ABSTRACT
The disconnect between the genomic prediction of secondary metabolite biosynthetic potential and the observed laboratory production profile of microorganisms is well documented. While heterologous expression of biosynthetic gene clusters (BGCs) is often seen as a potential solution to bridge this gap, it is not immune to many challenges including impaired regulation, the inability to recruit essential building blocks, and transcriptional and/or translational silence of the biosynthetic genes. Here we report the discovery, cloning, refactoring, and heterologous expression of a cryptic hybrid phenazine-type BGC (spz) from the marine actinomycete Streptomyces sp. CNB-091. Overexpression of the engineered spz pathway resulted in increased production and chemical diversity of phenazine natural products belonging to the streptophenazine family, including bioactive members containing an unprecedented N-formylglycine attachment. An atypical discrete adenylation enzyme in the spz cluster is required to introduce the formylglycine moiety and represents a phylogenetically distinct class of adenylation proteins.
Subject(s)
Bacterial Proteins/metabolism , Peptide Synthases/metabolism , Phenazines/metabolism , Polyketides/metabolism , Bacterial Proteins/classification , Bacterial Proteins/genetics , Chromatography, High Pressure Liquid , Mass Spectrometry , Multigene Family , Peptide Synthases/classification , Peptide Synthases/genetics , Phenazines/chemistry , Phylogeny , Polyketides/chemistry , Streptomyces/geneticsABSTRACT
Recent genome sequencing efforts have led to the rapid accumulation of uncharacterized or "orphaned" secondary metabolic biosynthesis gene clusters (BGCs) in public databases. This increase in DNA-sequenced big data has given rise to significant challenges in the applied field of natural product genome mining, including (i) how to prioritize the characterization of orphan BGCs and (ii) how to rapidly connect genes to biosynthesized small molecules. Here, we show that by correlating putative antibiotic resistance genes that encode target-modified proteins with orphan BGCs, we predict the biological function of pathway specific small molecules before they have been revealed in a process we call target-directed genome mining. By querying the pan-genome of 86 Salinispora bacterial genomes for duplicated house-keeping genes colocalized with natural product BGCs, we prioritized an orphan polyketide synthase-nonribosomal peptide synthetase hybrid BGC (tlm) with a putative fatty acid synthase resistance gene. We employed a new synthetic double-stranded DNA-mediated cloning strategy based on transformation-associated recombination to efficiently capture tlm and the related ttm BGCs directly from genomic DNA and to heterologously express them in Streptomyces hosts. We show the production of a group of unusual thiotetronic acid natural products, including the well-known fatty acid synthase inhibitor thiolactomycin that was first described over 30 years ago, yet never at the genetic level in regards to biosynthesis and autoresistance. This finding not only validates the target-directed genome mining strategy for the discovery of antibiotic producing gene clusters without a priori knowledge of the molecule synthesized but also paves the way for the investigation of novel enzymology involved in thiotetronic acid natural product biosynthesis.
Subject(s)
Biosynthetic Pathways/genetics , Genome, Bacterial , Anti-Bacterial Agents/chemistry , Anti-Bacterial Agents/metabolism , Anti-Bacterial Agents/pharmacology , Computational Biology , Gene Targeting , Hydroxybutyrates/chemistry , Hydroxybutyrates/metabolism , Hydroxybutyrates/pharmacology , Molecular Structure , Multigene Family , Streptomyces/drug effects , Streptomyces/genetics , Streptomyces/physiology , Sulfhydryl Compounds/chemistry , Sulfhydryl Compounds/metabolism , Sulfhydryl Compounds/pharmacology , Thiophenes/chemistry , Thiophenes/pharmacologySubject(s)
Bacteria/genetics , Computational Biology/standards , Fungi/genetics , Multigene Family , Plants/genetics , Protein Biosynthesis , Alkaloids/biosynthesis , Bacteria/metabolism , Databases, Genetic , Fungi/metabolism , Genetic Markers , International Cooperation , Metagenome , Peptide Biosynthesis, Nucleic Acid-Independent , Peptides/metabolism , Plants/metabolism , Polyketides/metabolism , Polysaccharides/biosynthesis , Terminology as Topic , Terpenes/metabolismABSTRACT
The marine alkaloid chlorizidine A contains chlorinated pyrroloisoindolone and pyrrolizine rings that are rare chemical features in bacterial natural products. Herein, we report the biosynthetic logic of their construction in Streptomyces sp. CNH-287 based on the identification of the chlorizidine A biosynthetic gene cluster. Using whole pathway heterologous expression and genetic manipulations, we show that chlorizidine A is assembled by a polyketide synthase that uniquely incorporates a fatty acid synthase-derived dichloropyrrolyl extender unit into the pyrroloisoindolone enzymatic product. We further provide the first biochemical characterization of a flavoenzyme associated with the oxidative formation of chlorizidine A's distinctive pyrrolizine ring. This work illuminates new enzymatic assembly line processes leading to rare nitrogen-containing rings in nature.
