Project Details
Characterisation of microbial dehalogenation using compound specific stable isotope analysis
Applicant
Dr. Ivonne Nijenhuis
Subject Area
Metabolism, Biochemistry and Genetics of Microorganisms
Term
from 2011 to 2018
Project identifier
Deutsche Forschungsgemeinschaft (DFG) - Project number 171475307
Although organohalide respiration has been investigated over the last few decades, it is still unclear which reaction mechanisms are involved. Although similar pathways and enzymes are thought to be involved in different organohalide respireres, our recent research comparing the reductive dechlorination of chlorinated ethenes in a variety of microbial strains showed a high variability in apparent kinetic carbon isotope fractionation. The variability of apparent kinetic isotope effects gives rise to the hypothesis that pathways and mechanisms of dehalogenation reactions are slightly different and a systematic study comparing the enzymatic inventory and fractionation factors is needed for a better understanding of the dehalogenation process. Therefore, the main aim of this project is the characterization of the reaction mechanism of reductive dehalogenation using chlorine and carbon isotope fractionation patterns and hydrogen solvent kinetic effects. In this proposal, Dehalococcoides spp., possessing different enzymes capable of dehalogenating a wide variety of substrates, will be used as one of the model systems to investigate the variability of reductive dehalogenases related to the isotope fractionation pattern. The described Dehalococcoides sp. strains 195 and CBDB1 will be used and compared to other organohalide respiring strains such as Sulfurospirillum, Desulfitobacterium or Dehalobacter as well as to our highly enriched Dehalococcoides culture BTF08 derived from Bitterfeld groundwater. Isotope fractionation patterns using multi-isotope analysis including Cl and H isotopes should allow the characterisation of the reaction mechanism as previously done for BTEX and MTBE in our research group.
DFG Programme
Research Units