Saccharomyces cerevisiae Big1p,a putative endoplasmic reticulum membrane protein required for normal levels of cell wall beta-1,6-glucan

Deletion of Saccharomyces cerevisiae BIG1 causes an approximately 95% reduction in cell wall beta-1,6-glucan, an essential polymer involved in the cell wall attachment of many surface mannoproteins. The big1 deletion mutant grows very slowly, but growth can be enhanced if cells are given osmotic support. We have begun a cell biological and genetic analysis of its product. We demonstrate, using a Big1p-GFP fusion construct, that Big1p is an N-glycosylated integral membrane protein with a Type I topology that is located in the endoplasmic reticulum (ER). Some phenotypes of a big1Delta mutant resemble those of strains disrupted for KRE5, which encodes another ER protein affecting beta-l,6-glucan levels to a similar extent. In a big1Deltakre5Delta double mutant, both the growth and alkali-soluble beta-l,6-glucan levels were reduced as compared to either single mutant. Thus, while Big1p and Kre5p may have similar effects on beta-l,6-glucan synthesis, these effects are at least partially distinct. Residual beta-l,6-glucan levels in the big1Deltakre5Delta double mutant indicate that these gene products are unlikely to be beta-l,6-glucan synthase subunits, but rather may play some ancillary roles in beta-l,6-glucan synthase assembly or function, or in modifying proteins for attachment of beta-l,6-glucan.     

The linkage of (1–3)-β-glucan to chitin during cell wall assembly in Saccharomyces cerevisiae

Pulse-chase experiments with [¹⁴C]glucose demonstrated that in the cell wall of wild-type Saccharomyces cerevisiae alkali-soluble (1–3)-β-glucan serves as a precursor for alkali-insoluble (1–3)-β-glucan. The following observations support the notion that the insolubilization of the glucan is caused by linkage to chitin: (i) degradation of chitin by chitinase completely dissolved the glucan, and (ii) disruption of the gene for chitin synthase 3 prevented the formation of alkali-insoluble glucan. These cells, unable to form a glucan–chitin complex, were highly vulnerable to hypo-osmotic shock indicating that the linkage of the two polymers significantly contributes to the mechanical strength of the cell wall. Conversion of alkali-soluble glucan into alkali-insoluble glucan occurred both early and late during budding and also in the ts-mutant cdc24-1 in the absence of bud formation.     

Glucan structure in a fragile mutant of Saccharomyces cerevisiae

The phenotype of VY1160 fragile Saccharomyces cerevisiae mutant is characterized by cell lysis upon transfer to hypotonic solutions and increased permeability of cells growing in osmotically stabilized media. Two mutations, srb1 and ts1, have been identified in VY1160 cells and previous studies have shown that the increased permeability is due to the ts1 mutation which causes a shortening of mannan side-chains. Here we report that the srb1 mutation, which is the genetic determinant of cell lysis, is responsible for quantitative and structural changes of glucans. Experiments with isogenic single mutation strains, genetic studies coupled with quantitative measurements of glucan content per cell, and methylation analysis of glucans provide evidence that srb1 mutation leads to i) formation of mechanically unstable cell wall network made of insoluble glucan fibrils which are shorter and contain beta(1-6) inter-residue linkages and ii) insufficient filling of the space between the fibrils due to a shortage of the alkali-soluble glucan. Although growing exponentially in osmotically stabilized media, the srb1 cells cannot resist an osmotic shock and, hence, burst immediately.     

Importance of cell wall mannoproteins for septum formation in Saccharomyces cerevisiae

The mannosyltransferase mutants mnn9 and mnn10 were isolated in a genetic screen for septation defects in Saccharomyces cerevisiae. Ultrastructural examination of mutant cell walls revealed markedly thin septal structures and occasional failure to construct trilaminar septa, which then led to the formation of bulky default septa at the bud neck. In the absence of a functional septation apparatus, mnn10 mutants are unable to complete cytokinesis and die as cell chains with incompletely separated cytoplasms, indicating that mannosylation defects impair the ability to form remedial septa. We could not detect N-linked glycosylation of the beta(1,3)glucan synthase Fks1p and mnn10 defects do not change the molecular weight or abundance of the protein. We discuss a model explaining the pleiotropic effects of impaired N-linked protein glycosylation on septation in S. cerevisiae.     

