Studies on Chemical Constituents of the Plant Fritillaria unibracteata

The plant Fritillaria unibracteata Hsiao et K. CHsia of the family Liliaceae is an elemental species of traditional Chinese drug "Chuan Beimu" in Chinese Pharmacopoeia. Four compounds(C, D, E,F) have been isolated from its medicinal part (dried bulb). The latter three compounds were identified as D/E cis(22R, 25s)-20- deoxy-3β,6β-dihydroxy-5α,14α, 17β-cevanine(D), β-sitcsterol (E), stearic acid and palmitic acid(F) by mean of spectroscopic methods. Compound D belongs to a new alkaloid of cevine group of isosteroidal alkaloids which is attributed to the characteristic constituent of this genus, named as songbeinine.     

The Existence of Isosteroidal Alkaloids in Fritillaria L.(Liliaceae) and Its Taxonomical Significance

The plant chemotaxonomical marker of Fritillaria L. is discussed in this paper according to the information on chemical components. Plenty of evidence shows that 5α-cevanine isosteroidal alkaloids are the characteristic constituents of this genus. In the light of the biogensis of this kind of alkaloids, the C-13 and C- 17 of the molecular structures may be rational positions uniting a nitrogenous group in their biosyntheses which make two kinds of 5α-cevanine isosteroidal alkaloids, the dihydrogen of C- 13 and C- 17 being at the state of trans-configuration (e. g. verticine, verticinone) and at the state of cisconfiguration (e.g. delavine, chuanbeinone and songbeinine). Meanwhile, this paper reports the existence and content of some 5α-cevanine isosteroidal alkaloids in main Chinese fritillarias. This result reveals that there may be a relationship between the formation of characteristic constituents on one hand and other morphological characters and distribution of the plants concerned on the other,which encourages further investigation.     

Two steroidal alkaloids from fritillaria harelinii

Two new steroidal alkaloids named harepermine and hareperminside have been isolated from the bulbs of Fritillaria harelinii together with a known alkaloid, peiminine. The structure of the alkaloids were found to be 3β, 6β-dihydroxy-5α, 14α,17β-cevanine and its 3-O-glucoside on the basis of spectroscopic evidence.     

Studies on Chemical Constituents of Fritillaria yuminensis

Six compounds were isolated from the bulbs of Fritillaria yuminensis X. Z. Duan. They were elucidated as 5α, 14α-cevanine-3α-hydroxy-6-one ( Ⅰ ), 5α, 14α-cevanine-3-one-6β-O-β-D-glucoside ( Ⅱ ), imperialine ( Ⅲ ), delavinone ( Ⅳ ), tortifolisine ( Ⅴ ) and adenosine( Ⅵ ) by means of spectral analysis and chemical reaction. They all were firstly isolated from this plant. Among them, compound Ⅰ and Ⅱ, named yubeinine and yubeiside respectively, were new compounds.     

New Steroidal Saponin of Stem and Leaf of Fritillaria ussuriensis Maxim

A new steroidal saponin, pingpeisaponin, was isolated from stem and leaf of Fritillaria ussuriensis Maxim by column chromatographic technique. On the basis of the IR, MS, 1H NMR and 13C NMR spectra of pingpei saponin, the structure has been established as 24α-hydroxyl diosgenin-3-O-α-L-rhomno-pyranosyl-(l-2)-β-D-glucopyranoside.     

Studies on Chemicai Constituents of Fritillaria thunbergii Miq.

In our previous paper, it was reported that peimine, peiminine and a new alkaloid, Zhebeinine, were isolated from the bulbs of Fritillaria thunbergii Miq. In consecutive investigation of the plant, an additional new alkloid, 5α, 14α-cevanine-3β-hydroxy-6-one, named zhebei rine(2) and a known eduardine (1) were isolated and the structure of zhebeirine was determined on the basis of spectral analysis. Eduardine(1) was firstly isolated from the bulbs.     

