Phospho-Bcl-xL(Ser62) plays a key role at DNA damage-induced G2 checkpoint

Accumulating evidence suggests that Bcl-xL, an anti-apoptotic member of the Bcl-2 family, also functions in cell cycle progression and cell cycle checkpoints. Analysis of a series of phosphorylation site mutants reveals that cells expressing Bcl-xL(Ser62Ala) mutant are less stable at the G₂ checkpoint and enter mitosis more rapidly than cells expressing wild-type Bcl-xL or Bcl-xL phosphorylation site mutants, including Thr41Ala, Ser43Ala, Thr47Ala, Ser56Ala and Thr115Ala. Analysis of the dynamic phosphorylation and location of phospho-Bcl-xL(Ser62) in unperturbed, synchronized cells and during DNA damage-induced G₂ arrest discloses that a pool of phospho-Bcl-xL(Ser62) accumulates into nucleolar structures in etoposide-exposed cells during G₂ arrest. In a series of in vitro kinase assays, pharmacological inhibitors and specific siRNAs experiments, we found that Polo kinase 1 and MAPK9/JNK2 are major protein kinases involved in Bcl-xL(Ser62) phosphorylation and accumulation into nucleolar structures during the G₂ checkpoint. In nucleoli, phospho-Bcl-xL(Ser62) binds to and co-localizes with Cdk1(cdc2), the key cyclin-dependent kinase required for entry into mitosis. These data indicate that during G₂ checkpoint, phospho-Bcl-xL(Ser62) stabilizes G₂ arrest by timely trapping of Cdk1(cdc2) in nucleolar structures to slow mitotic entry. It also highlights that DNA damage affects the dynamic composition of the nucleolus, which now emerges as a piece of the DNA damage response.     

Bcl-xL phosphorylation at Ser49 by polo kinase 3 during cell cycle progression and checkpoints

Functional analysis of a Bcl-xL phosphorylation mutant series has revealed that cells expressing Bcl-xL(Ser49Ala) mutant are less stable at G2 checkpoint after DNA damage and enter cytokinesis more slowly after microtubule poisoning, than cells expressing wild-type Bcl-xL. These effects of Bcl-xL(Ser49Ala) mutant seem to be separable from Bcl-xL function in apoptosis. Bcl-xL(Ser49) phosphorylation is cell cycle-dependent. In synchronized cells, phospho-Bcl-xL(Ser49) appears during the S phase and G2, whereas it disappears rapidly in early mitosis during prometaphase, metaphase and early anaphase, and re-appears during telophase and cytokinesis. During DNA damage-induced G2 arrest, an important pool of phospho-Bcl-xL(Ser49) accumulates in centrosomes which act as essential decision centers for progression from G2 to mitosis. During telophase/cytokinesis, phospho-Bcl-xL(Ser49) is found with dynein motor protein. In a series of in vitro kinase assays, specific small interfering RNA and pharmacological inhibition experiments, polo kinase 3 (PLK3) was implicated in Bcl-xL(Ser49) phosphorylation. These data indicate that, during G2 checkpoint, phospho-Bcl-xL(Ser49) is another downstream target of PLK3, acting to stabilize G2 arrest. Bcl-xL phosphorylation at Ser49 also correlates with essential PLK3 activity and function, enabling cytokinesis and mitotic exit.     

Phospho-Bcl-xL(Ser62) influences spindle assembly and chromosome segregation during mitosis

