Meu10 is required for spore wall maturation in Schizosaccharomyces pombe

BACKGROUND: Many genes are meiosis and/or sporulation-specifically transcribed during this process. Isolation and analysis of these genes might help us to understand how meiosis and sporulation are regulated. For this purpose, we have isolated a large number of cDNA clones from Schizosaccharomyces pombe whose expression is up-regulated during meiosis. RESULTS: We have isolated meu10+ gene, which encodes 416 amino acids and bears homology to SPS2 of Saccharomyces cerevisiae. A strain whose meu10+ gene has been deleted forms no viable spores. Thin-section electron micrographs showed that the meu10Delta strain has abnormally formed spore walls, and then they disrupt, allowing cytoplasmic material to escape. The Meu10-GFP fusion protein is localized to the spore periphery, thereafter returned to the cytoplasm after sporulation. Meu10-GFP localization to the spore wall was almost normal in the bgs2Delta or chs1Delta mutants that lack 1,3-beta-glucan or chitin, respectively. In contrast, 1,3-beta-glucan is abnormally localized in meu10Delta cells. Meu10 has an N-terminal domain with homology to the mammalian insulin receptor and a C-terminal domain with a transmembrane motif. Mutants whose N-terminal or C-terminal domain was truncated were severely defective for sporulation. CONCLUSIONS: Meu10 is a spore wall component and plays a pivotal role in the formation of the mature spore wall structure.     

Exogenous inositol and genes responsible for inositol transport are required for mating and sporulation in Schizosaccharomyces pombe

Fission yeast, Schizosaccharomyces pombe, is a natural inositol auxotroph. We show here that the amount of exogenous inositol added to the medium is critical for the control of its life cycle. Above growth-limiting concentrations inositol stimulates mating and sporulation in minimal medium. The effect of inositol is also observed on yeast-extract-medium plates. We selected a mutant, IM49, which mates and sporulates only poorly and show that it is defective in inositol transport. Its defect is in a gene (itr2) coding for a putative 12 membrane-spanning protein. The polypeptide contains the two sugar-transport motifs typical for hexose transporters and shows good homology to the two Saccharomyces cerevisiae inositol transporters. The itr2 gene is essential for cell growth and its mRNA level is repressed by glucose. Mutant IM49 is also complemented by a multicopy suppressor gene (itr1) which codes for a putative hexose transporter with unknown substrate specifity. Received: 10 September 1997 / 9 February 1998     

Switching genes in Schizosaccharomyces pombe

Summary In homothallic (h ⁹⁰) Schizosaccharomyces pombe strains mutants occur which exhibit reduced frequencies of mating-type switching. The colonies of such mutants show a mottled iodine reaction. The underlying mutations map either in a switching signal at matl or in switching (swi) genes which are not linked to the mating-type region. Forty-nine swi mutants were examined. They map in ten different swi genes, swi1 to swi10. Seven swi genes were assigned to chromosomes I and II, respectively. Two classes of swi genes can be distinguished: when plated, class I mutants yield only mottled colonies, whereas class Il mutants yield mottled and iodine-negative colonies (most of the latter are h ¹).     

Schizosaccharomyces pombe taf1 + is required for nitrogen starvation-induced sexual development and for entering the dormant G0 state

Environmental change, such as nutritional starvation, induces physiological and morphological alterations that enable fission yeast cells to survive. We isolated a novel gene, taf1 ⁺ , required for the response to nitrogen starvation in the fission yeast Schizosaccharomyces pombe. taf1 disruptants could not mate upon nitrogen starvation, but could upon carbon starvation. taf1 disruptants had a defect in inducing ste11 ⁺ expression under nitrogen starvation conditions. Furthermore, they lost viability quickly in nitrogen-depleted medium. Unlike wild-type cells, starved taf1 ⁻ cells had nuclear chromatin that were flat and adhered to the cell periphery. These results indicate that taf1 ⁺ is required for nitrogen starvation-induced sexual development and entering the dormant G0 state. Received: 30 May 2000 / Accepted: 21 August 2000     

Two genes control three alkaline phosphatases in Schizosaccharomyces pombe

Summary Mutants of Schizosaccharomyces pombe defective in alkaline phosphatase activity have been selected and analyzed. The mutations map in two different loci, pho2 and pho3, both located on the right arm of chromosome II. Pho2-mutants lack the activity of a soluble alkaline phosphatase specific for nitrophenyl-phosphate. Its activity requires Mg ions and it is abolished with Zn ions. The pho3-mutations block the activities of a soluble and of a membrane-bound nonspecific alkaline phosphatase. Both pho3-controlled enzyme forms exhibit similar substrate specificities, pH-optima and Mg ions are essential for both activities. Zn ions can partially replace the Mg ions. The three enzyme forms migrate differently on nondenaturing polyacrylamide gels. We speculate that pho2 and pho3 represent the structural genes for a substrate-specific and two forms of a nonspecific alkaline phosphatase.     

