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.     

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.     

Effect of ay-9944 on sterol biosynthesis in Chlorella sorokiniana

When Chlorella sorokiniana was grown in the presence of 4 ppm AY-9944 total sterol production was unaltered in comparison to control cultures. However, inhibition of sterol biosynthesis was shown by the accumulation of a number of sterols which were considered to be intermediates in sterol biosynthesis. The sterols which were found in treated cultures were identified as cyclolaudenol, 4α,14α-dimethyl-9β,19-cyclo-5α-ergost-25-en-3β-ol, 4α,14α-dimethyl -5α-ergosta-8,25-dien-3β-ol, 14α-methyl-9β,19-cyclo-5α-ergost-25-en-3β-ol, 24-methylpollinastanol, 14α-methyl-5α-ergost-8-en-3β-ol, 5α-ergost -8(14)-enol, 5α-ergost-8-enol, 5α-ergosta-8(14),22-dienol, 5α-ergosta-8,22-dienol, 5α-ergosta-8,14-dienol, and 5α-ergosta-7,22-dienol, in addition to the normally occurring sterols which are ergosterol, 5α-ergost-7-enol, and ergosta-5,7-dienol.The occurrence of these sterols in the treated culture indicates that AY-9944 is an effective inhibitor of the Δ⁸ → Δ⁷ isomerase and Δ¹⁴-reductase, and also inhibits introduction of the Δ²²-double bond. The occurrence of 14α-dimethyl-5α-ergosta-8,25-dien-3β-ol and 14α-methyl-9β,19-cyclo-5α-ergost -25-en-3β-ol is reported for the first time in living organisms. The presence of 25-methylene sterols suggests that they, and not 24-methylene derivatives, are intermediates in the biosynthesis of sterols in C. sorokiniana.     

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.     

Active site mapping and substrate channeling in the sterol methyltransferase pathway

Sterol methyltransferase (SMT) from Saccharomyces cerevisiae was purified from Escherichia coli BL21(DE3) and labeled with the mechanism-based irreversible inhibitor [3-3H]26,27-dehydrozymosterol (26,27-DHZ). A 5-kDa tryptic digest peptide fragment containing six acidic residues at positions Glu-64, Asp-65, Glu-68, Asp-79, Glu-82, and Glu-98 was determined to contain the substrate analog covalently attached to Glu-68 by Edman sequencing and radioanalysis using C18 reverse phase high performance liquid chromatography. Site-directed mutagenesis of the six acidic residues to leucine followed by activity assay of the purified mutants confirmed Glu-68 as the only residue to participate in affinity labeling. Equilibration studies indicated that zymosterol and 26,27-DHZ were bound to native and the E68L mutant with similar affinity, whereas S-adenosylmethionine was bound only to the native SMT, K(d) of about 2 microm. Analysis of the incubation products of the wild-type and six leucine mutants by GC-MS demonstrated that zymosterol was converted to fecosterol, 26,27-DHZ was converted to 26-homo-cholesta-8(9),23(24)E,26(26')-trienol as well as 26-homocholesta-8(9),26(26')-3beta,24beta-dienol, and in the case of D79L and E82L mutants, zymosterol was also converted to a new product, 24-methylzymosta-8,25(27)-dienol. The structures of the methylenecyclopropane ring-opened olefins were determined unambiguously by a combination of (1)H and (13)C NMR techniques. A K(m) of 15 microm, K(cat) of 8 x 10(-4) s(-1), and partition ratio of 0.03 was established for 26,27-DHZ, suggesting that the methylenecyclopropane can serve as a lead structure for a new class of antifungal agents. Taken together, partitioning that leads to loss of enzyme function is the result of 26,27-DHZ catalysis forming a highly reactive cationic intermediate that interacts with the enzyme in a region normally not occupied by the zymosterol high energy intermediate as a consequence of less than perfect control. Alternatively, the gain in enzyme function resulting from the production of a delta(25(27))-olefin originates with the leucine substitution directing substrate channeling along different reaction channels in a similar region at the active site.     

