S-phase checkpoint controls mitosis via an APC-independent Cdc20p function

Cells divide with remarkable fidelity, allowing complex organisms to develop and possess longevity. Checkpoint controls contribute by ensuring that genome duplication and segregation occur without error so that genomic instability, associated with developmental abnormalities and a hallmark of most human cancers, is avoided. S-phase checkpoints prevent cell division while DNA is replicating. Budding yeast Mec1p and Rad53p, homologues of human checkpoint kinases ATM/ATR and Chk2, are needed for this control system. How Mec1p and Rad53p prevent mitosis in S phase is not known. Here we provide evidence that budding yeasts avoid mitosis during S phase by regulating the anaphase-promoting complex (APC) specificity factor Cdc20p: Mec1p and Rad53p repress the accumulation of Cdc20p in S phase. Because precocious Cdc20p accumulation causes anaphase onset and aneuploidy, Cdc20p concentrations must be precisely regulated during each and every cell cycle. Catastrophic mitosis induced by Cdc20p in S phase occurs even in the absence of core APC components. Thus, Cdc20p can function independently of the APC.     

Cdc20 in S-phase: the Banquo at replication's banquet

The Anaphase Promoting Complex/Cyclosome (APC/C) is an E3 ubiquitin ligase that covalently attaches ubiquitins onto proteins to target them for proteolysis by the 26S proteasome. During mitosis, the APC/C is instrumental in allowing the cell to enter and exit from mitosis. The APC/C accomplishes this by using different specificity factors to recognize, interact with, and ubiquitylate key proteins that block cell cycle progression. The specificity factors, Cdc20p and Cdh1p, are not always associated with the APC/C and indeed they have the ability to interact with substrates in isolation. The molecular events that take place in order for Cdc20p and Cdh1p to couple substrates and APC/C are currently being resolved. Meanwhile, evidence has emerged suggesting that at least one of the specificity factors, Cdc20p, might be capable of functioning independently of the APC/C.     

Spatio-temporal regulation of the human licensing factor Cdc6 in replication and mitosis

To maintain genome stability, the thousands of replication origins of mammalian genomes must only initiate replication once per cell cycle. This is achieved by a strict temporal separation of ongoing replication in S phase, and the formation of pre-replicative complexes in the preceding G1 phase, which "licenses" each origin competent for replication. The contribution of the loading factor Cdc6 to the timing of the licensing process remained however elusive due to seemingly contradictory findings concerning stabilization, degradation and nuclear export of Cdc6. Using fluorescently tagged Cdc6 (Cdc6-YFP) expressed in living cycling cells, we demonstrate here that Cdc6-YFP is stable and chromatin-associated during mitosis and G1 phase. It undergoes rapid proteasomal degradation during S phase initiation followed by active export to the cytosol during S and G2 phases. Biochemical fractionation abolishes this nuclear exclusion, causing aberrant chromatin association of Cdc6-YFP and, likely, endogenous Cdc6, too. In addition, we demonstrate association of Cdc6 with centrosomes in late G2 and during mitosis. These results show that multiple Cdc6-regulatory mechanisms coexist but are tightly controlled in a cell cycle-specific manner.     

Chromatin dynamics from S-phase to mitosis: contributions of histone modifications

This review focuses on the major protein moiety of chromosomes, i.e., the histone proteins, on the contribution of their posttranslational modification to structural and functional chromatin dynamics, on the acetylation and methylation of lysine residues, and on the phosphorylation of serine or threonine with respect to various steps during the cell cycle.     

CDK-Dependent Stabilization of Cdc6: Linking Growth and Stress Signals to Activation of DNA Replication

Cyclin-dependent kinases (CDKs) play a crucial role in cell cycle progression by controlling the transition from G1 phase into S phase where DNA is replicated. Key to this transition is the regulation of initiation of DNA replication at replication origins. CDKs are thought to regulate origins of replication both positively and negatively by phosphorylating replication proteins at origins. Several replication proteins that are potentially negatively regulated upon CDK phosphorylation have been identified. However, the mechanism by which CDKs activate replication is currently less well understood. New observations revealing that the initiation protein Cdc6 is stabilized by CDK2-dependent phosphorylation may give more insight in this process.     

Linking Cdc7 with the replication checkpoint

Comment on: Matsumoto S, et al. Cell Cycle 2010; 9: In press.     

