Differential metabolism of diastereoisomeric diterpenes by Preussia minima,found as endophytic fungus in Cupressus lusitanica

The plant diastereoisomeric diterpenes ent-pimara-8(14)-15-dien-19-oic acid, obtained from Viguiera arenaria, and isopimara-8(14)-15-dien-18-oic acid, isolated from Cupressus lusitanica, were distinctly functionalized by the enzymes produced in whole cell cultures of the fungus Preussia minima, isolated from surface sterilized stems of C. lusitanica. The ent-pimaradienoic acid was transformed into the known 7β-hydroxy-ent-pimara-8(14)-15-dien-19-oic acid, and into the novel diterpenes 7-oxo-8 β-hydroxy-ent-pimara-8(14)-15-dien-19-oic and 7-oxo-9β-hydroxy-ent-pimara-8(14)-15-dien-19-oic acids. Isopimara-8(14)-15-dien-18-oic acid was converted into novel diterpenes 11α-hydroxyisopimara-8(14)-15-dien-18-oic acid, 7β,11α-dihydroxyisopimara-8(14)-15-dien-18-oic acid, and 1β,11α-dihydroxyisopimara-8(14)-15-dien-18-oic acid, along with the known 7β-hydroxyisopimara-8(14)-15-dien-18-oic acid. All compounds were isolated and fully characterized by 1D and 2D NMR, especially ¹³C NMR. The diterpene bioproduct 7-oxo-9β-hydroxy-ent-pimara-8(14)-15-dien-19-oic acid is an isomer of sphaeropsidin C, a phytotoxin that affects cypress trees produced by Shaeropsis sapinea, one of the main phytopathogen of Cupressus. The differential metabolism of the diterpene isomers used as substrates for biotransformation was interpreted with the help of computational molecular docking calculations, considering as target enzymes those of cytochrome P450 group.     

Polyoxygenated ent-kauranes and water-soluble conjugates in seed of Phaseolus coccineus

C-α and C-β, previously isolated from seed of Phaseolus coccineus, are shown respectively to be the bis-O-isopropylidene and the 16,17-mono-O-isopropylidene derivatives of ent-6α,7α,16β,17-tetrahydroxykauranoic acid. By GC-MS characterization of the products of acidic, basic and enzymatic hydrolysis, water soluble conjugates of the following compounds have been shown to occur in P. coccineus seed: GA₈, GA₁₇, GA₂₀, GA₂₈, ent-6α,7α,13-trihydroxykaurenoic acid, ent-6α,7α,17-trihydroxy-16β-kauranoic acid, ent-6α,7α,16β,17-tetrahydroxykauranoic acid, 7β,13-dihydroxykaurenolide and abscisic acid.     

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.     

The microbiological transformation of some trachylobane diterpenoids by Gibberella fujikuroi

The microbiological transformation of ent-trachylobane, ent-7α-hydroxytrachylobane and ent-19-hydroxytrachylobane into trachylobagibberellins A₇, A₉, A₁₃, A₂₅, A₄₀ and A₄₇ by Gibberella fujikuroi is described. Whereas 7β-hydroxy- and 7β,18-dihydroxytrachylobanolides were obtained from ent-trachylobane and ent-trachyloban- 19-ol, the presence of a 7β-hydroxyl group directed metabolism exclusively into the gibberellin pathway. An 18-hydroxyl group as in ent-7α,18-dihydroxytrachylobane inhibited oxidation at C-6 affording ent-7α,18,19-trihydroxytrachylobane as the major metabolite.     

Carbon-13 nmr spectra of some ent-rosane diterpenoids

The ¹³C NMR signals of the parent hydrocarbon ent-rosa-5,15-diene (ent-(8,5-friedo-pimara-5,15-diene)and some of their oxygenated derivatives have been assigned.     

The microbiological transformation of some ent-beyerene diterpenoids by Gibberella fujikuroi to beyergibberellins and beyerenolides

The microbiological transformation by Gibberelia fujikuroi of ent-beyer-15-ene into the beyergibberellins A₉ and A₁₃, 7β-hydroxy- and 7β,18-dihydroxybeyerenolides, and of ent-beyer-15-en-19-ol into beyergibberellins A₄, A₇, A₉, A₁₃ and A₂₅,and 7β-hydroxy-and 7β,18-dihydroxybeyerenolides is described. In contrast, ent-beyer-15-en-18-ol gave _ent-7α, 18,19-trihydroxybeyer-15-ene, 7β,18-dihydroxybeyerenolide and _ent-7α,18-dihydroxybeyer-15-en-19-oic acid again revealing the inhibitory effect of an 18-hydroxyl group on oxidative transformations at C-6β by Gibberella fujikuroi.     