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.     

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.     

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.     

Azasterol inhibitors in yeast. Inhibition of the 24-methylene sterol delta24(28)-reductase and delta24-sterol methyltransferase of Saccharomyces cerevisiae by 23-azacholesterol.

The effects of 23-azacholesterol on sterol biosynthesis and growth of Saccharomyces cervisiae were examined. In the presence of 0.2, 0.5, and 1 micron 23-azacholesterol, aerobically-growing yeast produced a nearly constant amount of ergosta-5,7,22,24(28)-tetraenol (approx. 36% of total sterol) and slowly accumulated zymosterol with a concommitant decline in ergosterol synthesis. Growth and total sterol content of yeast cultures treated with 0.2-1 micron 23-azacholesterol were similar to that of the control culture. Yeast cultures treated with 5 and 10 micron 23-azacholesterol produced mostly zymosterol (58-61% of total sterol), while ergosta-5,7,22,24(28)-tetraenol production declined to less than 10% of total sterol. The observed changes in the distribution of sterols in treated cultures are consistent with inhibition of 24-methylene sterol 24(28)-sterol reductase (total inhibition at 1 micron 23-azacholesterol) and of 24-sterol methyltransferase (71% inhibition at 10 micron 23-azacholesterol). Yeast cultures treated with 10 micron 23-azacholesterol were found to contain 4,4-dimethylcholesta-8,14,24-trienol and 4alpha-methylcholesta-8,14,24-trienol, which were isolated and characterized for the first time.     

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.     

Aerobic isolation of an ERG24 null mutant of Saccharomyces cerevisiae.

The ERG24 gene, encoding the C-14 sterol reductase, has been reported to be essential to the aerobic growth of Saccharomyces cerevisiae. We report here, however, that strains with null mutations in the ERG24 gene can grow on defined synthetic media in aerobic conditions. These sterol mutants produce ignosterol (ergosta-8,14-dienol) as the principal sterol, with no traces of ergosterol. In addition, we mapped the ERG24 gene to chromosome XIV between the MET2 and SEC2 genes. Our results indicate that ignosterol can be a suitable sterol for aerobic growth of S. cerevisiae on synthetic media and that inactivation of ERG24 is only conditionally lethal.     

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.     

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 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.     

Investigation of the Sterol Composition and Azole Resistance in Field Isolates of Septoria tritici

We report here a biochemical study of resistance to azole antifungal agents in a field isolate (S-27) of a fungal phytopathogen. Isolates of Septoria tritici were compared in vitro, and their responses reflected that observed in the field, with S-27 exhibiting resistance relative to RL2. In untreated cultures, both RL2 and S-27 contained isomers of ergosterol and ergosta-5,7-dienol, although in differing concentrations. Under azole treatment, this phytopathogen exhibited a response similar to that of other pathogenic fungi, with a reduction in desmethyl sterols and an accumulation of 14(alpha)-methyl sterols, indicative of inhibition of the P450-mediating sterol 14(alpha)-demethylase. Growth arrest was attributed to the reduction of ergosterol combined with an accumulation of nonutilizable sterols. Strain S-27 exhibited an azole-resistant phenotype which was correlated with decreased cellular content of azole.     

Cholesterol import fails to prevent catalyst-based inhibition of ergosterol synthesis and cell proliferation of Trypanosoma brucei

