Application of α- and β-naphthoflavones as monooxygenase inhibitors of Absidia coerulea KCh 93, Syncephalastrum racemosum KCh 105 and Chaetomium sp. KCh 6651 in transformation of 17α-methyltestosterone

In this work, 17α-methyltestosterone was effectively hydroxylated by Absidia coerulea KCh 93, Syncephalastrum racemosum KCh 105 and Chaetomium sp. KCh 6651. A. coerulea KCh 93 afforded 6β-, 12β-, 7α-, 11α-, 15α-hydroxy derivatives with 44%, 29%, 6%, 5% and 9% yields, respectively. S. racemosum KCh 105 afforded 7α-, 15α- and 11α-hydroxy derivatives with yields of 45%, 19% and 17%, respectively. Chaetomium sp. KCh 6651 afforded 15α-, 11α-, 7α-, 6β-, 9α-, 14α-hydroxy and 6β,14α-dihydroxy derivatives with yields of 31%, 20%, 16%, 7%, 5%, 7% and 4%, respectively. 14α-Hydroxy and 6β,14α-dihydroxy derivatives were determined as new compounds. Effect of various sources of nitrogen and carbon in the media on biotransformations were tested, however did not affect the degree of substrate conversion or the composition of the products formed. The addition of α- or β-naphthoflavones inhibited 17α-methyltestosterone hydroxylation but did not change the percentage composition of the resulting products.     

Biocatalyst mediated production of 6β,11α-dihydroxy derivatives of 4-ene-3-one steroids

Biotransformation of steroids with 4-ene-3-one functionality such as progesterone (I), testosterone (II), 17α-methyltestosterone (III), 4-androstene-3,17-dione (IV) and 19-nortestosterone (V) were studied by using a fungal system belonging to the genera of Mucor (M881). The fungal system efficiently and quantitatively converted these steroids in regio- and stereo-selective manner into corresponding 6β,11α-dihydroxy compounds. Time course experiments suggested that the transformation was initiated by hydroxylation at 6β- or 11α-(10β-hydroxy in case of V) to form monohydroxy derivatives which upon prolonged incubation were converted into corresponding 6β,11α-dihydroxy derivatives. The fermentation studies carried out using 5 L table-top fermentor with substrates (I and II) clearly indicates that 6β,11α-dihydroxy derivatives of steroids with 4-ene-3-one functionality can be produced in large scale by using M881.     

Enzymatic biotransformation of terpenes as bioactive agents

The plant-derived terpenoids are considered to be the most potent anticancer, anti-inflammatory and anticarcinogenic compounds known. Enzymatic biotransformation is a very useful approach to expand the chemical diversity of natural products. Recent enzymatic biotransformation studies on terpenoids have resulted in the isolation of novel compounds. 14-hydroxy methyl caryophyllene oxide produced from caryophyllene oxide showed a potent inhibitory activity against the butyryl cholinesterase enzyme, and was found to be more potent than parent caryophyllene oxide. The metabolites 3β,7β-dihydroxy-11-oxo-olean-12-en-30-oic acid, betulin, betulonic acid, argentatin A, incanilin, 18β glycyrrhetinic acid, 3,11-dioxo-olean-12-en-30-oic acid produced from 18β glycyrrhetinic acid were screened against the enzyme lipoxygenase. 3,11-Dioxo-olean-12-en-30-oic acid, was found to be more active than the parent compound. The metabolites 3β-hydroxy sclareol 18α-hydroxy sclareol, 6α,18α-dihydroxy sclareol, 11S,18α-dihydroxy sclareol, and 1β-hydroxy sclareol and 11S,18α-dihydroxy sclareol produced from sclareol were screened for antibacterial activity. 1β-Hydroxy sclareol was found to be more active than parent sclareol. There are several reports on natural product enzymatic biotransformation, but few have been conducted on terpenes. This review summarizes the classification, advantages and agents of enzymatic transformation and examines the potential role of new enzymatically transformed terpenoids and their derivatives in the chemoprevention and treatment of other diseases.     

