Abstract
Hexavalent chromium [Cr(VI)] is one of the common heavy-metal contaminants in groundwater, and the availability of electron donors is considered to be a key parameter for Cr(VI) biotransformation. During the autotrophic remediation process, however, much remains to be illuminated about how complex syntrophic microbial communities couple Cr(VI) reduction with other elemental cycles. Two series of Cr(VI)-reducing groundwater bioreactors were independently amended by elemental sulfur and iron and inoculated with the same inoculum. After 160 days of incubation, both bioreactors showed similar archaea-dominating microbiota compositions, whereas a higher Cr(VI)-reducing rate and more methane production were detected in the Fe0-driven one. Metabolic reconstruction of 23 retrieved genomes revealed complex symbiotic relationships driving distinct elemental cycles coupled with Cr(VI) reduction in bioreactors. In both bioreactors, these Cr(VI) reducers were assumed to live in syntrophy with oxidizers of sulfur, iron, hydrogen, and volatile fatty acids and methane produced by carbon fixers and multitrophic methanogens, respectively. The significant difference in methane production was mainly due to the fact that the yielded sulfate greatly retarded acetoclastic methanogenesis in the S-bioreactor. These findings provide insights into mutualistic symbioses of carbon, sulfur, iron, and chromium metabolisms in groundwater systems and have implications for bioremediation of Cr(VI)-contaminated groundwater.
Highlights
Hexavalent chromium [Cr(VI)] is one of ubiquitous heavy-metal contaminants in groundwater, and electron donors are considered to be a key parameter for Cr(VI) biotransformation
Two types of electron donors, S0 and Fe0 were used for microbially-mediated chromate reduction
Results revealed that the Cr(VI) concentration in both bioreactors decreased significantly and remained stable for each cycle, the steady-state biogeochemical process was achieved in these reactors after 160 days incubation (Figure S1)
Summary
Hexavalent chromium [Cr(VI)] is one of ubiquitous heavy-metal contaminants in groundwater, and electron donors are considered to be a key parameter for Cr(VI) biotransformation. For microbial Cr(VI) reduction, various electron donors (e.g., organic substrates, H2, CH4, S0, and Fe0) have been utilized, and satisfactory Cr(VI) removal performance has been achieved in these bioreactors treating Cr(VI)-contaminated groundwater [10, 11]. Previous studies have revealed a number of aerobic and anaerobic microorganisms capable of direct Cr(VI) reduction in nature, such as Pseudomonas putida MK1, Desulfovibrio vulgaris, Arthrobacter aurescens, and Geobacter sulfurreducens [7, 15, 16]. These organisms usually harbor soluble and/or membrane-associated Cr(VI) reductases (such as ChrR, NemA, NfsA, cytochromes) [1, 8]. The majority of studies regarding Cr(VI) bio-reduction have focused on the kinetics and metabolic potential of some specific microbes [12, 18,19,20], whereas few attempts have been made to clarify the mechanism of community assembly and functional roles of indigenous microorganisms in Cr(VI)-contaminated natural and artificial groundwater systems
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