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.     

Biotransformation of the diterpene 15β-hydroxy-18(4→3)-abeo-ent-kaur-4(19),16-diene by the fungus Fusarium fujikuroi

15β-Hydroxy-18(4→3)-abeo-ent-kaur-4(19),16-diene (4) was biotransformed by the fungus Fusarium fujikuroi into 3α,11β,15β-trihydroxy-18(4→3)-abeo-ent-kaur-4(19),16-diene (5). The hydroxylation at C-3(α) in this diterpene reminds a similar reaction that occurs at C-13 in the biosynthesis of gibberellic acid in this fungus. The presence of the 15β-alcohol in the substrate directs the second hydroxylation at C-11(β), which had been observed in the incubation of ent-kaur-16-ene derivatives with this fungus when the C-19 hydroxylation was inhibited by the existence in the molecule of a 3α-OH or 3-oxo group. We also show that the angelate of the substrate is an undescribed natural product now identified as a component of the plant Distichoselinum tenuifolium.     

Biotransformation of 5-en-3β-ol steroids by Mucor circinelloides lusitanicus

In this work, we report the mode of biotransformation of 5-en-3β-ol steroids using Mucor circinelloides lusitanicus for the first time. Here, we selected seven 5-en-3β-ol steroids as substrates. The main characteristic of the fungus was to introduce a 7α-hydroxyl group into substrates 1--5. With substrate 2, 3β, 7α, 11α-trihydroxypregna-5-en-20-one (2b) was obtained as the final product in good yield (46.4%). All the metabolites were determined by infrared spectra, high-resolution mass spectrometry, proton nuclear magnetic resonance, and carbon-13 nuclear magnetic resonance.     

Tagitinin C induces ferroptosis through PERK-Nrf2-HO-1 signaling pathway in colorectal cancer cells

Rationale: Colorectal cancer (CRC) is a common malignant tumor of the digestive system. However, the efficacy of surgery and chemotherapy is limited. Ferroptosis is an iron- and reactive oxygen species (ROS)-dependent form of regulated cell death (RCD) and plays a vital role in tumor suppression. Ferroptosis inducing agents have been studied extensively as a novel promising way to fight against therapy resistant cancers. The aim of this study is to investigate the mechanism of action of tagitinin C (TC), a natural product, as a novel ferroptosis inducer in tumor suppression.Methods: The response of CRC cells to tagitinin C was assessed by cell viability assay, clonogenic assay, transwell migration assay, cell cycle assay and apoptosis assay. Molecular approaches including Western blot, RNA sequencing, quantitative real-time PCR and immunofluorescence were employed as well.Results: Tagitinin C, a sesquiterpene lactone isolated from Tithonia diversifolia, inhibits the growth of colorectal cancer cells including HCT116 cells, and induced an oxidative cellular microenvironment resulting in ferroptosis of HCT116 cells. Tagitinin C-induced ferroptosis was accompanied with the attenuation of glutathione (GSH) levels and increased in lipid peroxidation. Mechanistically, tagitinin C induced endoplasmic reticulum (ER) stress and oxidative stress, thus activating nuclear translocation of nuclear factor erythroid 2-related factor 2 (Nrf2). As a downstream gene (effector) of Nrf2, heme oxygenase-1 (HO-1) expression increased significantly with the treatment of tagitinin C. Upregulated HO-1 led to the increase in the labile iron pool, which promoted lipid peroxidation, meanwhile tagitinin C showed synergistic anti-tumor effect together with erastin.Conclusion: In summary, we provided the evidence that tagitinin C induces ferroptosis in colorectal cancer cells and has synergistic effect together with erastin. Mechanistically, tagitinin C induces ferroptosis through ER stress-mediated activation of PERK-Nrf2-HO-1 signaling pathway. Tagitinin C, identified as a novel ferroptosis inducer, may be effective chemosensitizer that can expand the efficacy and range of chemotherapeutic agents.     

Steroid derivatives

The dependence of the course of hydroxylation of steroid compounds substituted differently in positions 16 and 17 was studied, using several economically important 11α-hydroxylating microorganisms. All the steroid substrates used yielded the 11α-hydroxy-derivative as the main product, with the exception of 16β-methyl-16α, 17-oxidoprogesterone, during the biotransformation of which the formation of the 11α-hydroxy-derivative was accompanied by appreciable amount of its 7β,11α-dihydroxyderivative. In the transformation achieved byBeauveria bassiana, the last-named dihydroxy-compound was formed as the main product, whereas the biotransformation carried out with the aid ofBeauveria globulifera yielded the 5-saturated analogue of 7β,11α-dihydroxy-methylepoxyprogesterone as the main product.     