Synthesis and stereochemistry of C-3- and C-7-linked (O-carboxymethyl)-oximino- and hemisuccinamido derivatives of 5 alpha-dihydrotestosterone.

The 3-(O-carboxymethyl)oximino derivative of 17β-hydroxy-5α-androstan-3-one (5α-dihydrotestosterone) was prepared. Thin-layer chromatography of the corresponding methyl ester showed the presence of two syn (60%) and anti (40%) geometrical isomers of the oxime chain to the C-4 position, which were characterized by ¹³C nmr. The 3β-hemisuccinami-do-5α-androstan-17β-ol was obtained after selective saponification with potassium carbonate of the 17β-hemisuccinate group of the 3,17-dihemi-succinoylated derivative of the previously described 3β-amino-5α-androstan-17β-ol. This 3β-hemisuccinamide was purified as the corresponding methyl ester-17β-acetate and was regenerated after saponification. The 3,3'-ethylenedioxy-7-oxo-5α-androstan-17β-yl acetate was obtained in quantitative yield by catalytic hydrogenation over 10% palladium-oncharcoal of the Δ⁵-7-oxo precursor in a dioxane-ethanol mixture containing traces of pyridine. The exclusive 5α-configuration of this hydrogenated product was established from nmr data and was confirmed by the synthesis of methyl 3,3'-ethylenedioxy-7-oxo-5β-cholan-24-oate as 5β-H-reference compound. The preceding 5α-H-7-ketone was converted into the 7-(O-carboxymethyl)oximino derivative (syn isomer to the C-6 position, exclusively) which was esterified into the corresponding methyl ester. The selective hydrolysis of the 3-ethyleneketal group was achieved by a short treatment with a formic acid-ether 1:1 (v/v) mixture at 20°C. Saponification of the latter reaction product with ethanolic potassium hydroxide gave the 7-(O-carboxymethyl)oximino-17β-hydroxy-5α-androstan-3-one derivative, which was characterized as the corresponding methyl ester. The reduction of the oxime of the 5α-H-7-ketone with sodium in ethanol or with lithium-aluminium hydride gave respectively the 7β-amine or the 7α-amine as the major product. The 7β- and 7α-configurations were established from nmr spectra of the corresponding 7-acetamido derivatives. The 7β- and 7α-hemisuccinamido derivatives were prepared from the mixture of 7β- and 7α-amines, as described above for 3-derivatives and were isolated after thin-layer chromatography of the methyl esters, followed by saponification of the corresponding 17β-acetates.     

Effect of ageing on sterol metabolism in potato tuber slices

When fresh potato tuber slices were incubated with [1-¹⁴C]-sodium acetate, cycloartenol was heavily labelled but no radioactivity was recovered in 24-methylene cycloartanol and free sterols. If potato slices were aged for 0–24 hr before feeding with radioactive acetate, a rapid increase of the label in the sterol precursors and the free sterols was observed. The free sterol content was 5 × higher after ageing for 24 hr. Isofucosterol synthesis was especially stimulated. The synthesis of sterols during the ageing process seems to be related to the appearance of a cycloartenol C24-methylase and may be linked to a biogenesis of membranes.Nomenclature: (1) 4,4,14α-trimethyl 9β, 19β-cyclo-5α-cholest-24-en 3β-ol; (2) 4,4,14α-trimethyl 9β, 19β-cyclo-5α-ergost-24(28)-en 3β-ol; (3) 4α,14α-dimethyl 9β,19β-cyclo 5α-ergost 24(28)-en 3β-ol; (4) 4α, 14α-dimethyl 5α-ergosta 8.24(28)-dien 3β-ol; (5) 4α-methyl 5α-ergosta 7,24(28)-dien 3β-ol; (6) ergosta 5,24(28)-dien 3β-ol; (7) stigmasta 5,Z-24(28)-dien 3β-ol; (8) (24R)-24 methyl cholest 5-en 3β-ol; (9) (24R)-24 ethyl cholest 5-en 3β-ol; (10) (24S)-24 ethyl cholesta 5,E-22(23)-dien 3β-ol; (11) cholest 5-en 3β-ol.     

