Composition of the triterpene alcohol fraction of horse chestnut seed

The triterpene alcohol fraction was isolated from the seed oil of horse chestnut; it amounted to 42.2% of the unsaponifiable matter, i.e. 0.93% of the oil. The components were identified as taraxerol, β-amyrin, butyrospermol, parkeol, 5α-tirucalla-8,23-dien-3β-ol, α-amyrin and 24-methylenecycloartenol. Butyrospermol and 5α-tirucalla-8,23- dien-3β-ol were the major components and amounted to 60% of the fraction. The latter has not been identified in any vegetable oils yet.     

The neutral sterols of Megalotomus quinquespinosus (say) (hemiptera: Alydidae) and identification of makisterone a as the major free ecdysteroid

Last-stage nymphs of the broad-headed bug, Megalotomus quinquespinosus contain the C₂₈ ecdysteroid makisterone A as their major ecdysteroid. No ecdysone or 20-hydroxyecdysone was detected in whole body extracts analyzed by high performance liquid chromatography and radioimmune assay. Analyses of the neutral sterols of this phytophagous hemipteran revealed that the sterol composition of the nymphs was highly reflective of their dietary sterols. The most abundant nymphal sterols were sitosterol (46.6%), Δ⁷-stigmastenol (13.8%) and spinasterol (13.4%). Cholesterol accounted for only 0.2% of the total sterols and indicates that this species is incapable of converting 24-alkyl sterols to cholesterol.     

Neue sterine in Helianthus annuus

Six Δ⁷-sterols were isolated from sunflower seed oil by preparative TLC. On the basis of physica and chemical data five of the Δ⁷-sterols were identified: Δ⁷-stigmastenol, Δ⁷-campestenol, Δ^7,24(28)-stigma-stadienol, Δ^7,24(25)-stigmastadienol, and Δ^{7,9(11),24(28)}-stigmastatrienol. The last two sterols have not previously been detected in nature.     

Sterine in Trichosanthes kirilowii

Four Δ⁵-sterols and six Δ⁷-sterols were isolated from the seed oil of Trichosanthes kirilowii and identified as campesterol, sitosterol, stigmasterol, Δ⁷-campesterol, Δ⁷-stigmasterol, Δ^7,22-stigmastadienol, 24-ethylcholesta-5,25-diene-3β-ol, 24-ethylcholesta-7,24(25)-diene-3β-ol, 24-ethylcholesta-7,25-diene-3β-ol, and 24-ethylcholesta-7,22,25-trine-3β-ol.     

Observations on the biosynthesis of 24-methylcholesterol and 24-ethylcholesterol by Zea mays

Examination of the sterols of Zea mays shoots has established that the 24-ethylcholesterol is predominately the 24α-epimer, sitosterol, but the 24-methylcholesterol is a mixture of the 24α- and 24β-epimers. After incubation of Z. mays shoots with [2-¹⁴C, (4R)4-³H₁]mevalonic acid the sitosterol had a ³H: ¹⁴C atomic ratio of 2.09:5 which is consistent with previous results indicating that a Δ²⁴⁽²⁵⁾ -sterol is implicated in its biosynthesis. By contrast, the 24α- and 24β-methylcholesterol mixture had a higher ³H: ¹⁴C atomic ratio of 2.82:5. This can be explained by the operation of two routes for the elaboration of the 24-methylcholesterol side chain. One may proceed via Δ²⁴⁽²⁵⁾- and Δ²⁴⁽²⁵⁾-sterols to produce the 24α-methylcholesterol with a ³H: ¹⁴C atomic ratio of 2:5. The other route may involve reduction of either a Δ²⁴⁽²⁸⁾-, a Δ²³- or a Δ²⁵-sterol intermediate to give the 24β1-methylcholesterol with a ³H: ¹⁴C atomic ratio of 3:5. The proportion of these two labelled compounds in the mixture then determines the observed ³H: ¹⁴C atomic ratio (2.82:5). Some evidence for the formation of a Δ²⁵-compound, cyclolaudenol, by Z. mays shoots was provided by incorporation studies employing either [2-¹⁴C]mevalonic acid or [Me-¹⁴C]methionine as the sterol precursor.     

