Insignoic acids A - E, unusual α, ß-unsaturated keto fatty acids isolated from the exocarp of Australian rainforest tree Endiandra insignis (Lauraceae).

Anti-inflammatory bioassay-guided compound isolation from the exocarp of the Australian rainforest tree Endiandra insignis (family Lauraceae) has led to the discovery and structural elucidation of unusual α, ß-unsaturated twenty-four carbon fatty acids and their positional isomers, insignoic acids A - E (1a - 5c). The stereochemistry and position of the double bond within the aliphatic chain were independently determined via NMR spectroscopy and Ozone-Induced Dissociation (OzID) Mass Spectrometry, respectively. Compounds (1a - 5c) displayed good to moderate anti-inflammatory activity in the range of 8-84 µM. The low therapeutic index observed when assessing the cell viability in the RAW macrophage cell lines, prompted us to investigate the anticancer potential of these unusual fatty acids. The anti-cancer activity was assessed in A-431 carinoma cell lines and MM649 melanoma cell lines. Insignoic acid C (3a-f) exhibited the highest level of potency with an IC50 value of 5-7 µM against both the cell lines. The insignoic acids are the first of their kind known for incorporating an alpha-beta unsaturated system flanked next to a keto group with an additional level of oxygenation at C-6 in a 24­carbon fatty acid backbone.

Ternstroenol F: a new pentacyclic triterpenoid saponin isolated from the Australian rainforest plant Ternstroemia cherryi.

A detailed close phytochemical investigation of the fruits of Ternstroemia cherryi led to the isolation and identification of the minor metabolite, ternstroenol F, which possessed the usual barrigenol-like terpenoid backbone. The notable difference was that this minor metabolite had the 2(E)-4(Z)-6(E)-decatrienoic acid forming an ester bond at C-22 of the oleanane backbone. Ternstroenol F was evaluated for its inhibitory effects on NO inhibition, cell viability and TNF- α release in RAW 264.7 macrophages, displaying an IC50 values of 0.23, 0.81 and 1.84 µM respectively.

Cryptocaryoic acids A - C: New phenyl alkyl acids isolated from the leaves of Australian rainforest plant Cryptocarya mackinnoniana.

Phytochemical investigation of the leaves of the Australian rainforest tree Cryptocarya mackinnoniana led to the discovery of three new oxygenated phenyl alkyl acids, cryptocaryoic acids A - C and two known compounds, cryptocaryone and 2',6'-dihydroxy-4'-methoxychalcone. The structures of all the compounds were determined by detailed spectroscopic analysis. Mosher's analysis was used for absolute stereochemistry determination at C-11, while the remaining stereochemistry determination of the one remaining stereocenter C-13 was based on NOESY correlations. All compounds isolated were also evaluated for their anti-inflammatory properties by assessing their inhibitory effects on LPS and interferon-γ induced nitric oxide (NO) production and TNF- α release in RAW 264.7 macrophages. The new cryptocaryoic acids exhibited weak to moderate anti-inflammatory activity (NO inhibition) ranging from (18.4-56 µM).

Cryptic Epoxytiglianes from the Kernels of the Blushwood Tree (Fontainea picrosperma).

The kernels of the Australian blushwood tree (Fontainea picrosperma) are the source of the veterinary anticancer drug tigilanol tiglate (2a, Stelfonta) and contain a concentration of phorboids significantly higher than croton oil, the only abundant source of these compounds previously known. The oily matrix of the blushwood kernels is composed of free fatty acids and not by glycerides as found in croton oil. By active partitioning, it was therefore possible to recover and characterize for the first time a cryptic tigliane fraction, that is, the diterpenoid fraction that, because of its lipophilicity, could not be obtained by solvent partition of crude extracts. The cryptic tigliane fraction accounted for ca. 30% of the tigliane kernel titer and was quantified by 1H NMR spectroscopy and profiled by HPLC-MS. Long-chain (linoleates and/or oleates) 20-acyl derivatives of the epoxytigliane diesters tigilanol tiglate (EBC-46, 2a), EBC-47 (4a), EBC-59 (5a), EBC-83 (6a), and EBC-177 (7a) were identified. By chemoselective acylation of EBC-46 (2a) and EBC-177 (7a) the natural triesters 2b and 7b and a selection of analogues were prepared to assist identification of the natural compounds. The presence of a free C-20 hydroxy group is a critical requirement for PKC activation by phorbol esters. The unexpected activity of 20-linoleoyl triester 2b in a cytotoxicity assay based on PKC activation was found to be related mainly to its hydrolysis to tigilanol tiglate (2a) under the prolonged conditions of the assay, while other esters were inactive. Significant differences between the esterification profile of the epoxytigliane di- and triesters exist in F. picrosperma, suggesting a precise, yet elusive, blueprint of acyl decoration for the tigliane polyol 5-hydroxyepoxyphorbol.

