Fission yeast Cdc37 is required for multiple cell cycle functions.

The identification of a Schizosaccharomyces pombe homologue of the cdc37 gene is described. The gene product is most similar to the budding yeast homologue, but shows similarity to metazoan Cdc37 proteins, with a region of high similarity at the extreme N-terminus. Gene transplacement experiments in diploid cells followed by tetrad dissection show that the gene is essential. Depletion of the gene product after switching off expression of cdc37 from the regulatable nmt81 promoter results in cessation of growth and division. The cells arrest heterogeneously, with a significant proportion showing mitotic defects; paradoxically, a proportion of the cells show a short-cell phenotype consistent with an advanced cell cycle.

MCB-mediated regulation of cell cycle-specific cdc22+ transcription in fission yeast.

The cdc22+ gene of the fission yeast, Schizosaccharomyces pombe, encodes the large subunit of ribonucleotide reductase, and is periodically expressed during the mitotic cell cycle, transcript abundance reaching a maximum at the G1-S boundary. This regulation of expression is controlled by a transcription factor complex called DSC1, which binds to MCB motifs (ACGCGT) present in the promoter of cdc22+. cdc22+ has a complex pattern of MCBs, including two clusters of four motifs each, one of which is located within the transcribed region. We show that both clusters of MCBs contribute to the regulation of cdc22+ expression during the cell cycle, each having a different role. The MCB cluster within the transcribed region has the major role in regulating cdc22+, as its removal results in loss of transcription. The upstream cluster, instead, controls cell cycle-specific transcription through a negative function, as its removal results in expression of cdc22+ throughout the cell cycle. Both MCB clusters bind DSC1. We show that the interaction of DSC1 with the MCB cluster within the transcribed region has a high "on-off" rate, suggesting a mechanism by which DSC1 could activate expression, and still allow RNA polymerase to pass during transcription. Finally, we show that both clusters are orientation-dependent in their function. The significance of these results, in the context of MCB-mediated regulation of G1-S expression in fission yeast, is discussed.

Essential interaction between the fission yeast DNA polymerase delta subunit Cdc27 and Pcn1 (PCNA) mediated through a C-terminal p21(Cip1)-like PCNA binding motif.

Direct interaction between DNA polymerase delta and its processivity factor proliferating cell nuclear antigen (PCNA) is essential for effective replication of the eukaryotic genome, yet the precise manner by which this occurs is unclear. We show that the 54 kDa subunit of DNA polymerase delta from Schizosaccharomyces pombe interacts directly with Pcn1 (PCNA) both in vivo and in vitro. Binding is effected via a short sequence at the C-terminus of Cdc27 with significant similarity to the canonical PCNA binding motif first identified in the mammalian p21(Cip1) protein. This motif is both necessary and sufficient for binding of Pcn1 by Cdc27 in vitro and is essential for Cdc27 function in vivo. We also show that the Pcn1 binding motif in Cdc27 is distinct from its binding site for Cdc1, the 55 kDa B-subunit of polymerase delta, and present evidence that Cdc27 can bind to Pcn1 and Cdc1 simultaneously. Finally, we show that Cdc27 performs at least two distinct essential functions, one of which is independent of Pcn1 binding.

A key role for replication factor C in DNA replication checkpoint function in fission yeast.

Replication factor C (RF-C) is a five subunit DNA polymerase (Pol) delta/straightepsilon accessory factor required at the replication fork for loading the essential processivity factor PCNA onto the 3'-ends of nascent DNA strands. Here we describe the genetic analysis of the rfc2 +gene of the fission yeast Schizosaccharomyces pombe encoding a structural homologue of the budding yeast Rfc2p and human hRFC37 proteins. Deletion of the rfc2 + gene from the chromosome is lethal but does not result in the checkpoint-dependent cell cycle arrest seen in cells deleted for the gene encoding PCNA or for those genes encoding subunits of either Pol delta or Pol straightepsilon. Instead, rfc2 Delta cells proceed into mitosis with incompletely replicated DNA, indicating that the DNA replication checkpoint is inactive under these conditions. Taken together with recent results, these observations suggest a simple model in which assembly of the RF-C complex onto the 3'-end of the nascent RNA-DNA primer is the last step required for the establishment of a checkpoint-competent state.

Cdm1, the smallest subunit of DNA polymerase d in the fission yeast Schizosaccharomyces pombe, is non-essential for growth and division.

