S. pombe pac1+, whose overexpression inhibits sexual development, encodes a ribonuclease III-like RNase.

The Schizosaccharomyces pombe pac1 gene is a multicopy suppressor of the pat1 temperature-sensitive mutation, which directs uncontrolled meiosis at the restrictive temperature. Overexpression of the pac1 gene had no apparent effect on vegetative growth but inhibited mating and sporulation in wild type S. pombe cells. In such cells, expression of certain genes required for mating or meiosis was inhibited. The pac1 gene is essential for vegetative cell growth. The deduced pac1 gene product has 363 amino acids. Its C-terminal 230 residues revealed 25% amino acid identity with ribonuclease III, an enzyme that digests double-stranded RNA and is involved in processing ribosomal RNA precursors and certain mRNAs in Escherichia coli. The pac1 gene product could degrade double-stranded RNA in vitro. These observations establish the presence of a RNase III homolog in eukaryotic cells. The pac1 gene product probably inhibits mating and meiosis by degrading a specific mRNA(s) required for sexual development. It is likely that mRNA processing is involved in the regulation of sexual development in fission yeast.     

A zinc finger protein controls the onset of premeiotic DNA synthesis of fission yeast in a Mei2-independent cascade.

In the fission yeast Schizosaccharomyces pombe, meiosis is initiated by the action of Mei2 in a complex cascade activated following conjugation. We have isolated a new gene named rep1+ that is required for the initiation of premeiotic DNA synthesis. rep1+ encodes a 53 kDa protein with one zinc finger motif that is essential for function, and effectively rescues a null mutant of the res1+ gene but only partially a temperature-sensitive mutant of the cdc10+ gene, both of which are required for the onset of mitotic, as well as premeiotic, S phase. Deletion of rep1+ has no apparent effects on the mitotic cell cycle or conjugation, but blocks the initiation of premeiotic DNA synthesis. However, this defect is partially suppressed when rapidly growing cells are induced to conjugate, indicating that the rep1+ function is at least partly substituted by those of the genes controlling the 'start' of the mitotic cell cycle. The rep1 null mutant fails to induce the res2+ gene, a newly identified res1+ homolog cooperating with Cdc10 and acting for the onset of mitotic and premeiotic DNA synthesis, as well as for meiotic division. The rep1+ gene itself is induced moderately during nitrogen starvation but highly during conjugation, and this induction is dependent on both ste11+ and mating pheromones but independent of mei2+. Thus, rep1+ controls the initiation of premeiotic DNA synthesis via induction and/or activation of Res2 and some other essential factors in a cascade independent of Mei2.     

The Role of Cdc2 and Other Genes in Meiosis in Schizosaccharomyces Pombe

The requirement of the cdc2, cdc13 and cdc25 genes for meiosis in Schizosaccharomyces pombe was investigated using three different conditions to induce meiosis. These genes were known to be required for meiosis II. cdc13 and cdc25 are essential for meiosis I. The cdc2 gene, which is required for the initiation of both mitotic S-phase and M-phase, is essential for premeiotic DNA synthesis and meiosis II. The requirement of cdc2 for meiosis I was unclear. This contrasts with Saccharomyces cerevisiae, where CDC28, the homolog of cdc2, is required for meiosis I but not for premeiotic DNA synthesis. Expression of cdc13 and cdc25 was induced after premeiotic DNA synthesis, reaching a sharp peak before the first nuclear division. Expression of cdc22, encoding the large subunit of ribonucleotide reductase, was also induced but the peak was before premeiotic DNA synthesis. The induction of cdc13 and cdc25 was largely dependent on DNA synthesis and the function of the mei4 gene. The mei4 gene itself was also induced in a DNA synthesis-dependent manner. The chain of gene expression activating cdc25 may be important as part of the mechanism that ensures the dependency of nuclear division on DNA replication during meiosis.     

