Evidence that the G1-S and G2-M transitions are controlled by different cdc2 proteins in higher eukaryotes.

Xenopus eggs contain two distinct cdc2 homologs of 34 and 32 kd. We show that the 32 kd cdc2 protein, like the 34 kd protein, is a kinase. However, unlike the 34 kd homolog, the 32 kd cdc2 kinase activity does not decrease dramatically at the end of mitosis. The 32 kd protein does not associate with mitotic cyclins B1 and B2 but does associate with cyclin A and a novel doublet of proteins of 54 kd that may regulate its activity. We also show that depletion of the 32 kd cdc2 homolog from a Xenopus extract blocks DNA replication, but does not inhibit entry into mitosis. By contrast, depletion of the 34 kd cdc2 homolog or absence of mitotic cyclins from an extract does not inhibit replication, but does block entry into mitosis. Our results indicate that in higher eukaryotes, DNA replication (G1-S) and mitosis (G2-M) may be controlled by distinctly different cdc2 proteins.     

The substrates of the cdc2 kinase.

The eukaryotic cell cycle is characterized by two major events, DNA replication (S phase) and mitosis (M phase). According to the current paradigm of the cell cycle as a cdc2 cycle, both of these events are driven by serine-threonine specific protein kinases encoded by functional homologs of the fission yeast cdc2 gene. To understand how cdc2 kinases function, it is necessary to identify their physiological substrates and to determine how phosphorylation of these substrates promotes cell cycle progression. Definitive information about substrates relevant to early stages of the cell cycle (G1 and S phases) remains scarce, but several likely physiological targets of the mitotic cdc2 kinase have recently been identified. Current evidence indicates that cdc2 kinase may trigger entry of cells into mitosis not only by initiating important regulatory pathways but also by direct phosphorylation of abundant structural proteins.     

Premature initiation of mitosis in yeast lacking RCC1 or an interacting GTPase.

A fission yeast mutant is described in which the onset of mitosis is uncoupled from the completion of DNA replication. pim1 (premature initiation of mitosis) cells can undergo mitotic chromosome condensation and mitotic spindle formation without completion of S phase and without the cdc25 mitotic inducer. The M phase kinase is required for pim1-induced mitosis and becomes activated. pim1 encodes a homolog of the human RCC1 nuclear protein. pim1 mutants are fully rescued by overexpression of spi1, a newly identified essential gene whose predicted product shares 81% identity with human TC4. spi1 and TC4 define a new subclass within the "ras-like" GTPase superfamily that is structurally distinct from the ras, rho, or sec4 families. Diploid yeast that carry one wild-type and one disrupted copy of spi1 have multiple satellite nuclei, and mitotic haploidization occurs at very high frequency. spi1 appears to interact with pim1 in the maintenance of a coordinated cell cycle.     

Regulatory phosphorylation of the p34cdc2 protein kinase in vertebrates.

The p34cdc2 protein kinase is a conserved regulator of the eukaryotic cell cycle. Here we show that residues Thr14 and Tyr15 of mouse p34cdc2 become phosphorylated as mouse fibroblasts proceed through the cell cycle. We have mutated these residues and measured protein kinase activity of the p34cdc2 variants in a Xenopus egg extract. Phosphorylation of residues 14 and 15, which lie within the presumptive ATP-binding region of p34cdc2, normally restrains the protein kinase until it is specifically dephosphorylated and activated at the G2/M transition. Regulation by dephosphorylation of Tyr15 is conserved from fission yeast to mammals, while an extra level of regulation of mammalian p34cdc2 involves Thr14 dephosphorylation. In the absence of phosphorylation on these two residues, the kinase still requires cyclin B protein for its activation. Inhibition of DNA synthesis inhibits activation of wild-type p34cdc2 in the Xenopus system, but a mutant which cannot be phosphorylated at residues 14 and 15 escapes this inhibition, suggesting that these phosphorylation events form part of the pathway linking completion of DNA replication to initiation of mitosis.     

Effects of mutant Ran/TC4 proteins on cell cycle progression.