Functional analysis of a series of phosphorylation mutants reveals that Bcl-xL(Ser62Ala) influences cell entry into anaphase and mitotic exit in taxol-exposed cells compared with cells expressing wild-type Bcl-xL or a series of other phosphorylation mutants, an effect that appears to be independent of its anti-apoptotic activity. During normal mitosis progression, Bcl-xL(Ser62) is strongly phosphorylated by PLK1 and MAPK14/SAPKp38α at the prometaphase, metaphase, and the anaphase boundaries, while it is de-phosphorylated at telophase and cytokinesis. Phospho-Bcl-xL(Ser62) localizes in centrosomes with γ-tubulin and in the mitotic cytosol with some spindle-assembly checkpoint signaling components, including PLK1, BubR1, and Mad2. In taxol- and nocodazole-exposed cells, phospho-Bcl-xL(Ser62) also binds to Cdc20- Mad2-, BubR1-, and Bub3-bound complexes, while Bcl-xL(Ser62Ala) does not. Silencing Bcl-xL expression and expressing the phosphorylation mutant Bcl-xL(Ser62Ala) lead to an increased number of cells harboring mitotic spindle defects including multipolar spindle, chromosome lagging and bridging, aneuploidy with micro-, bi-, or multi-nucleated cells, and cells that fail to resolve undergo mitosis within 6 h. Together, the data indicate that during mitosis, Bcl-xL(Ser62) phosphorylation impacts on spindle assembly and chromosome segregation, influencing chromosome stability. Observations of mitotic cells harboring aneuploidy with micro-, bi-, or multi-nucleated cells, and cells that fail to resolve undergo mitosis within 6 h were also made with cells expressing the phosphorylation mutant Bcl-xL(Ser49Ala) and dual mutant Bcl-xL(Ser49/62Ala).     

Chk1 phosphorylation at Ser286 and Ser301 occurs with both stalled DNA replication and damage checkpoint stimulation

We previously reported Chk1 to be phosphorylated at Ser286 and Ser301 by cyclin-dependent kinase (Cdk) 1 during mitosis [T. Shiromizu et al., Genes Cells 11 (2006) 477-485]. Here, we demonstrated that Chk1-Ser286 and -Ser301 phosphorylation also occurs in hydroxyurea (HU)-treated or ultraviolet (UV)-irradiated cells. Unlike the mitosis case, however, Chk1 was phosphorylated not only at Ser286 and Ser301 but also at Ser317 and Ser345 in the checkpoint response. Treatment with Cdk inhibitors diminished Chk1 phosphorylation at Ser286 and Ser301 but not at Ser317 and Ser345 with the latter. In vitro analyses revealed Ser286 and Ser301 on Chk1 to serve as two major phosphorylation sites for Cdk2. Immunoprecipitation analyses further demonstrated that Ser286/Ser301 and Ser317/Ser345 phosphorylation occur in the same Chk1 molecule during the checkpoint response. In addition, Ser286/Ser301 phosphorylation by Cdk2 was observed in Chk1 mutated to Ala at Ser317 and Ser345 (S317A/S345A), as well as Ser317/Ser345 phosphorylation by ATR was in S286A/S301A. Therefore, Chk1 phosphorylation in the checkpoint response is regulated not only by ATR but also by Cdk2.     

MAPK Pathway Activation Delays G2/M Progression by Destabilizing Cdc25B

Activation of the mitogen-activated protein kinase (MAPK) pathway by growth factors or phorbol esters during G₂ phase delays entry into mitosis; however, the role of the MAPK pathway during G₂/M progression remains controversial. Here, we demonstrate that activation of the MAPK pathway with either epidermal growth factor or 12-O-tetradecanoylphorbol-13-acetate induces a G₂ phase delay independent of known G₂ phase checkpoint pathways but was specifically dependent on MAPK/extracellular signal-regulated kinase kinase (MEK1). Activation of MAPK signaling also blocked exit from a G₂ phase checkpoint arrest. Both the G₂ phase delay and blocked exit from the G₂ checkpoint arrest were mediated by the MEK1-dependent destabilization of the critical G₂/M regulator cdc25B. Reintroduction of cdc25B overcame the MEK1-dependent G₂ phase delay. Thus, we have demonstrated a new function for MEK1 that controls G₂/M progression by regulating the stability of cdc25B. This represents a novel mechanism by which factors that activate MAPK signaling can influence the timing of entry into mitosis, particularly exit from a G₂ phase checkpoint arrest.     

