Fission Yeast Mutants Research Articles

Wobble Inosine tRNA Modification Is Essential to Cell Cycle Progression in G1/S and G2/M Transitions in Fission Yeast

Inosine (I) at position 34 (wobble position) of tRNA is formed by the hydrolytic deamination of a genomically encoded adenosine (A). The enzyme catalyzing this reaction, termed tRNA A:34 deaminase, is the heterodimeric Tad2p/ADAT2.Tad3p/ADAT3 complex in eukaryotes. In budding yeast, deletion of each subunit is lethal, indicating that the wobble inosine tRNA modification is essential for viability; however, most of its physiological roles remain unknown. To identify novel cell cycle mutants in fission yeast, we isolated the tad3-1 mutant that is allelic to the tad3(+) gene encoding a homolog of budding yeast Tad3p. Interestingly, the tad3-1 mutant cells principally exhibited cell cycle-specific phenotype, namely temperature-sensitive and irreversible cell cycle arrest both in G(1) and G(2). Further analyses revealed that in the tad3-1 mutant cells, the S257N mutation that occurred in the catalytically inactive Tad3 subunit affected its association with catalytically active Tad2 subunit, leading to an impairment in the A to I conversion at position 34 of tRNA. In tad3-1 mutant cells, the overexpression of the tad3(+) gene completely suppressed the decreased tRNA inosine content. Notably, the overexpression of the tad2(+) gene partially suppressed the temperature-sensitive phenotype and the decreased tRNA inosine content, indicating that the tad3-1 mutant phenotype is because of the insufficient I(34) formation of tRNA. These results suggest that the wobble inosine tRNA modification is essential for cell cycle progression in the G(1)/S and G(2)/M transitions in fission yeast.

Ribosomal Protein rpS2 Is Hypomethylated in PRMT3-deficient Mice

PRMT3 is a type I arginine methyltransferase that resides in the cytoplasm. A large proportion of this cystosolic PRMT3 is found associated with ribosomes. It is tethered to the ribosomes through its interaction with rpS2, which is also its substrate. Here we show that mouse embryos with a targeted disruption of PRMT3 are small in size but survive after birth and attain a normal size in adulthood, thus displaying Minute-like characteristics. The ribosome protein rpS2 is hypomethylated in the absence of PRMT3, demonstrating that it is a bona fide, in vivo PRMT3 substrate that cannot be modified by other PRMTs. Finally, the levels 40 S, 60 S, and 80 S monosomes and polyribosomes are unaffected by the loss of PRMT3, but there are additional as yet unidentified proteins that co-fractionate with ribosomes that are also dedicated PRMT3 substrates.

Valproic acid affects membrane trafficking and cell-wall integrity in fission yeast.

Valproic acid (VPA) is widely used to treat epilepsy and manic-depressive illness. Although VPA has been reported to exert a variety of biochemical effects, the exact mechanisms underlying its therapeutic effects remain elusive. To gain further insights into the molecular mechanisms of VPA action, a genetic screen for fission yeast mutants that show hypersensitivity to VPA was performed. One of the genes that we identified was vps45+, which encodes a member of the Sec1/Munc18 family that is implicated in membrane trafficking. Notably, several mutations affecting membrane trafficking also resulted in hypersensitivity to VPA. These include ypt3+ and ryh1+, both encoding a Rab family protein, and apm1+, encoding the mu1 subunit of the adaptor protein complex AP-1. More importantly, VPA caused vacuolar fragmentation and inhibited the glycosylation and the secretion of acid phosphatase in wild-type cells, suggesting that VPA affects membrane trafficking. Interestingly, the cell-wall-damaging agents such as micafungin or the inhibition of calcineurin dramatically enhanced the sensitivity of wild-type cells to VPA. Consistently, VPA treatment of wild-type cells enhanced their sensitivity to the cell-wall-digesting enzymes. Altogether, our results suggest that VPA affects membrane trafficking, which leads to the enhanced sensitivity to cell-wall damage in fission yeast.