Human replication protein Cdc6 prevents mitosis through a checkpoint mechanism that implicates Chk1

In yeasts, the replication protein Cdc6/Cdc18 is required for the initiation of DNA replication and also for coupling S phase with the following mitosis. In metazoans a role for Cdc6 has only been shown in S phase entry. Here we provide evidence that human Cdc6 (HuCdc6) also regulates the onset of mitosis, as overexpression of HuCdc6 in G(2) phase cells prevents entry into mitosis. This block is abolished when HuCdc6 is expressed together with a constitutively active Cyclin B/CDK1 complex or with Cdc25B or Cdc25C. An inhibitor of Chk1 kinase activity, UCN-01, overcomes the HuCdc6 mediated G(2) arrest indicating that HuCdc6 blocks cells in G(2) phase via a checkpoint pathway involving Chk1. When HuCdc6 is overexpressed in G(2), we detected phosphorylation of Chk1. Thus, HuCdc6 can trigger a checkpoint response, which could ensure that all DNA is replicated before mitotic entry. We also present evidence that the ability of HuCdc6 to block mitosis may be regulated by its phosphorylation.     

Cyclin destruction in mitosis: a crucial task of Cdc20

Proteolytic destruction of cyclins is a fundamental process for cell division. At the end of mitosis, degradation of mitotic cyclins results in the inactivation of cyclin-dependent kinases. Cyclin proteolysis is triggered by the anaphase-promoting complex/cyclosome (APC/C), a multi-subunit complex which contains ubiquitin ligase activity. Recent data in yeast demonstrated that a partial degradation of the mitotic cyclin Clb2, mediated by APC/C and its activator protein Cdc20, is essential and sufficient for the mitotic exit. Remarkably, a complete inactivation of cyclin-dependent kinases seems to be not essential. This review discusses recent novel insights into cyclin destruction and its implications for the mitotic exit.     

The fission yeast S-phase cyclin Cig2 can drive mitosis

Commitment to mitosis is regulated by cyclin-dependent kinase (CDK) activity. In the fission yeast Schizosaccharomyces pombe, the major B-type cyclin, Cdc13, is necessary and sufficient to drive mitotic entry. Furthermore, Cdc13 is also sufficient to drive S phase, demonstrating that a single cyclin can regulate alternating rounds of replication and mitosis, and providing the foundation of the quantitative model of CDK function. It has been assumed that Cig2, a B-type cyclin expressed only during S phase and incapable of driving mitosis in wild-type cells, was specialized for S-phase regulation. Here, we show that Cig2 is capable of driving mitosis. Cig2/CDK activity drives mitotic catastrophe—lethal mitosis in inviably small cells—in cells that lack CDK inhibition by tyrosine-phosphorylation. Moreover, Cig2/CDK can drive mitosis in the absence of Cdc13/CDK activity and constitutive expression of Cig2 can rescue loss of Cdc13 activity. These results demonstrate that in fission yeast, not only can the presumptive M-phase cyclin drive S phase, but the presumptive S-phase cyclin can drive M phase, further supporting the quantitative model of CDK function. Furthermore, these results provide an explanation, previously proposed on the basis of computational analyses, for the surprising observation that cells expressing a single-chain Cdc13-Cdc2 CDK do not require Y15 phosphorylation for viability. Their viability is due to the fact that in such cells, which lack Cig2/CDK complexes, Cdc13/CDK activity is unable to drive mitotic catastrophe.     

Phosphorylation at serine 75 is required for UV-mediated degradation of human Cdc25A phosphatase at the S-phase checkpoint

The human Cdc25A phosphatase plays a pivotal role at the G1/S transition by activating cyclin E and A/Cdk2 complexes through dephosphorylation. In response to ionizing radiation, Cdc25A is phosphorylated by both Chk1 and Chk2 on Ser-123. This in turn leads to ubiquitylation and rapid degradation of Cdc25A by the proteasome resulting in cell cycle arrest. We found that in response to UV irradiation, Cdc25A is phosphorylated at a different serine residue, Ser-75. Significantly, Cdc25A mutants carrying alanine instead of either Ser-75 or Ser-123 demonstrate that only Ser-75 mediates protein stabilization in response to UV-induced DNA damage. As a consequence, cyclin E/Cdk2 kinase activity was high. Furthermore, we find that Cdc25A was phosphorylated by Chk1 on Ser-75 in vitro and that the same site was also phosphorylated in vivo. Taken together, these data strongly suggest that phosphorylation of Cdc25A on Ser-75 by Chk1 and its subsequent degradation is required to delay cell cycle progression in response to UV-induced DNA lesions.     

Cdc16p, Cdc23p and Cdc27p form a complex essential for mitosis.

Cdc16p, Cdc23p and Cdc27p are all essential proteins required for cell cycle progression through mitosis in Saccharomyces cerevisiae. All three proteins contain multiple tandemly repeated 34 amino acid tetratricopeptide repeats (TPRs). Using two independent assays, two-hybrid analysis in vivo and co-immunoprecipitation in vitro, we demonstrate that Cdc16p, Cdc23p and Cdc27p self associate and interact with one another to form a macromolecular complex. A temperature sensitive mutation in the most highly conserved TPR domain of Cdc27p results in a greatly reduced ability to interact with Cdc23p, but has no effect on interactions with wild-type Cdc27p or Cdc16p. The specificity of this effect indicates that TPRs can mediate protein-protein interactions and that this mutation may define an essential interaction for cell cycle progression in yeast. The conservation of at least two of the three proteins from yeast to man suggests that this protein complex is essential for mitosis in a wide range of eukaryotes.     

