Azasterol inhibition of delta 24-sterol methyltransferase in Saccharomyces cerevisiae

The inhibition of the delta 24-sterol methyltransferase (24-SMT) of Saccharomyces cerevisiae by side-chain azasterols is related to their nuclear skeleton and side chain nitrogen position. Inhibitory power [I50 (microM)] was found to be in the order of 25-azacholesterol hydrochloride salt (0.05) greater than 25-aza-24,25-dihydrozymosterol (0.08) greater than 25-azacholesterol approximately equal to 25-azacholestanol (0.14) greater than (20R)- and (20S)-22,25-diazacholesterol (0.18) greater than 24-azacholesterol (0.22) greater than 25-aza-24,25-dihydrolanosterol (1.14) greater than 23-azacholesterol (4.8). In the presence of azasterols, S. cerevisiae produces increased amounts of zymosterol, decreased amounts of ergosterol and ergostatetraenol, and the new metabolites cholesta-7,24-dienol, cholesta-5,7,24-trienol, and cholesta-5,7,22,24-tetraenol. Kinetic inhibition studies with partially purified 24-SMT and several azasterols suggest the azasterols act uncompetitively with respect to zymosterol and are competitive inhibitors with respect to S-adenosyl-L-methionine (SAM). These results are consistent with at least two kinetic mechanisms. One excludes competition of azasterol and zymosterol for the same site, whereas a second could involve a ping-pong mechanism in which 24-SMT is methylated by SAM and the methylated enzyme reacts with sterol substrate.     

The structure of a Burkholderia pseudomallei immunophilin-inhibitor complex reveals new approaches to antimicrobial development

TbSMT [Trypanosoma brucei 24-SMT (sterol C-24-methyltransferase)] synthesizes an unconventional 24-alkyl sterol product set consisting of Δ24(25)-, Δ24(28)- and Δ25(27)-olefins. The C-methylation reaction requires Si(β)-face C-24-methyl addition coupled to reversible migration of positive charge from C-24 to C-25. The hydride shifts responsible for charge migration in formation of multiple ergostane olefin isomers catalysed by TbSMT were examined by incubation of a series of sterol acceptors paired with AdoMet (S-adenosyl-L-methionine). Results obtained with zymosterol compared with the corresponding 24-2H and 27-13C derivatives revealed isotopic-sensitive branching in the hydride transfer reaction on the path to form a 24-methyl-Δ24(25)-olefin product (kinetic isotope effect, kH/kD=1.20), and stereospecific CH3→CH2 elimination at the C28 branch and C27 cis-terminal methyl to form Δ24(28) and Δ25(27) products respectively. Cholesta-5,7,22,24-tetraenol converted into ergosta-5,7,22,24(28)-tetraenol and 24β-hydroxy ergosta-5,7,23-trienol (new compound), whereas ergosta-5,24-dienol converted into 24-dimethyl ergosta-5,25(27)-dienol and cholesta-5,7,24-trienol converted into ergosta-5,7,25(27)trienol, ergosta-5,7,24(28)-trienol, ergosta-5,7,24-trienol and 24 dimethyl ergosta-5,7,25(27)-trienol. We made use of our prior research and molecular modelling of 24-SMT to identify contact amino acids that might affect catalysis. Conserved tyrosine residues at positions 66, 177 and 208 in TbSMT were replaced with phenylalanine residues. The substitutions generated variable loss of activity during the course of the first C-1-transfer reaction, which differs from the corresponding Erg6p mutants that afforded a gain in C-2-transfer activity. The results show that differences exist among 24-SMTs in control of C-1- and C-2-transfer activities by interactions of intermediate and aromatic residues in the activated complex and provide an opportunity for rational drug design of a parasite enzyme not synthesized by the human host.     

