Identification of tetragocarbone C and sideroxylin as the most potent anti-inflammatory components of Syncarpia glomulifera.

In contrast to ancient Western and Asian cultures, medicinal plants of the Aboriginal and Torres Strait Islanders in Australia have not been as intensively studied for their molecular composition and molecular bioactivity. Syncarpia glomulifera subsp. glomulifera is a species in the plant family Myrtaceae. The resin of the plant has been traditionally used by the D'harawal people of Western Sydney to heal inflamed sores and ulcers. Hence, the anti-inflammatory activity of its leaf extract was investigated in RAW 264.7 macrophage and N11 microglia cell lines to isolate and identify the most active compounds. One new compound, tetragocarbone C, and three known compounds, tetragocarbone B, sideroxylin, and lumaflavanone A showed potent anti-inflammatory activity by downregulating nitric oxide and TNF-α production in LPS and IFN-γ stimulated cells. Except for the less potent tetragocarbone B, all compounds had an IC50 value (for nitric oxide downregulation) of <10 µg/mL and moderate cytotoxicity in both cell lines. The molecular targets along pro-inflammatory signaling pathways were further investigated in RAW 264.7 cells. All four compounds suppressed phosphorylation of ERK, c-Jun, and limited the phosphorylation of STAT-1 and STAT-3 in response to LPS and IFN-γ activation. The four compounds also suppressed NF-κB activation by preventing the translocation of the p65 subunit into the nucleus. Collectively, these findings suggest that the compounds isolated from Syncarpia glomulifera, especially tetragocarbone C and sideroxylin are promising anti-inflammatory agents, and could be further investigated for the treatment of diseases characterized by chronic inflammation.

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.