Steroids in Porifera. II. Steroid derivatives from two sponges of the family Halichondriidae. Sokotrasterol sulfate, a marine steroid with a new pattern of side chain alkylation

A trisulfated derivative of 24,25,26,26-tetramethyl-5 alpha-cholest-23E-ene-2 alpha, 3 beta, 6 alpha-triol (sokotrasterol sulfate) has been isolated from the sponge Halichondriidae gen. sp., collected near Sokotra Island (Arabian Sea), and its structure has been elucidated. The side chain of the new steroid involves a "normal" alkylation at C-24 and the unprecedented addition of two extra methyl groups at C-26 and one extra methyl group at C-25. A free sterol fraction contained only 24-isopropyl-5-cholesten-3 beta-ol and 24-isopropyl-5, 22E-cholestadien-3 beta-ol. 24-Isopropyl-5, 22E-cholestadien-3 beta-ol as sole monohydroxy sterol and halistanol sulfate as major polyhydroxylated steroid derivative have been detected in Halichondria sp., a Madagascar sponge.     

Effect of dietary cholesterol deficiency upon its distribution in the larvae of the housefly, Musca domestica

The free sterol, total phospholipids and protein content of the various tissues and haemolymph lipoproteins obtained from the larvae of Musca domestica, reared on the diets containing 0.56 μmole cholesterol/g wet weight of diet (normal) and 0.05 μmole cholesterol/g wet weight of diet (deficient) have been determined. The cholesterol in the diet was found to be taken up by the larvae and distributed between all the tissues examined. About 60% of the free sterol in the larvae was recovered from the composite gut fraction and muscle. Cholesterol deficiency reduced both the growth of larvae and the free sterol content of the various tissues and haemolymph when compared to that of normal larvae. Cholesterol deficiency resulted in a slightly higher proportion of sterol and protein of the larval haemolymph being associated with the lipoproteins having slower electrophoretic mobility. Most of the different tissues from the cholesterol deficient larvae contained a much smaller proportion of their normal free sterol content than of their phospholipid or protein; the brain tissue however contained a higher percentage of free sterol and the haemolymph a much lower percentage than would be expected from the lowering of phospholipid and protein content as a result of the deficiency. When the sterol content was expressed relative to the protein, the ratio was higher in the brain tissue of both the normal and deficient larvae than the ratio present in the remaining tissues, apart from the composite gut fraction of the normal larvae. The results suggest that a disproportionate amount of available cholesterol was being concentrated into the nervous system of the cholesterol deficient insect.A rather higher proportion of the total sterol fraction recovered from the various tissues and haemolymph lipoproteins of cholesterol deficient larvae behaved as ‘polar metabolites’ of cholesterol when compared with that of normal larvae.     

Sterol distribution in intracellular organelles isolated from tobacco leaves

All membrane-containing fractions isolated from tobacco leaves contained free sterols, sterol glycosides, and sterol esters. The three sterol forms increased, on a dry weight basis, with a decrease in particle size. The supernatant fraction contained only trace amounts of sterol. The major sterols in all cellular fractions, in the order of decreasing amounts, were: stigmasterol, β-sitosterol, campesterol, and cholesterol. The 500g pellet contained the largest percentage of free sterol, while the 46,000g pellet contained the largest percentage of esterified sterol. The individual sterol composition of the free sterol and sterol glycoside fraction was very similar; however, the composition of the sterol ester fraction varied widely among intracellular fraction. The intracellular distribution pattern of cholesterol-¹⁴C added to the isolation medium provided evidence that the intracellular sterol distribution pattern is not an artifact. These results support the suggestion that sterols in plant cells may have a physiological function associated with membranes.     

Thermodynamic equilibria of cholesterol-detergent-water.

