Influence du milieu de culture sur la composition en sterols de Leptosphaeria typhae

C₂₇, C₂₈ and C₂₉ sterols have been isolated from a Leptosphaeria typhae culture grown in vitro in light on a synthetic medium. These products were characterized by GLC and MS. Saturated and mono-, di- and tri-unsaturated sterols are present, both free and esterified. There are significant differences between these sterols and those in the same fungus grown on “oat water”. Unexpectedly, cholesterol was detected in the latter case.     

The independence of photosynthesis and aerobiosis from sterol biosynthesis in bacteria

Sterols were present in neither of two representative species of photosynthetic bacteria, Rhodopseudomonas spheroides and Chromatium vinosum. These organisms were grown under conditions commonly viewed as anaerobic. However, such conditions did not prevent Saccharomyces cerevisiae from biosynthesizing sterols, although they did induce accumulation of both 4,4-dimethyl and 4-desmethyl intermediates. Since the photosynthetic organisms did not biosynthesize sterols, bacterial photosynthesis must not be mated genetically or functionally to sterol biosynthesis. In contrast to what the literature records, Escherichia coli, grown under fully aerobic conditions, also failed to contain sterols which indicates that bacterial aerobiosis does not necessarily imply either the presence of sterol biosynthesis or a requirement for an exogenous source of sterols. Among the lipids of E. coli was a substance with the formula C₁₆H₃₂O₂ which moved in silica gel TLC at a rate similar to that of sterols and may have been a keto-alcohol of the same formula already isolated from coliforms. In the photosynthetic bacteria the major neutral lipid after saponification was phytol, in agreement with expectation based on the presence of bacteriochlorophyll-a.     

Sur le sterol a 26 atomes de carbone de l'algue rouge Rhodymenia palmata

Triterpene alcohols and sterols of the red alga Rhodymenia palmata have been investigated. Cycloartanol, 31-nor-cycloartanol and the C₂₆ sterol 24-dimethylchola-5,22-diene-3β-ol (1) have been identified. Feeding experiments have been performed using 1-¹⁴C-acetate, 5-¹⁴C-mevalonic acid or ¹⁴C-methylmethionine. The C₂₇, C₂₈ and C₂₉ sterols incorporate radioactivities but the C₂₆ sterol is unlabelled after each experiment; its possible origin is discussed.     

Sterols of Goniotrichum elegans

The sterol fraction was examined from cultures of the filamentous red alga Goniotrichum elegans. Brassicasterol accounted for nearly half of the total sterol and was accompanied by cholesterol (24%) as well as a number of minor components. This is the first record of brassicasterol as a major sterol in the Rhodophycophyta. The occurrence of this C₂₈ major sterol may be of taxonomic importance in determining the relationship of the Goniotrichales to the other red algae of which have C₂₇ major sterols.     

Sterols of Xanthoria parietina: Evidence for two sterol ‘pools’ and the identification of a novel C,8 triene,ergosta-5,8,22-trien-3β-ol

Sterols extracted from Xanthoria parietina with organic solvents and released by saponification of the residual lichen tissue were analysed by GC-MS. The main components of the solvent-extractable sterols were two C₂₈ trienes and those of the more tightly bound sterols were ergost-5-en-3β-ol and two C₂₉ compounds. The structures of the C₂₈ compounds were shown to be ergosta-5,7,22-trien-3β-ol, Ia (ergosterol) and the previously unreported ergosta-5,8,22-trien-3β-ol, IIa, for which the name lichesterol is proposed. The main C₂₉ sterol was identified as (24R)-24-ethylcholesta-5,22-dien-3β-ol (poriferasterol).     

Sterols of Amphidinium species in the Operculatum Clade: Predominance of cholesterol instead of Δ8(14) sterols previously considered Amphidinium-specific biomarkers

The dinoflagellates Amphidinium carterae and Amphidinium corpulentum have been previously characterized as having Δ⁸⁽¹⁴⁾-nuclear unsaturated 4α-methyl-5α-cholest-8(14)-en-3β-ol (C_28:1) and 4α-methyl-5α-ergosta-8(14),24(28)-dien-3β-ol (amphisterol; C_29:2) as predominant sterols, where they comprise approximately 80% of the total sterol composition. These two sterols have hence been considered as possible major sterol biomarkers for the genus. Here, we have examined the sterols of four recently identified species of Amphidinium (Amphidinium fijiense, Amphidinium magnum, Amphidinium theodori, and Amphidinium tomasii) that are closely related to Amphidinium operculatum as part of what is termed the Operculatum Clade to show that each species has its sterol composition dominated by the common dinoflagellate sterol cholesterol (cholest-5-en-3β-ol; C_27:1), which is found in many other dinoflagellate genera, rather than Δ⁸⁽¹⁴⁾ sterols. While the Δ⁸⁽¹⁴⁾ sterols 4α-methyl-5α-cholest-8(14)-en-3β-ol and 4α,23,24-trimethyl-5α-cholest-8(14),22E-dien-3β-ol (C_30:2) were present as minor sterols along with another common dinoflagellate sterol, 4α,23,24-trimethyl-5α-cholest-22E-en-3β-ol (dinosterol; C_30:1), in some of these four species, amphisterol was not conclusively observed. From a chemotaxonomic perspective, while this does reinforce the genus Amphidinium's ability to produce Δ⁸⁽¹⁴⁾ sterols, albeit here as minor sterols, these results demonstrate that caution should be used when considering Δ⁸⁽¹⁴⁾ sterols, especially amphisterol, as Amphidinium-specific biomarkers within these species where cholesterol is the predominant sterol.     

