Progression into the First Meiotic Division Is Sensitive to Histone H2a-H2b Dimer Concentration in Saccharomyces Cerevisiae

The yeast Saccharomyces cerevisiae contains two genes for histone H2A and two for histone H2B located in two divergently transcribed gene pairs: HTA1-HTB1 and HTA2-HTB2. Diploid strains lacking HTA1-HTB1 (hta1-htb1Δ/hta1-htb1Δ, HTA2-HTB2/HTA2-HTB2) grow vegetatively, but will not sporulate. This sporulation phenotype results from a partial depletion of H2A-H2B dimers. Since the expression patterns of HTA1-HTB1 and HTA2-HTB2 are similar in mitosis and meiosis, the sporulation pathway is therefore more sensitive than the mitotic cycle to depletion of H2A-H2B dimers. After completing premeiotic DNA replication, commitment to meiotic recombination, and chiasma resolution, the hta1-htb1Δ/hta1-htb1Δ, HTA2-HTB2/HTA2-HTB2 mutant arrests before the first meiotic division. The arrest is not due to any obvious disruptions in spindle pole bodies or microtubules. The meiotic block is not bypassed in backgrounds homozygous for spo13, rad50Δ, or rad9Δ mutations, but is bypassed in the presence of hydroxyurea, a drug known to inhibit DNA chain elongation. We hypothesize that the deposition of H2A-H2B dimers in the mutant is unable to keep pace with the replication fork, thereby leading to a disruption in chromosome structure that interferes with the meiotic divisions.     

IBD2 encodes a novel component of the Bub2p-dependent spindle checkpoint in the budding yeast Saccharomyces cerevisiae

During mitosis, genomic integrity is maintained by the proper coordination of mitotic events through the spindle checkpoint. The bifurcated spindle checkpoint blocks cell cycle progression at metaphase by monitoring unattached kinetochores and inhibits mitotic exit in response to the incorrect orientation of the mitotic spindle. Bfa1p is a spindle checkpoint regulator of budding yeast in the Bub2p checkpoint pathway for proper mitotic exit. We have isolated a novel Bfa1p interacting protein named Ibd2p in the budding yeast Saccharomyces cerevisiae. We found that IBD2 (Inhibition of Bud Division 2) is not an essential gene but its deletion mutant proceeded through the cell cycle in the presence of microtubule-destabilizing drugs, thereby inducing a sharp decrease in viability. In addition, overexpression of Mps1p caused partial mitotic arrest in ibd2Delta as well as in bub2Delta, suggesting that IBD2 encodes a novel component of the spindle checkpoint downstream of MPS1. Overexpression of Ibd2p induced mitotic arrest with increased levels of Clb2p in wild type and mad2Delta, but not in deletion mutants of BUB2 and BFA1. Pds1p was also stabilized by the overexpression of Ibd2p in wild-type cells. The mitotic arrest defects observed in ibd2Delta in the presence of nocodazole were restored by additional copies of BUB2, BFA1, and CDC5, whereas an extra copy of IBD2 could not rescue the mitotic arrest defects of bub2Delta and bfa1Delta. The mitotic arrest defects of ibd2Delta were not recovered by MAD2, or vice versa. Analysis of the double mutant combinations ibd2Deltamad2Delta, ibd2Deltabub2Delta, and ibd2Deltadyn1Delta showed that IBD2 belongs to the BUB2 epistasis group. Taken together, these data demonstrate that IBD2 encodes a novel component of the BUB2-dependent spindle checkpoint pathway that functions upstream of BUB2 and BFA1.     

Differential Kinetochore Requirements for Establishment and Maintenance of the Spindle Checkpoint Are Dependent on the Mechanism of Checkpoint Activation in Saccharomyces cerevisiae

The spindle checkpoint in the yeast Saccharomyces cerevisiae is an intracellular signal transduction pathway comprised of two branches that inhibit two different mitotic transitions in cells treated with benzimidazole drugs such as nocodazole. The kinetochore is an integral component of the MAD2 branch of the spindle checkpoint pathway. Current models propose that the kinetochore is required for both the establishment and maintenance of the spindle checkpoint but a role for the kinetochore in the maintenance of spindle checkpoint in yeast has never been directly tested. We used a temperature sensitive ndc10-1 mutant to inactivate kinetochores before and after arresting cells in mitosis to determine the role of kinetochores in the establishment and maintenance of the spindle checkpoint. We show that both establishment and maintenance requires kinetochore function in response to spindle damage induced by benzimidazole drugs. Excess expression of the Mps1 protein kinase causes wild type cells and ndc10-1 cells to arrest in mitosis. Unlike the spindle checkpoint arrest activated by benzimidazoles, this arrest can be maintained independently of kinetochores. The arrest induced by excess Mps1p is independent of BUB2. Therefore, mitotic arrest induced by excess Mps1p expression is due to the action of the MAD2 branch of the spindle checkpoint pathway and excess Mps1p acts downstream of the kinetochore.     

