The conversion of 24-ethylidene sterols into poriferasterol by the alga Ochromonas malhamensis

A convenient method is described for the preparation of fucosterol-[7-³H₂] and 28-isofucosterol-[7-³H₂]. Both of these 24-ethylidene sterols, as well as 5α-stigmasta-7,Z-24(28)-diene-3β-ol-[2,4-³H₄], were converted into the 24β-ethyl sterol, poriferasterol, by cultures of the chrysophyte alga Ochromonas malhamensis. However, fucosterol-[7-³H₂] was not so efficiently incorporated as the other two compounds thus indicating that the configuration of the 24-ethylidene group is of some importance. It is suggested that a 24-ethylidene sterol of the Z-configuration is produced in de novo poriferasterol synthesis and that a Δ^22,24(28)-diene may be an important subsequent intermediate.     

UDP-glucose-4-epimerase from Poterioochromonas malhamensis

UDP-glucose-4-epimerase of Poterioochromonas malhamensis, Peterfi has been purified to apparent electrophoretic homogeneity. The enzyme has an apparent MW of 120 000 as determined by gel filtration of the active enzyme. Sodium dodecylsulfate polyacrylamide gel electrophoresis gave a MW of 59 000, thus indicating a dimeric structure. The epimerase does not require external NAD for activity. The apparent K_m values for UDP-glucose and UDP-galactose were calculated to be 1.67 mM and 0.26 mM, respectively. The pH optimum is at pH 8.7 and the isoelectric point is at pH 5.1 ± 0.15.     

The conversion of 5α-lanost-24-ene-3β,9α-diol and parkeol into poriferasterol by the alga Ochromon as malhamensis

The 4,4-dimethylsterols 4α-lanost-24-ene-3β,9α-diol-[2-³H₂] and parkeol-[2-³H₂] were synthesized from lanosterol and subsequently incubated with cultures of Ochromonas malhamensis. 5α-Lanost-24-ene-3β,9α-diol was converted into poriferasterol with three times the efficiency of parkeol. Clionasterol was also found to be labelled from both parkeol and 5α-lanost-24-ene-3β,9α-diol. No significant incorporation of radioactivity into sterols was obtained after feeding 5α-lanost-24-ene-3β,9α-diol to higher plants, the chlorophyte alga Trebouxia, yeast or a cell free homogenate of rat liver.     

Dissecting the sterol C-4 demethylation process in higher plants. From structures and genes to catalytic mechanism

Sterols become functional only after removal of the two methyl groups at C-4. This review focuses on the sterol C-4 demethylation process in higher plants. An intriguing aspect in the removal of the two C-4 methyl groups of sterol precursors in plants is that it does not occur consecutively as it does in yeast and animals, but is interrupted by several enzymatic steps. Each C-4 demethylation step involves the sequential participation of three individual enzymatic reactions including a sterol methyl oxidase (SMO), a 3β-hydroxysteroid-dehydrogenase/C4-decarboxylase (3βHSD/D) and a 3-ketosteroid reductase (SR). The distant location of the two C-4 demethylations in the sterol pathway requires distinct SMOs with respective substrate specificity. Combination of genetic and molecular enzymological approaches allowed a thorough identification and functional characterization of two distinct families of SMOs genes and two 3βHSD/D genes. For the latter, these studies provided the first molecularly and functionally characterized HSDs from a short chain dehydrogenase/reductase family in plants, and the first data on 3-D molecular interactions of an enzyme of the postoxidosqualene cyclase sterol biosynthetic pathway with its substrate in animals, yeast and higher plants. Characterization of these three new components involved in C-4 demethylation participates to the completion of the molecular inventory of sterol synthesis in higher plants.     

Biogenesis of cyclobuxine-D and cyclovirobuxine-D in Buxus sempervirens

Two major alkaloids from Buxus sempervirens, cyclovirobuxine-D and cyclobuxine-D, were found to be radioactively labelled following administration of mevalonic acid [2-¹⁴C,(4R)-4-³H₁] to freshly-harvested shoots. The ³H: ¹⁴C atomic ratio of 3:4 in cyclovirobuxine-D indicated a biosynthetic pathway from cycloartenol involving 3-ketone and 20-ketone intermediates. A ³H: ¹⁴C atomic ratio of ca 3:3 in cyclobuxine-D suggests that the 4α-methyl group of cycloartenol is lost in its formation, and this conforms with current theories of the sequence of C-4 demethylation of sterols.     