Sterol mutants of Chlamydomonas reinhardtii: Characterisation of three strains deficient in C24(28) reductase

Three mutants of Chlamydomonas reinhardtii (strain arg7cw15) were obtained using the strategy of insertional mutagenesis by random plasmid integration with subsequent selection for resistance against the polyene antibiotic nystatin. Sterols were isolated by precipitation with digitonin, fractionated by both normal and argentation TLC, and then analysed by GLC and GC-MS. All the mutants accumulated ergosta-5,7,22,24(28)-tetraenol, ergosta-5,7,24(28)-trienol, ergosta-7,24(28)-dienol, stigmasta-5,7,22,24(28)-tetraenol, stigmasta-5,7,24(28)-trienol, stigmasta-8,24(28)-dienol and stigmasta-7,24(28)-dienol, while ergosterol and 7-dehydroporiferasterol which are the only major sterol components of the original strain were absent in the mutants. It is concluded that all these mutants are impaired in this C24(28) reductase which catalyses the reduction of the C24(28) tetraenol to the corresponding 24-alkyl sterol. There is strong evidence that the same enzyme acts on both the C₂₈ and C₂₉ sterol series. This view is also supported by Southern blot hybridisation analysis revealing that in all three mutants, plasmid insertion occurred at the same site indicating the disruption of the same gene. Due to the insertional nature of the mutations, the strains can be used for cloning the corresponding gene.     

Metabolism of delta24-sterols by yeast mutants blocked in removal of the C-14 methyl group.

We have investigated the metabolism of exogenously provided delta24-sterols by whole cell cultures of a polyene-resistant mutant (D10) of Candida albicans blocked at removal of the C-14 methyl group. Comparison of the relative efficiencies of transmethylation at C-24 of selected sterol substrates revealed the following substrate preferences of the Candida delta24-sterol methyltransferase (EC 2.1.1.41): zymosterol greater than 4alpha-methylzymosterol greater than 14alpha-methylzymosterol. Exogenous 4,4-dimethylzymosterol was not transmethylated by mutant D10. Incorporation of the 14C-labelled methyl group of S-adenosyl-L-[methyl-14C]methionine into the sterols of a D10 culture preloaded with zymosterol indicated that zymosterol was a better (40 X) substrate than endogenous lanosterolmfeeding zymosterol to D10 and a polyene-resistant strain of Saccharomyces cerevisiae (Nys-P100) that was also blocked at removal of the C-14 methyl group gave 24-methyl sterols possessing delta22 and ring B unsaturation. Mutant D10 was able to produce ergosterol from zymosterol whereas Nys-P100 produced ergosta-7,22-dienol. When grown in the presence of 3 micrometer 25-aza-24,25-dihydrozymosterol, a known inhibitor of the delta24-sterol methyltransferase, Nys-P100 accumulated 14alpha-methylzymosterol, a minor metabolite in this mutant under normal growth conditions and hitherto unidentified as a yeast sterol.     

Sterol biosynthesis by symbiotes: cytochrome P450 sterol C-22 desaturase genes from yeastlike symbiotes of rice planthoppers and anobiid beetles

Rice planthoppers and anobiid beetles harbor intracellular yeastlike symbiotes (YLS), whose sterols are nutritionally advantageous for the host insects that cannot synthesize sterols. YLS of anobiid beetles synthesize ergosterol, whereas YLS of planthoppers produce ergosta-5,7,24(28)-trienol, which is a metabolic intermediate in the ergosterol biosynthetic pathway in yeasts. Since sterol C-22 desaturase (ERG5p, CYP61) metabolizes ergosta-5,7,24(28)-trienol into ergosta-5,7,22,24(28)-tetraenol, which is the penultimate compound in the ergosterol biosynthesis, we examined the gene of this enzyme to determine whether this enzyme works in the planthopper YLS. C-22 desaturase genes (ERG5) of YLS of the planthoppers and beetles had four introns in identical positions; such introns are not found in the reported genes of yeasts. Cytochrome P450 cysteine heme-iron ligand signature motif was well conserved among the putative amino acid sequences. The gene expression of the planthopper YLS were strongly suppressed, and the genes possessed nonsense mutations. The accumulation of ergosta-5,7,24(28)-trienol in the planthopper YLS was attributed to the inability of the planthopper YLS to produce functional ERG5p.     