Biotransformation of ent-pimaradienoic acid by cell cultures of Aspergillus niger

Microbial transformation stands out among the many possible semi-synthetic strategies employed to increase the variety of chemical structures that can be applied in the search for novel bioactive compounds. In this paper we obtained ent-pimaradienoic acid (1, PA, ent-pimara-8(14),15-dien-19-oic acid) derivatives by fungal biotransformation using Aspergillus niger strains. To assess the ability of such compounds to inhibit vascular smooth muscle contraction, we also investigated their spasmolytic effect, along with another five PA derivatives previously obtained in our laboratory, on aortic rings isolated from male Wistar rats. The microbial transformation experiments were conducted at 30 °C using submerged shaken liquid culture (120 rpm) for 10 days. One known compound, 7α-hydroxy ent-pimara-8(14),15-dien-19-oic acid (2), and three new derivatives, 1β-hydroxy ent-pimara-6,8(14),15-trien-19-oic acid (3), 1α,6β,14β-trihydroxy ent-pimara-7,15-dien-19-oic acid (4), and 1α,6β,7α,11α-tetrahydroxy ent-pimara-8(14),15-dien-19-oic acid (5), were isolated and identified on the basis of spectroscopic analyses and computational studies. The compounds obtained through biotransformation (2–5) did not display a significant antispasmodic activity (values ranging from 0% to 16.8% of inhibition); however the previously obtained diterpene, methyl 7α-hydroxy ent-pimara-8(14),15-dien-19-oate (8), showed to be very effective (82.5% of inhibition). In addition, our biological results highlight the importance to study the antispasmodic potential of a large number of novel diterpenes, to conduct further structure–activity relationship investigations.     

Zierane sesquiterpene lactone,cembrane and fusicoccane diterpenoids,from the Tahitian liverwort Chandonanthus hirtellus

Cembrane-type diterpenoids, 13,18,20-epi-iso-chandonanthone (1) and (8E)-4α-acetoxy-12α,13α-epoxycembra-1(15),8-diene (2), two fusicoccane-type diterpenoids, fusicoauritone 6α-methyl ether (3) and 6β,10β-epoxy-5β-hydroxyfusicocc-2-ene (4) and a zierane sesquiterpene γ-lactone, chandolide (5) were isolated from the Tahitian liverwort Chandonanthus hirtellus (Web.) Mitt., together with eight known diterpenoids, chandonanthine (6), fusicogigantone A (7), fusicogigantone B (8), fusicogigantepoxide (9), anadensin (10), fusicoauritone (11), ent-verticillol (12) and ent-epi-verticillol (13). Their structures were established by a combination of extensive NMR spectroscopy and/or X-ray crystallographic analyses. Compounds 1, 5 and 10 showed weak cytotoxic activity against HL-60. Compound 3 also indicated weak cytotoxic activity against KB cell lines.     

Synthesis and biological evaluation of tubulysin D analogs related to stereoisomers of tubuvaline

The synthesis and biological evaluation of stereoisomers in tubulysin D are described. The stereoselective synthesis of all possible stereoisomers of C-11 and C-13 positions in tubulysin D was achieved by employing 1′-epi-Tuv-Me, 3′-epi-Tuv-Me, and ent-Tuv-Me and their biological properties were evaluated. It is clear that the stereochemistries of the C-11 and C-13 positions in tubulysin D have no practical impact on the inhibition of tubulin polymerization but play a role in the potent antiproliferative activities.     

Heteroannelated and 7-deoxygenated goniofufurone mimics with antitumour activity: Design,synthesis and preliminary SAR studies

Cytotoxic (+)-goniofufurone mimic such as benzoxepane 2 was preferentially formed after the treatment of 7-O-benzoyl-5-O-benzyl (+)-goniofufurone derivative 6 with titanium(IV) fluoride. However, the corresponding 7-epimer 5 (derivative of 7-epi-goniofufurone) under the similar reaction conditions gave mainly 7-deoxy derivative 7 as a result of an unexpected 1,5-hydride shift. Extension of this methodology to the enantiomer ent-6 provided cytotoxic (?)-goniofufurone mimics ent-2 and ent-7. Synthesized compounds showed diverse growth inhibitory effects against selected tumour cell lines, but were devoid of any significant toxicity towards the normal foetal lung fibroblasts (MRC-5). A SAR study reveals the structural features of these lactones that are beneficial for their antiproliferative activity, such as presence of an additional oxepane ring, the absolute stereochemistry and the presence of a deoxy function at the C-7 position.     

