Diverse functions of spindle assembly checkpoint genes in Saccharomyces cerevisiae

The spindle assembly checkpoint regulates the metaphase-to-anaphase transition from yeast to humans. We examined the genetic interactions with four spindle assembly checkpoint genes to identify nonessential genes involved in chromosome segregation, to identify the individual roles of the spindle assembly checkpoint genes within the checkpoint, and to reveal potential complexity that may exist. We used synthetic genetic array (SGA) analysis using spindle assembly checkpoint mutants mad1, mad2, mad3, and bub3. We found 228 synthetic interactions with the four spindle assembly checkpoint mutants with substantial overlap in the spectrum of interactions between mad1, mad2, and bub3. In contrast, there were many synthetic interactions that were common to mad1, mad2, and bub3 that were not shared by mad3. We found shared interactions between pairs of spindle assembly checkpoint mutants, suggesting additional complexity within the checkpoint and unique interactions for all of the spindle assembly checkpoint genes. We show that most genes in the interaction network, including ones with unique interactions, affect chromosome transmission or microtubule function, suggesting that the complexity of interactions reflects diverse roles for the checkpoint genes within the checkpoint. Our analysis expands our understanding of the spindle assembly checkpoint and identifies new candidate genes with possible roles in chromosome transmission and mitotic spindle function.     

Evolution and function of the mitotic checkpoint

The mitotic checkpoint evolved to prevent cell division when chromosomes have not established connections with the chromosome segregation machinery. Many of the fundamental molecular principles that underlie the checkpoint, its spatiotemporal activation, and its timely inactivation have been uncovered. Most of these are conserved in eukaryotes, but important differences between species exist. Here we review current concepts of mitotic checkpoint activation and silencing. Guided by studies in model organisms and our phylogenomics analysis of checkpoint constituents and their functional domains and motifs, we highlight ancient and taxa-specific aspects of the core checkpoint modules in the context of mitotic checkpoint function.     

Spindle checkpoint protein Bub1 is required for kinetochore localization of Mad1, Mad2, Bub3, and CENP-E, independently of its kinase activity

The spindle checkpoint inhibits the metaphase to anaphase transition until all the chromosomes are properly attached to the mitotic spindle. We have isolated a Xenopus homologue of the spindle checkpoint component Bub1, and investigated its role in the spindle checkpoint in Xenopus egg extracts. Antibodies raised against Bub1 recognize a 150-kD phosphoprotein at both interphase and mitosis, but the molecular mass is reduced to 140 upon dephosphorylation in vitro. Bub1 is essential for the establishment and maintenance of the checkpoint and is localized to kinetochores, similar to the spindle checkpoint complex Mad1-Mad2. However, Bub1 differs from Mad1-Mad2 in that Bub1 remains on kinetochores that have attached to microtubules; the protein eventually dissociates from the kinetochore during anaphase. Immunodepletion of Bub1 abolishes the spindle checkpoint and the kinetochore binding of the checkpoint proteins Mad1, Mad2, Bub3, and CENP-E. Interestingly, reintroducing either wild-type or kinase-deficient Bub1 protein restores the checkpoint and the kinetochore localization of these proteins. Our studies demonstrate that Bub1 plays a central role in triggering the spindle checkpoint signal from the kinetochore, and that its kinase activity is not necessary for the spindle checkpoint in Xenopus egg extracts.     

Recruitment of Mad1 to metaphase kinetochores is sufficient to reactivate the mitotic checkpoint

The mitotic checkpoint monitors kinetochore–microtubule attachment and prevents anaphase until all kinetochores are stably attached. Checkpoint regulation hinges on the dynamic localization of checkpoint proteins to kinetochores. Unattached, checkpoint-active kinetochores accumulate multiple checkpoint proteins, which are depleted from kinetochores upon stable attachment, allowing checkpoint silencing. Because multiple proteins are recruited simultaneously to unattached kinetochores, it is not known what changes at kinetochores are essential for anaphase promoting complex/cyclosome (APC/C) inhibition. Using chemically induced dimerization to manipulate protein localization with temporal control, we show that recruiting the checkpoint protein Mad1 to metaphase kinetochores is sufficient to reactivate the checkpoint without a concomitant increase in kinetochore levels of Mps1 or BubR1. Furthermore, Mad2 binding is necessary but not sufficient for Mad1 to activate the checkpoint; a conserved C-terminal motif is also required. The results of our checkpoint reactivation assay suggest that Mad1, in addition to converting Mad2 to its active conformation, scaffolds formation of a higher-order mitotic checkpoint complex at kinetochores.     