Ran/TC4, a member of the RAS gene superfamily, encodes an abundant nuclear protein that binds and hydrolyzes GTP. Transient expression of a Ran/TC4 mutant protein deficient in GTP hydrolysis blocked DNA replication, suggesting a role for Ran/TC4 in the regulation of cell cycle progression. To test this possibility, we exploited an efficient transfection system, involving the introduction of cDNAs in the pMT2 vector into 293/Tag cells, to analyze phenotypes associated with mutant and wild-type Ran/TC4 expression. Expression of a Ran/TC4 mutant protein deficient in GTP hydrolysis inhibited proliferation of transfected cells by arresting them predominantly in the G2, but also in the G1, phase of the cell cycle. Deletion of an acidic carboxy-terminal hexapeptide from the Ran/TC4 mutant did not alter its nuclear localization but did block its inhibitory effect on cell cycle progression. These data suggest that normal progression of the cell cycle is coupled to the operation of a Ran/TC4 GTPase cycle. Mediators of this coupling are likely to include the nuclear regulator of chromosome condensation 1 protein and the mitosis-promoting factor complex.     

Identification of MSA1, a cell cycle-regulated,dosage suppressor of drc1/sld2 and dpb11 mutants

The Dpb11 and Drc1/Sld2 proteins form a complex that is critical for the initiation of DNA replication. In this study we identify MSA1 as a high copy suppressor of a drc1-1 mutant. MSA1 overproduction can also suppress the temperature sensitivity of dpb11-1 and pol2-12 mutants. Reciprocally, msa1 deletion exacerbates the mutant phenotypes of both drc1/sld2 and dpb11 mutants and msa1 deletion alone results in a delay in S phase entry of synchronous cells indicating a positive role for MSA1 in DNA replication. Paradoxically, MSA1 overproduction is deleterious to cdc6-1, cdc7-1, cdc28-1N and cdc14-1 mutants indicating a complex relationship with DNA replication and cell cycle regulatory genes. The Msa1 protein is tightly cell cycle regulated. Msa1 and its paralog, Msa2, both accumulate in highly modified forms just as cells commit to enter S phase and then are rapidly destroyed. MSA1 represents a new cell cycle regulated gene important for S phase entry.     

Identification of the nuclear localization signal in Xenopus cyclin E and analysis of its role in replication and mitosis

Cyclin-dependent kinase (Cdk)2/cyclin E is imported into nuclei assembled in Xenopus egg extracts by a pathway that requires importin-alpha and -beta. Here, we identify a basic nuclear localization sequence (NLS) in the N-terminus of Xenopus cyclin E. Mutation of the NLS eliminated nuclear accumulation of both cyclin E and Cdk2, and such versions of cyclin E were unable to trigger DNA replication. Addition of a heterologous NLS from SV40 large T antigen restored both nuclear targeting of Cdk2/cyclin E and DNA replication. We present evidence indicating that Cdk2/cyclin E complexes must become highly concentrated within nuclei to support replication and find that cyclin A can trigger replication at much lower intranuclear concentrations. We confirmed that depletion of endogenous cyclin E increases the concentration of cyclin B necessary to promote entry into mitosis. In contrast to its inability to promote DNA replication, cyclin E lacking its NLS was able to cooperate with cyclin B in promoting mitotic entry.     

Cdc25 regulates the phosphorylation and activity of the Xenopus cdk2 protein kinase complex.

