Evidence from cell-free systems for differences in the sterol biosynthetic pathway of Rhizoctonia solani and Phytophthora cinnamomi.

Cell-free preparations of both Rhizoctonia solani, a sterol-synthesizing fungus, and Phytophthora cinnamomi, a non-sterol-synthesizing fungus, incubated in the presence of [2(-14)C]mevalonate and iodacetamide, converted the mevalonate into labelled mevalonate 5-phosphate, mevalonate 5-pyrophosphate and isopentenyl pyrophosphate. In the absence of iodoacetamide, but under anaerobic conditions, the same preparations converted the mevalonate into labelled geraniol, farnesol and squalene, the first two compounds presumably as their pyrophosphates. When cell-free preparations of both organisms were incubated aerobically in the presence of [1(-14)C]isopentenyl pyrophosphate, only labelled geraniol, farnesol and squalene were recovered from the P. cinnamomi reaction mixture, whereas labelled geraniol, farnesol, squalene, squalene epoxide, lanosterol and ergosterol were present in the R. solani reaction mixture. When these same preparations were incubated in the presence of 14C-labelled squalene, labelled squalene epoxide, lanosterol and ergosterol were recovered from the R. solani reaction mixture. In contrast, the P. cinnamomi preparation was unable to convert the squalene into products further along the sterol pathway; instead, a portion of the labelled squalene was converted into water-soluble products, indicating the possible existence of a squalene-degradation process in this organism. It appears that the block in the sterol biosynthetic pathway of P. cinnamomi occurs at the level of squalene epoxidation.     

Sterols in species of Pythium

Summary Analysis by gas chromatography revealed the presence of small amounts of squalene, but not lanosterol nor ergosterol in Pythium paroecandrum, P. ultimum, P. graminicola, and P. arrhenomonas. However, when acetate-¹⁴C was used as a precursor for sterols, even squalene was not found in P. graminicola. The deficiency in the sterol synthesizing mechanism may therefore be at or before the squalene forming step. Both squalene and ergosterol were present in the mycelium of Rhizoctonia solani, as shown by both gas chromatography and by the incorporation of acetate-¹⁴C into ergosterol. The absence of ergosterol in Pythium and its presence in Rhizoctonia is consistant with the resistance to the antibiotic filipin of Pythium species and the sensitivity of R. solani.     

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.     

Sterol biosynthesis via cycloartenol and other biochemical features related to photosynthetic phyla in the amoeba Naegleria lovaniensis and Naegleria gruberi

The sterols and sterol precursors of two amoebae of the genus Naegleria, Naegleria lovaniensis and Naegleria gruberi were investigated. Cycloartenol, the sterol precursor in photosynthetic organisms, is present in both amoebae. In N. lovaniesis, it is accompanied by lanosterol and parkeol, as well as by the 24,25-dihydro derivatives of these triterpenes. One of the most striking features of these amoebae is the accumulation of 4 alpha-methylsterols which are present in similar amounts as those of 4,4-desmethylsterols (3-5 mg/g, dry weight). 4 alpha-Methylergosta-7,22-dienol was identified as a new compound. Ergosterol was the major 4,4-desmethylsterol, accompanied by small amounts of C27 and other C28 sterols. Treatment of N. lovaniensis with fenpropimorph modified the sterol pattern of this amoeba and inhibited its growth. This fungicide, known to inhibit steps of sterol biosynthesis in fungi and plants, induced the disappearance of 4 alpha-methyl-delta 7-sterols and the appearance of the unusual delta 6,8,22-ergostatrienol as in A. polyphaga. These results might be explained by a partial inhibition of the delta 8----delta 7 isomerase, the small amounts of delta 7-sterols formed being converted into ergosterol which is still present in fenpropimorph-exposed cells. De novo sterol biosynthesis in N. lovaniensis was shown by incorporation of [1-14C]acetate into sterols and sterol precursors, especially cycloartenol. Lanosterol and parkeol were not significantly labelled. Furthermore, [3-3H]squalene epoxide was efficiently cyclized by a cell-free system of this amoeba into cycloartenol, and again no significant radioactivity was detected in lanosterol and parkeol. This shows that cycloartenol, the sterol precursor in plants and algae, is also the sterol precursor in Naegleria species, and that these amoebae, like A. polyphaga, are related by some biosynthetic pathways to photosynthetic phyla. Lanosterol, the sterol precursor in non-photosynthetic phyla (animal and fungi) and parkeol are more likely dead-ends of this biosynthetic pathway. The peculiar phylogenetic position of these protozoa was further emphasized by the action of indole acetic acid and other auxine-like compounds on their growth. Indeed amoebic growth was enhanced in the presence of these higher plant growth hormones. The differences in the sterol composition of the protozoa we have hitherto examined is related to their sensitivity toward polyene macrolide antibiotics.(ABSTRACT TRUNCATED AT 400 WORDS)     

