6533b871fe1ef96bd12d1af4
RESEARCH PRODUCT
Combined metabolic activity within an atrazine-mineralizing community enriched from agrochemical factory soil
Dubravka HršakAna Begonja KolarInes PetrićFabrice Martin-laurentNikolina Udiković KolićGuy SoulasSanja Stipičevićsubject
ATRAZINE[SDV]Life Sciences [q-bio]BIODEGRADATION010501 environmental sciences01 natural sciencesMicrobiologyMicrobiologyARTHROBACTERBiomaterials03 medical and health scienceschemistry.chemical_compoundOchrobactrumTRZAtrazineWaste Management and DisposalGene0105 earth and related environmental sciencesOCHROBACTRUM2. Zero hunger0303 health sciencesbiology030306 microbiologyMICROBIAL COMMUNITYPseudomonasMineralization (soil science)Biodegradation16S ribosomal RNAbiology.organism_classificationatrazine; biodegradation; atz; trz; microbial communityMicrobial population biologychemistry[SDE]Environmental SciencesATZdescription
Abstract The main objective of this work was to characterize an atrazine-mineralizing community originating from agrochemical factory soil, especially to elucidate the catabolic pathway and individual metabolic and genetic potentials of culturable members. A stable four-member bacterial community, characterized by colony morphology and 16S rDNA sequencing, was rapidly able to mineralize atrazine to CO 2 and NH 3 . Two primary organisms were identified as Arthrobacter species (ATZ1 and ATZ2) and two secondary organisms (CA1 and CA2) belonged to the genera Ochrobactrum and Pseudomonas, respectively. PCR assessment of atrazine-degrading genetic potential of the community, revealed the presence of trzN, trzD, atzB and atzC genes. Isolates ATZ1 and ATZ2 were capable of dechlorinating atrazine to hydroxyatrazine and contained the trzN gene. ATZ2 further degraded hydroxyatrazine to cyanuric acid and contained atzB and atzC genes whereas ATZ1 contained atzC but not atzB. Isolates CA1 and CA2 grew on cyanuric acid and contained the trzD gene. Complete atrazine degradation was a result of the combined metabolic attack on the atrazine molecule, and complex interactions may exist between the community members sharing carbon and nitrogen from atrazine mineralization. Scientific relevance: Despite numerous reports on atrazine degradation by pure bacterial cultures, the pathways and the atrazine-degrading gene combinations harboured by bacterial communities are only poorly described. In this work, we characterized a four-member atrazine-mineralizing community enriched from an agrochemical factory soil, which was capable of rapidly metabolizing atrazine to CO 2 . This study will contribute towards better understanding of the genetic potential and metabolic activities of atrazine-degrading communities, which are generally considered to be responsible for atrazine mineralization in the natural environment.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2007-01-01 |