Cpc2, a fission yeast homologue of mammalian RACK1 protein, interacts with Ran1 (Pat1) kinase To regulate cell cycle progression and meiotic development

The Schizosaccharomyces pombe ran1/pat1 gene regulates the transition between mitosis and meiosis. Inactivation of Ran1 (Pat1) kinase is necessary and sufficient for cells to exit the cell cycle and undergo meiosis. The yeast two-hybrid interaction trap was used to identify protein partners for Ran1/Pat1. Here we report the identification of one of these, Cpc2. Cpc2 encodes a homologue of RACK1, a WD protein with homology to the beta subunit of heterotrimeric G proteins. RACK1 is a highly conserved protein, although its function remains undefined. In mammalian cells, RACK1 physically associates with some signal transduction proteins, including Src and protein kinase C. Fission yeast cells containing a cpc2 null allele are viable but cell cycle delayed. cpc2Delta cells fail to accumulate in G(1) when starved of nitrogen. This leads to defects in conjugation and meiosis. Copurification studies show that although Cpc2 and Ran1 (Pat1) physically associate, Cpc2 does not alter Ran1 (Pat1) kinase activity in vitro. Using a Ran1 (Pat1) fusion to green fluorescent protein, we show that localization of the kinase is impaired in cpc2Delta cells. Thus, in parallel with the proposed role of RACK1 in mammalian cells, fission yeast cpc2 may function as an anchoring protein for Ran1 (Pat1) kinase. All defects associated with loss of cpc2 are reversed in cells expressing mammalian RACK1, demonstrating that the fission yeast and mammalian gene products are indeed functional homologues.     

The Role of the RACK1 Ortholog Cpc2p in Modulating Pheromone-Induced Cell Cycle Arrest in Fission Yeast

The detection and amplification of extracellular signals requires the involvement of multiple protein components. In mammalian cells the receptor of activated C kinase (RACK1) is an important scaffolding protein for signal transduction networks. Further, it also performs a critical function in regulating the cell cycle by modulating the G₁/S transition. Many eukaryotic cells express RACK1 orthologs, with one example being Cpc2p in the fission yeast Schizosaccharomyces pombe. In contrast to RACK1, Cpc2p has been described to positively regulate, at the ribosomal level, cells entry into M phase. In addition, Cpc2p controls the stress response pathways through an interaction with Msa2p, and sexual development by modulating Ran1p/Pat1p. Here we describe investigations into the role, which Cpc2p performs in controlling the G protein-mediated mating response pathway. Despite structural similarity to Gβ-like subunits, Cpc2p appears not to function at the G protein level. However, upon pheromone stimulation, cells overexpressing Cpc2p display substantial cell morphology defects, disorientation of septum formation and a significantly protracted G₁ arrest. Cpc2p has the potential to function at multiple positions within the pheromone response pathway. We provide a mechanistic interpretation of this novel data by linking Cpc2p function, during the mating response, with its previous described interactions with Ran1p/Pat1p. We suggest that overexpressing Cpc2p prolongs the stimulated state of pheromone-induced cells by increasing ste11 gene expression. These data indicate that Cpc2p regulates the pheromone-induced cell cycle arrest in fission yeast by delaying cells entry into S phase.     

Drosophila Wee1 kinase regulates Cdk1 and mitotic entry during embryogenesis

Cyclin-dependent kinases (Cdks) are the central regulators of the cell division cycle. Inhibitors of Cdks ensure proper coordination of cell cycle events and help regulate cell proliferation in the context of tissues and organs. Wee1 homologs phosphorylate a conserved tyrosine to inhibit the mitotic cyclin-dependent kinase Cdk1. Loss of Wee1 function in fission or budding yeast causes premature entry into mitosis. The importance of metazoan Wee1 homologs for timing mitosis, however, has been demonstrated only in Xenopus egg extracts and via ectopic Cdk1 activation . Here, we report that Drosophila Wee1 (dWee1) regulates Cdk1 via phosphorylation of tyrosine 15 and times mitotic entry during the cortical nuclear cycles of syncytial blastoderm embryos, which lack gap phases. Loss of maternal dwee1 leads to premature entry into mitosis, mitotic spindle defects, chromosome condensation problems, and a Chk2-dependent block of subsequent development, and then embryonic lethality. These findings modify previous models about cell cycle regulation in syncytial embryos and demonstrate that Wee1 kinases can regulate mitotic entry in vivo during metazoan development even in cycles that lack a G2 phase.     