Excretion of S- and O-methyl esters and other volatile compounds by Ochromonas danica

The formation of volatile excretion products was studied in axenic cultures of Ochromonas danica. Under microaerobic conditions in the light, an ac     

The Candida albicans ERG26 gene encoding the C-3 sterol dehydrogenase (C-4 decarboxylase) is essential for growth

The Candida albicans ERG26 gene encoding the C-3 sterol dehydrogenase (C-4 decarboxylase) was cloned by complementing a Saccharomyces cerevisiae erg26 mutant with a C. albicans genomic library. Sequence analysis showed a 70% identity between the C. albicans and S. cerevisiae ERG26 genes at the amino acid level. Sequential disruption of both copies of the ERG26 gene in the presence of an integrated rescue cassette containing a third copy of the ERG26 gene under the control of the inducible pMAL2 promoter, resulted in cells capable of growing only in the presence of the inducer. The results establish that the ERG26 gene is essential for growth and that inhibitors of the Erg26p may represent a new and highly effective class of antifungal agents.     

The mechanism of alkylation at C-24 during clionasterol biosynthesis in Monodus subterraneus

Clionasterol isolated from Monodus subterraneus grown in the presence of methionine-[methyl-²H₃] contained four ²H atoms showing the participation of a 24-ethylidene sterol intermediate in its biosynthesis. Clionasterol isolated from M. subterraneus grown in the presence of mevalonic acid-[2-¹⁴C,(4R)-4-³H₁ had a ¹⁴C:₃H atomic ratio of 5:3 indicating that the 24-ethylidene sterol intermediate is reduced directly to clionasterol and not isomerized to a Δ²⁴-sterol which is then reduced.     

Biosynthese des ramifications en C-24 des phytosterols de Physarum polycephalum et d'Ochromonas danica

The side chain C-24 alkylation mechanism of phytosterols of Physarum polycephalum and Ochromonas danica, cultured in a nutrient medium containing methionine-CD₃, has been studied. Depending on species, five or four deuterium atoms were incorporated respectively in C-24 ethyl phytosterols. No relation could be established between the stereochemistry of C-24 and the alkylation mechanism at this position.     

Biosynthesis of the chlorosulpholipids of Ochromonas danica

Radioactively labelled acetate and malonate have been shown to be readily incorporated into the chlorosulpholipids of Ochromonas danica. Even-numbered, saturated fatty acids (6C-16C) are also readily incorporated but their efficiency of incorporation increases with increasing chain length. Oleic and linoleic acids are poorly incorporated. Docosane-1,14-disulphate-[13-¹⁴C] is readily chlorinated to give mono- to hexa-chloro-derivatives. Evidence is presented to show that chlorination of the chlorosulpholipids is a sequential process.     

Manipulation by 25-azacycloartanol of the relative percentage of C10, C9 and C8 side-chain sterols in suspension cultures of bramble cells

The addition of 25-azacycloartanol to the medium of suspension cultures of bramble cells resulted, after 6 weeks of growth, in a large decrease in the percentage of C₁₀ side-chain sterols, sitosterol and isofucosterol (83 % of the total in the control, 9 % in the treated cells), and in a spectacular increase in the percentage of C₈ side-chain sterols, cycloartenol, desmosterol and cholesterol (less than 1 % in the control, 53 % in the treated cells). In addition the relative percentage of C₉ side-chain sterols, mainly 24-methylene cholesterol increased significantly (from 16 to 37 %). A secondary effect of 25-azacycloartanol consisted in an increase of the percentage of Δ²⁴ sterols and in a decrease of the percentage of sterols with a saturated side chain. These results are in agreement with an inhibition by 25-azacycloartanol of the C-24 and C-28 methyltransferases and of the Δ²⁴ reductase.     

