Relative contributions of soil chemistry, plant physiology and rhizosphere induced changes in speciation on Ni accumulation in plant shoots

Relative contributions of soil chemistry, plant physiology and rhizosphere induced changes in speciation on Ni accumulation in plant shoots

The aim of this study is to rank the relative importance of soil properties, root uptake and root-to-shoot redistribution on the transfer of the trace element nickel from soil to the shoots of non hyperaccumulatings plants. Two contrasting soils and seven plant species have been studied using the ra...

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Published in:Plant and soil Vol. 255; no. 2; pp. 619 - 629
Main Authors: Pinel, F, Leclerc-Cessac, E, Staunton, S
Format: Journal Article
Language:English
Published: Dordrecht Kluwer Academic Publishers 01-08-2003
Springer
Springer Nature B.V
Springer Verlag
Subjects:
Acid soils
Acidic soils
Agronomy. Soil science and plant productions
Animal, plant and microbial ecology
bioaccumulation
Biological and medical sciences
Brassica napus
clay soils
Festuca ovina
Festuca rubra
Forest soils
Fundamental and applied biological sciences. Psychology
Life Sciences
Lolium perenne
Nickel
Nutrient solutions
nutrient transport
nutrient uptake
plant growth
Plant physiology
Plant roots
Plant species
Plants
quantitative analysis
Radioactive tracers
Raphanus sativus
Rhizosphere
Roots
sandy soils
Shoots
silty soils
soil chemical properties
Soil chemistry
Soil nutrients
Soil pH
Soil pollution
Soil properties
Soil solution
Soils
Solanum lycopersicum var. lycopersicum
Speciation
Trace elements
Trifolium alexandricum
Vegetal Biology
France
Nutrition
uptake
Agricultural soil
Forest soil
soil
Soil pollution
Inorganic element
Heavy metal
Pollutant
Rhizosphere
Biogeochemistry
Absorption
Adsorption
Angiospermae
plant
Environment
Poison
Spermatophyta
Nickel
Trace element (nutrient)
Cultivated plant
Soil plant relation
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Summary:The aim of this study is to rank the relative importance of soil properties, root uptake and root-to-shoot redistribution on the transfer of the trace element nickel from soil to the shoots of non hyperaccumulatings plants. Two contrasting soils and seven plant species have been studied using the radioactive isotope, 63Ni. Shoots and roots were analysed separately and the specific activity of each plant has been measured. The isotopic exchange properties of rhizosphere soil where compared with control non rhizosphere soil. Possible changes in Ni speciation in the rhizosphere have been assessed by comparing the isotopic exchange properties of the rhizosphere and control soil and by comparing the specific activities of Ni in each plant. The capacity of soil to immobilise added radiotracer largely determines root uptake, leading to between a 4- and 40-fold difference between soils for a given species. The redistribution of nickel from roots to shoots was fairly constant for plants grown on the rendzina, but varied strongly between species for the acid soil. This variation enhanced the contrast between species of the soil-toshoot transfer factor. Root action significantly enhanced immobilisation of added nickel in an acid soil due to the modification of speciation of initially non exchangeable soil nickel, but had little effect on a neutral rendzina. Changes in rhizosphere pH were similar on the two soils. In the acid soil, these pH changes were accompanied by changes in Ni speciation but a causative link has not been established. In the neutral soil pH changes may have modified root uptake properties.
Bibliography:http://www.kluweronline.com/issn/0032-079X/contents
ObjectType-Article-2
SourceType-Scholarly Journals-1
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content type line 23
ISSN:0032-079X
1573-5036
DOI:10.1023/A:1026052228609