Cloning and characterization of a gene complementing the mutation of an ethanol-sensitive mutant of sake yeast

Ethanol-sensitive mutants (esl to es10) were isolated from sake yeast, Saccharomyces cerevisiae SY-32. These mutants were unable to grow at 7% ethanol at which the wild type strain SY-32 does grow. The mutants had a variety of fermentation rates and viabilities in the presence of ethanol. The gene ERG6, complementing the ethanol-sensitive mutation of es5, was cloned from an SY-32 gene library. ERG6 encodes S-adenosylmethionine: delta 24-sterol-C-methyltransferase (EC 2.1.1.41) in the ergosterol synthetic pathway. Mutant es5 had a reduced ability to synthesize ergosterol. An erg6 disruptant was also ethanol-sensitive. These results suggested that ERG6 plays an important role in the ethanol tolerance of S. cerevisiae.     

ESR determination of membrane order parameter in yeast sterol mutants.

ESR investigations designed to determine membrane order parameter in sterol mutants of Saccharomyces cerevisiae were conducted using the membrane probe, 5-doxyl stearic acid. These mutants are blocked in the ergosterol biosynthetic pathway and thus do not synthesize ergosterol, the end product sterol. They do not require exogenous ergosterol for growth and, therefore, incorporate ergosterol biosynthetic intermediates in their membrane. Increasing order parameter is reflective of an increase in membrane rigidity. Single mutants involving B-ring delta 8 leads to delta 7 isomerization (erg 2) and C-24 methylation (erg 6) showed greater membrane rigidity than wild-type during exponential growth. A double mutant containing both lesions (erg 6/2) showed an even greater degree of membrane rigidity. During stationary phase the order of decreasing membrane rigidity was erg 6 greater than erg 6/2 greater than erg 2 = wild-type. The increased membrane order parameter was attributed to the presence of substituted sterols rather than increased sterol content or altered fatty acid synthesis.     

The yeast gene ERG6 is required for normal membrane function but is not essential for biosynthesis of the cell-cycle-sparking sterol.

In Saccharomyces cerevisiae, methylation of the principal membrane sterol at C-24 produces the C-28 methyl group specific to ergosterol and represents one of the few structural differences between ergosterol and cholesterol. C-28 in S. cerevisiae has been suggested to be essential for the sparking function (W. J. Pinto and W. R. Nes, J. Biol. Chem. 258:4472-4476, 1983), a cell cycle event that may be required to enter G1 (C. Dahl, H.-P. Biemann, and J. Dahl, Proc. Natl. Acad. Sci. USA 84:4012-4016, 1987). The sterol biosynthetic pathway in S. cerevisiae was genetically altered to assess the functional role of the C-28 methyl group of ergosterol. ERG6, the putative structural gene for S-adenosylmethionine: delta 24-methyltransferase, which catalyzes C-24 methylation, was cloned, and haploid strains containing erg6 null alleles (erg6 delta 1 and erg6 delta ::LEU2) were generated. Although erg6 delta cells are unable to methylate ergosterol precursors at C-24, they exhibit normal vegatative growth, suggesting that C-28 sterols are not essential in S. cerevisiae. However, erg6 delta cells exhibit pleiotropic phenotypes that include defective conjugation, hypersensitivity to cycloheximide, resistance to nystatin, a severely diminished capacity for genetic transformation, and defective tryptophan uptake. These phenotypes reflect the role of ergosterol as a regulator of membrane permeability and fluidity. Genetic mapping experiments revealed that ERG6 is located on chromosome XIII, tightly linked to sec59.     