Sterols and fatty acids of the marine diatom biddulphia sinensis

Nine sterols, most showing Δ⁵- or Δ^5,22-unsaturation, were identified in the marine diatom Biddulphia sinensis. One sterol, cholesta-5,22E-dien-3β-ol, comprised 70–80% of the total sterols which is the first such predominance noted in a diatom. The only Δ⁷-sterol detected was cholest-7-en-3β-ol and this was a very minor component. A sterol showing unusual side-chain alkylation,23,24-dimethylcholesta-5,22E-dien-3β-ol, was identified for the first time in a diatom. Total fatty acids exhibited a predominance of Δ⁹- 16:1, 14:0, 20:5 and 16:0, typical of diatoms, although the proportions of these acids were found to vary with culture maturity. n-Heneicosahexaene was the major hydrocarbon together with a small amount of squalene.     

Incorporation of [4-14C] cholesterol into steryl derivatives and saponins of oat (Avena sativa L.) plants

Sterols from both green and etiolated oat plants (Avena sativa) contain sitosterol, stigmasterol, cholesterol, ⁷-stigmastenol, ⁷-cholestenol and campesterol. In the saponin fraction avenacosides A and B and 26-desgluco-avenacosides A and B were detected. Etiolated plants incorporated [4-¹⁴C] cholesterol into steryl derivatives (esters, glycosides and acylated glycosides) and also into all of the 4 saponins. [4-¹⁴C] sitosterol, however, is incorporated only into steryl derivatives, but not in saponins. From this it is concluded that cholesterol, but not sitosterol is the in vivo precursor of oat saponins.Abbreviations GLC gas liquid chromatography - I.D. inner diameter - TMS trimethylsilyl - dpm decompositions per minute     

Studies on Fatty Acids and Unsaponifiable Constituents of Oil from Tubers of Cyperus esculentus L.

The fatty acids of the oil from tubers of Cyperus esculentus L. were determined by gas chromatography with DC-11 and DEGS stationary phases. Oleic, linoleic, palmitic and stearic acids are the major constituents in the fatty acid fraction, while lauric, myristic, linolenic, arachidic, dadoleic, behenic and tetracosanoic acids are the minor ones. The unsaponifiable matters of the oil were separated by column chromatography with silica gel and thin layer chromatography with silica gel G into three fractions: sterols, 4-methylsterols and triterpene alcohols. The acetates of sterols, 4-methylsterols and triterpene alcohols were separated by TLC with 20% silver nitrate impregnated silica gel G, using CH2Cl2-petroleum system as developing reagents. The identification of major components was carried out by TLC, mp, optical rotation, GLC, IR spectrum and GC-MS. It was found that β-sitosterol, stigmasterol and campesterol were present in large amounts in the unsaponifiable fraction, β-sitosterol, stigmasterol, △5-and △7-avenasterol, 24- methylenecholesterol and 24-methylenecholest-7-enol in the sterol fraction, obtusifoliol, gramisterol and citrostadienol in the 4-methylsterol fraction, and cycloartanol, cydoartenol, 24- methylenecydoartanol and cyclobranol in the triterpene alcohol fraction were isolated and identified, while campesterol, campestanol, stigmastanol, △7-stigmastenol, △7-campestenol and △7-cholestenol were identified only. We found no evidence of the occurence of nonedibles in this oil.     

