51. Effect of uranium (VI) on two sulphate-reducing bacteria cultures from a uranium mine site
- Author
-
Maria Leonor Faleiro, Mónica Martins, Maria Clara Costa, Sandra Chaves, and Rogério Tenreiro
- Subjects
inorganic chemicals ,Bioaugmentation ,Environmental Engineering ,Rhodocyclaceae ,Molecular Sequence Data ,chemistry.chemical_element ,complex mixtures ,Mining ,Soil Pollutants, Radioactive ,Environmental Chemistry ,Desulfovibrio vulgaris ,Desulfovibrio desulfuricans ,Sulfate-reducing bacteria ,Waste Management and Disposal ,Phylogeny ,Soil Microbiology ,Bacteria ,Base Sequence ,biology ,Sulfates ,Ecology ,technology, industry, and agriculture ,Uranium ,biology.organism_classification ,16S ribosomal RNA ,Pollution ,Soil contamination ,Biodegradation, Environmental ,chemistry ,Genes, Bacterial ,Environmental chemistry ,Temperature gradient gel electrophoresis - Abstract
This work was conducted to assess the impact of uranium (VI) on sulphate-reducing bacteria (SRB) communities obtained from environmental samples collected on the Portuguese uranium mining area of Urgeiriça. Culture U was obtained from a sediment, while culture W was obtained from sludge from the wetland of that mine. Temperature gradient gel electrophoresis (TGGE) was used to monitor community changes under uranium stress conditions. TGGE profiles of dsrB gene fragment demonstrated that the initial cultures were composed of SRB species affiliated with Desulfovibrio desulfuricans, Desulfovibrio vulgaris and Desulfomicrobium spp. (sample U), and by species related to D. desulfuricans (sample W). A drastic change in SRB communities was observed as a result of uranium (VI) exposure. Surprisingly, SRB were not detected in the uranium removal communities. Such findings emphasize the need of monitoring the dominant populations during bio-removal studies. TGGE and phylogenetic analysis of the 16S rRNA gene fragment revealed that the uranium removal consortia are composed by strains affiliated to Clostridium genus, Caulobacteraceae and Rhodocyclaceae families. Therefore, these communities can be attractive candidates for environmental biotechnological applications associated to uranium removal.
- Published
- 2010