Uth1p: a yeast mitochondrial protein at the crossroads of stress, degradation and cell death

UTH1 is a yeast aging gene that has been identified on the basis of stress resistance and longer life span of mutants. It was also shown to participate in mitochondrial biogenesis. The absence of Uth1p was found to trigger resistance to autophagy induced by rapamycin. Uth1p is therefore the first mitochondrial protein proven to be required for the autophagic degradation of mitochondria. Since this protein is also involved in yeast cell death induced by heterologous expression of the pro-apoptotic protein Bax, the results are discussed in the light of evidence suggesting a co-regulation of apoptosis and autophagy in mammalian cells.     

Incorporation of Sed1p into the cell wall of Saccharomyces cerevisiae involves KRE6

KRE6 (YPR159W) encodes a Golgi membrane protein required for normal beta-1,6-glucan levels in the cell wall. A functional Kre6p is necessary for cell wall protein accumulation in response to changing metabolic conditions. The product of the SED1 (YDR077W) gene is a stress-induced GPI-cell wall protein. Successful incorporation of HA-tagged Sed1p into the cell wall involves KRE6. The double-mutant sed1 kre6 has a reduced growth rate, increased flocculation and increased sensitivity to Zymolyase. A similar phenotype is found in mutants defective in glycosyl-phosphatidyl-insositol (GPI) anchor assembly. These findings support the theory that Kre6p could function as a transglucosylase that allows the incorporation of proteins with a GPI anchor into the cell wall.     

A murine monoclonal antibody directed against a yeast cell wall glycoprotein antigen of the yeast genus Saccharomyces

Abstract Murine monoclonal antibodies (mAbs) were selected against a cell wall glycoprotein of Saccharomyces cerevisiae . One of the mAbs (92-276/018) specifically identified S. cerevisiae and the sibling species S. paradoxus, S. pastorianus and S. bayanus in immunofluorescence studies and immunoblot analyses, while no other yeast genera except Saccharomyces were recognized. Further analysis indicated that the mAb 92-276/018 reacts with an epitope in the carbohydrate chain of the cell wall glycoproteins.     

酿酒酵母氧化胁迫应答反应机制

氧化胁迫是生物体面对逆境时的重要反应。在与逆境和活性氧做斗争的过程中,细胞进化出一套完整的应答调控机制,通过调节体内活性氧的代谢平衡,来保护DNA、脂质和蛋白质等免受氧化攻击。本文以酿酒酵母为例,根据近年来国内外研究的进展,围绕其在氧化胁迫应答过程中的三道保护屏障,即抗氧化物质和防御酶系统、转录调节和氧化物降解以及细胞器自噬,综述了其抗氧化代谢机理,为深入认识细胞的抗氧化应答机制奠定基础。     

The plasma membrane proteome of Saccharomyces cerevisiae and its response to the antifungal calcofluor

Calcofluor is an antifungal compound known to induce structural perturbations of the cell wall by interfering with the synthesis of chitin microfibril. Proteins from a stripped plasma membrane fraction were solubilized with the neutral and non-denaturing detergent, the n-dodecyl beta-D-maltoside. Proteins were then resolved using a recently described ion-exchange chromatography (IEC)/lithium dodecyl sulfate (LDS)-PAGE procedure. Nearly 90 proteins were identified and clustered, based on their pI, molecular weight, abundance and/or hydrophobicity. This method was then applied to profile the plasma membrane response to calcofluor. The LDS-PAGE patterns obtained from whole plasma membrane proteins were similar for the non-treated and calcofluor-treated samples. However, IEC/LDS-PAGE analysis revealed subtle changes in the expression of several proteins of low abundance, in response to calcofluor. These proteins include Pil1p and Lsp1p, two sphingolipid long-chain base-responsive inhibitors of protein kinases involved in signaling pathways for cell wall integrity and Rho1p, a small GTPase. It was recently hypothesized that Pil1p and Lsp1p could associate with, and regulate, the plasma membrane beta-1-3-glucan synthase, responsible for the synthesis of another major microfibril for yeast cell wall. Results are discussed with respect to both calcofluor effects on the plasma membrane proteins and the power of the IEC/LDS-PAGE procedure in the search for new potential therapeutics targets.     

