In addition, two flavin-binding monooxygenases were found to be upregulated during growth on alkanes indicative of two novel pathways likely to be involved in alkane degradation by A. borkumensis (ABO_0282, ABO_1097, Table 1). PD0332991 cost Moreover, we detected the up-expression of two genes similar to the ones involved in the degradation of halogenated alkanes in other bacteria, namely haloacid dehalogenase-like hydrolase dhlA (ABO_1537, Table 1) and haloalkane dehalogenase dhmA (ABO_2415,

Table 1). If the first enzyme is known to convert haloalkanes to corresponding alcohols and halides, the second one catalyzes hydrolytic cleavage of carbon-halogen bonds in halogenated aliphatic compounds, leading to the formation of primary alcohols, halide ions, and protons. Alkane-induced coexpression of these enzymes mediating the breakdown of haloalkanes, alongside the induction of enzymes degrading aliphatic alkanes, signifies unspecific upregulation of expression, probably reflecting the presence of halogenated alkanes in sea water. Additionally, we found alkane-induced

expression of aldehyde reductase (ABO_2414, Table 1). This gene is predicted to be involved in the metabolic activation of polycyclic aromatic hydrocarbons (PAHs), as shown recently for human aldehyde reductase AKR1A1 (Palackal et al., 2001). However, as yet, A. borkumensis has not been shown to either degrade or transform PAHs, and thus requires further experimentation to explore what coexpression INCB018424 chemical structure of this gene alongside those mediating the degradation of aliphatic alkanes may signify for the degradation of alkanes or petroleum. These data allow us to update the list of enzymatic systems shown before by our proteomic study to be potentially involved in the initial terminal oxidation of alkanes by A. borkumensis (Figs 1 and 2). Attachment of A. borkumensis to hydrocarbons and its molecular mechanisms have not yet been studied, although such abilities are likely to form part of the specific ecological adaptation of this bacterium. EM observation of Alcanivorax SK2 indeed indicates that this organism forms biofilm-supporting structures during growth on alkanes (Fig.

selleck chemicals 3). Cells grown on alkane seem to more connect to each other rather than to the solid surface of the carrier slide, and they are shorter and rounder, and produce considerable amount of extracellular polymeric substances (EPS), which appears to support the three-dimensional structure of a biofilm. After 10 days of growth, alkane-grown cells develop a biofilm, which exhibits a pronounced three-dimensional architecture supported by extracellular matrix (Fig. 3). The argument of an alkane-induced formation of EPS is supported by alkane-induced up-expression of gmhA (ABO_0584). GmhA encodes a phosphoheptose isomerases that mediates the synthesis of heptose, a conserved component of outer membrane lipopolysaccharide, that for example in Yersinia, was shown to contribute to the formation of biofilms (Darby et al., 2005).