Specific sterols required for the internalization step of endocytosis in yeast

Sterols are major components of the plasma membrane, but their functions in this membrane are not well understood. We isolated a mutant defective in the internalization step of endocytosis in a gene (ERG2) encoding a C-8 sterol isomerase that acts in the late part of the ergosterol biosynthetic pathway. In the absence of Erg2p, yeast cells accumulate sterols structurally different from ergosterol, which is the major sterol in wild-type yeast. To investigate the structural requirements of ergosterol for endocytosis in more detail, several erg mutants (erg2Delta, erg6Delta, and erg2Deltaerg6Delta) were made. Analysis of fluid phase and receptor-mediated endocytosis indicates that changes in the sterol composition lead to a defect in the internalization step. Vesicle formation and fusion along the secretory pathway were not strongly affected in the ergDelta mutants. The severity of the endocytic defect correlates with changes in sterol structure and with the abundance of specific sterols in the ergDelta mutants. Desaturation of the B ring of the sterol molecules is important for the internalization step. A single desaturation at C-8,9 was not sufficient to support internalization at 37 degrees C whereas two double bonds, either at C-5,6 and C-7,8 or at C-5,6 and C-8,9, allowed internalization.     

A specific structural requirement for ergosterol in long-chain fatty acid synthesis mutants important for maintaining raft domains in yeast

Fungal sphingolipids contain ceramide with a very-long-chain fatty acid (C26). To investigate the physiological significance of the C26-substitution on this lipid, we performed a screen for mutants that are synthetically lethal with ELO3. Elo3p is a component of the ER-associated fatty acid elongase and is required for the final elongation cycle to produce C26 from C22/C24 fatty acids. elo3delta mutant cells thus contain C22/C24- instead of the natural C26-substituted ceramide. We now report that under these conditions, an otherwise nonessential, but also fungal-specific, structural modification of the major sterol of yeast, ergosterol, becomes essential, because mutations in ELO3 are synthetically lethal with mutations in ERG6. Erg6p catalyzes the methylation of carbon atom 24 in the aliphatic side chain of sterol. The lethality of an elo3delta erg6delta double mutant is rescued by supplementation with ergosterol but not with cholesterol, indicating a vital structural requirement for the ergosterol-specific methyl group. To characterize this structural requirement in more detail, we generated a strain that is temperature sensitive for the function of Erg6p in an elo3delta mutant background. Examination of raft association of the GPI-anchored Gas1p and plasma membrane ATPase, Pma1p, in the conditional elo3delta erg6(ts) double mutant, revealed a specific defect of the mutant to maintain raft association of preexisting Pma1p. Interestingly, in an elo3delta mutant at 37 degrees C, newly synthesized Pma1p failed to enter raft domains early in the biosynthetic pathway, and upon arrival at the plasma membrane was rerouted to the vacuole for degradation. These observations indicate that the C26 fatty acid substitution on lipids is important for establishing raft association of Pma1p and stabilizing the protein at the cell surface. Analysis of raft lipids in the conditional mutant strain revealed a selective enrichment of ergosterol in detergent-resistant membrane domains, indicating that specific structural determinants on both sterols and sphingolipids are required for their association into raft domains.     

Flux of sterol intermediates in a yeast strain deleted of the lanosterol C-14 demethylase Erg11p

Lanosterol C-14 demethylase Erg11p of the yeast Saccharomyces cerevisiae catalyzes the enzymatic step following formation of lanosterol by the lanosterol synthase Erg7p in lipid particles (LP). Localization experiments employing microscopic inspection and cell fractionation revealed that Erg11p in contrast to Erg7p is associated with the endoplasmic reticulum (ER). An erg11Delta mutation in erg3Delta background, which is required to circumvent lethality of the erg11 defect, did not only change the sterol pattern but also the sterol distribution within the cell. Whereas in wild type the plasma membrane was highly enriched in ergosterol and LP harbored large amounts of sterol precursors in the form of steryl esters, sterol intermediates were more or less evenly distributed among organelles of erg11Delta erg3Delta. This distribution is not result of the erg3Delta background, because in the erg3Delta strain the major intermediate formed, ergosta-7,22-dienol, is also highly enriched in the plasma membrane similar to ergosterol in wild type. These results indicate that (i) exit of lanosterol from LP occurs independently of functional Erg11p, (ii) random supply of sterol intermediates to all organelles of erg11Delta erg3Delta appears to compensate for the lack of ergosterol in this mutant, and (iii) preferential sorting of ergosterol in wild type, but also of ergosta-7,22-dienol in erg3Delta, supplies sterol to the plasma membrane.     

