Uptake and Toxicity of Arsenic, Copper, and Silicon in Azolla caroliniana and Lemna minor

Here we report on the analysis of two aquatic plant species, Azolla caroliniana and Lemna minor, with respect to tolerance and uptake of co-occurring arsenic, copper, and silicon for use in engineered wetlands. Plants were cultured in nutrient solution that was amended with arsenic (0 or 20 μM), cop...

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Bibliographic Details
Published in:International journal of phytoremediation 2014-02, Vol.16 (2), p.155-166
Main Authors: Rofkar, Jordan R., Dwyer, Daryl F., Bobak, Deanna M.
Format: Article
Language:English
Subjects:
anthocyanins
Anthocyanins - metabolism
Araceae - drug effects
Araceae - growth & development
Araceae - metabolism
Arsenic
Arsenic - analysis
Arsenic - metabolism
Arsenic - toxicity
Azolla caroliniana
Biodegradation, Environmental
Biomass
Bioremediation
Chlorophyll
Chlorophyll - metabolism
Chlorophylls
Copper
Copper - analysis
Copper - metabolism
Copper - toxicity
Ferns - drug effects
Ferns - growth & development
Ferns - metabolism
Flowers & plants
Lemna minor
mixed contaminants
phytoremediation
Plants (organisms)
Silicon
Silicon - analysis
Silicon - metabolism
Silicon - toxicity
Soil contaminants
Uptakes
Water Pollutants, Chemical - analysis
Water Pollutants, Chemical - metabolism
Water Pollutants, Chemical - toxicity
Wetlands
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Summary:Here we report on the analysis of two aquatic plant species, Azolla caroliniana and Lemna minor, with respect to tolerance and uptake of co-occurring arsenic, copper, and silicon for use in engineered wetlands. Plants were cultured in nutrient solution that was amended with arsenic (0 or 20 μM), copper (2 or 78 μM), and silicon (0 or 1.8 mM) either singly or in combination. We hypothesized that arsenic and copper would negatively affect the uptake of metals, growth, and pigmentation and that silicon would mitigate those stresses. Tolerance was assessed by measuring growth of biomass and concentrations of chlorophyll and anthocyanins. Both plant species accumulated arsenic, copper, and silicon; L. minor generally had higher levels on a per biomass basis. Arsenic negatively impacted A. caroliniana, causing a 30% decrease in biomass production and an increase in the concentration of anthocyanin. Copper negatively impacted L. minor, causing a 60% decrease in biomass production and a 45% decrease in chlorophyll content. Silicon augmented the impact of arsenic on biomass production in A. caroliniana but mitigated the effect of copper on L. minor. Our results suggest that mixtures of plant species may be needed to maximize uptake of multiple contaminants in engineered wetlands.
ISSN:1522-6514
1549-7879
DOI:10.1080/15226514.2012.759534