Sterols in hardening winter wheat

The main sterols in winter wheat crowns and roots were sitosterol and campesterol, with significant amounts of stigmasterol and traces of cholesterol. The main groups of sterol-containing lipids were free sterols, steryl glucosides, steryl esters and esterified steryl glucosides. Sterol analysis within each group showed little difference between them. Steryl esters were relatively rich in cholesterol and poor in stigmasterol. Free sterols were rich in stigmasterol. Low temperature caused an increase in sterol content but had little effect on sterol composition and sterol to lipid P ratio. There was some increase in steryl esters and some decrease in free sterols. Cholesterol and stigmasterol decreased in the steryl ester and free sterol fractions, respectively. There was little evidence for involvement of sterols in winter wheat frost hardening.     

Effect of Light on Mevalonic Acid Incorporation into the Phytosterols of Nicotiana tabacum L. Seedlings

Mevalonic acid-2-¹⁴C was readily incorporated into the free, esterified, and glycosidic sterol fractions of tobacco (Nicotiana tabacum L. var. Burley 21) seedlings. The time course of mevalonic acid-2-¹⁴C incorporation was different for the various individual sterols. Campesterol and sitosterol (group I) became radioactive as the free sterol and subsequently as the steryl ester. The reverse order was observed for cholesterol and stigmasterol (group II). Light stimulated the incorporation of mevalonic acid-2-¹⁴C into the group I free sterols and during the first 6 to 9 hours into the steryl esters of group II. The increase in specific radioactivity of the group II steryl esters was followed by a decline. Based on time course studies it is suggested that the group II steryl esters turn over rapidly and that light influences the rate of turnover.     

Sterols in Germinating Seeds and Developing seedlings of Longleaf Pine, Pinus palustris

Sterols in germinating embryos and young seedlings of longleaf pine (Pinus palustris Mill.) were identified and quantities determined for different periods after germination. Sterol analyses were performed by gas-liquid chromatography (GLC) and verified by combination of GLC-mass spectrometry. Campesterol and β-sitosterol were two major sterols which accounted for most of the sterol composition while stigmasterol was present in very small amounts. No cholesterol was revealed by GLC-mass spectrometry although there was a minor peak appearing on the sterol gas-liquid chromatograms with a retention time close to that of authentic cholesterol. By fractionation, three different forms of sterols were obtained: steryl esters, steryl glycosides, and free sterols. The sterols were mainly found in the esterified fraction, while steryl glycosides and free sterols only made up a small portion of the total sterol value. The total sterol content in general increased during seedling development, and this increase reflected mainly a change in steryl esters. The low levels of both free and glycosidic sterols remained nearly unchanged throughout the experimental germination period.     

The incorporation of mevalonate-[2-14C] into the sterol fractions of Calendula officinalis

The incorporation of mevalonate-[2-¹⁴C] into the free sterols, steryl esters, steryl glucosides, acylated steryl glucosides and water-soluble complexes was investigated and the sterols of each fraction were separated into stanols, Δ⁷ sterols, Δ⁵ sterols, stigmasterol, clerosterol and methylene-cholesterol. The stanols and Δ⁷ sterols were more strongly labelled in the steryl esters than in the free sterols. The Δ⁵ sterols and stigmasterol were more intensively labelled in the free sterols than in the steryl esters. All sterol types were more labelled in the steryl glycosides than in the acylated steryl glucosides. Stanols were probably formed from Δ⁷ or Δ⁵ precursors.     

Quantitative aspects of free and esterified sterols in Saccharomyces cerevisiae under various conditions.

For extraction of free and esterified sterols from yeast cells, a method was devised in which both forms of sterols were extracted with light petroleum after the treatment of the cells with acetone, and then with dimethylsulfoxide. The content of sterol esters in the cells under aerobic conditions markedly increased with time, amounting to 95% of the total sterols under some conditions. However, the formed sterol esters were decreased, accompanied with an increase of free sterols, when the cells were put under anaerobic conditions. Variations of radioactivities of both sterols which had been labeled in the side chain by incubation of the cells with [Me[-14C]methionine were examined on the cells grown under various conditions. No variation was observed on the cells under aerobic conditions. On the other hand, the labeled esters were hydrolyzed to yield free sterols in the cells under anaerobic conditions. In the cells under aerobic conditions, the free sterols were found to consist mainly of ergosterol, whereas the esterified sterols contained considerable amounts of zymosterol, lanosterol, and other intermediate sterols besides ergosterol.     

