Complex evolutionary dynamics govern the diversity and distribution of biosynthetic gene clusters and their encoded specialized metabolites

While specialized metabolites are thought to mediate ecological interactions, the evolutionary processes driving their distributions, particularly among closely related lineages, remain poorly understood. Here, we examine the evolutionary dynamics governing the diversity and distribution of biosynthetic gene clusters (BGCs) in 118 strains across nine described species within the marine actinomycete genus Salinispora. While previous evidence indicated that horizontal gene transfer largely contributed to BGC diversity, we find that a majority of BGCs in Salinispora genomes are maintained by processes of vertical descent. In particular, we identified species-specific signatures that were associated with both BGC distributions and the production of their encoded specialized metabolites. By analyzing nine experimentally characterized BGCs that range in conservation from species to genus specific, we find that the distribution of BGCs among Salinispora species is maintained by selection, while BGC diversification is constrained by recombination among closely related strains and strengthened by gain/loss events between species. Notably, the evolutionary processes driving BGC diversification had direct consequences for compound production, elucidating the mechanisms that lead to chemical diversification. These results support the concept that specialized metabolites, and their cognate BGCs, represent functional traits associated with ecological differentiation among Salinispora species.