Implications of sterol structure for membrane lipid composition, fluidity and phospholipid asymmetry in Saccharomyces cerevisiae

Sterols are essential components of the plasma membrane in eukaryotic cells. Nystatin-resistant erg mutants were used in the present study to investigate the in vitro effects of altered sterol structure on membrane lipid composition, fluidity, and asymmetry of phospholipids. Quantitative analyses of the wild type and mutants erg2, erg3 and erg6 revealed that mutants have lower sterol (free)-to-phospholipid molar ratios than the wild type. Phosphatidylcholine content was decreased in erg2 and erg3 mutants; however, it was increased in erg6 strains as compared to normals. Phosphatidylserine content was increased in the erg6 mutant only. Fluorescence anisotropy decreased with temperature in both probes, and was lower for mutants than for the wild type, suggesting an increased freedom in rotational movement due to decreased membrane order. Investigation of changes in the aminophospholipid transbilayer distribution using two chemical probes, trinitrobenzene sulfonic acid and fluorescamine, revealed that the amounts of phosphatidylethanolamine derivatized by these probes were quite similar in both the wild type and various erg strains. The present findings suggest that adaptive responses in yeast cells with altered sterol structure are possibly manifested through changes in membrane lipid composition and fluidity, and not through transbilayer rearrangement of aminophospholipids.     

Yeast resistance to polyene antibiotics. VI. Isolation and biochemical analysis of strains of Saccharomyces cerevisiae yeasts with mutations in the 2 nystatin-resistance genes

The comparative analysis of sterol content in the yeast Saccharomyces cerevisiae strains singly or doubly defective in nystatin resistance genes was carried out. The strains with two mutations in NYS genes were shown to accumulate the sterol mixture, similar to that of the parental singly defective mutant. This type of gene interaction allows to define the main biochemical order of reaction in ergosterol synthesis: methylation in C24 (NYS1), delta 8----delta 7 isomerization (NYS2), C5 (6) and C22 (23) desaturation (NYS3 and NYSX).     

Biosynthesis of cholesterol in the yeast mutant erg6

A mutant (erg6) of Saccharomyces cerevisiae defective in S-adenosylmethionine: delta 24-sterol-C-methyl transferase (EC2.1.1.41) which normally produces cholesta-5,7,24-trienol and cholesta-5,7,22,24-tetraenol as the major sterols (total 4,4-desmethyl sterol content-8.3 fg/cell) was shown to synthesize trace levels of cholesterol (0.08 fg/cell). The identity of cholesterol was established by co-chromatography in TLC, GLC and HPLC with an authentic sample, mass spectroscopy and after an incubation with [1-14C]acetate by isotopic dilution and recrystallization of the radiochemically purified material to constant specific activity.     

Sterol level in Saccharomyces cerevisiae mutants with altered ergosterol biosynthesis

The sterol content in Saccharomyces cerevisiae mutants defective in the synthesis of cyclic ergosterol precursors has been studied. It was found that strains with mutational blocks involving the stages of zymosterol side chain methylation at C24 and delta 8----delta 7 isomerization accumulated twice more sterols as compared to parent strains. Regulation of the ergosterol biosynthesis is discussed.     

Effects of the hypocholesteremic agent trifluperidol on the sterol, steryl ester, and fatty acid metabolism of Saccharomyces cerevisiae.

Trifluperidol (TFP), at a concentration of 100 muM, inhibited the 24-h growth of Saccharomyces cerevisiae by about 30%. Effects on lipid metabolism were investigated by monitoring the incorporation of [1-14C]sodium acetate into various lipid fractions after 4 and 24 h of growth in the presence of several concentrations of TFP. Although little effect was noted on the amount of free sterols, 24-h incorporation of label into steryl esters was increased two- to fourfold by 100 muM TFP. Major sterol components of the steryl ester fraction isolated from an untreated culture were zymosterol (48%) and ergosterol (24%), whereas from the TFP-treated culture delta8,24(28)-ergostadienol (66.6%) and delta8-ergostenol (14.7%) were most abundant. Free sterols present in the highest concentration in the untreated culture were ergosterol (78.2%) and lanosterol (13%); whereas delta8,22-ergostadienol (38.5%), delta8-ergostenol (35.4%), and delta8,24(28)-ergostadienol (25.4%) were the most abundant free sterols obtained from the TFP-treated culture. Thus, the major block in the sterol biosynthetic pathway in yeast appears to be delta8 leads to delta7 isomerization. In these same cultures the relative amounts of C12 and C14 acids isolated from both steryl ester and miscellaneous lipid fractions were increased more than threefold over controls.     

