Inhibition of Sterol Biosynthesis in Monilinia fructigena by the Fungicide,S-1358

When Moniiinia fructigena was treated with S–1358 at a concentration of 10 μm, both quality and quantity of digitonin-precipitable sterols were markedly altered. The amount of ergosterol which is a major sterol in the control culture was reduced by S–1358 and the concomitant accumulation of obtusifoliol (one of 4α-methyl sterols) and 24-methylenedihy-drolanosterol (one of 4,4-dimethyl sterols) was observed. The time course study of acetate-U-¹⁴C incorporation into the digitonin-precipitable sterols revealed that 4α-methyl sterols accumulated slowly in the treated culture, while 4,4-dimethyl sterols accumulated rapidly. The accumulation of the sterols containing “extra1” methyl groups suggests that S–1358 blocks demethylation reactions in the conversion from lanosterol to ergosterol in M. fructigena.     

Perception,regulation, and fitness effects of pollen phytosterols in the bumble bee,Bombus terrestris

Premise

Many flowering plants depend on insects for pollination and thus attract pollinators by offering rewards, mostly nectar and pollen. Bee pollinators rely on pollen as their main nutrient source. Pollen provides all essential micro- and macronutrients including substances that cannot be synthesized by bees themselves, such as sterols, which bees need for processes such as hormone production. Variations in sterol concentrations may consequently affect bee health and reproductive fitness. We therefore hypothesized that (1) these variations in pollen sterols affect longevity and reproduction in bumble bees and (2) can thus be perceived via the bees' antennae before consumption.

Methods

We studied the effect of sterols on longevity and reproduction of Bombus terrestris workers in feeding experiments and investigated sterol perception using chemotactile proboscis extension response (PER) conditioning.

Results

Workers could perceive several sterols (cholesterol, cholestenone, desmosterol, stigmasterol, β-sitosterol) via their antennae but not differentiate between them. However, when sterols were presented in pollen, and not as a single compound, the bees were unable to differentiate between pollen differing in sterol content. Additionally, different sterol concentrations in pollen neither affected pollen consumption nor brood development or worker longevity.

Conclusions

Since we used both natural concentrations and concentrations higher than those found in pollen, our results indicate that bumble bees may not need to pay specific attention to pollen sterol content beyond a specific threshold. Naturally encountered concentrations might fully support their sterol requirements and higher concentrations do not seem to have negative effects.

     

Effects of Echinostoma trivolvis (Trematoda) infection on neutral lipids,sterols, and carotenoids in Helisoma trivolvis (Gastropoda)

• 1.1. Histochemical, thin layer and gas-liquid chromatographic studies were done on neutral lipids, sterols and carotenes in the digestive gland-gonad (DGG) complex of Helisoma trivolvis infected with Echinostoma trivolvis vs uninfected DGG.
• 2.2. Hitochemical Oil Red O staining showed the presence of neutral lipids in the redial body wall and in the digestive cells of the DGG.
• 3.3. TLC showed that free sterols and triacylglycerols were major neutral lipid fractions along with lesser amounts of steryl esters and free fatty acids in the DGG of both populations. The percentage composition of all neutral lipid fractions was greater in infected than uninfected DGG.
• 4.4. Infected DGG contained more carotenoid fractions than uninfected DGG, but only beta-carotene was identified from both.
• 5.5. GLC studies showed that the major sterol present in snail DGG was cholesterol (about 70%) along with lesser amounts of stigmasterol, campesterol, beta-sitosterol and desmosterol. No clear cut distinction was seen in sterols from infected vs uninfected DGG.