The facile bioconversion of testosterone by alginate-immobilised filamentous fungi

The potential for biotransformation of the substrate 17β-hydroxyandrost-4-en-3-one (testosterone) by six filamentous fungi, namely, Rhizopus oryzae ATCC 11145, Mucor plumbeus ATCC 4740, Cunninghamella echinulata var. elegans ATCC 8688a, Aspergillus niger ATCC 9142, Phanerochaete chrysosporium ATCC 24725 and Whetzelinia sclerotiorum ATCC 18687, was investigated. In this study both free cells and macerated mycelia immobilised in calcium alginate were utilised and the results (products, % yields, % transformation) were compared. In general the encapsulated cells of the microorganisms effectively generated products similar to those found using free cells. However, with immobilised macerated mycelia, isolation of the transformation products was expedited by the simple work up procedure, and their purification was facilitated by the absence of fungal secondary metabolites. Twenty seven analogues of testosterone were generated, wherein the androstane skeleton was functionalised at C-1β, -2β, -6β, -7α, -11α, -14, -15α, -15β and -16β by the moulds. Redox chemistry was also observed. Seven of the analogues, 6β,11α,17β-trihydroxyandrost-4-en-3-one, 6β,14α,17β-trihydroxyandrost-4-en-3-one, 2,6β-dihydroxyandrosta-1,4-diene-3,17-dione, 2β,16β-dihydroxyandrost-4-ene-3,17-dione, 2β,6β-dihydroxyandrost-4-ene-3,17-dione, 2β,15β,17β-trihydroxyandrost-4-en-3-one and 2β,3α,17β-trihydroxyandrost-4-ene, were novel compounds. Five others, namely, 7α,17β-dihydroxyandrost-4-en-3-one, 6β,14α-dihydroxyandrost-4-ene-3,17-dione, 15α,17β-dihydroxyandrost-4-en-3-one, 16β,17α-dihydroxyandrost-4-en-3-one and 2β,16β,17β-trihydroxyandrost-4-en-3-one, were fully characterised for the first time.     

Three ent-kaurene diterpenes from Vellozia caput-ardeae

Three new ent-kaurene diterpenes have been isolated from the roots and stem of Vellozia caput-ardeae. Their structures were elucidated by spectroscopic methods as ent-9β-hydroxy kaur-16-ene, ent-11α-hydroxy kaur-16-ene and ent-9β,11α-dihydroxy kaur-16-ene.     

Biotransformations of steroid compounds by Chaetomium sp. KCH 6651

Biotransformations of steroid compounds: androstenedione, testosterone, progesterone, pregnenolone and DHEA using Chaetomium sp. 1 KCH 6651 strain as a biocatalyst were investigated. The microorganism proved capable of selective hydroxylation of the steroid substrates. Androstenedione was converted to 14α-hydroxyandrost-4-en-3,17-dione (in over 75% yield) and 6β-hydroxyandrost-4-en-3,17-dione (in low yield), while testosterone underwent regioselective hydroxylation at 6β position. Progesterone was transformed to a single product—6β,14α-dihydroxypregnan-4-en-3,20-dione in high yield, whereas biotransformation of DHEA resulted in the formation of 7α-hydroxy derivative, which was subsequently converted to 7α-hydroxyandrost-4-en-3,17-dione.     

The germacranolides of Viguiera buddleiaeformis structures of budlein-A and -B

The structure of budlein-A, the main sesquiterpene lactone of Viguiera buddleiaeformis was established as the 8 angeloyl ester of 1 keto, 8-β, 14-dihydroxy germacra-2,4,11 (13)-trien-3, (10 β) oxido-6 α, 12-olide. Its structure and stereochemistry was determined by chemical and spectroscopic means. Budlein-B, found in the same plant as a minor constituent, is 8 α, 15-dihydroxygermacra-1 (10), 4, 11 (13)-trien-6 α, 12-olide.     

