Abstract

Antibiotic resistance is an increasing problem, exacerbated by global dissemination of drug resistance genes under selection pressure. Moreover, the rate of new antibiotic discovery declined over previous decades and so there is a growing need for new antibiotic discovery and a deeper appreciation of the various genetic and physiological factors that influence antibiotic biosynthesis. The enterobacterium Serratia sp. ATCC 39006 (Serratia) is a useful model for studies on the biosynthesis and regulation of bioactive secondary metabolites, including two antibiotics - a carbapenem and prodigiosin. Both compounds are tightly regulated in response to various physiological and environmental signals, including quorum sensing. We have identified novel regulators of antibiotic production after random transposon mutagenesis. Multiple regulatory mutations mapped to a small locus defining an intergenic region (IGR). These IGR insertion mutants display elevated production of both the carbapenem and prodigiosin antibiotics and they also exhibit reduced motility, confirming pleiotropic impacts. Exploiting phage transduction, we constructed double mutants with 15 known Serratia regulators and showed that the IGR mutant phenotype was epistatic over several of these. Further analysis suggested the presence of a putative gene encoded within the IGR locus, which may play an impactful role in the intricate regulatory network. Functional characterisation of the IGR region and its physiological impacts in both the modulation of antibiotic production and in wider pleiotropy were dissected. Mechanistic understanding of the regulatory mechanisms involved may prove exploitable in enhancing controlled antibiotic hyperproduction.

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