Mutants at Ser277 of Xenopus cdc2 protein kinase induce oocyte maturation in the absence of the positive regulatory phosphorylation site Thr161.

The cdc2 protein kinase is an important regulatory protein for both meiosis and mitosis. Previously, we demonstrated that simultaneous mutation of Thr14-->Ala14 and Tyr15-->Phe15 in the Xenopus cdc2 protein results in an activated cdc2 mutant that induces maturation in resting oocytes. In addition, we confirmed the importance of the positive regulatory phosphorylation site, Thr161, by demonstrating that cdc2 mutants containing additional mutations of Thr161-->Ala161 or Glu161 are inactive in the induction of oocyte maturation. Here, we have analyzed the importance of an additional putative cdc2 phosphorylation site,Ser277. Single mutation of Ser277-->Asp277 or Ala277 had no effect on activity, and these mutants were unable to induce Xenopus oocyte maturation. However, the double mutant Ala161/Asp277 was capable of inducing oocyte maturation, suggesting that mutation of Ser277-->Asp277 could compensate for the mutation of Thr161-->Ala161. The Asp277 mutation could also compensate for the Ala161 mutation in the background of the activating mutations Ala14/Phe15. Although mutants containing the compensatory Ala161 and Asp277 mutations were capable of inducing oocyte maturation, these mutant cdc2 proteins lacked detectable in vitro kinase activity. Tryptic phosphopeptide mapping of mutant cdc2 protein and comparison with in vitro synthesized peptides indicated that Ser277 is not a major site of phosphorylation in Xenopus oocytes; however, we cannot rule out the possibility of phosphorylation at this site in a biologically active subpopulation of cdc2 molecules. The data presented here, together with prior reports of Ser277 phosphorylation in somatic cells, suggest an important role for Ser277 in the regulation of cdc2 activity. The regulatory role of Ser277 most likely involves its indirect effects on the nearby residue Arg275, which participates in a structurally important ion pair with Glu173, which lies in the same loop as Thr161 in the cdc2 protein.     

Partial inhibition of Cdk1 in G2 phase overrides the SAC and decouples mitotic events

Entry and progression through mitosis has traditionally been linked directly to the activity of cyclin-dependent kinase 1 (Cdk1). In this study we utilized low doses of the Cdk1-specific inhibitor, RO3306 from early G₂ phase onwards. Addition of low doses of RO3306 in G₂ phase induced minor chromosome congression and segregation defects. In contrast, mild doses of RO3306 during G₂ phase resulted in cells entering an aberrant mitosis, with cells fragmenting centrosomes and failing to fully disassemble the nuclear envelope. Cells often underwent cytokinesis and metaphase simultaneously, despite the presence of an active spindle assembly checkpoint, which prevented degradation of cyclin B1 and securin, resulting in the random partitioning of whole chromosomes. This highly aberrant mitosis produced a significant increase in the proportion of viable polyploid cells present up to 3 days post-treatment. Furthermore, cells treated with medium doses of RO3306 were only able to reach the threshold of Cdk1 substrate phosphorylation required to initiate nuclear envelope breakdown, but failed to reach the levels of phosphorylation required to correctly complete pro-metaphase. Treatment with low doses of Okadaic acid, which primarily inhibits PP2A, rescued the mitotic defects and increased the number of cells that completed a normal mitosis. This supports the current model that PP2A is the primary phosphatase that counterbalances the activity of Cdk1 during mitosis. Taken together these results show that continuous and subtle disruption of Cdk1 activity from G₂ phase onwards has deleterious consequences on mitotic progression by disrupting the balance between Cdk1 and PP2A.     