Sterol Changes during Germination of Nicotiana tabacum Seeds

The identity, composition, and concentration of the total, free, esterified, and glycosidic sterol fractions were determined during germination of tobacco seeds. The total, free, and esterified sterols increased, with stigmasterol and campesterol accounting for most of the increase. Steryl glycosides decreased during germination, and stigmasteryl and sitosteryl glycosides showed the largest decrease. During germination, sitosterol was the major sterol in all fractions but stigmasterol and campesterol showed the greatest changes. The fatty acid composition of the steryl esters and acylated steryl glycosides most closely resembled the di- and triglycerides.     

STEROLIC BIOMARKERS IN MARINE PHYTOPLANKTON. II. FREE AND CONJUGATED STEROLS OF SEVEN SPECIES USED IN MARICULTURE

The sterols of seven unicellular algae widely used in mariculture and belonging to different classes (Prasinophyceae, Haptophyceae, Eustigmatophyceae, and Diatomophyceae) were examined for free and combined forms. Under standard culture conditions, all synthesized free sterols and combined forms (steryl esters, acyl steryl glycosides, and steryl glycosides). Free sterols were dominant in five of the species. In contrast, sterols were mostly esterified in the eustigmatophyte Nannochloropsis oculata (Droop) Hibberd and the diatom Thalassiosira pseudonana Hasle et Heimdal, whereas in another diatom, Chaetoceros calcitrans (Paulsen) Takano, glycosylated forms represented over 60% of total sterols. The pennate diatom Haslea ostrearia (Gaillon) Simonsen synthesized large amounts of steryl glycosides consisting mainly of an unusual sterol, 23,24-dimethylcholest-5-en-3β-ol, occurring in some dinoflagellates.     

The biosynthesis of the free sterols and sterol esters of Neurospora crassa.

The composition of the free and esterified sterols in Neurospora crassa was examined as a function of incubation time in starvation medium containing [2-14C]mevalonic acid. The 14C incorporation was monitored in nuclear methylated and 4,14-desmethyl sterol fractions. After 7 h incubation, sterol esterification had increased from an initial 5% in the log phase culture to 48% of the total sterol pool, with a concomitant decrease in free sterols. The relationship of the free and esterified sterol components in ergosterol biosynthesis is discussed.     

Sterol-induced upregulation of phosphatidylcholine synthesis in cultured fibroblasts is affected by the double-bond position in the sterol tetracyclic ring structure.

We have examined how a specific enrichment of cultured fibroblasts with various sterols (cholesterol, lathosterol, 7-dehydrocholesterol, allocholesterol and dihydrocholesterol) regulate synthesis de novo of phosphatidylcholine, cholesterol and cholesteryl (or steryl) esters in human skin fibroblasts. When human skin fibroblasts were incubated for 1 h with 130 microM cholesterol/CyD complexes, the mass of cellular free cholesterol increased by 100 nmol.mg-1 protein (from 90 nmol.mg-1 to 190 nmol.mg-1 protein). A similar exposure of cells to different sterol/CyD complexes increased the cell sterol content between 38 and 181 nmol sterol per mg cell protein. In cholesterol-enriched cells, the rate of phosphatidylcholine synthesis was doubled compared to control cells, irrespective of the type of precursor used ([3H]choline, [3H]palmitic acid, or [14C]glycerol). Enrichment of fibroblasts with 7-dehydrocholesterol, allocholesterol, or dihydrocholesterol also upregulated phosphatidylcholine synthesis, whereas cells enriched with lathosterol failed to upregulate their phosphatidylcholine synthesis. The activity of membrane-bound CTP:phosphocholine cytidylyltransferase, the rate-limiting enzyme, was increased by 47 +/- 4% in cholesterol-enriched cells whereas its activity was unchanged in lathosterol-enriched cells. Sterol enrichment with all tested sterols (including lathosterol) down-regulated acetate-incorporation into cholesterol, and upregulated sterol esterification in the sterol-enriched fibroblasts. Using 31P-NMR to measure the lamellar-to-hexagonal (Lalpha-HII) phase transition in multilamellar lipid dispersions, lathosterol-containing membranes underwent their transition at significantly higher temperatures compared to membranes containing any of the other sterols. In a system with 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine and either cholesterol or lathosterol (70:30 mol/mol), differential scanning calorimetry also revealed that the Lalpha-HII-transition occurred at a higher temperature with lathosterol compared to either cholesterol, allocholesterol, or dihydrocholesterol. These findings together suggest that there may exist a correlation between the propensity of a sterol to stabilize the Lalpha-HII-transition and its capacity to upregulate the activity of CTP:phosphocholine cytidylyltransferase in cells.     

