Effect of ethanol on the glucose-induced movements of protons across the plasma membrane of Saccharomyces cerevisiae NCYC 431

The study of glucose-induced proton fluxes in Saccharomyces cerevisiae NCYC 431 showed a decrease of proton net efflux by ethanol across the plasma membrane of energized cells. Furthermore a negative net proton efflux (an influx) occurred from a given ethanol concentration (between 1.3 and 1.5 M) whatever the experimental conditions used, thus allowing the definition of a nil-net exchange step where no net movement of protons across the plasma membrane could be observed. A new technique of ethanol tolerance determination in yeast based upon a correlation for the same ethanol concentration between both the collapse of the proton gradient and the growth cessation in cultures supplemented with ethanol after 8 h incubation was proposed. The defined method also showed a cumulated effect of temperature and ethanol on Saccharomyces cerevisiae NCYC 431.     

Mechanisms underlying the acquisition of resistance to octanoic-acid-induced-death following exposure of Saccharomyces cerevisiae to mild stress imposed by octanoic acid or ethanol

Acquisition of resistance to lethal concentrations of octanoic acid was induced in cells of Saccharomyces cerevisiae grown in the presence of sublethal concentrations of this lipophilic acid or following rapid exposure (1 h) of unadapted yeast cells to mild stress imposed by the same acid. Experimental evidence indicated that the referred adaptation involved de novo protein synthesis, presumably due to the rapid induction of a plasma membrane transporter which mediates the active efflux of octanoate out of the cell. Rapid exposure of cells to mild ethanol stress also led to increased resistance to lethal concentrations of octanoic acid. This cross-resistance to octanoic-acid-induced death was below the level of resistance induced by mild octanoic acid stress and did not involve induction of the active expulsion of octanoate out of the cell. However, the rapid exposure of yeast cells to octanoic acid or ethanol led to the activation of plasma membrane H+-ATPase. The physiological role of the two stress responses examined during the present study, namely, the active efflux of octanoate specifically induced by octanoic acid and the stimulation of plasma membrane H+-ATPase activity, is discussed.     

Transient hyperpolarization of yeast by glucose and ethanol

At pH 7, addition of glucose under anaerobic conditions to a suspension of the yeast Saccharomyces cerevisiae causes both a transient hyperpolarization and a transient net efflux of K+ from the cells. Hyperpolarization shows a peak at about 3 min and a net K+ efflux at 4-5 min. An additional transient hyperpolarization and net K+ efflux are found after 60-80 and 100 min, respectively. Addition of 2-deoxyglucose instead of glucose does not lead to hyperpolarization of the cells or K+ efflux. At low pH, neither transient hyperpolarization nor a transient K+ efflux are found. With ethanol as substrate and applying aerobic conditions, both a transient hyperpolarization and a transient K+ efflux are found at pH 7. The fluorescent probe 2-(dimethylaminostyryl)-1-ethylpyridinium appears to be useful for probing changes in the membrane potential of S. cerevisiae. It is hypothesized that the hyperpolarization of the cells is due to opening of K+ channels in the plasma membrane. Accordingly, the hyperpolarization of the cells at pH 7 is almost completely abolished by 1.25 mM K+, whereas the same amount of Na+ does not reduce the hyperpolarization.     

钙离子通过降低细胞膜透性提高自絮凝颗粒酵母耐酒精能力

生长阶段和冲击阶段均添加 1 6 4mmol LCa2 能显著提高自絮凝颗粒酵母于 30℃在 2 0 % (V V)酒精冲击下的存活率 ,经过 9h冲击 ,对照组的存活率为 0 ,而添加Ca2 试验组的存活率为 5 0 0 % ,表明添加适当浓度的Ca2 能显著提高菌体的耐酒精能力。通过考察Ca2 对菌体于 30℃在 15 % (V V)酒精冲击下细胞膜透性的影响发现 ,生长阶段和冲击阶段均添加 1 6 4mmol LCa2 的试验组的菌体胞外核苷酸平衡浓度和细胞膜透性系数 (P′)分别仅为对照组水平的 5 0 0 %和 2 9 3% ,表明添加适当浓度的Ca2 能显著降低受冲击菌体的细胞膜透性 ;而且 ,添加Ca2 提高存活率与添加Ca2 降低胞外核苷酸浓度和P′存在直接的对应关系。因此 ,Ca2 提高自絮凝颗粒酵母耐酒精能力是与其降低受冲击菌体的细胞膜透性密切相关的。     