Changes in regulatory phosphorylation of Cdc25C Ser287 and Wee1 Ser549 during normal cell cycle progression and checkpoint arrests

Entry into mitosis is catalyzed by cdc2 kinase. Previous work identified the cdc2-activating phosphatase cdc25C and the cdc2-inhibitory kinase wee1 as targets of the incomplete replication-induced kinase Chk1. Further work led to the model that checkpoint kinases block mitotic entry by inhibiting cdc25C through phosphorylation on Ser287 and activating wee1 through phosphorylation on Ser549. However, almost all conclusions underlying this idea were drawn from work using recombinant proteins. Here, we report that in the early Xenopus egg cell cycles, phosphorylation of endogenous cdc25C Ser287 is normally high during interphase and shows no obvious increase after checkpoint activation. By contrast, endogenous wee1 Ser549 phosphorylation is low during interphase and increases after activation of either the DNA damage or replication checkpoints; this is accompanied by a slight increase in wee1 kinase activity. Blocking mitotic entry by adding the catalytic subunit of PKA also results in increased wee1 Ser549 phosphorylation and maintenance of cdc25C Ser287 phosphorylation. These results argue that in response to checkpoint activation, endogenous wee1 is indeed a critical responder that functions by repressing the cdc2-cdc25C positive feedback loop. Surprisingly, endogenous wee1 Ser549 phosphorylation is highest during mitosis just after the peak of cdc2 activity. Treatments that block inactivation of cdc2 result in further increases in wee1 Ser549 phosphorylation, suggesting a previously unsuspected role for wee1 in mitosis.     

Phosphorylation statuses at different residues of lamin B2, B1, and A/C dynamically and independently change throughout the cell cycle

Lamins, major components of the nuclear lamina, undergo phosphorylation at multiple residues during cell cycle progression, but their detailed phosphorylation kinetics remain largely undetermined. Here, we examined changes in the phosphorylation of major phosphorylation residues (Thr14, Ser17, Ser385, Ser387, and Ser401) of lamin B2 and the homologous residues of lamin B1, A/C during the cell cycle using novel antibodies to the site-specific phosphorylation. The phosphorylation levels of these residues independently changed during the cell cycle. Thr14 and Ser17 were phosphorylated during G₂/M phase to anaphase/telophase. Ser385 was persistently phosphorylated during mitosis to G₁ phase, whereas Ser387 was phosphorylated discontinuously in prophase and G₁ phase. Ser401 phosphorylation was enhanced in the G₁/S boundary. Immunoprecipitation using the phospho-antibodies suggested that metaphase-phosphorylation at Thr14, Ser17, and Ser385 of lamins occurred simultaneously, whereas G₁-phase phosphorylation at Ser385 and Ser387 occurred in distinct pools or with different timings. Additionally, we showed that lamin B2 phosphorylated at Ser17, but not Ser385, Ser387 and Ser401, was exclusively non-ionic detergent soluble, depolymerized forms in growing cells, implicating specific involvement of Ser17 phosphorylation in lamin depolymerization and nuclear envelope breakdown. These results suggest that the phosphorylations at different residues of lamins might play specific roles throughout the cell cycle.     

New alternative phosphorylation sites on the cyclin dependent kinase 1/cyclin a complex in p53-deficient human cells treated with etoposide: possible association with etoposide-induced apoptosis

Cell cycle arrest is a major cellular response to DNA damage preceding the decision to repair or die. Many malignant cells have non-functional p53 rendering them more “aggressive” in nature. Arrest in p53-negative cells occurs at the G2M cell cycle checkpoint. Failure of DNA damaged cells to arrest at G2 results in entry into mitosis and potential death through aberrant mitosis and/or apoptosis. The pivotal kinase regulating the G2M checkpoint is Cdk1/cyclin B whose activity is controlled by phosphorylation. The p53-negative myeloid leukemia cell lines K562 and HL-60 were used to determine Cdk1 phosphorylation status during etoposide treatment. Cdk1 tyrosine 15 phosphorylation was associated with G2M arrest, but not with cell death. Cdk1 tyrosine 15 phosphorylation also led to suppression of nuclear cyclin B-associated Cdk1 kinase activity. However cell death, associated with broader tyrosine phosphorylation of Cdk1 was not attributed to tyrosine 15 alone. This broader phosphoryl isoform of Cdk1 was associated with cyclin A and not cyclin B. Alternative phosphorylations sites were predicted as tyrosines 4, 99 and 237 by computer analysis. No similar pattern was found on Cdk2. These findings suggest novel Cdk1 phosphorylation sites, which appear to be associated with p53-independent cell death following etoposide treatment.     