Phaeoside,a Novel Galactoside of Hydroxymanoyl Oxide from the Gibberellin A1-Producing Phaeosphaeria sp. L487

Isolation and examination of a diterpene glycoside from the culture filtrate of the gibberellin A₁-producing Phaeosphaeria sp. L487 allowed us to identify a novel fungal galactoside of hydroxymanoyl oxide together with (?)-ent-13-epi-manoyl oxide. It was designated phaeoside and determined to be 1α-hydroxy-ent-13-epi-manoyl oxide 1-O-β-D-galactopyranoside based on its chemical degradation and spectroscopic methods. This is the first report of the isolation of a diterpene galactoside from fungi.     

Biotransformation of 7α-hydroxy- and 7-oxo-ent-atis-16-ene derivatives by the fungus Gibberella fujikuroi

The microbiological transformation of 7α,19-dihydroxy-ent-atis-16-ene by the fungus Gibberella fujikuroi gave 19-hydroxy-7-oxo-ent-atis-16-ene, 13(R),19-dihydroxy-7-oxo-ent-atis-16-ene, 7α,11β,19-trihydroxy-ent-atis-16-ene and 7α,16β,19-trihydroxy-ent-atis-16-ene, while the incubation of 19-hydroxy-7-oxo-ent-atis-16-ene afforded 13(R),19-dihydroxy-7-oxo-ent-atis-16-ene and 16β,17-dihydroxy-7-oxo-ent-atisan-19-al. The biotransformation of 7-oxo-ent-atis-16-en-19-oic acid gave 6β-hydroxy-7-oxo-ent-atis-16-en-19-oic acid, 6β,16β,17-trihydroxy-7-oxo-19-nor-ent-atis-4(18)-ene and 3β,7α-dihydroxy-6-oxo-ent-atis-16-en-19-oic acid.     

Side chain functionalization of cholesterol in the biosynthesis of solasodine in Solanum laciniatum

(25R)-26-Amino-cholesterol-[7α-³H], (25R)-26-amino-5-cholestene-3β,16β-diol-[7α-³H] and (25R)-26-acetylamino-5-cholestene-3β,16β-diol-[7α-³H] administered to Solanum laciniatum were converted into solasodine. The results indicate that in the biosynthesis of solasodine the introduction of nitrogen occurs immediately after the hydroxylation at C-26 and before a further oxidation of the side chain of cholesterol. The next step after the amination at C-26 is not hydroxylation at the 16β-position but probably the functionalization of C-22.     

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).     

Diterpenoids of Halimium viscosum

From the neutral fraction of the hexane extract of Halimium viscosum the following components were isolated; 7-labdene-3β,l5-diol, 15-acetoxy-7-labden-3β-ol and a new diterpene-lactone with a rearranged ent-labdane skeleton, 13S-ent-9, 1-friedo-labd-1(10)-en-15-acetoxy-2R,18-olide. From the non-saponifiable part, beside 7-labdene-3β, 15-diol and 7, 13E-labdadiene-3β, 15-diol, the new diterpene 8(17)-labdene-3β, 7α, 15-triol was extracted. The structures were elucidated by spectroscopic methods, correlations or synthesis.     

Four new diterpenes from Sideritis serrata

Four new diterpenes have been isolated from Sideritis serata: lagascol (4, ent-8,5-friedopimar-5-ene-15S,16-diol), tobarrol (8, ent-15-beyerene-12α,17-diol), benuol (12, ent-15-beyerene-7α,17-diol) and serradiol (18, ent-16R-atis-13-ene-16,17-diol). The previously known diterpenes lagascatriol (1, ent-8,5-friedopimar-5-ene-11β,15S,16-triol), jativatriol (2, ent-15-beyerene-1β,12α,17-triol), conchitriol (3, ent-15-beyerene-7α,12α,17-triol) and sideritol (17, ent-16R-atis-13-ene-1β,16,17-triol) have also been obtained from the same source.     

