Cdc2 and the Regulation of Mitosis: Six Interacting Mcs Genes

A cdc2-3w weel-50 double mutant of fission yeast displays a temperature-sensitive lethal phenotype that is associated with gross abnormalities of chromosome segregation and has been termed mitotic catastrophe. In order to identify new genetic elements that might interact with the cdc2 protein kinase in the regulation of mitosis, we have isolated revertants of the lethal double mutant. The suppressor mutations define six mcs genes (mcs: mitotic catastrophe suppressor) that are not allelic to any of the following mitotic control genes: cdc2, wee 1, cdc13, cdc25, suc1 or nim1. Each mcs mutation is recessive with respect to wild-type in its ability to suppress mitotic catastrophe. None confer a lethal phenotype as a single mutant but few of the mutants are expected to be nulls. A diverse range of genetic interactions between the mcs mutants and other mitotic regulators were uncovered, including the following examples. First, mcs2 cdc2w or mcs6 cdc2w double mutants display a cell cycle defect dependent on the specific wee allele of cdc2. Second, both mcs1 cdc25-22 or mcs4 cdc25-22 double mutants are nonconditionally lethal, even at a temperature normally permissive for cdc25-22. Finally, the characteristic suppression of the cdc25 phenotype by a loss-of-function wee1 mutation is reversed in a mcs3 mutant background. The mcs genes define new mitotic elements that might be activators or substrates of the cdc2 protein kinase.     

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.     

Mcs4 mitotic catastrophe suppressor regulates the fission yeast cell cycle through the Wik1-Wis1-Spc1 kinase cascade.

Spc1 in Schizosaccharomyces pombe is a member of the stress-activated protein kinase family, an evolutionary conserved subfamily of mitogen-activated protein kinases (MAPKs). Spc1 is activated by a MAPK kinase homologue, Wis1, and negatively regulated by Pyp1 and Pyp2 tyrosine phosphatases. Mutations in the spc1+ and wis1+ genes cause a G2 cell cycle delay that is exacerbated during stress. Herein, we describe two upstream regulators of the Wis1-Spc1 cascade. wik1+ (Wis1 kinase) was identified from its homology to budding yeast SSK2, which encodes a MAPKK kinase that regulates the HOG1 osmosensing pathway. Delta wik1 cells are impaired in stress-induced activation of Spc1 and show a G2 cell cycle delay and osmosensitive growth. Moreover, overproduction of a constitutively active form of Wik1 induces hyperactivation of Spc1 in wis1(+)-dependent manner, suggesting that Wik1 regulates Spc1 through activation of Wis1. A mutation of mcs4+ (mitotic catastrophe suppressor) was originally isolated as a suppressor of the mitotic catastrophe phenotype of a cdc2-3w wee1-50 double mutant. We have found that mcs4- cells are defective at activation of Spc1 in response to various forms of stress. Epistasis analysis has placed Mcs4-upstream of Wik1 in the Spc1 activation cascade. These results indicate that Mcs4 is part of a sensor system for multiple environmental signals that modulates the timing of entry into mitosis by regulating the Wik1-Wis1-Spc1 kinase cascade. Inactivation of the sensor system delays the onset of mitosis and rescues lethal premature mitosis in cdc2-3w wee1-50 cells.     

Stf1: Non-Wee Mutations Epistatic to Cdc25 in the Fission Yeast Schizosaccharomyces Pombe

In Schizosaccharomyces pombe, cdc25 is a cell cycle regulated inducer of mitosis. wee1 and phenotypically wee alleles of cdc2 are epistatic to cdc25. Mutant alleles of a new locus, stf1 (suppressor of twenty-five), identified in a reversion analysis of conditionally lethal cdr1-76 cdc25-22 and cdr2-96 cdc25-22 double mutant strains, also suppress both temperature-sensitive and gene disruption alleles of cdc25. These mutants, by themselves, are phenotypically indistinguishable from wild type strains; hence they represent the first known mutations that are epistatic to cdc25 and do not display a wee phenotype. stf1 genetically interacts with other elements of mitotic control in S. pombe. stf1-1 is additive with wee1-50, cdc2-1w and cdc2-3w for suppression of cdc25-22. Also, like wee1- and cdc2-w, stf1- suppression of cdc25 is reversed by overexpression of the putative type 1 protein phosphatase bws1+/dis2+. Interaction with various mutants and plasmid overexpression experiments suggest that stf1 does not operate either upstream or downstream of wee1. Similarly, it does not operate through cdc25 since it rescues the disruption. stf1 appears to encode an important new element of mitotic control.     