Chemical constituents from bulbs of Fritillaria pallidiflora Schrenk

A new steroidal alkaloid, 5α, 14α, 17β-cevanin-6-oxo-3β, 20β, 24β-triol(1), together with ten known compounds (2–11) were isolated from the bulbs of Fritillaria pallidiflora Schrenk. Their structures were determined on the basis of spectroscopic analysis and by comparison of their spectral data with those reported in the literature. Compounds 8, 9, 10 were obtained from the genus Fritillaria for the first time; Compounds 2, 3, 4 and 11 are isolated from this plant for the first time.     

Stereospecific reduction of progesterone by Pisum sativum

[4 -¹⁴C]-Progesterone was applied to the leaves of growing pea plants, Pisum sativum. After 3 weeks, about 50% of the administered steroid was reduced, about 20% being reduced to 5α-pregnane-3α,20β-diol as the major metabolite. The radioactivities of 5α-pregnane-3α,20α-diol and 5α-pregnane-3α,20β-diol after 3 weeks were more than twice those after one week. The following radioactive metabolises were also isolated: 5α-pregnane-3,20-dione; 20α-hydroxy-4- pregnen-3-one; 20β-hydroxy-4-pregnen-3-one; 3α-hydroxy-5α-pregnan-20-one; 3α-hydroxy-5β-pregnan-20-one; 3β-hydroxy- 5α-pregnan-20-one; 20β-hydroxy-5α-pregnan-3-one; 5α-pregnane-3β,20β-diol; and 5β-pregnane-3α,20β-diol. The radioactivities of the 5α-pregnane derivatives were considerably higher than those of the corresponding 5β-pregnane derivatives.     

Acetylation and hydroxylation of 5alpha-androstane-3beta,17beta-diol by prostate and epididymis

An unknown radiometabolite, formed in the canine prostate and epididymis after intra-arterial infusion of testosterone-4-¹⁴C in physiologic saline and extraction of the organs with ethyl acetate-acetone, was identified as the 3-monoacetate of 5α-androstane-3β, 17β-diol (3β-diol). Transformation of 3β-diol-¹⁴C to its identified 3-monoacetate derivative could also be demonstrated, if the incubation of the radiosubstrate with minced canine prostate was terminated by ethyl acetate extraction. The formation of polar products in high yield was noted. Whereas minced canine prostate actively converted 5α-androstane-3α,17β-diol-¹⁴C to 17β-hydroxy-5α-androstan-3-one-¹⁴C, the same preparation hydroxylated 3β-diol-¹⁴C predominantly at the 7ξ- and, to a lesser extent, at the 6ξ-positions. Partial identification of the hydroxylated radiometabolites was by crystallization of the CrO₃-oxidation products 5α-androstane-3,6,17-trione-¹⁴C and 5α-androstane-3,7,17-trione-¹⁴C to constant SA and by GLC/MS of the latter derivative. NADPH-supplementation of the preparation enhanced the yield of hydroxylated products derived from 3β-diol-¹⁴C in a 1 hr incubation from 22% to 41%. Analogous supplemented incubations of benign hyperplastic human prostate and canine epididymis produced polar metabolites (in 12.5% and 76% yields, respectively) which gave rise to similar proportions of the same androstanetrione epimers on CrO₃-oxidation.     

Biotransformation of testosterone and other androgens by suspension cultures of Nicotiana tabacum “Bright yellow”

It has been shown that the cultured cells of Nicotiana tabacum “Bright Yellow” are capable of transforming testosterone to Δ⁴-androstene-3, 17-dione, 5α-androstan-17β-ol-3-one, 5α-androstane-3β, 17β-diol, its dipalmitate and 3- and 17-monoglucosides, epiandrosterone, its palmitate and glucoside, testosterone glucoside. 5α-Androstane-3β, 17β-diol dipalmitate and 3- and 17-monoglucosides, epiandrosterone palmitate and glucoside, and testosterone glucoside have been found for the first time as metabolites of testosterone in plant systems. Δ⁴-Androstene-3,17-dione was converted to testosterone. 5α-Androstan-17β-ol-3-one, which has been recognized as an active form of testosterone in mammals, was also detected. It has also been demonstrated that [4-¹⁴C]testosterone is actively incorporated in these transformations.     