Hydroxylation of steroids by Fusarium oxysporum, Exophiala jeanselmei and Ceratocystis paradoxa

The potential of Fusarium oxysporum var. cubense UAMH 9013 to perform steroid biotransformations was reinvestigated using single phase and pulse feed conditions. The following natural steroids served as substrates: dehydroepiandrosterone (1), pregnenolone (2), testosterone (3), progesterone (4), cortisone (5), prednisone (6), estrone (7) and sarsasapogenin (8). The results showed the possible presence of C-7 and C-15 hydroxylase enzymes. This hypothesis was explored using three synthetic androstanes: androstane-3,17-dione (9), androsta-4,6-diene-3,17-dione (10) and 3α,5α-cycloandrost-6-en-17-one (11). These fermentations of non-natural steroids showed that C-7 hydroxylation was as a result of that position being allylic. The evidence also pointed towards the presence of a C-15 hydroxylase enzyme.The eleven steroids were also fed to Exophialajeanselmei var. lecanii-corni UAMH 8783. The results showed that the fungus appears to have very active 5α and 14α-hydroxylase enzymes, and is also capable of carrying out allylic oxidations.Ceratocystis paradoxa UAMH 8784 was grown in the presence of the above-mentioned steroids. The results showed that monooxygenases which effect allylic hydroxylation and Baeyer–Villiger rearrangement were active. However, redox reactions predominated.     

GC/MS analysis of the plant hormones in seeds of Cucurbita maxima

The GC/MS detection is reported of over 30 compounds, in extracts of the endosperm and embryos from seeds of Cucurbita maxima. The compounds which were identified from reference spectra include: cis,trans-ABA; trans,trans-ABA; dihydrophaseic acid; IAA; GA₄; GA₁₂; GA₁₃; GA₂₅; GA₃₉; GA₄₃; GA₄₉; ent-13-hydroxy-, ent-6α,7α-and ent-7α,13-dihydroxy-, and ent-6α,7α,13-trihydroxykaur-16-en-19-oic acids; ent-7α,16,17-trihydroxy- and ent-6α,7α,16,17-tetrahydroxy-kauran-19-oic acids, ent-6,7-seco-7-oxokauren-6,19-dioic acid and/or ent-6,7-secokauren-6,7,19-trioic acid, and 7β,12α-dihydroxykaurenolide. New compounds, the structures of which were deduced from GC/MS data, include: the 12α-hydroxy-derivatives of GA₁₂, GA₁₄, GA₃₇ and GA₄, and the 12β-hydroxy-derivatives of ent-7α-hydroxy- and ent-6α,7α-dihydroxykaurenoic acids.     

The metabolism of steviol to 13-hydroxylated ent-Gibberellanes and ent-kauranes

Steviol(ent-13-hydroxykaur-16-en-19-oic acid) is rapidly metabolised by the mutant B1-41a of Gibberellafujikuroi. The initial product is the ent- 7-α-hydroxy derivative which is then further metabolised to gibberellins A₁, A₁₈, A₁₉, A₂₀, 13-hydroxy GA₁₂, the ent-6α, 7α, 13- and ent-6β, 7α, 13 (19,6-lactone)-trihydroxykaurenoic acids, and a seco-ring B diacid. This apparently low substrate specificity of the enzymes operative beyond the block in the mutant B1-41a provides a useful model for the biosynthetic pathways to 13-hydroxylated gibberellins of higher plants and a preparative route to these plant gibberellins.     

Microbiological conversion of 12-oxygenated and other derivatives of ent-kaur-16-en-19-oic acid by Gibberella Fujikuroi, mutant B1-41a

The metabolism of several ring C and D-functionalized ent-kaur-16-en-19-oic acids by cultures of Gibberella fujikuroi, mutant B1-41a, to the corresponding derivatives of the normal fungal gibberellins (GAs) and ent-kaurenoids is described. A range of 12α- and 12β-hydroxyGAs and ent-kaurenoids are characterized by their mass spectra and GC Kovats retention indices. The mass spectral and GC data are used to identify the 12α-hydroxy derivatives of GA₁₂, GA₁₄, GA₃₇ and GA₄ (GA₅₈), and of the 12β-hydroxy derivatives of ent-7α-hydroxy- and ent-6α, 7α-dihydroxykaurenoic acids, in seeds of Cucurbita maxima. Similarly the metabolites of GA₉, formed in seeds of Pisum sativum and cultures of G.fujikuroi, mutant B1-41a, are identified as 12α-hydroxyGA₉. ent-11β-Hydroxy- and ent-11-oxo-kaurenoic acids are metabolized by the fungus to the corresponding 11-oxygenated derivatives of the normal fungal ent-kaurenoids and some C₂₀-GAs; no 11-oxygenated C₁₉-GAs are formed. Grandiflorenic acid, 11β-hydroxygrandiflorenic acid, attractyligen and ent-15β-hydroxykaurenoic acid are metabolized to unidentified products.