24β-ethylsterols,n-alkanes and n-alkanols of Clerodendrum splendens

The sterols of Clerodendrum splendens, an angiosperm belonging to the family Verbenaceae, were found to possess a 24β-ethyl group. No other sterols were detected. The major sterol was 24β-ethylcholesta-5,22E,25(27)-trien-3β-ol [also known as 25(27)-dehydroporiferasterol]. A very small amount of what may have been its 22-dihydroderivative, clerosterol [also known as 25(27)-dehydroclionasterol] was also found. The dominant n-alkane was C₂₉ (n-nonacosane) and the dominant n-alkanol was C₂₈ (n-octacosanol).     

Sterols,sterol esters and fatty acids of Botrydium granulatum, Tribonema aequale and Monodus subterraneus

The composition of the sterols, sterol esters and fatty acids has been determined in 8-, 11- and 14-day cultures of three members of the Xanthophyceae, Botrydium granulatum, Tribonema aequale and Monodus subterraneus. The main sterols, whether esterified or unesterified, were cholesterol and clionasterol, whose proportions do not vary with age of culture. Much smaller quantities of cycloartenol and 24-methylenecycloartanol were also found in all three algae. The C₁₆ fatty acids are the most common fatty acids in all three algae with C_16:1 being particularly abundant. B. granulatum and T. aequale, however, differ from M. subterraneus in having polyunsaturated C₁₆ fatty acids and a smaller proportion of C_20:5.     

Growth of Candida albicans in the presence of hydrocarbons: a correlation between sterol concentration and hydrocarbon uptake

Summary Candida albicans KTCC 89062 grown on n-alkanes showed higher levels of sterol content as compared to glucose-grown cells. Certain sterols, such as lanosterol, were significantly reduced in cells grown on n-alkanes, while others, such as ergosterol, increased in these cells. Sterol fractions declined as the chain length of the n-alkanes increased. Ergosterol supplementation of the chemically defined medium showed an increase in the uptake of dodecane (C₁₂) by cells grown on such medium. Increase in the concentration of ergosterol supplementation resulted in an increase in C₁₂ uptake. The uptake of C₁₂ was not stimulated by ergosterol supplementation in the case of non-viable yeast cells.     

Functional importance for developmental regulation of sterol biosynthesis in Acanthamoeba castellanii

The sterol metabolome of Acanthamoeba castellanii (Ac) yielded 25 sterols. Substrate screening of cloned AcCYP51 revealed obtusifoliol as the natural substrate which converts to ?^8,14-sterol (<95%). The combination of [²H₃-methyl]methionine incubation to intact cultures showing C₂₈-ergosterol incorporates 2-²H atoms and C₂₉-7-dehydroporiferasterol incorporates 5 ²H-atoms, the natural distribution of sterols, CYP51 and previously published sterol methyltransferase (SMT) data indicate separate ?²⁴⁽²⁸⁾- and ?²⁵⁽²⁷⁾-olefin pathways to C₂₈- and C₂₉-sterol products from the protosterol cycloartenol. In cell-based culture, we observed a marked change in sterol compositions during the growth and encystment phases monitored microscopically and by trypan blue staining; trophozoites possess C₂₈/C₂₉-?^5,7-sterols, viable encysted cells (mature cyst) possess mostly C₂₉-?⁵-sterol and non-viable encysted cells possess C₂₈/C₂₉-?^5,7-sterols that turnover variably from stress to 6-methyl aromatic sterols associated with changed membrane fluidity affording lysis. An incompatible fit of steroidal aromatics in membranes was confirmed using the yeast sterol auxotroph GL7. Only viable cysts, including those treated with inhibitor, can excyst into trophozoites. 25-Azacycloartanol or voriconazole that target SMT and CYP51, respectively, are potent enzyme inhibitors in the nanomolar range against the cloned enzymes and amoeba cells. At minimum amoebicidal concentration of inhibitor amoeboid cells rapidly convert to encysted cells unable to excyst. The correlation between stage-specific sterol compositions and the physiological effects of ergosterol biosynthesis inhibitors suggests that amoeba fitness is controlled mainly by developmentally-regulated changes in the phytosterol B-ring; paired interference in the ?^5,7-sterol biosynthesis (to ?^5,7) - metabolism (to ?⁵ or 6-methyl aromatic) congruence during cell proliferation and encystment could be a source of therapeutic intervention for Acanthamoeba infections.     

