Inactivating Cdc25, Mitotic Style

Mitotic entry and exit require activation and inactivation of the Cdk1-cyclin B kinase complex, respectively. The Cdc25 protein phosphatase family activates Cdk1-cyclin B at the G2/M transition by removing inhibitory phosphate groups. Cdc25 family members, held inactive during interphase, are activated during mitotic progression in an amplification loop involving Cdk1-cyclin B. While Cdc25 activation at the G2/M transition is required for the timely initiation of mitosis, recent evidence suggests that the inactivation of Cdc25 in late mitosis may play a role in supporting Cdk1-cyclin B inactivation. Here, we discuss the mechanisms of Cdc25 regulation and how they pertain to both mitotic entry and exit.     

Inactivating Cdc25, mitotic style

Mitotic entry and exit require activation and inactivation of the Cdk1-cyclin B kinase complex, respectively. The Cdc25 protein phosphatase family activates Cdk1-cyclin B at the G2/M transition by removing inhibitory phosphate groups. Cdc25 family members, held inactive during interphase, are activated during mitotic progression in an amplification loop involving Cdk1-cyclin B. While Cdc25 activation at the G2/M transition is required for the timely initiation of mitosis, recent evidence suggests that the inactivation of Cdc25 in late mitosis may play a role in supporting Cdk1-cyclin B inactivation. Here, we discuss the mechanisms of Cdc25 regulation and how they pertain to both mitotic entry and exit.     

Human Cdc14A becomes a cell cycle gene in controlling Cdk1 activity at the G2/M transition

Cdc14 belongs to a dual-specificity phosphatase family highly conserved through evolution that preferentially reverses CDK (Cyclin dependent kinases) –dependent phosphorylation events. In the yeast Saccharomyces cerevisiae, Cdc14 is an essential regulator of late mitotic events and exit from mitosis by counteracting CDK activity at the end of mitosis. However, many studies have shown that Cdc14 is dispensable for exiting mitosis in all other model systems analyzed. In fission yeast, the Cdc14 homologue Flp1/Clp1 regulates the stability of the mitotic inducer Cdc25 at the end of mitosis to ensure Cdk1 inactivation before cytokinesis. We have recently reported that human Cdc14A, the Cdc14 isoform located at the centrosomes during interphase, down-regulates Cdc25 activity at the G2/M transition to prevent premature activation of Cdk1-Cyclin B1 complexes and untimely entry into mitosis. Here we speculate about new molecular mechanisms for Cdc14A and discuss the current evidence suggesting that Cdc14 phosphatase plays a role in cell cycle control in higher eukaryotes.     

Human Cdc14B promotes progression through mitosis by dephosphorylating Cdc25 and regulating Cdk1/cyclin B activity

Entry into and progression through mitosis depends on phosphorylation and dephosphorylation of key substrates. In yeast, the nucleolar phosphatase Cdc14 is pivotal for exit from mitosis counteracting Cdk1-dependent phosphorylations. Whether hCdc14B, the human homolog of yeast Cdc14, plays a similar function in mitosis is not yet known. Here we show that hCdc14B serves a critical role in regulating progression through mitosis, which is distinct from hCdc14A. Unscheduled overexpression of hCdc14B delays activation of two master regulators of mitosis, Cdc25 and Cdk1, and slows down entry into mitosis. Depletion of hCdc14B by RNAi prevents timely inactivation of Cdk1/cyclin B and dephosphorylation of Cdc25, leading to severe mitotic defects, such as delay of metaphase/anaphase transition, lagging chromosomes, multipolar spindles and binucleation. The results demonstrate that hCdc14B-dependent modulation of Cdc25 phosphatase and Cdk1/cyclin B activity is tightly linked to correct chromosome segregation and bipolar spindle formation, processes that are required for proper progression through mitosis and maintenance of genomic stability.     

Functional homology among human and fission yeast Cdc14 phosphatases

Budding and fission yeast Cdc14 homologues, a conserved family of serine-threonine phosphatases, play a role in the inactivation of mitotic cyclin-dependent kinases (CDKs) by molecularly distinct mechanisms. Saccharomyces cerevisiae Cdc14 protein phosphatase inactivates CDKs by promoting mitotic cyclin degradation and the accumulation of a CDK inhibitor to allow budding yeast cells to exit from mitosis. Schizosaccharomyces pombe Flp1 phosphatase down-regulates CDK/cyclin activity, controlling the degradation of the Cdc25 tyrosine phosphatase for fission yeast cells to undergo cytokinesis. In the present work, we show that human Cdc14 homologues (hCdc14A and hCdc14B) rescued flp1-deficient fission yeast strains, indicating functional homology. We also show that hCdc14A and B interacted in vivo with S. pombe Cdc25 and that hCdc14A dephosphorylated this mitotic inducer both in vitro and in vivo. Our results support a Cdc14 conserved inhibitory mechanism acting on S. pombe Cdc25 protein and suggest that human cells may regulate Cdc25 in a similar manner to inactivate Cdk1-mitotic cyclin complexes.     

