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 amansieae (rhodomelaceae: Rhodophyta)

Osmundaria prolifera, kuetzingia natalensis, Halopythis pinastroïdes and Vidalia fimbriata contain C₂₇ sterols as the major sterols. Six other species of the Amansieae, belonging to the genera Amansia, Vidalia, Lenormandia and Rythiphlaea, contain C₂₈-sterols as the major sterols.     

Sterols of the lichen Pseudevernia furfuracea

A mixture of C₂₇, C₂₈ and C₂₉ sterols was isolated from the lichen Pseudevernia furfuracea and characterized by means of GLC and MS. Mono-, di- and tri-unsaturated sterols were identified as well as a small amount of fully saturated sterols (stanols). Only a part of the total sterols present in the lichen tissue was easily extractable with organic solvents. Another portion was only obtained after saponification of the lichen residue remaining after extraction with organic solvents. The composition of these two fractions difrered considerably, the former contained predominantly 5a,8a-epidioxy-5a-ergosta-6,22-dien-3β-ol (ergosterol peroxide) and 24-ethylcholesta-5,22-dien-3β-ol while in the latter 24-ethylcholesta-5,22-dien- 3β-ol and C₂₈ triene sterols were the main components.     

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.     

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.     

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.     

The conversion of (24S)-24-ethylcholesta-5,22,25-trien-3β-ol into poriferasterol,both in vivo and with a cell-free homogenate of the alga Trebouxia sp.

[6-³H₁] (24S)-24-Ethylcholesta-5,22,25-trien-3β-ol added to the growth medium of a culture of Trebouxia sp. 213/3 was efficiently taken-up by the cells and converted into (24R)-24-ethylcholesta-5,22-dien-3β-ol (poriferasterol) which is one of the major sterols of this alga. A cell-free homogenate was obtained from Trebouxia which catalysed the NADPH-dependent reduction of [6-³H₁] (24S)-24-ethylcholesta-5,22,25-trien-3β-ol to yield poriferasterol. The δ²⁵-sterol reductase was found to be mainly localized in the microsomal fraction of the homogenate.     

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.     

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 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.     

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).     

Les sterols de l'Ascomycete Leptosphaeria typhae

A mixture of C₂₈ and C₂₉ sterols have been isolated from Leptosphaeria typhae grown in vitro on “oat water” and characterized by GLC and MS. Mono-, di- and tri-unsaturated sterols are present in the extracts of fungi cultivated both in the dark and in the light but the sterol composition is different. The influence of “oat water” on sterol structure has been determined by comparison with the sterols of the same fungus grown on synthetic medium in the dark.     

Dietary sterols/steroids and the generalist caterpillar Helicoverpa zea: Physiology,biochemistry and midgut gene expression

Sterols are essential nutrients for insects because, in contrast to mammals, no insect (or arthropod for that matter) can synthesize sterols de novo. Plant-feeding insects typically generate their sterols, commonly cholesterol, by metabolizing phytosterols. However, not all phytosterols are readily converted to cholesterol. In this study we examined, using artificial diets containing single sterols/steroids, how typical (cholesterol and stigmasterol) and atypical (cholestanol and cholestanone) sterols/steroids affect the performance of a generalist caterpillar (Helicoverpa zea). We also performed sterols/steroids analyses, using GC/MS techniques, to explore the metabolic fate of these different dietary sterols/steroids. Finally, we used a microarray approach to measure, and compare, midgut gene expression patterns that arise as a function of dietary sterols/steroids. In general, H. zea performed best on the cholesterol and stigmasterol diets, with cholesterol as the dominant tissue sterol on these two treatments. Compared to the cholesterol and stigmasterol diets, performance was reduced on the cholestanol and cholestanone diets; on these latter treatments stanols were the dominant tissue sterol. Finally, midgut gene expression patterns differed as a function of dietary sterol/steroid; using the cholesterol treatment as a reference, gene expression differences were smallest on stigmasterol, intermediate on cholestanol, and greatest on cholestanone. Inspection of our data revealed two broad insights. First, they identify a number of genes potentially involved in sterol/steroid metabolism and absorption. Second, they provide unique mechanistic insights into how variation in dietary sterol/steroid structure can affect insect herbivores.     

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).     

Presqualene alcohol,squalene, and sterol biosynthesis from bifarnesol

To cast light on the overall biosynthetic conversion of farnesol pyrophosphate to presqualene alcohol pyrophosphate (PSA), the biochemical precursor of squalene as well as all sterols, radiolabeled bifarnesol (1) was prepared and fed toGibberella fujikuroi. The diol (1), acting as a surrogate for a previously suggested phosphorylated version of1, was converted to radiolabeled presqualene alcohol and squalene, as well as various sterols, including lanosterol and24-β-methylcholesta-5,7,9(11),22-tetraen-3β-ol, previously isolated from the same fungus. The results are interpreted to imply that a phosphorylated version of1 may act as a bone fide intermediate in the biosynthesis of PSA, thereby rendering unlikely any type of concerted farnesyl/presqualene pyrophosphate change.     

