A new strategy to trigger the biosynthesis of fungal natural prod

A new strategy to trigger the biosynthesis of fungal natural products is based on the discovery that transcription of fungal genes is often controlled by epigenetic regulation such as histone deacetylation and DNA methylation. Histone modifications and DNA methylation communally operate to modify chromatin thereby regulating gene expression or silencing in fungi and other organisms. Thus, it is assumed that epigenetic Omipalisib cell line modifiers may be applied for modulating secondary metabolite production (Scherlach and Hertweck 2009; Cichewicz 2010). Accordingly, twelve fungi were

treated with DNA methyltransferase (DNMT) ISRIB clinical trial and histone deacetylase (HDAC) inhibitors in a dose dilution series. Eleven strains were found to produce new or enhanced levels of secondary metabolites (Williams et al. 2008; Henrikson et al. 2009). Examples of commonly used DNMT inhibitors include 5-azacytidine and 5-aza-20-deoxycytidine, and the HDAC inhibitors hydroxamic-acid-containing compounds or cyclic peptides such as trichostatin A and trapoxin B, respectively (Cichewicz 2010). An increase

in carotenoid production by Neurospora crassa cultures was achieved by addition of low doses of 5-azacytidine (≤30 μM), whereas higher doses (100 and 300 μM) decreased carotenoid levels and altered reproductive structures (Kritsky et TPCA-1 mouse al. 2001). The same compound triggered the PRKACG biosynthesis of two new galactose-conjugated polyunsaturated polyketides in Diatrype sp. (Cichewicz 2010). Similarly, addition of 1 μM trichostatin A to Alternaria alternata and Penicillium expansum significantly increased the concentrations of numerous hitherto unidentified natural products (Shwab et al. 2007). Furthermore, addition of epigenetic modifiers to A. niger cultures resulted in increased transcriptional rates among

most of its PKS, NRPS and hybrid PKS-NRPS (HPN) biosynthetic gene clusters, whereas less than 30 % of these gene clusters were transcribed when the organism was grown in absence of the modifiers (Fisch et al. 2009). In a further study implying molecular-based gene manipulation, deletion of cclA gene in A. nidulans resulted in a significant decrease in methylation of histone H3. Thus, this gene presumably encodes for a protein component of the Set1-containing COMPASS complex catalyzing methylation of histone H3. The cclA deletant was found to produce several silent secondary metabolites, including monodictyophenone, emodin and its derivatives, and to inhibit the growth of wild-type A. nidulans. 2-Hydroxyemodin, which exhibited significant anti-fungal and anti-bacterial activities, was assumed to mediate the inhibitory activity of the cclA deletant. Hence, it can be concluded that changes in chromatin levels are involved in the suppression or activation of biosynthetic gene clusters (Cichewicz 2010; Giles et al. 2011).

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