The metabolism of androgens in rat preputial glands

The metabolism of testosterone, androstenedione and dehydroepiandrosterone in the rat preputial gland has been studied. A high activity of 5α-reductase is present as shown by the formation of 17β hydroxy-5α-androstan-3-one and 5α-androstan-3, 17-dione as the major products from testosterone and androstenedione respectively. Other enzyme activities are present including 17β-hydroxy steroid dehydrogenase, but the amounts of testosterone and 17β-hydroxy-5α-androstan-3-one formed from androstenedione and dehydroepiandrosterone are low. The main product of dehydroepiandrosterone metabolism was androstenedione indicating a high level of 3β-hydroxy steroid dehydrogenase 4-5 isomerase activity. The metabolism was compared with that in rat skin where it was found that the extent of metabolism was much less. The possible significance of the various products formed and of differences between skin and preputial gland metabolism is discussed. Some differences were noted between the metabolism of androgens by rat skin and preputial gland and the metabolism of androgens by human skin.     

Comparative placental steroid synthesis. II. C19 steroid metabolism by guinea-pig placentas and fetal adrenals in vitro

Placental homogenates from guinea-pigs at 16, 20, 35 and 55 days gestation were incubated with 7α-³H-dehydroepiandrosterone and 4-¹⁴C-androstenedione and analyzed for conversion products by reverse isotope dilution methods. ¹⁴C-3α-Hydroxy-5α-androstan-17-one, ¹⁴C-androstane-3α, 17β-diol and ³Handrost-5-ene-3β, 17β-diol were isolated from homogenates incubated with substrates for 2 hours. ³H, ¹⁴C-Testosterone was isolated from preparations incubated for 15 minutes or with high substrate: tissue ratios. Androst-4-ene-3, 17-dione, 5α-androstane-3, 17-dione, 5β-androstanedione derivative and C₁₈ steroid formation could not be demonstrated. These results demonstrate the capacity of guinea-pig placentas to convert dehydroepiandrosterone and androstenedione to testosterone and to derivatives reduced in ring A (5α) and at carbon 17. The activity of the Δ⁵-3β-hydroxysteroid dehydrogenase enzyme system appears to have been rate limiting.Homogenates of adrenals from 44–55 day old fetuses converted 4-¹⁴C-pregnenolone to androst-4-ene-3, 17-dione and 6β- and 11β-hydroxyandrostenedione. A guineapig fetal-placental unit is postulated, with steroid metabolic characteristics different from the human unit. Both permit reduction of fetal adrenal cortisol production and placental removal of C₁₉ steroids.     

Identification and quantification of C21 and C19 steroids in the haemolymph of Leptinotarsa decemlineata,a phytophagous insect

o-Pentafluorobenzyloxime (OPFB)-heptafluorobutyrylester (HFB)-derivatives were prepared from extracts of haemolymph from last instar larvae of Leptinotarsa decemlineata and subjected to negative ion chemical ionization capillary gas chromatography-mass spectrometry (NCI/GC-MS). Ten C21 and C19 steroids could be positively identified: testosterone, dehydroepiandrosterone, 5α-dihydrotestosterone, 11-ketotestosterone, 11β-hydroxytestosterone, androstenedione, progesterone, 17α-hydroxyprogesterone, pregnenolone and 17α,20β-dihydroprogesterone. No estrogens could be found in these larvae. Radioimmunoassay of chromatographed extracts of haemolymph taken from the larval and pupal stages showed fluctuations in testosterone (and 5α-dihydrotestosterone) titer.     

Intracellular distributian and substrate specificity of the 16 alpha-hydroxylase in the adrenal of human fetus

When [7α-³H] dehydroepiandrosterone was incubated with the adrenal homogenates of human fetus at 22 to 26 weeks gestational age, 16α-hydroxydehydroepiandrosterone and/or its sulfate was formed as the only detectable metabolite. The 16α-hydroxylase activity was concentrated in the microsomal fraction of the adrenal homogenate.[1,2-³H]Androstenedione, [4-¹⁴C] pregnenolone and [7α-³H] progesterone were also 16α-hydroxylated by incubation with the microsomal fraction. Amoung these substrates, progesterone gave the highest yield of 16α-hydroxylated products. By incubation with the microsomal fraction, formation of following steroids were also established: 6β-hydroxyandrostenedione from androstenedione; 17-hydroxypregnenolone, 17,21-dihydroxypregnenolone and dehydroepiandrosterone from pregnenolone; 17-hydroxy-progesterone, deoxycorticosterone, 11-deoxycortisol and androstenedione from progesterone.     

