A novel Thermotoga strain TFO isolated from a Californian petroleum reservoir phylogenetically related to Thermotoga petrophila and T. naphthophila, two thermophilic anaerobic isolates from a Japanese reservoir: Taxonomic and genomic considerations.

Hot oil reservoirs harbor diverse microbial communities, with many of them inhabiting thermophilic or hyperthermophilic fermentative Thermotogae species. A new Thermotoga sp. strain TFO was isolated from an Californian offshore oil reservoir which is phylogenetically related to thermophilic species T. petrophila RKU-1T and T. naphthophila RKU-10T, isolated from the Kubiki oil reservoir in Japan. The average nucleotide identity and DNA-DNA hybridization measures provide evidence that the novel strain TFO is closely related to T. naphthophila RKU-10T, T. petrophila RKU-1T and can not be differentiated at the species level. In the light of these results, the reclassification of T. naphthophila RKU-10 and strain TFO as heterotypic synonyms of T. petrophila is proposed. A pangenomic survey of closely related species revealed 55 TFO strain-specific proteins, many of which being linked to glycosyltransferases and mobile genetic elements such as recombinases, transposases and prophage, which can contribute to genome evolution and plasticity, promoting bacterial diversification and adaptation to environmental changes. The discovery of a TFO-specific transport system dctPQM, encoding a tripartite ATP-independent periplasmic transporter (TRAP), has to be highlighted. The presence of this TRAP system assumes that it could assist in anaerobic n-alkane degradation by addition of fumarate dicarboxylic acid, suggesting a niche-specific gene pool which correlates with the oil reservoir that T. petrophila TFO inhabits. Finally, T. naphthophila RKU-10, T. petrophila RKU-1T, T. petrophila TFO form a distinct phylogenetic lineage with different geographic origins, share the same type of ecological niche including the burial history of fields. Theses findings might support the indigenous character of this species in oil reservoirs.

Quantification of Desulfovibrio vulgaris dissimilatory sulfite reductase gene expression during electron donor- and electron acceptor-limited growth.

Previous studies have suggested that levels of transcripts for dsrA, a gene encoding a subunit of the dissimilatory sulfite reductase, are not directly related to the rates of sulfate reduction in sediments under all conditions. This phenomenon was further investigated with chemostat-grown Desulfovibrio vulgaris. Under sulfate-limiting conditions, dsrA transcript levels increased as the bulk rates of sulfate reduction in the chemostat increased, but transcript levels were similar at all sulfate reduction rates under electron donor-limiting conditions. When both electron donor- and electron acceptor-limiting conditions were considered, there was a direct correspondence between dsrA transcript levels and the rates of sulfate reduction per cell. These results suggest that dsrA transcript levels may provide important information on the metabolic state of sulfate reducers.