Phytosterols in tobacco leaves at various stages of physiological maturity

Leaves of varying maturity from 84-day-old tobacco plants were harvested and analyzed for total sterol and their individual sterol components. The mature leaves had a significant higher sterol content than the immature leaves. Separation into free sterols, steryl esters, steryl glycosides, and acylated steryl glycosides showed that the free sterols accounted for most of the sterol increase, and stimgasterol was principally responsible for this increase.     

Cholesterol and oxysterol metabolism and subcellular distribution in macrophage foam cells. Accumulation of oxidized esters in lysosomes

Cholesterol- and cholesteryl ester-rich macrophage foam cells, characteristic of atherosclerotic lesions, are often generated in vitro using oxidized low density lipoprotein (OxLDL). However, relatively little is known of the nature and extent of sterol deposition in these cells or of its relationship to the foam cells formed in atherosclerotic lesions. The purpose of this study was to examine the content and cellular processing of sterols in OxLDL-loaded macrophages, and to compare this with macrophages loaded with acetylated LDL (AcLDL; cholesteryl ester-loaded cells containing no oxidized lipids) or 7-ketocholesterol-enriched acetylated LDL (7KCAcLDL; cholesteryl ester-loaded cells selectively supplemented with 7-ketocholesterol (7KC), the major oxysterol present in OxLDL). Both cholesterol and 7KC and their esters were measured in macrophages after uptake of these modified lipoproteins. Oxysterols comprised up to 50% of total sterol content of OxLDL-loaded cells. Unesterified 7KC and cholesterol partitioned into cell membranes, with no evidence of retention of either free sterol within lysosomes. The cells also contained cytosolic, ACAT-derived, cholesteryl and 7-ketocholesteryl esters. The proportion of free cholesterol and 7KC esterified by ACAT was 10-fold less in OxLDL-loaded cells than in AcLDL or 7KCAcLDL-loaded cells. This poor esterification rate in OxLDL-loaded cells was partly caused by fatty acid limitation. OxLDL-loaded macrophages also contained large (approximately 40-50% total cell sterol content) pools of oxidized esters, containing cholesterol or 7KC esterified to oxidized fatty acids. These were insensitive to ACAT inhibition, very stable and located in lysosomes, indicating resistance to lysosomal esterases. Macrophages loaded with OxLDL do not accumulate free sterols in their lysosomal compartment, but do accumulate lysosomal deposits of OxLDL-derived cholesterol and 7-ketocholesterol esterified to oxidized fatty acids. The presence of similar deposits in lesion foam cells would represent a pool of sterols that is particularly resistant to removal.     

Intracellular sterol transport in eukaryotes,a connection to mitochondrial function?

Eukaryotic cells synthesize sterols in the endoplasmatic reticulum (ER) from where it needs to be efficiently transported to the plasma membrane, which harbors approximately 90% of the free sterol pool of the cell. Sterols that are being taken up from the environment, on the other hand, are transported back from the plasma membrane to the ER, where the free sterols are esterified to steryl esters. The molecular mechanisms that govern this bidirectional movement of sterols between the ER and the plasma membrane of eukaryotic cells are only poorly understood. Proper control of this transport is important for normal cell function and development as indicated by fatal human pathologies such as Niemann Pick type C disease and atherosclerosis, which are characterized by an over-accumulation of free sterols within endosomal membranes and the ER, respectively. Recently, a number of complementary approaches using Saccharomyces cerevisiae as a model organism lead to a more precise characterization of the pathways that control the subcellular transport of sterols and led to the identification of components that directly or indirectly affect sterol uptake at the plasma membrane and its transport back to the ER. A genetic approach that is based on the fact that yeast is a facultative anaerobic organism, which becomes auxotrophic for sterols in the absence of oxygen, resulted in the identification of 17 genes that are required for efficient uptake and/or transport of sterols. Unexpectedly, many of these genes are required for mitochondrial functions. A possible connection between mitochondrial biogenesis and sterol biosynthesis and uptake will be discussed in light of the fact that cholesterol transport into the inner membranes of mitochondria is a well established sterol transport route in vertebrates, where it is required to convert cholesterol into pregnenolone, the precursor of steroids.     

