The metabolism of cycloartenol,lanosterol, 24-methylenecholesterol and fucosterol in Chlorella ellipsoidea

Lanosterol and cycloartenol labelled with tritium at C-2, and 24-methylenecholesterol and fucosterol labelled with tritium at C-2 and C-4 were fed to actively growing cultures of Chlorella ellipsoidea. Lanosterol and cycloartenol were converted to each of the five desmethyl sterols of C. ellipsoidea. Lanosterol was more efficiently incorporated than cycloartenol.Although there was some evidence for the reduction of the 24-methylene group, it was apparent that 24-methylene-cholesterol was converted primarily to the C₂₉ sterols, clionasterol and poriferasterol. Labelled fucosterol was reduced at the 24(28) double bond, producing clionasterol.     

Sterols of the mycobiont and phycobiont isolated from the litchen Xanthoria parietina

The mycobiont, Xanthoria parietina, and the phycobiont, Trebouxia decolorans, of the lichen X. parietina have been cultured separately and their sterols analysed. X. parietina contained ergosterol and lichesterol as the major constituents together with lower levels of three other C₂₈ sterols. Culture of the mycobiont in the presence of [CD₃]-methionine resulted in the incorporation of two deuterium atoms into the C-24 methyl group of these sterols demonstrating that a 24-methylene intermediate was produced as occurs in other fungi. The phycobiont, T. decolorans contained predominantly poriferasterol with lower levels of clionasterol, ergost-5-en-3β-ol, brassicasterol and cholesterol. Two other Trebouxia spp. (213/3 and 219/2) contained similar sterol mixtures.     

Biosynthesis of α-spinasterol from (2- 14C (4R)-4-3H1) mevalonic acid by Spinacea oleracea and Medicago sativa

Leaves of Spinacea oleracea and Medicago sativa were incubated with (2-¹⁴C, (4R)-4³H₁ mevalonic acid and the sterols isolated. Cycloartenol had a ³H: ¹⁴C atomic ratio of 6:6 whilst oxidation to cycloartenone resulted in a ratio of 5:6 showing that tritium was present in the 3α-position and that the cycloartenol was symmetrically labelled. Separation of the 4-demethyl sterols gave α-spinasterol and a mixture of stigmast-7-enol and 24-methylcholest-7-enol, which had ³H: ¹⁴C atomic ratios of 3:5. Ozonolysis of α-spinastery] acetate gave the terminal side chain fragment as 2-ethyl-3-methyl butanoic acid. The acid contained ¹⁴C but no tritium thus showing that the C-24 hydrogen of cycloartenol is lost during the alkylation reactions leading to the C-24 ethyl group of α-spinasterol.     

Sterols of Mediterranean Florideophyceae

The distribution of sterols in 31 Mediterranean Florideophyceae has been investigated. Cholesterol is present in the greatest majority of the species examined, while the occurrence of other C-27 sterols (desmosterol, 22-dehydrocholesterol, liagosterol and cholest-7-en-3β-ol) is much more restricted. Two species (Rytiphloea tinctoria and Vidalia volubilis) contain, in addition to C-27 sterols, large amounts of C-28 and C-29 compounds.     

A sterol methyltransferase from bean rust uredospores,Uromyces phaseoli

A methyltransferase(s) that catalyzes the transfer of the methyl group from S-adenosylmethionine to a sterol acceptor was solubilized with Triton X-100 and partially purified from bean rust uredospores (Uromyces phaseoli). Zymosterol was the most active substrate tested while desmosterol and lanosterol exhibited good activity. The products were sterols with either a methylene or ethylidene group at the C-24 position. Direct evidence for the synthesis of the ethylidene group was obtained by using 24-methylenecholesterol as a substrate.     

Sterol methyltransferase from Uromyces phaseoli: An investigation of the first and the second transmethylation reactions

The two-carbon unit at C-24 of many plant, algal and fungal sterols is known to be synthesized by two successive transmethylations with S-adenosylm     

Biochemical effects of miconazole on fungi. II. Inhibition of ergosterol biosynthesis in Candida albicans.