The deficiency of sterol biosynthesis in Saccharomyces cerevisiae affects the synthesis of glycosyl derivatives of dolichyl phosphates

Abstract Mutants deficient in sterol (thermosensitive ergosterol auxotrophs) erg 8, 9, 12 and heme synthesis hem 1, 12 were screened for the level of free dolichol and dolichyl phosphate synthesized in the mevalonate pathway as well as for the activity of dolichyl phosphate-dependent glycosyl transferases. The amount of DolP synthesized via CTP-dependent phosphorylation was the same in mutants and parental strains. However, mannosylation and glucosylation of endogenous dolichyl phosphates in ergosterol mutants was about four times lower compared to parental strains, while the same reactions carried out with exogenous Dol₂₄P reached 80% of the level observed in parental strains indicating that activities of DolPMan and DolPGlc synthases are not the rate-limiting factors. It is postulated that the de novo synthesis of DolP is impaired in the ergosterol mutants. Moreover, a block in the ergosterol branch of the metabolic pathway ( erg 9 ) causes an increase in the de novo synthesis of dolichyl phosphate.     

Yeast mutants deficient in heme biosynthesis and a heme mutant additionally blocked in cyclization of 2,3-oxidosqualene.

Mutants of Saccharomyces cerevisiae were isolated which were blocked in heme biosynthesis and required heme for growth on a nonfermentable carbon source. They were rho+, and grew fermentatively on ergosterol or cholesterol and Tween 80, as a source of oleic acid. Cells grown on ergosterol and Tween 80 lacked cytochromes and catalase which were restored by growth on heme. The mutants comprised five nonoverlapping complementation groups. Tetrad analysis showed that the pleiotropic properties of each of the mutants resulted from a single mutation in one of five unlinked loci (hem1 to hem5) affecting heme biosynthesis. Biochemical studies confirmed that each mutation resulted in loss of a single enzyme activity. hem1 mutants grew on delta-aminolevulinate and lacked delta-aminolevulinate synthase activity, hem2 mutants lacked delta-aminolevulinate dehydratase, and hem3 mutants uroporphyrin I synthase. Mutants in hem1, hem2, and hem3 had an additional requirement for methionine on synthetic medium supplemented with either heme or ergosterol and Tween 80, owing to a lack of sulfite reductase which contains siroheme, a modified uroporphyrin III. Since hem4 and hem5 mutants have sulfite reductase activity under all growth conditions, they are blocked after uroporphyrin III. Cell extracts of a hem4 mutant incubated with delta-aminolevulinate accumulated coproporphyrin III suggesting a block in coproporphyrinogenase, the enzyme which converts coproporphyrinogen III to protoporphyrinogen. Cells and extracts of a hem5 mutant accumulated protoporphyrin IX. Since it was the only mutant that grew on heme but not on protoporphyrin IX, a block in ferrochelatase was suggested for this strain. Mutant strains grown on heme had the sterol composition of wild type cells, whereas without heme only squalene, small amounts of lanosterol, and added sterol was observed. A heme product therefore participates in the transformation of lanosterol to ergosterol. A hem3 mutant was isolated which was also blocked between 2,3-oxidosqualene and lanosterol (erg12). When grown on lanosterol or ergosterol (with Tween 80) it accumulated a compound which was identified as 2,3-oxidosqualene by comparison with the synthetic compound in thin layer and gas-liquid chromatography, and by proton magnetic resonance and mass spectroscopy. Supplementation with heme did not remove the requirement for sterol, but it enabled the mutant to convert lanosterol to ergosterol.     

