In vivo transformations of artemisinic acid in Artemisia annua plants

Artemisinic acid labeled with both ¹³C and ²H at the 15-position has been fed to intact plants of Artemisia annua via the cut stem, and its in vivo transformations studied by 1D- and 2D-NMR spectroscopy. Seven labeled metabolites have been isolated, all of which are known as natural products from this species. The transformations of artemisinic acid—as observed both for a group of plants, which was kept alive by hydroponic administration of water and for a group, which was allowed to die by desiccation—closely paralleled those, which have been recently described for its 11,13-dihydro analog, dihydroartemisinic acid. It seems likely therefore that similar mechanisms, involving spontaneous autoxidation of the Δ^4,5 double bond in both artemisinic acid and dihydroartemisinic acid and subsequent rearrangements of the resultant allylic hydroperoxides, may be involved in the biological transformations, which are undergone by both compounds. All of the sesquiterpene metabolites, which were obtained from in vivo transformations of artemisinic acid retained their unsaturation at the 11,13-position, and there was no evidence for conversion into any 11,13-dihydro metabolite, including artemisinin, the antimalarial drug, which is produced by A. annua. This observation led to the proposal of a unified biosynthetic scheme, which accounts for the biogenesis of many of the amorphane and cadinane sesquiterpenes that have been isolated as natural products from A. annua. In this scheme, there is a bifurcation in the biosynthetic pathway starting from amorpha-4,11-diene leading to either artemisinic acid or dihydroartemisinic acid; these two committed precursors are then, respectively, the parents for the two large families of highly oxygenated 11,13-dehydro and 11,13-dihydro sesquiterpene metabolites, which are known from this species.     

Sesquiterpenoids from the Rhizome of Ligularia virgaurea

Two novel sesquiterpene dimers, compounds 1 and 2 , were isolated from the rhizome of Ligularia virgaurea, together with the six known sesquiterpenoids 3 – 8 . Their structures were established by physico‐chemical and spectroscopic methods, especially by means of 1D‐ and 2D‐NMR as well as HR‐MS analyses. A mechanism based on a classical Diels–Alder cyclization is proposed for the formation of the dimer 1 from the precursors 8 and the quinone form of 6 (Scheme).     

Emission of 2-phenylethanol from its β-d-glucopyranoside and the biogenesis of these compounds from [H8] l-phenylalanine in rose flowers

The hydrolysis of 2-phenylethyl β-d-glucopyranoside (3) was found to be partially inhibited by feeding with 2-phenyl-N-glucosyl-acetamidiumbromide (8), a β-glucosidase inhibitor, resulting in a decrease in the diurnal emission of 2-phenylethanol (2) from Rosa damascena Mill. flowers. Detection of [1,1,2,2′,3′,4′,5′,6′-²H₈]-2 and [1,2,2′,3′,4′,5′,6′-²H₇]-2 from R. ‘Hoh-Jun’ flowers fed with [1,1,2,2′,3′,4′,5′,6′-²H₈]-3 suggested that β-glucosidase, alcohol dehydrogenase, and reductase might be involved in scent emission. Comprehensive GC-SIM analyses revealed that [1,2,2,2′,3′,4′,5′,6′-²H₈]-2 and [1,2,2,2′,3′,4′,5′,6′-²H₈]-3 must be biosynthesized from [1,2,2,2′,3′,4′,5′6′-²H₈] l-phenylalanine ([²H₈]-1) with a retention of the deuterium atom at α-position of [²H₈]-1.     

In vivo transformations of dihydroartemisinic acid in Artemisia annua plants

[15-¹³C²H₃]-dihydroartemisinic acid (2a) and [15-C²H₃]-dihydroartemisinic acid (2b) have been fed via the root to intact Artemisia annua plants and their transformations studied in vivo by one-dimensional ²H NMR spectroscopy and two-dimensional ¹³C-²H correlation NMR spectroscopy (¹³C-²H COSY). Labelled dihydroartemisinic acid was transformed into 16 12-carboxy-amorphane and cadinane sesquiterpenes within a few days in the aerial parts of A. annua, although transformations in the root were much slower and more limited. Fifteen of these 16 metabolites have been reported previously as natural products from A. annua. Evidence is presented that the first step in the transformation of dihydroartemisinic acid in vivo is the formation of allylic hydroperoxides by the reaction of molecular oxygen with the Δ^4,5-double bond in this compound. The origin of all 16 secondary metabolites might then be explained by the known further reactions of such hydroperoxides. The qualitative pattern for the transformations of dihydroartemisinic acid in vivo was essentially unaltered when a comparison was made between plants, which had been kept alive and plants which were allowed to die after feeding of the labelled precursor. This, coupled with the observation that the pattern of transformations of 2 in vivo demonstrated very close parallels with the spontaneous autoxidation chemistry for 2, which we have recently demonstrated in vitro, has lead us to conclude that the main ‘metabolic route’ for dihydroartemisinic acid in A. annua involves its spontaneous autoxidation and the subsequent spontaneous reactions of allylic hydroperoxides which are derived from 2. There may be no need to invoke the participation of enzymes in any of the later biogenetic steps leading to all 16 of the labelled 11,13-dihydro-amorphane sesquiterpenes which are found in A. annua as natural products.     