Changes of Saccharomyces cerevisiae cell membrane components and promotion to ethanol tolerance during the bioethanol fermentation

During bioethanol fermentation process, Saccharomyces cerevisiae cell membrane might provide main protection to tolerate accumulated ethanol, and S. cerevisiae cells might also remodel their membrane compositions or structure to try to adapt to or tolerate the ethanol stress. However, the exact changes and roles of S. cerevisiae cell membrane components during bioethanol fermentation still remains poorly understood. This study was performed to clarify changes and roles of S. cerevisiae cell membrane components during bioethanol fermentation. Both cell diameter and membrane integrity decreased as fermentation time lasting. Moreover, compared with cells at lag phase, cells at exponential and stationary phases had higher contents of ergosterol and oleic acid (C_18:1) but lower levels of hexadecanoic (C_16:0) and palmitelaidic (C_16:1) acids. Contents of most detected phospholipids presented an increase tendency during fermentation process. Increased contents of oleic acid and phospholipids containing unsaturated fatty acids might indicate enhanced cell membrane fluidity. Compared with cells at lag phase, cells at exponential and stationary phases had higher expressions of ACC1 and HFA1. However, OLE1 expression underwent an evident increase at exponential phase but a decrease at following stationary phase. These results indicated that during bioethanol fermentation process, yeast cells remodeled membrane and more changeable cell membrane contributed to acquiring higher ethanol tolerance of S. cerevisiae cells. These results highlighted our knowledge about relationship between the variation of cell membrane structure and compositions and ethanol tolerance, and would contribute to a better understanding of bioethanol fermentation process and construction of industrial ethanologenic strains with higher ethanol tolerance.     

细胞膜磷脂脂肪酸组成对自絮凝酵母质膜ATP酶响应酒精刺激的影响及其与菌体耐酒精的关系

研究揭示细胞膜磷脂脂肪酸组成与质膜ATP酶在酵母菌耐酒精中的一种新颖关系。实验表明,细胞膜磷脂脂肪酸组成特点对生长于未添加酒精条件下的自絮凝颗粒酵母质膜ATP酶活性没有影响,但却明显影响生长于添加酒精(1％～10％,V／V)条件下的菌体质膜ATP酶对酒精激活的敏感性：预培养于添加0．6mmol／L棕榈酸、亚油酸、或亚麻酸条件下的菌体的质膜ATP酶的最大激活水平分别为各自酶的基态水平(未激活)的3．6、1．5和1．2倍,而对照组(预培养于未添加脂肪酸条件下的菌体)的相应值为2．3倍,酶产生上述最大激活水平时的酒精浓度分别为7％、6％、6％、和7％(V/V)。酶激活后米氏常数Km、最适pH和对钒酸钠(质膜ATP酶特异性抑制剂)的敏感性等性质不变,但最大反应速度υmax明显增加。实验表明,细胞膜磷脂脂肪酸组成特点对提高菌体的耐酒精能力越有利,则其质膜ATP酶被酒精激活的幅度越大,说明菌体耐酒精能力的提高与其质膜ATP酶对酒精激活的敏感性的增加密切相关。细胞膜磷脂脂肪酸组成会影响酵母菌质膜ATP酶对酒精激活的敏感性是观察到的新的实验现象。     

Metabolic fate of [14C]-ethanol into endothelial cell phospholipids including platelet-activating factor, sphingomyelin and phosphatidylethanol

The metabolic fate of ethanol into the phospholipid pool of calf pulmonary artery endothelial cells was studied. [14C]-ethanol was incorporated into various endothelial cell phospholipids including phosphatidylethanol (PEth), which may represent a substantial fraction in microdomains of membrane phospholipids. The incorporation into phospholipids was reduced in the presence of pyrazole and cyanamide, inhibitors of ethanol metabolism. Wortmannin, the phosphatidylinositol 3-kinase inhibitor, increased [14C]-PEth formation. [3H]-acetate was also incorporated into endothelial cell phospholipids but in a different pattern. Distribution of [3H]-acetate and [14C]-ethanol into the fatty acyl moiety versus the glycerophosphoryl backbone of the phospholipids was also different. Stimulation of the endothelial cells with ATP increased [3H]-acetate incorporation into platelet-activating factor (PAF) and ethanol decreased it. Ethanol exposure increased ATP-stimulated [3H]-acetate incorporation into sphingomyelin. However, ATP had no effect on the incorporation of [14C]-ethanol into any phospholipids. The results suggest that the two precursors contribute to a separate acetate pool and that the sphingomyelin cycle may be sensitized in ethanol-treated cells. Thus, metabolic conversions of ethanol into lipids and the effect of ethanol on specific lipid mediators, e.g PAF, PEth and sphingomyelin, may be critical determinants in the altered responses of the endothelium in alcoholism.     

