FLO11 is essential for flor formation caused by the C-terminal deletion of NRG1 in Saccharomyces cerevisiae

The flor strains of Saccharomyces cerevisiae form a flor on the surface of wine after alcoholic fermentation. High hydrophobicity of the cell surface is suggested to be important for flor formation by the flor wine yeasts. However, the molecular mechanism of flor formation is not clear. We found that expression of C-terminal deleted NRG1 lacking its two C2H2 zinc finger motifs (NRG1(1-470)) on the multicopy plasmid conferred the ability to form a flor to a non-flor laboratory strain. The cell surface hydrophobicity of NRG1(1-470) was higher than of the non-flor strain. Disruption of the Nrg1p-repressed gene FLO11, which encodes a cell surface glycoprotein that functions as a flocculin or an adhesin, abolished flor formation. Moreover, expression of FLO11 on a multicopy plasmid could also cause flor formation. These results indicate that FLO11 is essential for flor formation by NRG1(1-470). In addition, the results suggest that the C-terminal truncated form of Nrg1p exerts a dominant negative effect on FLO11 repression, resulting in FLO11 expression and, thus, flor formation.     

酵母交配过程的极性生长及其调控机制

酿酒酵母单倍体细胞能够与相反交配型的单倍体细胞发生交配。交配时酿酒酵母放弃原有出芽位点,根据信息素的浓度梯度,重新选择生长位点,向相反交配型细胞伸出突起进行极性生长。交配因子受体指导选择交配突起的位点,通过G蛋白激活Ste20p,将信号经由Ste11p、Ste7p和Fus3p组成的MAPK模块传递到Far1p和Ste12p等因子,调控相关基因的转录,抑制原有的出芽位点,选择新的生长位点,并使细胞周期停止在G1期,G蛋白与Cdc24p、Cdc42p和Bem1p等蛋白作用,聚集在细胞,使得肌协蛋白细胞骨架在交配突起处聚集,呈极性化分布,使细胞发生极性生长。     

The immunosuppressive drug leflunomide affects mating-pheromone response and sporulation by different mechanisms in Saccharomyces cerevisiae

Leflunomide (LFM) is a novel anti-inflammatory and immunosuppressive drug, and inhibits the growth of cytokine-stimulated lymphoid cells in vitro. The effect of LFM on haploid and diploid cells of Saccharomyces cerevisiae was investigated to elucidate the molecular mechanism of action of the drug. Using a halo assay, LFM was shown to enhance the cell cycle arrest of haploid cells induced by mating pheromone alpha-factor. LFM also inhibited sporulation of diploid cells completely. S. cerevisiae genes which were cloned to suppress the anti-proliferative effect when present in increased copy number were introduced and examined for their activity to suppress the effect of LFM. Out of them, MLF4/SSH4, was found to suppress the sporulation-inhibitory effect of LFM. However, MLF4 failed to suppress the enhancing effect of LFM on pheromone response. Thus, LFM is suggested to act on haploid and diploid cells by different mechanisms.     

Characterization of gamma-glutamylamidase-glutaminase activity in Saccharomyces cerevisiae

In a foregoing paper we have shown the presence in the yeast Saccharomyces cerevisiae of an enzyme catalyzing the hydrolysis of L-gamma-glutamyl-p-nitroanilide, but apparently distinct from gamma-glutamyltranspeptidase. The cellular level of this enzyme was not regulated by the nature of the nitrogen source supplied to the yeast cell. Purification was attempted, using ion exchange chromatography on DEAE Sephadex A 50, salt precipitations and successive chromatographies on DEAE Sephadex 6B and Sephadex G 100. The apparent molecular weight of the purified enzyme was 14,800 as determined by gel filtration. As shown by kinetic studies and thin layer chromatography, the enzyme preparation exhibited only hydrolytic activity against gamma-glutamylarylamide and L-glutamine with an optimal pH of about seven. Various gamma-glutamylaminoacids, amides, dipeptides and glutathione were inactive as substrates and no transferase activity was detected. The yeast gamma-glutamylarylamidase was activated by SH protective agents, dithiothreitol and reduced glutathione. Oxidized glutathione, ophtalmic acid and various gamma-glutamylaminoacids inhibited competitively the enzyme. The activity was also inhibited by L-gamma-glutamyl-o-(carboxy)phenylhydrazide and the couple serine-borate, both transition-state analogs of gamma-glutamyltranspeptidase. Diazooxonorleucine, reactive analog of glutamine, inactivated the enzyme. The physiological role of yeast gamma-glutamylarylamidase-glutaminase is still undefined but is most probably unrelated to the bulk assimilation of glutamine by yeast cells.     

