Microbiomes in a manganese oxide producing ecosystem in the Ytterby mine, Sweden: impact on metal mobility

ABSTRACT Microbe-mediated precipitation of Mn-oxides enriched in rare earth elements (REE) and other trace elements was discovered in tunnels leading to the main shaft of the Ytterby mine, Sweden. Defining the spatial distribution of microorganisms and elements in this ecosystem provide a better und...

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Bibliographic Details
Published in:FEMS microbiology ecology 2020-11, Vol.96 (11), p.1
Main Authors: Sjöberg, Susanne, Stairs, Courtney W, Allard, Bert, Homa, Felix, Martin, Tom, Sjöberg, Viktor, Ettema, Thijs J G, Dupraz, Christophe
Format: Article
Language:English
Subjects:
Aquatic environment
bimessite
Biofilms
birnessite
Depletion
Ecology
ecosystem
Environmental impact
Heavy metals
High-throughput screening (Biochemical assaying)
Identification and classification
Manganese
Manganese Compounds
Manganese oxides
Methods
Microbiology
Microbiomes
Microbiota
Microorganisms
Mn-oxidizers
Next-generation sequencing
Niches
Oxidation
Oxidation-Reduction
Oxides
Physiological aspects
Precipitates
Properties
Rare earth elements
REE fractionation
Separation (Technology)
shallow subsurface
Spatial analysis (Statistics)
Spatial distribution
Subsystems
Sweden
Trace elements
Tunnels
Water seepage
Ytterby mine
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Summary:ABSTRACT Microbe-mediated precipitation of Mn-oxides enriched in rare earth elements (REE) and other trace elements was discovered in tunnels leading to the main shaft of the Ytterby mine, Sweden. Defining the spatial distribution of microorganisms and elements in this ecosystem provide a better understanding of specific niches and parameters driving the emergence of these communities and associated mineral precipitates. Along with elemental analyses, high-throughput sequencing of the following four subsystems were conducted: (i) water seeping from a rock fracture into the tunnel, (ii) Mn-oxides and associated biofilm; referred to as the Ytterby Black Substance (YBS) biofilm (iii) biofilm forming bubbles on the Mn-oxides; referred to as the bubble biofilm and (iv) fracture water that has passed through the biofilms. Each subsystem hosts a specific collection of microorganisms. Differentially abundant bacteria in the YBS biofilm were identified within the Rhizobiales (e.g. Pedomicrobium), PLTA13 Gammaproteobacteria, Pirellulaceae, Hyphomonadaceae, Blastocatellia and Nitrospira. These taxa, likely driving the Mn-oxide production, were not detected in the fracture water. This biofilm binds Mn, REE and other trace elements in an efficient, dynamic process, as indicated by substantial depletion of these metals from the fracture water as it passes through the Mn deposit zone. Microbe-mediated oxidation of Mn(II) and formation of Mn(III/IV)-oxides can thus have considerable local environmental impact by removing metals from aquatic environments. Defining the spatial distribution of microorganisms and elements in this REE-enriched Mn-oxide producing ecosystem contribute to a better understanding of specific niches and parameters driving the emergence of these communities.
ISSN:1574-6941
0168-6496
1574-6941
DOI:10.1093/femsec/fiaa169