Incorporation of 4-14C-22,23-3 H-sitosterol Into diosgenin by Dioscorea deltoidea tissue suspension cultures

Sitosterol-4-¹⁴C-22,23-³H with a ³H/¹⁴C ratio of 5.0 was incorporated into diosgenin such that the ³H/¹⁴C ratio in diosgenin was approx. 2.3. The per cent of ¹⁴C incorporation was 0· and for ³H was 0·42%. The results indicate that C-23 is not involved in the transformation of sitosterol into diosgenin. The first step in the cyclization of the sterol side-chain may either involve oxygenation at C-26 or direct hydroxylation at C-22 via a mixed function oxidase system. Other indirect evidence suggests that the C-26 oxygenation mechanism is operative.     

4-Hydroxyisoleucine from seed of Trigonella foenum-graecum

The principal free amino acid present in seed of Trigonella foenum-graecum has been isolated and identified as (2S, 3R, 4R)-4-hydroxyisoleucine. This compound has not been reported previously as a constituent of higher plants, but it is a component of the toxic peptide, γ-amanitin, produced by Amanita phalloides. The (2S, 3R, 4R)-isomer lactonizes readily under acidic conditions, whilst strong acid causes partial epimerization. The (2R, 3R, 4R)-isomer forms a minor component of Trigonella seed. The 4-hydroxyisoleucine content of fenugreek increases during the growth of seedlings and plants, and ¹⁴C-isoIeucine was used effectively as a biosynthetic precursor.     

Amo 1618 effects on incorporation of 14C-MVA and 14C-acetate into sterols in Nicotiana and Digitalis seedlings and cell-free preparations from Nicotiana

Incorporation of radioactivity from acetate-[¹⁴C] and MVA-[¹⁴C] into sterols and sterol precursors in tobacco was inhibited by Amo 1618; differing patterns of accumulation were obtained with the two precursors, suggesting more than one point of inhibition. This was borne out with cell-free preparations with which it was demonstrated that both HMG-CoA reductase and squalene-2,3-epoxide cyclase were inhibited, the latter more strongly than the former. GLC analysis of gross sterol and hydrocarbon fractions confirmed previous indications that incorporation of radioactivity into individual sterols was inhibited by Amo 1618. Finally, incorporation of MVA-[¹⁴C] into sterols and sterol precursors of Digitalis was significantly altered by the retardant, thus expanding the generality of the relationship between sterol (particularly 4-desmethylsterol) biosynthesis inhibition and retardant effect.     

Stereochemical aspects of the conversion of cyclopeptine into dehydrocyclopeptine by cyclopeptine dehydrogenase from Penicillium cyclopium

Cyclopeptine dehydrogenase, an enzyme from Penicillium cyclopium, catalyses the reversible transformation of the benzodiazepine alkaloids cyclopeptine and dehydrocyclopeptine. By the dehydrogenation of cyclopeptine two hydrogen atoms are removed from the positions 3 and 10. It was demonstrated that, from the two optical isomers of cyclopeptine, only the naturally occurring 3S-compound was used as substrate by cyclopeptine dehydrogenase. To test the stereospecificity of the enzyme with respect to the second hydrogen which is eliminated from C-10 a mixture of cyclopeptine-3S-[10R-³H₁] and cyclopeptine-3R-10S-³H₁] was prepared. The 3S-isomer was transformed by the enzyme into radioactively labelled dehydrocyclopeptine. This demonstrated that cyclopeptine dehydrogenase removes the 10-proS hydrogen atom from the cyclopeptine molecule. Because the formed dehydrocyclopeptine has the trans-configuration it is probable that a synperiplanar elimination takes place. The hydride ion removed from cyclopeptine is transferred to the 4-proR-position of NAD⁺. Cyclopeptine dehydrogenase thus belongs to the A-specific dehydrogenases.     