Rôle of phagostimulants of cotton leaves in the feeding behaviour of Spodoptera littoralis

Petroleum ether extract of cotton leaves was the most attractive to the hatched larvae of Spodoptera littoralis, and it remained so even after removal of the chlorophyll and other pigments. Steam distillation of this filtrate gave a volatile oil which also proved highly attractive to the larvae. In this fraction, 12 components were identified by thin-layer chromatography. Of these components, α-terpineol, citronellol and α-pinene were the most attractive, whereas humulene and linalool were less attractive. The remaining non-volatile lipid fraction was also attractive to the larva. In this fraction the unsaponifiable matter contained the attractive ingredients. This fraction proved to be a hydrocarbon. The infrared spectrum and nuclear magnetic resonance showed only typical hydrocarbon bonds.     

Sterols in seeds and leaves of oats (Avena sativa L.)

In seeds and leaves of oats (Avena sativa L.) 12 different sterols (cholesterol, cholstanol, ⁷-cholestenol, campesterol, campestanol, stigmasterol, lophenol, sitosterol, stigmastanol, ⁵-avenasterol, ⁷-avenasterol and ⁷-stigmastenol) have been identified. The sterol pattern is qualitatively the same, but the relative composition is different in leaves and in seeds. Leaves contain mainly sitosterol, stigmasterol, cholesterol and campesterol, but only minor portions of avenasterols. Seeds contain sitosterol, ⁵- and ⁷-avenasterol, campesterol, but only minor amounts of stigmasterol and cholesterol. In leaf lipids 1-hexacosanol (2.35 wt % of total lipid) has also been identified.     

Novel nuclear methylation of sterols by the nematode Caenorhabditis elegans

Caenorhabditis elegans possesses a unique sterol methylation pathway not reported to occur in any other organism and also removes the C-24 ethyl group of sitosterol (a plant sterol). This nematode produced substantial quantities of 4 alpha-methyl-5 alpha-cholest-8(14)-en-3 beta-ol and smaller amounts of lophenol from dietary cholesterol, desmosterol or sitosterol. When C. elegans was propagated in media containing sitosterol plus 25-azacoprostane hydrochloride (25-aza-5 beta-cholestane hydrochloride), an inhibitor of delta 24-sterol reductase in insects, its 4 alpha-methylsterol fraction largely consisted of equal amounts of 4 alpha-methyl-5 alpha-cholesta-7,24-dien-3 beta-ol and 4 alpha-methyl-5 alpha-cholesta-8(14),24-dien-3 beta-ol. Thus 25-azacoprostane hydrochloride inhibited both a delta 24-sterol reductase and a delta 7-sterol isomerase in C. elegans.     

Hydrocarbons,sterols and tocopherols in the seeds of six Adansonia species

The composition of the unsaponifiable matter of the lipids of six Adansonia species (A. grandidieri, A. za, A. fony, A. madagascariensis, A. digitata and A. suarezensis) was investigated. The total unsaponifiable content, its general composition and the identity of the components of the hydrocarbon, sterol and tocopherol fractions are presented. The unsaponifiable content in oil ranges from 0.4 to 1.1% (hexane method) and from 0.6 to 2.2% (diethyl ether method). In two species (A. grandidieri and A. suarezensis) the major components are 4-demethylsterols (23–42%) tocopherols (37-10%) and hydrocarbons (15–17%). In both species examined, eight 4-demethylsterols occur in the sterol fraction with sitosterol (81–88%) being predominant. Among the four tocopherols present, γ-tocopherol (68–98%) is the major compound. Each Adansonia species shows a characteristic gas liquid chromatography pattern for the hydrocarbon fraction. Squalene is the major component for five species (40–75%). Iso-, anteiso- and other branched hydrocarbons were not identified but were present in small amounts in comparison with n-alkanes. The dominance of odd- over even-carbon number chain length of n-alkanes was not observed in any species. The results show that C₂₂, C₂₅, C₂₆, C₂₇, C₂₈ and C₂₉ are the most frequent major constituents.     

