Hybridization of the CIArray with DNA from the 14C-phenol-amended

Hybridization of the CIArray with DNA from the 14C-phenol-amended sample indicated that bacteria assimilating 14C-atoms, presumably directly from phenol, under nitrate-reducing conditions were abundant in the reactor, and taxonomic assignment of the fosmid clone end sequences suggested that they belonged to the Gammaproteobacteria. The specificity Olaparib order of the CIArray was validated by quantification of fosmid-clone-specific DNA in density-resolved DNA fractions from samples incubated with 13C-phenol, which verified that all CIArray-positive probes stemmed

from microorganisms that assimilated isotopically labeled carbon. This also demonstrated that the CIArray was more sensitive than DNA-SIP, as the former enabled positive detection at a phenol concentration that failed to yield a ‘heavy’ DNA fraction. Finally, two operational taxonomic units distantly

related to marine Gammaproteobacteria were identified to account for more than half of 16S rRNA gene clones in the ‘heavy’ DNA library, corroborating the CIArray-based identification. “
“The marine oil-degrading bacterium Alcanivorax borkumensis SK2 has attracted significant interest Volasertib purchase due to its hydrocarbonoclastic lifestyle, its alkane-centered metabolism, and for playing an important ecological role in cleaning up marine oil spills. In this study, we used microarray technology to characterize the transcriptional

responses of A. borkumensis to n-hexadecane exposure as opposed to pyruvate, which led to the identification of a total of 220 differentially expressed genes, with 109 genes being upregulated and 111 genes being downregulated. Among the genes upregulated on alkanes are systems predicted to be involved in the terminal oxidation of alkanes, biofilm formation, Dapagliflozin signal transduction, and regulation. Marine oil-degrading bacteria play an essential role in degrading crude oil and thus in cleaning up marine oil spills (Yakimov et al., 2007). Alcanivorax borkumensis has become a paradigm of marine ‘hydrocarbonoclastic’ bacteria, as it exclusively grows on alkanes and plays a predominant ecological role in oil-degrading consortia that form following marine oil spills (McKew et al., 2007; Gertler et al., 2009). Alcanivorax borkumensis SK2 metabolizes a wide range of alkanes, such as linear alkanes, cyclo-alkanes, and isoprenoids (Dutta & Harayama, 2001; McKew et al., 2007). Given its important ecological role in the removal of oil spills and with the availability of its full genome sequence (Schneiker et al., 2006), Alcanivorax may now serve as a model organism to understand bacterial alkane metabolism.

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