Differential kinetochore requirements for establishment and maintenance of the spindle checkpoint are dependent on the mechanism of checkpoint activation in Saccharomyces cerevisiae

The spindle checkpoint in the yeast Saccharomyces cerevisiae is an intracellular signal transduction pathway comprised of two branches that inhibit two different mitotic transitions in cells treated with benzimidazole drugs such as nocodazole. The kinetochore is an integral component of the MAD2 branch of the spindle checkpoint pathway. Current models propose that the kinetochore is required for both the establishment and maintenance of the spindle checkpoint but a role for the kinetochore in the maintenance of spindle checkpoint in yeast has never been directly tested. We used a temperature sensitive ndc10-1 mutant to inactivate kinetochores before and after arresting cells in mitosis to determine the role of kinetochores in the establishment and maintenance of the spindle checkpoint. We show that both establishment and maintenance requires kinetochore function in response to spindle damage induced by benzimidazole drugs. Excess expression of the Mps1 protein kinase causes wild type cells and ndc10-1 cells to arrest in mitosis. Unlike the spindle checkpoint arrest activated by benzimidazoles, this arrest can be maintained independently of kinetochores. The arrest induced by excess Mps1p is independent of BUB2. Therefore, mitotic arrest induced by excess Mps1p expression is due to the action of the MAD2 branch of the spindle checkpoint pathway and excess Mps1p acts downstream of the kinetochore.     

CDC6 regulates both G2/M transition and metaphase-to-anaphase transition during the first meiosis of mouse oocytes

Cell division cycle protein, CDC6, is essential for the initiation of DNA replication. CDC6 was recently shown to inhibit the microtubule-organizing activity of the centrosome. Here, we show that CDC6 is localized to the spindle from pro-metaphase I (MI) to MII stages of oocytes, and it plays important roles at two critical steps of oocyte meiotic maturation. CDC6 depletion facilitated the G2/M transition (germinal vesicle breakdown [GVBD]) through regulation of Cdh1 and cyclin B1 expression and CDK1 (CDC2) phosphorylation in a GVBD-inhibiting culture system containing milrinone. Furthermore, GVBD was significantly decreased after knockdown of cyclin B1 in CDC6-depleted oocytes, indicating that the effect of CDC6 loss on GVBD stimulation was mediated, at least in part, by raising cyclin B1. Knockdown of CDC6 also caused abnormal localization of γ-tubulin, resulting in defective spindles, misaligned chromosomes, cyclin B1 accumulation, and spindle assembly checkpoint (SAC) activation, leading to significant pro-MI/MI arrest and PB1 extrusion failure. These phenotypes were also confirmed by time-lapse live cell imaging analysis. The results indicate that CDC6 is indispensable for maintaining G2 arrest of meiosis and functions in G2/M checkpoint regulation in mouse oocytes. Moreover, CDC6 is also a key player regulating meiotic spindle assembly and metaphase-to-anaphase transition in meiotic oocytes.     

The spindle checkpoint of Saccharomyces cerevisiae responds to separable microtubule-dependent events

The spindle checkpoint regulates microtubule-based chromosome segregation and helps to maintain genomic stability [1,2]. Mutational inactivation of spindle checkpoint genes has been implicated in the progression of several types of human cancer. Recent evidence from budding yeast suggests that the spindle checkpoint is complex. Order-of-function experiments have defined two separable pathways within the checkpoint. One pathway, defined by MAD2, controls the metaphase-to-anaphase transition and the other, defined by BUB2, controls the exit from mitosis [3-6]. The relationships between the separate branches of the checkpoint, and especially the events that trigger the pathways, have not been defined. We localized a Bub2p-GFP fusion protein to the cytoplasmic side of the spindle pole body and used a kar9 mutant to show that cells with misoriented spindles are arrested in anaphase of mitosis. We used a kar9 bub2 double mutant to show that the arrest is BUB2 dependent. We conclude that the separate pathways of the spindle checkpoint respond to different classes of microtubules. The MAD2 branch of the pathway responds to kinetochore microtubule interactions and the BUB2 branch of the pathway operates within the cytoplasm, responding to spindle misorientation.     