Combined overexpression of genes of the ergosterol biosynthetic pathway leads to accumulation of sterols in Saccharomyces cerevisiae

Genes of the post-squalene ergosterol biosynthetic pathway in Saccharomyces cerevisiae have been overexpressed in a systematic approach with the aim to construct yeast strains that produce high amounts of sterols from a squalene-accumulating strain. This strain had previously been deregulated by overexpressing a truncated HMG-CoA reductase (tHMG1) in the main bottleneck of the early ergosterol pathway. The overexpression of the gene ERG1 (squalene epoxidase) induced a significant decrease of the direct substrate squalene, a high increase of lanosterol, and a small increase of later sterols. The overexpression of the ERG11 gene encoding the sterol-14alpha-demethylase resulted in a decrease of lanosterol and an increase of downstream sterols. When these two genes were simultaneously overexpressed, later sterols from zymosterol to ergosterol accumulated and the content of squalene was decreased about three-fold, indicating that these steps had limited the transformation of squalene into sterols. The total sterol content in this strain was three-fold higher than in a wild-type strain.     

Effect of sub-inhibitory concentration of chlorhexidine on lipid and sterol composition of shape Candida albicans

The effect of a sub-inhibitory concentration of chlorhexidine on lipid and sterol composition of Candida albicans was investigated. The total lipid content of this yeast grown in the presence of chlorhexidine was reduced whilst the total sterol content was increased compared with control-grown cells. Lipids and sterol analyses of this yeast grown in the presence and absence of chlorhexidine are presented. Chlorhexidine-grown yeast had a higher level of phosphatidylethanolamine, phosphatidylcholine and monogalactosyldiacylglycerol. Lower proportions of phosphatidylinositol plus phosphatidylserine, phosphatidic acid and cardiolipin were found in C. albicans grown in the presence of the drug when compared with control-grown yeast. The major fatty acids in control-grown cells were C16 and C18. Drug grown-cells had higher proportions of palmitic acid (16 : 0) and stearic acid (18 : 0), but lower proportions of palmitoleic acid (16 : 1) and oleic acid (18 : 1). Chlorhexidine also decreased the unsaturated-to-saturated fatty acid ratio, while the C16/C18 ratios increased compared to control-grown cells. Differences in the fatty acid composition of major phospholipids and neutral lipids between drug and control-grown yeast were also detected. Sterol analysis of control-grown cells showed that the major sterol present was ergosterol (55.4% wt). A significant increase in ergosterol and obtusifoliol was observed in chlorhexidine-treated cells and a significant decrease in squalene and lanosterol. Our results suggested that chlorhexidine affected the lipid and sterol composition of C. albicans. This revised version was published online in August 2006 with corrections to the Cover Date.     

Effects of thiamine and pyridoxine on the content and composition of sterols in Saccharomyces carlsbergensis 4228

The level of sterols in $\text{S. carlsbergensis}$ 4228 cells grown aerobically on a synthetic medium fortified with thiamine was significantly low compared with that in the control cells. The levels of free and esterified sterols in the thiamine-cells were 60% and 10% of the corresponding sterol levels in the control cells, respectively. Analysis by gas-liquid chromatography of non-saponifiable lipids extracted from the cells revealed that the amounts of squalene, lanosterol and two unidentified sterols were higher than those in the control cells and that ergosterol and zymosterol, major sterols in the control cells, were not present. These effects of thiamine on the content and composition of sterols were abolished by the addition of pyridoxine to the medium.     