Britanlins A-D, four novel sesquiterpenoids from Inula britannica

A phytochemical investigation on the flowers of Inula britannica has led to the isolation of four novel sesquiterpenoids, britanlins A-D. Britanlins A-C feature the rare presilphiperfolane-type frameworks, which play an important role in biogenesis of triquinane sesquiterpenoids. Britanlin D possessed a rearranged pseudoguaiane skeleton, which was first isolated from nature. The structures of britanlins A to D were elucidated on the basis of extensive spectroscopic methods. The structures of britanlins A and D were further confirmed by single crystal X-ray diffraction.     

Longipedlactones A-I, nine novel triterpene dilactones possessing a unique skeleton from Kadsura longipedunculata

Nine novel triterpene dilactones with an unprecedented rearranged pentacyclic skeleton, longipedlactones A-I (1-9), have been isolated from the leaves and stems of Kadsura longipedunculata Finet et Gagnep (Schisandraceae). Their structures were determined on the basis of comprehensive spectroscopic analysis and single-crystal X-ray structure determination. A biogenetic pathway for longipedlactone A (1) was also proposed. Compounds 1-3, 6, and 8 showed significant cytotoxicity against A549, with HT-29 and K562 cell lines having IC₅₀ values of 0.84-11.38 μM in vitro.     

Enantiodifferentiation of α-ketols in sherry by one- and two-dimensional HRGC techniques

The enantiomeric distrubution of solerone (5-oxo-4-hexanolide) 1, ethyl 4-hydroxy- 5-oxohexanoate 2, ethyl 5-hydroxy-4-oxohexanoate 3, 4-oxo-5-hexanolide 4, and solerol (5-hydroxy-4-hexanolide) 5 in sherry wines was determined by several HRGC techniques. While gas chromatography-mass spectrometry on chiral cyclodextrin phases (chiral GC-MS) prevented any racemization of α-ketols 2 and 3 caused by keto-enol tautomerization during analysis, multidimensional gas chromatography MDGC (coupled either by “live-T” switching or by “moving column stream switching” MCSS) led to rearranged constitutional-and stereoisomers. The stereochemical results are discussed regarding the biogenesis of sherry constituents 1–5.     

Two New Ring A‐Cleaved Lanostane‐Type Triterpenoids and Four Known Steroids Isolated from Endophytic Fungus Glomerella sp. F00244

Two new ring A‐cleaved lanostane‐type triterpenoids, glometenoid A ( 1 ) and glometenoid B ( 2 ), together with four known steroids, (20S,22E,24R)‐ergosta‐7,22‐dien‐3β,5α,6β‐triol ( 3 ), (3β,5α,8α,22E)‐ergosta‐6,22‐diene‐3,5,8‐triol ( 4 ), 5α,8α‐epidioxy‐22E‐ergosta‐6,22‐dien‐3β‐ol ( 5 ), and ergosterol ( 6 ), were isolated from the endophytic fungus Glomerella sp. F00244. Their structures were elucidated by comprehensive spectroscopic analyses of NMR and MS data. Their antimicrobial activities were evaluated against pathogenic bacteria Bacillus subtilis ATCC 9372, Staphylococcus aureus ATCC 25923, Bacillus pumilus CMCC (B) 63202, Micrococcus luteus CMCC28001, and pathogenic fungi Candida albicans AS2.538 and Aspergillus niger ACCC30005, but no inhibition was observed at a concentration of 20 μg/ml. Further cytotoxicity assessment revealed that compound 1 exhibited weak antiproliferative activity against ovarian cancer HeLa cell.     

Chamigrenelactone, a polyoxygenated sesquiterpene with a novel structural type and devoid of halogen from Laurencia obtusa

A biogenetically interesting halogen-devoid metabolite chamigrenelactone 1, with a high oxygen-content, has been isolated from Laurencia obtusa from Isla Grande (Caribbean Panama). Its structure and stereochemistry were determined on the basis of spectral studies.     

Uncommon Sesquiterpenoids and New Triterpenoids from Jatropha neopauciflora (Euphorbiaceae)

Eight new terpenoids ( 1 – 8 ) were isolated from the bark of Jatropha neopauciflora, together with eight known compounds. The new isolates include the sesquiterpenoids (1R,2R)‐diacetoxycycloax‐4(15)‐ene ( 1 ); (1R,2R)‐dihydroxycycloax‐4(15)‐ene ( 2 ), (2R)‐δ‐cadin‐4‐ene‐2,10‐diol ( 3 ), (2R)‐δ‐cadina‐4,9‐dien‐2‐ol ( 4 ), (1R,2R)‐dihydroxyisodauc‐4‐en‐14‐ol ( 5 ) and its acetonide 6 (artifact), as well as the two triterpenoids (3β,16β)‐16‐hydroxylup‐20(29)‐en‐3‐yl (E)‐3‐(4‐hydroxyphenyl)prop‐2‐enoate ( 7 ) and (3β,16β)‐16‐hydroxyolean‐18‐en‐3‐yl (E)‐3‐(4‐hydroxyphenyl)prop‐2‐enoate ( 8 ). The structures of these compounds were established by extensive 1D‐ and 2D‐NMR spectroscopic methods, and their absolute configurations were determined by circular‐dichroism (CD) experiments, and by X‐ray crystallographic analysis (compound 7 ; Fig. 3). A plausible biosynthesis of the sesquiterpenoids 1 – 5 is proposed (Scheme), starting from (?)‐germacrene D as the common biogenetic precursor.