Glutathione is an important antioxidant molecule in the yeast Saccharomyces cerevisiae

Abstract The tripeptide γ-l-glutamyl-l-cystinylglycine (glutathione) is one of the major antioxidant molecules of cells and is thought to play a vital role in buffering the cell against reactive oxygen species and toxic electrophiles. We wished to determine the role of glutathione in the protection of the yeast Saccharomyces cerevisiae against oxidative stress. This study shows that glutathione is an important antioxidant molecule in yeast, with γ-glutamylcysteine synthetase ( gshI ) mutants, deficient in glutathione synthesis, being hypersensitive to H₂O₂ and Superoxide anions in both exponential- and stationary-phase cultures. Despite this, these mutants are still able to induce adaptive stress responses to oxidants.     

An upstream regulator and downstream target of phospholipase D1 activity during pheromone response in Saccharomyces cerevisiae

Phospholipase D1 (PLD1), which is the product of the SPO14 gene, has been shown to play a role in the process of polarized cell growth (PCG) during the pheromone response in Saccharomyces cerevisiae. PLD1 hydrolyzes phosphatidylcholine to produce phosphatidic acid (PA) and a free choline headgroup. This study investigated the interactions of PLD1 and PA with two proteins known to be involved in the cellular signaling leading to PCG in yeast, the small GTPase Cdc42p and the PAK family kinase Ste20p. Constitutively activated Cdc42p stimulates PLD1 activity. Protein-lipid binding blots confirmed the specific binding of Ste20p to the PLD1 product, PA. Finally, kinase activity assays provided evidence for the stimulation of Ste20p by PA. These findings highlight the important interactions among PLD1, Cdc42p and Ste20p during PCG in S. cerevisiae.     

过量表达蛋白激酶YPK1使酵母细胞对高盐胁迫的高度敏感依赖于雷帕霉素靶蛋白

摘要：YPK1是酵母中和哺乳动物蛋白激酶SGK同源的一种丝氨酸∕苏氨酸蛋白激酶,在酿酒酵母（Saccharomyces cerevisiae）生理调节中有重要的作用,和酵母细胞壁的完整性、细胞骨架中肌动蛋白极性、细胞内吞作用、细胞在氮源缺乏和营养条件调节下细胞内部的翻译情况密切相关。【目的】为了深入研究YPK1蛋白激酶的细胞功能以及在细胞信号传导中的作用,【方法】我们构建了过量表达YPK1的高拷贝质粒,研究了过量表达YPK1的酵母细胞在盐胁迫条件下的生长情况,【结果】发现过量表达YPK1会导致酵母细胞对盐胁迫高度敏感,并且这种敏感性依赖于TOR1的存在。【结论】我们的研究结果首次初步揭示YPK1与细胞盐胁迫应答的关系,并初步证明YPK1的功能充分发挥需要TOR1的参与。     

The Saccharomyces cerevisiae Wss1 protein is only present in mother cells

The Saccharomyces cerevisiae WSS1 (Weak Suppressor of Smt3) gene has initially been identified as a multicopy suppressor of a mutation in SMT3 encoding the small ubiquitin-like modifier. Later, multiple functions related to DNA replication and repair have been found for WSS1. Here, we report the subcellular location of the Wss1 protein. Fluorescence microscopy of strains expressing a Wss1p-green fluorescent protein (GFP) fusion shows that the protein is present in a single sharp spot near the nuclear membrane, distinct from the spindle pole bodies and nucleolus. In dividing cells, the spot is exclusively present in the mother cell, suggesting a mother cell-specific function of WSS1.     

Dihydroxyacetone-induced death is accompanied by advanced glycation endproduct formation in selected proteins of Saccharomyces cerevisiae and Caenorhabditis elegans

Advanced glycation endproduct (AGE) formation is an important mechanism for protein deterioration during diabetic complications and ageing. The effects on AGE formation following dihydroxyacetone (DHA) stress were studied in two model organisms, the yeast Saccharomyces cerevisiae and the nematode Caenorhabditis elegans. Total protein AGEs, detected using an anti-N(epsilon)-carboxyalkyllysine-specific monoclonal antibody, displayed a strong correlation to DHA-induced yeast cell mortality in the wild-type and hypersensitive as well as resistant mutant strains. During DHA-induced cell death we also detected AGEs as the formation of acidic protein modifications by 2-D PAGE. Furthermore, we confirmed AGE targets immunologically on 2-D gel-separated protein extracted from DHA-treated cells. AGE modification of several metabolic enzymes (Eno2p, Adh1p, Met6 and Pgk1p) and actin (Act1p) displayed a strong correlation to DHA-induced cell death. DHA was toxic to C. elegans even at low concentration and also in this organism AGE formation accompanied death. We propose the use of DHA as a model AGE-generating substance for its apparent lack of a clear oxidative stress connection, and yeast and worm as model organisms to identify genetic determinants of protein AGE formation.     