Phytosterol biosynthesis pathway in Mortierella alpina

The Zygomycetes fungus Mortierella alpina was cultured to growth arrest to assess the phytosterol biosynthesis pathway in a less-advanced fungus. The mycelium was found to produce 13 sterols, but no ergosterol. The sterol fractions were purified to homogeneity by HPLC and their identifies determined by a combination of GC-MS and 1H NMR spectroscopy. The principal sterol of the mycelium was cholesta-5, 24-dienol (desmosterol) (83%), with lesser amounts of 24beta-methyl-cholesta-5,25(27)-dienol (codisterol) (2%), 24-methyldesmosterol (6%), 24(28)-methylene cholesterol (3%) and lanosterol (3%) and several other minor compounds (3%). The total sterol accounted for approximately 0.07% of the mycelial dry wt. Mycelium fed methionine-methyl-2H3 for 6 days, generated 3 2H-24-methyl(ene) sterols, [C28-2H2]24(28)-methylenecholesterol, [C28-2H3]24-methylcholesta-5,24-dienol and [C28-2H3]24beta-methyl-cholesta-5,25(27)-dienol. The formation of the 24-methyl sterols seems to be catalyzed by the direct methylation of a common Delta24-acceptor sterol thereby bypassing the intermediacy of an isomerization step for rearrangement of the Delta24(28)-bond to Delta25(25)-position as operates in Ascomycetes fungi and all plants.     

Sterol biosynthesis by a prokaryote: first in vitro identification of the genes encoding squalene epoxidase and lanosterol synthase from Methylococcus capsulatus

Sterol biosynthesis by prokaryotic organisms is very rare. Squalene epoxidase and lanosterol synthase are prerequisite to cyclic sterol biosynthesis. These two enzymes, from the methanotrophic bacterium Methylococcus capsulatus, were functionally expressed in Escherichia coli. Structural analyses of the enzymatic products indicated that the reactions proceeded in a complete regio- and stereospecific fashion to afford (3S)-2,3-oxidosqualene from squalene and lanosterol from (3S)-2,3-oxidosqualene, in full accordance with those of eukaryotes. However, our result obtained with the putative lanosterol synthase was inconsistent with a previous report that the prokaryote accepts both (3R)- and (3S)-2,3-oxidosqualenes to afford 3-epi-lanosterol and lanosterol, respectively. This is the first report demonstrating the existence of the genes encoding squalene epoxidase and lanosterol synthase in prokaryotes by establishing the enzyme activities. The evolutionary aspect of prokaryotic squalene epoxidase and lanosterol synthase is discussed.     

Multiple functions for sterols in Saccharomyces cerevisiae

Analyses with a yeast sterol auxotroph indicated that there are at least four different levels of function for sterol which have been designated sparking, critical domain, domain and bulk. Growth of yeast sterol auxotrophs on cholestanol is precluded unless minute amounts of ergosterol are available. We have designated this phenomenon the sparking of growth, in which cholestanol satisfies an overall membrane sterol requirement and ergosterol fulfills a high specificity sparking function. The critical domain role for sterol is observed under conditions of lanosterol supplementation where low levels of ergosterol (10-times those necessary for sparking on cholestanol) are required for growth. The sterol functions designated domain and bulk are illustrated by assessing cellular free sterol levels and plasma membrane properties of a sterol auxotroph after growth on different concentrations of exogenously supplied sterol. Plasma membranes isolated from auxotrophs grown on domain or bulk levels of sterol underwent no lipid thermotropic transitions, while plasma membranes from cells grown on critical domain levels of sterol underwent a lipid thermotropic transition, when analyzed by steady-state fluorescence anisotropy.     

