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Multi-Omic Analyses Provide Links between Low-Dose Antibiotic Treatment and Induction of Secondary Metabolism in Burkholderia thailandensis

Anran Li, Dainan Mao, Aya Yoshimura, Paul C. Rosen, Warham Lance Martin, Étienne Gallant, Martin Wühr, Mohammad R. Seyedsayamdost

2020mBio33 citationsDOIOpen Access PDF

Abstract

The discovery of antibiotics ranks among the most significant accomplishments of the last century. Although the targets of nearly all clinical antibiotics are known, our understanding regarding their natural functions and the effects of subinhibitory concentrations is in its infancy. Stimulatory rather than inhibitory functions have been attributed to low-dose antibiotics. Among these, we previously found that antibiotics activate silent biosynthetic genes and thereby enhance the metabolic output of bacteria. The regulatory circuits underlying this phenomenon are unknown. We take a first step toward elucidating these circuits and show that low doses of trimethoprim (Tmp) have cell-wide effects on the saprophyte Burkholderia thailandensis . Most importantly, inhibition of one-carbon metabolic processes by Tmp leads to an accumulation of homoserine, which induces the production of an otherwise silent cytotoxin via a LuxR-type transcriptional regulator. These results provide a starting point for uncovering the molecular basis of the hormetic effects of antibiotics.

Topics & Concepts

MetabolomeBiologyAntibioticsTranscriptomeQuorum sensingResistomeProteomeMetabolomicsMicrobiologyProteomicsBacteriaVirulenceComputational biologyGeneBiochemistryGeneticsGene expressionBioinformaticsAntibiotic resistanceIntegronBacteriophages and microbial interactionsAntibiotic Resistance in BacteriaBacterial Genetics and Biotechnology
Multi-Omic Analyses Provide Links between Low-Dose Antibiotic Treatment and Induction of Secondary Metabolism in Burkholderia thailandensis | Litcius