     

The sterols of calcareous sponges (Calcarea, Porifera)

Sponges are sessile suspension-feeding organisms whose internal phylogenetic relationships are still the subject of intense debate. Sterols may have the potential to be used as independent markers to test phylogenetic hypotheses. Twenty representative specimens of calcareous sponges (class Calcarea, phylum Porifera) with a broad coverage within both subclasses Calcinea and Calcaronea were analysed for their sterol content. Two major pseudohomologous series were found, accompanied by some additional sterols. The first series encompassing conventional C(27) to C(29)Delta(5,7,22) sterols represented the major sterols, with ergosterol (ergosta-5,7,22-trien-3beta-ol, C(28)Delta(5,7,22)) being most prominent in many species. The second series consisted of unusual C(27) to C(29)Delta(5,7,9(11),22) sterols. Cholesterol occurred sporadically, mostly in trace amounts. The sterol patterns did not resolve intraclass phylogenetic relationships, namely the distinction between the subclasses, Calcinea and Calcaronea. This pointed towards major calcarean lipid traits being established prior to the separation of subclasses. Furthermore, calcarean sterol patterns clearly differ from those found in Hexactinellida, whereas partial overlap occurred with some Demospongiae. Hence, sterols only partly reflect the phylogenetic separation of Calcarea from both of the other poriferan classes that was proposed by recent molecular work and fatty acid analyses.     

A SURVEY OF THE STEROL COMPOSITION OF THE MARINE DINOFLAGELLATES KARENIA BREVIS,KARENIA MIKIMOTOI,AND KARLODINIUM MICRUM: DISTRIBUTION OF STEROLS WITHIN OTHER MEMBERS OF THE CLASS DINOPHYCEAE1

The sterol composition of different marine microalgae has been examined to determine the utility of sterols as biomarkers to distinguish members of various algal classes. For example, members of the class Dinophyceae possess certain 4‐methyl sterols, such as dinosterol, which are rarely found in other classes of algae. The ability to use sterol biomarkers to distinguish certain dinoflagellates such as the toxic species Karenia brevis Hansen and Moestrup, responsible for red tide events in the Gulf of Mexico, from other species within the same class would be of considerable scientific and economic value. Karenia brevis has been shown by others to possess two major sterols, (24S)‐4α‐methyl‐5α‐ergosta‐8(14),22‐dien‐3β‐ol (ED) and its 27‐nor derivative (NED), having novel structures not previously known to be present in other dinoflagellates. This prompted the present study of the sterol signatures of more than 40 dinoflagellates. In this survey, sterols with the properties of ED and NED were found in cultures of K. brevis and shown also to be the principal sterols of Karenia mikimotoi Hansen and Moestrup and Karlodinium micrum Larsen, two dinoflagellates closely related to K. brevis. They are also found as minor components of the more complex sterol profiles of other members of the Gymnodinium/Peridinium/Prorocentrum (GPP) taxonomic group. The distribution of these sterols is consistent with the known close relationship between K. brevis, K. mikimotoi, and K. micrum and serves to limit the use of these sterols as lipid biomarkers to a few related species of dinoflagellates.     

Effects of the Fungicide,S-1358, on General Metabolism and Lipid Biosynthesis in Monilina fructigena

S–1358 (S-n-butyl-S′-p-tert-butylbenzyl n-3-pyridylimidodithiocarbonate) remarkably inhibited growth of Monilinia fructigena at 10 μm, causing excessive branching and distortion of hyphae. Endogenous as well as exogenous respiration was not affected by the toxicant. The incorporations of Uracil-U-¹⁴C and thymine-2-¹⁴C into nucleic acids and protein hydroly-Sate-U-¹⁴C into proteins were only slightly inhibited. Furthermore, S–1358 has no influence on the incorporations of d--glucose-U-¹⁴C and d-glucosamine-1-¹⁴C into cell wall during early incubation periods. On the other hand, although sodium acetate-U-¹⁴C incorporation into total lipids was only moderately suppressed, thin-layer chromatographic separation of labeled lipids revealed that the incorporation into 4-desmethyl sterols was strictly diminished by the toxicant and at the same time the accumulation of radioactivity into 4,4-dimethyl sterols took place. The results presented evidence that S–1358 disturbs the biosynthetic pathways of sterols rather than the other metabolism in M. fructigena.     

Selective Inhibition of the Demethylation at C-14 in Ergosterol Biosynthesis by the Fungicide,Denmert (S-1358)

In cell-free homogenates of Saccharomyces cerevisiae, Denmert (S-1358) inhibited the incorporation of radioactivity from dl-mevalonate-2-¹⁴C into 14-desmethyl-lanosterol, 4α-methyl-cholesta-8,24-dien-3-one, 4α-methyl-zymosterol and 4-desmethyl sterols (zymosterol and episterol) at a concentration of 10^?4 m. Concomitantly, a large accumulation of radioactivity was observed in the Ianosterol fraction.

