Utilization of mixed cultures as a strategy to stimulate the biosynthesis of natural products by endophytic fungi

The study of plant-microbe interactions has been of great interest over the past years. Currently, the interactions that occur among organisms that live in close relationship also have been receiving great attention because mutualistic and competitive forces may induce the production of new bioactive metabolites. Therefore, studying the interactions between endophytic microorganisms that colonize the same plant seems to be a promising strategy for obtaining chemically different substances that might also be bioactive. Through the utilization of mixed microbial cultures, this study contributed to knowledge of the relationship among the endophytic fungi SS13 (Papulaspora immersa), SS50 (Fusarium oxysporum), SS67 (Nigrospora sphaerica), SS77 (Alternaria tenuissima) and SS84 (Phoma betae), isolated from the medicinal plant Smallanthus sonchifolius (yacon), and its role in the increase of the chemical diversity of microbial natural products, in order to identify anticancer secondary metabolites. For this aim, the fungi were grown in single and mixed cultures, both in liquid and semi-solid media. Different media, different approaches to establish the mixed cultures and different extraction methods were used. The extracts were analyzed chemically and biologically. After the fractionation, five compounds were isolated: aphidicolin (I), 3-deoxy-aphidicolin (II), stemphyperylenol (III), alterperylenol (IV) and alternariol monomethyl ether (V). Compounds I and II are terpene derivatives, while III, IV and V are polyketide derivatives. The substances I and II were produced by the fungus SS67, and the production of I apparently increased in liquid mixed cultures with SS13 and SS84, decreasing considerably in mixed culture with SS77. Due to the high cytotoxic activity of aphidicolin (I), the cultures of the fungus SS67 originated extracts highly active in the cytotoxicity assays in cancer cells. Substance III was only detected by HPLC-DAD in the mixed culture between the fungi SS67 and SS77, and the production of compound IV was higher in this mixed culture when compared to the single culture of the fungus SS77 (malt extract medium). Probably these compounds were produced by SS77 in response to the presence of SS67. The extract obtained during this mixed culture showed the highest cytotoxic activity against the cell line MDAMB-435 (breast cancer). In a subsequent fermentation in PDB medium, compound III was also isolated from the single culture of the fungus SS77 grown, along with compound V. Additionally, antagonism experiments in Petri dishes with these two fungi revealed the presence of several other compounds in the inhibition zone, which does not correspond to the substances previously isolated from the liquid medium, and may be responsible for the antagonistic effect observed in semi-solid medium. The experiments of antagonistic activity of metabolites produced by fungi showed that many active compounds are probably produced in very small quantities, making it impossible to detect by HPLC-DAD. Moreover, it was found that aphidicolin (I) did not have significant antifungal activity against the fungi SS13, SS50 and SS77 and that the SS67 inhibition by SS77 is due to the production of diffusible compounds in semi-solid medium, and likely, due to the production of compound III and IV in liquid medium, and other polyketides. The production of secondary metabolites by endophytic fungi probably occurs as a result of the ecological role they play in nature. Thus, the use of mixed cultures of these microorganisms may induce the production of compounds that would not be produced under unnatural conditions. (AU)