Ribonuclease Activity of Dis3 Is Required for Mitotic Progression and Provides a Possible Link between Heterochromatin and Kinetochore Function

BackgroundCellular RNA metabolism has a broad range of functional aspects in cell growth and division, but its role in chromosome segregation during mitosis is only poorly understood. The Dis3 ribonuclease is a key component of the RNA-processing exosome complex. Previous isolation of the dis3-54 cold-sensitive mutant of fission yeast Schizosaccharomyces pombe suggested that Dis3 is also required for correct chromosome segregation.Methodology/Principal FindingsWe show here that the progression of mitosis is arrested in dis3-54, and that segregation of the chromosomes is blocked by activation of the mitotic checkpoint control. This block is dependent on the Mad2 checkpoint protein. Double mutant and inhibitor analyses revealed that Dis3 is required for correct kinetochore formation and function, and that this activity is monitored by the Mad2 checkpoint. Dis3 is a member of the highly conserved RNase II family and is known to be an essential subunit of the exosome complex. The dis3-54 mutation was found to alter the RNaseII domain of Dis3, which caused a reduction in ribonuclease activity in vitro. This was associated with loss of silencing of an ura4+ reporter gene inserted into the outer repeats (otr) and central core (cnt and imr) regions of the centromere. On the other hand, centromeric siRNA maturation and formation of the RITS RNAi effector complex was normal in the dis3-54 mutant. Micrococcal nuclease assay also suggested the overall chromatin structure of the centromere was not affected in dis3-54 mutant.Conclusions/SignificanceRNase activity of Dis3, a core subunit of exosome, was found to be required for proper kinetochore formation and establishment of kinetochore-microtubule interactions. Moreover, Dis3 was suggested to contribute to kinetochore formation through an involvement in heterochromatic silencing at both outer centromeric repeats and within the central core region. This activity is likely monitored by the mitotic checkpoint, and distinct from that of RNAi-mediated heterochromatin formation directly targeting outer centromeric repeats.

Rad4TopBP1 Associates with Srr2, an Spc1 MAPK-regulated Protein, in Response to Environmental Stress

Rad4(TopBP1) is a scaffold in a protein complex containing both replication proteins and checkpoint proteins and plays essential roles in both replication and checkpoint responses. We have previously identified four novel fission yeast mutants of rad4+(TopBP1) to explore how Rad4(TopBP1), a single protein, can play multiple roles in genomic integrity maintenance. Among the four novel mutants, rad4-c17(TopBP1) is a thermosensitive mutant. Here, we characterized rad4-c17(TopBP1) and identified a rad4-c17(TopBP1) allele specific suppressor named srr2+ (suppressor of Rad4(TopBP1) R2 domain). srr2+ has previously been identified as an environmental stress-responsive gene (GenBank accession number AL049644.1, locus spcc191.01). srr2+ null cells are sensitive to hydroxyurea (HU) at elevated temperatures. Deletion of srr2+ in rad4-c17(TopBP1) exacerbates the HU sensitivity of the mutant. Overexpression of srr2+ suppresses the rad4-c17(TopBP1) mutant sensitivity to temperature and HU and restores the compromised ability of rad4-c17(TopBP1) to activating Cds1 kinase in response to HU treatment. Furthermore, stress-activated MAPK, Spc1 (also known as StyI or Phh1), induces the expression and phosphorylation of the Srr2 protein. Significantly, environmental stress induces co-precipitation of Srr2 protein with Rad4(TopBP1), and the co-precipitation is compromised in the rad4-c17(TopBP1) mutant. These results have led us to propose a model; Rad4(TopBP1) exists in a large protein complex to coordinate genomic perturbations with checkpoint responses to maintain genomic integrity. In addition, when cells experience environmental stress, Rad4(TopBP1) associates with Srr2, an Spc1 MAPK-responsive protein, to survive the stress, potentially by providing a link of the Spc1 MAPK response to checkpoint responses.