Yarrowia lipolytica possesses two plasma membrane alkali metal cation/H+ antiporters with different functions in cell physiology

The family of Nha antiporters mediating the efflux of alkali metal cations in exchange for protons across the plasma membrane is conserved in all yeast species. Yarrowia lipolytica is a dimorphic yeast, phylogenetically very distant from the model yeast Saccharomyces cerevisiae. A search in its sequenced genome revealed two genes (designated as YlNHA1 and YlNHA2) with homology to the S. cerevisiae NHA1 gene, which encodes a plasma membrane alkali metal cation/H+ antiporter. Upon heterologous expression of both YlNHA genes in S. cerevisiae, we showed that Y. lipolytica antiporters differ not only in length and sequence, but also in their affinity for individual substrates. While the YlNha1 protein mainly increased cell tolerance to potassium, YlNha2p displayed a remarkable transport capacity for sodium. Thus, Y. lipolytica is the first example of a yeast species with two plasma membrane alkali metal cation/H+ antiporters differing in their putative functions in cell physiology; cell detoxification vs. the maintenance of stable intracellular pH, potassium content and cell volume.     

Active extrusion of potassium in the yeast Saccharomyces cerevisiae induced by low concentrations of trifluoperazine

Trifluoperazine (TFP), the antipsychotic drug, induces substantial K+ efflux, membrane hyperpolarization and inhibition of H+-ATPase in the yeast Saccharomyces cerevisiae. Investigations on the mechanism of these effects revealed two different processes observed at different incubation conditions. At an acidic pH of 4.5 and an alkaline pH of 7.5, K+ efflux was accompanied by substantial proton influx which led to intracellular acidification and dissipation of delta psi formed by cation efflux. The results indicated nonspecific changes in membrane permeability. Similar results were also observed when cells were incubated at pH 5.5-6.0 with higher concentrations of TFP (above 75 microM). On the other hand, low concentrations of TFP (30-50 microM) at pH 5.5-6.0 caused marked membrane hyperpolarization and K+ efflux unaccompanied by the efflux of other cations and by H+ influx. Our experiments indicate that under these conditions K+ efflux was an active process. (1) K+ efflux proceeded only in the presence of a metabolic substrate and was inhibited by metabolic inhibitors. (2) When 0.3-0.9 mM-KCl was present in the medium at pH 6.0, the concentration of K+ within the cells (measured at the end of the incubation with TFP) was much lower than the theoretical concentration of Kin+ if the distribution of K+ between medium and cell water was at equilibrium (at zero electrochemical gradient). (3) Valinomycin decreased the net K+ efflux and decreased the membrane hyperpolarization induced by TFP, probably by increasing the flux of K+ into the cells along its electrochemical gradient. (4) Conditions which led to active K+ efflux also led to a marked decrease in cellular ATP level. The results indicate that under a specific set of conditions TFP induces translocation of K+ against its electrochemical gradient.     

Relationship between ethanol tolerance and fatty acyl composition of Saccharomyces cerevisiae

Summary The effect of ethanol on exponential phase cultures of S. cerevisiae has been examined using l-alanine uptake and proton efflux as indices of ethanol tolerance. Preincubation with 2 M ethanol inhibited l-alanine uptake, proton efflux and fermentation rates. However, the effect of ethanol varied in yeast cells enriched with different fatty acyl residues. It was observed that cells enriched with polyunsaturated fatty acids acquired greater tolerance to ethanol as compared to monounsaturated fatty acids. By varying the degree of unsaturation of supplemented fatty acid, a sequential insertion of double bonds in yeast membrane lipid was achieved. Results demonstrated that S. cerevisiae became more resistant to ethanol with an increase in the degree of unsaturation and that membrane fluidity could be an important determinant of ethanol tolerance.     