Cholesterol monomer is incorporated into alkyl sulfate micelles with a unitary free energy of -10.3 kcal/mol. This experimental free energy is in good agreement with that predicted by our previous determination of the hydrophobicity of the sterol suggesting that the partitioning is primarily hydrophobic with little or no contribution to the free energy from head group interactions in this system. The intrinsic hydrophobicity of cholesterol is shown to be insufficient for effective partitioning of the sterol between micelles (or bilayers) and its own self-associated form. This finding strongly supports a model of phospholipid-cholesterol interaction involving significant free energy contributions from head group effects such as alterations in hydrogen bonds or hydration. Since these head group contributions are not observed in the cholesterol-alkyl sulfate system, one concludes that there is a high degree of specificity of interaction between the sterol OH and polar moieties of other amphiphilic molecules.     

Changes in lipid composition during starvation and germ-tube formation inCandida albicans

The changes in the lipid components ofCandida albicans have been determined during growth, starvation, and germ-tube formation.¹⁴C-Labeled cells were used to determine the extent of synthesis and degradation of the different lipid fractions. On a dry weight basis the percentage of total lipid increased from 18% for blastospores to 22% after starvation but decreased to 11% after 4 h of germination. The major components of the lipid fraction were sterols (36–52%) and phospholipids (28–42%). The free and esterified sterol fractions both increased approximately 45% during starvation. The free sterol content continued to increase over the initial stage of germ-tube formation, then decreased with time. The sterol ester fraction decreased throughout germination to the concentration found in growing blastospores. The changes in specific activity (cpm/μg sterol) of these fractions indicated that sterol esters were precursors for free sterols during germination. The total phospholipid fraction increased during starvation but there was a decrease in both the cellular concentration (60%) and the specific activity during germination. There were only minor changes in the relative concentrations of phosphatidylinositol, phosphatidylserine, phosphatidylcholine, and phosphatidylethanolamine which indicated coordinate synthesis and degradation of these components. Free fatty acids and triacylglycerides are only minor components of the total lipid pool.     

Cholesteryl sulfate and sterol sulfatase in the human reproductive tract.

Cholesteryl sulfate is a component of human seminal plasma (avg. 445 mug%) and spermatozoa (15 mug/10 (9) cells) and represents more than 85% of the sterol sulfate fraction. This conjugate is avidly bound by spermatozoa when compared to other steroids or steroid sulfates. Autoradiographic localization of CS associated with the spermatozoa revealed a greater accumulation of the radioactivity in the acrosomal region in many, but not all, of those cells examined. Semen is not a site of metabolism of the sterol sulfate but the enzyme, sterol sulfatase, is present in the human female reproductive tract. This cleavage enzyme was detected in Graafian follicles and the activity in the endometrium was ten-fold that found in the Fallopian tube. These findings lead to the proposal that cholesteryl sulfate, an amphipathic molecule ideally suited for interaction with membrane components and implicated in erythrocyte membrane stabilization, may be involved in membrane modifications of the spermatozoa during the process of fertilization.     

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.     

A new sterol sulfate,Sch 572423, from a marine sponge,Topsentia sp

Bioassay-guided fractionation of an active fraction from a marine sponge Topsentia sp. in our marine fraction library (MFL) led to the isolation and identification of halistanol sulfate (1) and a new sterol sulfate Sch 572423 (2). Compounds 1 and 2 were identified as P2Y(12) inhibitors with IC(50) of 0.48 and 2.2 microM, respectively. The general method of purification for the MFL library and the structure elucidation of compound 2 are described.     

Liposome formation with wool lipid extracts rich in ceramides

Internal wool lipids (IWLs) are rich in cholesterol, free fatty acids, cholesteryl sulfate, and, mainly, ceramides. The repairing effect of these lipids structured as liposomes was demonstrated by reinforcing the skin-barrier integrity and increasing the water-holding capacity when applied onto the skin. This work was focused on the formation of liposomes with IWLs rich in ceramides, obtained at pilot plant level with organic solvent extraction by using methanol and acetone. The lipid composition of the two extracts was quantitatively analyzed. IWL extracts containing different amounts of sterol sulfate were used to form liposomes at physiologic p^H. Vesicle size distribution, polydispersity index, and zeta potential of all liposomes were determined to characterize them and to study their stability. The results obtained showed that IWL extract composition, which was different depending on the extraction methodologies used, greatly influences the characteristics of the liposomes formed. Vesicular size and polydispersity index liposomes were smaller when the extract composition contained a higher proportion of either free fatty acids or sterol sulfate. Moreover, liposome stability was improved when some amount of sterol sulfate was added to the composition of methanol and acetone extracts. This natural mixture with keratinaceous origin could have a special interest for cosmetic or dermopharmaceutical companies.     