Ordered assembly of Sld3, GINS and Cdc45 is distinctly regulated by DDK and CDK for activation of replication origins

Initiation of chromosome DNA replication in eukaryotes is tightly regulated through assembly of replication factors at replication origins. Here, we investigated dependence of the assembly of the initiation complex on particular factors using temperature-sensitive fission yeast mutants. The psf3-1 mutant, a GINS component mutant, arrested with unreplicated DNA at the restrictive temperature and the DNA content gradually increased, suggesting a defect in DNA replication. The mutation impaired GINS complex formation, as shown by pull-down experiments. Chromatin immunoprecipitation assays indicated that GINS integrity was required for origin loading of Psf2, Cut5 and Cdc45, but not Sld3. In contrast, loading of Psf2 onto origins depended on Sld3 and Cut5 but not on Cdc45. These results suggest that Sld3 functions furthest upstream in initiation complex assembly, followed by GINS and Cut5, then Cdc45. Consistent with this conclusion, Cdc7-Dbf4 kinase (DDK) but not cyclin-dependent kinase (CDK) was required for Sld3 loading, whereas recruitment of the other factors depended on both kinases. These results suggest that DDK and CDK regulate distinct steps in activation of replication origins in fission yeast.

Noncore Components of the Fission Yeast γ-Tubulin Complex

Relatively little is known about the in vivo function of individual components of the eukaryotic gamma-tubulin complex (gamma-TuC). We identified three genes, gfh1+, mod21+, and mod22+, in a screen for fission yeast mutants affecting microtubule organization. gfh1+ is a previously characterized gamma-TuC protein weakly similar to human gamma-TuC subunit GCP4, whereas mod21+ is novel and shows weak similarity to human gamma-TuC subunit GCP5. We show that mod21p is a bona fide gamma-TuC protein and that, like gfh1Delta mutants, mod21Delta mutants are viable. We find that gfh1Delta and mod21Delta mutants have qualitatively normal microtubule nucleation from all types of microtubule-organizing centers (MTOCs) in vivo but quantitatively reduced nucleation from interphase MTOCs, and this is exacerbated by mutations in mod22+. Simultaneous deletion of gfh1p, mod21p, and alp16p, a third nonessential gamma-TuC protein, does not lead to additive defects, suggesting that all three proteins contribute to a single function. Coimmunoprecipitation experiments suggest that gfh1p and alp16p are codependent for association with a small "core" gamma-TuC, whereas mod21p is more peripherally associated, and that gfh1p and mod21p may form a subcomplex independently of the small gamma-TuC. Interestingly, sucrose gradient analysis suggests that the major form of the gamma-TuC in fission yeast may be a small complex. We propose that gfh1p, mod21p, and alp16 act as facultative "noncore" components of the fission yeast gamma-TuC and enhance its microtubule-nucleating ability.

Regulation of DNA Replication Machinery by Mrc1 in Fission Yeast

Faithful replication of chromosomes is crucial to genome integrity. In yeast, the ORC binds replication origins throughout the cell cycle. However, Cdc45 binds these before S-phase, and, during replication, it moves along the DNA with MCM helicase. When replication progression is inhibited, checkpoint regulation is believed to stabilize the replication fork; the detailed mechanism, however, remains unclear. To examine the relationship between replication initiation and elongation defects and the response to replication elongation block, we used fission yeast mutants of Orc1 and Cdc45--orp1-4 and sna41-928, respectively--at their respective semipermissive temperatures with regard to BrdU incorporation. Both orp1 and sna41 cells exhibited HU hypersensitivity in the absence of Chk1, a DNA damage checkpoint kinase, and were defective in full activation of Cds1, a replication checkpoint kinase, indicating that normal replication is required for Cds1 activation. Mrc1 is required to activate Cds1 and prevent the replication machinery from uncoupling from DNA synthesis. We observed that, while either the orp1 or the sna41 mutation partially suppressed HU sensitivity of cds1 cells, sna41 specifically suppressed that of mrc1 cells. Interestingly, sna41 alleviated the defect in recovery from HU arrest without increasing Cds1 activity. In addition to sna41, specific mutations of MCM suppressed the HU sensitivity of mrc1 cells. Thus, during elongation, Mrc1 may negatively regulate Cdc45 and MCM helicase to render stalled forks capable of resuming replication.