Eupomatenes A - E: Neolignans isolated from the leaves of Australian rainforest plant Eupomatia laurina.

A detailed phytochemical investigation of the leaves of the Australian rainforest tree Eupomatia laurina, led to the discovery of five new neolignans, eupomatenes A - E and eight known compounds, eupomatenoid-2, trans-(2'S)-2-[1'-(4-methoxyphenyl)prop-2'-yl]anethol, chlorogenic acid, chlorogenic acid-methyl ester, tyrosol-1-O-ß-xylopyranosyl-1(1 â†’ 6)-O-ß-glucopyranoside, leucoside, kaempferol-3-O-neohesperidoside, and pachypodol. The structures of all the compounds were determined by detailed spectroscopic analysis. All compounds were also evaluated for their anti-inflammatory properties by assessing their inhibitory effects on nitric oxide (NO) production and TNF- α release in RAW 264.7 macrophages. Whilst slight anti-inflammatory activity (in terms of inhibition of NO production) was observed with eupomatenes A - E, this was also associated with high levels of cell growth inhibition.

Transcriptome analysis of the medicinally significant plant Fontainea picrosperma (Euphorbiaceae) reveals conserved biosynthetic pathways.

Euphorbiaceae is a large and diverse family of herbs, shrubs and trees that includes a number of species of considerable economic importance as sources of food, medicines and raw materials. One member of this family, Fontainea picrosperma, is the source plant for the diterpene ester tigilanol tiglate, a natural product recently approved as a treatment for canine mast cell tumours. Here we report the development of reference transcriptomes from root and leaf tissues of F. picrosperma, which include core diterpene biosynthesis genes. A total of ~12 Gb of combined clean reads were generated for assembly into 167,566 contigs with a GC (guanine-cytosine) content of ~41%. Gene ontology showed that 2286 and 2504 transcripts were enriched in the cellular process and 2369 and 2529 transcripts were enriched in the metabolic process categories in leaf and root tissue, respectively. The reference transcriptome contains genes coding for core enzymes involved in common secondary metabolite biosynthetic pathways, including the diterpene biosynthesis pathway within the mevalonate (MVA) and 2-C-methyl-D-erythritol 4- phosphate (MEP) pathways. A phylogenetic analysis using these genes found that F. picrosperma clustered most closely to Jatropha curcas. We found a significantly higher concentration of tigilanol tiglate in F. picrosperma root tissue, which correlated with higher levels of gene expression for enzymes associated with the MVA (6 genes) and MEP (7 genes) pathways, and we hypothesise that the initial stages of tigilanol tiglate biosynthesis occur primarily in the roots of F. picrosperma. This study provides a resource for future gene-related biodiscovery investigations in F. picrosperma and diterpene biosynthesis, in particular for tigilanol tiglate and related macrocyclic diterpenes.

Ternstroenols A - E: Undescribed pentacyclic triterpenoids from the Australian rainforest plant Ternstroemia cherryi.

Chromatographic separation of the extracts of the Australian rainforest plant Ternstroemia cherryi led to the isolation of five undescribed barrigenol-like triterpenoids, ternstroenols A - E, from the fruits and three known ones from the leaves. Ternstroenols A - E represent a new form of structural diversity, being the first in its kind to incorporate a trans- 2, 4, 6- decatrienoyl moiety at C-22. The structures of the ternstroenols were assigned by detailed spectroscopic analysis, degradation and chemical derivatization. All compounds exhibited potent anti-inflammatory activity in LPS and IFN- γ activated RAW 264.7 macrophages, with IC50 values as low as 0.7 µM. Despite the remarkable potency, high levels of unwanted cell growth inhibition was also observed, which prompted their cytotoxic evaluation in U87/U251 human glioblastoma cell lines.

The reciprocal EC50 value as a convenient measure of the potency of a compound in bioactivity-guided purification of natural products.

Identification of potent natural products is a challenging task in which sophisticated separation processes including HPLC are employed. The bioactivity of HPLC fractions is determined with a bioassay, and the most potent compounds are progressed to structural elucidation. In pharmacology, the potency of a compound is expressed as the half-maximal effective concentration (EC50), which refers to the concentration of a drug that induces a response halfway between the baseline and maximum. While expressing the potency of a compound by its EC50 value makes sense in a clinical context, it is counterintuitive in the context of bioactivity-guided purification, as the potency of a compound is inversely related to its EC50 value, and the most potent compound is the one with the lowest EC50. In natural products chemistry, it would be more logical if an increase in potency would be reflected by an increase of a parameter reflecting the potency. In this study, we introduce the term "effective dilution volume (EDV50)" as the reciprocal of the EC50 (1/EC50). We show how the EDV50 can be used to identify potent compounds in chromatographic separations, allowing to easily graph and identify anti-inflammatory compounds. We show two examples of this approach by overlaying an HPLC chromatogram with the EDV50 to point out the most potent compounds. We hope that the EDV50 will make the illustration of active fractions containing potent compounds in a chromatogram obvious for the reader and will become a useful graphic tool in the natural products literature in the future.