Ethanol sensitivity and membrane lipid composition in three strains of mouse

Strains of mouse (Swiss OF 1, DBA/2J Ico and C57 BL/6J Ico) with different sensitivities to the hypnotic effects of acute ethanol administration were also found to have differences in fatty acid composition in synaptosomal and erythrocyte membrane phospholipids. Chronic ethanol treatment altered membrane fatty acid composition in quantitatively different ways depending on whether the mice developed tolerance (DBA, C57) or not (Swiss). These results support the hypothesis that membrane lipid composition plays a role in the sensitivity to the effects of ethanol.     

Yeast plasma membrane Ena1p ATPase alters alkali-cation homeostasis and confers increased salt tolerance in tobacco cultured cells

In plants, the plasma membrane Na(+)/H(+) antiporter is the only key enzyme that extrudes cytosolic Na(+) and contributes to salt tolerance. But in fungi, the plasma membrane Na(+)/H(+) antiporter and Na(+)-ATPase are known to be key enzymes for salt tolerance. Saccharomyces cerevisiae Ena1p ATPase encoded by the ENA1/PMR2A gene is primarily responsible for Na(+) and Li(+) efflux across the plasma membrane during salt stress and for K(+) efflux at high pH and high K(+). To test if the yeast ATPase would improve salt tolerance in plants, we expressed a triple hemagglutinin (HA)-tagged Ena1p (Ena1p-3HA) in cultured tobacco (Nicotiana tabacum L.) cv Bright Yellow 2 (BY2) cells. The Ena1p-3HA proteins were correctly localized to the plasma membrane of transgenic BY2 cells and conferred increased NaCl and LiCl tolerance to the cells. Under moderate salt stress conditions, the Ena1p-3HA-expressing BY2 clones accumulated lower levels of Na(+) and Li(+) than nonexpressing BY2 clones. Moreover, the Ena1p-3HA expressing BY2 clones accumulated lower levels of K(+) than nonexpressing cells under no-stress conditions. These results suggest that the yeast Ena1p can also function as an alkali-cation (Na(+), Li(+), and K(+)) ATPase and alter alkali-cation homeostasis in plant cells. We conclude that, even with K(+)-ATPase activity, Na(+)-ATPase activity of the yeast Ena1p confers increased salt tolerance to plant cells during salt stress.     

Decline in ribonucleic acid and protein synthesis with loss of viability during the early hours of imbibition of rye (Secale cereale L.) embryos.

The specificity of amino acid transport in normal (high-glutathione) sheep erythrocytes was investigated by studying the interaction of various neutral and dibasic amino acids in both competition and exchange experiments. Apparent Ki values were obtained for amino acids as inhibitors of L-alanine influx. Amino acids previously found to be transported by high-glutathione cells at fast rates (L-cysteine, L-alpha-amino-n-butyrate) were the most effective inhibitors. D-Alanine and D-alpha-amino-n-butyrate were without effect. Of the remaining amino acids studied, only L-norvaline, L-valine, L-norleucine, L-serine and L-2,4-diamino-n-butyrate significantly inhibited L-alanine uptake. L-Alanine efflux from pre-loaded cells was markedly stimulated by extracellular L-alanine. Those amino acids that inhibited L-alanine influx also stimulated L-alanine efflux. In addition, D-alanine, D-alpha-amino-n-biutyrate, L-threonine, L-asparagine, L-alpha, beta-diaminoproprionate, L-ornithine, L-lysine and S-2-aminoethyl-L-cysteine also significantly stimulated L-alanine efflux. L-Lysine uptake was inhibited by L-alanine but not by D-alanine, and the inhibitory potency of L-alanine was not influenced by the replacement of Na+ in the incubation medium with choline. L-Lysine efflux from pre-loaded cells was stimulated by L-alanine but not by D-alanine. It is concluded that these cells possess a highly selective stero-specific amino acid-transport system. Although the optimum substrates are small neutral amino acids, this system also has a significant affinity for dibasic amino acids.     

Schizosaccharomyces pombe possesses two plasma membrane alkali metal cation/H antiporters differing in their substrate specificity

