Soil exposed to silver nanoparticles reveals significant changes in community structure and altered microbial transcriptional profiles

Soil exposed to silver nanoparticles reveals significant changes in community structure and altered microbial transcriptional profiles

Anthropogenic activities can disrupt soil ecosystems, normally resulting in reduced soil microbial health. Regulatory agencies need to determine the effects of uncharacterized substances on soil microbial health to establish the safety of these chemicals if they end up in the environment. Previous w...

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Bibliographic Details
Published in:Environmental pollution (1987) Vol. 258; p. 113816
Main Authors: Meier, Matthew J., Dodge, Annette E., Samarajeewa, Ajith Dias, Beaudette, Lee A.
Format: Journal Article
Language:English
Published: England Elsevier Ltd 01-03-2020
Subjects:
Alberta
Bacteria
Dose-response modeling
Ecosystem
Genomics
Metal Nanoparticles - toxicity
Silver - toxicity
Silver nanoparticles
Soil
Soil Microbiology
Soil Pollutants - toxicity
Alberta
Soil
Bacteria
Genomics
Silver nanoparticles
Dose-response modeling
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Summary:Anthropogenic activities can disrupt soil ecosystems, normally resulting in reduced soil microbial health. Regulatory agencies need to determine the effects of uncharacterized substances on soil microbial health to establish the safety of these chemicals if they end up in the environment. Previous work has focused on measuring traditional ecotoxicologial endpoints within the categories of microbial biomass, activity, and community structure/diversity. Because these tests can be labor intensive, lengthy to conduct, and cannot measure changes in individual gene functions, we wanted to establish whether metatranscriptomics could be used as a more sensitive endpoint and provide a perspective on community function that is more informative than taxonomic identification of microbes alone. We spiked a freshly collected sandy loam soil (Vulcan, Alberta, Canada) with 0, 60, 145, 347, 833, and 2000 mg kg−1 of silver nanoparticles (AgNPs), a known antagonist of microorganisms due to its propensity for dissolution of toxic silver ions. Assessments performed in our previous work using traditional tests demonstrated the toxicity of AgNPs on soil microbial processes. We expanded this analysis with genomics-based tests by measuring changes in community taxonomic structure and function using 16S rDNA profiling and metatranscriptomics. In addition to identifying bacterial taxa affected by AgNPs, we found that genes involved in heavy metal resistance (e.g., the CzcA efflux pump) and other toxicity response pathways were highly upregulated in the presence of silver. Dose-response analysis using BMDExpress2 software successfully modeled many physiologically relevant genes responding to low concentrations of AgNPs. We found that the transcriptomic point of departure (BMD50) was lower than the IC50s calculated using the traditional tests in our previous work. These results suggest that dose-response modeling of metatranscriptomic gene expression is a useful tool in soil microbial health assessment. Genomics-based endpoints for the assessment of soil microbial health can be used to perform quantitative dose-response modeling, and soil-based RNAseq adds functional insights. [Display omitted] •We used RNAseq to measure the effect of silver nanoparticles on soil bacteria.•Gene expression in soil bacteria can be used to perform dose-response modeling.•Transcriptional profiles from silver exposure reveal mechanisms of stress response.
ISSN:0269-7491
1873-6424
DOI:10.1016/j.envpol.2019.113816