Fe(III) reduction was monitored by measuring the increase in 0.5 N HCl-extractable Fe(II) over time using a ferrozine assay (Stookey, 1970). Mineral products of Fe(III) reduction were analysed using X-ray powder diffraction (XRD) obtained with a Bruker D8Advance instrument using Cu Kα1 radiation. In incubation experiments exploring the
biogeochemistry of sediments representative of the Sellafield site, the pH rose from 6.8 to c. 9.3 during reduction of 100 mM nitrate (in the presence of added acetate) and Fe(III) reduction was observed to follow (Fig. 1a). Subaliquots from these sediment incubations added to acetate-amended, Fe(III)-citrate medium were enriched further for the Fe(III)-reducing microbial community MK-2206 manufacturer and continued Alectinib cost to support stable Fe(III) reduction at pH > 9 (Fig. 1b). RISA results illustrate that the microbial community became less diverse as the subculture was transferred to fresh medium every c. 6 weeks (10 % inoculum) (Fig. 2). After seven transfers, 16S rRNA gene analysis identified a mixed culture, with 41 % of the clone library comprising genes most closely related (99 % identical) to the known alkaliphilic bacterium Alkaliphilus cronotoxidens and 56 % most closely related (99 % identical) to
S. liquefaciens CIP 103238T, with other species making up < 3 % of the clone library (Table 1). However,
after 10 transfers, the community was much less diverse, and by plating out onto LB agar plates, an axenic culture that was shown to reduce Fe(III) at pH c. 9.0 was obtained (Fig. 1c). RISA analysis confirmed that this isolated species was the organism that dominated the mixed culture at subculture 10, and 16S rRNA gene sequence confirmed that this was the Serratia species identified previously (Fig. 2). The phylogenetic placement of this organism compared with other Fe(III)-reducing bacteria is medroxyprogesterone shown in Fig. 3. It is interesting that despite the consistently high pH in these subcultures, and the presence of a close relative to a known alkaliphile, the Serratia species was shown to predominate in these systems. In a previous study at an acidic rock drainage site, a Serratia species was isolated and shown to respire using Fe(III) (‘Serratia Adams et al., 2007’ on Fig. 3) and was characterized as acidotolerant with an optimum growth pH of 6.5 (Adams et al., 2007). In addition to aerobic growth on LB medium, the Serratia species was found to be capable of utilizing a variety of electron acceptors under anaerobic conditions: , Fe(III)-NTA, Fe(III)-citrate and Fe(III)-oxyhydroxide (ferrihydrite), although only minimal reduction of ferrihydrite (< 10%) was observed (data not shown).