Biological attenuation of arsenic and iron in a continuous flow bioreactor treating acid mine drainage (AMD)

Abstract: Passive water treatments based on biological attenuation can be effective for arsenic-rich acid mine drainage (AMD). However, the key factors driving the biological processes involved in this attenuation are not well-known. Here, the efficiency of arsenic (As) removal was investigated in a bench-scale continuous flow channel bioreactor treating As-rich AMD (∼30-40 mg L). In this bioreactor, As removal proceeds via the formation of biogenic precipitates consisting of iron- and arsenic-rich mineral phases encrus… Show more

“…This might facilitate arsenic adsorption and/or co-precipitation. During Fe(II) oxidation, arsenic can also be co-precipitated with Fe(III), resulting in the formation of amorphous ferric arsenate (Fernandez-Rojo et al, 2017;Tian et al, 2017). In this study, although a large proportion of arsenic was co-precipitated during Fe(III) precipitation (Fig.…”

“…Previous reports show that arsenic is toxic to many microorganisms, which consequently affects the distribution of FeOB (Fernandez-Rojo et al, 2017). The cluster analysis showed that the structure of microbial community in the iron oxide layer was significantly affected by the presence of arsenic (Fig.…”

“…These microaerophilic FeOB precipitate biogenic Fe(III) oxyhydroxides at circumneutral pH in the form of twisted ribbon-like stalks, hollow tubular sheaths, and granular or amorphous structures that can adsorb and immobilize organics, arsenic, and other metals (Emerson et al, 2010;Muehe and Kappler, 2014). Although previous studies have shown that biogenic Fe(III) oxyhydroxides formed by FeOB play an important role in arsenic cycling (Hohmann et al, 2009;Xiu et al, 2016;Fernandez-Rojo et al, 2017;Sowers et al, 2017), few studies have explored microaerophilic microbial Fe(II) oxidation for the mechanisms by which arsenic is immobilized by biogenic Fe (III) oxyhydroxides formed from paddy soil microbes under micro-oxic conditions.…”

“…As(III) oxidation by microorganisms is usually catalyzed by As(III) oxidases, which are encoded by arsenite oxidase genes (aioA) (Slyemi and Bonnefoy, 2012). Recent studies have revealed the distribution of the diverse aioA in arsenic-contaminated soils and found that some FeOB encoded aioA are essential in As(III) oxidation (Fernandez-Rojo et al, 2017;Nitzsche et al, 2015;Zhang et al, 2015). Although arsenic is highly toxic to many microorganisms in paddy soils, some FeOB are able to metabolize arsenic for growth.…”

Biological Fe(II) and As(III) oxidation immobilizes arsenic in micro-oxic environments

“…This might facilitate arsenic adsorption and/or co-precipitation. During Fe(II) oxidation, arsenic can also be co-precipitated with Fe(III), resulting in the formation of amorphous ferric arsenate (Fernandez-Rojo et al, 2017;Tian et al, 2017). In this study, although a large proportion of arsenic was co-precipitated during Fe(III) precipitation (Fig.…”

“…Previous reports show that arsenic is toxic to many microorganisms, which consequently affects the distribution of FeOB (Fernandez-Rojo et al, 2017). The cluster analysis showed that the structure of microbial community in the iron oxide layer was significantly affected by the presence of arsenic (Fig.…”

“…These microaerophilic FeOB precipitate biogenic Fe(III) oxyhydroxides at circumneutral pH in the form of twisted ribbon-like stalks, hollow tubular sheaths, and granular or amorphous structures that can adsorb and immobilize organics, arsenic, and other metals (Emerson et al, 2010;Muehe and Kappler, 2014). Although previous studies have shown that biogenic Fe(III) oxyhydroxides formed by FeOB play an important role in arsenic cycling (Hohmann et al, 2009;Xiu et al, 2016;Fernandez-Rojo et al, 2017;Sowers et al, 2017), few studies have explored microaerophilic microbial Fe(II) oxidation for the mechanisms by which arsenic is immobilized by biogenic Fe (III) oxyhydroxides formed from paddy soil microbes under micro-oxic conditions.…”

“…As(III) oxidation by microorganisms is usually catalyzed by As(III) oxidases, which are encoded by arsenite oxidase genes (aioA) (Slyemi and Bonnefoy, 2012). Recent studies have revealed the distribution of the diverse aioA in arsenic-contaminated soils and found that some FeOB encoded aioA are essential in As(III) oxidation (Fernandez-Rojo et al, 2017;Nitzsche et al, 2015;Zhang et al, 2015). Although arsenic is highly toxic to many microorganisms in paddy soils, some FeOB are able to metabolize arsenic for growth.…”

Biological Fe(II) and As(III) oxidation immobilizes arsenic in micro-oxic environments

“…real-time PCR (qPCR), respectively from DNAs and cDNAs obtained from cultures of "T.arsenivorans" and H. arsenicoxydans. qPCR was carried out using m4-1F forward (GCCGGCGGGGGNTWYGARRAYA) and m2-1R reverse (GGAGTTGTAGGCGGGCCKRTTRTGDAT) primers, as designed in[30] and applied in[31]. The expected product size was 110 bp.…”

Simple or complex organic substrates inhibit arsenite oxidation and aioA gene expression in two β-Proteobacteria strains

A Comparison of Technologies for Remediation of Arsenic-Bearing Water: The Significance of Constructed Wetlands