Identification of a cdk-activating kinase in fission yeast.

We have identified a second cyclin-dependent kinase (cdk) in fission yeast, crk1, which encodes a 335 amino acid protein that is most closely related to the KIN28 gene product from Saccharomyces cerevisiae and to a cdk activating kinase (CAK) encoded by the MO15 gene from Xenopus laevis, crk1 is essential for viability and delta crk1 cells arrest with septa and condensed chromatin. We show that Crk1 associates with the Mcs2 mitotic catastrophe suppressor, a cyclin H-like molecule, and overexpression of crk1 rescues the cell-cycle arrest defect of a mcs2-75 cdc2-3w cdc25-22 triple mutant at high temperature. The Crk1-Mcs2 complex possesses CAK activity in vitro in that it phosphorylates human Cdk2 on Thr160 which results in its activation in the presence of cyclin A. In addition Crk1-Mcs2 effectively phosphorylates a peptide corresponding to the C-terminal repeat domain (CTD) of RNA polymerase II. We demonstrate that crk1 is allelic to the mcs6 mitotic catastrophe suppressor and that the X.laevis MO15 gene rescues the cell-cycle arrest of an mcs6-13 cdc2-3w cdc25-22 at high temperature. Together these data suggest that the Crk1-Mcs2 complex is a CAK that interacts genetically with Cdc2 in fission yeast.     

Involvement of a type 1 protein phosphatase encoded by bws1+ in fission yeast mitotic control

Fission yeast cdc25+ and wee1+ interact genetically with cdc2+ in the regulation of cell division, respectively as a mitotic activator and inhibitor. cdc25+ is normally essential for mitosis, but this requirement is alleviated in a loss-of-function wee1 mutant background. A plasmid-borne sequence, other than wee1+, that causes a cdc25ts wee1- double mutant to revert to a temperature-sensitive cdc phenotype has been isolated. The gene carried by this plasmid is called bws1+ (for bypass of wee suppression). bws1+ also bypasses the ability of alleles of cdc2 that confer a wee phenotype (cdc2w) to suppress loss-of-function cdc25 mutants. The nucleotide sequence of bws1+ shows that the predicted protein shares 81% amino acid identity with the catalytic subunit of mammalian type 1 protein phosphatase. Thus a genetic screen that might have yielded a protein kinase (wee1+) uncovered a phosphatase that also appears to be involved in the pathway of mitotic control.     

mik1 and wee1 cooperate in the inhibitory tyrosine phosphorylation of cdc2.

wee1 acts antagonistically to cdc25 in the tyrosine dephosphorylation and activation of cdc2, yet biochemical evidence suggests that wee1 is not required for tyrosine phosphorylation and its role is obscure. We show here that a related 66 kd kinase, called mik1, acts redundantly with wee1 in the negative regulation of cdc2 in S. pombe. A null allele of mik1 has no discernible phenotype, but a mik1 wee1 double mutant is hypermitotically lethal: all normal M phase checkpoints are bypassed, including the requirement for initiation of cell cycle "start," completion of S phase, and function of the cdc25+ mitotic activator. In the absence of mik1 and wee1 activity, cdc2 rapidly loses phosphate on tyrosine, both in strains undergoing mitotic lethality and in those that are viable owing to a compensating mutation within cdc2. The data suggest that mik1 and wee1 act cooperatively on cdc2, either directly as the inhibitory tyrosine kinase or as essential activators of that kinase.     

RACH2, a novel human gene that complements a fission yeast cell cycle checkpoint mutation.

We have identified a novel human gene by virtue of its ability to complement the rad1-1 checkpoint mutant of Schizosaccharomyces pombe. This gene, called RACH2, rescues the temperature-sensitive lethality of a rad1-1 wee1-50 double mutant of S. pombe. Expression of RACH2 in S. pombe rad1-1 strains partially restores UV resistance to the rad1-1 mutant strain. Expression of RACH2 in a rad1-1 cdc25-22 double mutant partially restores the dose-dependent delay in mitotic entry after irradiation that is lost in rad1-1 checkpoint-deficient mutants. Overexpression of RACH2 in human tissue culture cells induces apoptosis.     

