Abstract
Bacteria produce diverse specialized metabolites that mediate ecological interactions and serve as a rich source of industrially relevant natural products. Biosynthetic pathways for these metabolites are encoded by organized groups of genes called biosynthetic gene clusters (BGCs). Understanding the natural function and distribution of BGCs provides insight into the mechanisms through which microorganisms interact and compete. Further, understanding BGCs is extremely important for biocontrol and the mining of new bioactivities. Here, we investigated phage-encoded BGCs (pBGCs), challenging the relationship between phage origin and BGC structure and function. The results demonstrated that pBGCs are rare, and they predominantly reside within temperate phages infecting commensal or pathogenic bacterial hosts. Further, the vast majority of pBGCs were found to encode for bacteriocins. Using the soil- and gut-associated bacterium Bacillus subtilis, we experimentally demonstrated how a temperate phage equips a bacterium with a fully functional BGC, providing a clear competitive fitness advantage over the ancestor. Moreover, we demonstrated a similar transfer of the same phage in prophage form. Finally, using genetic and genomic comparisons, a strong association between pBGC type and phage host range was revealed. These findings suggest that bacteriocins are encoded in temperate phages of a few commensal bacterial genera. In these cases, lysogenic conversion provides an evolutionary benefit to the infected host and, hence, to the phage itself. This study is an important step toward understanding the natural role of bacterial compounds encoded by BGCs, the mechanisms driving their horizontal transfer, and the sometimes mutualistic relationship between bacteria and temperate phages.
Highlights
Alongside molecules that are directly involved in basic metabolism, microbes produce a plethora of specialized compounds, or metabolites
Bacteriocins are recognized for their role in interbacterial competition[9] and their biosynthetic gene clusters (BGCs) are smaller than PKS and non-ribosomal peptide synthetases (NRPSs) BGCs
BGCs are extremely rare within virion-derived genomes To assess the contribution of phages to the genetic pool of microbial specialized metabolites, we addressed the following fundamental question: can BGCs that encode for specialized metabolites be found in phage genomes? To this end, all complete phage genomes that were available in the PATRIC 3.6.2 database (10,063 in total) were subjected to BGC detection using antiSMASH 4
Summary
Alongside molecules that are directly involved in basic metabolism, microbes produce a plethora of specialized compounds, or metabolites. These specialized metabolites mediate microbial ecological interactions, and supply medical[1] and biotechnological industries[2] with novel biological activities. Despite a longstanding tradition of industrial exploitation, the natural role of most specialized metabolites remains largely unknown.[3] there is evidence that some of these metabolites act as chemical weapons in competitive interactions.[4,5]. BGCs encode polyketide synthases (PKS BGCs) and non-ribosomal peptide synthetases (NRPSs), which are extremely large (10–100 kb), multi-enzyme complexes that synthesize peptides with antibiotic properties and signaling, immunosuppressive, and biosurfactant activities.[7,8] Ribosomal peptide natural products (RPNPs or RiPPs) are mostly represented by bacteriocins. Bacteriocins are recognized for their role in interbacterial competition[9] and their BGCs are smaller than PKS and NRPS BGCs
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