The yeast mRNA-binding protein Cth2 post-transcriptionally modulates ergosterol biosynthesis in response to iron deficiency

Sterol synthesis is an iron-dependent metabolic pathway in eukaryotes. Consequently, fungal ergosterol biosynthesis (ERG) is down-regulated in response to iron deficiency. In this report, we show that, upon iron limitation or overexpression of the iron-regulated mRNA-binding protein Cth2, the yeast Saccharomyces cerevisiae down-regulates the three initial enzymatic steps of ergosterol synthesis (ERG1, ERG7 and ERG11). Mechanistically, we show that Cth2 protein limits the translation and promotes the decrease in the mRNA levels of these specific ERG genes, which contain consensus Cth2-binding sites defined as AU-rich elements (AREs). Thus, expression of CTH2 leads to the accumulation of initial sterol intermediates, such as squalene, and to the drop of ergosterol levels. Changes in CTH2 expression levels disturb the response of yeast cells to stresses related to membrane integrity such as high ethanol and sorbitol concentrations. Therefore, CTH2 should be considered as a critical regulatory factor of ergosterol biosynthesis during iron deficiency.     

Characterization of a mutation that results in independence of oxidosqualene cyclase (Erg7) activity from the downstream 3-ketoreductase (Erg27) in the yeast ergosterol biosynthetic pathway

In yeast, deletion of ERG27, which encodes the sterol biosynthetic enzyme, 3-keto-reductase, results in a concomitant loss of the upstream enzyme, Erg7p, an oxidosqualene cyclase (OSC). However, this phenomenon occurs only in fungi, as mammalian Erg27p orthologues are unable to rescue yeast Erg7p activity. In this study, an erg27 mutant containing the mouse ERG27 orthologue was isolated that was capable of growing without sterol supplementation (FGerg27). GC/MS analysis of this strain showed an accumulation of squalene epoxides, 3-ketosterones, and ergosterol. This strain which was crossed to a wildtype and daughter segregants showed an accumulation of squalene epoxides as well as ergosterol indicating that the mutation entailed a leaky block at ERG7. Upon sequencing the yeast ERG7 gene an A598S alteration was found in a conserved alpha helical region. We theorize that this mutation stabilizes Erg7p in a conformation that mimics Erg27p binding. This mutation, while decreasing OSC activity still retains sufficient residual OSC activity such that the strain in the presence of the mammalian 3-keto reductase enzyme functions and no longer requires the yeast Erg27p. Because sterol biosynthesis occurs in the ER, a fusion protein was synthesized combining Erg7p and Erg28p, a resident ER protein and scaffold of the C-4 demethyation complex. Both FGerg27 and erg27 strains containing this fusion plasmid and the mouse ERG27 orthologue showed restoration of ergosterol biosynthesis with minimal accumulation of squalene epoxides. These results indicate retention of Erg7p in the ER increases its activity and suggest a novel method of regulation of ergosterol biosynthesis.     

Interactions of oxidosqualene cyclase (Erg7p) with 3-keto reductase (Erg27p) and other enzymes of sterol biosynthesis in yeast

In Saccharomyces cerevisiae and Candida albicans, two enzymes of the ergosterol biosynthetic pathway, oxidosqualene cyclase (Erg7p) and 3-keto reductase (Erg27p) interact such that loss of the 3-keto reductase also results in a concomitant loss of activity of the upstream oxidosqualene cyclase. This interaction wherein Erg27p has a stabilizing effect on Erg7p was examined to determine whether Erg7p reciprocally has a protective effect on Erg27p. To this aim, three yeast strains each lacking the ERG7 gene were tested for 3-ketoreductase activity by incubating either cells or cell homogenates with unlabeled and radiolabeled 3-ketosteroids. In these experiments, the ketone substrates were effectively reduced to the corresponding alcohols, providing definitive evidence that oxidosqualene cyclase is not required for the 3-ketoreductase activity. This suggests that, in S. cerevisiae, the protective relationship between the 3-keto reductase (Erg27p) and oxidosqualene cyclase (Erg7p) is not reciprocal. However, the absence of the Erg7p, appears to affect other enzymes of sterol biosynthesis downstream of lanosterol formation. Following incubation with radiolabeled and non-radiolabeled 3-ketosteroids we detected differences in hydroxysteroid accumulation and ergosterol production between wild-type and ERG7 mutant strains. We suggest that oxidosqualene cyclase affects Erg25p (C-4 sterol oxidase) and/or Erg26p (C-3 sterol dehydrogenase/C-4 decarboxylase), two enzymes that, in conjunction with Erg27p, are involved in C-4 sterol demethylation.     