Trypanosoma brucei (TB) cultured in rat blood, bovine serum, or lipid-depleted serum generated distinct differences in cholesterol availability. Whereas cell proliferation of the parasite was relatively unaffected by cholesterol availability, the ratios of cellular ergostenols to cholesterol varied from close to unity to 3 orders of magnitude different with cholesterol as the major sterol (>99%) of bloodstream form cells. In the procyclic form cultured with lipid-depleted serum, 15 sterols at 52 fg/cell were identified by GC-MS. The structures of these sterols reveal a nonconventional ergosterol pathway consistent with the novel product diversity catalyzed by the recently cloned sterol methyltransferase (SMT). A potent transition state analog of the TB SMT C24 alkylation reaction, 25-azalanosterol (25-AL; inhibition constant Ki = 39 nM), was found to inhibit the growth of the procyclic and bloodstream forms at an IC(50) of approximately 1 microM. This previously unrecognized catalyst-specific inhibition of cell growth was unmasked further using the 25-AL-treated procyclic form, which, compared with control cultures, caused a change in cellular sterol content from ergostenols to cholesterol. However, growth of the bloodstream form disrupted by 25-AL was not rescued by cholesterol absorption from the host, suggesting an essential role for ergosterol (24-methyl sterol) in cell proliferation and that the SMT can be a new enzyme target for drug design.     

Sterol C-methyl transferase from Prototheca wickerhamii mechanism, sterol specificity and inhibition

The membrane-bound sterol methyl transferase (SMT) enzyme from Prototheca wickerhamii, a non-photosynthetic, yeast-like alga, was found to C-methylate appropriate delta24(25)-sterol acceptor molecules to delta25(27)-24beta-methyl products stereoselectively. Incubation with pairs of substrates--[2H3-methyl]AdoMet and cycloartenol, and AdoMet and [27-(13)C]lanosterol--followed by 1H and 13C NMR analysis of the isotopically labeled products demonstrated the si-face (beta-face attack) mechanism of C-methylation and the regiospecificity of delta25(27)-double bond formation from the pro-Z methyl group (C27) on lanosterol. The enzyme has a substrate preference for a sterol with a 3beta-hydroxyl group, a planar nucleus and a side chain oriented into a 'right-handed' structure (20R-chirality) characteristic of the native substrate, cycloartenol. The apparent native molecular weight of the SMT was determined to be approximately 154,000, as measured by Superose 6 FPLC. A series of sterol analogues which contain heteroatoms substituted for C24 and C25 or related structural modifications, including steroidal alkaloids, havs been used to probe further the active site and mechanism of action of the SMT enzyme. Sterol side chains containing isoelectronic modifications of a positively charged moiety in the form of an ammonium group substituted for carbon at C25, C24, C23 or C22 are particularly potent non-competitive inhibitors (Ki for the most potent inhibitor tested, 25-azacycloartanol, was ca. 2 nM, four orders of magnitude less than the Km for cycloartenol of 28 microM), supporting the intermediacy of the 24-methyl C24(25)-carbenium ion intermediate. Ergosterol, but neither cholesterol nor sitosterol, was found to inhibit SMT activity (Ki = 80 microM). The combination of results suggests that the interrelationships of substrate functional groups within the active center of a delta24(25) to delta25(27) 24beta-methyl-SMT could be approximated thereby allowing the rational design of C-methylation inhibitors to be formulated and tested.     

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.     

Cloning, sequencing, and disruption of the gene encoding sterol C-14 reductase in Saccharomyces cerevisiae.

A sterol C-14 reductase (erg24-1) mutant of Saccharomyces cerevisiae was selected in a fen1, fen2, suppressor background on the basis of nystatin resistance and ignosterol (ergosta-8,14-dienol) production. The erg24-1 allele segregated genetically as a single, recessive gene. The wild-type ERG24 gene was cloned by complementation onto a 12-kb fragment from a yeast genomic library, and subsequently subcloned onto a 2.4-kb fragment. This was sequenced and found to contain an open reading frame of 1,314 bp, predicting a polypeptide of 438 amino acids (M(r) 50,612). A 1,088-bp internal region of the ERG24 gene was excised, replaced with a LEU2 gene, and integrated into the chromosome of the parental strain, FP13D (fen1, fen2) by gene replacement. The ERG24 null mutant produced ergosta-8,14-dienol as the major sterol, indicating that the delta 8-7 isomerase, delta 5-desaturase and the delta 22-desaturase were inactive on sterols with the C14 = 15 double bond.     

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).