In good agreement with the results described above, Denmert inhibited the conversion of ¹⁴C-labeled lanosterol to 4-desmethyl sterols, while the conversion of ¹⁴C-labeled 14-desmethyl-lanosterol to 4-desmethyl sterols was hardly affected by the fungicide. It is therefore evident that Denmert is a potent selective inhibitor of the demethylation at the C–14 position in ergosterol biosynthesis.

The fungicide, triarimol, was also found to exhibit the same effect on sterol biosynthesis as Denmert.     

Plant sterols: Diversity,biosynthesis, and physiological functions

Sterols, which are isoprenoid derivatives, are structural components of biological membranes. Special attention is now being given not only to their structure and function, but also to their regulatory roles in plants. Plant sterols have diverse composition; they exist as free sterols, sterol esters with higher fatty acids, sterol glycosides, and acylsterol glycosides, which are absent in animal cells. This diversity of types of phytosterols determines a wide spectrum of functions they play in plant life. Sterols are precursors of a group of plant hormones, the brassinosteroids, which regulate plant growth and development. Furthermore, sterols participate in transmembrane signal transduction by forming lipid microdomains. The predominant sterols in plants are β-sitosterol, campesterol, and stigmasterol. These sterols differ in the presence of a methyl or an ethyl group in the side chain at the 24th carbon atom and are named methylsterols or ethylsterols, respectively. The balance between 24-methylsterols and 24-ethylsterols is specific for individual plant species. The present review focuses on the key stages of plant sterol biosynthesis that determine the ratios between the different types of sterols, and the crosstalk between the sterol and sphingolipid pathways. The main enzymes involved in plant sterol biosynthesis are 3-hydroxy-3methylglutaryl-CoA reductase, C24-sterol methyltransferase, and C22-sterol desaturase. These enzymes are responsible for maintaining the optimal balance between sterols. Regulation of the ratios between the different types of sterols and sterols/sphingolipids can be of crucial importance in the responses of plants to stresses.     

Sterols in red and green algae: quantification, phylogeny, and relevance for the interpretation of geologic steranes

Steroids, a class of triterpenoid lipids with high preservation potential, are widely distributed in sedimentary rocks. All eukaryotes have a physiological requirement for these molecules, making steroids important biomarkers for aiding our understanding of eukaryote molecular evolution and geologic history. C(26)-C(30) sterols are the molecules most commonly incorporated or synthesized by eukaryotes, and correspond to C(26)-C(30) steranes ubiquitously and abundantly preserved in petroleums and sedimentary bitumens. Because these sterols occur in evolutionarily diverse taxa, it can be difficult to associate any particular compound with a single group of organisms. Nevertheless, geochemists have still been able to draw parallels between the empirical patterns in geologic sterane abundances and the age of petroleum source rocks. Paleobiologists have also used sterane data, in particular the patterns in C(29) and C(28) steranes, to support fossil evidence of an early radiation of green algae in latest Proterozoic and Paleozoic and the succession of the major modern phytoplankton groups in the Mesozoic. Although C(29) sterols are found in many eukaryotes, organisms that produce them in proportional abundances comparable to those preserved in Proterozoic and Paleozoic rocks are limited. Based on a large, phylogenetically based survey of sterol profiles from the kingdom Plantae, we conclude that modern ulvophyte and early diverging prasinophyte green algae produce high abundances of C(29) relative to C(27) and C(28) sterols most consistent with the sterane profiles observed in Paleozoic rocks. Our analysis also suggests that ancestral stem groups among the Plantae, including the glaucocystophytes and early divergent red algae are also plausible candidates.     

