cyclin-dependent kinase activity, undergo cytokinesis and enter G1 of the next cell cycle. Here we show that separase activation at the onset of anaphase is sufficient to promote release from the nucleolus and activation of the budding yeast phosphatase, Cdc14, a key step in mitotic exit. The ability of separase to activate Cdc14 is independent of its protease function but may involve promoting phosphorylation of the Cdc14 inhibitor Net1. This novel separase function is coregulated with its proteolytic activity by the separase inhibitor securin. This helps to explain the coupling of anaphase and mitotic exit--after securin degradation at anaphase onset, separase cleaves cohesin to trigger chromosome segregation and concurrently uses a non-proteolytic mechanism to initiate mitotic exit.     

Nucleolar Segregation Lags Behind the Rest of the Genome and Requires Cdc14p Activation by the FEAR Network

In order to transmit a full genetic complement cells must ensure that all chromosomes are accurately split and distributed during anaphase. Chromosome XII in S. cerevisiae contains the site of nucleolar assembly, a 1-2Mb array of rDNA genes named RDN1. Cdc14p is a conserved phosphatase, essential for anaphase progression and mitotic exit, which is kept inactive at the nucleolus until mitosis. In early anaphase, the FEAR network (Cdc Fourteen Early Anaphase Release) promotes the transient and partial release of Cdc14p from the nucleolus. The putative role of Cdc14p released by the FEAR network is thought to be the stimulation of full Cdc14p release by activation of the GTPase-driven signalling cascade (the Mitotic Exit Network or MEN) that ensures mitotic exit. Here, we show that nucleolar segregation is spatially separated and temporally delayed from the rest of the genome. Nucleolar segregation occurs during mid-anaphase and coincides with the FEAR release of Cdc14p. Inactivation of FEAR delays nucleolar segregation until late anaphase, demonstrating that one function of the FEAR network is to promote segregation of repetitive nucleolar chromatin during mid-anaphase.

Links to supplemental material:

http://www.landesbioscience.com/supplement/aragonCC3-4-sup.pdf

http://www.landesbioscience.com/supplement/aragonCC3-4-supmov.mov     

The spindle position checkpoint in budding yeast: the motherly care of MEN

ABSTRACT : Mitotic exit and cytokinesis must be tightly coupled to nuclear division both in time and space in order to preserve genome stability and to ensure that daughter cells inherit the right set of chromosomes after cell division. This is achieved in budding yeast through control over a signal transduction cascade, the mitotic exit network (MEN), which is required for mitotic CDK inactivation in telophase and for cytokinesis. Current models of MEN activation emphasize on the bud as the place where most control is exerted. This review focuses on recent data that instead point to the mother cell as being the residence of key regulators of late mitotic events.     

Caenorhabditis elegans TLK-1 controls cytokinesis by localizing AIR-2/Aurora B to midzone microtubules

Defects in chromosome condensation, segregation or cytokinesis during mitosis disrupt genome integrity and cause organismal death or tumorigenesis. The conserved kinase AIR-2/Aurora B is required for normal execution of all these important mitotic events in Caenorhabditis elegans. TLK-1 has been recently shown to be a substrate and activator of AIR-2 in the presence of another AIR-2 activator ICP-1/INCENP, and to cooperate with AIR-2 to ensure proper mitotic chromosome segregation. However, whether TLK-1 may contribute to chromosome condensation or cytokinesis is unclear. A time-lapse microscopy analysis showed that tlk-1 mutants are defective in chromosome condensation and cytokinesis, in addition to chromosome segregation, during mitosis. Our data indicate that TLK-1 contributes to chromosome condensation and segregation, at least in part, in a manner that is distinct from the ICP-1-mediated mechanism and does not involve loading AIR-2 or condensin proteins to mitotic chromosomes. Moreover, TLK-1 functions in cytokinesis by localizing AIR-2 to the midzone microtubules. The localization pattern of TLK-1 is different from those of ICP-1 and AIR-2, revealing differences in dynamic regulation and association of TLK-1 and ICP-1 towards AIR-2 in vivo. Interestingly, human TLK2 could functionally substitute for tlk-1, suggesting that the mitotic roles of TLK members might be evolutionarily conserved.     