The induced biosynthesis of 7-dehydrocholesterols in yeast: potential sources of new provitamin D3 analogs.

The effect of low concentrations of a specifically designed sterol-24-transmethylase inhibitor, 25-aza-24, 25-dihydrozymosterol (10) on sterol production in Saccharomyces cerevisiae was examined. The synthesis of cholesta-5,7,22,24-tetraen-3beta-ol (4), its 7,22,24 analog (15) and the 7,24 analog (5) coupled with the availability of zymosterol (6) and cholesta-5,7,24-3beta-ol (3) derivatives facilitated a search for these sterols in cultures treated with this inhibitor. When S. cerevisiae was grown in the presence of 1.3 and 5 muM 10, it produced no ergosterol but accumulated zymosterol (6), cholesta-5,7,22,24-tetraen-3beta-ol (4) and related C27 sterols (3 and 5). These results indicate blockage of the side chain methylation that normally occurs during the biosynthesis of ergosterol in yeast by compound 10 is efficient. The cholesta-5,7,22,24-tetraen-3beta-ol is a close structural analog of provitamin D3 (7-dehydrocholesterol). The inhibited yeast thus provides a source of a potentially new provitamin D3 substitute.     

Inhibitors of ergosterol biosynthesis and growth of the trypanosomatid protozoan Crithidia fasciculata

Six nitrogen-, sulfur- and cyclopropane-containing derivatives of cholestanol were examined as inhibitors of growth and sterol biosynthesis in the trypanosomatid protozoan Crithidia fasciculata. The concentrations of inhibitors in the culture medium required for 50% inhibition of growth were 0.32 microM for 24-thia-5 alpha,20 xi-cholestan-3 beta-ol (2), 0.009 microM for 24-methyl-24-aza-5 alpha,20 xi-cholestan-3 beta-ol (3), 0.95 microM for (20,21),(24,-25)-bis-(methylene)-5 alpha,20 xi-cholestan-3 beta-ol (4), 0.13 microM for 22-aza-5 alpha,20 xi-cholestan-3 beta-ol (5), and 0.3 microM for 23-azacholestan-3-ol (7). 23-Thia-5 alpha-cholestan-3 beta-ol (6) had no effect on protozoan growth at concentrations as high as 20 microM. Ergosterol was the major sterol observed in untreated C. fasciculata, but significant amounts of ergost-7-en-3 beta-ol, ergosta-7,24(28)-dien-3 beta-ol, ergosta-5,7,22,24(28)-tetraen-e beta-ol, cholesta-8,24-dien-3 beta-ol, and, in an unusual finding, 14 alpha-methyl-cholesta-8,24-dien-3 beta-ol were also present. When C. fasciculata was cultured in the presence of compounds 2 and 3, ergosterol synthesis was suppressed, and the principal sterol observed was cholesta-5,7,24-trien-3 beta-ol, a sterol which is not observed in untreated cultures. The presence of this trienol strongly suggests that 2 and 3 specifically inhibit the S-adenosylmethionine:sterol C-24 methyltransferase but do not interfere with the normal enzymatic processing of the sterol nucleus. When C. fasciculata was cultured in the presence of compounds 5 and 7, the levels of ergosterol and ergost-7-en-3 beta-ol were suppressed, but the amounts of the presumed immediate precursors of these sterols, ergosta-5,7,22,24(28)-tetraen-3 beta-ol and ergosta-7,24-(28)-dien-3 beta-ol, respectively, were correspondingly increased. These findings suggest that 5 and 7 specifically inhibit the reduction of the delta 24(28) side chain double bond. When C. fasciculata was cultured in the presence of compound 4, ergosterol synthesis was suppressed, but the sterol distribution in these cells was complex and not easily interpreted. Compound 6 had no significant effect on sterol synthesis in C. fasciculata.     

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.     