Fission yeast Clp1p phosphatase affects G2/M transition and mitotic exit through Cdc25p inactivation

The Cdc14 family of phosphatases specifically reverses proline-directed phosphorylation events. In Saccharomyces cerevisiae, Cdc14p promotes Cdk1p inactivation at mitotic exit by reversing Cdk1p-dependent phosphorylations. Cdk1p is a proline-directed kinase whose activity is required in all eukaryotes for the transit into mitosis. At mitotic commitment, Cdk1p participates in its own regulation by activating the mitotic inducing phosphatase, Cdc25p, and inhibiting the opposing kinase, Wee1p. We have investigated the ability of Schizosaccharomyces pombe Clp1p, a Cdc14p homolog, to disrupt this auto-amplification loop. We show here that Clp1p is required to dephosphorylate, destabilize, and inactivate Cdc25p at the end of mitosis. Clp1p promotes recognition of Cdc25p by the anaphase-promoting complex/cyclosome, an E3 ubiquitin ligase. Failure to inactivate and destabilize Cdc25p in late mitosis delays progression through anaphase, interferes with septation initiation network signaling, and additionally advances the commitment to mitotic entry in the next cycle. This may be a widely conserved mechanism whereby Cdc14 proteins contribute to Cdk1p inactivation.     

Phospho-regulation of the Cdc14/Clp1 phosphatase delays late mitotic events in S. pombe

In eukaryotes, exit from mitosis occurs through the inactivation of the Cdk1-cyclin B kinase complex and the reversal of its phosphorylation events. These late mitotic events are tightly regulated to occur only after the onset of anaphase and prior to cytokinesis. Central to this regulation is the conserved Cdc14 family of protein phosphatases, whose activity reverses Cdk-dependent phosphorylation events. S. cerevisiae Cdc14 activity is restrained from dephosphorylating Cdk substrates and inactivating Cdk1 through its nucleolar sequestration prior to anaphase. Here, we describe a unique mode of Cdc14 regulation that operates prior to anaphase in fission yeast. Cdk1 phosphorylates and inhibits the catalytic activity of the Cdc14 family member, Clp1/Flp1. As Cdk1 activity declines during anaphase progression, Clp1/Flp1 autocatalytically reverses these phosphorylation events to stimulate its own activity. These findings point to a simple regulatory circuit that couples Cdk1 activation with its inactivation mediated through phosphorylation-dependent regulation of Clp1/Flp1 phosphatase activity.     

The role of Cdc25 phosphatases in cell cycle checkpoints

Summary The major driving forces in the eukaryotic cell cycle are the cyclin-dependent kinases (Cdk). Cdks can be activated through dephosphorylation of inhibitory phosphorylations catalyzed by the Cdc25 phosphatase family. In higher-eukaryotic cells, there exist three Cdc25 family members, Cdc25A, Cdc25B, and Cdc25C. While Cdc25A plays a major role at the G₁-to-S phase transition, Cdc25B and C are required for entry into mitosis. The regulation of Cdc25C is crucial for the operation of the DNA-damage checkpoint. Two protein kinases, Chk1 and Cds1, can be activated in response to DNA damage or in the presence of unreplicated DNA. Chk1 and Cds1 may phosphorylate Cdc25C to prevent entry into mitosis through inhibition of Cdc2 (Cdk1) dephosphorylation.     

When the Checkpoints Have Gone: Insights into Cdc25 Functional Activation

DNA-responsive checkpoints operate at the G2/M transition to prevent premature mitosis in the presence of incompletely replicated or damaged DNA. These pathways prevent mitotic entry, at least in part, by suppressing Cdc25, the phosphatase that activates Cdc2/Cyclin B. To gain insight into how checkpoint signaling controls Cdc25 function, we have carefully examined the individual steps in Cdc25 activation. We found that removal of the regulatory protein, 14-3-3, that binds to phosphorylated Cdc25 during interphase is one of the early steps in mitotic activation. Moreover, our studies unexpectedly implicated the phosphatase PP1 and the G1/S kinase Cdk2 in the process of Cdc25 activation. Here we integrate our findings and those of others to propose a model for Cdc25 activation in an effort to provide insight into novel loci of DNA-responsive checkpoint control of mitotic entry.     