Checkpoints controlling mitosis

Each year many reviews deal with checkpoint control.((1-5)) Here we discuss checkpoint pathways that control mitosis. We address four checkpoint systems in depth: budding yeast DNA damage, the DNA replication checkpoint, the spindle assembly checkpoint and the mammalian G2 topoisomerase II-dependent checkpoint. A main focus of the review is the organization of these checkpoint pathways. Recent work has elucidated the order-of-function of several checkpoint components, and has revealed that the S phase, DNA damage and spindle assembly checkpoints each have at least two parallel branches. These steps forward have largely come from kinetic studies of checkpoint-defective mutants.     

Dual inhibition of Cdc20 by the spindle checkpoint

The metaphase-to-anaphase transition is triggered by the Anaphase-Promoting Complex (APC), an E3 ubiquitin ligase that targets proteins for degradation, leading to sister chromatid separation and mitotic exit. The function of APC is controlled by the spindle checkpoint that delays anaphase onset in the presence of any chromosome that has not established bipolar attachment to the mitotic spindle. In this way, the checkpoint ensures accurate chromosome segregation. The spindle checkpoint is mostly activated from kinetochores that are not attached to microtubules or not under tension that is normally generated from bipolar attachment. These kinetochores recruit several spindle checkpoint proteins to assemble an inhibitory complex composed of checkpoint proteins Mad2, Bub3, and Mad3/BubR1. This complex binds and inhibits Cdc20, an activator and substrate adaptor for APC. In addition, the checkpoint complex promotes Cdc20 degradation, thus lowering Cdc20 protein level upon checkpoint activation. This dual inhibition on Cdc20 likely ensures that the spindle checkpoint is sustained even when the cell contains only a single unattached kinetochore.     

Colocalization of sensors is sufficient to activate the DNA damage checkpoint in the absence of damage

Previous work on the DNA damage checkpoint in Saccharomyces cerevisiae has shown that two complexes independently sense DNA lesions: the kinase Mec1-Ddc2 and the PCNA-like 9-1-1 complex. To test whether colocalization of these components is sufficient for checkpoint activation, we fused these checkpoint proteins to the LacI repressor and artificially colocalized these fusions by expressing them in cells harboring Lac operator arrays. We observed Rad53 and Rad9 phosphorylation, Sml1 degradation, and metaphase delay, demonstrating that colocalization of these sensors is sufficient to activate the checkpoint in the absence of DNA damage. Our tethering system allowed us to establish that CDK functions in the checkpoint pathway downstream of damage processing and checkpoint protein recruitment. This CDK dependence is likely, at least in part, through Rad9, since mutation of CDK consensus sites compromised its checkpoint function.     

An Imperfect G2M Checkpoint Contributes to Chromosome Instability Following Irradiation of S and G2 Phase Cells

DNA double strand break (DSB) repair and checkpoint control represent two major mechanisms that function to reduce chromosomal instability following ionising irradiation (IR). Ataxia telangiectasia (A-T) cells have long been known to have defective checkpoint responses. Recent studies have shown that they also have a DSB repair defect following IR raising the issue of how ATM’s repair and checkpoint functions interplay to maintain chromosomal stability. A-T and Artemis cells manifest an identical and epistatic repair defect throughout the cell cycle demonstrating that ATM’s major repair defect following IR represents Artemis-dependent end-processing. Artemis cells show efficient G2/M checkpoint induction and a prolonged arrest relative to normal cells. Following irradiation of G2 cells, this checkpoint is dependent on ATM and A-T cells fail to show checkpoint arrest. In contrast, cells irradiated during S phase initiate a G2/M checkpoint which is independent of ATM and, significantly, both Artemis and A-T cells show a prolonged arrest at the G2/M checkpoint likely reflecting their repair defect. Strikingly, the G2/M checkpoint is released before the completion of repair when approximately 10-20 DSBs remain both for S phase and G2 phase irradiated cells. This defined sensitivity level of the G2/M checkpoint explains the prolonged arrest in repair-deficient relative to normal cells and provides a conceptual framework for the co-operative phenotype between checkpoint and repair functions in maintaining chromosomal stability.     