Differential condensation of sister chromatids acts with Cdc6 to ensure asynchronous S-phase entry in Drosophila male germline stem cell lineage

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Cdc28 activates exit from mitosis in budding yeast

The activity of the cyclin-dependent kinase 1 (Cdk1), Cdc28, inhibits the transition from anaphase to G1 in budding yeast. CDC28-T18V, Y19F (CDC28-VF), a mutant that lacks inhibitory phosphorylation sites, delays the exit from mitosis and is hypersensitive to perturbations that arrest cells in mitosis. Surprisingly, this behavior is not due to a lack of inhibitory phosphorylation or increased kinase activity, but reflects reduced activity of the anaphase-promoting complex (APC), a defect shared with other mutants that lower Cdc28/Clb activity in mitosis. CDC28-VF has reduced Cdc20- dependent APC activity in mitosis, but normal Hct1- dependent APC activity in the G1 phase of the cell cycle. The defect in Cdc20-dependent APC activity in CDC28-VF correlates with reduced association of Cdc20 with the APC. The defects of CDC28-VF suggest that Cdc28 activity is required to induce the metaphase to anaphase transition and initiate the transition from anaphase to G1 in budding yeast.     

Phosphorylation of Cdc6 at serine 74, but not at serine 106, drives translocation of Cdc6 to the cytoplasm

Phosphorylation‐dependent cytoplasmic translocation of human Cdc6 during S phase is sufficient to control its activity after origin firing. Export from the nucleus also serves as a mechanism for preventing re‐replication in mammalian cells. Phosphorylation of the CDK consensus serine residues 54, 74, and 106 has been suggested to be involved in the cytoplasmic translocation of Cdc6. To determine the relative importance of the three phosphorylation sites, we have generated Cdc6 variants by substituting one or more of the three serine residues with alanine or aspartic acid and have assessed their cytoplasmic translocation behavior. Phosphorylation of serine 74 mainly contributes to the cytoplasmic translocation of Cdc6, while serine 54 phosphorylation provides a minor contribution. In contrast, phosphorylation at serine 106 does not affect the nuclear export of Cdc6. Comparative results were found in cells coexpressing the phosphorylation defective mutants of Cdc6 and cyclin A as well as in non‐transfected cells synchronized by their release from a double thymidine block. We conclude that Cdk‐mediated phosphorylation of Cdc6 at serine 74 is required for the cytoplasmic translocalization of Cdc6 during the cell cycle. Phosphorylation of Cdc6 at serine 54 plays a minor role and phosphorylation of serine 106 plays no role in the cytoplasmic localization of Cdc6. The phosphorylation of S74 in Cdc6 could be important for binding to the nuclear export protein for translocalization. J. Cell. Physiol. 228: 1221–1228, 2013. © 2012 Wiley Periodicals, Inc.     

Cdc25B cooperates with Cdc25A to induce mitosis but has a unique role in activating cyclin B1-Cdk1 at the centrosome

Cdc25 phosphatases are essential for the activation of mitotic cyclin-Cdks, but the precise roles of the three mammalian isoforms (A, B, and C) are unclear. Using RNA interference to reduce the expression of each Cdc25 isoform in HeLa and HEK293 cells, we observed that Cdc25A and -B are both needed for mitotic entry, whereas Cdc25C alone cannot induce mitosis. We found that the G2 delay caused by small interfering RNA to Cdc25A or -B was accompanied by reduced activities of both cyclin B1-Cdk1 and cyclin A-Cdk2 complexes and a delayed accumulation of cyclin B1 protein. Further, three-dimensional time-lapse microscopy and quantification of Cdk1 phosphorylation versus cyclin B1 levels in individual cells revealed that Cdc25A and -B exert specific functions in the initiation of mitosis: Cdc25A may play a role in chromatin condensation, whereas Cdc25B specifically activates cyclin B1-Cdk1 on centrosomes.     

WARTS tumor suppressor is phosphorylated by Cdc2/cyclin B at spindle poles during mitosis

Identification of physiological substrates for Cdc2/cyclin B is crucial for understanding the functional link between mitotic events and Cdc2/cyclin B activation. A human homologue of the Drosophila warts tumor suppressor, termed WARTS, is a serine/threonine kinase and a dynamic component of the mitotic apparatus. We have found that Cdc2/cyclin B forms a complex with a fraction of WARTS in the centrosome and phosphorylates the Ser613 site of WARTS during mitosis. Immunocytochemical analysis has shown that the S613-phosphorylated WARTS appears in the spindle poles at prometaphase and disappears at telophase. Our findings suggest that Cdc/cyclin B regulates functions of WARTS on the mitotic apparatus.     

