Publication Details

Reference Category Journals
DOI / URL link
Title (Primary) Molecular characterization of bacterial communities mineralizing benzene under sulfate-reducing conditions
Author Kleinsteuber, S.; Schleinitz, K.M.; Breitfeld, J.; Harms, H.; Richnow, H.H.; Vogt, C.
Journal FEMS Microbiology Ecology
Year 2008
Department ISOBIO; UMB
Volume 66
Issue 1
Page From 143
Page To 157
Language englisch
Keywords natural attenuation; benzene; anaerobic degradation; syntrophy; Desulfotomaculum subcluster Ih
Abstract The microbial communities of in situ reactor columns degrading benzene with sulfate as an electron acceptor were analyzed based on clone libraries and terminal restriction fragment length polymorphism fingerprinting of PCR-amplified 16S rRNA genes. The columns were filled with either lava granules or sand particles and percolated with groundwater from a benzene-contaminated aquifer. The predominant organisms colonizing the lava granules were related to Magnetobacterium sp., followed by a phylotype affiliated to the genera Cryptanaerobacter/Pelotomaculum and several Deltaproteobacteria. From the sand-filled columns, a stable benzene-degrading consortium was established in sand-filled laboratory microcosms under sulfate-reducing conditions. It was composed of Delta- and Epsilonproteobacteria, Clostridia, Chloroflexi, Actinobacteria and Bacteroidetes. The most prominent phylotype of the consortium was related to the genus Sulfurovum, followed by Desulfovibrio sp. and the Cryptanaerobacter/Pelotomaculum phylotype. The proportion of the latter was similar in both communities and significantly increased after repeated benzene-spiking. During cultivation on aromatic substrates other than benzene, the Cryptanaerobacter/Pelotomaculum phylotype was outcompeted by other community members. Hence, this organism appears to be specific for benzene as a growth substrate and might play a key role in benzene degradation in both communities. Based on the possible functions of the community members and thermodynamic calculations, a functional model for syntrophic benzene degradation under sulfate-reducing conditions is proposed.
Persistent UFZ Identifier
Kleinsteuber, S., Schleinitz, K.M., Breitfeld, J., Harms, H., Richnow, H.H., Vogt, C. (2008):
Molecular characterization of bacterial communities mineralizing benzene under sulfate-reducing conditions
FEMS Microbiol. Ecol. 66 (1), 143 - 157