组蛋白H3K4甲基转移酶复合物亚基Ash2参与裂殖酵母产孢

在氮源缺乏及信息素存在的条件下,裂殖酵母(Schizosaccharomyces pombe)进行减数分裂并完成产孢。在此过程中,信息素介导的MAPK(Mitogen-activated protein kinases)信号通路调控减数分裂相关基因的表达。Spk1是MAPK通路的核心成员,通过蛋白磷酸化的方式激活转录因子Ste11,从而激活mei2⁺、mam2⁺和map3⁺等减数分裂相关基因的表达。尽管组蛋白H3K4甲基化参与基因转录激活、染色质重塑等诸多生物学过程,但其在裂殖酵母产孢过程中的作用并不清楚。文章通过序列比对,发现裂殖酵母Ash2作为H3K4甲基转移酶复合物COMPASS的亚基具有两个保守的结构域,定位于细胞核内参与H3K4的甲基化修饰。ash2⁺的缺失引起裂殖酵母在氮源缺乏时产孢过程的延迟及产孢率下降。ChIP、定量PCR分析结果显示,ash2⁺的缺失降低了spk1⁺编码区H3K4的二甲基化水平,造成spk1⁺mRNA水平的明显下调。在ash2Δ细胞中,虽然ste11⁺的转录水平没有变化,但Ste11的靶基因mei2⁺、mam2⁺和map3⁺的转录水平明显下降。在裂殖酵母中,组蛋白H3K4甲基转移酶复合物COMPASS的亚基Ash2通过调控二甲基化水平修饰从而调节MAPK信号通路,参与裂殖酵母的有性生殖,为建立表观遗传修饰与减数分裂之间的联系提供了新的线索。     

The Arabidopsis-mei2-like genes play a role in meiosis and vegetative growth in Arabidopsis

The Arabidopsis-mei2-Like (AML) genes comprise a five-member gene family related to the mei2 gene, which is a master regulator of meiosis in Schizosaccharomyces pombe and encodes an RNA binding protein. We have analyzed the AML genes to assess their role in plant meiosis and development. All five AML genes were expressed in both vegetative and reproductive tissues. Analysis of AML1-AML5 expression at the cellular level indicated a closely similar expression pattern. In the inflorescence, expression was concentrated in the shoot apical meristem, young buds, and reproductive organ primordia. Within the reproductive organs, strong expression was observed in meiocytes and developing gametes. Functional analysis using RNA interference (RNAi) and combinations of insertion alleles revealed a role for the AML genes in meiosis, with RNAi lines and specific multiple mutant combinations displaying sterility and a range of defects in meiotic chromosome behavior. Defects in seedling growth were also observed at low penetrance. These results indicate that the AML genes play a role in meiosis as well as in vegetative growth and reveal conservation in the genetic mechanisms controlling meiosis in yeast and plants.     

Regulation of p105wee1 and p34cdc2 during meiosis in Schizosaccharomyces pombe.

Temperature-sensitive pat1 mutants of the fission yeast Schizosaccharomyces pombe can be induced to undergo meiosis at the restrictive temperature, irrespective of the mat1 configuration and the nutritional conditions. Using a combination of exit from stationary phase and thermal inactivation of the 52-kilodalton protein kinase that is encoded by the pat1 (also called ran1) gene, highly synchronous meiotic cultures were obtained. Synthesis and tyrosyl phosphorylation of p34cdc2 was evident during meiotic G1 and S phases. During this period there was increased expression of p105wee1, a protein kinase implicated in the tyrosyl phosphorylation of p34cdc2. Following a relatively brief G2 period, during which a reduction in the steady-state level of p105wee1 occurred, there was an approximately 19-fold increase in the histone H1 phosphotransferase activity of p34cdc2. Only a single peak of histone H1 kinase activation was observed, which implies that unlike meiosis in amphibians and echinoderms, p34cdc2 is functional only during one of the meiotic divisions in S. pombe, presumably meiosis II. Stimulation of the kinase activity of p34cdc2 was associated with its tyrosyl dephosphorylation. This is analogous to mitotic M phase and suggests parallels in the mechanism of activation of p34cdc2 during mitosis and one of the meiotic divisions in S. pombe.     