The transition metal chelator nicotianamine is synthesized by filamentous fungi

Nicotianamine is an important metal ligand in plants. Surprisingly, recent genome sequencing revealed that ascomycetes encode proteins with similarity to plant nicotianamine synthases (NAS). By expression in a Zn 2+-hypersensitive fission yeast mutant we show for a protein from Neurospora crassa that it indeed possesses NAS activity. Using electrospray-ionization-quadrupole-time-of-flight mass spectrometry we prove the formation of nicotianamine in N. crassa. Transcript level is strongly upregulated under Zn deficiency as shown by real-time PCR. These findings demonstrate that nicotianamine is more widespread in nature than anticipated and provide further evidence for a function of nicotianamine as a cytosolic chelator of Zn 2+ ions.

Is genomic grading killing histological grading?

Two previously unidentified human cdc25 genes have been isolated, cdc25A and cdc25B. Both genes rescue a cdc25ts mutant of fission yeast. Microinjection of anti-cdc25A antibodies into HeLa cells causes their arrest in mitosis. cdc25A and cdc25B display endogenous tyrosine phosphatase activity that is stimulated several-fold, in the absence of cdc2, by stoichiometric addition of either cyclin B1 or B2 but not A or D1. Association between cdc25A and cyclin B1cdc2 was detected in the HeLa cells. These findings indicate that B-type cyclins are multifunctional proteins that not only act as M phase regulatory subunits of the cdc2 protein kinase, but also activate the cdc25 tyrosine phosphatase, of which cdc2 is the physiological substrate. A region of amino acid similarity between cyclins and tyrosine PTPases has been detected. This region is absent in cdc25 phosphatases. The motif may represent an activating domain that has to be provided to cdc25 by intermolecular interaction with cyclin B.

Regulation of Cdc2p and Cdc13p Is Required for Cell Cycle Arrest Induced by Defective RNA Splicing in Fission Yeast

Screening of cdc mutants of fission yeast for those whose cell cycle arrest is independent of the DNA damage checkpoint identified the RNA splicing-deficient cdc28 mutant. A search for mutants of cdc28 cells that enter mitosis with unspliced RNA resulted in the identification of an orb5 point mutant. The orb5+ gene, which encodes a catalytic subunit of casein kinase II, was found to be required for cell cycle arrest in other mutants with defective RNA metabolism but not for operation of the DNA replication or DNA damage checkpoints. Loss of function of wee1+ or rad24+ also suppressed the arrest of several splicing mutants. Overexpression of the major B-type cyclin Cdc13p induced cdc28 cells to enter mitosis. The abundance of Cdc13p was reduced, and the phosphorylation of Cdc2p on tyrosine 15 was maintained in splicing-defective cells. These results suggest that regulation of Cdc13p and Cdc2p is required for G2 arrest in splicing mutants.

A screen for Schizosaccharomyces pombe mutants defective in rereplication identifies new alleles of rad4+, cut9+ and psf2+.

Fission yeast mutants defective in DNA replication have widely varying morphological phenotypes. We designed a screen for temperature-sensitive mutants defective in the process of replication regardless of morphology by isolating strains unable to rereplicate their DNA in the absence of cyclin B (Cdc13). Of the 42 rereplication-defective mutants analyzed, we were able to clone complementing plasmids for 10. This screen identified new alleles of the APC subunit cut9(+), the initiation/checkpoint factor rad4(+)/cut5(+), and the first mutant allele of psf2(+), a subunit of the novel GINS replication complex. Other genes identified are likely to play general roles in gene expression and protein localization.