Metabolic transformations of some ent-kaurenes in Gibberella fujikuroi

The conversion of ent-kaur-16-enes to gibberellic acid in Gibberella fujikuroi is blocked by A-ring modifications. Thus ent-3β-hydroxykaur-16-en-19-yl succinate gives good conversion (46%) to the 7β-hydroxy derivative.* Under the same conditions the 3β-epimer gives 7β- or 6α-hydroxylation and the former occurs for the 3-oxo analogue. The succinoyloxy function acts as a less efficient block and ent-kaur-16-en-19-yl succinate is converted to 7β-hydroxy and 6β,7β-dihydroxy derivatives along with gibberellic acid. Hydrolysis of the succinate block of the metabolities provides the 7β, 19-diol and 6β,7β, 19-triol. Of this pair only the former was effectively metabolized to gibberellic acid in G. fujikuroi.     

Microbial Baeyer-Villiger oxidation of steroidal ketones using Beauveria bassiana: Presence of an 11α-hydroxyl group essential to generation of D-homo lactones

This paper demonstrates for the first time transformation of a series of 17-oxo steroidal substrates (epiandrosterone, dehydroepiandrosterone, androstenedione) by the most frequently used whole cell biocatalyst, Beauveria bassiana, to 11α-hydroxy-17a-oxa-d-homo-androst-17-one products, in the following sequence of reactions: 11α-hydroxylation and subsequent Baeyer-Villiger oxidation to a ring-D lactone. 11α-Hydroxyprogesterone, the product of the first stage of the progesterone metabolism, was further converted along two routes: hydroxylation to 6β,11α-dihydroxyprogesterone or 17β-acetyl chain degradation leading to 11α-hydroxytestosterone, the main metabolite of the substrate. Part of 11α-hydroxytestosterone underwent a rare reduction to 11α-hydroxy-5β-dihydrotestosterone. The experiments have demonstrated that the Baeyer-Villiger monooxygenase produced by the strain catalyzes solely oxidation of C-20 or C-17 ketones with 11α-hydroxyl group. 17-Oxo steroids, beside the 11α-hydroxylation and Baeyer-Villiger oxidation, also underwent reduction to 17β-alcohols; activity of 17β-hydroxysteroid dehydrogenase (17β-HSD) has significant impact on the amount of the formed ring-D δ-lactone.     

Enhancement of microbial hydroxylation of 13-ethyl-gon-4-ene-3,17-dione by Metarhizium anisopliae using nano-liposome technique

The introduction of 11α-hydroxy to 13-ethyl-gon-4-ene-3,17-dione (GD) by microbial transformation is a key step in the synthesis of oral contraceptive desogestrel, while low substrate solubility and uptake into cells are tough problems influencing biotransformation efficiency greatly. Nano-liposome technique was used in the hydroxylation of GD by Metarhizium anisopliae. The substrate GD was processed to be GD-loaded nano-liposomes (GNLs) with high stability and encapsulation efficiency, and then applied in microbial hydroxylation by M. anisopliae. The results proved that the yield of the main product 11α-hydroxy-13-ethyl-gon-4-ene-3,17-dione (HGD) tripled compared to regular solvent dimethylformamide dispersion method at 2 g/l of substrate feeding concentration, and the HGD conversion rate showed no obvious reduction when the substrate feeding concentration increased from 2 to 6 g/l, which indicated the improvement of GNL addition method on biotransformation. Furthermore, the main byproduct changed from 6β-hydroxy derivative of GD (with similar polarity to HGD) to 6β,11α-dihydroxy derivative, which benefits the following purification of HGD from fermentation broth. These advantages suggest a great potential for the application of nano-liposome technique in microbial steroid transformation.     