Genetic and Molecular Analysis of Cdr1/Nim1 in Schizosaccharomyces Pombe

The cdr1 gene in Schizosaccharomyces pombe was identified as a mutation affecting the nutritional responsiveness of the mitotic size control. cdr1 alleles have been further analyzed for genetic interactions with elements of the mitotic control pathway and cloned by plasmid rescue of a conditional lethal cdr1-76 cdc25-22 double mutant. These analyses show that the cdr1 gene is allelic to nim1, a gene identified as a high copy number plasmid suppressor of the mitotic control gene, cdc25. The gene structure for cdr1 differs from the described nim1 gene in the carboxyl-terminal portion of the gene. The published nim1 sequence encoded a product of predicted Mr 45,000, and included 356 amino acids from the amino-terminal region of the gene and 14 amino acids from a noncontiguous carboxyl-terminal fragment. The cdr1 sequence includes an additional 237 amino acids of the contiguous fragment and encodes a product of predicted Mr 67,000. The sequence shows a high level of identity with protein kinases over the amino-terminal catalytic domain, and limited identity with yeast protein kinases SNF1, KIN2 and KIN1 over part of the carboxyl-terminal domain. The effect of overexpression of the full length gene has been examined in various genetic backgrounds. These data show that the full length gene product is required to give a normal cell cycle response to nitrogen starvation. A detailed examination of the genetic interaction of cdr1 mutants with various mutants of mitotic control genes (cdc2, cdc25, wee1, cdc13) demonstrated strong interactions with cdc25, some cdc2 alleles, and with cdc13-117. Overall, the results are interpretable within the framework of the existing model of cdr1/nim1 action in mitotic control, i.e., cdr1 functions upstream of wee1 to relieve mitotic inhibition.     

Negative regulation of mitosis by wee1+, a gene encoding a protein kinase homolog

Fission yeast wee1- mutants initiate mitosis at half the cell size of wild type. The wee1+ activity is required to prevent lethal premature mitosis in cells that overproduce the mitotic inducer cdc25+. This lethal phenotype was used to clone wee1+ by complementation. When wee1+ expression is increased, mitosis is delayed until cells grow to a larger size. Thus wee1+ functions as a dose-dependent inhibitor of mitosis, the first such element to be specifically identified and cloned. The carboxy-terminal region of the predicted 112 kd wee1+ protein contains protein kinase consensus sequences, suggesting that negative regulation of mitosis involves protein phosphorylation. Genetic evidence indicates that wee1+ and cdc25+ compete in a control system regulating the cdc2+ protein kinase, which is required for mitotic initiation.     

Drosophila Wee1 kinase rescues fission yeast from mitotic catastrophe and phosphorylates Drosophila Cdc2 in vitro.

Cdc2 kinase activity is required for triggering entry into mitosis in all known eukaryotes. Elaborate mechanisms have evolved for regulating Cdc2 activity so that mitosis occurs in a timely manner, when preparations for its execution are complete. In Schizosaccharomyces pombe, Wee1 and a related Mik1 kinase are Cdc2-inhibitory kinases that are required for preventing premature activation of the mitotic program. To identify Cdc2-inhibitory kinases in Drosophila, we screened for cDNA clones that rescue S. pombe wee1- mik1- mutants from lethal mitotic catastrophe. One of the genes identified in this screen, Drosophila wee1 (Dwee1), encodes a new Wee1 homologue. Dwee1 kinase is closely related to human and Xenopus Wee1 homologues, and can inhibit Cdc2 activity by phosphorylating a critical tyrosine residue. Dwee1 mRNA is maternally provided to embryos, and is zygotically expressed during the postblastoderm divisions of embryogenesis. Expression remains high in the proliferating cells of the central nervous system well after cells in the rest of the embryo have ceased dividing. The loss of zygotically expressed Dwee1 does not lead to mitotic catastrophe during postblastoderm cycles 14 to 16. This result may indicate that maternally provided Dwee1 is sufficient for regulating Cdc2 during embryogenesis, or it may reflect the presence of a redundant Cdc2 inhibitory kinase, as in fission yeast.     

Negative regulation of mitosis by two functionally overlapping PTPases in fission yeast.