Inhibition of sterol transmethylation by S-adenosylhomocysteine analogs.

Structural analogs of S-adenosylhomocysteine were tested in vitro for inhibition of the yeast S-adenosylmethionine:delta 24-sterol-C-methyltransferase enzyme. A wide inhibitory range by these compounds was observed, suggesting which structural features of the parent compound are important for binding to the enzyme. No analog tested had inhibitory activity specific only for this enzyme. The most active compound was sinefungin, a metabolite of Streptomyces griseolus, which was also able to inhibit growth of yeast cultures. Sterol extracts of cells grown in the presence of sinefungin revealed a dramatic increase in the levels of zymosterol, the sterol substrate in the transmethylation under study, and a concomitant decrease in the levels of ergosterol. Evidence is presented that sinefungin is transported inside the cell by the same permease as S-adenosylmethionine. We conclude that sinefungin is blocking the in vivo methylation of sterols in yeast. The implications of this finding are discussed.     

Ergosterol is required for targeting of tryptophan permease to the yeast plasma membrane

It was known that the uptake of tryptophan is reduced in the yeast erg6 mutant, which is defective in a late step of ergosterol biosynthesis. Here, we show that this is because the high affinity tryptophan permease Tat2p is not targeted to the plasma membrane. In wild-type cells, the plasma membrane localization of Tat2p is regulated by the external tryptophan concentration. Tat2p is transported from the Golgi apparatus to the vacuole at high tryptophan, and to the plasma membrane at low tryptophan. However, in the erg6 mutant, Tat2p is missorted to the vacuole at low tryptophan. The plasma membrane targeting of Tat2p is dependent on detergent-insoluble membrane domains, suggesting that sterol affects the sorting through the organization of lipid rafts. The erg6 mutation also caused missorting to the multivesicular body pathway in late endosomes. Thus, sterol composition is crucial for protein sorting late in the secretory pathway. Tat2p is subject to polyubiquitination, which acts as a vacuolar-targeting signal, and the inhibition of this process suppresses the Tat2p sorting defects of the erg6 mutant. The sorting mechanisms of Tat2p that depend on both sterol and ubiquitin will be discussed.     

The effect of altered sterol composition on cytochrome oxidase and S-adenosylmethionine: delta 24 sterol methyltransferase enzymes of yeast mitochondria

Arrhenius kinetics of two mitochondrial enzymes, cytochrome oxidase and S-adenosylmethionine: Δ 24 sterol methyltransferase were analyzed in wild-type and sterol mutant strains of yeast. Temperature effects on the enzymes isolated from the ergosterol producing wild-type and nystatin resistant mutants (major sterol Δ⁸(9), 22 ergostadiene-3-β-ol) were compared. Transition temperatures were lower in both mutant strains compared to wild-type. Lipid analysis shows a relationship between sterol content and the temperature dependent transition phases.     

Defective sterol C5-6 desaturation and azole resistance: a new hypothesis for the mode of action of azole antifungals

Two azole resistant isolates of Saccharomyces cerevisiae carried mutations allelic to erg 3 and were blocked to differing degrees at the C5-6 desaturation step of ergosterol biosynthesis. When treated with the sterol 14 alpha-demethylation inhibitor fluconazole the wild-type sensitive strain accumulated lanosterol and 14 alpha-methyl-erogosta-8,24(28)-dien-3 beta, 6 alpha-diol (14-methyl-3,6 diol). The stringent desaturase mutant, A2, accumulated 14 alpha-methyl-8,24(28)-dien-3 beta-ol (14-methyl fecosterol) and lanosterol as the major sterol components when treated with fluconazole. Resistant isolate A3 accumulated 14-methyl-3,6-diol, 14-methyl fecosterol, and lanosterol and was only partially blocked at sterol C5-6 desaturation. We conclude that functional sterol C5-6 desaturase is required for the synthesis of 14-methyl-3,6-diol under conditions of azole inhibition. We present a new hypothesis for the mode of action of azole antifungals based on the inability of 14-methyl-3,6-diol to support growth, and suggest that growth can occur through utilisation of 14-methyl fecosterol, produced by a combination of azole inhibition and defective sterol C5-6 desaturation.     

