A patchwork pathway of apparently recent origin enables degradation of the synthetic buffer compound TRIS in bacteria

Abstract

AbstractThe widely used synthetic buffer compound TRIS was long considered to be biologically inert. Herein, we describe the discovery of a complete bacterial degradation pathway for TRIS. By serendipity, aPseudomonasstrain was isolated from sewage sludge that was able to grow with TRIS as only carbon and nitrogen source. Genome and transcriptome analyses revealed two adjacent gene clusters embedded in a mobile genetic element on a conjugative plasmid to be involved in TRIS degradation. Conjugational transfer of this plasmid intoP. putidaKT2440 enabled this strain to grow with TRIS, demonstrating that the complete TRIS degradation pathway can be transmitted by horizontal gene transfer. Heterologous gene expression revealed cluster I to encode a TRIS uptake protein, a TRIS alcohol dehydrogenase, and a TRIS aldehyde dehydrogenase, catalyzing the oxidation of TRIS into 2-hydroxymethylserine. Gene cluster II encodes a methylserine hydroxymethyltransferase and a D-serine dehydratase which plausibly catalyze the conversion of 2-hydroxymethylserine into pyruvate. Subsequent enrichments from wastewater purification systems led to the isolation of further TRIS-degrading bacteria from thePseudomonasandShinellagenera carrying highly similar TRIS degradation gene clusters.Our data indicate that TRIS degradation evolved recently via gene recruitment and enzyme adaptation from multiple independent metabolic pathways and database searches suggest that the TRIS degradation pathway is now globally distributed. Our study illustrates how engineered environments can enhance the emergence of new microbial metabolic pathways in short evolutionary time scales. This knowledge is valuable for developing new water purification processes in times of increasing water scarcity.