Mutants of Schizosaccharomyces pombe which sporulate in the haploid state

Summary Suppressor mutants of mei1–102, a mutation in one of the mating type cassette genes (mat2-P) which blocks the progression into meiosis, were isolated and characterized in Schizosaccharomyces pombe. These suppressor mutations conferred either temperature-sensitivity or cold-sensitivity. The growth of these strains is halted and sporulation initiated at the restrictive temperatures, regardless of other conditions usually required for the initiation of meiosis i.e. they sporulate in the presence of a nitrogen source and mating type homozygosity. Their most striking feature is that they can sporulate from the haploid state. The haploidy of these mutants was confirmed by genetical analysis and by measurement of the DNA content of the cells. The mutants are all recessive and define a single gene pat1. The pat1 gene maps very close to the centromere of chromosome II. A meiosis defective mutation in mei5 can suppress the temperature-sensitivity caused by pat1, indicating some interaction between them. Spores produced from a haploid cell have poor viability and appear to contain only 1/2C DNA on average.     

Effect of nitrosative stress on Schizosaccharomyces pombe: inactivation of glutathione reductase by peroxynitrite

Oxidative stress has been shown to alter cellular redox status in various cell types. Changes in expressions of several antioxidative and antistress-responsive genes along with activation or inactivation of various proteins were also reported during oxidative insult as well as during nitrosative stress. In the present study, we show the effect of nitrosative stress on cellular redox status of fission yeast Schizosaccharomyces pombe. This is the first report of S-nitrosoglutathione (GSNO) reductase activity in S. pombe and its inactivation by GSNO. We also show the inactivation of glutathione reductase (GR) and glutathione peroxidase in the presence of various reactive nitrogen species in vivo. In addition, we first observe the inactivation of GR by peroxynitrite in vivo using S. pombe cells and also similar observations under in vitro conditions. An immunoreactive band against monoclonal anti-3-nitrotyrosine antibody confirms the modification of GR under in vitro conditions. We also show the effect of nitrosative stress on Deltapap1 cells of S. pombe, which are more sensitive to nitrosative stress, indicating the involvement of Pap1 in the protection against nitrosative stress. Finally, exposure of S. pombe cells to reactive nitrogen species reveals an important role of cellular thiol pool in protection against nitrosative stress.     

PCR-mediated direct gene disruption in Schizosaccharomyces pombe.

We have examined the feasibility and efficiency of PCR-mediated direct gene disruptions in the fission yeast Schizosaccharomyces pombe. In the present study, the S.pombe ura4+ gene was amplified by PCR with oligonucleotides that had short flanking regions ( approximately 40 bp) to the target gene. Using this purified PCR product we were able to disrupt genes in an S. pombe strain bearing aura4 deletion, with an efficiency ranging between 1 and 3% among selected transformants. The results indicated that despite S.pombe's preference for non-homologous or illegitimate recombination, even very short stretches of homologous regions could be used to target genes at a defined frequency in this organism. The successful disruption of four independent genes (sts1+, gcs1+, gsh2+and hmt1+) by this method further demonstrates that, despite the relatively low efficiency, the method is very feasible, and it's simplicity, especially when coupled to phenotype-based screening, should greatly facilitate disruption of genes in S.pombe.     

Meiotically Induced Rec7 and Rec8 Genes of Schizosaccharomyces Pombe

The Schizosaccharomyces pombe rec7 and rec8 genes, which are required for meiotic intragenic recombination but not for mitotic recombination, have been cloned and their DNA sequences determined. Genetic and physical analyses demonstrated that the cloned fragments contained the rec genes rather than rec mutation suppressors. A 1.6-kb DNA fragment contained a functional rec7 gene, and a 2.1-kb fragment contained a functional rec8 gene. The nucleotide sequences of these fragments revealed open reading frames predicting 249 amino acids for the rec7 gene product and 393 amino acids for the rec8 gene product. Northern hybridization analysis showed that both rec gene mRNAs were detectable only at 2-3 hr after induction of meiosis. The absence of these mRNAs in mitosis and their disappearance at 4 hr and later in meiosis suggest that the rec7 and rec8 gene products may be involved primarily in the early steps of meiotic recombination in S. pombe.