Optimization of factors influencing enzyme activity and product selectivity and the role of proton transfer in the catalytic mechanism of patchoulol synthase

The patchoulol synthase (PTS) from Pogostemon cablin is a versatile sesquiterpene synthase and produces more than 20 valuable sesquiterpenes by conversion of the natural substrate farnesyl pyrophosphate (FPP). PTS has the potential to be used as a biocatalyst for the production of valuable sesquiterpenes such as (−)-patchoulol. The objective of the present study is to develop an efficient biotransformation and to characterize the biocatalytic mechanism of the PTS in detail. For this purpose, soluble PTS was prepared using an optimized cultivation protocol and continuous downstream process with a purity of 98%. The PTS biotransformation was then optimized regarding buffer composition, pH-value, and temperature for biotransformation as well as functional and kinetic properties to improve productivity. For the bioconversion of FPP, the highest enzyme activity was reached with the 2-(N-morphlino)ethanesulfonic acid (MES) buffer containing 10% (v/v) glycerol and 10 mM MgCl₂ at pH 6.4 and 34°C. The PTS showed an unusual substrate inhibition for sesquiterpene synthases indicating an intermediate sesquiterpene formed in the active center. Deuteration experiments were used to gain further insights into the biocatalytic mechanism described in literature. Thus it could be shown that a second substrate binding site must be responsible for substrate inhibition and that further protonation and deprotonation steps are involved in the reaction mechanism.     

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.     

Neue sesquiterpene aus Liabum-arten

The reinvestigation of the roots of Liabum eggersii afforded, in addition to compounds reported before, several sesquiterpene hydrocarbons with unusual carbon skeletons and the first derivative of the propellane modhephene which itself is also present. The roots of L. floribundum contain a tricyclic sesquiterpene with three five-membered rings. This ketone most probably is a derivative of the sesquiterpene silphiperfolene. The structures of the new compounds were elucidated by extensive NMR studies and by some chemical transformations. Two further species only afforded known compounds. The chemotaxonomic situation is discussed briefly.     

Microbial hydroxylation of 2-oxatestosterone

An investigation has been undertaken of the microbial biotransformation of 2-oxatestosterone by microorganisms known to hydroxylate conventional steroids, using Aspergillus ochraceus, Bacillus megaterium, Curvularia lunata and Rhizopus arrhizus. A. ochraceus and B. megaterium gave products of 11α- and 15β-hydroxylation, respectively. Biotransformation by C. lunata gave C-11β- and C-14α-hydroxylated products, whereas R. arrhizus produced only the 6β-hydroxy derivative.     

Sesquiterpene lactones of Podanthus mitiqui

Ovatifolin and two new sesquiterpene lactones, deacetylovatifolin and arturin (1β-hydroxy-8β-angeloyloxy-eudesmane-4(15),11(13)-diene-6α,12-olide, have been isolated from stems and leaves of Podanthus mitiqui. Two of these compounds showed cytotoxic activity.     

Identification of drostanolone and 17-methyldrostanolone metabolites produced by cryopreserved human hepatocytes

Methyldrostanolone (2α,17α-dimethyl-17β-hydroxy-5α-androstan-3-one) was synthesized from drostanolone (17β-hydroxy-2α-methyl-5α-androstan-3-one) and identified in commercial products. Cultures of cryopreserved human hepatocytes were used to study the biotransformation of drostanolone and its 17-methylated derivative. For both steroids, the common 3α- (major) and 3β-reduced metabolites were identified by GC-MS analysis of the extracted culture medium and the stereochemistry confirmed by incubation with 3α-hydroxysteroid dehydrogenase. Structures corresponding to hydroxylated metabolites in C-12 (minor) and C-16 were proposed for other metabolites based upon the evaluation of the mass spectra of the pertrimethylsilyl (TMS-d₀ and TMS-d₉) derivatives. Finally, on the basis of the GC-MS and ¹H NMR data and through chemical synthesis of the 17-methylated model compounds, structures could be proposed for metabolites hydroxylated in C-2. All the metabolites extracted from hepatocyte culture medium were present although in different relative amounts in urines collected following the administration to a human volunteer, therefore confirming the suitability of the cryopreserved hepatocytes to generate characteristic metabolites and study biotransformation of new steroids.     