Changes in Sterol Composition during Greening of Etiolated Barley Shoots

The following sterols were identified in barley shoots: stigmasterol, β-sitosterol, campesterol, and cholesterol. The total sterol content of green and etiolated tissue was 2.84 and 3.20 milligrams per gram dry weight, respectively. The free sterols accounted for most of the difference in total sterol content. The sterol ester, sterol glycoside, and acylated sterol glycoside contents of green and etiolated barley shoots were essentially the same. Etiolated tissue had twice as much total β-sitosterol as stigmasterol, while green tissue had equal amounts of these two sterols. The campesterol and cholesterol content was the same in green and etiolated tissue. This same sterol composition pattern held true for the free, glycosidic, and acylated glycosidic sterols; however, the sterol ester fraction had a completely different composition pattern. The esterified stigmasterol content was quite low in green and etiolated tissue, and campesterol was the second largest esterfied sterol component in etiolated tissue. Etiolated barley seedlings exposed to light had a shift in the ratio of free stigmasterol to β-sitosterol in favor of stigmasterol; however, no correlation was observed between chlorophyll synthesis and shift in sterol composition.     

Role of sterol superlattice in free radical-induced sterol oxidation in lipid membranes

We developed a new fluorescence assay for sterol oxidation and used it to study the relationship between free radical-induced sterol oxidation and membrane sterol lateral organization. This assay used dehydroergosterol (DHE) as both a membrane probe and a membrane component. Sterol oxidation was induced by a free radical generator, AAPH (2,2'-azobis(2-amidinopropane)dihydrochloride). Using this new assay, we found that, in unilamellar vesicles composed of DHE and 1-palmitoyl-2-oleoyl-l-alpha-phosphatidylcholine (POPC), the initial rate of DHE oxidation induced by AAPH changed with membrane sterol content in an alternating manner, exhibiting a local maximum at 20.3, 22.2, 25.0, 32.3, and 40.0 mol % DHE. These mole fractions correspond to the critical sterol mole fractions C(r) predicted for maximal sterol superlattice formation. In three-component bilayers composed of POPC, cholesterol, and DHE (fixed at 1 and 5 mol %), the initial rate of AAPH-induced DHE oxidation exhibited a biphasic change whenever the total sterol mole fraction, irrespective of the DHE content, was near C(r), indicating that the correlation between sterol oxidation and sterol superlattice formation revealed in this study is not an artifact due to the use of the fluorescent cholesterol analogue DHE. The alternating variation of AAPH-induced sterol oxidation with sterol content also appeared in multicomponent unilamellar vesicles containing bovine brain sphingomyelins (bbSPM), POPC, and DHE. The present work and our previous study on cholesterol oxidase-induced sterol oxidation [Wang et al. (2004) Biochemistry 43, 2159-2166] suggest that sterol oxidation in general, either by reactive oxygen species or by enzymes, may be regulated by the extent of sterol superlattice in the membrane and thus regulated by the membrane sterol content in a fine-tuning manner.     

Die quantitative verteilung der sterine und sterinderivate in organen von Solanum dulcamara

The following sterols were found in the roots, stems, leaves, unripe and ripe fruits of Solanum dulcamara: cholesterol, sitosterol, stigmasterol, campesterol, brassicasterol, isofucosterol and 24-methylenecholesterol. The most abundant components are cholesterol, sitosterol and stigmasterol (77–84%). In all parts of the plant the sterols are present in the free form and as esters, glycosides and acylated glycosides. The total sterol content and the content of combined forms were determined photometrically. In the leaves 58% of the sterols were found in the form of glycoside (26%), acylated glycoside (29%) and ester (2%). In the roots only 25% of the sterol were found in combined form. In the other organs the ratio of free and combined sterols was intermediate. In all cases, the ester fraction was the least.     

