Activation of cryptic biosynthetic gene clusters by fungal artificial chromosomes to produce novel secondary metabolites

Abstract

<abstract> <p>In 2017, we reported the discovery of Berkeleylactone A (BPLA), a novel, potent antibiotic produced exclusively in co-culture by two extremophilic fungi, <italic>Penicillium fuscum</italic> and <italic>P. camembertii/clavigerum</italic>, which were isolated from the Berkeley Pit, an acid mine waste lake, in Butte, Montana. Neither fungus synthesized BPLA when grown in axenic culture. Recent studies suggest that secondary metabolites (SMs) are often synthesized by enzymes encoded by co-localized genes that form “biosynthetic gene clusters” (BGCs), which might remain <italic>silent</italic> (inactive) under various fermentation conditions. Fungi may also harbor cryptic BGCs that are not associated with previously characterized molecules.</p> <p>We turned to the tools of Fungal Artificial Chromosomes (FAC)-Next-Gen-Sequencing (NGS) to understand how co-culture activated cryptic biosynthesis of BPLA and several related berkeleylactones and to further investigate the true biosynthetic potential of these two fungi. FAC-NGS enables the capture of BGCs as individual FACs for heterologous expression in a modified strain of <italic>Aspergillus nidulans</italic> (heterologous host, FAC-<italic>An</italic>HH). With this methodology, we created ten BGC-FACs that yielded fourteen different SMs, including strobilurin, which was previously isolated exclusively from basidiomycetes. Eleven of these compounds were not detected in the extracts of the FAC-<italic>An</italic>HH. Of this discrete set, only the novel compound citreohybriddional had been isolated from either <italic>Penicillium</italic> sp. before and only at very low yield. We propose that through heterologous expression, FACs activated these silent BGCs, resulting in the synthesis of new natural products (NPs) with yields as high as 50%–60% of the crude organic extracts.</p> </abstract>