A new method for isolation of S-adenosylmethionine (SAM)-accumulating yeast

S-Adenosylmethionine (SAM) is an important metabolite that participates in many reactions as a methyl group donor in all organisms, and has attracted much interest in clinical research because of its potential to improve many diseases, such as depression, liver disease, and osteoarthritis. Because of these potential applications, a more efficient means is needed to produce SAM. Accordingly, we developed a positive selection method to isolate SAM-accumulating yeast in this study. In Saccharomyces cerevisiae, one of the main reactions consuming SAM is thought to be the methylation reaction in the biosynthesis of ergosterol that is catalyzed by Erg6p. Mutants with deficiencies in ergosterol biosynthesis may accumulate SAM as a result of the reduction of SAM consumption in ergosterol biosynthesis. We have applied this method to isolate SAM-accumulating yeasts with nystatin, which has been used to select mutants with deficiencies in ergosterol biosynthesis. SAM-accumulating mutants from S. cerevisiae K-9 and X2180-1A were efficiently isolated through this method. These mutants accumulated 1.7–5.5 times more SAM than their parental strains. NMR and GC-MS analyses suggested that two mutants from K-9 have a mutation in the erg4 gene, and erg4 disruptants from laboratory strains also accumulated more SAM than their parental strains. These results indicate that mutants having mutations in the genes for enzymes that act downstream of Erg6p in ergosterol biosynthesis are effective in accumulating SAM.     

Dual Localization of Squalene Epoxidase, Erg1p, in Yeast Reflects a Relationship between the Endoplasmic Reticulum and Lipid Particles

Squalene epoxidase, encoded by the ERG1 gene in yeast, is a key enzyme of sterol biosynthesis. Analysis of subcellular fractions revealed that squalene epoxidase was present in the microsomal fraction (30,000 × g) and also cofractionated with lipid particles. A dual localization of Erg1p was confirmed by immunofluorescence microscopy. On the basis of the distribution of marker proteins, 62% of cellular Erg1p could be assigned to the endoplasmic reticulum and 38% to lipid particles in late logarithmic-phase cells. In contrast, sterol Δ²⁴-methyltransferase (Erg6p), an enzyme catalyzing a late step in sterol biosynthesis, was found mainly in lipid particles cofractionating with triacylglycerols and steryl esters. The relative distribution of Erg1p between the endoplasmic reticulum and lipid particles changes during growth. Squalene epoxidase (Erg1p) was absent in an erg1 disruptant strain and was induced fivefold in lipid particles and in the endoplasmic reticulum when the ERG1 gene was overexpressed from a multicopy plasmid. The amount of squalene epoxidase in both compartments was also induced approximately fivefold by treatment of yeast cells with terbinafine, an inhibitor of the fungal squalene epoxidase. In contrast to the distribution of the protein, enzymatic activity of squalene epoxidase was only detectable in the endoplasmic reticulum but was absent from isolated lipid particles. When lipid particles of the wild-type strain and microsomes of an erg1 disruptant were mixed, squalene epoxidase activity was partially restored. These findings suggest that factor(s) present in the endoplasmic reticulum are required for squalene epoxidase activity. Close contact between lipid particles and endoplasmic reticulum may be necessary for a concerted action of these two compartments in sterol biosynthesis.     

ERG2 and ERG24 Are Required for Normal Vacuolar Physiology as Well as Candida albicans Pathogenicity in a Murine Model of Disseminated but Not Vaginal Candidiasis

Several important classes of antifungal agents, including the azoles, act by blocking ergosterol biosynthesis. It was recently reported that the azoles cause massive disruption of the fungal vacuole in the prevalent human pathogen Candida albicans. This is significant because normal vacuolar function is required to support C. albicans pathogenicity. This study examined the impact of the morpholine antifungals, which inhibit later steps of ergosterol biosynthesis, on C. albicans vacuolar integrity. It was found that overexpression of either the ERG2 or ERG24 gene, encoding C-8 sterol isomerase or C-14 sterol reductase, respectively, suppressed C. albicans sensitivity to the morpholines. In addition, both erg2Δ/Δ and erg24Δ/Δ mutants were hypersensitive to the morpholines. These data are consistent with the antifungal activity of the morpholines depending upon the simultaneous inhibition of both Erg2p and Erg24p. The vacuoles within both erg2Δ/Δ and erg24Δ/Δ C. albicans strains exhibited an aberrant morphology and accumulated large quantities of the weak base quinacrine, indicating enhanced vacuolar acidification compared with that of control strains. Both erg mutants exhibited significant defects in polarized hyphal growth and were avirulent in a mouse model of disseminated candidiasis. Surprisingly, in a mouse model of vaginal candidiasis, both mutants colonized mice at high levels and induced a pathogenic response similar to that with the controls. Thus, while targeting Erg2p or Erg24p alone could provide a potentially efficacious therapy for disseminated candidiasis, it may not be an effective strategy to treat vaginal infections. The potential value of drugs targeting these enzymes as adjunctive therapies is discussed.     

