33 mM As(III) in presence of 0.1 g L-1 yeast extract, but this positive effect was no longer detected in presence of 0.2 g L-1 yeast extract. The ability of T. arsenivorans to grow autotrophically using As(III) as the sole energy source was confirmed by the observation of increasing quantities of carbon fixed as more As(III) was oxidised
(Figure. 2). This demonstrated that T. arsenivorans was able to use energy gained from the oxidation of As(III) to fix inorganic carbon. In contrast, strain 3As was unable to fix inorganic carbon under the same conditions (in MCSM), as 1.33 mM As(III) was found to inhibit growth in presence of 0.1 or 0.2 g L-1 yeast extract (Table 1), and this strain was unable to grow in presence of As(III) as the sole energy source. Figure 2 Carbon fixed as a product of
As(III) oxidised by T. arsenivorans. Error bars, where visible, show Screening Library standard deviation; n = 3 for each data point. Figure 2 shows an STA-9090 cell line essentially HDAC inhibitor linear relationship between carbon fixed and arsenic oxidised, corresponding to 3.9 mg C fixed for 1 g of As(III) oxidised, i.e. 0.293 mg C fixed mM-1 As(III). It requires 40 J to produce 1 mg of organic carbon cellular material from CO2 [26]. The energy produced from the oxidation of As(III) with O2 is 189 J mMol-1 [27]. As a consequence, if 100% of this energy was used for carbon fixation, 4.73 mg C would be fixed for 1 mM As(III) oxidised. Thus, in this experiment, 6% of the energy available from arsenic oxidation was used for carbon fixation. This result is in accordance with the 5 to 10% range of efficiency
for carbon fixation by various autotrophic bacteria [26]. Enzymes involved in carbon metabolism and energy acquisition are expressed differently in T. arsenivorans and 3As in response to arsenic Protein profiles expressed in MCSM or m126 media, in the presence and absence of arsenic were compared in each strain (Figure. 3, Table 2 and see Additional file1). In both strains, arsenic-specific enzymes (ArsA2 in T. arsenivorans, ArsC1 in 3As) were more abundant in the presence of As(III), suggesting that a typical arsenic-specific Ribose-5-phosphate isomerase response occurred in both strains. ArsA2 is part of the efflux pump with ArsB2 and is encoded by the ars2 operon. Moreover, expression of a putative oxidoreductase (THI3148-like protein) was induced in the presence of arsenic. This protein is conserved in At. caldus, with 90% amino-acid identity (Arsène-Ploetze & Bertin, unpublished). The At. caldus gene encoding this THI3148-like protein is embedded within an ars operon. This protein is also conserved in more than 56 other bacteria, for example in Mycobacterium abscessus (51% identity) and Lactobacillus plantarum (48% identity). In these two cases the corresponding gene was also found in the vicinity of ars genes. Table 2 Arsenic-induced or repressed proteins in T. arsenivorans and Thiomonas sp. 3As. Functional class Metabolic pathway Gene Protein Induction/repression by Asa T.