Mulgravanols A and B, rare oxidized xanthenes and a new phloroglucinol isolated from the Australian rainforest plant Waterhousea mulgraveana (Myrtaceae).

Phytochemical investigation of the Australian rainforest plant leaves Waterhousia mulgraveana, yielded two rare oxidized xanthenes, mulgravanols A (1) and B (2) along with a new phloroglucinol, mulgravanol C (3). Mulgravanol A (1) is the first reported example of a complex xanthene flanked by a methine bridged phloroglucinol unit. All the compounds displayed moderate inhibitory effects on nitric oxide production and TNF-α release in RAW 264.7 macrophages (IC50) 42-55 µM. The structures of the new compounds were assigned based on a detailed spectroscopic interpretation.

Antibacterial 5α-Spirostane Saponins from the Fruit of Cordyline manners-suttoniae.

Antibacterial-activity-guided fractionation of a dichloromethane extract from the fruit of Cordyline manners-suttoniae and subsequent structure-activity investigations resulted in the identification of 10 new (1-10) and one known (11) 5α-spirostane saponin. The structures of the new compounds were established by 1D and 2D NMR analyses. The absolute configurations of the isolated compounds were determined by X-ray diffraction analysis or chemical derivatizations. The most active compound, suttonigenin F (6), inhibited the Gram-positive bacteria Staphylococcus aureus with MIC75 values that were comparable to those of the antibiotic chloramphenicol. Structure-activity relationships were also obtained from the assessment of antibacterial and cytotoxic activities of the isolated saponins.

Short distance pollen dispersal and low genetic diversity in a subcanopy tropical rainforest tree, Fontainea picrosperma (Euphorbiaceae).

Gene flow via pollen movement affects genetic variation in plant populations and is an important consideration in plant domestication. Fontainea picrosperma is a subcanopy rainforest tree that is of commercial interest because it is the source of tigilanol tiglate, a natural product used for the treatment of solid tumors. We identify patterns of pollen-mediated gene flow within natural populations of F. picrosperma and estimate genetic parameters and genetic structure between adult and juvenile groups using microsatellite markers. Our results show pollination events occur over much shorter distances than reported for tropical canopy species. At least 63% of seeds are sired by male trees located within 30 m of the mother. On average, 27% of the local male population contributed to successful reproduction of F. picrosperma with most fathers siring a single seed, however, the contributions to reproduction were uneven. Larger male trees with more flowers had greater reproductive success than those with less flowers (P < 0.05). There were comparatively low levels of genetic variation across the species (HE = 0.405 for adult trees and 0.379 for juveniles) and we found no loss of genetic diversity between adult and juvenile trees. Short distance pollen flow and low genetic diversity is theoretically a prelude to genetic impoverishment, however F. picrosperma has persisted through multiple significant climatic oscillations. Nevertheless, the remaining low genetic diversity is of concern for domestication programs which require maximal genetic diversity to facilitate efficient selective breeding and genetic improvement of this commercially significant species.

Anti-Inflammatory Chemical Profiling of the Australian Rainforest Tree Alphitonia petriei (Rhamnaceae).

Chronic inflammation is an important pathological condition in many human diseases, and due to the side effects of the currently used non-steroidal anti-inflammatory drugs, discovery of novel anti-inflammatory drugs is of general interest. Anti-inflammatory activity guided compound isolation from the plant Alphitonia petriei led to the isolation of the known plant sterols emmolic acid (1), alphitolic acid (2), trans- and cis-coumaroyl esters of alphitolic acid (3 and 4) and betulinic acid (5). A detailed spectroscopic analysis led to the structure elucidation of the alphitolic acid derivatives (1-5), and the semi-synthetic emmolic acid acetate (6). When tested in LPS (Lipopolysaccharides) + IFN-γ (Interferon gamma) activated RAW 264.7 macrophages, all compounds except (1) exhibited potent anti-inflammatory activity (IC50 values as low as 1.7 µM) in terms of downregulation of NO and TNF-α production, but also demonstrated some considerable cytotoxicity.

Unprecedented 1,14-seco-crotofolanes from Croton insularis: oxidative cleavage of crotofolin C by a putative homo-Baeyer-Villiger rearrangement.

EBC-162 isolated from Croton insularis, obtained from the northern rainforest of Australia, was structurally affirmed as crotofolin C (4). Novel oxidative degradation products, EBC-233 and EBC-300, which are the first crotofolane endoperoxides, were also isolated. Both endoperoxides were found to be stable intermediates, which are proposed to undergo an unprecedented homo-Baeyer-Villiger biosynthetic rearrangement to give a new class of 1,14-seco-crotofolane diterpenes. Prolonged storage of all isolates assisted in authenticating their natural product status. Anticancer activities of reported compounds are presented.