Sterols of the green-pigmented, aberrant plastid dinoflagellate, Lepidodinium chlorophorum (Dinophyceae)

Lepidodinium chlorophorum is a green-pigmented dinoflagellate with an aberrant, tertiary plastid of chlorophyte ancestry rather than the typical red algal, secondary endosymbiont found in the vast majority of photosynthetic dinoflagellates. To date, only one published study exists on the galactolipids of L. chlorophorum, with nothing known about other lipid classes, including sterols. Our objectives were to examine the sterol composition of L. chlorophorum to determine if it produces any unique sterols with the potential to serve as biomarkers, and to compare it to members of the Chlorophyceae to determine if it has inherited any signature green algal sterols from its chlorophyte-derived endosymbiont. We have found that L. chlorophorum produces 6 sterols, all with a 4α-methyl substituent and none of which are known to occur in the Chlorophyceae. Rather, the sterols produced by L. chlorophorum place it within a group of dinoflagellates that have the common dinoflagellate sterols, dinosterol and dinostanol, as part of their sterol composition.     

Comparison of sterols of pollens,honeybee workers,and prepupae from field sites

Sterols from pollen collected by foraging honeybees, Apis mellifera L, at seven field sites were compared with the sterols of foraging adults and/or prepupae collected from colonies at each site. Invariably, the composition of prepupal sterols was comparable to that found in previous cage studies using chemically defined diets containing various dietary sterols: 24-methyl-enecholesterol was the major sterol; sitosterol and isofucosterol were present in lesser, but significant amounts; and a trace amount of cholesterol was identified in each sample. This occurred even though some of the pollen sterols contained little 24-methylenecholesterol, sitosterol, or isofucosterol and a preponderance of certain other sterols, such as δ⁷-stigmasten-3β-ol and δ^7,24(28)-campestadien-3β-ol in goldenrod and corn pollens, respectively. Thus the selective transfer and utilization of sterols in honeybees that have been demonstrated in cage studies with artificial diets were also shown to occur under field conditions.     

Sterols and membrane dynamics

The effect of sterols from mammals, plants, fungi, and bacteria on model and natural membrane dynamics are reviewed, in the frame of ordering–disordering properties of membranes. It is shown that all sterols share a common property: the ability to regulate dynamics in order to maintain membranes in a microfluid state where it can convey important biological processes. Depending on the sterol class, this property is modulated by molecular modifications that have occurred during evolution. The role of sterols in rafts, antibiotic complexes, and in protecting membranes from the destructive action of amphipathic toxins is also discussed.     

Seasonal changes in condition and lipids composition of the bivalve Macoma balthica L. from the gulf of Gdańsk (Southern Baltic)

• 1.1. The total lipids content and composition of lipid classes, their per cent in dry wt of soft tissues and level in standard animal, as well as composition of fatty acids and sterols were studied in Macoma balthica collected from three sites in the Gulf of Gdańsk, in the years, 1983–1984.
• 2.2. The increase in the content of total lipids, triacylglycerols, oleopalmitic, 16:1 and eicosapentaenoic acids, 20:5, C27 sterols (mainly cholest-5en-3β-ol), in spring and early summer and their decrease in autumn and winter were observed.
• 3.3. Content of phospholipids, sterols and hydrocarbons in the tissue dry wt of Macoma balthica remained nearly constant.

     

Sterols with 29, 28 and 27 carbon atoms metabolically related to cholesterol, occurring in developing and mature brain

Brain sterols from chick embryos (11 and 18 days of incubation) and mature rats, previously injected with [2-¹⁴C]mevalonate, were analysed. Acetate derivatives of the sterols were chromatographed on Silica Gel:Celite:AgNO₃ columns. Sterol fractions were assayed for radioactivity and the amounts determined by gas chromatography. Sterol structures were elucidated by gas chromatography-mass spectrometry. The method used allowed the identification of some sterols representing no more than 0-01 per cent of the total mixture. The following brain sterols were identified: cholesterol, cholestanol, cholest-5,24-dien-3β-ol (desmosterol); 4,4′-dimethyl-cholest-8-en-3β-ol, 4α-methyl-cholest-8-en-3β-ol, cholest-8-en-3β-ol, 4,4′-dimethyl-choIest-8,24-dien-3β-ol, 4α-methyl-cholest-8,24-dien-3β-ol, cholest-8,24-dien-3β-ol and cholest-7,24-dien-3β-ol. Small amounts of other sterols including polyhydroxy sterols, were also detected. There were no qualitative differences in the sterols detected in developing and mature brain. In the developing chick brain, cholesterol represented approximately 90 per cent of the total sterols. In the mature rat brain, cholesterol accounted for 98 per cent of the sterols. The adult rat brain, as well as the embryonic chick brain, demonstrated the capacity to incorporate mevalonate into cholesterol precursors and cholestanol. The sterols retaining the double bond in the lateral chain, that is, those of the Δ^8,24 series with 29, 28 and 27 carbon atoms and desmosterol, were highly labelled compared with the other identified intermediates. The possibility, supported by our data, that a preferential biosynthetic route for cholesterol exists in brain, is discussed.     