Isotope ratio mass spectrometry analysis of the oxidation products of the main and minor metabolites of hydrocortisone and cortisone for antidoping controls

Metabolites of hydrocortisone (HC) and cortisone (C), namely tetrahydrocortisol (THF), tetrahydrocortisone (THE), allo-THF, allo-THE for the main metabolites and 11-hydroxyandrosterone, 11-hydoxyetiocholanolone, 11-ketoandrosterone, and 11-ketoetiocholanolone for the minor metabolites, as well as the two main metabolites of testosterone, androsterone and etiocholanolone, were separated from each other using HPLC fractionation of urine extracts. An isotopic ratio mass spectrometry (IRMS) analysis determined the absolute δ¹³C values of 5α-androstanetrione (5α-AT) and 5β-androstanetrione (5β-AT) as the oxidation products (ox-products) of the HC and C metabolites and as target compounds (TCs). We also performed IRMS analysis of 5α-androstanedione (5α-AD) and 5β-androstanedione (5β-AD) as the ox-products of etiocholanolone and androsterone and as endogenous reference compounds (ERCs). Urine samples came from two male volunteers treated with a single 10-mg oral dose and a single 100-mg intramuscular dose of HC hemisuccinate, a male volunteer treated with a single 25-mg oral dose of C acetate, and a control group of 30 drug-free athletes. The mean −3SD of δ¹³C depletion values from the controls were −1.46, −1.98, −1.78 and −2.42 for 5β-AT-5β-AD, 5α-AT-5β-AD, 5β-AT-5α-AD and 5α-AT-5α-AD, respectively, indicating −3‰ as a safe cut-off value for differentiating the pharmaceutical from the natural form. In the main metabolite fraction, δ¹³C depletion values peaked around −5‰ and −9‰ after oral and intramuscular administration of HC, respectively, and around −6‰ after oral administration of C. In comparison, less impressive results were obtained when IRMS analysis focused on the ox-products of the minor metabolites.     

In vitro conversion of testosterone-4-14C to androgens of the 5alpha-androstane series by a normal human ovary

In a previous communication (1) the identification of Δ⁴ -3-oxo-steroids and estrogens as metabolites of testosterone-4-¹⁴C incubated with normal post-ovulatory human ovaries was reported. Thin-layer chromatography of the extracts of those ovaries which contained no corpus luteum yielded zones of radioactivity which were not associated with any of these products. Detailed investigation of these zones from the extract of one of these glands resulted in identification of the following radiometabolites of the 5α-androstane series: 5α-androstane-3,17-dione, androsterone, 3β-hydroxy-5α-androstan-17-one, 17β-hydroxy-5α-androstan-3-one, 5α-androstane-3ga, 17β-diol and 5α-androstane-3β, 17β-diol. The capacity of a normal human ovary to produce these 5α-reduced androgens, especially the potent 17β-hydroxy-steroids, suggests a regulatory role of these compounds in ovarian function.     