Two different protein kinases act on a different time schedule as glial filament kinases during mitosis.

Glial fibrillary acidic protein (GFAP) is a component of glial filaments specific to astroglia. We now report the spatial and temporal distributions of four phosphorylated sites in the GFAP molecule during mitosis of astroglial cells, determined by antibodies which can distinguish phosphorylated epitopes from non-phosphorylated-epitopes. Immunofluorescence microscopy showed that the Ser8 residues in the entire cytoplasmic glial filament system are initially phosphorylated when the cells enter mitosis. In cytokinesis, the phosphoSer8 residues become dephosphorylated, whereas Thr7, Ser13 and Ser34 in glial filaments at the cleavage furrow become the preferred sites of phosphorylation. The cdc2 kinase purified from mitotic cells can phosphorylate GFAP at Ser8 but not at Thr7, Ser13 or Ser34, in vitro. These results suggest that cdc2 kinase acts as a glial filament kinase only at the G2-M phase transition while other glial filament kinases are probably activated at the cleavage furrow before final separation of the daughter cells.     

Cdk1 phosphorylation of BubR1 controls spindle checkpoint arrest and Plk1-mediated formation of the 3F3/2 epitope

Accurate chromosome segregation is controlled by the spindle checkpoint, which senses kinetochore– microtubule attachments and tension across sister kinetochores. An important step in the tension-signaling pathway involves the phosphorylation of an unknown protein by polo-like kinase 1/Xenopus laevis polo-like kinase 1 (Plx1) on kinetochores lacking tension to generate the 3F3/2 phosphoepitope. We report here that the checkpoint protein BubR1 interacts with Plx1 and that phosphorylation of BubR1 by Plx1 generates the 3F3/2 epitope. Formation of the BubR1 3F3/2 epitope by Plx1 requires a prior phosphorylation of BubR1 on Thr 605 by cyclin-dependant kinase 1 (Cdk1). This priming phosphorylation of BubR1 by Cdk1 is required for checkpoint-mediated mitotic arrest and for recruitment of Plx1 and the checkpoint protein Mad2 to unattached kinetochores. Biochemically, formation of the 3F3/2 phosphoepitope by Cdk1 and Plx1 greatly enhances the kinase activity of BubR1. Thus, Cdk1-mediated phosphorylation of BubR1 controls checkpoint arrest and promotes the formation of the kinetochore 3F3/2 epitope.     

Two S-phase checkpoint systems, one involving the function of both BIME and Tyr15 phosphorylation of p34cdc2, inhibit NIMA and prevent premature mitosis.

We demonstrate that there are at least two S-phase checkpoint mechanisms controlling mitosis in Aspergillus. The first responds to the rate of DNA replication and inhibits mitosis via tyrosine phosphorylation of p34cdc2. Cells unable to tyrosine phosphorylate p34cdc2 are therefore viable but are unable to tolerate low levels of hydroxyurea and prematurely enter lethal mitosis when S-phase is slowed. However, if the NIMA mitosis-promoting kinase is inactivated then non-tyrosine-phosphorylated p34cdc2 cannot promote cells prematurely into mitosis. Lack of tyrosine-phosphorylated p34cdc2 also cannot promote mitosis, or lethality, if DNA replication is arrested, demonstrating the presence of a second S-phase checkpoint mechanism over mitotic initiation which we show involves the function of BIME. In order to overcome the S-phase arrest checkpoint over mitosis it is necessary both to prevent tyrosine phosphorylation of p34cdc2 and also to inactivate BIME. Lack of tyrosine phosphorylation of p34cdc2 allows precocious expression of NIMA during S-phase arrest, and lack of BIME then allows activation of this prematurely expressed NIMA by phosphorylation. The mitosis-promoting NIMA kinase is thus a target for S-phase checkpoint controls.     