The degradation of two mitotic cyclins contributes to the timing of cytokinesis

BACKGROUND: Cytokinesis occurs just as chromosomes complete segregation and reform nuclei. It has been proposed that cyclin/Cdk kinase inhibits cytokinesis until exit from mitosis; however, the timer of cytokinesis has not been experimentally defined. Whereas expression of a stable version of Drosophila cyclin B blocks cytokinesis along with numerous events of mitotic exit, stable cyclin B3 allows cytokinesis even though it blocks late events of mitotic exit. We examined the interface between mitotic cyclin destruction and the timing of cytokinesis. RESULTS: In embryonic mitosis 14, the cytokinesis furrow appeared 60 s after the metaphase/anaphase transition and closed 90 s later during telophase. In cyclin B or cyclin B3 mutant cells, the cytokinesis furrow appeared at an earlier stage of mitosis. Expression of stable cyclin B3 delayed and prolonged furrow invagination; nonetheless, cytokinesis completed during the extended mitosis. Reduced function of Pebble, a Rho GEF required for cytokinesis, also delayed and slowed furrow invagination, but incomplete furrows were aborted at the time of mitotic exit. In functional and genetic tests, cyclin B and cyclin B3 inhibited Pebble contributions to cytokinesis. CONCLUSIONS: Temporal coordination of mitotic events involves inhibition of cytokinesis by cyclin B and cyclin B3 and punctual relief of the inhibition by destruction of these cyclins. Both cyclins inhibit Pebble-dependent activation of cytokinesis, whereas cyclin B can inhibit cytokinesis by additional modes. Stable cyclin B3 also blocks the later return to interphase that otherwise appears to impose a deadline for the completion of cytokinesis.     

Aberrant replication timing induces defective chromosome condensation in Drosophila ORC2 mutants

Background: The accurate duplication and packaging of the genome is an absolute prerequisite to the segregation of chromosomes in mitosis. To understand the process of cell-cycle chromosome dynamics further, we have performed the first detailed characterization of a mutation affecting mitotic chromosome condensation in a metazoan. Our combined genetic and cytological approaches in Drosophila complement and extend existing work employing yeast genetics and Xenopus in vitro extract systems to characterize higher-order chromosome structure and function.Results: Two alleles of the ORC2 gene were found to cause death late in larval development, with defects in cell-cycle progression (delays in S-phase entry and metaphase exit) and chromosome condensation in mitosis. During S-phase progression in wild-type cells, euchromatin replicates early and heterochromatin replicates late. Both alleles disrupted the normal pattern of chromosomal replication, with some euchromatic regions replicating even later than heterochromatin. Mitotic chromosomes were irregularly condensed, with the abnormally late replicating regions of euchromatin exhibiting the greatest problems in mitotic condensation.Conclusions: The results not only reveal novel functions for ORC2 in chromosome architecture in metazoans, they also suggest that the correct timing of DNA replication may be essential for the assembly of chromatin that is fully competent to undergo mitotic condensation.     

Long-Tract Mitotic Gene Conversion in Yeast: Evidence for a Triparental Contribution during Spontaneous Recombination

In Saccharomyces cerevisiae, spontaneous mitotic gene conversion at one site is statistically correlated with recombination at other loci. In general, coincident conversion frequencies are highest for tightly linked markers and decline as a function of intermarker distance. Paradoxically, a significant fraction of mitotic gene convertants exhibits concomitant nonreciprocal segregation for multiple and widely spaced markers. We have undertaken a detailed genetic analysis of this class of mitotic recombinants. Our results indicate that mitotic gene conversion in yeast is frequently associated with nonreciprocal segregation of markers centromere-distal to the selected site of conversion. In addition, distal markers are often found to be mosaic within the product colonies. These observations, and others described here, suggest that a percentage of gene conversion in vegetative yeast cells is coupled to a chromosome break and repair mechanism. This hypothesis was further tested using a strain trisomic for chromosome VII which was specially marked to detect homolog-dependent repair events. An association between mitotic gene conversion events and the production of broken chromosomes which are repaired by a homologous-pairing-copy mechanism was supported.