Spindle assembly checkpoint: the third decade

The spindle assembly checkpoint controls cell cycle progression during mitosis, synchronizing it with the attachment of chromosomes to spindle microtubules. After the discovery of the mitotic arrest deficient (MAD) and budding uninhibited by benzymidazole (BUB) genes as crucial checkpoint components in 1991, the second decade of checkpoint studies (2001-2010) witnessed crucial advances in the elucidation of the mechanism through which the checkpoint effector, the mitotic checkpoint complex, targets the anaphase-promoting complex (APC/C) to prevent progression into anaphase. Concomitantly, the discovery that the Ndc80 complex and other components of the microtubule-binding interface of kinetochores are essential for the checkpoint response finally asserted that kinetochores are crucial for the checkpoint response. Nevertheless, the relationship between kinetochores and checkpoint control remains poorly understood. Crucial advances in this area in the third decade of checkpoint studies (2011-2020) are likely to be brought about by the characterization of the mechanism of kinetochore recruitment, activation and inactivation of checkpoint proteins, which remains elusive for the majority of checkpoint components. Here, we take a molecular view on the main challenges hampering this task.     

Association of MAD2 expression with mitotic checkpoint competence in hepatoma cells

Chromosomal instability (CIN) refers to high rates of chromosomal gains and losses and is a major cause of genomic instability of cells. It is thought that CIN caused by loss of mitotic checkpoint contributes to carcinogenesis. In this study, we evaluated the competence of mitotic checkpoint in hepatoma cells and investigated the cause of mitotic checkpoint defects. We found that 6 (54.5%) of the 11 hepatoma cell lines were defective in mitotic checkpoint control as monitored by mitotic indices and flow-cytometric analysis after treatment with microtubule toxins. Interestingly, all 6 hepatoma cell lines with defective mitotic checkpoint showed significant underexpression of mitotic arrest deficient 2 (MAD2), a key mitotic checkpoint protein. The level of MAD2 underexpression was significantly associated with defective mitotic checkpoint response (p<0.001). In addition, no mutations were found in the coding sequences of MAD2 in all 11 hepatoma cell lines. Our findings suggest that MAD2 deficiency may cause a mitotic checkpoint defect in hepatoma cells.     

Resisting Arrest: Recovery from Checkpoint Arrest Through Dephosphorylation of Chk1 by PP1

The G2 DNA damage checkpoint prevents mitotic entry in the presence of damaged DNA, and thus is essential for cells to replicate with stable genetic inheritance. Whilst significant progress has been made in the past 10 years on the mechanism of checkpoint activation, little attention has been paid to how the DNA damage checkpoint is switched off to allow cell cycle re-entry. Insight into the mechanism of cell cycle re-entry was recently provided by our finding that the Schizosaccharomyces pombe type 1 phosphatase (PP1) Dis2 dephosphorylates the checkpoint effector kinase Chk1. This occurs on a site phosphorylated by the ATR homologue Rad3 in response to DNA damage, and results in Chk1 inactivation and checkpoint release. Here we discuss the implications of this finding on DNA damage checkpoint signalling, and speculate on models for checkpoint maintenance and release.     

Resisting arrest: recovery from checkpoint arrest through dephosphorylation of Chk1 by PP1

The G2 DNA damage checkpoint prevents mitotic entry in the presence of damaged DNA, and thus is essential for cells to replicate with stable genetic inheritance. Whilst significant progress has been made in the past 10 years on the mechanism of checkpoint activation, little attention has been paid to how the DNA damage checkpoint is switched off to allow cell cycle re-entry. Insight into the mechanism of cell cycle re-entry was recently provided by our finding that the Schizosaccharomyces pombe type 1 phosphatase (PP1) Dis2 dephosphorylates the checkpoint effector kinase Chk1. This occurs on a site phosphorylated by the ATR homologue Rad3 in response to DNA damage, and results in Chk1 inactivation and checkpoint release. Here we discuss the implications of this finding on DNA damage checkpoint signaling, and speculate on models for checkpoint maintenance and release.     