The effects of the antifungal agent miconazole nitrate on the ergosterol biosynthesis in Candida albicans were investigated after in vitro contact with the drug for 1, 4, 16 and 24 h. A time- and dose-(2.10^?10–10^?4 M) dependent inhibition of [¹⁴C]acetate incorporation into ergosterol was observed. Fifty percent inhibition of the acetate incorporation into ergosterol was found after 1 h incubation in the presence of 10^?9 M miconazole. Simultaneously 24-methylenedihydrolanosterol, lanosterol, obtusifoliol, 4,14-dimethylzymosterol and 14-methylfecosterol accumulated.The accumulation of 14 α-methyl sterols suggests that this antifungal agent is a potent inhibitor of one of the metabolic steps involved in the demethylation at C-14. The absence of 24-methyl sterols and of sterols with a C-22 [23] double bond in miconazole treated C. albicans indicates that miconazole also inteferes with the reduction of the 24(28)-double bond and with the introduction of the 22(23)-double bond.Miconazole also intervenes to a small extent in triglyceride synthesis. However, in all circumstances studied, ergosterol biosynthesis was affected at lower doses than those interfering with the acetate incorporation into triglycerides. 16 and 24 h of incubation in the presence of miconazole (≥ 10^?6 M) also resulted in an increased fatty acid synthesis.It is suggested that the miconazole-induced inhibition of the C-14 demethylation may be at the origin of the previously observed permeability changes in miconazole treated C. albicans.     

Recent Developments in Nematode Steroid Biochemistry

Current knowledge of steroid nutrition, metabolism, and function in free-living, plant-parasitic and animal-parasitic nematodes is reviewed, with emphasis upon recent investigation of Caenorhabditis elegans. A number of 4-desmethylsterols with a trans-A/B ring configuration can satisfy the steroid nutritional requirement in C. elegans, but sterols with a cis-A/B ring configuration or trans-A/B sterols with a 4-methyl group cannot. C. elegans removes methyl or ethyl substituents at C-24 of the plant sterols sitosterol, campesterol, stigmasterol, stigmastanol, and 24-methylene-cholesterol to produce various sterols with structures partially dependent upon that of the dietary sterol. Additional metabolic steps in C. elegans include reduction of Δ²²- and Δ⁵-bonds, C-7 dehydrogenation, isomerization of a Δ⁷-bond to a Δ⁸⁽¹⁴⁾-bond, and 4α-methylation. An azasteroid and several long-chain alkyl amines interfere with the dealkylation pathway in C. elegans by inhibiting the Δ²⁴-sterol reductase; these compounds also inhibit growth and reproduction in various plant-parasitic and animal-parasitic nematodes. A possible hormonal role for various steroids identified in nematodes is discussed.     

The occurrence of C29 sterols with different configurations at C-24 in Cucurbita Pepo as shown by 270 MHz NMR

The 270MHz NMR spectra of the major sterols of pumpkin seeds show that the configuration at C-24 of 24-ethyl-5α-cholesta-7,22,25-trien-3β-ol and 24-ethyl-5α-cholesta-7,25-dien-3β-ol is 24β_F = (24S) whereas the α-spinasterol has the 24α_F = (24S) configuration.     

Co-occurrence of chondrillasterol and spinasterol in two cucurbitaceae seeds as shown by 13C NMR

¹³C NMR spectroscopy of the sterols isolated from seeds of bottle gourd (Lagenaria leucantha var. gourda) and water melon (Citrullus battich) has demonstrated the co-occurrence of the C-24 epimers spinasterol and chondrillasterol.     