Biosynthesis of sitosterol in barley seedlings

A method is described for the chemical synthesis of stigmasta-5,24-dien-3β-ol-[26-¹⁴C] and (24S)-24-ethylcholesta-5,25-dien-3β-ol-[26-¹⁴C] (clerosterol). 28-Isofucosterol-[7-³H₂] fed to developing barley seedlings (Hordeum vulgare) was incorporated into sitosterol and stigmasterol confirming the utilisation of a 24-ethylidene sterol intermediate in 24α-ethyl sterol production in this plant. Also, the use of mevalonic acid-[2-¹⁴C(4R)-4-³H₁] verified the loss of the C-25 hydrogen of 28-isofucosterol during its conversion into sitosterol and stigmasterol in agreement with the previously postulated isomerisation of the 24-ethylidene sterol to a Δ²⁴⁽²⁵⁾-sterol prior to reduction. However, feeding stigmasta-5,24-dien-3β-ol [26-¹⁴C] to barley seedlings gave very low incorporation into sitosterol. Attempts to trap radioactivity from mevalonic-[2-¹⁴C(4R)-4-³H₁] in stigmasta-5,24-dien-3β-ol when this unlabelled sterol was administered to barley seedlings gave only a very small incorporation although both 28-isofucosterol and sitosterol were labelled.     

Codisterol and other Δ5-sterols in the seeds of Cucurbita maxima

A substantial amount (ca 18%) of the sterol found in the seeds of Cucurbita maxima had a Δ-bond and consisted of seven components. They were identified as 25(27)-dehydroporiferasterol, clerosterol, isofucosterol, stigmasterol, sitosterol, campesterol and codisterol. The C-24 configuration of each of the sterols was unequivocally established by a ¹H NMR spectral comparison with authentic standards. This is the first time codisterol has been found in a higher plant and also the first time the structures and configurations of the Δ⁵-sterols from a Cucurbitaceae species have been clearly characterized.     

Effect of AY-9944 on sterol biosynthesis in suspension cultures of bramble cells

Bramble suspension cultures normally contain Δ⁵ sterols (sitosterol, campesterol, and isofucosterol). When the cells were grown in a medium supplemented with AY-9944, their content of Δ⁵ sterols was greatly decreased and Δ⁸ sterols accumulated. Six Δ⁸ sterols, including three new compounds, (24R)-24-ethyl-5α-cholest-8-en-3β-ol, stigmasta-8,Z-24(28)-dien-3β-ol, and 4α-methyl-stigmasta-8,Z-24(28)-dien-3β-ol, were identified. AY-9944 probably inhibited the Δ⁸→Δ⁷ isomerase. A stable cell line growing permanently in an AY-supplemented medium was obtained.     

Steroids,phthalyl esters and hydrocarbons from Balanites wilsoniana stem bark

IR assay for sapogenin of Balanites wilsoniana revealed 0.2% in the root wood, 0.7% in the root bark, 0.3% in the stem bark, 1.4% in the fatty seed and 0.6%. w/w in the leaf. The 25 α-epimers predominated in all parts except in the root wood. Six glucosideshaving diosgenin or yamogenin as aglycones were found and one was characterized diosgenin 3 β-d-glucopyranoside from IR, MS and NMR studies. Cholesterol, stigmasterol, sitosterol, 25 α-spirosta-3:5-diene and 25-β-spirosta-3:5-diene were also present. Free diosgenin and dienes were detected in appreciable quantities in the fat from the bark. The ‘unsaponifiable’ fraction of this fat contained phthalyl esters (mainly dioctyl and dibutyl) and saturated hydrocarbons C₁₀C₃₂ (with C₁₀C₂₀ predominating), together with the above mentioned steroids.     