Cdc25 Phosphatases Are Required for Timely Assembly of CDK1-Cyclin B at the G2/M Transition

Progression through mitosis requires the coordinated regulation of Cdk1 kinase activity. Activation of Cdk1 is a multistep process comprising binding of Cdk1 to cyclin B, relocation of cyclin-kinase complexes to the nucleus, activating phosphorylation of Cdk1 on Thr¹⁶¹ by the Cdk-activating kinase (CAK; Cdk7 in metazoans), and removal of inhibitory Thr¹⁴ and Tyr¹⁵ phosphorylations. This dephosphorylation is catalyzed by the dual specific Cdc25 phosphatases, which occur in three isoforms in mammalian cells, Cdc25A, -B, and -C. We find that expression of Cdc25A leads to an accelerated G₂/M phase transition. In Cdc25A-overexpressing cells, Cdk1 exhibits high kinase activity despite being phosphorylated on Tyr¹⁵. In addition, Tyr¹⁵-phosphorylated Cdk1 binds more cyclin B in Cdc25A-overexpressing cells compared with control cells. Consistent with this observation, we demonstrate that in human transformed cells, Cdc25A and Cdc25B, but not Cdc25C phosphatases have an effect on timing and efficiency of cyclin-kinase complex formation. Overexpression of Cdc25A or Cdc25B promotes earlier assembly and activation of Cdk1-cyclin B complexes, whereas repression of these phosphatases by short hairpin RNA has a reverse effect, leading to a substantial decrease in amounts of cyclin B-bound Cdk1 in G₂ and mitosis. Importantly, we find that Cdc25A overexpression leads to an activation of Cdk7 and increase in Thr¹⁶¹ phosphorylation of Cdk1. In conclusion, our data suggest that complex assembly and dephosphorylation of Cdk1 at G₂/M is tightly coupled and regulated by Cdc25 phosphatases.     

When the checkpoints have gone: insights into Cdc25 functional activation

DNA-responsive checkpoints operate at the G(2)/M transition to prevent premature mitosis in the presence of incompletely replicated or damaged DNA. These pathways prevent mitotic entry, at least in part, by suppressing Cdc25, the phosphatase that activates Cdc2/Cyclin B. To gain insight into how checkpoint signaling controls Cdc25 function, we have carefully examined the individual steps in Cdc25 activation. We found that removal of the regulatory protein, 14-3-3, that binds to phosphorylated Cdc25 during interphase is one of the early steps in mitotic activation. Moreover, our studies unexpectedly implicated the phosphatase PP1 and the G(1)/S kinase Cdk2 in the process of Cdc25 activation. Here we integrate our findings and those of others to propose a model for Cdc25 activation in an effort to provide insight into novel loci of DNA-responsive checkpoint control of mitotic entry.     

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.     

The Zds proteins control entry into mitosis and target protein phosphatase 2A to the Cdc25 phosphatase

The Wee1 kinase restrains entry into mitosis by phosphorylating and inhibiting cyclin-dependent kinase 1 (Cdk1). The Cdc25 phosphatase promotes entry into mitosis by removing Cdk1 inhibitory phosphorylation. Experiments in diverse systems have established that Wee1 and Cdc25 are regulated by protein phosphatase 2A (PP2A), but a full understanding of the function and regulation of PP2A in entry into mitosis has remained elusive. In budding yeast, entry into mitosis is controlled by a specific form of PP2A that is associated with the Cdc55 regulatory subunit (PP2A(Cdc55)). We show here that related proteins called Zds1 and Zds2 form a tight stoichiometric complex with PP2A(Cdc55) and target its activity to Cdc25 but not to Wee1. Conditional inactivation of the Zds proteins revealed that their function is required primarily at entry into mitosis. In addition, Zds1 undergoes cell cycle-dependent changes in phosphorylation. Together, these observations define a role for the Zds proteins in controlling specific functions of PP2A(Cdc55) and suggest that upstream signals that regulate PP2A(Cdc55) may play an important role in controlling entry into mitosis.     