不同温度下酿酒酵母细胞分裂周期蛋白Cdc5在有丝分裂中的分子动力学研究

[目的] 探究不同温度下酿酒酵母细胞分裂周期蛋白Cdc5蛋白在有丝分裂中的分子动力学变化。[方法] 本研究以酿酒酵母（Saccharomyces cerevisiae）为材料,采用活细胞成像的方法,探究Cdc5蛋白在不同温度下在酿酒酵母有丝分裂过程中的精细分子动力学变化;通过测量OD₅₉₅绘制生长曲线图,看其宏观的分裂情况是否与微观下Cdc5蛋白的分子动力学变化一致;利用流式细胞术检测细胞的细胞周期变化的情况。[结果] 在胞质分裂时,Cdc5蛋白从母细胞进入子细胞,并在芽颈处发生聚集。25℃条件下细胞中Cdc5蛋白在芽颈处的聚集时间长,37℃条件下Cdc5蛋白在芽颈处聚集时间短,两者间存在显著差异;但两个温度下,细胞中Cdc5蛋白的表达量没有显著性差异。同时,温度也会影响Cdc5蛋白在降解过程中的动力学行为,包括Cdc5蛋白在母细胞与子细胞中荧光强度峰值出现的次数和时间。生长曲线结果显示,酿酒酵母单一细胞分裂周期的变化影响了其宏观的细胞生长,且酵母分裂速度越快,子细胞长宽比越小;细胞周期结果表明,37℃下Cdc5蛋白的动力学变化与酿酒酵母细胞周期变化一致,酿酒酵母细胞周期从G₀/G₁期进入S期,亦加速了酿酒酵母的分裂。[结论] 本研究首次探究了不同温度下酿酒酵母有丝分裂中Cdc5蛋白的精细分子动力学及对应的酵母的宏观生长情况,结果表明温度会对Cdc5蛋白的动力学产生影响,且其精细分子动力学与酿酒酵母的分裂速度成正相关,该结果为进一步研究其在细胞有丝分裂中的功能提供了前期研究基础。     

Cdc6 chromatin affinity is unaffected by serine-54 phosphorylation, S-phase progression, and overexpression of cyclin A

Ectopically expressed Cdc6 is translocated from the nucleus during S phase in a cyclin A-Cdk2-dependent process, suggesting that reinitiation of DNA replication is prevented by removal of phosphorylated Cdc6 from chromatin after origin firing. However, whether endogenous Cdc6 translocates during S phase remains controversial. To resolve the questions regarding regulation of endogenous Cdc6, we cloned the cDNA encoding the Chinese hamster Cdc6 homolog and specifically focused on analyzing the localizations and chromatin affinities of endogenous and exogenous proteins during S phase and following overexpression of cyclin A. In agreement with other reports, ectopically expressed Cdc6 translocates from the nucleus during S phase and in response to overexpressed cyclin A. In contrast, using a combination of biochemical and immunohistochemical assays, we show convincingly that endogenous Cdc6 remains nuclear and chromatin bound throughout the entire S period, while Mcm5 loses chromatin affinity during S phase. Overexpression of cyclin A is unable to alter the nuclear localization of Cdc6. Furthermore, using a phosphospecific antibody we show that phosphoserine-54 Cdc6 maintains a high affinity for chromatin during the S period. Considering recent in vitro studies, these data are consistent with a proposed model in which Cdc6 is serine-54 phosphorylated during S phase and functions as a chromatin-bound signal that prevents reformation of prereplication complexes.     

Separate SCF(CDC4) recognition elements target Cdc6 for proteolysis in S phase and mitosis

The Cdc6 DNA replication initiation factor is targeted for ubiquitin-mediated proteolysis by the E3 ubiquitin ligase SCF(CDC4) from the end of G1phase until mitosis in the budding yeast Saccharomyces cerevisiae. Here we describe a dominant-negative CDC6 mutant that, when overexpressed, arrests the cell cycle by inhibiting cyclin-dependent kinases (CDKs) and, thus, prevents passage through mitosis. This mutant protein inhibits CDKs more efficiently than wild-type Cdc6, in part because it is completely refractory to SCF(CDC4)-mediated proteolysis late in the cell cycle and consequently accumulates to high levels. The mutation responsible for this phenotype destroys a putative CDK phosphorylation site near the middle of the Cdc6 primary amino acid sequence. We show that this site lies within a novel Cdc4-interacting domain distinct from a Cdc4-interacting site identified previously near the N-terminus of the protein. We show that both sites can target Cdc6 for proteolysis in late G1/early S phase whilst only the newly identified site can target Cdc6 for proteolysis during mitosis.