Monitoring the Cell Cycle by Multi-Kinase-Dependent Regulation of Swe1/Wee1 in Budding Yeast

In eukaryotes, G2/M transition is induced by the activation of cyclin B-bound Cdk1, which is held in check by the protein kinase, Wee1. Recent advances in our understanding of mitotic entry in budding yeast has revealed that these cells utilize the level of Swe1 (Wee1 ortholog) phosphorylation as a means of monitoring cell cycle progression and of coordinating morphogenetic events with mitotic entry. Swe1 is phosphorylated by at least three distinct kinases at different stages of the cell cycle. This cumulative phosphorylation leads to the hyperphosphorylation and degradation of Swe1 through ubiquitin-mediated proteolysis. Thus, Swe1 functions as an important cell cycle modulator that integrates multiple upstream signals from prior cell cycle events before its ultimate degradation permits passage into mitosis.     

Rkp1/Cpc2, a fission yeast RACK1 homolog, is involved in actin cytoskeleton organization through protein kinase C, Pck2, signaling

The Rkp1/Cpc2, a fission yeast RACK1 homolog, interacted with Pck2, one of the known PKC homologs, in vivo and in vitro. The rkp1-deletion mutants (Deltarkp1) are elongated and the pck2-deletion mutant (Deltapck2) showed abnormal morphology. The double-deletion mutant (Deltarkp1Deltapck2) showed more aberrant cell shapes and was sensitive to high salt concentration. Both Deltarkp1 and Deltapck2 cells were sensitive to latrunculin B (Lat B) which inhibits actin polymerization. The cells expressing the human RACK1 homolog complemented the latrunculin B sensitivity of Deltarkp1 indicating that human RACK1 is a functional homolog of Rkp1/Cpc2. We propose that Rkp1/Cpc2 may function as a receptor for Pck2 in the regulation of actin cytoskeleton organization during cell wall synthesis and morphogenesis of Schizosaccharomyces pombe.     

The S. pombe cytokinesis NDR kinase Sid2 activates Fin1 NIMA kinase to control mitotic commitment through Pom1/Wee1

Mitotic exit integrates the reversal of the phosphorylation events initiated by mitotic kinases with a controlled cytokinesis event that cleaves the cell in two. The mitotic exit network (MEN) of budding yeast regulates both processes, whereas the fission yeast equivalent, the septum initiation network (SIN), controls only the execution of cytokinesis. The components and architecture of the SIN and MEN are highly conserved. At present, it is assumed that the functions of the core SIN-MEN components are restricted to their characterized roles at the end of mitosis. We now show that the NDR (nuclear Dbf2-related) kinase component of the fission yeast SIN, Sid2-Mob1, acts independently of the other known SIN components in G2 phase of the cell cycle to control the timing of mitotic commitment. Sid2-Mob1 promotes mitotic commitment by directly activating the NIMA (Never In Mitosis)-related kinase Fin1. Fin1's activation promotes its own destruction, thereby making Fin1 activation a transient feature of G2 phase. This spike of Fin1 activation modulates the activity of the Pom1/Cdr1/Cdr2 geometry network towards?Wee1.     

HIV-1 Vpr induces G2 cell cycle arrest in fission yeast associated with Rad24/14-3-3-dependent, Chk1/Cds1-independent Wee1 upregulation