Studies on the C-24 configurations of Δ7-sterols in theseeds of Cucurbita maxima

Uncertainties surrounding the structures of the Δ⁷-sterols in the seeds of Cucurbita maxima have been resolved. Seven components were found by TLC, GLC, HPLC, mass spectrometry and ¹H NMR. They were 24β-ethyl-5α-cholesta-7,22,25(27)-trien-3β-ol, 24β-ethyl-5α-cholesta-7,25(27)-dien-3gb-ol, avenasterol, spinasterol, 24-dihydrospinasterol, 24ζ-methyllathosterol and 25(27)-dehydrofungisterol. The ¹H NMR spectra indicated that the sterols with an ethyl substituent at C-24 occurred in the absence of their C-24 epimers. This seems to be the first instance of the detection of 25(27)-dehydrofungisterol in a higher plant.     

Minor sterols of marine invertebrates 37. Isolation of novel coprostanols and 4α-methyl sterols from the tunicate Ascidia nigra

The complex sterol mixture isolated from $\text{A, nigra}$ was found to contain a low level of Δ⁴-3-keto steroids, 5β-stanols and 4α-methyl sterols in addition to regular (4-demethyl) sterols. The following new marine sterols were isolated and identified using MS and 360 MHz NMR: 5β-cholest-22E-en-3β-ol, 24S-methyl-5β-cholest-22E-en-3β-ol, 24-methylene-5β-cholestan-3β-ol, both epimers at C-24 of 4α-methyl-24-ethyl-5α-cholest-22E-en-3β-ol, 4α, 22ξ, 23ξ-(or 24ξ-)trimethyl-5α-cholest-8(14)-en-3β-ol and (22S, 23S, 24S)-4α-24-dimethyl-22, 23-methylene-5α-cholestan-3β-ol. The latter sterol and 23-demethylgorqosterol have opposite configurations at C-22, C-23, and C-24; the Δ⁸⁽¹⁴⁾ sterol has an unprecedented side chain.     

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.     

Biosynthesis of Δ5.23 sterols in etiolated coleoptiles from Zea mays

In addition to the previously found ergosta-5, E-23-dien-3β-ol and 5α-ergosta-7, E-23-dien-3β-ol, the following Δ23 sterols have been identified in etiolated maize coleoptiles: cyclosadol, 4α, 14α-dimethyl-5α-ergosta-8, E-23-dien-3β-ol, 4α, 14α-dimethyl-9β, 19-cyclo-5α-ergosta-8, E-23-dien-3β-ol and 4α-methyl-5α-ergosta-7, E-23-dien-3β-ol. The incubation of maize coleoptile microsomes in the presence of cycloartenol and of [¹⁴C-methyl]S-adenosyl methionine gave a mixture of labelled 24-methylene cycloartanol and cyclosadol. No trace of cyclolaudenol could be detected in these conditions. It is suggested that Δ²³ sterols are products of the C-24 methyltransferase reaction and they probably do not arise from a Δ²⁴ → Δ²³ isomerization occurring at a later stage of the biosynthesis. The Δ¹³-sterols may play an intermediary role in the biosynthesis of 24-methyl sterols in this plant material.     

Stereochemical aspects of the biosynthesis of the side chain of 9beta, 19-cyclopropyl sterols in maize seedlings treated with tridemorph