Highly purified DNA polymerase delta from the fission yeast Schizosaccharomyces pombe is a complex of at least four distinct subunits. Genes encoding three of these (pol3+/cdc6+, cdc1+ and cdc27+) have been characterised previously. Here we describe the isolation and characterisation of cdm1+, the gene encoding the smallest (22kDa) subunit of the Pol delta complex. Over-expression of cdm1+, which encodes a 160 amino-acid protein with no significant sequence similarity to proteins in current databases, is able to rescue cells carrying temperature-sensitive mutations in either pol3+/cdc6+, cdc1+ or cdc27+. Cells deleted for cdm1+ are viable, indicating that cdm1+ is non-essential for mitotic growth, and are no more sensitive to a variety of DNA replication inhibitors and DNA damaging agents than are wild-type cells. In addition, over-expression of cdm1+ suppresses the temperature-sensitive cdc24-M38 mutant suggesting that cdc24+ may also have a role in DNA polymerase delta function.

The fission yeast mitotic regulator win1+ encodes an MAP kinase kinase kinase that phosphorylates and activates Wis1 MAP kinase kinase in response to high osmolarity.

The Schizosaccharomyces pombe win1-1 mutant has a defect in the G2-M transition of the cell cycle. Although the defect is suppressed by wis1+ and wis4+, which are components of a stress-activated MAP kinase pathway that links stress response and cell cycle control, the molecular identity of Win1 has not been known. We show here that win1+ encodes a polypeptide of 1436 residues with an apparent molecular size of 180 kDa and demonstrate that Win1 is a MAP kinase kinase kinase that phosphorylates and activates Wis1. Despite extensive similarities between Win1 and Wis4, the two MAP kinase kinase kinases have distinct functions. Wis4 is able to compensate for loss of Win1 only under unstressed conditions to maintain basal Wis1 activity, but it fails to suppress the osmosignaling defect conferred by win1 mutations. The win1-1 mutation is a spontaneous duplication of 16 nucleotides, which leads to a frameshift and production of a truncated protein lacking the kinase domain. We discuss the cell cycle phenotype of the win1-1 cdc25-22 wee1-50 mutant and its suppression by wis genes.

Multiple modes of activation of the stress-responsive MAP kinase pathway in fission yeast.

The Schizosaccharomyces pombe wis1(+) gene is essential for cell survival under stress conditions. The MAPKK homologue Wis1 is required for activation of the MAPK homologue Spc1, and integrity of the Wis1-Spc1 pathway is required for survival in extreme conditions of heat, osmolarity, oxidation or limited nutrition. We show here that Wis4, a protein kinase of a new MAPKKK class, phosphorylates Wis1 in vitro and activates it in vivo. Win1 is also required for full activation of Wis1, and Win1 rather than Wis4 mediates the osmotic stress signal. Surprisingly, the pathway can still be activated by heat or oxidative stress independently of the phosphorylation of two conserved Wis1 residues. Evidence is presented that the Pyp1 protein tyrosine phosphatase, which dephosphorylates Spc1, is central to this alternative activation mechanism.

Genetic and physiological analysis of DNA replication in fission yeast.

Studies on DNA replication in S. pombe have provided powerful insights into the way in which the genome of this model eukaryote is replicated and how the replication process is controlled. These studies have been facilitated by the simplicity and range of methods available in this organism for physiological and genetic analysis of DNA replication mutants. In the future, continued focus on the analysis of such mutants, coupled with increasingly sophisticated biochemical investigation of the processes of DNA replication in both wild-type and mutant cells, will ensure continued rapid progress in this area.

The fission yeast Cdc1 protein, a homologue of the small subunit of DNA polymerase delta, binds to Pol3 and Cdc27.

cdc1+ is required for cell cycle progression in Schizosaccharomyces pombe. Cells carrying temperature-sensitive cdc1 mutants undergo cell cycle arrest when shifted to the restrictive temperature, becoming highly elongated. Here we describe the cloning and sequencing of cdc1+, which is shown to encode a 462 residue protein that displays significant sequence similarity to the small subunit of mammalian DNA polymerase delta. cdc1+ interacts genetically with pol3+, which encodes the large subunit of DNA polymerase delta in fission yeast, and the Cdc1 protein binds to Pol3 in vitro, strongly suggesting that Cdc1 is likely to be the small subunit of Pol delta. In addition, we show that cdc1+ overexpression is sufficient to rescue cells carrying temperature-sensitive cdc27 alleles and that the Cdc1 and Cdc27 proteins interact in vivo and in vitro. Deletion of either cdc1+ or cdc27+ results in cell cycle arrest with the arrested cells having a single nucleus with 2C DNA content. No evidence was obtained for a cut phenotype, indicating that neither cdc1+ nor cdc27+ is required for checkpoint function. cdc1 mutant cells are supersensitive to the DNA synthesis inhibitor hydroxyurea and to the DNA damaging agent MMS, display increased frequency of mini-chromosome loss and have an extended S phase.

Cell cycle, DNA damage and heat shock regulate suc22+ expression in fission yeast.