Viral protein R (Vpr), an accessory protein of human immunodeficiency virus type 1 (HIV-1), induces the G2 cell cycle arrest in fission yeast for which host factors, such as Wee1 and Rad24, are required. Catalyzing the inhibitory phosphorylation of Cdc2, Wee1 is known to serve as a major regulator of G2/M transition in the eukaryotic cell cycle. It has been reported that the G2 checkpoint induced by DNA damage or incomplete DNA replication is associated with phosphorylation and upregulation of Wee1 for which Chk1 and Cds1 kinase is required. In this study, we demonstrate that the G2 arrest induced by HIV-1 Vpr in fission yeast is also associated with increase in the phosphorylation and amount of Wee1, but in a Chk1/Cds1-independent manner. Rad24 and human 14-3-3 appear to contribute to Vpr-induced G2 arrest by elevating the level of Wee1 expression. It appears that Vpr could cause the G2 arrest through a mechanism similar to, but distinct from, the physiological G2 checkpoint controls. The results may provide useful insights into the mechanism by which HIV-1 Vpr causes the G2 arrest in eukaryotic cells. Vpr may also serve as a useful molecular tool for exploring novel cell cycle control mechanisms.     

The Wee1 protein kinase regulates T14 phosphorylation of fission yeast Cdc2.

The Cdc2 protein kinase is a key regulator of the G1-S and G2-M cell cycle transitions in the fission yeast Schizosaccharomyces pombe. The activation of Cdc2 at the G2-M transition is triggered by dephosphorylation at a conserved tyrosine residue Y15. The level of Y15 phosphorylation is controlled by the Wee1 and Mik1 protein kinases acting in opposition to the Cdc25 protein phosphatase. Here, we demonstrate that Wee1 overexpression leads to a high stoichiometry of phosphorylation at a previously undetected site in S. pombe Cdc2, T14. T14 phosphorylation was also detected in certain cell cycle mutants blocked in progression through S phase, indicating that T14 phosphorylation might normally occur at low stoichiometry during DNA replication or early G2. Strains in which the chromosomal copy of cdc2 was replaced with either a T14A or a T14S mutant allele were generated and the phenotypes of these strains are consistent with T14 phosphorylation playing an inhibitory role in the activation of Cdc2 as it does in higher eukaryotes. We have also obtained evidence that Wee1 but not Mik1 or Chk1 is required for phosphorylation at this site, that the Mik1 and Chk1 protein kinases are unable to drive T14 phosphorylation in vivo, that residue 14 phosphorylation requires previous phosphorylation at Y15, and that the T14A mutant, unlike Y15F, is recessive to wild-type Cdc2 activity. Finally, the normal duration of G2 delay after irradiation or hydroxyurea treatment in a T14A mutant strain indicates that T14 phosphorylation is not required for the DNA damage or replication checkpoint controls.     

The function of the chicken p34CDC2 protein kinase in fission yeast is cold sensitive for cell cycle progression through the G1 phase and temperature sensitive for traversal of mitosis

The protein kinase p34^cdc2 is required at the onset of DNA replication and for entry into mitosis. The catalytic subunit and its regulatory proteins, notably the cyclins, are conserved from yeast to man. This suggests that the control mechanisms necessary for progression through the cell cycle in fission yeast are conserved throughout evolution. This work describes the characterization of a fission yeast strain that is dependent for cell cycle progression on the activity of the p34^CDC2 protein kinase from chicken. The response of the chicken p34^CDC2 protein kinase to cell cycle components of fission yeast was examined. Cells expressing the chicken p34^CDC2 protein divide at reduced size at 31°?C. Cells are temperature sensitive at 35.5°?C and die as a result of mitotic catastrophe. This phenotype can be rescued by delaying cell cycle progression at the G1-S transition by adding low concentrations of hydroxyurea. Schizosaccharomyces pombe cells that are dependent on chicken p34^CDC2 are cold sensitive. At 19°?C to 25°?C cells arrest in the G1 phase, while traversal of the G2-M transition is not blocked at low temperature. Expression of chicken p34^CDC2 in the cold-sensitive G2-M mutant cdc2A21 suppresses the G1 arrest.     

