All authors read and approved the final manuscript.”
“Background Species of Desulfitobacterium are Gram-positive, strictly anaerobic bacteria that belong to the Firmicutes, Clostridia, Clostridiales and Peptococcaceae. The genus is currently composed of six described species, D. metallireducens,
D. dichloroeliminans, D. dehalogenans, D. chlororespirans, D. aromaticivorans, and D. hafniense [1, 2]. Most of Desulfitobacterium Belnacasan species were isolated for their ability to reductively dehalogenate organic compounds which are, in some cases, highly resistant to aerobic biodegradation and toxic to bacteria [1]. Dehalorespiration, in which energy is acquired under anaerobic conditions by coupling of the reduction of halogenated organic compounds to
the oxidation of electron donors, has been intensively studied in Desulfitobacterium and Dehalococcoides Selumetinib concentration as potential bioremediation agents at contaminated sites [1, 3]. Desulfitobacterium is distinguished in its use of a broad range of electron acceptors (As(V), Fe(III), U (VI), Cr(VI), Se(VI), Mn(IV), S°, SO3 -2, S2O3 -2, NO3 -, CO2, fumarate, DMSO, and AQDS [1]) as well as electron donors (H2, formate, L-lactate, butyrate, butanol, crotonate, malate, pyruvate, and ethanol). D. aromaticivorans, a recently discovered iron reducer, can use aromatic Rucaparib purchase hydrocarbons including toluene, phenol, p-cresol, and o-xylene as carbon and energy sources [2]. Desulfitobacterium hafniense DCB-2 was first
isolated from a municipal sludge in Denmark based on its ability to dechlorinate halogenated phenols [4]. Its ability to use metal ions as electron acceptors was reported for Fe(III), Mn(IV), Se(VI), and As(V) [5, 6]. The strain also uses non-metal electron acceptors such as S°, SO3 -2, S2O3 -2, NO3 -, fumarate, isethionate, DMSO, 2,4,6-trichlorophenol, and other chlorinated phenols [4, 6, 7]. Nine strains have been identified to date that belong to D. hafniense species including D. hafniense Y51 which was isolated from a Japanese soil contaminated with tetrachloroethene [8], and for which the complete genome sequence was reported [1, 9]. Although D. hafniense strains DCB-2 and Y51 are very closely related (> 99% identity in 16S rRNA sequence) and share many common metabolic features, important differences exist in certain aspects of metabolism such as the presence of a respiratory nitrate reduction system in Y51, the potential substrate use of 4-hydroxy-2-oxovalerate by DCB-2, and the different dehalogenation capacities.