Sterol limitation in a pollen-fed omnivorous lady beetle (Coleoptera: Coccinellidae)

Nutritional constraints of non-prey foods for entomophagous arthropods are seldom investigated, yet are crucial to understanding their nutritional ecology and function within natural and managed environments. We investigated whether pollen from five maize hybrids was of variable quality for the lady beetle, Coleomegilla maculata, whether suitability of these pollens was related with their sterol profiles, and how augmenting sterols (β-sitosterol, cholesterol, or ergosterol) affected the fitness and performance of C. maculata. Preimaginal survival, development rates, the duration of the pre-oviposition period, post-mortem adult dry weight, adult hind tibial length, sex ratio, fecundity, cohort generation time (T_c), net replacement rate (R₀) and intrinsic rate of increase (r) were measured. Individual sterols in the pollens were quantified using GC-MS. Pollens were of variable suitability for C. maculata; the development rate was positively correlated with the amount of 24-methylene-cholesterol and r was positively correlated with episterol and 24-methylene-lophenol found in the pollens. Performance of C. maculata was entirely unaffected by augmenting pollen meals with sterols. This research shows that pollens clearly vary in their sterol contents intraspecifically, which affects their suitability for omnivores that rely on pollen. However, sterols appear to be only one of the limiting nutrients in pollens.     

Special relationship between sterols and oxygen: Were sterols an adaptation to aerobic life?

A fascinating link between sterols and molecular oxygen (O₂) has been a common thread running through the fundamental work of Konrad Bloch, who elucidated the biosynthetic pathway for cholesterol, to recent work supporting a role of sterols in the sensing of O₂. Synthesis of sterols by eukaryotes is an O₂-intensive process. In this review, we argue that increased levels of O₂ in the atmosphere not only made the evolution of sterols possible, but that these sterols may in turn have provided the eukaryote with an early defence mechanism against O₂. The idea that nature crafted sterols as a feedback loop to adapt to, or help protect against, the hazards of O₂ is novel and enticing. We marshal several lines of evidence to support this thesis: (1) coincidence of atmospheric O₂ and sterol evolution; (2) sterols regulate O₂ entry into eukaryotic cells and organelles; (3) sterols act as O₂ sensors across eukaryotic life; (4) sterols serve as a primitive cellular defence against O₂ (including reactive oxygen species). Therefore, sterols may have evolved in eukaryotes partially as an adaptive response to the rise of terrestrial O₂, rather than merely as a consequence of it.     

24-Methylenecyclopropane steroidal inhibitors: A Trojan horse in ergosterol biosynthesis that prevents growth of Trypanosoma brucei

A new class of steroidal therapeutics based on phylogenetic-guided design of covalent inhibitors that target parasite-specific enzymes of ergosterol biosynthesis is shown to prevent growth of the protozoan-Trypanosoma brucei, responsible for sleeping sickness. In the presence of approximately 15 ± 5 μM 26,27-dehydrolanosterol, T. brucei procyclic or blood stream form growth is inhibited by 50%. This compound is actively converted by the parasite to an acceptable substrate of sterol C24-methyl transferase (SMT) that upon position-specific side chain methylation at C26 inactivates the enzyme. Treated cells show dose-dependent depletion of ergosterol and other 24β-methyl sterols with no accumulation of intermediates in contradistinction to profiles typical of tight binding inhibitor treatments to azoles showing loss of ergosterol accompanied by accumulation of toxic 14-methyl sterols. HEK cells accumulate 26,27-dehydrolanosterol without effect on cholesterol biosynthesis. During exposure of cloned TbSMT to 26,27-dehydrozymosterol, the enzyme is gradually inactivated (k_cat/k_inact = 0.13 min^− 1/0.08 min^− 1; partition ratio of 1.6) while 26,27-dehydrolanosterol binds nonproductively. GC–MS analysis of the turnover product and bound intermediate released as a C26-methylated diol (C3-OH and C24-OH) confirmed substrate recognition and covalent binding to TbSMT. This study has potential implications for design of a novel class of chemotherapeutic leads functioning as mechanism-based inhibitors of ergosterol biosynthesis to treat neglected tropical diseases.     

Membrane properties of plant sterols in phospholipid bilayers as determined by differential scanning calorimetry, resonance energy transfer and detergent-induced solubilization

The increased use of plant sterols as cholesterol-lowering agents warrants further research on the possible effects of plant sterols in membranes. In this study, the effects of the incorporation of cholesterol, campesterol, β-sitosterol and stigmasterol in phospholipid bilayers were investigated by differential scanning calorimetry (DSC), resonance energy transfer (RET) between trans parinaric acid (tPA) and 2-(6-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino)hexanoyl-1-hexadecanoyl-sn-glycero-3-phosphocholine (NBD-PC), and Triton X-100-induced solubilization. The phospholipids used were 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC), d-erythro-N-palmitoyl-sphingomyelin (PSM), and 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC). In DSC experiments, it was demonstrated that the sterols differed in their effect on the melting temperatures of both the sterol-poor and the sterol-rich domains in DPPC and PSM bilayers. The plant sterols gave rise to lower temperatures of both transitions, when compared with cholesterol. The plant sterols also resulted in lower transition temperatures, in comparison with cholesterol, when sterol-containing DPPC and PSM bilayers were investigated by RET. In the detergent solubilization experiments, the total molar ratio between Triton X-100 and POPC at the onset of solubilization (R_t,sat) was higher for bilayers containing plant sterols, in comparison with membranes containing cholesterol. Taken together, the observations presented in this study indicate that campesterol, β-sitosterol and stigmasterol interacted less favorably than cholesterol with the phospholipids, leading to measurable differences in their domain properties.     

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.