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.     

Leptocarpin and 17,18-dihydroleptocarpin,two new heliangolides from Leptocarpha rivularis

The isolation and structure determination of two new sesquiterpene lactones of the heliangolide type, leptocarpin and 17,18-dihydroleptocarpin from Leptocarpha rivularis, are described. The structure of leptocarpin was established as the 8β-angeloyl ester of 3β,8β-dihydroxy germacra-4,11(13)-dien- 1(10)-oxido-6α,12-olide. The second component was the 17,18-dihydro derivative of leptocarpin.     

Hydroxylation of DHEA and its analogues by Absidia coerulea AM93. Can an inducible microbial hydroxylase catalyze 7α- and 7β-hydroxylation of 5-ene and 5α-dihydro C19-steroids?

In this paper we focus on the course of 7-hydroxylation of DHEA, androstenediol, epiandrosterone, and 5α-androstan-3,17-dione by Absidia coerulea AM93. Apart from that, we present a tentative analysis of the hydroxylation of steroids in A. coerulea AM93. DHEA and androstenediol were transformed to the mixture of allyl 7-hydroxy derivatives, while EpiA and 5α-androstan-3,17-dione were converted mainly to 7α- and 7β-alcohols accompanied by 9α- and 11α-hydroxy derivatives. On the basis of (i) time course analysis of hydroxylation of the abovementioned substrates, (ii) biotransformation with resting cells at different pH, (iii) enzyme inhibition analysis together with (iv) geometrical relationship between the C–H bond of the substrate undergoing hydroxylation and the cofactor-bound activated oxygen atom, it is postulated that the same enzyme can catalyze the oxidation of C₇-H_α as well as C₇-H_β bonds in 5-ene and 5α-dihydro C₁₉-steroids. Correlations observed between the structure of the substrate and the regioselectivity of hydroxylation suggest that 7β-hydroxylation may occur in the normal binding enzyme-substrate complex, while 7α-hydroxylation—in the reverse inverted binding complex.     

Microbiological transformation of diosgenin by resting cells of filamentous fungus,Cunninghamella echinulata CGMCC 3.2716

Microbial transformation of the steroidal sapogenin diosgenin (1) by resting cells of the filamentous fungus, Cunninghamella echinulata CGMCC 3.2716 was studied. Four metabolites were isolated and unambiguously characterized as (25R)-spirost-5-ene-3β,7β-diol-11-one (2), (25R)-spirost-5-ene-3β,7β-diol (3), (25R)-spirost-5-ene-3β,7β,11α-triol (4), and (25R)-spirost-5-ene-3β,7β,12β-triol (5), by various spectroscopic methods (¹H, ¹³C NMR, DEPT, ¹H–¹H COSY, HMBC, HSQC and NOESY). Compound 2 is a new metabolite. The NMR data and full assignment for the known metabolites (25R)-spirost-5-ene-3β,7β-diol (3) and (25R)-spirost-5-ene-3β,7β,11α-triol (4) are described here for the first time. The biotransformation characteristics observed included were C-7β, C-11α and C-12β hydroxylations. Compounds 1–5 exhibited no significant cytotoxic activity to human glioma cell line U87.     

Two guaiane-type sesquiterpene lactones and their related sesquiterpene lactones from Porella japonica

Two new guaiane-type sesquiterpene dilactones, porelladiolide and 3α,4α-epoxyporelladiolide and a new germacranolide, 3β-hydroxycostunolide, together with the previously known germacranolides, guaianolides, pinguisane-type sesquiterpenes, and a sacculatane-type diterpene dialdehyde have been isolated from the liverwort, Porella japonica and their structures have been established by the spectral evidence and some chemical transformations. Porelladiolide, 3α,4α-epoxyporelladiolide and the sesquiterpene with α-methylene γ-lactone group showed inhibitory activity toward the germination and growth of roots of rice in the husk.     