Composition of sterols from arthrospores and mycelia of the fungus Mucor hiemalis

Sterol composition of the arthrospores and mycelium of the fungus Mucor hiemalis 1156 was studied by the method of chromatography-mass spectrometry. Along with ergosterol, the major sterol of the culture studied, ten minor sterol were identified, which were either precursors or products of ergosterol degradation. The content of individual sterols differed substantially in arthrospores and mycelium, which represent different stages of ontogenetic development of the fungus. In arthrospores, the content of ergosterol was lower than in mycelium (55.9 and 78%, respectively). Among the precursors of ergosterol, methylated sterols predominated in arthrospores (24.1% versus 11.6% in mycelium). Eburicol and 4,4-dimethylfecosterol were the major methylated sterols of arthrospores (10.6 and 8.1%, respectively). In addition, two uncommon and extremely rare sterols, 1-dihydro-dehydroneoergosterol and dehydroneoergosterol, were identified (for the first time in M. hiemalis). These substances, containing a complex system of conjugated double bonds in their A and B rings, are the products of ergosterol degradation. The data on sterol composition are discussed in terms of their morphogenetic implication.     

The manipulation of cellular cytochrome and lipid composition in a haem mutant of Saccharomyces cerevisiae.

1. The ole-3 mutant of Saccharomyces cerevisiae has an early lesion in the pathway of porphyrin biosynthesis. 2. This results in the loss of all haem-containing enzymes, including the mitochondrial cytochromes, and prevents the synthesis of components whose formation requires haem-containing enzymes, including unsaturated fatty acids, ergosterol and methionine. 3. The pleiotropic effects of the primary lesion are reversed by growing mutant ole-3 aerobically in the presence of intermediates of the porphyrin-biosynthetic pathway, and the present work reports the degree of manipulation of lipid and respiratory-cytochrome composition. 4. Supplements of delta-aminolaevulinate in the range 0.5--500 mg/l result in a progressive increase in the cellular content of unsaturated fatty acids and respiratory cytochromes, cause the replacement of lanosterol and squalene by ergosterol, and an increase in total sterol content. 5. Haematoporphyrin and protoporphyrin IX have similar but less extensive effects on cellular composition, whereas haematin allows unsaturated fatty acid synthesis and some sterol synthesis, but has no effect on the formation of respiratory cytochromes. 6. These results suggest that growth of the organism in the presence of defined amounts of delta-aminolaevulinate will be useful in the investigation of the role of lipids and cytochromes in the function and assembly of mitochondrial membranes.     

Identification of 24-methylene-24,25-dihydrolanosterol as a precursor of ergosterol in the yeasts Schizosaccharomyces pombe and Schizosaccharomyces octosporus

Abstract Study of the plasma membrane sterol composition in the yeasts Schizosaccharomyces pombe and Schizosaccharomyces octosporus revealed the presence of ergosterol, lanosterol, dehydroergosterol, fecosterol, episterol and 24-methylene-24,25-dihydrolanosterol (eburicol), a C-31 derivative. The growth of both yeasts in the presence of ketoconazole led to a decrease by 85% of the ergosterol content while the levels of lanosterol and eburicol increased. This suggests that in the biosynthetic pathway of ergosterol in Schizosaccharomyces species, the transmethylation process on the C-24 may occur directly on lanosterol and not only on zymosterol. On the other hand, it cannot be excluded that in the genus Schizosaccharomyces two routes exist from lanosterol to ergosterol: the classical one via a direct C-14, C-4 demethylation of lanosterol and the second one via the formation of a C-31 derivative followed by demethylations.     

Sterol biosynthesis in the free-living nematode Panagrellus redivivus

The fate of the known sterol precursor squalene 2,3-oxide was investigated in the free-living nematode Panagrellus redivivus. The nematodes were cultured axenically in the presence of [4-(3)H]squalene 2,3-oxide. Radioactivity was found in the total lipids of the isolated nematodes. Essentially all of the radioactivity encountered in the total lipids was found in the non-saponifiable fraction. The components present in the non-saponifiable fraction were separated and isolated by t.l.c. Three labelled components were identified by a combination of t.l.c., g.l.c. and mass spectroscopy. It is established that P. redivivus has the capacity for biosynthesis of lanosterol. No labelled C(27) sterols could be detected.     