9β, 19-Cyclopropyl sterols such as 24-methyl pollinastanol accumulate dramatically in maize (Zea mays L. var LG 11) seedlings treated with Tridemorph (2,6-dimethyl-N-tridecyl-morpholine), a systemic fungicide (M. Bladocha, P. Benveniste, Plant Physiol 1983 41: 756-762). In contrast to the situation in control plants where 24-ethyl sterols predominate largely, 24-methyl sterols were more than 98% of total cyclopropyl sterols. In addition, 24-methyl cyclopropyl sterols were a mixture of (24-R)- and (24-S)-24-methyl epimers and are similar in that respect to the 24-methyl cholesterol of control plants. The presence of two epimers at C-24 has been previously explained by the operation of two routes (M. Zakelj, L. J. Goad, Phytochemistry 1983 22: 1931-1936). One may proceed via Δ²⁴⁽²⁸⁾- and Δ²⁴⁽²⁵⁾-sterols to produce the (24-R)-24-methyl epimer. The other route may involve reduction of either a Δ²⁴⁽²⁸⁾-, a Δ²³-, or a Δ²⁵-sterol intermediate to give the (24-S)-24-methyl epimer. Such intermediates have been searched for in excised Zea mays axes grown aseptically in the presence of Tridemorph and either [5-¹⁴C]mevalonic acid, or [Me-¹⁴C]-l-methionine. Whereas Δ²⁴⁽²⁸⁾- and Δ²⁴⁽²⁵⁾-cyclopropyl sterols were found in relatively large amounts, only traces of radioactivity were associated with Δ²⁵-sterols. Gas chromatography/mass spectrometry analysis of the sterols from axes grown in the presence of [Me-²H₃]-l-methionine showed that Δ²⁴⁽²⁸⁾-cyclopropyl sterols contained only two ²H atoms at C-28 as expected and that the 24-methyl pollinastanol fraction contained species with two ²H atoms and no species with three ²H atoms. These results indicate that both (24-R)- and (24-S)-epimers originate from a common Δ²⁴⁽²⁸⁾ precursor. After incubation of the axis with [5-¹⁴C,(4-R)-4-³H₁]mevalonic acid, the 24-methyl pollinastanol had a ³H:¹⁴C atomic ratio of 4:6 which is consistent with the intermediacy of a Δ²⁴⁽²⁵⁾-sterol. All these data are in accordance with a pathway where Δ²⁴⁽²⁸⁾-cyclopropyl sterols are isomerized to give Δ²⁴⁽²⁵⁾-cyclopropyl sterols which in turn would be reduced nonregiospecifically to yield both (24-R)- and (24-S)-24-methyl pollinastanols. A plausible mechanism for the reduction step is discussed.     

7-Oxo-24ξ(28)-dihydrocycloeucalenol,a potent inhibitor of plant sterol biosynthesis

Cycloeucalenol-obtusifoliol isomerase from higher plant cells catalyses the opening of the cyclopropane ring of cycloeucalenol yielding obtusifoliol. 7-Oxo-24ξ(28)-dihydrocycloeucalenol was not a substrate but behaved like a potent inhibitor of the isomerase. The inhibition was reversible and highly specific; the inhibitor needed the presence of the 7-oxo group, the cyclopropane ring and the absence of a 4β-methyl group to be active. Other enzymes involved in plant sterol biosynthesis such as 2, 3-oxidosqualene-cycloartenol cyclase and S-adenosyl methionine cycloartenol C-24 methyltransferase were not inhibited by 7-oxo-24ξ(28)-dihydrocycloeucalenol. In vivo treatment of a suspension of bramble cells growing in a liquid medium with 7-oxo-24ξ(28)-dihydrocycloeucalenol resulted in a strong accumulation of 9β 19-cyclopropyl sterols confirming that the main cellular target of the inhibitor is the cycloeucalenol-obtusifoliol isomerase.     

Brassinosteroids and sterols from a green alga,Hydrodictyon reticulatum: Configuration at C-24

Two brassinosteroids, (24S)-24-ethylbrassinone [(22R,23R,24S)-2α,3α,22,23-tetrahydroxy-24-ethyl-5α-cholestan-6-one] and 24-epicastasterone [(22R,23R,24R)-2α,3α,22,23-tetrahydroxy-24-methyl-5α-cholestan-6-one] have been identified from Hydrodictyon reticulatum. Examination of the sterols of this alga has established that 24-ethylcholesterol is predominantly the 24α-epimer, but 24-methylcholesterol is a mixture of the 24α- and 24β-epimers. Thus, similarity with respect to the C-24 configuration was observed between the brassinosteroids and 4-demethylsterols.     