酵母细胞中Pil1的磷酸化与细胞压力抵抗的关系

在外界因素处理下,细胞将启动一系列保护措施以适应各种环境改变,磷酸化调节是蛋白功能调节的主要方式. 为了探讨酵母细胞中Pil1的磷酸化与细胞压力抵抗的关系,实验应用Pil1突变细胞检测在过氧化氢或热处理后细胞的生长情况,用免疫印记法检测热处理后Pil1的表达. 结果表明,相比野生细胞,Pil1突变细胞对抗过氧化氢和热的能力强,热处理后 Pil1的磷酸化水平增高, Pil1的丝氨酸273对于其磷酸化发生至关重要.     

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。     

SKO1 deficiency extends chronological lifespan in Saccharomyces cerevisiae

ABSTRACT

Sko1 plays a key role in the control of gene expression by osmotic and oxidative stress in yeast. We demonstrate that the decrease in chronological lifespan (CLS) of hog1Δ cells was suppressed by SKO1 deletion. sko1Δ single mutant cells were shown to have a longer CLS, thus implicating Sko1 in the regulation of their CLS.     

Pab1 acetylation at K131 decreases stress granule formation in Saccharomyces cerevisiae

Under environmental stress, such as glucose deprivation, cells form stress granules—the accumulation of cytoplasmic aggregates of repressed translational initiation complexes, proteins, and stalled mRNAs. Recent research implicates stress granules in various diseases, such as neurodegenerative diseases, but the exact regulators responsible for the assembly and disassembly of stress granules are unknown. An important aspect of stress granule formation is the presence of posttranslational modifications on core proteins. One of those modifications is lysine acetylation, which is regulated by either a lysine acetyltransferase or a lysine deacetylase enzyme. This work deciphers the impact of lysine acetylation on an essential protein found in Saccharomyces cerevisiae stress granules, poly(A)-binding protein (Pab1). We demonstrated that an acetylation mimic of the lysine residue in position 131 reduces stress granule formation upon glucose deprivation and other stressors such as ethanol, raffinose, and vanillin. We present genetic evidence that the enzyme Rpd3 is the primary candidate for the deacetylation of Pab1-K131. Further, our electromobility shift assay studies suggest that the acetylation of Pab1-K131 negatively impacts poly(A) RNA binding. Due to the conserved nature of stress granules, therapeutics targeting the activity of lysine acetyltransferases and lysine deacetylase enzymes may be a promising route to modulate stress granule dynamics in the disease state.     

Irreversible formation of pseudohyphae by haploid Saccharomyces cerevisiae

Abstract Culturing haploid strains of Saccharomyces cerevisiae in liquid minimal medium with 2% ethanol and 2% leucine resulted in the formation of long anucleate pseudohyphae. This occurred only with the combination of ethanol as carbon source and leucine as nitrogen source and was independent of mating type. The transition to a pseudohyphal form observed under these conditions appears to be irreversible. These findings further extend our view of the developmental alternatives in this important model eukaryote.     

The alpha-factor receptor C-terminus is important for mating projection formation and orientation in Saccharomyces cerevisiae

Successful mating of MATa Saccharomyces cerevisiae cells is dependent on Ste2p, the alpha-factor receptor. Besides receiving the pheromone signal and transducing it through the G-protein coupled MAP kinase pathway, Ste2p is active in the establishment and orientation of the mating projection. We investigated the role of the carboxyl terminus of the receptor in mating projection formation and orientation using a spatial gradient assay. Cells carrying the ste2-T326 mutation, truncating 105 of the 135 amino acids in the receptor tail including a motif necessary for its ligand-mediated internalization, display slow onset of projection formation, abnormal shmoo morphology, and reduced ability to orient the mating projection toward a pheromone source. This reduction was due to the increased loss of mating projection orientation in a pheromone gradient. Cells with a mutated endocytosis motif were defective in reorientation in a pheromone gradient. ste2-Delta296 cells, which carry a complete truncation of the Ste2p tail, exhibit a severe defect in projection formation, and those projections that do form are unable to orient in a pheromone gradient. These results suggest a complex role for the Ste2p carboxy-terminal tail in the formation, orientation, and directional adjustment of the mating projection, and that endocytosis of the receptor is important for this process. In addition, mutations in RSR1/BUD1 and SPA2, genes necessary for budding polarity, exhibited little or no defect in formation or orientation of mating projections. We conclude that mating projection orientation depends upon the carboxyl terminus of the pheromone receptor and not the directional machinery used in budding.     

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。