Genetic dissection of chlorate respiration in P seudomonas stutzeri PDA reveals syntrophic (per)chlorate reduction

Summary Genes important for growth of P seudomonas stutzeri   PDA on chlorate were identified using a randomly DNA bar‐coded transposon mutant library. During chlorate reduction, mutations in genes encoding the chlorate reductase clrABC , predicted molybdopterin cofactor chaperon clrD , molybdopterin biosynthesis and two genes of unknown function ( clrE , clrF ) had fitness defects in pooled mutant assays (Bar‐seq). Markerless in‐frame deletions confirmed that clrA, clrB and clrC were essential for chlorate reduction, while clrD , clrE and clrF had less severe growth defects. Interestingly, the key detoxification gene cld was essential for chlorate reduction in isogenic pure culture experiments, but showed only minor fitness defects in Bar‐seq experiments. We hypothesized this was enabled through chlorite dismutation by the community, as most strains in the Bar‐seq library contained an intact cld . In support of this, Δ cld grew with wild‐type PDA or Δ clrA , and purified Cld also restored growth to the Δ cld mutant. Expanding on this, wild‐type PDA and a Δ cld mutant of the perchlorate reducer A zospira suillum   PS grew on perchlorate in co‐culture, but not individually. These results demonstrate that co‐occurrence of cld and a chloroxyanion reductase within a single organism is not necessary and raises the possibility of syntrophic (per)chlorate respiration in the environment.