Microbiological hydroxylation of androst-1,4-dien-3,17-dione by Neurospora crassa

Nine hydroxy-derived androstadiene compounds were isolated from the fermentation broth of Neurospora crassa when incubated in the presence of androst-1,4-dien-3,17-dione (ADD; I) for 7 days. Hydroxylations at 6β, 7β, 11α, 14α- positions and 17-carbonyl reduction of the substrate were the characteristics observed in this biotransformation. Their structures were determined by spectroscopic methods as 17β-hydroxyandrost-1,4-dien-3-one (II), 14α-hydroxyandrost-1,4-dien-3,17-dione (III), 6β-hydroxyandrost-1,4-dien-3,17-dione (IV), 11α-hydroxyandrost-1,4-dien-3,17-dione (V), 6β,17β-dihydroxyandrost-1,4-dien-3-one (VI), 7β-hydroxyandrost-1,4-dien-3,17-dione (VII), 14α,17β-dihydroxyandrost-1,4-dien-3-one (VIII), 6β,14α-dihydroxyandrost-1,4-dien-3,17-dione (IX), and 11α,17β-dihydroxyandrost-1,4-dien-3-one (X). A new steroid substance, 6β,14α-dihydroxyandrost-1,4-dien-3,17-dione (IX), was also characterized during this study. The best fermentation condition was found to be 7-day incubation at 25°C and pH values of 5.0–6.0 in the presence of 0.05 g 100 mL^?1 of the substrate. At a concentration above 0.075 g 100 mL^?1, the biotransformation was completely inhibited.     

Concerning the biosynthesis of prostaglandin I2

Two diastereoisomers, 5R,6R-5-hydroxy-6(9α)-oxido-11α,15S-dihydroxyprost-13-enoic acid (7) and 5S,6S-5-hydroxy-6(9α)-oxido-11α,15S-dihydroxyprost-13-enoic acid (10) were synthesized for evaluation as possible biosynthetic intermediates in the enzymatic transformation of PGH₂ or PGG₂ into PGI₂. The synthetic sequence entails the stereospecific reduction of the 9-keto function in PGE₂ methyl ester after protecting the C-11 and C-15 hydroxyls as tbutyldimethylsilyl ethers. The resulting PGF_2α derivative was epoxidized exclusively at the C-5 (6) double bond to yield a mixture of epoxides, which underwent facile rearrangement with SiO₂ to yield the 5S,6S and 5R,6R-5-hydroxy-6(9α)-oxido cyclic ethers. It was found that dog aortic microsomes were unable to transform radioactive 9β-5S,6S[³H] or 9β-5R,6R[³H]-5-hydroxy-6(9α)-oxido cyclic ethers into PGI₂. Also, when either diastereoisomer was included in the incubation mixture, neither isomer diluted the conversion of [1-¹⁴C]arachidonic acid into [1-¹⁴C]PGI₂.     

Interactions between thrombin and natural products of Millettia nitita var. hirsutissima using capillary zone electrophoresis

A sensitive and selective high-performance analytical method based on capillary zone electrophoresis (CZE) was developed for investigating interactions between natural products isolated from Millettia nitita var. hirsutissima and thrombin qualitatively and quantitatively for the first time. The results showed that, compared with positive and negative control, the compounds ZYY-5 (genistein-8-C-β-d-apiofuranosyl-(1→6)-O-β-d-glucopyranoside), ZYY-6 (calycosin), ZYY-8 (isoliquiritigenin), ZYY-9 (formononetin), ZYY-12 (gliricidin), ZYY-13 (8-O-methylretusin), FJ-2 (dihydrokaempferol), FJ-3 (biochanin), FJ-5 (afromosin) and XC-2 (hirsutissimiside F) interacted with thrombin, while ZYY-1 (sphaerobioside), ZYY-2 (formononetin-7-O-β-d-apiofuranosyl-(1→6)-O-β-d-glucopyranoside), ZYY-3 (genistein-5-methylether-7-O-α-l-rhamnopyranosyl-(1→6)-O-β-d-glucopyranoside), ZYY-4 (retusin-7,8-O-β-d-diglucopyranoside), ZYY-7 (symplocoside), ZYY-10 (ononin), ZYY-11 (genistin), ZYY-14 (afromosin-7-O-β-d-glucopyranoside), ZYY-15 (lanceolarin), FJ-1 (liquiritigenin), FJ-4 (7,2-dihydroxy,4-methoxyisoflavan) and XC-1 (sphaerobioside) had no binding to thrombin. This indicated that the reported CZE method for the determination of compound–thrombin interactions is powerful, sensitive and fast, and requires less amounts of reagents, and further, it can be employed as a reliable alternative to other methods.     