Investigations on the biosynthesis of steroids and terpenoids: XI. The 24-methylene sterol 24(28)-reductase of Saccharomyces cerevisiae

The microsomal fraction of Saccharomyces cerevisiae has been shown to catalyse the NADPH-dependent reduction of ergosta-5,7,22,24(28)-tetraen-3β-ol to ergosterol. This cell-free system together with whole-cell cultures of polyene-resistant mutants has been used to compare the rates of reduction of other 24-methylene sterols. The results indicate that the enzyme involved exhibits a marked specificity for ergosta-5,7,22,24(28)-tetraen-3β-ol and support the concept of a major terminal step in ergosterol biosynthesis.     

Characterization of nystatin-resistant mutants of Saccharomyces cerevisiae and preparation of sterol intermediates using the mutants

Analysis of sterols of Saccharomyces cerevisiae mutants N3, N15, N26, and N3H, defective in sterol biosynthesis, was performed. Strains N3, N15, and N26 were isolated from their mother strain, M10, by screening with nystatin (Nagai et al. (1980) Mie Med. J. 30, 215-224), and strain N3H was isolated from N3 as a doubly-mutated strain. The main sterols of N3, N15, N26, and N3H were ergosta-7,22-dienol, ergost-8-enol, cholesta-5,7,24-trienol, and ergosta-7,22,24(28)-trienol, respectively. The former three strains were characterized as defective in delta 5-desaturation, delta 8--delta 7 isomerization, and C-24 transmethylation. Strain N3H was found to be defective in delta 5-desaturation as well as in delta 24(28)-reduction. However, the defect of N26 and N3H was suggested to be leaky, since small amounts of ergosterol and ergosta-7,22-dienol were found in these mutants, respectively. In N15, an accumulation (2% in total sterols) of the compound likely to be hydroxylated sterol was found. By aerobic adaptation of these strains, the accumulation of these strains, the accumulations of ergosta-7,22-dienol (22 mg/g dry cells), ergosta-7,22,24(28)-trienol (24 mg), ergosta-8,24(28)-dienol (18 mg), and cholesta-8,24-dienol (22 mg) reached a maximum in N3, N3H, N15, and N26 after 20, 20, 30, and 30 h, respectively. These strains appear to be useful for making 14C-labeled and non-labeled preparations of the above sterols.     

Structural requirements for transformation of substrates by the (S)-adenosyl-L-methionine:delta 24(25)-sterol methyl transferase

The membrane-bound enzyme of microsomes obtained from sunflower embryos that catalyzes the bi-substrate transfer reaction whereby the methyl group of (S)-adenosyl-L-methionine is transferred to C-24 of the sterol side chain has been investigated. Optimal incubation conditions for assay of the microsomal (S)-adenosyl-L-methionine:sterol delta 24-methyl transferase (SMT) have been established for the first time. The microsomal preparation was found to catalyze the formation of a delta 24(28)-sterol and to be free of contaminating methyl transferase enzymes, e.g. those which form delta 23-24 methyl sterols (cyclosadol) and delta 25-24 beta-methyl sterols (cyclolaudenol) and other sterolic enzymes which might transform the acceptor molecule to metabolites which could compete in the assay with the test substrate. From a series of incubations with 27 sterol and sterol-like (triterpenoids) substrates of which 23 compounds possessed a 24,25-double bond, we observed a marked dependence on precise structural features and three-dimensional shape of the acceptor molecule in its ability to be transformed by the SMT. In contrast to the yeast SMT where cycloartenol fails to bind to the SMT and zymosterol is the best substrate for methylation, the sunflower SMT studied here utilizes cycloartenol preferentially to zymosterol and the other substrates. Of the chemical groups which distinguishes cycloartenol, a free 3 beta-OH,9 beta,19-cyclopropyl group, trimethylated saturated nucleus, and delta 24-double bond, only the nucleophilic centers at C-3 and C-24 were obligatory for substrate binding and methylation. Of the bent or flat conformations which cycloartenol may orient in the enzyme-substrate complex, our results indicate a selection for acceptor molecules which possess the shape that closely resembles the crystal state and solution orientation of cycloartenol which is now known to be flat rather than bent (Nes, W. D., Benson, M., Lundin, R. E., and Le, P. H. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 5759-5763).     

