Identification of Mn(II)-Oxidizing Bacteria from a Low-pH Contaminated Former Uranium Mine

Akob, Denise M.; Bohu, Tsing; Beyer, Andréa; Schäffner, Franziska; Händel, Matthias; Johnson, Carol; Merten, D.; Büchel, Georg; Totsche, Kai Uwe; Küsel, Kirsten

doi:10.1128/aem.01296-14

Cited by 86 publications

(38 citation statements)

References 55 publications

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“…Whereas previous studies have demonstrated pH dependence of both fungal (Miyata et al ., ) and bacterial (Zhang et al ., ; Akob et al ., ) Mn(II) oxidation, our current study highlights the importance of the availability of carbon and other nutrients as important drivers of Mn(II) oxidation in environments such as caves. In addition, we show that microbial community composition and abundance can be intricately linked with the quality, quantity and form of the carbon input.…”

Section: Discussionmentioning

confidence: 68%

Nutrient input influences fungal community composition and size and can stimulate manganese (II) oxidation in caves

Carmichael

Zorn

Santelli

et al. 2015

Environ Microbiol Rep

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Little is known about the fungal role in biogeochemical cycling in oligotrophic ecosystems. This study compared fungal communities and assessed the role of exogenous carbon on microbial community structure and function in two southern Appalachian caves: an anthropogenically impacted cave and a near-pristine cave. Due to carbon input from shallow soils, the anthropogenically impacted cave had an order of magnitude greater fungal and bacterial quantitative-polymerase chain reaction (qPCR) gene copy numbers, had significantly greater community diversity, and was dominated by ascomycotal phylotypes common in early phase, labile organic matter decomposition. Fungal assemblages in the near-pristine cave samples were dominated by Basidiomycota typically found in deeper soils (and/or in late phase, recalcitrant organic matter decomposition), suggesting more oligotrophic conditions. In situ carbon and manganese (II) [Mn(II)] addition over 10 weeks resulted in growth of fungal mycelia followed by increased Mn(II) oxidation. A before/after comparison of the fungal communities indicated that this enrichment increased the quantity of fungal and bacterial cells, yet decreased overall fungal diversity. Anthropogenic carbon sources can therefore dramatically influence the diversity and quantity of fungi, impact microbial community function, and stimulate Mn(II) oxidation, resulting in a cascade of changes that can strongly influence nutrient and trace element biogeochemical cycles in karst aquifers.

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Section: Discussionmentioning

confidence: 68%

Nutrient input influences fungal community composition and size and can stimulate manganese (II) oxidation in caves

Carmichael

Zorn

Santelli

et al. 2015

Environ Microbiol Rep

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“…Natural attenuation of trace metal loads commonly occurs via a complex set of processes (Akob et al, 2014;Byrne et al, 2014;De Giudici et al, 2009, 2014Fuller and Bargar, 2014) Root growth enhances soil permeability with the development of a macropore system called rhizopores (Archer et al, 2013;Ghestem et al, 2011). As reviewed by Vergani and Graf (2015), the overall effect of plants on soil permeability depends on the soil type, the density of vegetation and the vegetation cover type.…”

Section: Vegetation Hydrology Hyporheic Zone and Biogeochemical Barmentioning

confidence: 99%

The role of natural biogeochemical barriers in limiting metal loading to a stream affected by mine drainage

Giudici

Pusceddu

Medas

et al. 2017

Applied Geochemistry

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Rio San Giorgio (Iglesiente, Sardinia, Italy), a stream affected by abandoned mine wastes, is characterized by dense vegetation in the streambed, mainly comprised of Phragmites australis and Juncus acutus. This vegetation creates natural biogeochemical barriers that drive mineralization processes and attenuate metals load in the stream. Several techniques, covering scales from micrometres to kilometres, were applied to investigate the biogeochemical processes: water chemistry, injected hydrologic tracer, mineralogy, microscopic investigation and X-ray spectroscopy. From this multiscale and multimethod approach, we recognized two predominant sets of biogeochemical processes: microbially driven metal sulphide precipitation, mainly resulting in pyrite formation; and plant uptake of metals that leads to formation of iron oxide-hydroxide and incorporation of Zn within the roots and aerial part (stem and leaves). The dense vegetation in the Rio San Giorgio streambed controls its morphology, velocity of streamflow, and, as reflected by observed bromide-tracer loss, enhanced water exchange between the streambed and the hyporheic zone. The combined effect of these vegetative controls is to establish biogeochemical barriers that greatly retard trace-metal mobility in the hyporheic zone. We estimated this effect can lead to an apparent decrease in Zn load up to 60%

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“…The pH of environments that would be good targets for Mn oxide-mediated attenuation, e.g., drainage basins, mine tailings, and leaching heaps, is normally acidic due to the aerobic oxidation of sulfidic minerals (3). Although manganese is readily oxidized from Mn(II) to Mn(III/IV) at circumneutral pH by a variety of microorganisms (4), we have limited knowledge about the formation of biogenic Mn oxides in acidic environments (5,6).…”

mentioning

confidence: 99%

“…In contrast, low-pH Mn(II) oxidation poses a challenge to microbes because the reaction is thermodynamically unfavored (5,6,19,20). Until recently, only the fungus Cephalosportium sp.…”

mentioning

confidence: 99%

“…However, recently, Akob et al reported new isolates of low-pH MOB, including Duganella sp. strain AB_14 and Albidiferax ferrireducens strain TB-2, which oxidize Mn(II) at pH 5.5 (5). In addition, Bohu et al characterized Mesorhizobium australicum T-G1, a low-pH Mn(II) oxidizer, that forms a bixbyite-like phase via a multi-copper oxidase pathway rather than reactive oxygen species at acidic pH (6).…”

mentioning

confidence: 99%

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Biological Low-pH Mn(II) Oxidation in a Manganese Deposit Influenced by Metal-Rich Groundwater

Bohu

Akob

Abratis

et al. 2016

Appl Environ Microbiol

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This study provides multiple lines of evidence to show that microbes are the main drivers of Mn(II) oxidation even at acidic pH, offering new insights into Mn biogeochemical cycling. A distinct, highly adapted microbial community inhabits acidic, oligotrophic Mn deposits and mediates biological Mn oxidation. These data highlight the importance of biological processes for Mn biogeochemical cycling and show the potential for new bioremediation strategies aimed at enhancing biological Mn oxidation in low-pH environments for contaminant mitigation.

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Identification of Mn(II)-Oxidizing Bacteria from a Low-pH Contaminated Former Uranium Mine

Cited by 86 publications

References 55 publications

Nutrient input influences fungal community composition and size and can stimulate manganese (II) oxidation in caves

Nutrient input influences fungal community composition and size and can stimulate manganese (II) oxidation in caves

The role of natural biogeochemical barriers in limiting metal loading to a stream affected by mine drainage

Biological Low-pH Mn(II) Oxidation in a Manganese Deposit Influenced by Metal-Rich Groundwater

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