The Xenopus cdk2 gene encodes a 32-kDa protein kinase with sequence similarity to the 34-kDa product of the cdc2 gene. Previous studies have shown that the kinase activity of the protein product of the cdk2 gene oscillates in the Xenopus embryonic cell cycle with a high in M-phase and a low in interphase. In the present study cdk2 was found not to be associated with any newly synthesized proteins during the cell cycle, but the enzyme did undergo periodic changes in phosphorylation. Upon exit from metaphase, cdk2 became increasingly phosphorylated on both tyrosine and serine residues, and labeling on these residues increased progressively until entry into mitosis, when tyrosine residues were markedly dephosphorylated. Phosphopeptide mapping of cdk2 demonstrated the major sites of phosphorylation were in a phosphopeptide with a pI of 3.7 that contained both phosphoserine and phosphotyrosine. This phosphopeptide accumulated in egg extracts blocked in S-phase with aphidicolin and was not evident in cdc2 immunoprecipitated under the same conditions. Under the same conditions cdc2 was phosphorylated primarily on a phosphopeptide containing both phosphothreonine and phosphotyrosine residues, most likely threonine 14 and tyrosine 15. Affinity-purified human GST-cdc25 was able to dephosphorylate and activate cdk2 isolated from interphase cells. Phosphopeptide mapping demonstrated that the phosphate was specifically removed from the same phosphopeptide identified as the major in vivo site of phosphorylation. These results demonstrate that cdk2 is regulated in the cell cycle by phosphorylation and dephosphorylation on both serine and tyrosine residues. Moreover, the increased phosphorylation of cdk2 in aphidicolin-blocked extracts and the ability of cdc25 to mediate cdk2 dephosphorylation in vitro suggest the possibility that cdk2 is part of the mechanism ensuring mitosis is not initiated until completion of DNA replication. It also implies cdc25 may have other functions in addition to the regulation of cdc2 kinase activity.     

Fission yeast cdc21, a member of the MCM protein family, is required for onset of S phase and is located in the nucleus throughout the cell cycle.

The fission yeast cdc21 protein belongs to the MCM family, implicated in the once per cell cycle regulation of chromosome replication. In budding yeast, proteins in this family are eliminated from the nucleus during S phase, which has led to the suggestion that they may serve to distinguish unreplicated from replicated DNA, as in the licensing factor model. We show here that, in contrast to the situation in budding yeast, cdc21 remains in the nucleus after S phase, as is found for related proteins in mammalian cells. We suggest that regulation of nuclear import of these proteins may not be an essential aspect of their function in chromosome replication. To determine the function of cdc21+, we have analysed the phenotype of a gene deletion. cdc21+ is required for entry into S phase and, unexpectedly, a proportion of cells depleted of the gene product are able to enter mitosis in the absence of DNA replication. These results are consistent with the view that individual proteins in the MCM family are required for all initiation events, and defective initiation may impair the coordination between mitosis and S phase.     

Chromotin binding, nuclear localization and phosphorylation of Xenopus cdc21 are cell-cycle dependent and associated with the control of initiation of DNA replication.

A Xenopus homologue of Schizosaccharomyces pombe cdc21 has been characterized as a new member of the MCM family of proteins. The cdc21 protein exhibits cell-cycle dependent chromatin binding and phosphorylation in association with S-phase control. Cdc21 binds to decondensing chromatin at the end of mitosis, localizing to numerous foci which form prior to reconstitution of the nuclear membrane. The association of cdc21 with chromatin occurs in membrane-free high speed extracts and is resistant to detergent extraction. The spatial organization of the cdc21 foci resembles that of pre-replication centres though no co-localization with RP-A was observed. Cdc21 remains bound to chromatin during the initiation of DNA replication and is displaced as the DNA replication forks progress. These subnuclear changes in localization correlate with cell-cycle-regulated changes in phosphorylation. Cdc21 binds to chromatin in an underphosphorylated state, but in early S phase the nuclear localized cdc21 is partially phosphorylated before it is displaced from the chromatin. Cytoplasmic cdc21 remains underphosphorylated but at the beginning of mitosis the entire pool of cdc21 is hyperphosphorylated, possibly by the cdc2/cyclin B kinase. These properties identify Xenopus cdc21 as a possible component of the DNA licensing factor.     

Coupling of mitosis to the completion of S phase in Xenopus occurs via modulation of the tyrosine kinase that phosphorylates p34cdc2.

In cell-free extracts derived from Xenopus eggs which oscillate between S phase and mitosis, incompletely replicated DNA blocks the activation of p34cdc2-cyclin by maintaining p34cdc2 in a tyrosine-phosphorylated form. We used a recombinant cyclin fusion protein to generate a substrate to measure the ability of the tyrosine kinase(s) to phosphorylate and inactivate p34cdc2 in the absence of tyrosine phosphatase activity. p34cdc2 tyrosine phosphorylation is highly regulated during the cell cycle, being elevated in S phase and attenuated in mitosis. The elevation in p34cdc2 tyrosine phosphorylation rate occurs in response to the presence of incompletely replicated DNA. Moreover, okadaic acid and caffeine, which uncouple the dependence of mitosis on the completion of S phase, increase unphosphorylated p34cdc2 by attenuating tyrosine kinase function. These data indicate that the control system, which monitors the state of DNA replication, modulates the function of the tyrosine kinase by a phosphorylation/dephosphorylation mechanism, ensuring that mitosis occurs only when S phase is complete.     