La diatomée Chaetoceros simplex calcitrans Paulsen et son environnement. II. Effets de la lumière et des irradiations ultra-violettes sur la production primaire et la biosynthèse des stérols

12-day cultures of the diatom Chaetoceros simplex calcitrans Paulsen in sea water have been analysed under different conditions of light. With a $\text{12 h}\text{24 h}$ photophase the primary production is 106 % higher than under continuous light but the unsaponifiable fraction is lower (?42 %) and the sterols increase by 100 %. When ultra-violet irradiation is added to the $\text{12 h}\text{24 h}$ photophase the primary production is lowered (?56 %) but the unsaponifiable fraction increases by 191 %, and the sterols by 110 %. When ultra-violet irradiation is added to the continuous light there is an increase in primary production (+30 %) and a decrease in the unsaponifiable fraction (?16%).Modifications of the sterol composition are reported. C₂₆ sterols have never been detected in these experiments.     

Effects of sterols,rat hematin and coproporphyrin on the free-living stages of Nematospiroides dubius and Nippostrongylus brasiliensis

Nematospiroides dubius, unlike the closely related nematode Nippostrongylus brasiliensis, lacks a sterol requirement for the completion of its development to the L₃ stage in an aqueous suspension of formalin-killed Escherichia coli. These larvae were justascapable of completing their development to adults in mice as those grown on charcoal-feces cultures. In addition, sterols had a toxic effect on the larvae of N. dubius which was removed by substituting a Krebs-Ringer solution for distilled water.In order to interpret the absence of a sterol requirement for the development of N. dubius larvae, an analysis of the egg lipids for both species was made. N. brasiliensis had about twice the sterol concentration of N. dubius eggs. A comparison of the development for both species showed, however, that N. brasiliensis grows more than twice as much as N. dubius to reach the L₃ larval stage. Therefore, the amount of endogenous sterol is insufficient for N. brasiliensis to develop from the egg to the L₃ stage.N. dubius and N. brasiliensis also differ in their porphyrin requirements. Unlike N. brasiliensis, coproporphyrin did not increase the size of N. dubius larvae so that they were comparable to those grown on charcoal-feces cultures. Coproporphyrin did result in larvae that were more robust in appearance than those grown without a supplement.     

STEROLS OF PORPHYRIDIUM(RHODOPHYTA)1,2

Species of the unicellular Porphyridium have been examined for their sterol content. Clones of 4 species maintained in axenic, chemically-defined culture were analyzed—these included P. sordidum Geitler, P. purpureum (Bory) Ross, P. aerugineum Geitler and P. violaceum Kormnann(P. griseum Geitler was not available to use for examination). The major sterol was 22-dehydrocholesterol in all except P. aerugineum in which there was a mixture of this sterol, cholesterol and higher sterols. Traces of C₂₈ and C₂₉ sterols were detected in most instances as well.     

Sterols from some sponges

The sterol composition of four sponges was determined by a combination of gas chromatography and mass spectrometry. Cliona viridis and Chondrosia reniformis contained mainly C₂₇-C₂₉Δ⁵ mono- and di-unsaturated sterols. Halichondria bowerbanki and Hymeniacidon sanguinea contained stanols and Δ⁵-sterols. Cholestanol was the major component of the sterol mixtures.     