Effects of triazoles on fungi: V. Response by a naturally tolerant species,Mucor rouxii

The responses ofMucor rouxii to propiconazole, and in some cases etaconazole, with respect to lipid metabolism were compared with those ofAspergillus ochraceus andRhizopus stolonifer which exhibit higehr sensitivity to this triazole by factors of 50 and 10, respectively. Propiconazole inhibited the C-14 demethylation of lanosterol in each of the species tested, which resulted in a dose-related decrease in ergosterol and increase in C-14 methyl sterols. The principal C-14 methyl sterol that accumulated with inhibitor treatment was 24-methylene dihydrolanosterol. The tolerance ofM. rouxii could not be explained by reduced inhibitor uptake, alteration of the inhibitor binding site, or detoxification through metabolism since C-14 methyl sterols accumulated in mycelium treated with 2.0 μg/ml propiconazole, a concentration 40 times less than that required for 50% growth inhibition and at which no growth inhibition was detected in this species, and one that gave over 50% inhibition ofA. ochraceus. Other alterations in lipid metabolism that accompany treatment with sterol inhibitors in relatively sensitive species, i.e., accumulation of free fatty acids and increase in linoleic acid (C_18:2), were not observed inM. rouxii orR. stolonifer, but they were found inA. ochraceus. The results of this study suggest that the quantitative and perhaps the qualitative nature of the requirement for sterols may be different inM. rouxii, and perhaps other tolerant Mucorales, than in the more sensitive fungi.     

A reappraisal of sterol biosynthesis and metabolism in aphids

Aphids of Schizaphis graminum (Rondani) (biotype C) reared on its host-plant, Sorghum bicolor (L.) Moench, sequestered campesterol, stigmasterol and sitosterol. Aphids reared for 72 hr on holidic diets supplemented with [4-¹⁴C]-sitosterol contained both [¹⁴C]-sitosterol and [¹⁴C]-cholesterol, indicating that these aphids are capable of dealkylation at C-24. When aphids were reared on artificial diets containing [2-¹⁴C]-mevalonic acid, no detectable amounts of radioactively labelled desmethyl sterols, nor metabolic intermediates in sterol synthesis (i.e. squalene, 2,3-oxidosqualene, 4,4-dimethyl and 4-monomethyl sterols) were found to accumulate in their tissues. The relevance of these findings to previous research suggesting the ability of aphids, via their symbiotes, to synthesize sterols is discussed.     

Antioxidant properties and total phenolic contents of some tropical seaweeds of the Brazilian coast

Many types of macroalgae contain a wide range of bioactive compounds that have antioxidant potential. However, in contrast to terrestrial plants, only a few studies have reported the antioxidant activity of seaweeds. Therefore, extracts from 26 marine macroalgae species from the south and southeast coasts of Brazil were evaluated for their antioxidant activity, using the 2,2-diphenyl-2-picrylhydrazyl hydrate (DPPH) method and β-carotene/linoleic acid assay, and their total phenolic contents, through Folin–Ciocalteu method. Padina gymnospora, Sargassum vulgare, and Osmundaria obtusiloba presented the highest values of total phenolic content. Using β-carotene bleaching assay, Colpomenia sinuosa, Dictyota sp., Dichotomaria marginata, Ganonema farinosum, and Spyridia clavata presented up to 65 % of antioxidant activity. Some of the extracts showed more than 60 % of inhibition of DPPH in the lowest concentration (0.01 mg/mL), including Amansia sp., Bostrychia tenella, Cryptonemia seminervis, Hypnea musciformis, Plocamium brasiliense (1), and S. clavata. Both Amansia sp., and C. seminervis presented the most relevant antioxidant potential, with percentage of inhibition greater than 70 % in the three tested concentrations. These two species were then analyzed by nuclear magnetic resonance spectroscopy (NMR) and were selected for guided fractionation bioassay. They both presented lipid compounds, fatty acids, esters of fatty acids, triglycerides, and sterols as major components. The fractionation of extracts revealed that the organic fractions were responsible for the antioxidant activity. The results obtained through this work indicate that the analyzed seaweeds are a promising source of compounds with high antioxidant potential.