The suc22+ gene of Schizosaccharomyces pombe encodes the small subunit of ribonucleotide reductase. Two transcripts that hybridise to suc22+ have previously been described: a constitutive transcript of 1.5 kb, and a transcript of approximately 1.9 kb that is induced when DNA replication is blocked by hydroxyurea. In this paper we show that both transcripts derive from the suc22+ gene, are polyadenylated, and have transcription initiation sites separated by approximately 550 nucleotides. The absence of translation initiation codons and predicted intron splice sites within this 550 nucleotide region suggests strongly that both transcripts encode the same protein. Under normal growth conditions, the larger suc22+ transcript is present at a very low level. This low level expression is periodic during the cell cycle, showing a pattern similar to that of other genes under regulation by MCB elements with a maximum in G1/S phase. Consistent with this, there are MCB elements upstream of the initiation site of the transcript. This pattern of expression contrasts with the continuous expression, at a much higher level, of the smaller suc22+ transcript. The larger suc22+ transcript is induced by exposure of cells to 4-nitroquinoline oxide (4-NQO),a UV-mimetic agent that causes DNA damage. The transcriptional response to 4-NQO is observed in cells previously arrested in G2 by a cdc2ts mutation, demonstrating that induction can occur outside S phase. We show that the rad1+ gene, part of the mitotic checkpoint, is required for induction of the large transcript. Exposure of cells to heat shock also induces the suc22+ large transcript: a consensus heat shock element has been identified upstream of the large transcript start site.

Stress signal, mediated by a Hog1-like MAP kinase, controls sexual development in fission yeast.

We identified the phh1+ gene that encodes a MAP kinase as the effector of Wis1 MAP kinase kinase in fission yeast, which is highly homologous with HOG1 of S. cerevisiae. Heterothalic phh1 dsiruptant is phenotypically indistinguishable from wis1 deletion mutant, both displaying the same extent of partial sterility and enhanced sensitivity to a variety of stress. In phh1 disruptant, nitrogen starvation-induced expression of ste11+, a key controller of sexual differentiation, is markedly diminished. Ectopic expression of ste11+ effectively restores fertility, but not stress resistance, to the phh1 disruptant. These data show that stress signal, mediated by a MAP kinase, is required for efficient start of sexual differentiation.

Positive and negative roles for cdc10 in cell cycle gene expression.

In this paper we describe properties of the cdc10-C4 mutant of the fission yeast Schizosaccharomyces pombe. The cdc10+ gene encodes a component of the DSC1Sp/MBF transcription complex, which is required for cell-cycle regulated expression at G1-S of several genes via cis-acting MCB (MIuI cell cycle box) elements. At permissive temperatures cdc10-C4 causes expression of MCB-regulated genes through the whole cell cycle, which in asynchronously dividing cells is manifested in overall higher expression levels. This overexpression phenotype is cold sensitive: in cdc10-C4 cells, MCB genes are expressed offprogressively higher levels at lower temperatures. In heterozygous cdc10-C4/cdc10+ diploid strains, MCB-regulated genes are not overexpressed, suggesting that loss, rather than alteration, of function of the cdc10-C4 gene product is the reason for unregulated target gene expression. Consistent with this, the cdc10-C4 mutant allele is known to encode a truncated protein. We have also overexpressed the region of the cdc10 protein absent in cdc10-C4 under the control of an inducible promoter. This induces a G1 delay, and additionally causes a reduction of the overexpression of MCB genes in cdc10-C4 strains. These results suggest that DSC1Sp/MBF represses, as well as activates, MCB gene expression during the cell cycle.

Five novel elements involved in the regulation of mitosis in fission yeast.

Five new elements of the mitotic control in the fission yeast Schizosaccharomyces pombe were isolated from gene libraries as multicopy suppressors of the conditional lethal phenotype of win1-1 wee1ts cdc25ts triple mutant strains. These genes were designated wis1(+)-wis5+ for win suppressing, and do not correspond to win1+ or any of the previously characterised mitotic control genes. None of the wis genes is capable of suppressing the cdc phenotype of cdc25ts strains, suggesting that their effect is not simply to reverse the effect of loss of cdc25 function. wis1+ has been previously reported to encode a putative serine/threonine protein kinase that acts as a dosage-dependent inducer of mitosis. wis4+ appears to be a specific suppressor of the win1-1 mutation. wis2+ and wis3+ are capable of suppressing a wide range of cdc phenotypes arising from the combination of various mutations with wee1ts and cdc25ts, suggesting that the wis2+ and wis3+ products may interact with elements central to the mitotic control.

Molecular cloning and sequence analysis of cdc27+ required for the G2-M transition in the fission yeast Schizosaccharomyces pombe.