Inhibitory effect of 2-deoxy-glucose on cell wall synthesis in cells and protoplasts of Schizosaccharomyces pombe

A study has been made of changes in cell walls and ultrastructure of cells and regenerating protoplasts of Schizosaccharomyces pombe grown in different concentrations of 2-deoxyglucose (2DG). At concentrations of 0.1% and higher the inhibitor reversibly blocked growth of cells and protoplasts and completely inhibited cell wall synthesis. Concentrations of 0.05% and lower allowed protoplasts to grow and induced early or late lysis in normal cells. On the surface of protoplasts only the fibrillar component was formed; secretion of the soluble fraction ceased. The early lysis of the cells was a result of degradation of cell wall material at growing sites (concentration of 2DG 0.02–0.05%), the late lysis occurred in cells with weakened growing regions, where aberrant material was deposited (concentrations 0.01–0.02%). Concentrations of 2DG below 0.01% did not affect the growth of the cells or the reversion of protoplasts to normal cells. 2DG was not incorporated into the walls of cells or regenerating protoplasts, and did not influence the ultrastructure of cells or protoplasts except for the effects on the cell wall.     

Meiosis-dependent mRNA splicing of the fission yeast Schizosaccharomyces pombe mes1 + gene

The mes1 ⁺ gene of the fission yeast Schizosaccharomyces pombe is essential for the second meiotic division. We have cloned a 1.1-kb HindIII fragment containing mes1 ⁺ by complementation from an S. pombe genomic library. Sequencing of the genomic and cDNA fragments indicates the existence of one small intron of 75 nucleotides, although both the 5 (G/GTTAGT) and 3 (CAG/T) intron-exon junctions deviate from the consensus sequences proposed for S. pombe. The putative translation product of the mature mes1 ⁺ mRNA is a 11-kDa protein of 101 amino acids which has no significant homology to any previously-reported proteins. Disruption of mes1 has no effect on cell growth but causes an arrest of meiosis before the second meiotic division. Northern-blot analysis revealed that mes1 ⁺ was preferentially transcribed under conditions of nitrogen starvation. When a h ⁹⁰ homothallic strain was shifted to a nitrogen-deficient medium, a pre-mRNA accumulated and then was gradually processed to generate a mature mRNA. This splicing did not occur in either a heterothallic haploid strain or in a homothallic mei2 mutant strain which was defective in the initiation of meiosis. Expression of the first exon alone was not able to suppress the mes1 null allele. These results indicate that mes1 ⁺ is required for the completion of meiosis, that splicing is required for the function of the mes1 ⁺ gene, and that this splicing requires the function of the mei2 ⁺ product.     

Two novel genes involved in the sexual development of Schizosaccharomyces pombe

We isolated two sterile mutants of Schizosaccharomyces pombe. One of them was mapped close to ste13 (8 cM). Since it turned out to be allelic with the hitherto unmapped ral2, its linkage with ste13 localizes ral2 on the right arm of chromosome II. The other mutant defines a novel class-I ste gene, ste15, closely linked to ste7 (4 cM) on chromosome I. ste15 is conjugation-specific and acts upstream of pat1 and ras1. During its genetic analysis, a phenotypic suppression of ste12-N9 was observed which was caused by mutations in the unlinked gene ssw1.     

Homologous recombination in the fission yeast Schizosaccharomyces pombe: different requirements for the rhp51+, rhp54+ and rad22+ genes

The Schizosaccharomyces pombe rhp51 ⁺ , rad22 ⁺ and rhp54 ⁺ genes are homologous to RAD51, RAD52 and RAD54 respectively, which are indispensable in the recombinational repair of double-strand breaks (DSBs) in Saccharomyces cerevisiae. The rhp51Δ and rhp54Δ strains are extremely sensitive to ionizing radiation; the rad22Δ mutant turned out to be much less sensitive. Homologous recombination in these mutants was studied by targeted integration at the leu1-32 locus. These experiments revealed that rhp51Δ and rhp54Δ are equally impaired in the integration of plasmid molecules (15-fold reduction), while integration in the rad22Δ mutant is only reduced by a factor of two. Blot-analysis demonstrated that the majority of the leu⁺ transformants of the wild-type and rad22Δ strains have integrated one or more copies of the vector. Gene conversion events were observed in less than 10% of the transformants. Interestingly, the relative contribution of gene conversion events is much higher in a rhp51Δ and a rhp54Δ background. Meiotic recombination is hardly affected in the rad22Δ mutant. The rhp51Δ and rhp54Δ strains also show minor deficiencies in this type of recombination. The viability of spores is 46% in the rad22Δ strain and 27% in the rhp54Δ strain, as compared with wild-type cells. However, in the rhp51Δ mutant the spore viability is only 1.7%, suggesting an essential role for Rhp51 in meiosis. The function of Rhp51 and Rhp54 in damage repair and recombination resembles the role of Rad51 and Rad54 in S. cerevisiae. Compared with Rad52 from S. cerevisiae, Rad22 has a much less prominent role in the recombinational repair pathway in S. pombe. Received: 20 July 1996     