We have identified a third protein tyrosine phosphatase (PTPase) gene in fission yeast, pyp2, encoding an 85 kDa protein. Disruption of pyp2 has no impact on cell viability, but pyp2 is essential in strains lacking the 60 kDa pyp1 PTPase. The two pyp PTPases are approximately 42% identical in their C-terminal catalytic domains and share weak homology in their N-terminal regions. Both genes play a role in inhibiting the onset of mitosis. Disruption of either gene rescues the G2 arrest caused by mutation of the cdc25 mitotic inducer, though the effect of pyp1-disruption is more pronounced. Disruption of pyp1 advances mitosis, suppresses overexpression of the tyrosine kinase encoded by the wee1 mitotic inhibitor, and causes lethal mitotic catastrophe in cdc25 overproducer cells. Cells bearing inactive wee1 are unresponsive to disruption of pyp1. Overexpression of pyp1 or pyp2 delays the onset of mitosis by a wee1-dependent mechanism. These data reveal an unexpected second role for protein tyrosine phosphorylation in the mitotic control that acts by promoting the inhibitory wee1 pathway.     

Genetic and Molecular Analysis of the Soe1 Gene: A Trna(3)(glu) Missense Suppressor of Yeast Cdc8 Mutations

The CDC8 gene of Saccharomyces cerevisiae encodes deoxythymidylate (dTMP) kinase and is required for nuclear and mitochondrial DNA replication in both the mitotic and meiotic cell cycles. All cdc8 temperature-sensitive mutants are partially defective in meiotic and mitochondrial functions at the permissive temperature. In a study of revertants of temperature-sensitive cdc8 mutants, the SOE201 and SOE1 mutants were isolated. The SOE201 mutant is a disome of chromosome X to which the cdc8 gene maps. Using the chromosome X aneuploids to vary cdc8 gene dosage, we demonstrate that different levels of dTMP kinase activity are required for mitotic, meiotic or mitochondrial DNA replication. The SOE1 mutant contains a dominant suppressor that suppresses five different cdc8 alleles but does not suppress a complete cdc8 deletion. The SOE1 gene is located less than 1.5 cM from the CYH2 gene on chromosome VII and is adjacent to the TSM437-CYH2 region, with the gene order being SOE1-TSM437-CYH2. SOE1 is an inefficient suppressor that can neither suppress the cdc8 hypomorphic phenotype nor restore dTMP kinase activity in vitro. SOE1 is a single C to T mutation in the anticodon of a tRNA(3Glu) gene and thereby, produces a missense suppressor tRNA capable of recognizing AAA lysine codons. We propose that the resultant lysine to glutamate change stabilizes thermo-labile dTMP kinase molecules in the cell.     

Involvement of cdc13+ in mitotic control in Schizosaccharomyces pombe: possible interaction of the gene product with microtubules.

Previous genetic studies have shown that the fission yeast cdc13+ gene product interacts closely with the cdc2+ protein kinase during mitosis. Here, we have cloned the cdc13+ gene from a S. pombe gene bank by complementation of the temperature-sensitive defect of a cdc13-117 mutant strain. The complementing activity was localized to a 1.9-kb XbaI-NsiI DNA fragment, and nucleotide sequencing revealed a 1446-bp open reading frame. The predicted amino acid sequence contained 482 residues and was not homologous to any protein in a protein database. The cdc13+ gene function was confirmed to be essential for cell division since cells carrying a cdc13 null allele arrested with a cdc phenotype. However, unlike any existing temperature-sensitive cdc13 mutants, cdc13 null mutants arrested in G2 without septa or condensed chromosomes indicating that cdc13+ gene function is required at or prior to the initiation of mitotis. cdc13-117 mutant strains were found to be hypersensitive to the tubulin inhibitor thiabendazole. This observation suggests that the cdc13+ gene product, which is required for mitotic initiation, may interact with microtubules.     

Conservation of mitotic controls in fission and budding yeasts

In fission yeast, the initiation of mitosis is regulated by a control network that integrates the opposing activities of mitotic inducers and inhibitors. To evaluate whether this control system is likely to be conserved among eukaryotes, we have investigated whether a similar mitotic control operates in the distantly related budding yeast S. cerevisiae. We have found that the protein kinase encoded by the mitotic inhibitor gene wee1+ of fission yeast, which acts to delay mitosis, is able also to delay the initiation of mitosis when expressed in S. cerevisiae. The wee1+ activity is counteracted in S. cerevisiae by the gene product of MIH1, a newly identified gene capable of encoding a protein of MW 54,000, which is a structural and functional homolog of the cdc25+ mitotic inducer of fission yeast. Expression of wee1+ in a mih1- strain prevents the initiation of mitosis. These data indicate that important features of the cdc25+-wee1+ mitotic control network identified in S. pombe are conserved in S. cerevisiae, and therefore are also likely to be generally conserved among eukaryotic organisms.     

The fission yeast genes pyp1+ and pyp2+ encode protein tyrosine phosphatases that negatively regulate mitosis.