Observations on the biosynthesis of 24-methylcholesterol and 24-ethylcholesterol by Zea mays

Examination of the sterols of Zea mays shoots has established that the 24-ethylcholesterol is predominately the 24α-epimer, sitosterol, but the 24-methylcholesterol is a mixture of the 24α- and 24β-epimers. After incubation of Z. mays shoots with [2-¹⁴C, (4R)4-³H₁]mevalonic acid the sitosterol had a ³H: ¹⁴C atomic ratio of 2.09:5 which is consistent with previous results indicating that a Δ²⁴⁽²⁵⁾ -sterol is implicated in its biosynthesis. By contrast, the 24α- and 24β-methylcholesterol mixture had a higher ³H: ¹⁴C atomic ratio of 2.82:5. This can be explained by the operation of two routes for the elaboration of the 24-methylcholesterol side chain. One may proceed via Δ²⁴⁽²⁵⁾- and Δ²⁴⁽²⁵⁾-sterols to produce the 24α-methylcholesterol with a ³H: ¹⁴C atomic ratio of 2:5. The other route may involve reduction of either a Δ²⁴⁽²⁸⁾-, a Δ²³- or a Δ²⁵-sterol intermediate to give the 24β1-methylcholesterol with a ³H: ¹⁴C atomic ratio of 3:5. The proportion of these two labelled compounds in the mixture then determines the observed ³H: ¹⁴C atomic ratio (2.82:5). Some evidence for the formation of a Δ²⁵-compound, cyclolaudenol, by Z. mays shoots was provided by incorporation studies employing either [2-¹⁴C]mevalonic acid or [Me-¹⁴C]methionine as the sterol precursor.     

Mechanism of alkylation at C-24 during ergosterol biosynthesis in Phycomyces blakesleeanus

Ergosterol isolated from Phycomyces blakesleeanus grown in the presence of methionine-[methyl-²H₃] contained two ²H atoms showing that one ²H atom is lost during transmethylation. Ergosterol isolated from P. blakesleeanus grown in the presence of mevalonic acid-[2-¹⁴C,(4R)-4-³H₁] had a ¹⁴C:³H atomic ratio of 5:3. Chemical degradation of 2,3-dimethylbutanal obtained by ozonolysis of the doubly-labelled ergosterol showed that the ³H atom originally at C-24 of lanosterol is transferred to C-25 of ergosterol during transmethylation. The mechanism of formation of the ergosterol side chain in P. blakesleeanus is presented.     

Stereospecificity of sterol biosynthesis in Calendula officinalis flowers

Flowers of Calendula officinalis were incubated with mevalonic acid doubly labelled with ¹⁴C in position 2 and ³H in positions 2R, 2S, 4R or 5R,S and the [³H/¹⁴C] ratios determined in squalene β-sitosterol, stigmasterol, Δ⁷-sterols and stigmastan-3 β-ol. The results indicated that in the biosynthesis of these sterols: formation of the Δ⁷ double bond is associated with elimination of hydrogen from the 7β position, formation of the Δ⁵ double bond with elimination of hydrogens from the 5 and 6α positions, and formation of the Δ²² double bond with elimination of the 22-pro-S and 23 hydrogens. Demethylation in position 4 is associated with elimination of hydrogen from the 3α position whereas demethylation in position 14 occurs without hydrogen loss from position 15. Alkylation in position 24 is associated with hydrogen elimination from this position.     

Incorporation of molecular oxygen into caffeic acid by green Helianthus annuus

The results of experiments in which Helianthus annuus were grown in the light in an atmosphere enriched with oxygen-18 indicated that the hydroxyl oxygen atoms in caffeic acid are derived from molecular oxygen.     

In vitro and in vivo biosynthesis of xanthophylls by the cyanobacterium Aphanocapsa

Of the six carotenoids identified in the cyanobacterium Aphanocapsa, β-carotene, zeaxanthin, echinenone and myxoxanthophyll are the major pigments, whilst β-cryptoxanthin and 3-hydroxy-4-keto-β-carotene are present only in trace amounts. With the exception of zeaxanthin, the other xanthophylls could be formed in vitro from [¹⁴C]phytoene in high yields, especially β-cryptoxanthin and 3-hydroxy-4-keto-β-carotene. In a time course experiment of xanthopyll biosynthesis the flow of radioactivity from [¹⁴C]phytoene was followed through the pools of phytofluene, lycopene, and β-carotene. The reaction sequence from phytoene to xanthophylls is sensitive in vitro to both difunone, an inhibitor of carotene desaturation, and CPTA, an inhibitor of cyclization.