Increased endocytosis in the Saccharomyces cerevisiae fragile mutant VY1160

The VY1160 mutant is characterized by cell lysis in hypotonic solutions and generally increased permeability to substances for which Saccharomyces cerevisiae cells are not permeable. Two mutations, srb1 and ts1, have been identified in VY1160 mutant, and previous studies (Kozhina et al., 1979) have shown srb1 to be responsible for cell lysis. We now present evidence that the ts1 mutation leads to increased endocytosis in VY1160 cells. The internalization of lucifer yellow carbohydrazide in VY1160 cells is time-, temperature- and energy-dependent and consistent with a fluid-phase mechanism of endocytosis. The rate of steady-state accumulation of the dye at 37 degrees C is 145 ng/micrograms DNA per h for VY1160 mutant and 23 ng/micrograms DNA per h for S288C parental strain. Studies with isogenic strains having either the srb1 or the ts1 mutation, or SRB1 TS1 wild-type alleles have shown that only ts1 strains possess increased endocytosis. Quantitation of endocytosis in cells grown at 24 degrees C and shifted at 38 degrees C shows that ts1 strains, but not srb1 and wild-type strains, increase ten-fold the internalization of lucifer yellow 2 h after the shift at 38 degrees C. The analysis of ts1 x wild-type crosses provides evidence that the temperature-sensitive phenotype segregates together with the enhanced endocytosis. It is concluded that the increased endocytosis might explain the generally increased permeability of VY1160 mutant cells.     

不同菌龄酿酒酵母细胞壁蛋白差异性分析

以酿酒酵母为研究对象,比较了完整细胞提取法、稀碱缓冲液提取法及溶菌酶和β-葡聚糖酶复合酶法等三种酵母菌细胞壁蛋白提取方法,分析了不同菌龄酵母细胞壁差异性蛋白。结果表明:溶菌酶和β-葡聚糖酶复合酶液水解纯化好细胞壁提取蛋白的方法具有所得胞壁蛋白条带较多,且纯度较高的优点,确定了此方法为提取酵母细胞壁蛋白的最佳提取方法。同时,通过SDS-PAGE电泳分析发现,不同菌龄酵母细胞壁蛋白存在着较大的差异性,并确定了分子质量在36 ku、17 ku和12 ku为不同酵母代数细胞壁的3个主要差异性蛋白,其中36 ku、17 ku处条带蛋白随着菌龄的增加酵母细胞壁蛋白表达量逐渐减少,而12 ku处条带蛋白随着菌龄的增加酵母细胞壁蛋白表达量逐渐增加。     

CDC15, an essential cell cycle gene in Saccharomyces cerevisiae, encodes a protein kinase domain

The cell division cycle gene CDC15 is essential for the late nuclear division in the yeast Saccharomyces cerevisiae. The amino acid sequence of the 974 amino acids/110 kDa CDC15 gene product, as deduced from the nucleotide sequence, includes an aminoterminal protein kinase domain which contains a primary sequence mosaic showing patterns specific for protein serine/threonine kinases besides those for protein tyrosine kinases. Many protein kinases non-essential for growth are known. CDC15 represents an essential protein kinase like CDC7 and CDC28. A carboxyterminal deletion of 32 amino acids renders the protein inactive.     

Casein kinase II phosphorylates translation initiation factor 5 (eIF5) in Saccharomyces cerevisiae

Eukaryotic translation initiation factor 5 (eIF5) interacts with the 40S initiation complex (40S-eIF3-mRNA-Met-tRNA(f)-eIF2-GTP) to promote the hydrolysis of ribosome-bound GTP. In Saccharomyces cerevisiae, eIF5 is encoded by a single-copy essential gene, TIF5, that is required for cell growth and viability. In this work, we show that eIF5 immunoprecipitated from cell-free extracts of (32)P-labelled yeast cells is phosphorylated on multiple serine residues. Phosphopeptide mapping reveals four major sites of phosphorylation that appear to be identical to recombinant yeast eIF5 sites phosphorylated in vitro by casein kinase II. Furthermore, analysis of eIF5 isolated from a yeast strain having a conditional mutant of casein kinase II indicates that phosphorylation of eIF5 is completely abolished at the non-permissive temperature. Additionally, haploid yeast strains were constructed to contain Ser-to-Ala mutations at the five casein kinase II consensus sequences in eIF5; in these cells, eIF5 phosphorylation was absent. Surprisingly, substitution of the TIF5 gene mutated at these sites for the wild-type gene had no obvious effect on cell growth under normal growth conditions. The implications of these results in eIF5 function are discussed.     