The Protein Kinase C�� Catalytic Fragment Is Critical for Maintenance of the G2/M DNA Damage Checkpoint

Protein kinase Cδ (PKCδ) is an essential component of the intrinsic apoptotic program. Following DNA damage, such as exposure to UV radiation, PKCδ is cleaved in a caspase-dependent manner, generating a constitutively active catalytic fragment (PKCδ-cat), which is necessary and sufficient for keratinocyte apoptosis. We found that in addition to inducing apoptosis, expression of PKCδ-cat caused a pronounced G₂/M cell cycle arrest in both primary human keratinocytes and immortalized HaCaT cells. Consistent with a G₂/M arrest, PKCδ-cat induced phosphorylation of Cdk1 (Tyr¹⁵), a critical event in the G₂/M checkpoint. Treatment with the ATM/ATR inhibitor caffeine was unable to prevent PKCδ-cat-induced G₂/M arrest, suggesting that PKCδ-cat is functioning downstream of ATM/ATR in the G₂/M checkpoint. To better understand the role of PKCδ and PKCδ-cat in the cell cycle response to DNA damage, we exposed wild-type and PKCδ null mouse embryonic fibroblasts (MEFs) to UV radiation. Wild-type MEFs underwent a pronounced G₂/M arrest, Cdk1 phosphorylation, and induction of apoptosis following UV exposure, whereas PKCδ null MEFs were resistant to these effects. Expression of PKCδ-green fluorescent protein, but not caspase-resistant or kinase-inactive PKCδ, was able to restore G₂/M checkpoint integrity in PKCδ null MEFs. The function of PKCδ in the DNA damage-induced G₂/M cell cycle checkpoint may be a critical component of its tumor suppressor function.     

“Ready,Set, Go”: Checkpoint regulation by Cdk1 inhibitory phosphorylation

ABSTRACT

Cell cycle checkpoints prevent mitosis from occurring before DNA replication and repair are completed during S and G2 phases. The checkpoint mechanism involves inhibitory phosphorylation of Cdk1, a conserved kinase that regulates the onset of mitosis. Metazoans have two distinct Cdk1 inhibitory kinases with specialized developmental functions: Wee1 and Myt1. Ayeni et al used transgenic Cdk1 phospho-acceptor mutants to analyze how the distinct biochemical properties of these kinases affected their functions. They concluded from their results that phosphorylation of Cdk1 on Y15 was necessary and sufficient for G2/M checkpoint arrest in imaginal wing discs, whereas phosphorylation on T14 promoted chromosome stability by a different mechanism. A curious relationship was also noted between Y15 inhibitory phosphorylation and T161 activating phosphorylation. These unexpected complexities in Cdk1 inhibitory phosphorylation demonstrate that the checkpoint mechanism is not a simple binary “off/on” switch, but has at least three distinct states: “Ready”, to prevent chromosome damage and apoptosis, “Set”, for developmentally regulated G2 phase arrest, and “Go”, when Cdc25 phosphatases remove inhibitory phosphates to trigger Cdk1 activation at the G2/M transition.     

Induction of a G2-Phase Arrest in Xenopus Egg Extracts by Activation of p42 Mitogen-activated Protein Kinase