Sterol Composition and Ecdysteroid Content of Eggs of the Root-knot Nematodes Meloidogyne incognita and M. arenaria

Free and esterified sterols of eggs of the root-knot nematodes Meloidogyne incognita races 2 and 3 and M. arenaria race 1 were isolated and identified by gas-liquid chromatography-mass spectrometry. The major sterols of eggs of each race were 24-ethylcholesterol (33.4-38.8% of total sterol), 24-ethylcholestanol (18.3-25.3%), 24-methylcholesterol (8.6-11.7%), 24-methylcholestanol (7.7-12.5%), and cholesterol (4.6-11.6%). Consequently, the major metabolic transformation performed by Meloidogyne females or eggs upon host sterols appeared to be saturation of the sterol nucleus. The free and esterified sterols of the same race did not differ appreciably, except for a slight enrichment of the steryl esters in cholesterol. Although the sterol composition of Meloidogyne eggs differed from that of other life stages of other genera of plant-parasitic nematodes, the three Meloidogyne races could not be distinguished from each other by their egg sterols. Ecdysteroids, compounds with hormonal function in insects, were not detected by radioimmunoassay in the Meloidogyne eggs either as free ecdysteroids or as polar conjugates.     

Total, free and conjugated sterolic forms in three microalgae used in mariculture

Total, free and conjugated forms (steryl esters, steryl glycosides and acyl steryl glycosides) of sterols from three microalgae that are extensively used in mariculture (Tetraselmis chuii, Nannochloropsis salina and Skeletonema costatum) were examined. The results revealed that cholesterol is the only common fraction detected in all investigated species and distributed in free and all conjugated forms. However, the total sterol content of T. chuii was about 325 microg/g dry wt, most of it was concentrated amongst 24-methylcholesta-5,24-diene-3beta-ol and 24-methylcholest-5-en-3beta-ol. On the other hand, the majority of the fractions were distributed in the free form. The total sterol content of N. salina was about 180 microg/g dry wt, cholesterol was the major fraction that was detected. Nevertheless, the dominant distribution forms were esterified. While in S. costatum, the total sterol content was 76 microg/g dry wt, approximately most fractions are quantitatively alike and dominated in the free form. Furthermore, our study shows clearly that most sterols are not distributed regularly within each form, a result that encouraged us to suggest a distribution of specific sterol fraction as a free or conjugated can be used as a serving tool in chemotaxonomic studies.     

Effects of the hypocholesteremic agent trifluperidol on the sterol, steryl ester, and fatty acid metabolism of Saccharomyces cerevisiae.

Trifluperidol (TFP), at a concentration of 100 muM, inhibited the 24-h growth of Saccharomyces cerevisiae by about 30%. Effects on lipid metabolism were investigated by monitoring the incorporation of [1-14C]sodium acetate into various lipid fractions after 4 and 24 h of growth in the presence of several concentrations of TFP. Although little effect was noted on the amount of free sterols, 24-h incorporation of label into steryl esters was increased two- to fourfold by 100 muM TFP. Major sterol components of the steryl ester fraction isolated from an untreated culture were zymosterol (48%) and ergosterol (24%), whereas from the TFP-treated culture delta8,24(28)-ergostadienol (66.6%) and delta8-ergostenol (14.7%) were most abundant. Free sterols present in the highest concentration in the untreated culture were ergosterol (78.2%) and lanosterol (13%); whereas delta8,22-ergostadienol (38.5%), delta8-ergostenol (35.4%), and delta8,24(28)-ergostadienol (25.4%) were the most abundant free sterols obtained from the TFP-treated culture. Thus, the major block in the sterol biosynthetic pathway in yeast appears to be delta8 leads to delta7 isomerization. In these same cultures the relative amounts of C12 and C14 acids isolated from both steryl ester and miscellaneous lipid fractions were increased more than threefold over controls.     