Murine Wee1 plays a critical role in cell cycle regulation and pre-implantation stages of embryonic development

Wee1 kinase regulates the G2/M cell cycle checkpoint by phosphorylating and inactivating the mitotic cyclin-dependent kinase 1 (Cdk1). Loss of Wee1 in many systems, including yeast and drosophila, leads to premature mitotic entry. However, the developmental role of Wee1 in mammals remains unclear. In this study, we established Wee1 knockout mice by gene targeting. We found that Wee-/- embryos were defective in the G2/M cell cycle checkpoint induced by gamma-irradiation and died of apoptosis before embryonic (E) day 3.5. To study the function of Wee1 further, we have developed MEF cells in which Wee1 is disrupted by a tamoxifen inducible Cre-LoxP approach. We found that acute deletion of Wee1 resulted in profound growth defects and cell death. Wee1 deficient cells displayed chromosome aneuploidy and DNA damage as revealed by gamma-H2AX foci formation and Chk2 activation. Further studies revealed a conserved mechanism of Wee1 in regulating mitotic entry and the G2/M checkpoint compared with other lower organisms. These data provide in vivo evidence that mammalian Wee1 plays a critical role in maintaining genome integrity and is essential for embryonic survival at the pre-implantation stage of mouse development.     

The function of the chicken p34CDC2 protein kinase in fission yeast is cold sensitive for cell cycle progression through the G1 phase and temperature sensitive for traversal of mitosis.

The protein kinase p34^cdc2 is required at the onset of DNA replication and for entry into mitosis. The catalytic subunit and its regulatory proteins, notably the cyclins, are conserved from yeast to man. This suggests that the control mechanisms necessary for progression through the cell cycle in fission yeast are conserved throughout evolution. This work describes the characterization of a fission yeast strain that is dependent for cell cycle progression on the activity of the p34^CDC2 protein kinase from chicken. The response of the chicken p34^CDC2 protein kinase to cell cycle components of fission yeast was examined. Cells expressing the chicken p34^CDC2 protein divide at reduced size at 31° C. Cells are temperature sensitive at 35.5° C and die as a result of mitotic catastrophe. This phenotype can be rescued by delaying cell cycle progression at the G1-S transition by adding low concentrations of hydroxyurea. Schizosaccharomyces pombe cells that are dependent on chicken p34^CDC2 are cold sensitive. At 19° C to 25° C cells arrest in the G1 phase, while traversal of the G2-M transition is not blocked at low temperature. Expression of chicken p34^CDC2 in the cold-sensitive G2-M mutant cdc2A21 suppresses the G1 arrest. Received: 14 October 1998 / Accepted: 15 March 1999     

RACK1 regulates G1/S progression by suppressing Src kinase activity

Cancer genes exert their greatest influence on the cell cycle by targeting regulators of a critical checkpoint in late G(1). Once cells pass this checkpoint, they are fated to replicate DNA and divide. Cancer cells subvert controls at work at this restriction point and remain in cycle. Previously, we showed that RACK1 inhibits the oncogenic Src tyrosine kinase and NIH 3T3 cell growth. RACK1 inhibits cell growth, in part, by prolonging G(0)/G(1). Here we show that RACK1 overexpression induces a partial G(1) arrest by suppressing Src activity at the G(1) checkpoint. RACK1 works through Src to inhibit Vav2, Rho GTPases, Stat3, and Myc. Consequently, cyclin D1 and cyclin-dependent kinases 4 and 2 (CDK4 and CDK2, respectively) are suppressed, CDK inhibitor p27 and retinoblastoma protein are activated, E2F1 is sequestered, and G(1)/S progression is delayed. Conversely, downregulation of RACK1 by short interference RNA activates Src-mediated signaling, induces Myc and cyclin D1, and accelerates G(1)/S progression. RACK1 suppresses Src- but not mitogen-activated protein kinase-dependent platelet-derived growth factor signaling. We also show that Stat3 is required for Rac1 induction of Myc. Our results reveal a novel mechanism of cell cycle control in late G(1) that works via an endogenous inhibitor of the Src kinase.     

Two distinct mechanisms for negative regulation of the Wee1 protein kinase.