The Mitotic Checkpoint in Cancer Therapy

The mitotic checkpoint is a key cell cycle control mechanism that ensures an accurate segregation of chromosomes during mitosis by delaying the onset of anaphase until all chromosomes are properly attached to a bipolar mitotic spindle. While complete loss of this checkpoint is lethal in vertebrates, a weakened mitotic checkpoint is frequently seen in cancer cells and it may contribute to tumorigenesis. Many antitumor drugs, including spindle assembly inhibitors and DNA damaging agents, can activate the mitotic checkpoint. However, since these drugs influence interphase events besides activating the mitotic checkpoint, the role of the mitotic checkpoint in drug-induced cell death remained unclear. Using a KSP antagonist that specifically acts on mitotic cells, we have recently shown that activation of the mitotic checkpoint followed by mitotic slippage or adaptation, activates Bax and initiates apoptosis. Notably, cells with a weakened mitotic checkpoint incur much less apoptotic death than their checkpoint-proficient counterparts, indicating the requirement of a competent mitotic checkpoint in the induction of apoptosis. In light of these findings and other recent reports, the potential influence of the mitotic checkpoint in response to chemotherapies, and the strategy to target the mitotic checkpoint for cancer therapeutics are discussed.     

Phosphorylation and activation of Bub1 on unattached chromosomes facilitate the spindle checkpoint

The spindle checkpoint inhibits anaphase until all kinetochores have attached properly to spindle microtubules. The protein kinase Bub1 is an essential checkpoint component that resides at kinetochores during mitosis. It is shown herein that Xenopus Bub1 becomes hyperphosphorylated and the kinase is activated on unattached chromosomes. MAP kinase (MAPK) contributes to this phosphorylation, as inhibiting MAPK or altering MAPK consensus sites in Bub1 to alanine or valine (Bub1(5AV)) abolishes the phosphorylation and activation on chromosomes. Both Bub1 and Bub1(5AV) support the checkpoint under an optimal condition for spindle checkpoint activation. However, Bub1, but not Bub1(5AV), supports the checkpoint at a relatively low concentration of nuclei or the microtubule inhibitor nocodazole. Similar to Bub1(5AV), Bub1 without the kinase domain (Bub1(deltaKD)) is also partially compromised in its checkpoint function and in its ability to recruit other checkpoint proteins to kinetochores. This study suggests that activation of Bub1 at kinetochores enhances the efficiency of the spindle checkpoint and is probably important in maintaining the checkpoint toward late prometaphase when the cell contains only a few or a single unattached kinetochore.     

Srs2 enables checkpoint recovery by promoting disassembly of DNA damage foci from chromatin

Following DNA repair, checkpoint signalling must be abated to resume cell cycling in a phenomenon known as checkpoint recovery. Although a number of genes have been implicated in the recovery process, it is still unknown whether checkpoint recovery is caused by a signalling network activated by DNA repair or whether it is the result of the loss of DNA structures that elicit the checkpoint. Here we show that checkpoint recovery can be uncoupled from bulk chromosome DNA repair if single-stranded (ss) DNA persists. This situation occurs in cells that are deficient in the Srs2 helicase, a protein that antagonizes Rad51. We report that srs2Δ cells fail to eliminate Ddc2 and RPA subnuclear foci following bulk chromosome repair due to the persistence of ssDNA. In contrast to cells with DNA double-strand breaks that remain unrepaired, srs2Δ cells remove the 9-1-1 checkpoint clamp from chromatin after repair. However, despite the loss of the 9-1-1 clamp, Dpb11 remains associated with chromatin to promote checkpoint activity. Our work indicates that Srs2 promotes checkpoint recovery by removing Rad51 after DNA repair. A failure to remove Rad51 causes persistence of ssDNA and the checkpoint signal. Therefore, we conclude that cells initiate recovery when the DNA structures that elicit the checkpoint are eliminated.     