Yeast Genome-Wide Expression Analysis Identifies a Strong Ergosterol and Oxidative Stress Response during the Initial Stages of an Industrial Lager Fermentation

Genome-wide expression analysis of an industrial strain of Saccharomyces cerevisiae during the initial stages of an industrial lager fermentation identified a strong response from genes involved in the biosynthesis of ergosterol and oxidative stress protection. The induction of the ERG genes was confirmed by Northern analysis and was found to be complemented by a rapid accumulation of ergosterol over the initial 6-h fermentation period. From a test of the metabolic activity of deletion mutants in the ergosterol biosynthesis pathway, it was found that ergosterol is an important factor in restoring the fermentative capacity of the cell after storage. Additionally, similar ERG10 and TRR1 gene expression patterns over the initial 24-h fermentation period highlighted a possible interaction between ergosterol biosynthesis and the oxidative stress response. Further analysis showed that erg mutants producing altered sterols were highly sensitive to oxidative stress-generating compounds. Here we show that genome-wide expression analysis can be used in the commercial environment and was successful in identifying environmental conditions that are important in industrial yeast fermentation.     

Membrane Rafts Are Involved in Intracellular Miconazole Accumulation in Yeast Cells

Azoles inhibit ergosterol biosynthesis, resulting in ergosterol depletion and accumulation of toxic 14α-methylated sterols in membranes of susceptible yeast. We demonstrated previously that miconazole induces actin cytoskeleton stabilization in Saccharomyces cerevisiae prior to induction of reactive oxygen species, pointing to an ancillary mode of action. Using a genome-wide agar-based screening, we demonstrate in this study that S. cerevisiae mutants affected in sphingolipid and ergosterol biosynthesis, namely ipt1, sur1, skn1, and erg3 deletion mutants, are miconazole-resistant, suggesting an involvement of membrane rafts in its mode of action. This is supported by the antagonizing effect of membrane raft-disturbing compounds on miconazole antifungal activity as well as on miconazole-induced actin cytoskeleton stabilization and reactive oxygen species accumulation. These antagonizing effects point to a primary role for membrane rafts in miconazole antifungal activity. We further show that this primary role of membrane rafts in miconazole action consists of mediating intracellular accumulation of miconazole in yeast cells.     

Changes in the Sterol Composition of the Plasma Membrane Affect Membrane Potential,Salt Tolerance and the Activity of Multidrug Resistance Pumps in Saccharomyces cerevisiae

We investigated the impact of the deletions of genes from the final steps in the biosynthesis of ergosterol (ERG6, ERG2, ERG3, ERG5, ERG4) on the physiological function of the Saccharomyces cerevisiae plasma membrane by a combination of biological tests and the diS-C₃(3) fluorescence assay. Most of the erg mutants were more sensitive than the wild type to salt stress or cationic drugs, their susceptibilities were proportional to the hyperpolarization of their plasma membranes. The different sterol composition of the plasma membrane played an important role in the short-term and long-term processes that accompanied the exposure of erg strains to a hyperosmotic stress (effect on cell size, pH homeostasis and survival of yeasts), as well as in the resistance of cells to antifungal drugs. The pleiotropic drug-sensitive phenotypes of erg strains were, to a large extent, a result of the reduced efficiency of the Pdr5 efflux pump, which was shown to be more sensitive to the sterol content of the plasma membrane than Snq2p. In summary, the erg4Δ and erg6Δ mutants exhibited the most compromised phenotypes. As Erg6p is not involved in the cholesterol biosynthetic pathway, it may become a target for a new generation of antifungal drugs.     

甾醇C-24甲基转移酶和甾醇C-8异构酶在酿酒酵母麦角甾醇生物合成中的调控作用

摘要：【目的】研究ERG6基因编码的甾醇C-24甲基转移酶和ERG2基因编码的甾醇C-8异构酶在酿酒酵母麦角甾醇生物合成代谢中的调控作用。【方法】通过PCR扩增克隆到酿酒酵母甾醇C-8异构酶的编码序列及其终止子序列,以大肠杆菌-酿酒酵母穿梭质粒YEp352为载体,以磷酸甘油酸激酶基因PGK1启动子为上游调控元件构建了酵母菌表达质粒pPERG2;同时,在本实验室已构建的ERG6表达质粒pPERG6的基础上,构建了ERG2和ERG6共表达的重组质粒pPERG6-2。将表达质粒转化酿酒酵母单倍体菌株YS58,依据营养缺陷互补筛选到重组菌株YS58(pPERG2)和YS58(pPERG6-2)。通过紫外分光光度法和气相色谱法分析重组菌株甾醇组分和含量。【结果】在ERG6高表达的重组酵母菌中,甾醇中间体和终产物麦角甾醇的含量均比对照菌高;而在ERG2高表达的酵母菌株中,无论甾醇中间体,还是麦角甾醇的含量均明显降低。ERG6和ERG2共表达重组菌株YS58(pPERG6-2)的麦角甾醇含量是对照菌株YS58(YEp352)的1.41倍,是ERG2单独高表达菌株YS58(pPERG2)的1.92倍,是ERG6单独高表达菌株YS58(pPERG6)的1.12倍。【结论】本研究首次证明甾醇C-24甲基转移酶催化的反应是酿酒酵母麦角甾醇合成代谢途径中的一个重要的限速步骤,该酶活性提高不但补偿了ERG2高表达对甾醇合成的负效应,而且使麦角甾醇含量进一步提高,为构建麦角甾醇高产酵母工程菌株提供了实验依据。