Mutant Caldesmon lacking cdc2 phosphorylation sites delays M-phase entry and inhibits cytokinesis

Caldesmon is phosphorylated by cdc2 kinase during mitosis, resulting in the dissociation of caldesmon from microfilaments. To understand the physiological significance of phosphorylation, we generated a caldesmon mutant replacing all seven cdc2 phosphorylation sites with Ala, and examined effects of expression of the caldesmon mutant on M-phase progression. We found that microinjection of mutant caldesmon effectively blocked early cell division of Xenopus embryos. Similar, though less effective, inhibition of cytokinesis was observed with Chinese hamster ovary (CHO) cells microinjected with 7th mutant. When mutant caldesmon was introduced into CHO cells either by protein microinjection or by inducible expression, delay of M-phase entry was observed. Finally, we found that 7th mutant inhibited the disassembly of microfilaments during mitosis. Wild-type caldesmon, on the other hand, was much less potent in producing these three effects. Because mutant caldesmon did not inhibit cyclin B/cdc2 kinase activity, our results suggest that alterations in microfilament assembly caused by caldesmon phosphorylation are important for M-phase progression.     

Fission yeast p13 blocks mitotic activation and tyrosine dephosphorylation of the Xenopus cdc2 protein kinase

It has been demonstrated that the Xenopus homolog of the fission yeast cdc2 protein is a component of M phase promoting factor (MPF). We show that the Xenopus cdc2 protein is phosphorylated on tyrosine in vivo, and that this tyrosine phosphorylation varies markedly with the stage of the cell cycle. Tyrosine phosphorylation is high during interphase (in Xenopus oocytes and activated eggs) but absent during M phase (in unfertilized eggs). In vitro activation of pre-MPF from Xenopus oocytes results in tyrosine dephosphorylation of the cdc2 protein and switching-on of its kinase activity. The product of the fission yeast suc1 gene (p13), which inhibits the entry into mitosis in Xenopus extracts, completely blocks tyrosine dephosphorylation and kinase activation. However, p13 has no effect on the activated form of the cdc2 kinase. These findings suggest that p13 controls the activation of the cdc2 kinase, and that tyrosine dephosphorylation is an important step in this process.     

Cell cycle regulation of the p34cdc2 inhibitory kinases.

In cells of higher eukaryotic organisms the activity of the p34cdc2/cyclin B complex is inhibited by phosphorylation of p34cdc2 at two sites within its amino-terminus (threonine 14 and tyrosine 15). In this study, the cell cycle regulation of the kinases responsible for phosphorylating p34cdc2 on Thr14 and Tyr15 was examined in extracts prepared from both HeLa cells and Xenopus eggs. Both Thr14- and Tyr15- specific kinase activities were regulated in a cell cycle-dependent manner. The kinase activities were high throughout interphase and diminished coincident with entry of cells into mitosis. In HeLa cells delayed in G2 by the DNA-binding dye Hoechst 33342, Thr14- and Tyr15-specific kinase activities remained high, suggesting that a decrease in Thr14- and Tyr15- kinase activities may be required for entry of cells into mitosis. Similar cell cycle regulation was observed for the Thr14/Tyr15 kinase(s) in Xenopus egg extracts. These results indicate that activation of CDC2 and entry of cells into mitosis is not triggered solely by activation of the Cdc25 phosphatase but by the balance between Thr14/Tyr15 kinase and phosphatase activities. Finally, we have detected two activities capable of phosphorylating p34cdc2 on Thr14 and/or Tyr15 in interphase extracts prepared from Xenopus eggs. An activity capable of phosphorylating Tyr15 remained soluble after ultracentrifugation of interphase extracts whereas a second activity capable of phosphorylating both Thr14 and Tyr15 pelleted. The pelleted fraction contained activities that were detergent extractable and that phosphorylated p34cdc2 on both Thr14 and Tyr15. The Thr14- and Tyr15-specific kinase activities co-purified through three successive chromatographic steps indicating the presence of a dual-specificity protein kinase capable of acting on p34cdc2.     

mei-41 and bub1 block mitosis at two distinct steps in response to incomplete DNA replication in Drosophila embryos.