Chk1, but not Chk2, inhibits Cdc25 phosphatases by a novel common mechanism

Cdc25 phosphatases activate cyclin-dependent kinases (Cdks) and thereby promote cell cycle progression. In vertebrates, Chk1 and Chk2 phosphorylate Cdc25A at multiple N-terminal sites and target it for rapid degradation in response to genotoxic stress. Here we show that Chk1, but not Chk2, phosphorylates Xenopus Cdc25A at a novel C-terminal site (Thr504) and inhibits it from C-terminally interacting with various Cdk-cyclin complexes, including Cdk1-cyclin A, Cdk1-cyclin B, and Cdk2-cyclin E. Strikingly, this inhibition, rather than degradation itself, of Cdc25A is essential for the Chk1-induced cell cycle arrest and the DNA replication checkpoint in early embryos. 14-3-3 proteins bind to Chk1-phosphorylated Thr504, but this binding is not required for the inhibitory effect of Thr504 phosphorylation. A C-terminal site presumably equivalent to Thr504 exists in all known Cdc25 family members from yeast to humans, and its phosphorylation by Chk1 (but not Chk2) can also inhibit all examined Cdc25 family members from C-terminally interacting with their Cdk-cyclin substrates. Thus, Chk1 but not Chk2 seems to inhibit virtually all Cdc25 phosphatases by a novel common mechanism.     

Mitotic Phosphorylation of Cdc25B Ser321 Disrupts 14-3-3 Binding to the High Affinity Ser323 Site

Cdc25B is a key regulator of entry into mitosis, and its activity and localization are regulated by binding of the 14-3-3 dimer. There are three 14-3-3 binding sites on Cdc25B, with Ser³²³ being the highest affinity binding and is highly homologous to the Ser²¹⁶ 14-3-3 binding site on Cdc25C. Loss of 14-3-3 binding to Ser³²³ increases cyclin/Cdk substrate access to the catalytic site, thereby increasing its activity. It also affects the localization of Cdc25B. Thus, phosphorylation and 14-3-3 binding to this site is essential for down-regulating Cdc25B activity, blocking its mitosis promoting function. The question of how this inhibitory signal is relieved to allow Cdc25B activation and entry into mitosis is yet to be resolved. Here, we show that Ser³²³ phosphorylation is maintained into mitosis, but phosphorylation of Ser³²¹ disrupts 14-3-3 binding to Ser³²³, mimicking the effect of inhibiting Ser³²³ phosphorylation on both Cdc25B activity and localization. The unphosphorylated Ser³²¹ appears to have a role in stabilizing 14-3-3 binding to Ser³²³, and loss of the Ser hydroxyl group appears to be sufficient to significantly reduce 14-3-3 binding. A consequence of loss of 14-3-3 binding is dephosphorylation of Ser³²³. Ser³²¹ is phosphorylated in mitosis by Cdk1. The mitotic phosphorylation of Ser³²¹ acts to maintain full activation of Cdc25B by disrupting 14-3-3 binding to Ser³²³ and enhancing the dephosphorylation of Ser³²³ to block 14-3-3 binding to this site.     

Analysis of the role of phosphorylation in fission yeast Cdc13p/cyclinB function

The Cdk1p-cyclin B complex drives entry into mitosis in all eukaryotes. Cdc13p is the single essential cyclin in Schizosaccharomyces pombe and a member of the cyclin B family. Cdc13p abundance rises during G(2)-phase and falls as cells progress through mitosis and G(1). Cdc13p degradation, mediated by the anaphase-promoting complex, is an important mechanism of Cdk1p inhibition and mitotic exit. Cdk1p-cyclin B1 complexes shuttle between the nucleus and cytoplasm, and preventing nuclear accumulation of Cdk1p-cyclin B1 in mammalian cells appears to be one mechanism of preventing entry into mitosis during a DNA damage-induced checkpoint delay. In vertebrates, phosphorylation plays a key role in regulating the intracellular distribution of cyclins. Previous mass spectrometric analysis identified sites of Cdc13p phosphorylation. Here, we have confirmed that these sites are the sole in vivo Cdc13p phosphorylation sites and have studied the role that phosphorylation plays in Cdc13p localization and function. Our data indicate that Cdc13p accumulates in the nucleolus in response to G(2) checkpoint delays, rather than in the cytoplasm, and that phosphorylation plays no role in Cdc13p localization or function.     

