Genetic Characterization of Periphyton Communities Associated with Selenium Bioconcentration and Trophic Transfer in a Simple Food Chain

A major source of uncertainty in predicting selenium (Se) distribution in aquatic food webs lies in the enrichment factor (EF), the ratio of Se bioconcentration in primary producers and microorganisms relative to the concentration of Se in the surrounding water. It has been well demonstrated that EF...

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Bibliographic Details
Published in:Environmental science & technology 2017-07, Vol.51 (13), p.7532-7541
Main Authors: Friesen, Vanessa, Doig, Lorne E, Markwart, Blue E, Haakensen, Monique, Tissier, Emily, Liber, Karsten
Format: Article
Language:English
Subjects:
Algae
Animals
Aquariums
Aquatic environment
Bacteria
Bioaccumulation
Bioavailability
Biodynamics
Biofilms
Biological magnification
Community composition
Community development
Concentration (composition)
Correlation
Cyanobacteria
Enrichment
Food Chain
Food chains
Food sources
Food webs
Geochemistry
Grazing
Influence
Inoculum
Light
Macroinvertebrates
Maturation
Microalgae
Microorganisms
Mollusks
Nutrients
Periphyton
Selenious Acid
Selenite
Selenium
Snails
Statistical analysis
Statistical methods
Taxa
Transfer factor
Water analysis
Water purification
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Summary:A major source of uncertainty in predicting selenium (Se) distribution in aquatic food webs lies in the enrichment factor (EF), the ratio of Se bioconcentration in primary producers and microorganisms relative to the concentration of Se in the surrounding water. It has been well demonstrated that EFs can vary dramatically among individual algal taxa, but data are lacking regarding the influence of periphyton community composition on EFs for a given geochemical form of Se. Therefore, the goals of this study were first to assess whether different periphyton communities could be established in aquaria with the same starting inoculum using different light and nutrient regimes, and second, to determine if the periphyton assemblage composition influences the uptake of waterborne Se (as selenite) and subsequent Se transfer to a model macroinvertebrate primary consumer. Periphyton biofilms were grown in aquaria containing filtered pond water (from Saskatoon, SK) spiked with approximately 20 μg Se/L (mean measured concentration 21.0 ± 1.2 μg Se/L), added as selenite. Five different light and nutrient regimes were applied to the aquaria (three replicates per treatment) to influence biofilm community development. After 6 weeks of biofilm maturation, 40 to 80 immature cultured snails (Stagnicola elodes) were added to each aquarium. The bacterial and algal members of the periphyton community were characterized by targeted metagenomic analyses before and after addition of snails to ensure the snails themselves did not significantly alter the biofilm community. Samples were collected for Se analysis of water, periphyton, and whole-body snail. The nutrient and light treatments resulted in substantially different compositions of the periphytic biofilms, with each being relatively consistent across replicates and throughout the study. Although the aqueous concentration of dissolved Se administered to treatments was constant, uptake by the different periphytic biofilms differed significantly. Both the low-light (61.8 ± 12.1 μg Se/g d.w.) and high-light (30.5 ± 4.7 μg Se/g d.w.) biofilms, which were found to have high proportions of cyanobacteria, contained statistically higher concentrations of Se relative to the other treatments. Furthermore, the concentration of Se in bulk periphyton was predictive of Se bioaccumulation in grazing snails but as an inverse relationship, opposite to expectations. The trophic transfer factor was inversely correlated with periphyton enrichment
ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.7b01001