Sterols in relation to ageing of seeds of Helianthus annuus and Cicer arietinum

Under accelerated ageing at high relative humidity and high temperature for 4 days germination and membrane permeability remained unaffected both in sunflower and chick pea seeds. However, the steryl glycoside concentration in the pooled leachate increased progressively with ageing. Total sterols, as well as steryl glycosides and free sterols of the seeds, increased with a concomitant decline in steryl esters under accelerated ageing. Pretreatment with the sterol biosynthesis inhibitor SK & F 7997A₃ prevented the increase of total sterols under accelerated ageing conditions but there were increases in the amounts of steryl glycosides and free sterols and a decrease in steryl ester after such treatment, therefore, indicating interconversions of the various sterol types. Accelerated ageing also caused increases in free amino acids and soluble carbohydrate. Low relative humidity-high temperature and high relative humidity-low temperature failed to produce such effects.     

The Neutral Lipids of Paramecium tetraurelia: Changes with Culture Age and the Detection of Steryl Esters in Ciliary Membranes1

Neutral lipids, particularly triglycerides, accounted for the major decrease in the total lipid content in Paramecium cells that occurs with culture age. Sterols, triglycerides, and steryl esters were the major classes of neutral lipids in cells and isolated cilia. Free as well as high concentrations of esterified sterols were detected in purified ciliary membrane preparations. Stigmasterol and 7-dehydrostigmasterol were the major components of both free and esterified sterols of cells and cilia; however, when cholesterol was present in the growth medium, it was desaturated to 7-dehydrocholesterol and incorporated into cellular and ciliary lipids. Free fatty acids from cells and triglycerides from cells and cilia were low in polyunsaturated fatty acids and reflected the composition of fatty acids in the culture medium. An exception was the reduced concentration of stearate in triglycerides from whole cells. Greater than 50% of triglyceride fatty acids from cilia were saturated. The fatty acid compositions of cellular triglycerides and ciliary steryl esters did not change with culture age, but those of cellular steryl esters and ciliary triglycerides did change. In comparison with phospholipids, these neutral lipid fatty acid compositional changes were smaller. The sensitivity of these stigmasterol-containing cells to polyene antibiotics indicated that they were killed by nystatin > filipin > amphotericin B. The unexpected finding of high concentrations of steryl esters in ciliary membrane preparations is discussed.     

Intracellular distribution and origin of sterols in Calendula officinalis leaves

In Calendula officinalis leaves 66% of all steryl forms are present in the ‘microsomal fraction’ (IV), 24% in the mitochondrial and Golgi membranes (III), 5% in the ‘chloroplast’ (II), 4% in the ‘cell wall and membrane’ (I) fraction and 1%. in the cytosol. Free sterols, their esters, glycosides and acylated glycosides are present in varying proportions in all cellular subtractions. Mevalonate-[2¹⁴C] labelling of sterols derived from various steryl forms showed that free sterols and all their derivatives, i.e. steryl esters and glucosides, are formed in fraction IV and are then translocated to other organelles. Fraction III is the main site of glycosylation of transported sterols as well as of acylation of steryl glycosides.     

Ergosterol and lanosterol from Aspergillus nidulans

Ergosterol was identified as the major free sterol of Aspergillus nidulans by thin-layer chromatography, alumina column chromatography, gas-liquid chromatography, high-performance liquid chromatography, UV spectroscopy, proton magnetic resonance spectroscopy and mass spectral analysis. Lanosterol, the initial cyclized precursor of ergosterol, was identified as a minor component of the free sterols. In the steryl ester material, however, lanosterol was usually more abundant than ergosterol, suggesting that the esters serve as storage compounds for the membrane sterol precursors.     

Yeast sterol esters and their relationship to the growth of yeast.

Variation in the percentage of sterols esterified to long-chain fatty acids during cellular growth has been examined. Under all conditions, a constant percentage of sterol esters was maintained during exponential growth. This maintenance level was found to vary with different growth conditions. A sharp increase in the rate of esterification was observed upon entry of the culture into the stationary growth phase. The minor cellular sterol components were found to accumulate after this period of rapid sterol ester synthesis, with a relative decrease in the size of the ergosterol pool. Evidence is presented that sterol esters of ergosterol precursors are unable to be metabolized to ergosterol. Once esterified, the fatty acids do not appear to be scavenged during starvation conditions.