Mechanistic analysis of a multiple product sterol methyltransferase implicated in ergosterol biosynthesis in Trypanosoma brucei

Sterol methyltransferase (SMT) plays a key role in sterol biosynthesis in different pathogenic organisms by setting the pattern of the side chain structure of the final product. This catalyst, absent in humans, provides critical pathway-specific enzymatic steps in the production of ergosterol in fungi or phytosterols in plants. The new SMT gene was isolated from Trypanosoma brucei genomic DNA and cloned into an Escherichia coli expression system. The recombinant SMT was purified to homogeneity to give a band at 40.0 kDa upon SDS-PAGE and showed a tetrameric subunit organization by gel chromatography. It has a pH optimum of 7.5, an apparent kcat value of 0.01 s(-1), and a Km of 47 +/- 4 microm for zymosterol. The products of the reaction were a mixture of C24-monoalkylated sterols, ergosta-8,24 (25)-dienol, ergosta-8,25 (27)-dienol, and ergosta-8,24 (28)-dienol (fecosterol), and an unusual double C24-alkylated sterol, 24,24-dimethyl ergosta-8,25 (27)-dienol, typically found in plants. Inhibitory profile studies with 25-azalanosterol (Ki value of 39 nm) or 24(R,S), 25-epiminolanosterol (Ki value of 49 nm), ergosterol (Ki value of 27 microm) and 26,27-dehydrozymosterol (Ki and kinact values of 29 microm and 0.26 min(-1), respectively) and data showing zymosterol as the preferred acceptor strongly suggest that the protozoan SMT has an active site topography combining properties of the SMT1 from plants and yeast (37-47% identity). The enzymatic activation of this and other SMTs reveals that the catalytic requirements for the C-methyl reaction are remarkably versatile, whereas the inhibition studies provide a powerful approach to rational design of new anti-sleeping sickness chemotherapeutic drugs.     

Identification of a sterol Delta7 reductase gene involved in desmosterol biosynthesis in Mortierella alpina 1S-4

Molecular cloning of the gene encoding sterol Delta7 reductase from the filamentous fungus Mortierella alpina 1S-4, which accumulates cholesta-5,24-dienol (desmosterol) as the main sterol, revealed that the open reading frame of this gene, designated MoDelta7SR, consists of 1,404 bp and codes for 468 amino acids with a molecular weight of 53,965. The predicted amino acid sequence of MoDelta7SR showed highest homology of 51% with that of sterol Delta7 reductase (EC 1.3.1.21) from Xenopus laevis (African clawed frog). Heterologous expression of the MoDelta7SR gene in yeast Saccharomyces cerevisiae revealed that MoDelta7SR converts ergosta-5,7-dienol to ergosta-5-enol (campesterol) by the activity of Delta7 reductase. In addition, with gene silencing of MoDelta7SR gene by RNA interference, the transformant accumulated cholesta-5,7,24-trienol up to 10% of the total sterols with a decrease in desmosterol. Cholesta-5,7,24-trienol is not detected in the control strain. This indicates that MoDelta7SR is involved in desmosterol biosynthesis in M. alpina 1S-4. This study is the first report on characterization of sterol Delta7 reductase from a microorganism.     

The action of the systemic fungicides tridemorph and fenpropimorph on sterol biosynthesis by the soil amoeba Acanthamoeba polyphaga

Tridemorph and fenpropimorph, two systemic fungicides known by their inhibitory effects on sterol biosynthesis in fungi and plants, were administered in vivo to the amoeba Acanthamoeba polyphaga. The compounds did not kill the cells, but modified completely their sterol pattern. Fungicide-exposed cells accumulated cyclopropylsterols indicating a partial blockage of the cyclopropane isomerase as in higher plants and delta 8-sterols indicating an inhibition of the delta 8----delta 7 isomerase as in fungi. Three new sterols, 4 alpha-methylergosta-9(11),24(28)-dienol, ergosta-6,8,22-trienol and poriferasta-6,8,22-trienol were isolated and identified, the former from control cells, the two latter from fungicide-treated cells. These results are in accordance with our previous results on the presence of cycloartenol as sterol precursor and confirm our hypothesis on a phylogenetic relationship of Acanthamoeba polyphaga with photosynthetic phyla.     