Analysis of the kar3 meiotic arrest in Saccharomyces cerevisiae

The motor protein Kar3p and its associated protein Cik1p are essential for passage through meiosis I. In the absence of either protein, meiotic cells arrest in prophase I. Experiments were performed to determine whether the arrest was caused by a structural inability to proceed through meiosis, or by a regulatory mechanism. The data demonstrate that the meiotic arrest is not structural; kar3 and cik1 mutants are able to form normal looking bipolar spindles and divide their DNA into two masses in spo11 mutant backgrounds. To identify the regulatory system necessary for the kar3/cik1 meiotic arrest, we tested whether the arrest could be bypassed by eliminating the pachytene checkpoint or the spindle checkpoint. The arrest is not solely dependent upon the pachytene checkpoint that monitors recombination and aspects of chromosome synapsis. Elimination of the spindle checkpoint failed to allow kar3 mutants to undergo meiosis I nuclear division, but phenotypes of the kar3/spindle checkpoint double mutants suggest that the kar3 meiotic arrest may be mediated by the spindle checkpoint.     

Analysis of the kar3 Meiotic Arrest in Saccharomyces cerevisiae

The motor protein Kar3p and its associated protein Cik1p are essential for passage through meiosis I. In the absence of either protein, meiotic cells arrest in prophase I. Experiments were performed to determine whether the arrest was caused by a structural inability to proceed through meiosis, or by a regulatory mechanism. The data demonstrate that the meiotic arrest is not structural; kar3 and cik1 mutants are able to form normal looking bipolar spindles and divide their DNA into two masses in spo11 mutant backgrounds. To identify the regulatory system necessary for the kar3/cik1 meiotic arrest, we tested whether the arrest could be bypassed by eliminating the pachytene checkpoint or the spindle checkpoint. The arrest is not solely dependent upon the pachytene checkpoint that monitors recombination and aspects of chromosome synapsis. Elimination of the spindle checkpoint failed to allow kar3 mutants to undergo meiosis I nuclear division, but phenotypes of the kar3/spindle checkpoint double mutants suggest that the kar3 meiotic arrest may be mediated by the spindle checkpoint.     

Checkpoint kinase 1 is essential for meiotic cell cycle regulation in mouse oocytes

Checkpoint kinase 1 (Chk1) plays key roles in all currently defined cell cycle checkpoints, but its functions in mouse oocyte meiosis remain unclear. In this study, we report the expression, localization and functions of Chk1 in mouse oocyte meiosis. Chk1 was expressed from germinal vesicle (GV) to metaphase II (MII) stages and localized to the spindle from pro-metaphase I (pro-MI) to MII stages in mouse oocytes. Chk1 depletion facilitated the G₂/M transition while Chk1 overexpression inhibited the G₂/M transition as indicated by germinal vesicle breakdown (GVBD), through regulation of Cdh1 and Cyclin B1. Chk1 depletion did not affect meiotic cell cycle progression after GVBD, but its overexpression after GVBD activated the spindle assembly checkpoint and prevented homologous chromosome segregation, thus arresting oocytes at pro-MI or metaphase I (MI) stages. These results suggest that Chk1 is indispensable for prophase I arrest and functions in G₂/M checkpoint regulation in meiotic oocytes. Moreover, Chk1 overexpression affects meiotic spindle assembly checkpoint regulation and thus chromosome segregation.     