Mutations in Fks1p affect the cell wall content of beta-1,3- and beta-1,6-glucan in Saccharomyces cerevisiae

Fks1p and Fks2p are related proteins thought to be catalytic subunits of the beta-1,3-glucan synthase. Analysis of fks1 delta mutants showed a partial K1 killer toxin-resistant phenotype and a 30% reduction in alkali-soluble beta-1,3-glucan that was accompanied by a modest reduction in beta-1,6-glucan. The gas1 delta mutant lacking a 1,3-beta-glucanosyltransferase displayed a similar reduction in alkali-soluble beta-1,3-glucan but did not share the beta-1,6-glucan defect, indicating that beta-1,6-glucan reduction is not a general phenotype among beta-1,3-glucan biosynthetic mutants. Overexpression of FKS2 suppressed the killer toxin phenotype of fks1 delta mutants, implicating Fks2p in the biosynthesis of the residual beta-1,6-glucan present in fks1 delta cells. In addition, eight out of 12 fks1ts fks2 delta mutants had altered beta-glucan levels at the permissive temperature: the partial killer resistant FKS1F1258Y N1520D allele was severely affected in both polymers and displayed a 55% reduction in beta-1,6-glucan, while the in vitro hyperactive allele FKS1T605I M761T increased both beta-glucan levels. These beta-1,6-glucan phenotypes may be due to altered availability of, and structural changes in, the beta-1,3-glucan polymer, which might serve as a beta-1,6-glucan acceptor at the cell surface. Alternatively, Fks1p and Fks2p could actively participate in the biosynthesis of both polymers as beta-glucan transporters. We analysed Fks1p and Fks2p in beta-1,6-glucan deficient mutants and found that they were mislocalized and that the mutants had reduced in vitro glucan synthase activity, possibly contributing to the observed beta-1,6-glucan defects.     

RCS1, a gene involved in controlling cell size in Saccharomyces cerevisiae

Cloning and sequencing of RCS1, Saccharomyces cerevisiae gene whose product seems to be involved in timing the budding event of the cell cycle, is described. A haploid strain in which the 3'-terminal region of the chromosomal copy of the gene has been disrupted produces cells that are, on average, twice the size of cells of the parental strain. The critical size for budding in the mutant is similarly increased, and the disruption mutation is dominant in a diploid heterozygous for the RCS1 gene. Spores from this diploid have a reduced ability to germinate, the effect being more pronounced in the spores carrying the disrupted copy of RCS1. However, disrupted cells recover from alpha-factor treatment equally as well as wild-type cells.     

青蛤凝集素CSL对酿酒酵母细胞形态的影响

通过研究青蛤凝集素CSL与酵母细胞壁肽聚糖的相互作用及CSL与酿酒酵母细胞结合后其表面积的变化,分析CSL对酿酒酵母细胞作用的影响。结果表明,固相吸附测试中,CSL可与酵母细胞壁肽聚糖结合,两者的结合具有浓度依赖关系,该结合位点受甘露糖（D-Mannose）及N-乙酰-D-半乳糖胺（N-acetyl-D-galactosamine）的抑制。CSL与酿酒酵母细胞壁相互作用,导致了它的表面积发生了改变,这表明其细胞壁发生了变化。对照组与CSL添加组两组酵母菌内的Ca²⁺含量未发生明显变化。扫描电镜观察表明,对照组酵母细胞表面较圆润光滑,CSL添加组酵母细胞表面有较多赘附凸起。研究结果为CSL促进酵母发酵能力的机理提供基础数据。      

Absence of cell wall chitin in Saccharomyces cerevisiae leads to resistance to Kluyveromyces lactis killer toxin

Kluyveromyces lactis killer toxin causes sensitive strains of a variety of yeasts to arrest at the G1 stage of the cell cycle, and to lose viability. We describe here the isolation and characterization of a class of recessive mutations in Saccharomyces cerevisiae that leads to toxin resistance and a temperature-sensitive phenotype. These mutant cells arrest growth at 37°C with a characteristic phenotype of elongated buds. Cloning of the gene complementing these defects revealed it to be CAL1, coding for chitin synthase 3 activity. Calcofluor staining of the mutant cells indicated that chitin is absent both at 23°C and 37°C. Given that the CAL1 activity is responsible for the synthesis of most of chitin in yeast cells, and that in its absence the cells are viable but resistant to the killer toxin, our results strongly suggest that chitin might represent the receptor for this killer toxin.     

Genetic and molecular analysis of DNA43 and DNA52: two new cell-cycle genes in Saccharomyces cerevisiae.