Drosophila double park encodes a homolog of Cdt1 that functions in initiation of DNA replication in fission yeast and Xenopus. dup mutants complete the first 15 embryonic cell cycles, presumably via maternal dup products, and show defects in the 16(th) S phase (S16). Cells carrying dup(a1) allele forgo S16 altogether but enter mitosis 16 (M16). We find that the timing of entry into M16 is similar in dup(a1) and heterozygous or wild-type (wt) controls. In contrast, we find that mutant cells carrying another allele, dup(a3), undergo a partial S16 and delay the entry into M16. Thus, initiation of S16 appears necessary for delaying M16. This delay is absent in double mutants of dup(a3) and mei-41 (Drosophila ATR), indicating that a mei-41-dependent checkpoint acts to delay the entry into mitosis in response to incomplete DNA replication. dup(a3) and dup(a1) mutant cells that enter M16 become arrested in M16. We find that mitotic cyclins are stabilized and that a spindle checkpoint protein, Bub1, localizes onto chromosomes during mitotic arrest in dup mutants. These features suggest an arrest prior to metaphase-anaphase transition. dup(a3) bub1 double mutant cells exit M16, indicating that a bub1-mediated checkpoint acts to block mitotic exit in dup mutants. To our knowledge, this is the first report of (1) incomplete DNA replication affecting both the entry into and the exit from mitosis in a single cell cycle via different mechanisms and (2) the role of bub1 in regulating mitotic exit in response to incomplete DNA replication.     

A connection between pre-mRNA splicing and the cell cycle in fission yeast: cdc28+ is allelic with prp8+ and encodes an RNA-dependent ATPase/helicase.

The fission-yeast gene cdc28+ was originally identified in a screen for temperature-sensitive mutants that exhibit a cell-division cycle arrest and was found to be required for mitosis. We undertook a study of this gene to understand more fully the general requirements for entry into mitosis. Cells carrying the conditional lethal cdc28-P8 mutation divide once and arrest in G2 after being shifted to the restrictive temperature. We cloned the cdc28+ gene by complementation of the temperature-sensitive growth arrest in cdc28-P8. DNA sequence analysis indicated that cdc28+ encodes a member of the DEAH-box family of putative RNA-dependent ATPases or helicases. The Cdc28 protein is most similar to the Prp2, Prp16, and Prp22 proteins from budding yeast, which are required for the splicing of mRNA precursors. Consistent with this similarity, the cdc28-P8 mutant accumulates unspliced precursors at the restrictive temperature. Independently, we isolated a temperature-sensitive pre-mRNA splicing mutant prp8-1 that exhibits a cell-cycle phenotype identical to that of cdc28-P8. We have shown that cdc28 and prp8 are allelic. These results suggest a connection between pre-mRNA splicing and progression through the cell cycle.     

Regulation of the cdc25 protein during the cell cycle in Xenopus extracts.

The cdc25 protein is a highly specific tyrosine phosphatase that triggers mitosis by dephosphorylating the cdc2 protein kinase. Using Xenopus extracts, we have found that the cdc25 protein is active at a low level throughout interphase. Near the onset of mitosis, the cdc25 protein undergoes a marked elevation in phosphatase activity that coincides with an extensive phosphorylation of the protein in its N-terminal region. In vitro dephosphorylation of this hyperphosphorylated form of cdc25 reduces its phosphatase activity back to the interphase level. Moreover, treatment of interphase Xenopus extracts with okadaic acid, a phosphatase inhibitor that accelerates the entry into mitosis, elicits both the premature hyperphosphorylation of cdc25 and the stimulation of its cdc2-specific tyrosine phosphatase activity. These experiments demonstrate the existence of a cdc25 regulatory system consisting of both a stimulatory kinase that phosphorylates a putative regulatory domain of the cdc25 protein and an inhibitory serine/threonine phosphatase that counteracts this kinase activity.