Formation of Metallic Copper Nanoparticles at the Soil−Root Interface

Manceau, Alain; Nagy, Kathryn L.; Marcus, Matthew A.; Lanson, Martine; Geoffroy, Nicolas; Jacquet, Thierry; Kirpichtchikova, Tatiana

doi:10.1021/es072017o

Cited by 222 publications

(128 citation statements)

References 62 publications

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“…So far, the knowledge of the effect of nanoparticles on mycorrhizal fungi is very limited, only one study was carried out, where it was suggested that mycorrhizal fungi assisting plants can alleviate the toxicity of Cu by the formation of Cu nanoparticles and thus limiting its toxicity (Manceau et al, 2008). In the present paper nanoparticles were used according to manufacturer's instructions.…”

Section: S106mentioning

confidence: 99%

Influence of silver and titanium nanoparticles on arbuscular mycorrhiza colonization and accumulation of radiocaesium in Helianthus annuus

Dubchak

Ogar

Mietelski

et al. 2010

Span. j. agric. res.

169

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The influence of arbuscular mycorrhizal fungus on 134Cs uptake by Helianthus annuus was studied in a pilot study under growth chamber conditions. Mycorrhizal plants took up five times more 134Cs (up to 250,000 Bq kg-1 dry weight) than non mycorrhizal plants. Silver and titanium nanoparticles, supplied into the surface soil layer decreased both the mycorrhizal colonization and Cs uptake by mycorrhizal plants. The application of activated carbon attenuated the effect of nanoparticles and increased 134Cs uptake in the presence of mycorrhizal fungi (up to 400,000 Bq kg-1 dry weight). The results underline the possible application of phytoremediation techniques based on mycorrhiza assisted plants in decontamination of both radionuclides and nanoparticles.

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Section: S106mentioning

confidence: 99%

Influence of silver and titanium nanoparticles on arbuscular mycorrhiza colonization and accumulation of radiocaesium in Helianthus annuus

Dubchak

Ogar

Mietelski

et al. 2010

Span. j. agric. res.

169

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“…A whole host of nano-sensors are being developed that could revolutionize our understanding of our environment (e.g., Andreescu et al, 2009;Cho et al, 2008;Chopra et al, 2002;Consales et al, 2009;Granqvist et al, 2007;Huang and Chang, 2006;Liu and Lin, 2005;Nelli et al, 1996;Park et al, 2009;Toal et al, 2005), allowing us to detect environmental conditions, gas concentrations, and contaminant loads at a temporal and spatial resolution never before possible. As the tools for nanomaterial measurement and characterization are transferred into ecology, we are increasingly recognizing that many organisms produce nanoparticles, and that these natural nanoparticles may play important roles in biogeochemical cycling (e.g., Gorby et al, 2006;Manceau et al, 2008;Blango and Mulvey, 2009). …”

Section: Discussionmentioning

confidence: 99%

“…Bacterial reduction of uranyl, U 6+ (aq), to U(IV) oxide (uraninite) is an important bioremediation strategy (Bargar et al, 2008). Manceau et al (2008) found that wetland plants, or their symbionts, synthesize copper (Cu) nanoparticles in their rooting zone when grown in contaminated soils, thereby reducing Cu uptake. Dissimilatory metal-reducing bacteria even respire on iron oxide nanoparticles in anaerobic environments (Bose et al, 2009).…”

Section: Naturally Occurring Nanoparticles Are Ubiquitous In Naturementioning

confidence: 99%

An Ecological Perspective on Nanomaterial Impacts in the Environment

et al. 2010

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1954Growing concerns over the potential for unintended, adverse consequences of engineered nanoparticles (ENPs) in the environment have generated new research initiatives focused on understanding the ecological eff ects of ENPs. Almost nothing is currently known about the fate and transport of ENPs in environmental waters, soils, and sediments or about the biological impacts of ENPs in natural environments, and the bulk of modern nanotoxicogical research is focused on highly controlled laboratory studies with single species in simple media. In this paper, we provide an ecological perspective on the current state of knowledge regarding the likely environmental impacts of nanomaterials and propose a strategy for making rapid progress in new research in ecological nanoscience.

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“…Biomolecular responses to oxidative stress are therefore likely in yellow soil. Also present in bacterial surfaces, humic acid and natural organic matter, trace Cu(0) is expected to exist in the rhizosphere of E. splendens at the soil-root interface (Fulda et al, 2013;González et al, 2016;Manceau et al, 2008;Navarret et al, 2011). Cu(II) mainly complexes to carboxylic groups (Cu(II)-O/N), and adsorbed on root cell walls in E. splendens (Liu et al, 2014;Shi et al, 2004).…”

Section: Cu Isotopic Fractionation Between Neighboring Tissues In E mentioning

confidence: 99%

Cu isotopic compositions in Elsholtzia splendens: Influence of soil condition and growth period on Cu isotopic fractionation in plant tissue

Zhu

et al. 2016

Chemical Geology

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This study investigates the magnitude and direction of Cu isotopic fractionation in the Cu-tolerant, strategy I plant, Elsholtzia splendens, considering the effect of soil condition and plant growth cycle. Uptake of Cu by E. splendens from soil was found to favor light Cu isotopic enrichment (δ 65 Cu b 0‰) due to reduction at the soilroot interface. The magnitude of fractionation between soil and plant was found to be dependent on free Cu ion species in soil solution correlated with pH value of soil other than the phytoavailable component of soil or total soil for the same parent soil. Cu isotopic fractionation occurs in plant, the fractionation direction and magnitude would vary between different plant organs (i.e., root and stem) as well as different plant tissues (i.e., xylem and phloem). Remobilization of Cu associated with plant senescence was found to have a considerable effect on Cu isotopic fractionation within the plant, and the fractionation factor was found to change with the degree of remobilization. Overall, the results show that the Cu isotopic composition is useful as a tracer for probing the mechanisms of Cu translocation and retranslocation between soil and plants, and within plants.

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Formation of Metallic Copper Nanoparticles at the Soil−Root Interface

Cited by 222 publications

References 62 publications

Influence of silver and titanium nanoparticles on arbuscular mycorrhiza colonization and accumulation of radiocaesium in Helianthus annuus

Influence of silver and titanium nanoparticles on arbuscular mycorrhiza colonization and accumulation of radiocaesium in Helianthus annuus

An Ecological Perspective on Nanomaterial Impacts in the Environment

Cu isotopic compositions in Elsholtzia splendens: Influence of soil condition and growth period on Cu isotopic fractionation in plant tissue

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