Abyssomicins—A 20-Year Retrospective View

Abyssomicins represent a new family of polycyclic macrolactones. The first described compounds of the abyssomicin family were abyssomicin B, C, atrop-C, and D, produced by the marine actinomycete strain Verrucosispora maris AB-18-032, which was isolated from a sediment collected in the Sea of Japan. Among the described abyssomicins, only abyssomicin C and atrop-abyssomicin C show a high antibiotic activity against Gram-positive bacteria, including multi-resistant and vancomycin-resistant strains. The inhibitory activity is caused by a selective inhibition of the enzyme 4-amino-4-deoxychorismate synthase, which catalyzes the transformation of chorismate to para-aminobenzoic acid, an intermediate in the folic acid pathway.

Unraveling the roles of the reductant and free copper ions in LPMO kinetics

Background Lytic polysaccharide monooxygenases (LPMOs) are monocopper enzymes that catalyze oxidative depolymerization of industrially relevant crystalline polysaccharides, such as cellulose, in a reaction that depends on an electron donor and O2 or H2O2. While it is well known that LPMOs can utilize a wide variety of electron donors, the variation in reported efficiencies of various LPMO-reductant combinations remains largely unexplained. Results In this study, we describe a novel two-domain cellulose-active family AA10 LPMO from a marine actinomycete, which we have used to look more closely at the effects of the reductant and copper ions on the LPMO reaction. Our results show that ascorbate-driven LPMO reactions are extremely sensitive to very low amounts (micromolar concentrations) of free copper because reduction of free Cu(II) ions by ascorbic acid leads to formation of H2O2, which speeds up the LPMO reaction. In contrast, the use of gallic acid yields steady reactions that are almost insensitive to the presence of free copper ions. Various experiments, including dose–response studies with the enzyme, showed that under typically used reaction conditions, the rate of the reaction is limited by LPMO-independent formation of H2O2 resulting from oxidation of the reductant. Conclusion The strong impact of low amounts of free copper on LPMO reactions with ascorbic acid and O2, i.e. the most commonly used conditions when assessing LPMO activity, likely explains reported variations in LPMO rates. The observed differences between ascorbic acid and gallic acid show a way of making LPMO reactions less copper-dependent and illustrate that reductant effects on LPMO action need to be interpreted with great caution. In clean reactions, with minimized generation of H2O2, the (O2-driven) LPMO reaction is exceedingly slow, compared to the much faster peroxygenase reaction that occurs when adding H2O2.

SECONDARY METABOLITES PRODUCED BY MARINE ACTINOMYCETE STREPTOMYCES SP. G246

In a recent study, we described two new lavandulylated flavonoids, along with eight known compounds from the culture broth of a Streptomyces sp. (strain G246), isolated from the sponge Halichondria panicea, collected in the sea of Son Tra peninsula (Da Nang). A comparison study was conducted to differentiate between solid and liquid fermentation technique for secondary metabolites production of strain G246. In this paper, we report the isolation and structural characterization of 9 secondary metabolites (1-9) from strain G246 by solid state fermentation. Compound 3 was the only one similarity between these fermentation techniques.

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

ABSTRACTWhile 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.GRAPHICAL ABSTRACT

Phylogenetic analysis of the salinipostin γ-butyrolactone gene cluster uncovers new potential for bacterial signaling-molecule diversity

Bacteria communicate by small-molecule chemicals that facilitate intra- and inter-species interactions. These extracellular signaling molecules mediate diverse processes including virulence, bioluminescence, biofilm formation, motility, and specialized metabolism. The signaling molecules produced by members of the phylum Actinobacteria are generally comprised of γ-butyrolactones, γ-butenolides, and furans. The best known actinomycete γ-butyrolactone is A-factor, which triggers specialized metabolism and morphological differentiation in the genus Streptomyces. Salinipostins A-K are unique γ-butyrolactone molecules with rare phosphotriester moieties that were recently characterized from the marine actinomycete genus Salinispora. The production of these compounds has been linked to the 9-gene biosynthetic gene cluster spt. Critical to salinipostin assembly is the γ-butyrolactone synthase encoded by spt9. Here, we report the global distribution of spt9 among sequenced bacterial genomes, revealing a surprising diversity of gene homologs across 12 bacterial phyla, the majority of which are not known to produce γ-butyrolactones. Further analyses uncovered a large group of spt-like gene clusters outside of the genus Salinispora, suggesting the production of new salinipostin-like diversity. These gene clusters show evidence of horizontal transfer between many bacterial taxa and location specific homologous recombination exchange among Salinispora strains. The results suggest that γ-butyrolactone production may be more widespread than previously recognized. The identification of new γ-butyrolactone biosynthetic gene clusters is the first step towards understanding the regulatory roles of the encoded small molecules in Actinobacteria.ImportanceSignaling molecules orchestrate a wide variety of bacterial behaviors. Among Actinobacteria, γ-butyrolactones mediate morphological changes and regulate specialized metabolism. Despite their importance, few γ-butyrolactones have been linked to their cognate biosynthetic gene clusters. A new series of γ-butyrolactones called the salinipostins was recently identified from the marine actinomycete genus Salinispora and linked to the spt biosynthetic gene cluster. Here we report the detection of spt-like gene clusters in diverse bacterial families not known for the production of this class of compounds. This finding expands the taxonomic range of bacteria that may employ this class of compounds and provides opportunities to discover new compounds associated with chemical communication.

Expansion of gamma-butyrolactone signaling molecule biosynthesis to phosphotriester natural products

Bacterial hormones, such as the iconic gamma-butyrolactone A-factor, are essential signaling molecules that regulate diverse physiological processes, including specialized metabolism. These low molecular weight compounds are common in Streptomyces species and display species-specific structural differences. Recently, unusual gamma-butyrolactone natural products called salinipostins were isolated from the marine actinomycete genus Salinispora based on their anti-malarial properties. As the salinipostins possess a rare phosphotriester motif of unknown biosynthetic origin, we set out to explore its construction by the widely conserved 9-gene spt operon in Salinispora species. We show through a series of in vivo and in vitro studies that the spt gene cluster dually encodes the saliniphostins and newly identified A-factor-like gamma-butyrolactones (Sal-GBLs). Remarkably, homologous biosynthetic gene clusters are widely distributed amongst many actinomycete genera, including Streptomyces, suggesting the significance of this operon in bacteria.