The A78V Mutation in the Mad3-like Domain ofSchizosaccharomyces pombeBub1p Perturbs Nuclear Accumulation and Kinetochore Targeting of Bub1p, Bub3p, and Mad3p and Spindle Assembly Checkpoint Function

During mitosis, the spindle assembly checkpoint (SAC) responds to faulty attachments between kinetochores and the mitotic spindle by imposing a metaphase arrest until the defect is corrected, thereby preventing chromosome missegregation. A genetic screen to isolate SAC mutants in fission yeast yielded point mutations in three fission yeast SAC genes: mad1, bub3, and bub1. The bub1-A78V mutant is of particular interest because it produces a wild-type amount of protein that is mutated in the conserved but uncharacterized Mad3-like region of Bub1p. Characterization of mutant cells demonstrates that the alanine at position 78 in the Mad3-like domain of Bub1p is required for: 1) cell cycle arrest induced by SAC activation; 2) kinetochore accumulation of Bub1p in checkpoint-activated cells; 3) recruitment of Bub3p and Mad3p, but not Mad1p, to kinetochores in checkpoint-activated cells; and 4) nuclear accumulation of Bub1p, Bub3p, and Mad3p, but not Mad1p, in cycling cells. Increased targeting of Bub1p-A78V to the nucleus by an exogenous nuclear localization signal does not significantly increase kinetochore localization or SAC function, but GFP fused to the isolated Bub1p Mad 3-like accumulates in the nucleus. These data indicate that Bub1p-A78V is defective in both nuclear accumulation and kinetochore targeting and that a threshold level of nuclear Bub1p is necessary for the nuclear accumulation of Bub3p and Mad3p.

Schizosaccharomyces pombe Pmr1p is essential for cell wall integrity and is required for polarized cell growth and cytokinesis.

The cps5-138 fission yeast mutant shows an abnormal lemon-like morphology at 28 degrees C in minimal medium and a lethal thermosensitive phenotype at 37 degrees C. Cell growth is completely inhibited at 28 degrees C in a Ca2+-free medium, in which the wild type is capable of growing normally. Under these conditions, actin patches become randomly distributed throughout the cell, and defects in septum formation and subsequent cytokinesis appear. The mutant cell is hypersensitive to the cell wall-digesting enzymatic complex Novozym234 even under permissive conditions. The gene SPBC31E1.02c, which complements all the mutant phenotypes described above, was cloned and codes for the Ca2+-ATPase homologue Pmr1p. The gene is not essential under optimal growth conditions but is required under conditions of low Ca2+ (<0.1 mM) or high temperature (>35 degrees C). The green fluorescent protein-tagged Cps5 proteins, which are expressed under physiological conditions (an integrated single copy with its own promoter in the cps5Delta strain), display a localization pattern typical of endoplasmic reticulum proteins. Biochemical analyses show that 1,3-beta-D-glucan synthase activity in the mutant is decreased to nearly half that of the wild type and that the mutant cell wall contains no detectable galactomannan when the cells are exposed to a Ca2+-free medium. The mutant acid phosphatase has an increased electrophoretic mobility, suggesting that incomplete protein glycosylation takes place in the mutant cells. These results indicate that S. pombe Pmr1p is essential for the maintenance of cell wall integrity and cytokinesis, possibly by allowing protein glycosylation and the polarized actin distribution to take place normally. Disruption and complementation analyses suggest that Pmr1p shares its function with a vacuolar Ca2+-ATPase homologue, Pmc1p (SPAPB2B4.04c), to prevent lethal activation of calcineurin for cell growth.

AtSGP1, AtSGP2 and MAP4K alpha are nucleolar plant proteins that can complement fission yeast mutants lacking a functional SIN pathway.