Microbial Baeyer–Villiger oxidation of 5α-steroids using Beauveria bassiana. A stereochemical requirement for the 11α-hydroxylation and the lactonization pathway

Beauveria bassiana KCH 1065, as was recently demonstrated, is unusual amongst fungal biocatalysts in that it converts C₁₉ 3-oxo-4-ene and 3β-hydroxy-5-ene as well as 3β-hydroxy-5α-saturated steroids to 11α-hydroxy ring-D lactones. The Baeyer–Villiger monooxygenase (BVMO) of this strain is distinguished from other enzymes catalyzing BVO of steroidal ketones by the fact that it oxidizes solely substrates with 11α-hydroxyl group. The current study using a series of 5α-saturated steroids (androsterone, 3α-androstanediol and androstanedione) has highlighted that a small change of the steroid structure can result in significant differences of the metabolic fate. It was found that the 3α-stereochemistry of hydroxyl group restricted “normal” binding orientation of the substrate within 11α-hydroxylase and, as a result, androsterone and 3α-androstanediol were converted into a mixture of 7β-, 11α- and 7α-hydroxy derivatives. Hydroxylation of androstanedione occurred only at the 11α-position, indicating that the 3-oxo group limits the alternative binding orientation of the substrate within the hydroxylase. Only androstanedione and 3α-androstanediol were metabolized to hydroxylactones. The study uniquely demonstrated preference for oxidation of equatorial (11α-, 7β-) hydroxyketones by BVMO from B. bassiana. The time course experiments suggested that the activity of 17β-HSD is a factor determining the amount of produced ring-D lactones. The obtained 11α-hydroxylactones underwent further transformations (oxy-red reactions) at C-3. During conversion of androstanedione, a minor dehydrogenation pathway was observed with generation of 11α,17β-dihydroxy-5α-androst-1-en-3-one. The introduction of C1C2 double bond has been recorded in B. bassiana for the first time.     

Selective oxidation of steroidal allylic alcohols

Pyridinium chlorochromate in CH₂Cl₂ containing pyridine (2%) at 2—3°C has been found to effect the high yield selective oxidation of the hydroxyl function of a number of steroidal allylic alcohols. Under these conditions the oxidation of cholest-4-cn-3β-ol to the corresponding ketone was effected in 92% yield. Only the allylic hydroxyl function of 5α-cholest-8(14)-ene-3β,15α-diol, 5α-cholest-8(14)ene-3β,15β-diol and 5α-cholest-8(14)-ene-3β,7β-diol was oxidized under these conditions to give the corresponding α,β-unsaturated ketones in high yields. 5α-Cholest-8(14)-ene-3β,7α,15α-triol gave 5α-cholest-8(14)-ene-3β,7α-diol-15-one in 82% yield. Attempted oxidations of the 5α-cholestan-3β,15α-diol and 5α-cholest-7-ene-3β,15α-diol, both lacking an allylic hydroxyl function, under these conditions, were unsuccessful. Selective oxidation of the allylic alcohol function of 5α-cholest-8(14)-ene-3β,15β-diol using activated manganese dioxide gave 5α-cholest-8(14)-en-3β-ol-15-one in high yield while oxidation of the corresponding 15α-hydroxy epimer using manganese dioxide was unsuccessful.     

The occurrence and subcellular localization of 3 -hydroxysteroid dehydrogenase in adult rat brain

The subcellular localization of 3α-hydroxysteroid dehydrogenase, the dependency of the rate of reaction on time, concentration of protein, cofactor requirements and the substrate stereospecificity were investigated in the adult rat brain. The $\text{in vitro}$ conversion of 3-keto-5β-cholanoic-24-¹⁴C acid to lithocholic acid was shown to occur in the cytosol without added cofactors. Incubation of ¹⁴C labeled 3α,7α-dihydroxy-5β-cholanoic and 3α,12α-dihydroxy-5β-cholanoic acids with adult rat brain cell-free preparations resulted in the production of less polar metabolites identified as 3-keto-7α-hydroxy-5β-cholanoic and 3-keto-12α-hydroxy-5β-cholanoic acids by TLC, GLC combined with a radioactive monitoring detection system and by cocrystallization to constant specific activity.     