The cell division cycle gene cdc27+ of the fission yeast Schizosaccharomyces pombe is required for the transition from G2 into mitosis. Genetic and physiological experiments suggest a close relationship between cdc27+ and the cdc2+ gene, a key regulator of mitosis in yeast and also in higher eukaryotic cells. We isolated the cdc27+ gene by complementation of a temperature-sensitive cdc27 mutant. The DNA sequence of this gene predicts a 1116 nucleotide open reading frame split by five short introns, ranging in size from 49 to 74 nucleotides. Analysis of cDNA clones confirmed the structure of the gene. The deduced cdc27+ gene product consists of 372 amino acids with a predicted Mr of 43 kDa. No homology of the predicted protein with known proteins could be found, thus the cdc27+ gene encodes a novel function required for the G2-M transition. Northern analysis revealed two mRNAs of 1.4 and 2.2 kb transcribed from this gene, the smaller transcript being approximately tenfold more abundant than the larger. The level of cdc27+ mRNAs remained constant through the cell cycle indicating that the time of action of the cdc27+ gene, which is known to be regulated by elements of the mitotic control, is not determined by periodic accumulation of its transcripts.

Control of DNA synthesis genes in fission yeast by the cell-cycle gene cdc10+.

In the budding yeast Saccharomyces cerevisiae, cell-cycle control over DNA synthesis occurs partly through the coordinate expression in late G1 phase of many, if not all, of the genes required for DNA synthesis. A cis-acting hexamer element ACGCGT (an MluI restriction site) is responsible for coordinating transcriptional regulation of these genes at the G1/S phase boundary and we have identified a binding activity, DSC1, that recognizes these sequences in a cell-cycle-dependent manner. In the distantly related fission yeast Schizosaccharomyces pombe, only one of the known DNA synthesis genes, cdc22+, which encodes a subunit of ribonucleotide reductase, is periodically expressed in late G1 (ref. 6). The promoter region of cdc22+ has two MluI sites and five related sequences, suggesting that similar controls over DNA synthesis genes could occur in fission yeast. We report here a binding activity in fission yeast that is very similar to DSC1 in budding yeast. We also show that the fission yeast cdc10+ gene product, which is required for Start and entry into S phase, is a component of this binding activity.

The wis1 protein kinase is a dosage-dependent regulator of mitosis in Schizosaccharomyces pombe.

The wis1+ gene encodes a newly identified mitotic control element in Schizosaccharomyces pombe. It was isolated by virtue of its interaction with the mitotic control genes cdc25, wee1 and win1. The wis1+ gene potentially encodes a 66 kDa protein with homology to the serine/threonine family of protein kinases. wis1+ plays an important role in the regulation of entry into mitosis, as it shares with cdc25+ and nim1+/cdr1+ the property of inducing mitosis in a dosage-dependent manner. Increased levels of wis1+ expression cause mitotic initiation to occur at a reduced cell size. Loss of wis1+ function does not prevent vegetative growth and division, though wis1- cells show an elongated morphology, indicating that their entry into mitosis and cell division is delayed relative to wild type cells. wis1- cells undergo a rapid reduction of viability upon entry into stationary phase, suggesting a role for wis1+ in the integration of nutritional sensing with the control over entry into mitosis.

Controlling cell cycle progress in the fission yeast Schizosaccharomyces pombe.

The suitability of fission yeast as a model for understanding the eukaryotic cell cycle has been validated in five years of exciting developments. We review recent advances in understanding the nature of the controls that regulate progression through the cell cycle and the coordination of DNA replication and mitosis.

New elements in the mitotic control of the fission yeast Schizosaccharomyces pombe.

The p107wee1 protein kinase plays a central role in regulating the cell cycle of fission yeast. It mediates transmission of signal(s) related to the nutritional status of the cell to the p34cdc2 protein kinase, which is an active component of the MPF complex driving cells into mitosis. p107wee1 is itself subject to control by the products of other genes such as nim1+/cdr1+, win1+, and perhaps wis1+ and other wis+ genes. At present, the relationships between these genes and their possible roles in the mitotic control are unclear and must await further analysis (Fig. 5). It is likely that some of the gene products are concerned with the sensing and/or transmission of nutritional signals. p107wee1 negatively regulates the activity of p34cdc2, probably by direct tyrosine phosphorylation, and also appears to regulate the activities of the cdc1+ and cdc27+ gene products. The effects of nitrogen starvation and of wee1 mutations on conditional lethal mutations at the cdc1, cdc2, and cdc27 loci, taken together, support the largely speculative model shown in Figure 5. During the normal cycle, the balance between phosphorylated and dephosphorylated p34cdc2 changes such that at the appropriate time, p34cdc2 is activated and the cell enters mitosis. We suggest that the cdc1+ and cdc27+ products may be regulated in a similar way. Such a mechanism would ensure coordinated activation of these and perhaps other proteins required for the G2/M transition. There are, of course, many uncertainties, and these must await elucidation by biochemical and genetic analysis.