Sensitive detection of specific repair endonucleases: radial diffusion assay utilizing differential alkaline denaturation of supercoiled and nicked PM2 DNA in agarose gels

An improved method for separation and quantitation of sulfated neutral and acidic steroids in human feces was developed. The procedure consists of separation of sulfated steroids on Sephadex LH-20 and hydrolysis by cholylglycine hydrolase followed by quantitation and identification of the trimethylsilylether derivatives by gas-liquid chromatography and gas-liquid chromatography-mass spectroscopy. Using this procedure, we detected no sulfated bile acids in human feces. However, sulfated cholesterol was detected in the sulfated bile acid fraction obtained from human fecal extracts. Analysis showed that cholesterol sulfate comprised 12.3, 11.2, and 31.0% of the total neutral sterol fraction in the three fecal samples. Using our procedures, cholesterol sulfate and bile acid sulfates in a biological mixture can be quantitated and identified when they are present.     

Cholesterol sulfate. II. Studies on its metabolism and possible function in canine blood.

Previous in vitro studies to evaluate the possible role of cholesterol sulfate in the stabilization of the human erythrocyte membrane have been extended to the dog in vivo. Thus, following the injection of labelled cholesterol sulfate, a large fraction of the administered sterol conjugate is taken up by the membrane of the canine erythrocyte. Peak membrane levels were obtained within 30-60 min. Measurement of radioactivity associated with the plasma and red cell fractions in serial samples allowed the calculation of the half-life of cholesterol sulfate in each fraction. From the data obtained from the plasma of four dogs, the half-life was calculated to 5.8 plus or minus 0.9 h. The half-life of chlesterol sulfate associated with the erythrocyte membrane was calculated to be 6.7 plus or minus 1.2 h. In addition, following the intravenous administration of 0.2-0.7 mg of cholesterol sulfate/kg of body weight and withdrawal of serial blood samples, a significant diminution in the degree of hemolysis was observed when the red cells were exposed to hypotonic saline solutions. Maximal stabilization effects were observed at approx. 6-7 h after the administration of the sterol conjugate. Hemolytic properties returned to normal at approx. 24 h following the injection.     

4-Desmethylsterol composition of citrus rootstocks of different salt exclusion capacity

Fibrous roots from seedlings of three citrus rootstocks (Rungpur lime, Kharna khatta and Etrog citron) grown hydroponically for 6 weeks in the presence or absence of 50 mM NaCl were analysed for their content of free, esterified, and glycosidic sterols. Leaf chloride analyses indicated that Rangpur lime was a good Cl- excluder and the other two rootstocks were Cl- accumulators.
On a dry weight basis and in the absence of NaCI only the free 4-desmethyIsterol levels showed significant rootstock differences. Kharna khatta had the highest, and Rangpur lime the lowest, free stcrol levels. Sitostcrol was the major component of all sterol fractions of Rangpur lime, the esterified fraction of the other rootstocks, and the glycosidic sterol fraction of Kharna khatta. The ratio of sitosterol to stigmasterol was highest in Rangpur lime and lowest in Etrog citron in all cases and the ratio of apos;more-planar apos; to apos;less-planar apos; free sterols was highest in Etrog citron and lowest in Rangpur lime.
Treatment with 50 mM NaCI resulted in an increase in free sterol levels in Rangpur lime and a decrease in Kharna khatta. Steryl ester levels were unaffected in Rangpur lime but were significantly reduced in the other rootstocks. In all three sterol fractions the sitosterol/stigmasterol ratio was decreased. A decrease in the ratio of apos;more-planarapos; to apos;less-planarapos; free sterols was observed only in Kharna khatta and, more notably, Etrog citron. Salt-induced changes in the apos;more-planar apos; to apos;less-planar apos; free sterol ratio correlated well with salt exclusion capacity.     