Proteasome-dependent degradation of human CDC25B phosphatase

The CDC25 dual specificity phosphatase is a universal cell cycle regulator. The evolutionary conservation of this enzyme from yeast to man bears witness to its major role in the control of cyclin-dependent kinases (CDK) activity that are central regulators of the cell cycle machinery. CDC25 phosphatase both dephosphorylates and activates CDKs. Three human CDC25s have been identified. CDC25A is involved in the control of G1/S, and CDC25C at G2/M throught the activation of CDK1-cyclin B. The exact function of CDC25B however remains elusive. We have found that CDC25B is degraded by the proteasome pathway in vitro and in vivo. This degradation is dependent upon phosphorylation by the CDK1-cyclin A complex, but not by CDK1-cyclin B. Together with the observations of others made in yeast and mammals, our results suggest that CDC25B might act as a mitotic starter triggering the activation of an auto-amplification loop before being degraded.     

Chk1-Dependent Regulation of Cdc25B Functions to Coordinate Mitotic Events

The coordination of mitotic spindle formation and chromatin condensation is an essential prerequisite for successful mitosis. Both events are thought to be initiated by cyclin B/Cdk1, whose initial activation occurs in late prophase at the centrosomes. Recently, we have shown that Chk1 localizes to interphase centrosomes and thereby negatively regulates entry into mitosis by preventing premature activation of cyclin B/Cdk1. Here, we demonstrate that inhibition of Chk1 kinase induces mitotic entry with regular spindle assembly but aberrant and mislocalized chromatin. This effect, which we have termed the ‘paraspindle’ phenotype, was reverted by downregulation of Cdc25B phosphatase using siRNA, which restored normal mitosis with regular chromatin. Analogous to Chk1 inhibition, the ‘paraspindle’ phenotype was induced by overexpression of Cdc25B but not Cdc25A. Our results suggest that Chk1 functions to coordinate mitotic events through regulation of Cdc25B.     

The cdc25 phosphatase is essential for the G2/M phase transition in the basidiomycete yeast Ustilago maydis

Cdc25-related phosphatases reverse the inhibitory phosphorylation of mitotic Cyclin-dependent kinases mediated by Wee1-related kinases, thereby promoting entry into mitosis. In the fission yeast, Schizosaccharomyces pombe, Cdc25 is required for entry into mitosis, while in the budding yeast Saccharomyces cerevisiae, Mih1 (the homologue of Cdc25) is not required for entry into mitosis or for viability. As these differences were linked to the different cell division and growth mechanism of these species, we sought to analyse the roles of Cdc25 in Ustilago maydis, which as S. cerevisiae divides by budding, but relies in a polar growth. This basidiomycete yeast is perfectly suited to analyse the relationships between cell cycle and morphogenesis. We show that U. maydis contains a single Cdc25-related protein, which is essential for growth. Loss of Cdc25 function results in a specific G2 arrest that correlated with high level of Tyr15 phosphorylation of Cdk1. Moreover, we show genetic interactions of cdc25 with wee1 and clb2 that support the notion that in U. maydis Cdc25 counteracts the Wee1-mediated inhibitory phosphorylation of Cdk1-Clb2 complex. Our results supports a model in which inhibitory phosphorylation of Cdk1 is a primary mechanism operating at G2/M transition in this fungus.     

Mitotic progression becomes irreversible in prometaphase and collapses when Wee1 and Cdc25 are inhibited

Mitosis requires precise coordination of multiple global reorganizations of the nucleus and cytoplasm. Cyclin-dependent kinase 1 (Cdk1) is the primary upstream kinase that directs mitotic progression by phosphorylation of a large number of substrate proteins. Cdk1 activation reaches the peak level due to positive feedback mechanisms. By inhibiting Cdk chemically, we showed that, in prometaphase, when Cdk1 substrates approach the peak of their phosphorylation, cells become capable of proper M-to-G1 transition. We interfered with the molecular components of the Cdk1-activating feedback system through use of chemical inhibitors of Wee1 and Myt1 kinases and Cdc25 phosphatases. Inhibition of Wee1 and Myt1 at the end of the S phase led to rapid Cdk1 activation and morphologically normal mitotic entry, even in the absence of G2. Dampening Cdc25 phosphatases simultaneously with Wee1 and Myt1 inhibition prevented Cdk1/cyclin B kinase activation and full substrate phosphorylation and induced a mitotic "collapse," a terminal state characterized by the dephosphorylation of mitotic substrates without cyclin B proteolysis. This was blocked by the PP1/PP2A phosphatase inhibitor, okadaic acid. These findings suggest that the positive feedback in Cdk activation serves to overcome the activity of Cdk-opposing phosphatases and thus sustains forward progression in mitosis.