The Ulp2 SUMO protease is required for cell division following termination of the DNA damage checkpoint

Eukaryotic genome integrity is maintained via a DNA damage checkpoint that recognizes DNA damage and halts the cell cycle at metaphase, allowing time for repair. Checkpoint signaling is eventually terminated so that the cell cycle can resume. How cells restart cell division following checkpoint termination is poorly understood. Here we show that the SUMO protease Ulp2 is required for resumption of cell division following DNA damage-induced arrest in Saccharomyces cerevisiae, although it is not required for DNA double-strand break repair. The Rad53 branch of the checkpoint pathway generates a signal countered by Ulp2 activity following DNA damage. Interestingly, unlike previously characterized adaptation mutants, ulp2Delta mutants do not show persistent Rad53 phosphorylation following DNA damage, suggesting checkpoint signaling has been terminated and no longer asserts an arrest in these cells. Using Cdc14 localization as a cell cycle indicator, we show that nearly half of cells lacking Ulp2 can escape a checkpoint-induced metaphase arrest despite their inability to divide again. Moreover, half of permanently arrested ulp2Delta cells show evidence of an aberrant mitotic spindle, suggesting that Ulp2 is required for proper spindle dynamics during cell cycle resumption following a DNA damage-induced cell cycle arrest.     

Bypass of a meiotic checkpoint by overproduction of meiotic chromosomal proteins

The Saccharomyces cerevisiae zip1 mutant, which exhibits defects in synaptonemal complex formation and meiotic recombination, triggers a checkpoint that causes cells to arrest at the pachytene stage of meiotic prophase. Overproduction of either the meiotic chromosomal protein Red1 or the meiotic kinase Mek1 bypasses this checkpoint, allowing zip1 cells to sporulate. Red1 or Mek1 overproduction also promotes sporulation of other mutants (zip2, dmc1, hop2) that undergo checkpoint-mediated arrest at pachytene. In addition, Red1 overproduction antagonizes interhomolog interactions in the zip1 mutant, substantially decreasing double-strand break formation, meiotic recombination, and homologous chromosome pairing. Mek1 overproduction, in contrast, suppresses checkpoint-induced arrest without significantly decreasing meiotic recombination. Cooverproduction of Red1 and Mek1 fails to bypass the checkpoint; moreover, overproduction of the meiotic chromosomal protein Hop1 blocks the Red1 and Mek1 overproduction phenotypes. These results suggest that meiotic chromosomal proteins function in the signaling of meiotic prophase defects and that the correct stoichiometry of Red1, Mek1, and Hop1 is needed to achieve checkpoint-mediated cell cycle arrest at pachytene.     

Mechanisms underlying the pro-survival pathway of p53 in suppressing mitotic death induced by adriamycin

The p53 tumor suppressor responds to chemotherapeutic stress by triggering apoptosis or eliciting pro-survival pathway through arresting cell cycle progression for DNA damage repair. Here we examined the pro-survival activity of p53 on the adriamycin-induced stress using H1299 cells stably expressing tsp53 V143A, a temperature-sensitive mutant activating only the subset of p53 target genes related to growth arrest and DNA repair, but not apoptosis. At 38 degrees C, cells evaded from adriamycin-induced G2 arrest and died of apoptosis and mitotic catastrophe, which could be inhibited by Cdk inhibitors. Activation of functional tsp53 V143A at 32 degrees C led to suppression of Cdk1/2 activities and Cyclin B1/Cdk1 expression, cells exhibited prolonged G2 arrest, regained reproductive potential and were protected from mitotic catastrophe induced by adriamycin. Inhibition of mitotic catastrophe and Cyclin B1/Cdk1 expression was ablated upon silencing p21 Waf1 expression in tsp53 V143A-H1299 cells or in HCT116 cells. Together we show that p21 Waf1 is a key component of G2 checkpoint necessary and sufficient for protecting tumor cells against adriamycin-induced mitotic catastrophe.     

Ectopic Expression of cdc2/cdc28 Kinase Subunit Homo sapiens 1 Uncouples Cyclin B Metabolism from the Mitotic Spindle Cell Cycle Checkpoint

Primary human fibroblasts arrest growth in response to the inhibition of mitosis by mitotic spindle-depolymerizing drugs. We show that the mechanism of mitotic arrest is transient and implicates a decrease in the expression of cdc2/cdc28 kinase subunit Homo sapiens 1 (CKsHs1) and a delay in the metabolism of cyclin B. Primary human fibroblasts infected with a retroviral vector that drives the expression of a mutant p53 protein failed to downregulate CKsHs1 expression, degraded cyclin B despite the absence of chromosomal segregation, and underwent DNA endoreduplication. In addition, ectopic expression of CKsHs1 interfered with the control of cyclin B metabolism by the mitotic spindle cell cycle checkpoint and resulted in a higher tendency to undergo DNA endoreduplication. These results demonstrate that an altered regulation of CKsHs1 and cyclin B in cells that carry mutant p53 undermines the mitotic spindle cell cycle checkpoint and facilitates the development of aneuploidy. These data may contribute to the understanding of the origin of heteroploidy in mutant p53 cells.     