Isolation and characterization of yeast mutants blocked in mevalonic acid formation

Yeast mutants defective in beta-hydroxy-beta-methylglutaryl-CoA synthase and acetoacetyl-CoA thiolase have been isolated. Mutants impaired in acetoacetyl-CoA thiolase range into two linked complementation units, erg 10 A and erg 10 B. Mutants deficient in beta-hydroxy-beta-methylglutaryl-CoA synthase belong to two unlinked complementation groups, erg 11 and erg 13. In strictly anaerobic growth conditions, mutants impaired in beta-hydroxy-beta-methylglutaryl-CoA synthase require mevalonic acid in addition to sterol and oleic acid, pointing out the role of mevalonic acid in other physiological function than ergosterol precursor. Growth of mutants impaired in acetoacetyl-CoA thiolase cannot be recovered by mevalonic acid supplementation, suggesting a role of acetoacetyl-CoA or thiolase not linked to sterol pathway.     

Sterol composition of yeast organelle membranes and subcellular distribution of enzymes involved in sterol metabolism.

Organelles of the yeast Saccharomyces cerevisiae were isolated and analyzed for sterol composition and the activity of three enzymes involved in sterol metabolism. The plasma membrane and secretory vesicles, the fractions with the highest sterol contents, contain ergosterol as the major sterol. In other subcellular membranes, which exhibit lower sterol contents, intermediates of the sterol biosynthetic pathway were found at higher percentages. Lipid particles contain, in addition to ergosterol, large amounts of zymosterol, fecosterol, and episterol. These sterols are present esterified with long-chain fatty acids in this subcellular compartment, which also harbors practically all of the triacylglycerols present in the cell but very little phospholipids and proteins. Sterol delta 24-methyltransferase, an enzyme that catalyzes one of the late steps in sterol biosynthesis, was localized almost exclusively in lipid particles. Steryl ester formation is a microsomal process, whereas steryl ester hydrolysis occurs in the plasma membrane and in secretory vesicles. The fact that synthesis, storage, and hydrolysis of steryl esters occur in different subcellular compartments gives rise to the view that ergosteryl esters of lipid particles might serve as intermediates for the supply of ergosterol from internal membranes to the plasma membrane.     

Sterols of Saccharomyces cerevisiae erg6 Knockout Mutant Expressing the Pneumocystis carinii S‐Adenosylmethionine:Sterol C‐24 Methyltransferase

The AIDS‐associated lung pathogen Pneumocystis is classified as a fungus although Pneumocystis has several distinct features such as the absence of ergosterol, the major sterol of most fungi. The Pneumocystis carinii S‐adenosylmethionine:sterol C24‐methyltransferase (SAM:SMT) enzyme, coded by the erg6 gene, transfers either one or two methyl groups to the C‐24 position of the sterol side chain producing both C₂₈ and C₂₉ 24‐alkylsterols in approximately the same proportions, whereas most fungal SAM:SMT transfer only one methyl group to the side chain. The sterol compositions of wild‐type Sacchromyces cerevisiae, the erg6 knockout mutant (Δerg6), and Δerg6 expressing the P. carinii or the S. cerevisiae erg6 gene were analyzed by a variety of chromatographic and spectroscopic procedures to examine functional complementation in the yeast expression system. Detailed sterol analyses were obtained using high performance liquid chromatography and proton nuclear magnetic resonance spectroscopy (¹H‐NMR). The P. carinii SAM:SMT in the Δerg6 restored its ability to produce the C₂₈ sterol ergosterol as the major sterol, and also resulted in low levels of C₂₉ sterols. This indicates that while the P. carinii SAM:SMT in the yeast Δerg6 cells was able to transfer a second methyl group to the side chain, the action of Δ²⁴⁽²⁸⁾‐sterol reductase (coded by the erg4 gene) in the yeast cells prevented the formation and accumulation of as many C₂₉ sterols as that found in P. carinii.