Previous work has established that activation of Mos, Mek, and p42 mitogen-activated protein (MAP) kinase can trigger release from G₂-phase arrest in Xenopus oocytes and oocyte extracts and can cause Xenopus embryos and extracts to arrest in mitosis. Herein we have found that activation of the MAP kinase cascade can also bring about an interphase arrest in cycling extracts. Activation of the cascade early in the cycle was found to bring about the interphase arrest, which was characterized by an intact nuclear envelope, partially condensed chromatin, and interphase levels of H1 kinase activity, whereas activation of the cascade just before mitosis brought about the mitotic arrest, with a dissolved nuclear envelope, condensed chromatin, and high levels of H1 kinase activity. Early MAP kinase activation did not interfere significantly with DNA replication, cyclin synthesis, or association of cyclins with Cdc2, but it did prevent hyperphosphorylation of Cdc25 and Wee1 and activation of Cdc2/cyclin complexes. Thus, the extracts were arrested in a G₂-like state, unable to activate Cdc2/cyclin complexes. The MAP kinase-induced G₂ arrest appeared not to be related to the DNA replication checkpoint and not to be mediated through inhibition of Cdk2/cyclin E; evidently a novel mechanism underlies this arrest. Finally, we found that by delaying the inactivation of MAP kinase during release of a cytostatic factor-arrested extract from its arrest state, we could delay the subsequent entry into mitosis. This finding suggests that it is the persistence of activated MAP kinase after fertilization that allows the occurrence of a G₂-phase during the first mitotic cell cycle.     

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.     

Phosphorylation of p27Kip1 at Thr187 by Cyclin-dependent Kinase 5 Modulates Neural Stem Cell Differentiation

Cyclin-dependent kinase 5 (Cdk5) plays a key role in the development of the mammalian nervous system; it phosphorylates a number of targeted proteins involved in neuronal migration during development to synaptic activity in the mature nervous system. Its role in the initial stages of neuronal commitment and differentiation of neural stem cells (NSCs), however, is poorly understood. In this study, we show that Cdk5 phosphorylation of p27^Kip1 at Thr187 is crucial to neural differentiation because 1) neurogenesis is specifically suppressed by transfection of p27^Kip1 siRNA into Cdk5^+/+ NSCs; 2) reduced neuronal differentiation in Cdk5^−/− compared with Cdk5^+/+ NSCs; 3) Cdk5^+/+ NSCs, whose differentiation is inhibited by a nonphosphorylatable mutant, p27/Thr187A, are rescued by cotransfection of a phosphorylation-mimicking mutant, p27/Thr187D; and 4) transfection of mutant p27^Kip1 (p27/187A) into Cdk5^+/+ NSCs inhibits differentiation. These data suggest that Cdk5 regulates the neural differentiation of NSCs by phosphorylation of p27^Kip1 at theThr187 site. Additional experiments exploring the role of Ser10 phosphorylation by Cdk5 suggest that together with Thr187 phosphorylation, Ser10 phosphorylation by Cdk5 promotes neurite outgrowth as neurons differentiate. Cdk5 phosphorylation of p27^Kip1, a modular molecule, may regulate the progress of neuronal differentiation from cell cycle arrest through differentiation, neurite outgrowth, and migration.     

Wip1 contributes to cell homeostasis maintained by the steady-state level of Wtp53

Wip1, a human protein Ser/Thr phosphatase also called PPM1D, stands for wild-type p53 induced phosphatase 1. Emerging evidences indicate that Wip1 can act as an oncogene largely by turning off DNA damage checkpoint responses. Here we report an unrecognized role of Wipl in normally growing cells. Wip1 can be induced by wild-type p53 under not only stressed but also non-stressed conditions. It can trigger G₂/M arrest in wild-type p53 containing cells, which was attributed to the decreased Cdc2 kinase activity resulting at least partly from a high level of inhibitory tyrosine phosphorylation on Cdc2 protein at Tyr-15. Furthermore, we also found that Wip1 not only causes G₂/M arrest but also decreases cell death triggered by microtubule assembly inhibitor in mouse fibroblasts when wild-type p53 function was restored. These results indicate that Wip1 can provide ample time for wild-type p53-containing cells to prepare entry into mitosis and avoid encountering mitotic catastrophe. Therefore, Wipl may play important roles in cell/tissue homeostasis maintained by wild-type p53 under normal conditions, enhancing our understanding of how p53 makes cell-fate decisions.Key words: p53, Wip1, cell homeostasis, cell arrest, cell death