In the fission yeast Schizosaccharomyces pombe, the onset of septum formation is signalled via the septation initiation network (SIN) involving several protein kinases and a GTPase. Arabidopsis thaliana and Brassica napus proteins homologous to fission yeast spg1p (AtSGP1, AtSGP2), cdc7p (AtMAP3K epsilon 1, AtMAP3K epsilon 2, BnMAP3K epsilon 1) and sid1p (AtMAP4K alpha 1, AtMAP4K alpha 2, BnMAP4K alpha 2) exhibit a significant similarity. The plant proteins AtSGP1/2 and BnMAP4K alpha 2 are able to complement the S. pombe mutant proteins spg1-B8 and sid1-239, respectively and to induce mutisepta when overexpressed in wild-type yeast. Yeast two-hybrid assays demonstrated interactions both between plant proteins and between plant and yeast proteins of the SIN pathway. However, the primary structure of the proteins as well as the partial complementation of yeast mutants indicates that plant homologous proteins and their yeast counterparts have diverged during evolution. Real-time RT-PCR studies demonstrated plant SIN-related gene expression in all organs tested and a co-expression pattern during the cell cycle, with a higher accumulation at G(2)-M. During interphase, the plant SIN-related proteins were found to co-localise predominantly in the nucleolus of the plant cells, as shown by fusions to green fluorescent protein. These data suggest the existence of a plant SIN-related pathway.

Characterization of end4+, a gene required for endocytosis in Schizosaccharomyces pombe.

To understand endocytic trafficking in Schizosaccharomyces pombe, we constructed an end4 disruption mutant. The end4+ gene encodes a protein homologous to Sla2p/End4p, which is essential for the assembly and function of the cytoskeleton and endocytosis in Saccharomyces cerevisiae. We characterized the fission yeast mutant end4 Delta as well as ypt7 Delta, which is deficient in vacuolar fusion and, hence, endocytosis. The delivery of FM4-64 to the vacuolar membrane, accumulation of Lucifer yellow CH and internalization of plasma membrane protein Map3-GFP were inhibited in the end4 mutant. Deletion of end4 resulted in pleiotropic phenotypes consistent with F-actin depolarization, including high temperature sensitivity, abnormal morphology and mating defects. Extensive missorting of carboxypeptidase Y was detected in the ypt7 mutant; however, little missorting was detected in the end4 mutant. These results indicate that End4p is essential for the internalization process and Ypt7p affects endocytosis at a post-internalization step after the intersection of the endocytic and the vacuolar protein-sorting pathways in fission yeast.

The Clp1p/Flp1p phosphatase ensures completion of cytokinesis in response to minor perturbation of the cell division machinery in Schizosaccharomyces pombe.

Fission yeast mutants defective in actomyosin ring formation and function exhibit a prolonged G2 delay following cytokinesis failure. This G2 delay depends on the SIN, a signaling network essential for cytokinesis, and the non-essential Cdc14p family phosphatase, Clp1p/Flp1p and has been proposed to signify a cytokinesis checkpoint mechanism. However, the physiological relevance of this proposed Clp1p/Flp1p-dependent checkpoint is unclear because all previous studies were carried out using mutations in essential actomyosin ring components under fully restrictive conditions and thus these cells would have died regardless of the presence of the checkpoint. Here we show that delays in cytokinesis caused by minor perturbations to different components of the cytokinetic machinery, which normally cause only mild defects, become lethal when Clp1p/Flp1p is inactivated. In addition, we show that Clp1p/Flp1p does not function simply to inhibit further rounds of nuclear division, but also allows damaged actomyosin rings to be maintained to facilitate completion of cell division. Ectopic activation of the SIN significantly bypasses the requirement of Clp1p/Flp1p for G2 delay as well as for completion of cytokinesis. We conclude that the Clp1p/Flp1p-dependent cytokinesis checkpoint provides a previously unrecognized cell survival advantage when the cell division apparatus is mildly perturbed.