Sterol Composition of the Arthrospores and Mycelium of the Fungus Mucor hiemalis

Sterol composition of the arthrospores and mycelium of the fungus Mucor hiemalis 1156 was studied by the method of chromatography–mass spectrometry. Along with ergosterol, the major sterol of the culture studied, ten minor sterols were identified, which were either precursors or products of ergosterol degradation. The content of individual sterols differed substantially in arthrospores and mycelium, which represent different stages of ontogenetic development of the fungus. In arthrospores, the content of ergosterol was lower than in mycelium (55.9 and 78.0%, respectively). Among the precursors of ergosterol, methylated sterols predominated in arthrospores (24.1% versus 11.6% in mycelium). Eburicol and 4,4-dimethylfecosterol were the major methylated sterols of arthrospores (10.6 and 8.1%, respectively). In addition, two uncommon and extremely rare sterols, 1-dihydro-dehydroneoergosterol and dehydroneoergosterol, were identified (for the first time in M. hiemalis). These substances, containing a complex system of conjugated double bonds in their A and B rings, are the products of ergosterol degradation. The data on sterol composition are discussed in terms of their morphogenetic implication.     

Metabolism of intracerebrally injected mevalonate in brain of suckling and young adult rats

We have investigated the in vivo metabolism via sterol and nonsterol pathways of intracerebrally injected mevalonate (MVA) in brains from suckling (10-day-old) and young adult (60-day-old) rats. Results of our study indicated that increasing the amounts of MVA injected increased MVA incorporation into all the lipid fractions examined. The incorporation of MVA into nonsaponiable lipids (NSF) and digitonin precipitable sterols (DPS) was similar in brains from adult and suckling rats. In brain tissue from both suckling and young adult rats the synthesis of dolichol from MVA varied with the amounts of MVA injected. Significant amounts of MVA were recovered in phosphorylated and free polyprenols (farnesol and geraniol) in brain tissue from rats of both ages. Also in both groups of animals, the amounts of MVA incorporated in phosphorylated and free farnesol were higher than the amounts recovered in either, phosphorylated or free geraniol. The amounts of MVA incorporated into the prenoic/fatty acid fraction by brain tissue from both suckling and young adult rats were less than 1% of the total MVA incorporated (nonsaponifiable and saponifiable lipids). Incorporation of MVA into the prenoic/fatty acid fraction by brain tissue was higher in suckling than in young adult rats. These data indicate that the brain tissue from suckling and young adult rats do not differ in their capacity to metabolize MVA into squalene and sterols and that in brain, metabolism of MVA by a shunt pathway is minimal. This suggests that in vivo regulation of cholesterol synthesis during brain development must occur at a step(s) in the sterol synthetic pathway prior to mevalonate, and that metabolism of mevalonate by shunt pathway did not play a role in the developmental regulation of brain sterol synthesis. The data also suggest that in both groups of animals the synthesis of squalene by synthetase may in part control brain sterol synthesis and the synthesis of dolichol is regulated by MVA concentration in the tissue.     

Microsomal synthesis of cholesterol from squalene, Lanosterol, and desmosterol. Evidence for the presence of two noncatalytic activator proteins in the 105,000 g supernatant fraction from brain, heart, and kidney

The biosynthesis of C₂₇ sterols (used as a generic term for 3 β-hydroxysterols containing 27 carbon atoms) from squalene and lanosterol, of cholesterol from desmosterol, and of lanosterol from squalene by microsomal fractions from adult rat heart, kidney, and brain was investigated. These conversions required the presence of 105,000g supernatant fraction. Heat treatment of the supernatant fractions resulted in a significant loss of their capacity to stimulate the conversion of squalene to sterols, but the capacity to stimulate conversion of lanosterol to C₂₇ sterols and desmosterol to cholesterol was unaffected. The stimulatory activity (for the conversion of all three substrates) of both the heated and unheated supernatant fractions was lost on treatment with trypsin. Thus the soluble fraction appears to contribute at least two essential protein components for the overall conversion of squalene to cholesterol; one a heat labile protein, which functions in the squalene to lanosterol sequence, and the other a heat-stable protein, which is operative in the pathway between lanosterol and cholesterol. Hepatic supernatant factors required for cholesterol synthesis by liver microsomal enzymes function with heart, kidney, and brain microsomal enzymes in stimulating sterol synthesis from squalene and sterol precursors. Moreover, heart, kidney, and brain supernatant fractions prepared in 100 mm phosphate buffer stimulated cholesterol synthesis from squalene and other sterol precursors by liver microsomes. The supernatant fractions of the extrahepatic tissues prepared in 20 mm phosphate buffer lacked the ability to stimulate the biosynthesis of lanosterol from squalene by liver microsomes but were able to stimulate the conversion of lanosterol to C₂₇ sterols or conversion of desmosterol to cholesterol. These findings indicate that the heat-stable protein factor present in the supernatant fractions from extrahepatic tissues is perhaps identical to that in liver, but that the heat-labile factor in extrahepatic tissues, which catalyzes the cyclization of squalene to lanosterol, differs in some respect from that in liver.     