All-or-none K+ efflux from yeast cells induced by calmodulin antagonists

Abstract Three calmodulin antagonists, trifluoperazin, compound 48/ 80 and calmidazolium provoke K⁺ efflux from metabolizing yeast cells. This K⁺ efflux is accompanied by a shrinkage of the cells. Part of the cells show a gradual shrinkage whilst the remainder of the cells shrink via an all-or-none process. Cells shrunken via an all-or-none process have the same size as cells which have been completely permeabilized by a cationic detergent with loss of all their K⁺.     

The immunosuppressant leflunomide blocks the yeast Saccharomyces cerevisiae cell cycle at the G1 phase

Abstract Leflunomide is a novel immunomodulatory drug representing a new small molecule class of substances which are structurally unrelated to previously described immunomodulatory/immunosuppressive compounds. The effect of leflunomide on the cell cycle of Saccharomyces cerevisiae was investigated to elucidate the molecular mechanism of its action in eukaryotic organisms. When yeast cells were treated with leflunomide, unbudded cells were accumulated, suggesting that leflunomide may arrest the cell cycle in the G☎ase. When leflunomide-treated cells were subjected to heat shock treatment, the cells became resistant to heat shock treatment, implying that leflunomide-mediated block to cell division results in entry from the proliferative cycle into the alternative developmental g₀ phase.     

Starvation and temperature upshift cause an increase in the enzymatically active cell wall-associated glyceraldehyde-3-phosphate dehydrogenase protein in yeast

The cell wall-associated glyceraldehyde-3-phosphate dehydrogenase (cwGAPDH) activity in Saccharomyces cerevisiae increases (two- to 10-fold, depending on the strain) in response to starvation and temperature upshift. Assays using transformants carrying pTDH, a yeast centromer derivative plasmid containing the Candida albicans TDH3 gene (encoding GAPDH) fused in frame with the yeast SUC2-coding region for internal invertase, showed that starvation and/or temperature upshift result in a similar increase in both cwGAPDH and cell wall-associated invertase activities. In addition, this incorporation of GAPDH protein into the cell wall in response to stress does not require (i) de novo protein synthesis, indicating that preexisting cytosolic enzyme is incorporated into the cell wall, (ii) nor the participation of the ubiquitin yeast stress response system, as no differences were observed between wild-type and polyubiquitin-depleted (Deltaubi4) strains.     

Construction of Saccharomyces cerevisiae strains that accumulate relatively low concentrations of trehalose, and their application in testing the contribution of the disaccharide to stress tolerance

Genetically related diploid strains of Saccharomyces cerevisiae that accumulate varied amounts of trehalose during starvation for nitrogen have been constructed. Strains that produced greater than 5% trehalose (dry cell weight) were more tolerant of thermal, or freeze-thaw stresses than strains that produced less than 4% trehalose. Thus trehalose appears to play a role in stress tolerance of yeast. The significance of these results is that, for the first time, a series of related, unmutated strains have been used to test the effect of trehalose on thermotolerance. Previous studies employed either heat shock treatment, or mutated strains to provide trehalose variations, and as such the contribution of the disaccharide to stress tolerance could not necessarily be separated from other factors such as heat shock proteins.     

A proteome analysis of the yeast response to the herbicide 2,4-dichlorophenoxyacetic acid

The intensive use of herbicides may give rise to a number of toxicological problems in non-target organisms and has led to the emergence of resistant weeds. To gain insights into the mechanisms of adaptation to the herbicide 2,4-dichlorophenoxyacetic acid (2,4-D), we have identified variations in protein expression level in the eukaryotic experimental model Saccharomyces cerevisiae exposed to herbicide aggression, based on two-dimensional gel electrophoresis. We show results suggesting that during the adaptation period preceding the resumption of inhibited exponential growth under herbicide stress, the antioxidant enzyme Ahp1p and the heat shock proteins Hsp12p and Ssb2p (or Ssb1p) are present in higher amounts. The increased level of other enzymes involved in protein (Cdc48p) and mRNA (Dcp1p) degradation, in carbohydrate metabolism (Eno1p, Eno2p and Glk1p) and in vacuolar H(+)-ATPase (V-ATPase) function (Vma1p and Vma2p, two subunits of the peripheral catalytic sector) was also registered. V-ATPase is involved in the homeostasis of intracellular pH and in the compartmentalization of amino acids and other metabolites in the vacuole. The increased expression of amino acid biosynthetic enzymes (Arg1p, Aro3p, Aro8p, Gdh1p, His4p, Ilv3p and Met6p), also suggested by comparative analysis of the proteome, was correlated with the reduction of amino acid concentration registered in both the vacuole and the cytosol of 2,4-D-stressed cells, possibly due to the disturbance of vacuolar and plasma membrane functions by the lipophilic acid herbicide.     