Biotransformation of ent-kaur-16-ene and ent-trachylobane 7β-acetoxy derivatives by the fungus Gibberella fujikuroi (Fusarium fujikuroi)

Candol A (7β-hydroxy-ent-kaur-16-ene) (6) is efficiently transformed by Gibberella fujikuroi into the gibberellin plant hormones. In this work, the biotransformation of its acetate by this fungus has led to the formation of 7β-acetoxy-ent-kaur-16-en-19-oic acid (3), whose corresponding alcohol is a short-lived intermediate in the biosynthesis of gibberellins and seco-ring ent-kaurenoids in this fungus. Further biotransformation of this compound led to the hydroxylation of the 3β-positions to give 7β-acetoxy-3β-hydroxy-ent-kaur-16-en-19-oic acid (14), followed by a 2β- or 18-hydroxylation of this metabolite. The incubation of epicandicandiol 7β-monoacetate (7β-acetoxy-18-hydroxy-ent-kaur-16-ene) (10) produces also the 19-hydroxylation to form the 18,19 diol (20), which is oxidized to give the corresponding C-18 or C-19 acids. These results indicated that the presence of a 7β-acetoxy group does not inhibit the fungal oxidation of C-19 in 7β-acetoxy-ent-kaur-16-ene, but avoids the ring B contraction that leads to the gibberellins and the 6β-hydroxylation necessary for the formation of seco-ring B ent-kaurenoids. The biotransformation of 7β-acetoxy-ent-trachylobane (trachinol acetate) (27) only led to the formation of 7β-acetoxy-18-hydroxy-ent-trachylobane (33).     

Side-chain cleavage and C-20 ketone reduction of hydrocortisone by a natural isolate ofChroococcus dispersus

A unicellular cyanobacterium,Chroococcus dispersus (Keissl.) Lemmermann, was isolated from paddy-field and tested in biotransformation experiments of hydrocortisone (compound 1). This strain has not been previously examined for steroid substance modification. Fermentation was carried out in BG-11 medium supplemented with 0.05% substrate at 25 °C for seven days incubation. The metabolites were chromatographically purified and characterised using spectroscopic methods. The fermentation yielded 11β,17α,20β,21-tetrahydroxypregn-4-en-3-one (compound 2), 11β,17β-dihydroxyandrost-4-en-3,17-dione (compound 3), and 11β-hydroxyandrost-4-en-3,17-dione (compound 4). Bioreaction characteristics observed were 20-ketone reduction for accumulation of compound 2 and side chain degradation of the substrate to give compounds 3 and 4. Time course study showed the accumulation of the product 2 from the second day of the fermentation and product 3 as well as product 4 from the third day. All the metabolites reached their maximum concentration in seven days. Aeration and continuous light or light duration (16/8 hours light/dark) have no effect on the transformation yield. Optimum concentration of the substrate, which gave maximum bioconversion efficiency, was 0.5 mg ml^?1 in the transformation experiment. Growth was not influenced by the addition of steroid substrate. Biotransformation was completely inhibited when steroid concentration was above 2.0 mg ml^?1.     

Terpenes and steroids from leaves of Oxandra sessiliflora R. E. Fries

The EtOH extract from the leaves of Oxandra sessiliflora R. E. Fries (Annonaceae) was partitioned using hexane and CH₂Cl₂. After several chromatographic steps, caryophyllene oxide and spathulenol were isolated from hexane phase while, from CH₂Cl₂ phase, we isolated (E)-phytol, spathulenol, 4β,10α-dihydroxyaromadendrane, 1β,6α-dihydroxyeudesm-4(15)-ene, and 4α,7β,10α-trihydroxyguai-5-ene, the latter being a new sesquiterpene derivative. Additionally, a mixture of steroids (campesterol, sitosterol, and stigmasterol) was obtained from the CH₂Cl₂ phase. The isolated compounds were characterized by mass spectrometry and analysis of their ¹H and ¹³C NMR spectroscopic data, including bidimensional analysis.     

Selective 4′-O-methylglycosylation of the pentahydroxy-flavonoid quercetin by Beauveria bassiana ATCC 7159

Biotransformation of the pentahydroxy-flavonoid natural product, quercetin, by Beauveria bassiana ATCC 7159 afforded a new derivative, quercetin-4'-O-methyl-7-O-β-D-glucopyranoside, in 87% isolated yield suggesting that glucosylation of the substrate occurred with high selectivity at C–7-OH out of the five hydroxyl groups. Most of the product was isolated from the mycelium and the filtrate of the culture medium did not show any catalytic activity. The mycelium is capable of performing this biotransformation when suspended in buffers of pH 2.1 and 7.2, suggesting that intracellular enzymes are involved and that they are active at a wide range of extracellular pH.