Sterol biosynthesis in the echinoderm Asterias rubens.

1. [2(-14)C]Mevalonic acid injected into the echinoderm Asterias rubens (Class Asteroidea) was effectively incorporated into the non-saponifiable lipid. 2. The most extensively labelled compounds were squalene and the 4,4-dimethyl sterols with much lower incorporations into the 4alpha-monomethyl and 4-demethyl sterol fractions. 3. Labelled compounds identified were squalene, lanosterol, 4,4-dimethyl-5alpha-cholesta-8,24-dien-3beta-ol and 4alpha-methyl-5alpha-cholest-7-en-3beta-ol; these are all intermediates in sterol biosynthesis. 4. The major sterol in A. rubens, 5alpha-cholest-7-en-3beta-ol, was also labelled showing that this echinoderm is capable of sterol biosynthesis de novo. 5. No evidence was obtained for the incorporation of [2(-14)C]mevalonic acid into the C28 and C29 components of the 4-demethyl sterols or 9beta,19-cyclopropane sterols found in A. rubens and it is assumed that these sterols are of dietary origin. 6. Another starfish Henricia sanguinolenta also incorporated [2(-14)C]mevalonic acid into squalene and lanosterol. 7. Various isolated tissues of A. rubens were all capable of incorporation of [2(-14)C]mevalonic acid into the nonsaponifiable lipid. With the body-wall and stomach tissues radioactivity accumulated in squalene and the 4,4-dimethyl sterols, but with the gonads and pyloric caecae there was a more efficient incorporation of radioactivity into the 4-demethyl sterols, principally 5alpha-cholest-7-en-3beta-ol.     

Quantification of plasma membrane ergosterol of Saccharomyces cerevisiae by direct-injection atmospheric pressure chemical ionization/tandem mass spectrometry

A method for the quantification of ergosterol by atmospheric pressure chemical ionization (APcI) mass spectrometry with direct injection is described. Ergosterol and squalene were ionizable with methanol as the carrier solvent. Using positive-mode tandem mass spectrometry (MS/MS), ergosterol could be identified unambiguously without interference from structurally related compounds such as lanosterol, cholesterol, and squalene. Molecular ions of ergosterol, lanosterol, and cholesterol were detected as the [M + H - H(2)O](+) ion species, while squalene appeared as the [M + H](+) ion species. Upon fragmentation of the three sterols and squalene, the product ion at m/z 69 was present as one of the major fragments in all four compounds. This product ion was used for the quantification of ergosterol in multiple-reaction-monitoring acquisition mode. The relationship between signal intensity and ergosterol concentration was linear over the concentration range of 0.15 to 5 microg/ml, or 7. 56-252 pmol ergosterol per 20 microl injection. The plasma membrane ergosterol of the yeast Saccharomyces cerevisiae could be quantified reproducibly without the need for prior separation from other lipids or derivatization. Six repeated injections of ergosterol standards at concentrations of 0.95 and 4.25 microg/ml gave standard deviations of 0.031 and 0.084, respectively, and coefficients of variation of 3.33 and 1.98%, respectively. The coefficient of variation for the four independently extracted membrane ergosterol samples was 11.18%. The presence of other lipids in a crude lipid extract did not interfere with the ergosterol determination. Direct injection APcI with multiple reaction monitoring is aconvenient and sensitive method for ergosterol quantification requiring no prior fractionation.     

23,24,25,26,27-Pentanorlanost-8-en-3β,22-diol from Verticillium lecanii

23,24,25,26,27-Pentanorlanost-8-en-3β,22-diol has been isolated from the mycelium of the fungus Verticillium lecanii. Addition of lanosterol to the culture medium did not significantly increase the yields either of the pentanorlanostane metabolites or of ergosterol.