The Schizosaccharomyces pombe plasma membrane Na(+)/H(+) antiporter, SpSod2p, has been shown to belong to the subfamily of yeast Na(+)/H(+) antiporters that only recognize Na(+) and Li(+) as substrates. Nevertheless, most of the studied plasma membrane alkali metal cation/H(+) antiporters from other yeasts have broader substrate specificities, exporting K(+) and Rb(+) as well. Such antiporters probably play two roles in the physiology of cells: the elimination of surplus toxic cations, and the regulation of stable intracellular K(+) content, pH and cell volume. The systematic sequencing of the Sch. pombe genome revealed the presence of an as-yet uncharacterized homolog of the Spsod2 gene (designated Spsod22). Spsod22 and Spsod2 were expressed in Saccharomyces cerevisiae cells lacking their own alkali metal cation efflux systems, and the transport properties of both Sch. pombe antiporters were compared to those of the Sac. cerevisiae Nha1 antiporter expressed under the same conditions. Here we show that SpSod22p has broad substrate specificity upon heterologous expression in Sac. cerevisiae cells and contributes to cell tolerance to high external levels of K(+). Thus, the Sch. pombe genome encodes two plasma membrane alkali metal cation/H(+) antiporters that play different roles in the physiology of the yeast.     

Regulation of Na+-H+ exchange by transmethylation reactions in rat colonic brush-border membranes

Incubation of rat colonic brush-border membrane vesicles with 200 microM S-adenosyl-L-[Me-3H]methionine resulted in the labeling of both membrane phospholipids and proteins. This labeling was decreased approximately 50% by the methylation inhibitor S-adenosyl-L-homocysteine (2 mM). Utilizing the pH-sensitive fluorescent dye, acridine orange, as a means of determining Na+-H+ exchange, S-adenosyl-L-methionine (200 microM) significantly increased sodium-stimulated proton efflux in these vesicles at all concentrations of sodium (2.5-50 mM) tested. Examination of the kinetic parameters for sodium-stimulated proton efflux in the presence and absence of 200 microM S-adenosyl-L-methionine revealed that the methyl donor increased the Vmax for this exchange mechanism (expressed in arbitrary fluorescence units) by approx. 36% but did not influence its Km for sodium. S-Adenosyl-L-homocysteine (2 mM) inhibited S-adenosyl-L-methionine-mediated stimulation of this exchange process. The results demonstrate that methylation of membrane phospholipids and/or proteins can modulate Na+-H+ exchange in rat colonic brush-border membrane vesicles.     

海藻糖与热激蛋白在酿酒酵母耐受乙醇胁迫中的作用

在燃料乙醇发酵生产过程中,酿酒酵母经常会受到高浓度乙醇的胁迫,导致乙醇转化率和产量降低。面对高浓度乙醇的胁迫,酿酒酵母也具有应对胁迫的应激机制。在对这种应激机制进行了解的基础上,如能提高酿酒酵母对乙醇的耐受性,对于燃料乙醇生产具有重要意义。在高浓度乙醇胁迫下,酿酒酵母细胞会产生一系列保护性物质,如海藻糖、热激蛋白、脯氨酸等,这些物质能够提高酿酒酵母细胞对乙醇的耐受性。海藻糖作为一种重要的碳源、能量贮藏物质,不仅能稳定细胞膜、蛋白质和核酸等大分子物质,还可增强酿酒酵母对高浓度乙醇的耐受性。此外,酿酒酵母还可以产生大量的热激蛋白,增强酿酒酵母的抗逆性。从海藻糖和热激蛋白在乙醇胁迫下对酿酒酵母细胞保护作用的研究方面进行了综述,并对存在的问题进行了讨论与展望。     

Stimulation of strontium accumulation in linoleate-enriched Saccharomyces cerevisiae is a result of reduced Sr2+ efflux

The influence of modified plasma membrane fatty acid composition on cellular strontium accumulation in Saccharomyces cerevisiae was investigated. Growth of S. cerevisiae in the presence of 1 mM linoleate (18:2) (which results in 18:2 incorporation to approximately 70% of total cellular and plasma membrane fatty acids, with no effect on growth rate) yielded cells that accumulated Sr2+ intracellularly at approximately twice the rate of S. cerevisiae grown without a fatty acid supplement. This effect was evident over a wide range of external Sr2+ concentrations (25 microM to 5 mM) and increased with the extent of cellular 18:2 incorporation. Stimulation of Sr2+ accumulation was not evident following enrichment of S. cerevisiae with either palmitoleate (16:1), linolenate (18:3) (n-3 and n-6 isomers), or eicosadienoate (20:2) (n-6 and n-9 isomers). Competition experiments revealed that Ca2+- and Mg2+-induced inhibition of Sr2+ accumulation did not differ between unsupplemented and 18:2-supplemented cells. Treatment with trifluoperazine (TFP) (which can act as a calmodulin antagonist and Ca2+-ATPase inhibitor), at a low concentration that precluded nonspecific K+ efflux, increased intracellular Sr2+ accumulation by approximately 3.6- and 1.4-fold in unsupplemented and 18:2-supplemented cells, respectively. Thus, TFP abolished the enhanced Sr2+ accumulation ability of 18:2-supplemented cells. Moreover, the rate of Sr2+ release from Sr2+-loaded fatty acid-unsupplemented cells was found to be at least twice as great as that from Sr2+-loaded 18:2-enriched cells. The influence of enrichment with other fatty acids on Sr2+ efflux was variable. The results reveal an enhanced Sr2+ accumulation ability of S. cerevisiae following 18:2-enrichment, which is attributed to diminished Sr2+ efflux activity in these cells.     