Two Saccharomyces cerevisiae genes previously unknown to be required for DNA synthesis have been identified by screening a collection of temperature-sensitive mutants. The effects of mutations in DNA43 and DNA52 on the rate of S phase DNA synthesis were detected by monitoring DNA synthesis in synchronous populations that were obtained by isopycnic density centrifugation. dna43-1 and dna52-1 cells undergo cell-cycle arrest at the restrictive temperature (37 degrees C), exhibiting a large-budded terminal phenotype; the nuclei of arrested cells are located at the neck of the bud and have failed to undergo DNA replication. These phenotypes suggest that DNA43 and DNA52 are required for entry into or completion of S phase. DNA43 and DNA52 were cloned by their abilities to suppress the temperature-sensitive lethal phenotypes of dna43-1 and dna52-1 cells, respectively. DNA sequence analysis suggested that DNA43 and DNA52 encode proteins of 59.6 and 80.6 kDa, respectively. Both DNA43 and DNA52 are essential for viability and genetic mapping experiments indicate that they represent previously unidentified genes: DNA43 is located on chromosome IX, 32 cM distal from his5 and DNA52 is located on chromosome IV, 0.9 cM from cdc34.     

Expression of recombinant platelet-derived endothelial cell growth factor in the yeast Saccharomyces cerevisiae.

A platelet-derived endothelial cell growth factor cDNA has been cloned, sequenced and expressed using the Saccharomyces cerevisiae PRB1 promoter. Soluble recombinant platelet-derived endothelial cell growth factor constituted 0.5-1.0% of total soluble protein. Yeast soluble protein extracts containing recombinant platelet-derived endothelial cell growth factor stimulate the growth of calf pulmonary artery endothelial cells in vitro.     

Cooperative functions of the mannoprotein-encoding genes in the biogenesis and maintenance of the cell wall in Saccharomyces cerevisiae.

To elucidate the roles of genes involved in the cell wall biogenesis and function in Saccharomyces cerevisiae, we isolated and characterized mutants that were lethal in a strain in which the SED1 gene encoding a cell wall mannoprotein was disrupted. Thus, double mutants of SED1 and either MNN9 or MNN10 were unable to grow and YOL155c on a multicopy plasmid could suppress their synthetic lethality. A Yol155cp-GFP fusion protein was found to localize to the cell wall, suggesting that it might also be a cell wall mannoprotein. Subsequently, we analysed the effects of the shut-off of SED1 in a sed1 and mnn9 double mutant: cells after the shut-off showed anomalous cellular morphology and died in the mitotic M phase. From these and other results, we postulate that these genes function cooperatively with each other and in a cell cycle-dependent manner in the biogenesis and maintenance of cell wall in S. cerevisiae.     

Functional analysis reports. Precise gene disruption in Saccharomyces cerevisiae by double fusion polymerase chain reaction

We adapted a fusion polymerase chain reaction (PCR) strategy to synthesize gene disruption alleles of any sequenced yeast gene of interest. The first step of the construction is to amplify sequences flanking the reading frame we want to disrupt and to amplify the selectable marker sequence. Then we fuse the upstream fragment to the marker sequence by fusion PCR, isolate this product and fuse it to the downstream sequence in a second fusion PCR reaction. The final PCR product can then be transformed directly into yeast. This method is rapid, relatively inexpensive, offers the freedom to choose from among a variety of selectable markers and allows one to construct precise disruptions of any sequenced open reading frame in Saccharomyces cerevisiae.     

Genomic reorganization between two sibling yeast species,Saccharomyces bayanus and Saccharomyces cerevisiae

Genomic comparison of two sibling yeast species, Saccharomyces bayanus and Saccharomyces cerevisiae, was performed by Southern blot analysis with various S. cerevisiae gene probes following electrophoretic karyotyping. Fifteen genes on chromosome IV of S. cerevisiae were examined and classified into two groups. Gene probes of CEN4 and TRP1, as well as six other genes located on the left arm of the chromosome hybridized to a 1100-kb chromosome of S. bayanus that is smaller than chromosome IV of S. cerevisiae. On the other hand, probes of seven genes located on the right arm of chromosome IV hybridized to a 1350-kb chromosome that is homeologous to chromosome IV, judging from its size. Two genes located on the left arm of chromosome II hybridized to the 1350-kb chromosome, while four genes on the right arm hybridized to the 1100-kb chromosome. These pieces of evidence indicate that chromosomes II and IV of S. cerevisiae are rearranged into 1350-kb and 1100-kb chromosomes in S. bayanus. Furthermore, it is suggested that chromosome XV is rearranged into two chromosomes (800 and 850 kb in size) in S. bayanus. The translocation points of chromosomes II and IV were delimited using S. cerevisiae prime clone membranes. The results indicated that the translocation points are located close to the FUR4 locus on chromosome II and close to the RAD57 locus on chromosome IV.