Novel sterol metabolic network of Trypanosoma brucei procyclic and bloodstream forms

Trypanosoma brucei is the protozoan parasite that causes African trypanosomiasis, a neglected disease of people and animals. Co-metabolite analysis, labelling studies using [methyl-2H3]-methionine and substrate/product specificities of the cloned 24-SMT (sterol C24-methyltransferase) and 14-SDM (sterol C14demethylase) from T. brucei afforded an uncommon sterol metabolic network that proceeds from lanosterol and 31-norlanosterol to ETO [ergosta-5,7,25(27)-trien-3β-ol], 24-DTO [dimethyl ergosta-5,7,25(27)-trienol] and ergosterol [ergosta-5,7,22(23)-trienol]. To assess the possible carbon sources of ergosterol biosynthesis, specifically 13C-labelled specimens of lanosterol, acetate, leucine and glucose were administered to T. brucei and the 13C distributions found were in accord with the operation of the acetate-mevalonate pathway, with leucine as an alternative precursor, to ergostenols in either the insect or bloodstream form. In searching for metabolic signatures of procyclic cells, we observed that the 13C-labelling treatments induce fluctuations between the acetyl-CoA (mitochondrial) and sterol (cytosolic) synthetic pathways detected by the progressive increase in 13C-ergosterol production (control<[2-(13)C]leucine<[2-(13)C]acetate<[1-(13)C]glucose) and corresponding depletion of cholesta-5,7,24-trienol. We conclude that anabolic fluxes originating in mitochondrial metabolism constitute a flexible part of sterol synthesis that is further fluctuated in the cytosol, yielding distinct sterol profiles in relation to cell demands on growth.     

Identification of a Sterol Δ7 Reductase Gene Involved in Desmosterol Biosynthesis in Mortierella alpina 1S-4

Molecular cloning of the gene encoding sterol Δ7 reductase from the filamentous fungus Mortierella alpina 1S-4, which accumulates cholesta-5,24-dienol (desmosterol) as the main sterol, revealed that the open reading frame of this gene, designated MoΔ7SR, consists of 1,404 bp and codes for 468 amino acids with a molecular weight of 53,965. The predicted amino acid sequence of MoΔ7SR showed highest homology of 51% with that of sterol Δ7 reductase (EC 1.3.1.21) from Xenopus laevis (African clawed frog). Heterologous expression of the MoΔ7SR gene in yeast Saccharomyces cerevisiae revealed that MoΔ7SR converts ergosta-5,7-dienol to ergosta-5-enol (campesterol) by the activity of Δ7 reductase. In addition, with gene silencing of MoΔ7SR gene by RNA interference, the transformant accumulated cholesta-5,7,24-trienol up to 10% of the total sterols with a decrease in desmosterol. Cholesta-5,7,24-trienol is not detected in the control strain. This indicates that MoΔ7SR is involved in desmosterol biosynthesis in M. alpina 1S-4. This study is the first report on characterization of sterol Δ7 reductase from a microorganism.     

Evidence for similarities and differences in the biosynthesis of fungal sterols

The sterol composition of two ascomycetous fungi, Saccharomyces cerevisiae and Gibberella fujikuroi, was examined by chromatographic (TLC, GLC, and HPLC) and spectral (MS and 1H-NMR) methods. Of notable importance was that both fungi produced cholesterol and a homologous series of long chain fatty alcohols (C22 to C30). In addition to ergosterol two novel sterols, ergosta-5,7, 9(11), 22-tetraenol and ergosterol endoperoxide, were isolated as minor compounds in growth-arrested cultures of yeast and in mycelia of G. fujikuroi. 24-Ethylidenelanosterol was also detected in mycelia of G. fujikuroi. A shift in sterol biosynthesis was observed by treatment with 24 (RS), 25-epiminolanosterol (an inhibitor of the S-adenosylmethionine C-24 transferase) and by monitoring the sterol composition at various stages of development. The results are interpreted to imply that the genes for 24-desalkyl, e.g., cholesterol, and 24-alkyl sterols, e.g., 24 beta- methyl cholesterol and 24-ethyl cholesterol, are distributed (but not always expressed) generally throughout the fungi but the occurrence of one or another compounds is influenced by the fitness (structure and amount) for specific sterols to act functionally during fungal ontogeny; sterol fitness is coordinated with Darwinian selection pressures.     