Physiological characterization of Saccharomyces cerevisiae kha1 deletion mutants

Maintenance of intracellular K+ homeostasis is one of the crucial requisites for the survival of yeast cells. In Saccharomyces cerevisiae, the high K+ content corresponds to a steady state between simultaneous influx and efflux across the plasma membrane. One of the transporters formerly believed to extrude K+ from the yeast cells (besides Ena1-4p and Nha1p) was named Kha1p and presumed as a putative plasma membrane K+/H+ antiporter. We prepared kha1 and tok1-kha1 deletion strains in the B31 and MAB 2d background. Both the strains contain the ena1-4 and nha1 deletions; that means they lack the main active sodium and potassium efflux systems. MAB 2d has additional trk1 and trk2 deletions, i.e. is impaired in active K+ uptake as well. We performed a large physiological study with these strains to specify the phenotype of kha1 deletion. In our experiments, no difference in K+ content or efflux was observed in strains lacking the KHA1 gene compared with control strains. Two main phenotype manifestations of the kha1 deletion were growth defect on high external pH and hygromycin sensitivity. The correlation between these phenotypes and the kha1 deletion was confirmed by plasmid complementation. Fluorescence microscopy of green fluorescent protein (GFP)-tagged Kha1p showed that this antiporter is localized preferentially intracellularly (in contrast to the plasma membrane Na+/H+ antiporter Nha1p). Based on these findings, Kha1p is probably not localized in plasma membrane and does not mediate efflux of alkali metal cations from cells, but is important for the regulation of intracellular cation homeostasis and optimal pH control, similarly as the Nhx1p.     

Ethanol tolerance in the yeast Saccharomyces cerevisiae is dependent on cellular oleic acid content

In this investigation, we examined the effects of different unsaturated fatty acid compositions of Saccharomyces cerevisiae on the growth-inhibiting effects of ethanol. The unsaturated fatty acid (UFA) composition of S. cerevisiae is relatively simple, consisting almost exclusively of the mono-UFAs palmitoleic acid (Delta(9)Z-C(16:1)) and oleic acid (Delta(9)Z-C(18:1)), with the former predominating. Both UFAs are formed in S. cerevisiae by the oxygen- and NADH-dependent desaturation of palmitic acid (C(16:0)) and stearic acid (C(18:0)), respectively, catalyzed by a single integral membrane desaturase encoded by the OLE1 gene. We systematically altered the UFA composition of yeast cells in a uniform genetic background (i) by genetic complementation of a desaturase-deficient ole1 knockout strain with cDNA expression constructs encoding insect desaturases with distinct regioselectivities (i.e., Delta(9) and Delta(11)) and substrate chain-length preferences (i.e., C(16:0) and C(18:0)); and, (ii) by supplementation of the same strain with synthetic mono-UFAs. Both experimental approaches demonstrated that oleic acid is the most efficacious UFA in overcoming the toxic effects of ethanol in growing yeast cells. Furthermore, the only other UFA tested that conferred a nominal degree of ethanol tolerance is cis-vaccenic acid (Delta(11)Z-C(18:1)), whereas neither Delta(11)Z-C(16:1) nor palmitoleic acid (Delta(9)Z-C(16:1)) conferred any ethanol tolerance. We also showed that the most ethanol-tolerant transformant, which expresses the insect desaturase TniNPVE, produces twice as much oleic acid as palmitoleic acid in the absence of ethanol and undergoes a fourfold increase in the ratio of oleic acid to palmitoleic acid in response to exposure to 5% ethanol. These findings are consistent with the hypothesis that ethanol tolerance in yeast results from incorporation of oleic acid into lipid membranes, effecting a compensatory decrease in membrane fluidity that counteracts the fluidizing effects of ethanol.