Circulating sterols as predictors of early allograft dysfunction and clinical outcome in patients undergoing liver transplantation

Introduction

Sensitive and specific assessment of the hepatic graft metabolism after liver transplantation (LTX) is essential for early detection of postoperative dysfunction implying the need for consecutive therapeutic interventions.

Objectives

Here, we assessed circulating liver metabolites of the cholesterol pathway, amino acids and acylcarnitines and evaluated their predictive value on early allograft dysfunction (EAD) and clinical outcome in the context of LTX.

Methods

The metabolites were quantified in the plasma of 40 liver graft recipients one day pre- and 10 days post-LTX by liquid chromatography/tandem mass spectrometry (LC–MS/MS). Plant sterols as well as cholesterol and its precursors were determined in the free and esterified form; lanosterol in the free form only. Metabolites and esterification ratios were compared to the model for early allograft function scoring (MEAF) which is calculated at day 3 post-LTX from routine parameters defining EAD.

Results

The hepatic esterification ratio of all sterols, but not amino acids and acylcarnitine concentrations, showed substantial metabolic disturbances post-LTX and correlated to the MEAF. In ROC analysis, the low esterification ratio of β-sitosterol and stigmasterol from day 1 and of the other sterols from day 3 were predictive for a high MEAF, i.e. EAD. Additionally, the ratio of esterified β-sitosterol and free lanosterol were predictive for all days and the esterification ratio of the other sterols at day 3 or 4 post-LTX for 3-month mortality.

Conclusion

Low ratios of circulating esterified sterols are associated with a high risk of EAD and impaired clinical outcome in the early postoperative phase following LTX.

     

Free fatty acids, neutral and polar lipids in Hordeum vulgare exposed to long-term fumigation with SO2

Three 9-day-old cultivars of Hordeum vulgare L. (Barberousse, Gerbel and Panda) were exposed to low levels of SO₂ fumigation (40 ± 5 and 117 ± 20 ppb). After 48 days of treatment the seedlings were harvested for lipid analysis. In comparison to the control (plants exposed to charcoal-filtered air), the total lipid content of fumigated seedlings declined at 40 ppb SO₂ and even more so at 117 ppb in all three cultivars. A large reduction in diacylglycerols. polar lipids and free sterols was also observed after fumigations at both SO₂ concentrations, whereas the treatments resulted in an increase in triacylglycerols and free fatty acids. The percentage composition of total fatty acids and that of each lipid class were changed by the fumigations. resulting in an increase in the degree of unsaturation. No changes in the percentage composition of sterols occurred in the fumigated leaves. These results suggest that even if SO₂ may not directly oxidize unsaturated fatty acids at the low concentrations used here (which do not cause visible injury). it may alter lipid metabolism. This alteration. which was particularly evident in the polar lipids and sterols, could affect the functions associated with membrane stabilization, in which lipids plus sterols play a key part.     

Sterol and Squalene Content of a Docosahexaenoic-Acid-Producing Thraustochytrid: Influence of Culture Age, Temperature, and Dissolved Oxygen