STEROLS OF 14 SPECIES OF MARINE DIATOMS (BACILLARIOPHYTA)1

The sterol compositions of 14 species of marine diatoms were determined by gas chromatography and gas chromatography-mass spectrometry. A variety of sterol profiles were found. The sterols 24-methylcholesta-5,22E-dien-3β-ol, cholest-5-en-3β-ol, and 24-methylcholesta-5,24(28)-dien-3β-ol, previously described as the most common sterols found in diatoms, were major sterols in only a few of the species. In light of this and other recent data, it is clear that these three sterols are not typical constituents of many diatom species. Most of the centric species examined had 24-methylcholesta-5,24(28)-dien-3β-ol and 24-methylcholest-5-en-3β-ol as two of their major sterols. The exception was Rhizosolenia setigera, which possessed cholesta-5,24-dien-3β-ol as its single major sterol. In contrast to the centric species, the pennate diatoms examined did not have any particular sterols common to most species. Minor levels ofΔ⁷-sterols, rarely found in large amounts in diatoms, were found in four species. C₂₉sterols were found in many species; seven contained 24-ethylcholest-5-en-3β-ol and three contained 24-ethylcholesta-5,22E-dien-3β-ol, reinforcing previous suggestions that C₂₉ sterols are not restricted to higher plants and macroalgae. 24-Ethylcholesta-5,22E-dien-3β-ol may prove to be useful for taxonomy of the genus Amphora and the order Thalassiophysales. A major sterol of Fragilaria pinnata was the uncommon algal sterol 23,24-dimethylcholesta-5,22E-dien-3β-ol. Cholesta-5,24-dien-3β-ol was the only sterol found in the culture of Nitzschia closterium. This differed from previous reports of 24-methylcholesta-5,22E-dien-3β-ol as the single major sterol in N. closterium. Two C₂₈ sterols possessing an unusual side chain were found in Thalassi-onema nitzschioides, a C_28:2 sterol (16%) and a C_28:1 sterol in lower abundance (2.5%), which may be 23-methylcholesta-5,22E-dien-3β-ol and 23-methyl-5α-cholest-22E-en-3β-ol, respectively. The species Cylindrotheca fusiformis, T. nitzschioides, and Skeletonema sp. may be useful as direct sources of cholesterol in mariculture feeds due to their moderate to high content of this sterol.     

Dehydrodinosterol,dinosterone and related sterols of a non-photosynthetic dinoflagellate, Crypthecodinium cohnii

The heterotrophic dinoflagellate Crypthecodinium cohnii contained the 4α-methyl sterols, dinosterol, dehydrodinosterol (4α,23,24-trimethylcholesta-5,22-dien-3β-ol) and the tentatively identified 4α,24-dimethyl-cholestan-3β-ol and 4α,24-dimethylcholest-5-en-3β-ol. The major 4-demethyl sterol was cholesta-5,7-dien-3β-ol which was accompanied by a smaller amount of cholesterol and traces of several other C₂₇,C₂₈ and C₂₉ sterols. In addition, a 3-oxo-steroid fraction was isolated and the major component identified as dinosterone (4α,23,24-trimethylcholest-22-en-3-one). The possible biosynthetic relationships of these compounds are discussed.     

DNA and cholesterol biosynthesis in synchronized embryonic rat fibroblasts: I. Temporal relationships between HMG-CoA reductase activity,sterol biosynthesis and thymidine incorporation into DNA

Temporal relationships between hydroxymethylglutaryl-CoA reductase activity, biosynthesis of C₂₇ sterols, and [³H]thymidine incorporation into DNA were studied in a rat embryo fibroblast cell line synchronized by double thymidine block and cultured in cholesterol-containing medium. Cyclic variations of HMG-CoA reductase activity and C₂₇ sterols occurred, with two maxima in S and G₂M phases; the relative shortness of the G₁ phase (3 h) in these cells could be responsible for the shift of sterol synthesis in the S phase. No noticeable variation of the individual C₂₇ sterols was observed during the entire cell cycle. In each experiment, there was a good linear correlation between HMG-CoA reductase activity and C₂₇ sterol synthesis, but from one experiment to another, a given level of enzymatic activity led to varying levels of [2-¹⁴C]acetate incorporation into sterols. In our experimental conditions, total HMG-CoA reductase activity is measured, and the preceding observation could be explained by a varying degree of phosphorylation of the enzyme depending on the metabolic state of the cells at the start of the experiment. The cyclic variations of the enzyme activity seem to be due more to increased synthesis at given times of the cycle than to periodic dephosphorylation. We question the existence of a relationship between cell division and cyclic sterol synthesis occurring in cells cultured in cholesterol-containing medium.     

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.     

The fate of radiolabelled C28 and C29 phytosterols in the honey bee

The fate of radiolabelled campesterol, sitosterol and 24-methylenecholesterol fed in chemically-defined diets to honey bee (Apis mellifera L.) workers was determined. At various intervals, sterols of prepupae, newly emerged adults and queens were analyzed qualitatively, quantitatively and radiochemically and it was determined that there was not sufficient radioactivity associated with cholesterol and/or desmosterol in any of the samples to verify that any of the three C₂₈ and C₂₉ sterols was dealkylated and converted to cholesterol. Similarly, there was no evidence for the conversion of campesterol or sitosterol to 24-methylenecholesterol. It was concluded that the major portion of the sterols incorporated into the tissues of the brood larvae originated from the worker bees used to establish the colony. There is good evidence supporting the premise that the workers can make available sterols from their endogenous pools to the nutrient in the hive and that they can replenish these sterols with those from the artificial diet. The queen is also able to replenish sterols utilized in egg production from those obtained by the workers from the artificial diet, and at the end of nine weeks queens contained more than four times as much sterol, on a ‘μg sterol per g fresh weight’ basis, than was found in fertile queens at the beginning of the test period.     

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

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