Dainan Mao scite author profile

Bacteria produce a diverse array of secondary metabolites that have been invaluable in the clinic and in research. These metabolites are synthesized by dedicated biosynthetic gene clusters (BGCs), which assemble architecturally complex molecules from simple building blocks. The majority of BGCs in a given bacterium are not expressed under normal laboratory growth conditions, and our understanding of how they are silenced is in its infancy. Here, we have addressed this question in the Gram-negative model bacterium Burkholderia thailandensis E264 using genetic, transcriptomic, metabolomic, and chemical approaches. We report that a previously unknown, quorum-sensing-controlled LysR-type transcriptional regulator, which we name ScmR (for secondary metabolite regulator), serves as a global gatekeeper of secondary metabolism and a repressor of numerous BGCs. Transcriptionally, we find that 13 of the 20 BGCs in B. thailandensis are significantly (threefold or more) upor down-regulated in a scmR deletion mutant (ΔscmR). Metabolically, the ΔscmR strain displays a hyperactive phenotype relative to wild type and overproduces a number of compound families by 18-to 210-fold, including the silent virulence factor malleilactone. Accordingly, the ΔscmR mutant is hypervirulent both in vitro and in a Caenorhabditis elegans model in vivo. Aside from secondary metabolism, ScmR also represses biofilm formation and transcriptionally activates ATP synthesis and stress response. Collectively, our data suggest that ScmR is a pleiotropic regulator of secondary metabolism, virulence, biofilm formation, and other stationary phase processes. A model for how the interplay of ScmR with pathwayspecific transcriptional regulators coordinately silences virulence factor production is proposed.biosynthetic gene clusters | natural products | Burkholderia thailandensis | regulation | virulence

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Mapping the Trimethoprim-Induced Secondary Metabolome of Burkholderia thailandensis

Okada

Mao

et al. 2016

ACS Chem. Biol.

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While bacterial genomes typically contain numerous secondary metabolite biosynthetic gene clusters, only a small fraction of these are expressed at any given time. The remaining majority is inactive or silent, and methods that awaken them would greatly expand our repertoire of bioactive molecules. We recently devised a new approach for identifying inducers of silent gene clusters and proposed that the clinical antibiotic trimethoprim acted as a global activator of secondary metabolism in Burkholderia thailandensis. Herein, we report that trimethoprim triggers the production of over 100 compounds that are not observed under standard growth conditions, thus drastically modulating the secondary metabolic output of B. thailandensis. Using MS/MS networking and NMR, we assign structures to ∼40 compounds, including a group of new molecules, which we call acybolins. With methods at hand for activation of silent gene clusters and rapid identification of small molecules, the hidden secondary metabolomes of bacteria can be interrogated.

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Recent advances in activating silent biosynthetic gene clusters in bacteria

Mao

Okada

et al. 2018

Current Opinion in Microbiology

103

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The explosion of microbial genome sequences has shown that bacteria harbor an immense, largely untapped potential for the biosynthesis of diverse natural products, which have traditionally served as an important source of pharmaceutical compounds. Most of the biosynthetic genes that can be detected bioinformatically are only weakly expressed, or not at all, under standard laboratory growth conditions. Herein we review three recent approaches that have been developed for inducing these so-called silent biosynthetic gene clusters: insertion of constitutively active promoters using CRISPR-Cas9, high-throughput elicitor screening for identification of small molecule inducers, and reporter-guided mutant selection for creation of overproducing strains. Together with strategies implemented previously, these approaches promise to unleash the products of silent gene clusters for years to come.

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

Mao

Yoshimura

et al. 2020

mBio

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Low doses of antibiotics can trigger secondary metabolite biosynthesis in bacteria, but the underlying mechanisms are generally unknown. We sought to better understand this phenomenon by studying how the antibiotic trimethoprim activates the synthesis of the virulence factor malleilactone in Burkholderia thailandensis. Using transcriptomics, quantitative multiplexed proteomics, and primary metabolomics, we systematically mapped the changes induced by trimethoprim. Surprisingly, even subinhibitory doses of the antibiotic resulted in broad transcriptional and translational alterations, with ∼8.5% of the transcriptome and ∼5% of the proteome up- or downregulated >4-fold. Follow-up studies with genetic-biochemical experiments showed that the induction of malleilactone synthesis can be sufficiently explained by the accumulation of methionine biosynthetic precursors, notably homoserine, as a result of inhibition of the folate pathway. Homoserine activated the malleilactone gene cluster via the transcriptional regulator MalR and gave rise to a secondary metabolome which was very similar to that generated by trimethoprim. Our work highlights the expansive changes that low-dose trimethoprim induces on bacterial physiology and provides insights into its stimulatory effect on secondary metabolism. IMPORTANCE 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.

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Thailandenes, Cryptic Polyene Natural Products Isolated from Burkholderia thailandensis Using Phenotype-Guided Transposon Mutagenesis

et al. 2019

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Burkholderia thailandensis has emerged as a model organism for investigating the production and regulation of diverse secondary metabolites. Most of the biosynthetic gene clusters encoded in B. thailandensis are silent, motivating the development of new methods for accessing their products. In the current work, we add to the canon of available approaches using phenotype-guided transposon mutagenesis to characterize a silent biosynthetic gene cluster. Because secondary metabolite biosynthesis is often associated with phenotypic changes, we carried out random transposon mutagenesis followed by phenotypic inspection of the resulting colonies. Several mutants exhibited intense pigmentation and enhanced expression of an iterative type I polyketide synthase cluster that we term org. Disruptions of orgA, orgB, and orgC abolished the biosynthesis of the diffusible pigment, thus linking it to the org operon. Isolation and structural elucidation by HR-MS and 1D/2D NMR spectroscopy revealed three novel, cryptic metabolites, thailandene A−C. Thailandenes are linear formylated or acidic polyenes containing a combination of cis and trans double bonds. Variants A and B exhibited potent antibiotic activity against Staphylococcus aureus and Saccharomyces cerevisiae but not against Escherichia coli. One of the transposon mutants that exhibited an enhanced expression of org contained an insertion upstream of a σ54-dependent transcription factor. Closer inspection of the org operon uncovered a σ54 promoter consensus sequence upstream of orgA, providing clues regarding its regulation. Our results showcase the utility of phenotype-guided transposon mutagenesis in uncovering cryptic metabolites encoded in bacterial genomes.

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Dainan Mao

Discovery of scmR as a global regulator of secondary metabolism and virulence in Burkholderia thailandensis E264

Mapping the Trimethoprim-Induced Secondary Metabolome of Burkholderia thailandensis

Recent advances in activating silent biosynthetic gene clusters in bacteria

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

Thailandenes, Cryptic Polyene Natural Products Isolated from Burkholderia thailandensis Using Phenotype-Guided Transposon Mutagenesis

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