Effect of altered sterol composition on the salt tolerance of Zygosaccharomyces rouxii

To obtain mutants containing altered sterol composition and sterol contents, nystatin-resistant mutants were isolated in Zygosaccharomyces rouxii. Two of nine mutants isolated were resistant toward 20 μg of nystatin per ml, while the other seven showed resistance toward 50 μg per ml. However, the seven mutants could not grow at 35°C. TN5, a mutant of the first group, showed the same sterol composition as the wild type strain, with ergosterol and zymosterol as major sterols, whereas it contained free sterols about 70% of those of the wild type. TN1 and TN3, representative mutants of the second group, had altered sterol compositions, containing three major sterols, zymosterol, ergosta-5,7,24-trienol, and an unidentified sterol. TN1 and TN3 could not grow in YPD medium containing more than 8% NaCl, whereas TN5 grew in the same medium containing 15% NaCl after a longer lag phase than the wild type strain. TN1 and TN3, in particular TN3, when incubated in YPD medium containing 15% NaCl, leaked significant amounts of glycerol. Protoplasts of these mutants were more labile than those of the wild-type cells. These facts suggest that the amount and kind of ergosterol in the cell membrane might be concerned with the salt tolerance of Z. rouxii.     

Studies on delta8-delta7 isomerization and methyl transfer of sterols in ergosterol biosynthesis of yeast.

The formation of cholesta-7,24-dien-3 beta-ol and its activity as a substrate for the sterol side-chain methyltransferase in yeast have not previously been studied. Experiments with acetone-powder extracts of yeast showed that the sterol is formed from zymosterol by delta8-delta7 isomerization. However, direct conversion of cholesta-7,24-dien-3 beta-ol into zymosterol could not be demonstrated. The reversibility of the reaction was proved by the detection of 3H-incorporation into cholesta-8-en-3 beta-ol (with lathosterol as a carrier) from [3H]H2O in the medium. Incubation of cholesta-7,24-dien-3 beta-ol and S-adenosyl-L-[methyl-14C]methionine with the acetone-powder extract resulted in methylation of the sterol to form episterol. Similar incubation of zymosterol gave fecosterol and episterol, suggesting that fecosterol initially formed by the methylation was isomerized to episterol. In intact cells, however, an alternative pathway (zymosterol yields cholesta-7,24-dien-3 beta-ol yields episterol) may also operate. The relative importance of the two pathways is not known.     

Total lipid and sterol components of Rhizopus arrhizus: identification and metabolism

The total lipid levels and the incorporation of [¹⁴C]acetate during the life cycle of the fungus Rhizopus arrhizus were investigated. The total lipid abundances ranged between 2.2 and 15.3% of the tissue, reaching the maximum midway through the 6-day growth period. The sporangiospores contained 2.65% total lipids.The sterols were also investigated and ranged in concentration from 1.88 to 9.1% of the total lipids during the growth period. 4,4-Dimethyl, 4α-methyl, and 4-des-methyl sterols were tentatively identified by tlc and the latter group separated and identified by combined glc-ms. The predominant 4-desmethyl sterols were ergosta-Δ^5,7,22-trienol (ergosterol), ergosta-Δ^7,22-dienol (5-dihydroergosterol), ergost-Δ⁷-enol (fungisterol), and the tentatively identified ergosta-Δ^5,7,14-trienol in relative concentrations of 24.6, 58.8, 9.9, and 6.7%, respectively. The sterol components of the spores were qualitatively identical to those of the mycelial tissues, but several minor components remain to be identified.