Abstract
Thiocyanate (SCN(-)) contamination threatens aquatic ecosystems and pollutes vital freshwater supplies. SCN(-)-degrading microbial consortia are commercially adapted for remediation, but the impact of organic amendments on selection within SCN(-)-degrading microbial communities has not been investigated. Here, we tested whether specific strains capable of degrading SCN(-) could be reproducibly selected for based on SCN(-) loading and the presence or absence of added organic carbon. Complex microbial communities derived from those used to treat SCN(-)-contaminated water were exposed to systematically increased input SCN concentrations in molasses-amended and -unamended reactors and in reactors switched to unamended conditions after establishing the active SCN(-)-degrading consortium. Five experiments were conducted over 790 days, and genome-resolved metagenomics was used to resolve community composition at the strain level. A single Thiobacillus strain proliferated in all reactors at high loadings. Despite the presence of many Rhizobiales strains, a single Afipia variant dominated the molasses-free reactor at moderately high loadings. This strain is predicted to break down SCN(-) using a novel thiocyanate desulfurase, oxidize resulting reduced sulfur, degrade product cyanate to ammonia and CO(2) via cyanate hydratase, and fix CO(2) via the Calvin-Benson-Bassham cycle. Removal of molasses from input feed solutions reproducibly led to dominance of this strain. Although sustained by autotrophy, reactors without molasses did not stably degrade SCN(-) at high loading rates, perhaps due to loss of biofilm-associated niche diversity. Overall, convergence in environmental conditions led to convergence in the strain composition, although reactor history also impacted the trajectory of community compositional change.