Prospects for functional genomics in Schizosaccharomyces pombe

Schizosaccharomyces pombe is well established as an experimental organism for basic research, with well developed technologies for molecular biology, genetics and cell biology. Its full genome sequence has recently been published. Here, the prerequisites for functional genomics studies in Sch. pombe are examined and compared with those of some established prominent functional genomics model organisms, especially Saccharomyces cerevisiae. It is argued that functional genomics studies in certain areas of cellular and molecular biology could potentially be more efficiently performed in Sch. pombe than in most other experimental organisms.     

Cloning the Schizosaccharomyces pombe lys2 + gene and construction of new molecular genetic tools

Molecular genetic analyses in Schizosaccharomyces pombe rely on selectable markers that are used in cloning vectors or to mark targeted gene deletions and other integrated constructs. In this study, we used genetic mapping data and genomic sequence information to predict the identity of the S. pombe lys2 ⁺ gene, which is homologous to Saccharomyces cerevisiae LYS4 ⁺. We confirmed this prediction, showing that the cloned SPAC343.16 gene can complement a lys2-97 mutant allele, and constructed the lys2 ⁺-based cloning vector pRH3. In addition, we deleted the S. pombe his7 ⁺ gene with a lys2 ⁺-marked polymerase chain reaction (PCR) product and the S. pombe lys2 ⁺ gene with a his7 ⁺-marked PCR product. Strains carrying these deletions of lys2 ⁺ or his7 ⁺ serve as relatively efficient hosts for the deletion of the ade6 ⁺ gene by lys2 ⁺- or his7 ⁺-marked PCR products when compared with hosts carrying lys2 or his7 point mutations. Therefore, these studies provide plasmids and strains allowing the use of lys2 ⁺ as a selectable marker, along with improved strains for the use of his7 ⁺ to mark gene deletions.     

Ksg1, a homologue of the phosphoinositide-dependent protein kinase 1, controls cell wall integrity in Schizosaccharomyces pombe

It has previously been shown that the Schizosaccharomyces pombe mutant ksg1-358 has a mating and sporulation defect at 30 degrees C and that it is temperature sensitive for growth at 35 degrees C. However the molecular basis for these phenotypes remained largely unknown. In this study we show that ksg1-358 mutant cells lysed at the non-permissive temperature, which could be prevented by sorbitol. Overexpression of ksg1 using the nmt1-promoter showed slow growth and cells became swollen when incubated at 35 degrees C under low inositol conditions. Interestingly, in a two-hybrid assay we found that the ksg1-protein interacted with Pck1p, a protein implicated in regulating cell wall integrity in S. pombe. Genetic complementation assays showed that an overexpression of pck2, the homologue of pck1 involved in the regulation of cell wall synthesis, could partially rescue ksg1-358 phenotypes. We digested the ksg1-358 cell wall using beta-glucanase. We found that the ksg1-358 mutant was more resistant to cell lysis at 30 degrees C than the wildtype strain h972, which was similar to a pck1-deletion strain. A ksg1-overexpressing strain was hypersensitive towards beta-glucanase treatment similar to a pck2-deletion strain. The pck1-deletion partially rescued beta-glucanase hypersensitivity of the ksg1-overexpressing strain but the pck2-deletion increased it. The ksg1-358 mutation increased beta-glucanase resistance of a pck1-overexpressing strain but it had no effect on a pck2-overexpressing strain. Our results provide evidence that ksg1 is a novel regulator of cell wall integrity in the fission yeast Schizosaccharomyces pombe. They further suggest that Ksg1p acts in a pathway with Pck1p, possibly upstream and through direct interaction.     