Thraustochytrid strain ACEM 6063, rich in omega-3 polyunsaturated fatty acids, was cultured at 15°C and 20°C in high (>40%) and low (<5%) dissolved oxygen (DO), and at 25°C in low-DO media. Samples were taken 4, 2, and 0 days before each culture reached peak biomass (T₋₄, T₋₂, and T_p, respectively). Twenty sterols, 13 of which were identified, were detected. Predominant were cholest-5-en-3β-ol, 24-ethylcholesta-5,22E-dien-3β-ol, 24-methylcholesta-5,22E-dien-3β-ol, and 2 coeluting sterols, one of which was 24-ethylcholesta-5,7,22-trien-3β-ol. These 4 sterols comprised 50% to 90% of total sterols. Cultures grown at high DO had simpler sterol profiles than those grown at low DO. Only the 4 sterols mentioned above were present at more than 3% of total sterols in high-DO cultures. In low-DO cultures, up to 6 additional sterols were present at more than 3% of total sterols. Culture age, temperature, and DO influenced squalene and sterol content. Total sterols (as a proportion of total lipids) decreased with increasing culture age. If organisms such as ACEM 6063 are to be used for commercial production of lipid products for human consumption, both their sterol content and factors influencing sterol production need to be characterized thoroughly. Received January 8, 2001; accepted March 6, 2001.     

Lipid compositions of cells isolated from pig, human, and rat epidermis.

Epidermal slices from pig, human, and rat skin were treated with dilute buffered trypsin solution (0.005%, w/v), and suspensions of mixed basal and spinous cells were obtained in good yield. Total lipids accounted for approximately 8% of the pig, 10% of the human, and 20% of the rat epidermal cell (dry weight). Phospholipids in pig, human, and rat cells accounted for, respectively, 62%, 53%, and 35% of the total lipids. Phosphatidylcholine (34-38%), phosphatidylethanolamine (18-23%), and sphingomyelin (17-21%) were major compounds in all species. The major neutral lipids were sterols (mostly cholesterol) and triglycerides. Free fatty acids were a major lipid class in pig and human cells, whereas wax esters were a major component in rat epidermal cells. Nearly half (45%) of the sterols in rat cells but less than 10% of those in pig and human cells were esterified. Cholest-7-ene-3beta-ol accounted for 20% of the total sterols in rat cells. Cholesteryl sulfate and ceramide were minor lipids in the three species. The predominant glycosphingolipid (greater than 99%) was glucosylceramide, which accounted for 7% and 9%, respectively, of the total lipids in pig and human cells. A significant proportion (pig, 17%; human, 11%) of the fatty acids in the glucosylceramides were C26:0 and C28:0.     

Metabolism of Δ0-, Δ5-, and Δ7-Sterols by Larvae of Heliothis zea

Heliothis zea was reared on artificial diets containing Δ⁵-sterols (cholesterol, campesterol, or sitosterol), Δ⁷-sterols (lathosterol, epifungisterol, or spinasterol), or Δ⁰-sterols (cholestanol, epicoprostanol, campestanol, or sitostanol) in order to determine how different dietary sterols affect the type of sterols present in the tissues of the late-sixth-instar larva. Although all of the dietary sterols (except epicoprostanol) supported the growth of the larvae, not all of the sterols were metabolized to the same end products. In each case, at least 80% of the sterols in the tissues of the larvae retained the same nucleus as that of the dietary sterol, indicating that H. zea carries out very little metabolism of ring B of Δ⁵-, Δ⁷-, and Δ⁰-sterols. The larvae dealkylated the Δ⁵-, Δ⁷-, and Δ⁰-alkylsterols to 24-desalkylsterols, but a greater percentage of the Δ⁵-alkylsterols were metabolized in this manner. The sterols present as free sterols in the larva were also present as esterifed sterols which accounted for 2–4% of the total sterols. Therefore, the sterol composition of the tissues of H. zea can be altered by varying the dietary sterols.     

Comparison of the metabolism of cholesterol, cholestanol, and -sitosterol in L-cell mouse fibroblasts

The following data have been obtained from comparative studies on the metabolism of cholesterol, cholestanol, and beta-sitosterol by L-cell mouse fibroblasts. (1) When the sterols are added to the growth medium under similar conditions, cellular incorporation of cholesterol > cholestanol > beta-sitosterol; (2) only limited cellular esterification of these compounds occurs; (3) no metabolic products arising from the sterols could be detected; (4) influx of all sterols is dependent upon the concentration; and (5) exogenous cholesterol reduces mevalonate incorporation into cellular sterol to a lesser extent than acetate or glucose. The metabolism of these sterols is discussed in relation to their ability to influence de novo sterol biosynthesis.