A conserved protein, Nuf2, is implicated in connecting the centromere to the spindle during chromosome segregation: a link between the kinetochore function and the spindle checkpoint

The centromere is crucial for the proper segregation of chromosomes in all eukaryotic cells. We identified a centromeric protein, Nuf2, which is conserved in fission yeast, human, nematode, and budding yeast. Gene disruption of nuf2+ in the fission yeast Schizosaccharomyces pombe caused defects in chromosome segregation and the spindle checkpoint: the mitotic spindle elongated without segregating the chromosomes, indicating that spindle function was compromised, but that this abnormality did not result in metaphase arrest. Certain nuf2 temperature-sensitive mutations, however, caused metaphase arrest with condensed chromosomes and a short spindle, indicating that, while these mutations caused abnormalities in spindle function, the spindle checkpoint pathway remained intact. Metaphase arrest in these cells was dependent on the spindle checkpoint component Mad2. Interestingly, Nuf2 disappeared from the centromere during meiotic prophase when centromeres lose their connection to the spindle pole body. We propose that Nuf2 acts at the centromere to establish a connection with the spindle for proper chromosome segregation, and that Nuf2 function is also required for the spindle checkpoint.     

Dynamic Solution Structures of Whole Human NAP1 Dimer Bound to One and Two Histone H2A-H2B Heterodimers Obtained by Integrative Methods

Nucleosome assembly protein 1 (NAP1) binds to histone H2A-H2B heterodimers, mediating their deposition on and eviction from the nucleosome. Human NAP1 (hNAP1) consists of a dimerization core domain and intrinsically disordered C-terminal acidic domain (CTAD), both of which are essential for H2A-H2B binding. Several structures of NAP1 proteins bound to H2A-H2B exhibit binding polymorphisms of the core domain, but the distinct structural roles of the core and CTAD domains remain elusive. Here, we have examined dynamic structures of the full-length hNAP1 dimer bound to one and two H2A-H2B heterodimers by integrative methods. Nuclear magnetic resonance (NMR) spectroscopy of full-length hNAP1 showed CTAD binding to H2A-H2B. Atomic force microscopy revealed that hNAP1 forms oligomers of tandem repeated dimers; therefore, we generated a stable dimeric hNAP1 mutant exhibiting the same H2A-H2B binding affinity as wild-type hNAP1. Size exclusion chromatography (SEC), multi-angle light scattering (MALS) and small angle X-ray scattering (SAXS), followed by modelling and molecular dynamics simulations, have been used to reveal the stepwise dynamic complex structures of hNAP1 binding to one and two H2A-H2B heterodimers. The first H2A-H2B dimer binds mainly to the core domain of hNAP1, while the second H2A-H2B binds dynamically to both CTADs. Based on our findings, we present a model of the eviction of H2A-H2B from nucleosomes by NAP1.     

Sirt2‐BubR1 acetylation pathway mediates the effects of advanced maternal age on oocyte quality

The level of Sirt2 protein is reduced in oocytes from aged mice, while exogenous expression of Sirt2 could ameliorate the maternal age‐associated meiotic defects. To date, the underlying mechanism remains unclear. Here, we confirmed that specific depletion of Sirt2 disrupts maturational progression and spindle/chromosome organization in mouse oocytes, with compromised kinetochore–microtubule attachments. Candidate screening revealed that acetylation state of lysine 243 on BubR1 (BubR1‐K243, an integral part of the spindle assembly checkpoint complex) functions during oocyte meiosis, and acetylation‐mimetic mutant BubR1‐K243Q results in the very similar phenotypes as Sirt2‐knockdown oocytes. Furthermore, we found that nonacetylatable‐mimetic mutant BubR1‐K243R partly prevents the meiotic deficits in oocytes depleted of Sirt2. Importantly, BubR1‐K243R overexpression in oocytes derived from aged mice markedly suppresses spindle/chromosome anomalies and thereupon lowers the incidence of aneuploid eggs. In sum, our data suggest that Sirt2‐dependent BubR1 deacetylation involves in the regulation of meiotic apparatus in normal oocytes and mediates the effects of advanced maternal age on oocyte quality.