The lipid composition of the non-photosynthetic diatom Nitzschia alba

The lipid composition of the non-photosynthetic marine diatom, Nitzschia alba, has been quantitatively determined. Triglycerides accounted for 20% of the cell dry weight and 87% of the total lipids. Smaller amounts of 1,2- and 1,3-diglycerides, free sterol (24-methylene cholesterol), hydrocarbons and an unknown component were the remaining neutral lipids detected. Phosphatidylsulfocholine (phosphatidyl S,S-dimethylmercaptoethanol), present in amounts of 0.8% of cell dry weight (35% of total polar lipids), was the major polar lipid component. Other phospholipids were lysophosphatidylsulfocholine, phosphatidylglycerol, phosphatidylinositol and cardiolipin, but both phosphatidylcholine and phosphatidylethanolamine were completely absent. Another novel sulfolipid, deoxyceramide sulfonic acid, as well as the sulfate ester of the free sterol, were also present. Considerable amounts of the four lipids often associated with photosynthetic organisms, mono- and di-galactosyl diglycerides, sulfoquinovosyl diglyceride and phosphatidylglycerol, were identified in N. alba. However, the fatty acid components of the glycosyl diglycerides did not show the high amounts of polyunsaturated acids (18 : 2, 18 : 3) normally found in photosynthesizing organisms. All polar lipids were found to be associated with various cell membrane fractions in N. alba.     

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.     

A Method for Fractional Determination of Soybean Sterols in Four Classes by Florisil Column Chromatography

A procedure for fractional determination of soybean sterols is presented. Sterols in lipid extracts were fractionated into four classes, fatty acid esters, the free form, acylated glucosides and non-acylated glucosides, by Florisil column chromatography. Sterol contents in the four classes were determined colorimetrically with ferric chloride-perchloric acid reagent. Before the colorimetry, the fatty acid ester fraction was hydrolyzed with ethanolic KOH, and the sterol was isolated as tomatinide. The free sterol fraction was directly treated with tomatine solution. The tomatinides were dissociated with dimethyl sulfoxide. To avoid the contamination of pigments from the acylated glucoside fraction, the second Florisil column was rinsed with diethyl ether between the elution with the first solvent (0 to 50% diethyl ether in n-heхane) and that with the second solvent (0 to 30% methanol in diethyl ether).     

Metabolic interconversion of free sterols and steryl esters in Saccharomyces cerevisiae.

The interconversion of free and esterified sterols was followed radioisotopically with [U-14C]acetate and [methyl-14C]methionine. In pulse-chase experiments, radioactivity first appeared mainly in unesterified sterols in exponential-phase cells. Within one generation time, the label equilibrated between the free and esterified sterol pools and subsequently accumulated in steryl esters in stationary-phase cells. When the sterol pools were prelabeled by growing cells aerobically to the stationary phase and the cells were diluted into unlabeled medium, the prelabeled steryl esters returned to the free sterol form under several conditions. (i) During aerobic growth, the prelabeled sterols decreased from 80% to 45% esters in the early exponential phase and then returned to 80% esters as the culture reached the stationary phase. (ii) Under anaerobic conditions, the percentage of prelabeled steryl esters declined continuously. When growth stopped, only 15% of the sterols remained esterified. (iii) In the presence of an inhibitor of sterol biosynthesis, which causes accumulation of a precursor to ergosterol, prelabeled sterols decreased to 40% steryl esters while the precursor was found preferentially in the esterified form. These results indicate that the bulk of the free sterol and steryl ester pools are freely interconvertible, with the steryl esters serving as a supply of free sterols. Furthermore, there is an active cellular control over what types of sterol are found in the free and esterified sterol pools.     

24-methylenepollinastanol and 24-dehydropollinastanol—two sterols of pollen

The esterified and unesterified sterol fractions of bee-gathered mixed pollens were examined, and total sterol composition was determined. Two new sterols of pollens, 14α-methyl-9β,19-cyclo-5α-cholest-24-en-3β-ol (24-dehydropollinastanol) and 14α-methyl-5α-ergost-24(28)-en-3β-ol (24-methylenepollinastanol) were isolated and identified. Both sterols were found primarily in the esterified sterol fraction, and 24-methylenepollinastanol accounted for 43% of the sterols of this fraction. 24-Dehydropollinastanol and four other sterols which also contain a 9β,19-cyclopropane ring were found only in the esterified sterol fraction. 24-Methylenecholesterol was the major sterol of the unesterified sterol fraction.