Taxonomic and functional analysis of soil microbial communities in a mining site across a metal(loid) contamination gradient

Soil microorganisms surviving in mining sites have developed metal‐resistance mechanisms to biotransform metals. Their use as biofertilizers can improve phytoremediation efficiency in contaminated soils by reducing metal toxicity while promoting plant growth. We analysed through whole‐metagenome sho...

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Bibliographic Details
Published in:European journal of soil science 2021-05, Vol.72 (3), p.1190-1205
Main Authors: Navas, Mariela, Pérez‐Esteban, Javier, Torres, Miguel‐Angel, Hontoria, Chiquinquira, Moliner, Ana
Format: Article
Language:English
Subjects:
Abandoned mines
Abundance
Actinobacteria
Archaea
biofertilizer
Biofertilizers
Bioremediation
Bradyrhizobium diazoefficiens
Copper
diversity
Fertilizers
Functional analysis
functional gene
Fungi
Genera
Genes
heavy metal
Heavy metals
Iron
Manganese
Metabolism
metagenomics
Metal concentrations
Metals
Microbial activity
Microbiomes
microorganism
Microorganisms
mine soil
Mining
Phytoremediation
Plant growth
pollution
Proteobacteria
Pseudomonas aeruginosa
Relative abundance
Resistance mechanisms
Sediment pollution
Sequences
Soil
Soil analysis
Soil contamination
Soil microorganisms
Soil pollution
Species
Survival
Toxicity
Zinc
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Summary:Soil microorganisms surviving in mining sites have developed metal‐resistance mechanisms to biotransform metals. Their use as biofertilizers can improve phytoremediation efficiency in contaminated soils by reducing metal toxicity while promoting plant growth. We analysed through whole‐metagenome shotgun sequencing the composition, diversity and function of microbial communities present in a contaminated mine soil along a gradient of metals (As, Cu, Fe, Mn, Pb, Zn) to identify tolerant species carrying metal‐resistance functional genes that can be used in association with plants for phytoremediation. Soil samples were collected from an abandoned copper mine, across three areas with different levels of metal contamination (unaffected, moderately contaminated and highly contaminated). The relative abundance of Proteobacteria, especially genus Bradyrhizobium, increased in the highly contaminated area, whereas Actinobacteria dominated in the unaffected area. Archaea (Euryarchaeota) predominated in the moderately contaminated area, Haloarcula, Halobacterium and Halorubrum being the most abundant genera. The fungi Basidiomycota did not exhibit differences among the areas, whereas Ascomycota, especially the genus Aspergillus, increased in areas with low metal concentrations. Metal‐resistance genes associated with Fe (acn, furA, dpsA), Cu (cop‐unnamed, copF, actP, copA, mmco, cutO) and As (arsT, arsC, aioA/aoxB) metabolism were the most abundant and were affected by the gradient of soil contamination. Those associated with Cu predominated in the most contaminated area, whereas As and Fe genes were more abundant in the least contaminated. Among the carriers of these metal‐resistance genes, Bradyrhizobium diazoefficiens, Pseudomonas aeruginosa, Halorubrum trapanicum, Aspergillus fumigatus and A. fischeri were dominant in the most contaminated area. These species could give rise to promising biofertilizers to be used in association with suitable plants for the phytoremediation of contaminated mining sites. Highlights Metals affect differentially abundance, diversity and function of microorganisms in a mine soil. Proteobacteria dominated in contaminated areas and Actinobacteria in the less contaminated. Most abundant metal‐resistance genes were associated with Cu, As and Fe. Bradyrhizobium diazoefficiens and other species are promising biofertilizers for phytoremediation.
ISSN:1351-0754
1365-2389
DOI:10.1111/ejss.12979