The Wee1 protein kinase negatively regulates the entry into mitosis by catalyzing the inhibitory tyrosine phosphorylation of the Cdc2 protein. To examine the potential mechanisms for Wee1 regulation during the cell cycle, we have introduced a recombinant form of the fission yeast Wee1 protein kinase into Xenopus egg extracts. We find that the Wee1 protein undergoes dramatic changes in its phosphorylation state and kinase activity during the cell cycle. The Wee1 protein oscillates between an underphosphorylated 107 kDa form during interphase and a hyperphosphorylated 170 kDa version at mitosis. The mitosis-specific hyperphosphorylation of the Wee1 protein results in a substantial reduction in its activity as a Cdc2-specific tyrosine kinase. This phosphorylation occurs in the N-terminal region of the protein that lies outside the C-terminal catalytic domain, which was recently shown to be a substrate for the fission yeast Nim1 protein kinase. These experiments demonstrate the existence of a Wee1 regulatory system, consisting of both a Wee1-inhibitory kinase and a Wee1-stimulatory phosphatase, which controls the phosphorylation of the N-terminal region of the Wee1 protein. Moreover, these findings indicate that there are apparently two potential mechanisms for negative regulation of the Wee1 protein, one involving phosphorylation of its C-terminal domain by the Nim1 protein and the other involving phosphorylation of its N-terminal region by a different kinase.     

Human Wee1 kinase inhibits cell division by phosphorylating p34cdc2 exclusively on Tyr15.

In fission yeast, the M-phase inducing kinase, a complex of p34cdc2 and cyclin B, is maintained in an inhibited state during interphase due to the phosphorylation of Cdc2 at Tyr15. This phosphorylation is believed to be carried out primarily by the Wee1 kinase. In human cells the negative regulation of p34cdc2/cyclin B is more complex, in that Cdc2 is phosphorylated at two inhibitory sites, Thr14 and Tyr15. The identities of the kinases that phosphorylate these sites are unknown. Since fission yeast Wee1 kinase behaves as a dual-specificity kinase in vitro, a popular hypothesis is that a human Wee1 homolog might phosphorylate p34cdc2 at both sites. We report here that a human gene, identified as a possible Wee1 homologue, blocks cell division when overexpressed in HeLa cells. This demonstrates functional conservation of the Wee1 mitotic inhibitor. Contrary to the dual-specificity kinase hypothesis, purified human Wee1 phosphorylates p34cdc2 exclusively on Tyr15 in vitro; no Thr14 phosphorylation was detected. Human and fission yeast Wee1 also specifically phosphorylate synthetic peptides at sites equivalent to Tyr15. Mutation of a critical lysine codon (Lys114) believed to be essential for kinase activity abolished both the in vivo mitotic inhibitor function and in vitro kinase activities of human Wee1. These results conclusively prove that Wee1 kinases inhibit mitosis by directly phosphorylating p34cdc2 on Tyr15, and strongly indicate that human cells have independent kinase pathways directing the two inhibitor phosphorylations of p34cdc2.     

spo12 is a multicopy suppressor of mcs3 that is periodically expressed in fission yeast mitosis

Hyperactivation of Cdc2 in fission yeast causes cells to undergo a lethal premature mitosis, a phenomenon called mitotic catastrophe. This phenotype is observed in cdc2-3w wee1-50 cells at high temperature and is suppressed by a single recessive mutant, mcs3-12. Mcs3 acts independently of the Wee1 kinase and Cdc25 phosphatase, two major regulators of Cdc2. We have isolated multicopy suppressors of the cell cycle arrest phenotype of mcs3-12 wee1-50 cdc25-22 cells, but did not identify the mcs3 gene itself. Instead several known mitotic regulators were isolated, including the Cdc25 phosphatase, Wis2 cyclophilin, Cek1 kinase, and an Hsp90 homologue, Swo1. We also isolated clones encoding non-functional, truncated forms of the Wee1 kinase and Dis2 type 1 phosphatase. In addition we identified a multicopy suppressor that encodes a structural homologue of the budding yeast SPO12 gene. We find that overexpression of fission yeast spo12 not only suppresses the phenotype of the mcs3-12 wee1-50 cdc25-22 strain, but also that of a win1-1 wee1-50 cdc25-22 strain at high temperature, indicating that the function of spo12 is not directly related to mcs3. We show that spo12 mRNA is periodically expressed during the fission yeast cell cycle, peaking at the G2/M transition coincidently with cdc15. Deletion of spo12, however, has no overt effect on either the mitotic or meiotic cell cycles, except when the function of the major B type cyclin, Cdc13, is compromised.