Investigations on the Δ23-, Δ24(28)- and Δ25-Sterols of zea mays

The sterols of Zea mays shoots were isolated and characterized by TLC, HPLC, GC/MS and ¹H NMR techniques. In all, 22 4-demethyl sterols were identified and they included trace amounts of the Δ²³-, Δ²⁴- and Δ²⁵-sterols, 24-methylcholesta-5,E-23-dien-3β-ol, 24-methylcholesta-5,Z-23-dien-3β-ol, 24-methylcholesta-5,25-dien-3β-ol, 24-ethylcholesta-5,25-dien-3β-ol and 24-ethylcholesta-5,24-dien-3β-ol. In the 4,4-dimethyl sterol fraction, cycloartenol and 24-methylenecycloartanol were the major sterol components but small amounts of the Δ²³-compound, cyclosadol, and the Δ²⁵-compound, cyclolaudenol, were recognized. These various Δ²³- and Δ²⁵-sterols may have some importance in alternative biosynthetic routes to the major sterols, particularly the 24β-methylcholest-5-en-3β-ol component of the C₂₈-sterols. Radioactivity from both [2-¹⁴C]MVA and [methyl-¹⁴C]methionine was incorporated by Z. mays shoots into the sterol mixture. Although 24-methylene and 24-ethylidene sterols were relatively highly labelled, the various Δ²³- and Δ²⁵-sterols contained much lower levels of radioactivity, which is possibly indicative of their participation in alternative sterol biosynthetic routes. (24R)-24-Ethylcholest-5-en-3β-ol (sitosterol) had a significantly higher specific activity than the 24-methylcholest-5-en-3β-ol indicating that the former is synthesized at a faster rate.     

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.     

Accumulation of Δ8,14-sterols in suspension cultures of bramble cells cultured with an azasterol antimycotic agent (A25822B)

Bramble suspension cultures normally contain Δ⁵-sterols (sitosterol, campesterol and isofucosterol). When the cells were grown in a medium supplemented with 15-aza-24-methylene-d-homocholesta-8,14-dien- 3β-ol, Δ⁵-sterols disappeared almost completely whereas Δ^8,14-sterols accumulated strongly. Five Δ^8,14-sterols, including two new compounds, (24R)-24-ethyl-5α-cholesta-8,14-dien-3β-ol and 4α-methyl-5α-stigmasta-8,14, Z-24(28)-trien-3β-ol, were identified. The 15-azasterol probably inhibited the reduction of the Δ¹⁴-bond. Cell lines growing permanently in an azasterol-supplemented medium were obtained.     

Utilization of Δ5,7 - and Δ8-sterols by larvae of Heliothis zea

Larvae from two populations of Heliothis zea were reared on artificial diets containing various sterols, which supported suboptimal growth, and their tissue sterols were characterized in order to determine how these dietary sterols are utilized by this insect. The sterols studied included Δ^5,7-sterols (7-dehydrocholesterol or ergosterol), Δ⁸-sterols (lanosterol and/or 24-dihydrolanosterol), and a Δ⁵-sterol (4,4-dimethylcholesterol). Although larvae did not develop on 4,4-dimethylcholesterol, those fed primarily Δ⁸-4,4,14-trimethylsterols developed to the third instar. When the latter sterols were spared with cholesterol, the larvae reached the sixth instar and contained 4,4,14-trimethylsterols as well as cholesterol in their tissues. When larvae were fed 7-dehydrocholesterol, <1% of the larvae from one population developed to the sixth instar and these larvae contained 7-dehydrocholesterol as their principal sterol. The other larvae successfully completed their larval stage when they were transferred from the diet containing 7-dehydrocholesterol (or no sterol) to a diet containing cholesterol within at least 9 days. The sterol composition of larvae transferred from a diet containing cholesterol to a diet containing 7-dehydrocholesterol, after they had reached 60% of their final weight, was 54% cholesterol and 46% 7-dehydrocholesterol. The major sterol isolated from the tissues of the larvae fed ergosterol was also 7-dehydrocholesterol. Therefore, although the larva of H. zea can dealkylate and saturate the side chain of the Δ^5,7,22-24β-methylsterol, it carries out little metabolism of the B ring of the nucleus. These studies demonstrate that, when Δ^5,7- or Δ⁸-sterols are the principal sterols in the diet of H. zea, they are absorbed and incorporated into its tissues, although they slow the rate of growth and may prevent complete development of the larva.