Switching genes in Schizosaccharomyces pombe: their influence on cell viability and recombination

Summary In Schizosaccharomyces pombe, mutations in 10 swi genes are known which reduce but not abolish mating-type (MT) switching in homothallic (h ⁹⁰) strains. Three classes (Ia, Ib, and II) of swi genes are distinguished. Three swi1 alleles are nonsense mutations. In strains with mutations in two or three swi genes, a cumulative reduction of MT switching only occurs if the genes belong to different classes. The class 1a combinations swi1 swi7 and swi3 swi7 are lethal. Besides its influence on MT switching, swi5 also reduces the frequencies of meiotic intragenic recombination and gene conversion in the ade6 locus.We dedicate this paper to Professor Kaudewitz on the occasion of his retirement     

Mapping of rRNA genes by integration of hybrid plasmids in Schizosaccharomyces pombe

Summary The major rRNA genes of the fission yeast Schizosaccharomyces pombe were mapped on chromosome III by plasmid integration. The integration vector YIp33 containing S. cerevisiae LEU2 gene was combined with the S. pombe rDNA. Since LEU2 complements S. pombe leu1 deficiency, it could be used as the genetic marker for integration. The 10.4 kb rDNA repeat contained ARS sequence, and therefore 2.4 kb and 0.7 kb subfragments not containing ARS were subcloned into YIp33 and transformed leu1 S. pombe cells to Leu⁺. Genetic analyses of the transformants indicated that the integrated rDNA resides in the long arm of the shortest chromosome III, tightly linked to ade5 (1.4 cM). This result is consistent with our previous finding that the DAPI-stained smallest chromosomes were associated with the nucleolus (Umesono et al. 1983).Abbreviations ARS autonomously replicating sequence - DAPI 4,6-diamidino-2-phenylindole - kb kilo base pairs - rDNA DNA segment containing ribosomal RNA genes - rRNA ribosomal RNA     

Acid phosphatase deficient mutants of Schizosaccharomyces pombe are defective in tyrosine uptake

Summary The uptake of tyrosine and arginine into wild type and acid phosphatase deficient mutants (pho 1) of Schizosaccharomyces pombe was investigated. All 11 pho 1-alleles tested exhibited a reduced tyrosine uptake and impaired uptake cosegregated with the lack of acid phosphatase activity. Kinetic analyses using wild type cells grown in high phosphate medium (acid phosphatase repressed) and low phosphate medium (acid phosphatase derepressed) showed staturation kinetics for tyrosine with a K_M of about 2 × 10^–4 M for both media and a V of about 5 nmol min^–1mg^–1 and 2 nmol min^–1mg^–1 for derepressed and repressed cells respectively. The pho 1–118 strain completely lacked this saturable uptake system for tyrosine. Preliminary evidence suggests that tyrosine uptake may be via a general amino acid permease system and we conclude that mutations in the structural gene of acid phosphatase which abolish enzyme activity lead to a loss of this uptake system. In contrast to tyrosine, arginine uptake seems not to be significantly affected either by different acid phosphatase levels in wild type cells or by the pho 1–118 mutation.     

Two new multi-purpose multicopy Schizosaccharomyces pombe shuttle vectors,pSP1 and pSP2

Plasmids pSP1 and pSP2 are two new Schizosaccharomyces pombe ars1 multicopy vectors with the Saccharomyces cerevisiae LEU2 and URA3 genes as selectable markers. They are derivatives of S. cerevisiae integrative plasmids. These plasmids allow classical molecular genetic techniques, such as mutagenesis, nested deletions and sequencing, to be performed directly.     

Mapping of four ras superfamily genes by physical and genetic means in Schizosaccharomyces pombe

Summary Four ras superfamily genes, namely ypt1, ypt2, ypt3 and ryh1, have been located on the S. pombe linkage map. This was achieved by constructing strains carrying a new NotI cutting site and the S. cerevisiae LEU2 gene integrated next to the respective gene. The physical location of these genes of the chromosomes was then determined by NotI restriction analysis of the DNA prepared from each strain. Fine genetic mapping was carried out by conventional tetrad analysis using the integrated LEU2 gene as a marker. The results indicated that ypt1 is tightly linked to top1 on the right arm of chromosome II; that ypt2 is 2.5 cM apart from ura2 on the right arm of chromosome I; that ypt3 is tightly linked to arg3 on the left arm of chromosome I; and that rhy1 is located approximately 20 cM from ade3 on the left arm of chromosome I.     

Genetical evidence of carbamoylphosphate compartmentation in Schizosaccharomyces pombe and Schizosaccharomyces japonicus

Summary Mutants defective in carbamoylphosphate synthetase have been isolated in the fission yeasts Schizosaccharomyces pombe and Schizosaccharomyces japonicus. Their growth properties indicate a compartmentation of the carbamoylphosphate pools between arginine and pyrimidine biosyntheses, as in Neurospora crassa but unlike Saccharomyces cerevisiae. Ornithine carbamoyltransferase-minus mutants, arg3 ^– , were also isolated in both Schizosaccharomyces species. In Schiz. pombe, a very close linkage was observed between arg3 and arg11, a gene putatively coding for acetylglutamylphosphate reductase. Arg4 and arg5, the two genes encoding the carbamoylphosphate synthetase of the arginine pathway, are also closely linked but not adjacent.