Bacteria harbor an immense, untapped trove of novel secondary metabolites in the form of ‘silent’ biosynthetic gene clusters (BGCs). These can be identified bioinformatically but are not expressed under normal laboratory growth conditions. Methods to access their products would dramatically expand our pool of bioactive compounds. We report a universal high-throughput method for activating silent BGCs in diverse microorganisms. Our approach relies on elicitor screening to induce the secondary metabolome of a given strain and imaging mass spectrometry to visualize the resulting metabolomes in response to ~500 conditions. Because it does not require challenging genetic, cloning, or culturing procedures, it can be used with both sequenced and unsequenced bacteria. We demonstrate the power of the approach by applying it to diverse bacteria and report the discovery of nine cryptic metabolites with potentially therapeutic bioactivities, including a new glycopeptide chemotype with potent inhibitory activity against a pathogenic virus.
Bacteria harbor an immense reservoir of potentially new and therapeutic small molecules in the form of 'silent' biosynthetic gene clusters (BGCs). These BGCs can be identified bioinformatically but are sparingly-expressed under normal laboratory growth conditions, or not at all, and therefore do not produce significant levels of the corresponding small molecule product. Several methods have been developed for activating silent BGCs. A major limitation for nearly all methods is that they require genetic procedures and/or do not report on the bioactivity of the cryptic metabolite. We herein report 'Bioactivty-HiTES', an approach that links the bioactivity of cryptic metabolites to their induction, while at the same time obviating the need for genetic manipulations. Using this method, we detected induction of cryptic antibiotics in three actinomycete strains tested. Follow-up studies in one case allowed us to structurally elucidate two cryptic metabolites, elicited by the beta-blocker atenolol in Streptomyces hiroshimensis, with selective growth-inhibitory activity against Gram-negative bacteria, notably Escherichia coli and Acinetobacter baumannii. Atenolol turned out to be a global elicitor of secondary metabolism, and characterization of additional cryptic metabolites led to the discovery of a novel naphthoquinone epoxide. Bioactivity-HiTES is a general, widely-applicable procedure that will be useful in identifying cryptic bioactive metabolites in the future.
Microbial genomes harbor an abundance of biosynthetic gene clusters, but most are expressed at low levels and need to be activated for characterization of their cognate natural products. In this work, we report the combination of high-throughput elicitor screening (HiTES) with matrixassisted laser desorption/ionization mass spectrometry (MALDI-MS) for the rapid identification of cryptic peptide natural products. Application to Streptomyces ghanaensis identified amygdalin as an elicitor of a novel non-ribosomal peptide, which we term cinnapeptin. Complete structural elucidation revealed cinnapeptin as a cyclic depsipeptide with an unusual 2-methyl-cinnamoyl group. Insights into its biosynthesis were provided by whole genome sequencing and gene deletion studies, while bioactivity assays showed antimicrobial activity against Gram-positive bacteria and fission yeast. MALDI-HiTES is a broadly applicable tool for the discovery of cryptic peptides encoded in microbial genomes.
Surface attachment, an early step in the colonization of multiple host environments, activates the virulence of the human pathogen P. aeruginosa. However, the downstream toxins that mediate surface-dependent P. aeruginosa virulence remain unclear, as do the signaling pathways that lead to their activation. Here, we demonstrate that alkyl-quinolone (AQ) secondary metabolites are rapidly induced upon surface association and act directly on host cells to cause cytotoxicity. Surface-induced AQ cytotoxicity is independent of other AQ functions like quorum sensing or PQS-specific activities like iron sequestration. We further show that packaging of AQs in outer-membrane vesicles (OMVs) increases their cytotoxicity to host cells but not their ability to stimulate downstream quorum sensing pathways in bacteria. OMVs lacking AQs are significantly less cytotoxic, suggesting these molecules play a role in OMV cytotoxicity, in addition to their previously characterized role in OMV biogenesis. AQ reporters also enabled us to dissect the signal transduction pathways downstream of the two known regulators of surface-dependent virulence, the quorum sensing receptor, LasR, and the putative mechanosensor, PilY1. Specifically, we show that PilY1 regulates surfaceinduced AQ production by repressing the AlgR-AlgZ two-component system. AlgR then induces RhlR, which can induce the AQ biosynthesis operon under specific conditions. These findings collectively suggest that the induction of AQs upon surface association is both necessary and sufficient to explain surface-induced P. aeruginosa virulence.
Lasso peptides are a class of ribosomally synthesized and post-translationally modified peptides (RiPPs) that feature a unique lariat-knot topology. Canucin A, a post-translationally hydroxylated lasso peptide, was recently discovered via activation of its otherwise silent biosynthetic gene cluster in Streptomyces canus. The biosynthesis of canucin A, notably the introduction of a hydroxyl group at the β-carbon of the terminal aspartate residue, is the topic of the current report. We combine genetic and biochemical experiments to show that an iron/2-oxoglutarate-dependent enzyme, CanE, installs the hydroxyl group onto the precursor peptide in vivo and in vitro. Moreover, we show that hydroxylation occurs prior to macrocyclization and that the RiPP recognition element (RRE), encoded within the gene cluster to facilitate the initial proteolytic reaction, also increases the yield of hydroxylation, hinting at a dual role for the RRE. Our results have implications for the combinatorial biosynthesis of lasso peptides.
The products of most secondary metabolite biosynthetic gene clusters (BGCs) have yet to be discovered, in part due to low expression levels in laboratory cultures. Reporter-guided mutant selection (RGMS) has recently been developed for this purpose: a mutant library is generated and screened, using genetic reporters to a chosen BGC, to select transcriptionally active mutants that then enable the characterization of the “cryptic” metabolite. The requirement for genetic reporters limits the approach to a single pathway within genetically tractable microorganisms. Herein, we utilize untargeted metabolomics in conjunction with transposon mutagenesis to provide a global read-out of secondary metabolism across large numbers of mutants. We employ self-organizing map analytics and imaging mass spectrometry to identify and characterize seven cryptic metabolites from mutant libraries of two different Burkholderia species. Applications of the methodologies reported can expand our understanding of the products and regulation of cryptic BGCs across phylogenetically diverse bacteria.
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