Phosphorylation of Cdc20 is required for its inhibition by the spindle checkpoint

The spindle checkpoint delays anaphase until all chromosomes are properly attached to spindle microtubules. When the spindle checkpoint is activated at unattached kinetochores, the checkpoint proteins BubR1, Bub3 and Mad2 bind and inhibit Cdc20, an activator of the anaphase-promoting complex (APC). Here, we show that Xenopus laevis Cdc20 is phosphorylated at Ser 50, Thr 64, Thr 68 and Thr 79 during mitosis and that mitogen-activated protein kinase (MAPK) contributes to the phosphorylation at Thr 64 or Thr 68. Cdc20 mutants that are phosphorylation-deficient are able to activate the APC in X. laevis egg extracts. However, Cdc20 mutants in which any of the four phosphorylation sites were altered to Ala or Val failed to respond to the spindle checkpoint signal, owing to their reduced affinity for the spindle checkpoint proteins. This study demonstrates that the spindle checkpoint stops anaphase by inhibiting fully-phosphorylated Cdc20. Our results also have implications for the spindle checkpoint silencing mechanism.     

DNA replication is required for the checkpoint response to damaged DNA in Xenopus egg extracts

Alkylating agents, such as methyl methanesulfonate (MMS), damage DNA and activate the DNA damage checkpoint. Although many of the checkpoint proteins that transduce damage signals have been identified and characterized, the mechanism that senses the damage and activates the checkpoint is not yet understood. To address this issue for alkylation damage, we have reconstituted the checkpoint response to MMS in Xenopus egg extracts. Using four different indicators for checkpoint activation (delay on entrance into mitosis, slowing of DNA replication, phosphorylation of the Chk1 protein, and physical association of the Rad17 checkpoint protein with damaged DNA), we report that MMS-induced checkpoint activation is dependent upon entrance into S phase. Additionally, we show that the replication of damaged double-stranded DNA, and not replication of damaged single-stranded DNA, is the molecular event that activates the checkpoint. Therefore, these data provide direct evidence that replication forks are an obligate intermediate in the activation of the DNA damage checkpoint.     

The C-terminal half of Saccharomyces cerevisiae Mad1p mediates spindle checkpoint function, chromosome transmission fidelity and CEN association

The evolutionarily conserved spindle checkpoint is a key mechanism ensuring high-fidelity chromosome transmission. The checkpoint monitors attachment between kinetochores and mitotic spindles and the tension between sister kinetochores. In the absence of proper attachment or tension, the spindle checkpoint mediates cell cycle arrest prior to anaphase. Saccharomyces cerevisiae Mad1p is required for the spindle checkpoint and for chromosome transmission fidelity. Moreover, Mad1p associates with the nuclear pore complex (NPC) and is enriched at kinetochores upon checkpoint activation. Using partial mad1 deletion alleles we determined that the C-terminal half of Mad1p is necessary and sufficient for checkpoint activation in response to microtubule depolymerizing agents, high-fidelity transmission of a reporter chromosome fragment, and in vivo association with centromeres, but not for robust NPC association. Thus, spindle checkpoint activation and chromosome transmission fidelity correlate and these Mad1p functions likely involve kinetochore association but not robust NPC association. These studies are the basis for elucidating the role of protein complexes containing Mad1p in the spindle checkpoint pathway and in maintaining genome stability in S. cerevisiae and other systems.     

The checkpoint clamp protein Rad9 facilitates DNA-end resection and prevents alternative non-homologous end joining

DNA damage activates the cell cycle checkpoint to regulate cell cycle progression. The checkpoint clamp (Rad9-Hus1-Rad1 complex) is recruited to damage sites, and is required for checkpoint activation. While functions of the checkpoint clamp in checkpoint activation have been well studied, its functions in DNA repair regulation remain elusive. Here we show that Rad9 is required for efficient homologous recombination (HR), and facilitates DNA-end resection. The role of Rad9 in homologous recombination is independent of its function in checkpoint activation, and this function is important for preventing alternative non-homologous end joining (altNHEJ). These findings reveal novel function of the checkpoint clamp in HR.