We have used degenerate oligonucleotide probes based on sequences conserved among known protein tyrosine phosphatases (PTPases) to identify two Schizosaccharomyces pombe genes encoding PTPases. We previously described the cloning of pyp1+ (S. Ottilie, J. Chernoff, G. Hannig, C. S. Hoffman, and R. L. Erikson, Proc. Natl. Acad. Sci. USA 88:3455-3459, 1991), and here we describe a second gene, called pyp2+. The C terminus of each protein contains sequences conserved in the apparent catalytic domains of all known PTPases. Disruption of pyp2+ results in viable cells, as was the case for pyp1+, whereas disruption of pyp2+ and pyp1+ results in synthetic lethality. Overexpression of either pyp1+ or pyp2+ in wild-type strains leads to a delay in mitosis but is suppressed by a wee1-50 mutation at 35 degrees C or a cdc2-1w mutation. A pyp1 disruption suppresses the temperature-sensitive lethality of a cdc25-22 mutation. Our data suggest that pyp1+ and pyp2+ act as negative regulators of mitosis upstream of the wee1+/mik1+ pathway.     

Radiation-induced mitotic delay: a genetic characterization in the fission yeast.

Radiation-induced mitotic delay is under investigation in the fission yeast, Schizosaccharomyces pombe. A large range of cell cycle- and radiation-sensitive mutants of this yeast is available to facilitate this effort. Through an examination of such mutants it has been shown that the X-ray transition point and the p34cdc2 execution point are coincident; wee1- strains are not delayed by irradiation; and the radiation-sensitive mutants rad1-1, rad3-136, rad9-192, and rad17-W are not delayed by radiation or by inhibitors of DNA synthesis, including hydroxyurea. A model is proposed: Damaged DNA generates a signal to delay mitosis which is carried by the products of the rad genes to activate the tyrosine kinase p110wee1. This in turn inactivates the serine/threonine kinase p34cdc2, thereby blocking entry to mitosis. Unreplicated DNA also initiates a signal to delay mitosis which is carried by these same rad genes but, as indicated in the literature, transmission to p34cdc2 does not require p110wee1. The delay-deficient rad mutants may possess some properties of tumor suppressor genes, with implications for mutagenesis and oncogenesis.     

Characterization of the fission yeast mcs2 cyclin and its associated protein kinase activity.

We have previously described the isolation of mcs2-75, a mutation obtained as an allele-specific suppressor of a dominant allele of cdc2. mcs2 was cloned and determined to be an essential gene, the product of which shares homology with the cyclin family of proteins. In contrast to the behavior of some, but not all cyclins, the mcs2 protein is constant in its abundance and localization throughout the cell cycle. A kinase activity that co-precipitates with mcs2 can be detected when myelin basic protein (MBP) is provided as an exogenous substrate. This kinase activity is constant throughout the cell cycle. mcs2 does not appear to associate with the cdc2 protein kinase or an antigenically related kinase. Finally, a protein kinase termed csk1 (cyclin suppressing kinase) was isolated as a high copy suppressor of an mcs2 mutation. csk1 is not essential, however, the level of kinase activity that co-precipitates with mcs2 is reduced approximately 3-fold in strains harboring a csk1 null allele. Therefore, csk1 may encode a protein kinase physically associated with mcs2 or alternatively may function as an upstream activator of the mcs2-associated kinase.     

The Saccharomyces cerevisiae CKS1 gene, a homolog of the Schizosaccharomyces pombe suc1+ gene, encodes a subunit of the Cdc28 protein kinase complex.

The Saccharomyces cerevisiae gene CDC28 encodes a protein kinase required for cell cycle initiation. In an attempt to identify genes encoding proteins that interact with the Cdc28 protein kinase, high-copy plasmid suppressors of a temperature-sensitive cdc28 mutation were isolated. One such suppressor, CKS1, was found to encode an 18-kilodalton protein that shared a high degree of homology with the suc1+ protein (p13) of Schizosaccharomyces pombe (67% amino acid sequence identity). Disruption of the chromosomal CKS1 gene conferred a G1 arrest phenotype similar to that of cdc28 mutants. The presence of the 18-kilodalton Cks1 protein in yeast lysates was demonstrated by using Cks-1 specific antiserum. Furthermore, the Cks1 protein was shown to be physically associated with active forms of the Cdc28 protein kinase. These data suggest that Cks1 is an essential component of the Cdc28 protein kinase complex.