Metabolism of progesterone by chorionic cells of the early sheep conceptus invitro

Progesterone-4-¹⁴C was extensively metabolized during incubation with dispersed trophoblast prepared from chorionic membranes of the 21-day sheep conceptus. Of the metabolites formed, 17,20α-dihydroxypregn-4-en-3-one, 20α-hydroxypregn-4-en-3-one, 20(β-hydroxypregn-4-en-3-one, 5α-pregnane-3α,17,20α-triol, 5β-pregnane-3ga, 17,20α-triol, 5β-pregnane-3g,20α-diol, 3β-hydroxy-5α-pregnan-20-one, 3α-hydroxy-5β-pregnan-20-one, 20β-hydroxy-5β-pregnan-3-one, 5α-pregnane-3,20-dione and 5β-pregnane-3,20-dione were identified. These findings indicate that the sheep conceptus acquires extensive steroid metabolizing capability very early in pregnancy.     

Effect of ay-9944 on sterol biosynthesis in Chlorella sorokiniana

When Chlorella sorokiniana was grown in the presence of 4 ppm AY-9944 total sterol production was unaltered in comparison to control cultures. However, inhibition of sterol biosynthesis was shown by the accumulation of a number of sterols which were considered to be intermediates in sterol biosynthesis. The sterols which were found in treated cultures were identified as cyclolaudenol, 4α,14α-dimethyl-9β,19-cyclo-5α-ergost-25-en-3β-ol, 4α,14α-dimethyl -5α-ergosta-8,25-dien-3β-ol, 14α-methyl-9β,19-cyclo-5α-ergost-25-en-3β-ol, 24-methylpollinastanol, 14α-methyl-5α-ergost-8-en-3β-ol, 5α-ergost -8(14)-enol, 5α-ergost-8-enol, 5α-ergosta-8(14),22-dienol, 5α-ergosta-8,22-dienol, 5α-ergosta-8,14-dienol, and 5α-ergosta-7,22-dienol, in addition to the normally occurring sterols which are ergosterol, 5α-ergost-7-enol, and ergosta-5,7-dienol.The occurrence of these sterols in the treated culture indicates that AY-9944 is an effective inhibitor of the Δ⁸ → Δ⁷ isomerase and Δ¹⁴-reductase, and also inhibits introduction of the Δ²²-double bond. The occurrence of 14α-dimethyl-5α-ergosta-8,25-dien-3β-ol and 14α-methyl-9β,19-cyclo-5α-ergost -25-en-3β-ol is reported for the first time in living organisms. The presence of 25-methylene sterols suggests that they, and not 24-methylene derivatives, are intermediates in the biosynthesis of sterols in C. sorokiniana.     

Engineering steroid hormone specificity into aldo-keto reductases

Steroid hormone transforming aldo-keto reductases (AKRs) include virtually all mammalian 3α-hydroxysteroid dehydrogenases (3α-HSDs), 20α-HSDs, as well as the 5β-reductases. To elucidate the molecular determinants of steroid hormone recognition we used rat liver 3α-HSD (AKR1C9) as a starting structure to engineer either 5β-reductase or 20α-HSD activity. 5β-Reductase activity was introduced by a single point mutation in which the conserved catalytic His (H117) was mutated to Glu117. The H117E mutant had a k_cat comparable to that for homogeneous rat and human liver 5β-reductases. pH versus k_cat profiles show that this mutation increases the acidity of the catalytic general acid Tyr55. It is proposed that the increased TyrOH₂⁺ character facilitates enolization of the Δ⁴-3-ketosteroid and subsequent hydride transfer to C5. Since 5β-reductase precedes 3α-HSD in steroid hormone metabolism it is likely that this metabolic pathway arose by gene duplication and point mutation. 3α-HSD is positional and stereospecific for 3-ketosteroids and inactivates androgens. The enzyme was converted to a robust 20α-HSD, which is positional and stereospecific for 20-ketosteroids and inactivates progesterone, by the generation of loop-chimeras. The shift in log₁₀(k_cat/K_m) from androgens to progestins was of the order of 10¹¹. This represents a rare example of how steroid hormone specificity can be changed at the enzyme level. Protein engineering with predicted outcomes demonstrates that the molecular determinants of steroid hormone recognition in AKRs will be ultimately rationalized.