Bioconversion of C19- and C21-steroids with parent and mutant strains of Curvularia lunata

Regio- and stereospecificity of microbial hydroxylation was studied at the transformation of 3-keto-4-ene steroids of androstane and pregnane series by the filamentous fungus of Curvularia lunata VKM F-644. The products of the transformations were isolated by column chromatography and identified using HPLC, massspectrometry (MS) and proton nuclear magnetic resonance (¹H NMR) analyses. Androst-4-ene-3,17-dione (AD) and its 1(2)-dehydro- and 9α-hydroxylated (9-OH-AD) derivatives were hydroxylated by the fungus mainly in position 14α, while 6α-, 6β- and 7α-hydroxylated products were revealed in minor amounts. At the transformation of C₂₁-steroids (cortexolone and its acetylated derivatives) the presence of 17-acetyl group was shown to facilitate further selectivity of 11β-hydroxylation. Original procedures for protoplasts obtaining, mutagenesis and mutant strain selection have been developed. A stable mutant (M4) of C. lunata with high 11β-hydroxylase activity towards 21-acetate and 17α,21-diacetate of cortexolone was obtained. Yield of 11β-hydroxylated products reached about 90% at the transformation of 17α, 21-diacetate of cortexolone (1 g/l) using mutant strain M4.     

Profiling of urinary steroids by gas chromatography-mass spectrometry detection and confirmation of androstenedione administration using isotope ratio mass spectrometry

Androstenedione (4-androstene-3,17-dione) is banned by the World Anti-Doping Agency (WADA) as an endogenous steroid. The official method to confirm androstenedione abuse is isotope ratio mass spectrometry (IRMS). According to the guidance published by WADA, atypical steroid profiles are required to trigger IRMS analysis. However, in some situations, steroid profile parameters are not effective enough to suspect the misuse of endogenous steroids. The aim of this study was to investigate the atypical steroid profile induced by androstenedione administration and the detection of androstenedione doping using IRMS. Ingestion of androstenedione resulted in changes in urinary steroid profile, including increased concentrations of androsterone (An), etiocholanolone (Etio), 5α-androstane-3α,17β-diol (5α-diol), and 5β-androstane-3α,17β-diol (5β-diol) in all of the subjects. Nevertheless, the testosterone/epitestosterone (T/E) ratio was elevated only in some of the subjects. The rapid increases in the concentrations of An and Etio, as well as in T/E ratio for some subjects could provide indicators for initiating IRMS analysis only for a short time period, 2-22 h post-administration. However, IRMS could provide positive determinations for up to 55 h post-administration. This study demonstrated that, 5β-diol concentration or Etio/An ratio could be utilized as useful indicators for initiating IRMS analysis during 2-36 h post-administration. Lastly, Etio, with slower clearance, could be more effectively used than An for the confirmation of androstenedione doping using IRMS.     

Sesquiterpene lactones from Artemisia maritima

Two new sesquiterpene lactones have been isolated from Artemisia maritima and the structures have been assigned on the basis of their spectral properties as 1-oxo-6β,7α,11βH,14β-methylgermacra-4(5)-ene-12,6-olide and 1-oxo-6β,7α,11βH-germacra-4(5),10(14)-dien-12,6-olide.