酵母PMT1基因参与内质网应激的调控机制

【目的】内质网应激(Endoplasmic reticulum stress,ERS)可激活细胞保护性信号级联反应——未折叠蛋白质反应(Unfolded protein response,UPR)。研究表明,酵母细胞中的UPR信号通路由转录因子Hac1p和ERS感应因子Ire1p共同介导。前期研究发现:蛋白质-O-甘露糖转移酶1(Protein-O-mannosyltransferase 1,PMT1)基因缺失能延长酵母细胞的复制性寿命,其机制与上调UPR通路活性相关。本文进一步探讨PMT1基因缺失在酵母ERS反应中的作用。【方法】观察PMT1基因与IRE1或HAC1基因双缺失酵母菌株(pmt1?hac1?和pmt1?ire1?)在ERS反应条件下的克隆形成能力;通过比色法检测各菌株的细胞增殖活性;RT-PCR检测各菌株UPR通路下游部分靶基因的转录水平。【结果】与对照菌株比较,PMT1基因缺失菌株(pmt1?)在ERS反应条件下生长较慢,而HAC1和IRE1单基因缺失菌株(hac1?和ire1?)在ERS反应条件下无法存活;在hac1?或ire1?菌株的基础上进一步缺失PMT1基因,可以改善hac1?菌株在ERS反应条件下的生长状态;但缺失PMT1基因没有上调hac1?菌株UPR通路靶基因的转录水平。【结论】缺失PMT1基因可增强hac1?菌株对ERS诱导剂衣霉素的抗性,机制与已知的UPR通路不相关,提示可能存在其它途径参与ERS反应的调控。     

Genetic transformation of yeast protoplasts with DNA encapsulated in liposomes

Abstract Protoplasts of auxotrophic strains of Saccharomyces cerevisiae could be transformed to prototrophy with plasmid DNA encapsulated in liposomes. With negatively charged liposomes, the transformation efficiency was higher than with naked DNA.     

Proteomic and phosphoproteomic analyses of yeast reveal the global cellular response to sphingolipid depletion

Sphingolipids are essential components of eukaryotic cells with important functions in membrane biology and cellular signaling. Their levels are tightly controlled and coordinated with the abundance of other membrane lipids. How sphingolipid homeostasis is achieved is not yet well understood. Studies performed primarily in yeast showed that the phosphorylation states of several enzymes and regulators of sphingolipid synthesis are important, although a global understanding for such regulation is lacking. Here, we used high‐resolution MS‐based proteomics and phosphoproteomics to analyze the cellular response to sphingolipid synthesis inhibition. Our dataset reveals that changes in protein phosphorylation, rather than protein abundance, dominate the response to blocking sphingolipid synthesis. We identified Ypk signaling as a pathway likely to be activated under these conditions, and we identified potential Ypk1 target proteins. Our data provide a rich resource for on‐going mechanistic studies of key elements of the cellular response to the depletion of sphingolipid levels and the maintenance of sphingolipid homeostasis. All MS data have been deposited in the ProteomeXchange with identifier PXD003854 ( http://proteomecentral.proteomexchange.org/dataset/PXD003854 ).     

Efficient initiation of S-phase in yeast requires Cdc40p, a protein involved in pre-mRNA splicing

The S. cerevisiae CDC40 gene was originally identified as a cell-division-specific gene that is essential only at elevated temperatures. Cells carrying mutations in this gene arrest with a large bud and a single nucleus with duplicated DNA content. Cdc40p is also required for spindle establishment or maintenance. Sequence analysis reveals that CDC40 is identical to PRP17, a gene involved in pre-mRNA splicing. In this paper, we show that Cdc40p is required at all temperatures for efficient entry into S-phase and that cell cycle arrest associated with cdc40 mutations is independent of all the known checkpoint mechanisms. Using immunofluorescence, we show that Cdc40p is localized to the nuclear membrane, weakly associated with the nuclear pore. Our results point to a link between cell cycle progression, pre-mRNA splicing, and mRNA export. Received: 9 April 1998 / Accepted: 10 August 1998