Ddb1 Is Required for the Proteolysis of the Schizosaccharomyces pombe Replication Inhibitor Spd1 during S Phase and after DNA Damage

Recently we showed that the Schizosaccharomyces pombe ddb1 gene plays a role in S phase progression. A mutant S. pombe strain lacking expression of the ddb1 gene exhibited slow replication through both early and late regions causing a slow S phase phenotype. We attributed the phenotypes in the ddb1 strain to an increased activity of the replication checkpoint kinase Cds1. However, the basis for a high basal Cds1 activity in the ddb1 strain was not clear. It was shown that Ddb1 associates with the Cop9/signalosome. Moreover, the phenotypes of the Deltaddb1 strain are remarkably similar to the Deltacsn1 (or Deltacsn2) strain that lacks expression of the Csn1 (or Csn2) subunit of the Cop9/signalosome. Cop9/signalosome cooperates with Pcu4 to induce proteolysis of Spd1, which inhibits DNA replication by inhibiting ribonucleotide reductase. Therefore, we investigated whether Ddb1 is required for the proteolysis of Spd1. Here we show that a S. pombe strain lacking expression of Ddb1 fails to induce proteolysis of Spd1 in S phase and after DNA damage. Moreover, deletion of the spd1 gene attenuates the Cds1 kinase activity in cells lacking the expression of ddb1, suggesting that an accumulation of Spd1 results in the increase of Cds1 activity in the Deltaddb1 strain. In addition, the double mutant lacking spd1 and ddb1 no longer exhibits the growth defects and DNA damage sensitivity observed in the Deltaddb1 strain. Our results establish an essential role of Ddb1 in the proteolysis of Spd1. In addition, the observation provides evidence for a functional link between Ddb1 and the Cop9/signalosome.

Size control in growing yeast and mammalian cells

BackgroundIn a recent publication it was claimed that cultured mammalian cells, in contrast to yeasts, maintain a constant size distribution in the population without a size checkpoint. This inference may be challengeable.Results(1) It is argued that "weak" size control implies the existence of a checkpoint, and unfortunately the technique used by Conlon and Raff might obscure such a weak mechanism. (2) Previous investigations of size control in yeasts have shown that individual cell data, rather than means and variances of cell populations, are prerequisites for reliable interpretation. (3) No experimental data so far obtained suggest that in any cell culture a linear growth pattern in cell mass can maintain size homeostasis on its own without size control. (4) Studies on fission yeast mutants indicate that the molecular mechanisms of size control vary with genetic background, implying that no single mechanism is likely to apply to any cell type, including cultured mammalian cells, under all conditions.ConclusionThe claim that cultured mammalian cells maintain size homeostasis without a checkpoint needs to be re-evaluated by measurements on individual cells.

The Arabidopsis 14-3-3 protein, GF14omega, binds to the Schizosaccharomyces pombe Cdc25 phosphatase and rescues checkpoint defects in the rad24- mutant.

The fission yeast (S. pombe) mitotic inducer gene, Spcdc25, interacts with the plant cell cycle to establish a small cell size phenotype compared with wild-type cells. We have investigated the nature of this interaction by yeast two-hybrid screening using Spcdc25 as bait in a cDNA library prepared from root tips of Arabidopsis thaliana (L.) Heynh. Three 14-3-3 proteins were detected: G-box Factor-like (GF)14kappa, lambda and omega; binding with Spcdc25 was confirmed by an independent immunoprecipitation assay. To test for cell cycle checkpoint function, GF14kappa, lambda and omega were transformed independently, using the strong nmt1+ promoter, into rad24-, a fission yeast mutant deficient in a 14-3-3 checkpoint protein. When exposed to UV irradiation or in the presence of 10 mM hydroxyurea, only cells transformed with GF14omega could fully rescue the defects in the DNA-damage and DNA-replication checkpoints of this mutant. Supporting evidence for a GF14omega cell cycle function was provided by semi-quantitative reverse transcription-polymerase chain reaction indicating that expression of this gene was elevated in regions of the plant that comprise dividing cells whereas GF14kappa and lambda expression was more evenly detected in all tissues examined. The data are consistent with the hypothesis that interaction between Spcdc25 and the plant cell cycle occurs at the level of a 14-3-3 protein with distinct checkpoint properties.