Leaf manganese accumulation and phosphorus-acquisition efficiency

•Plants that use a phosphorus (P)-mobilising strategy based on carboxylate release tend to have high leaf manganese concentrations ([Mn]).•This occurs because the carboxylates mobilise not only soil inorganic and organic P, but also a range of micronutrients, including Mn.•We propose that leaf [Mn]...

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Published in	Trends in plant science Vol. 20; no. 2; pp. 83 - 90
Main Authors	Lambers, Hans, Hayes, Patrick E., Laliberté, Etienne, Oliveira, Rafael S., Turner, Benjamin L.
Format	Journal Article
Language	English
Published	England Elsevier Ltd 01.02.2015
Subjects	carboxylates Carboxylic Acids - metabolism Ecosystem exudation Genotype habitats leaves manganese Manganese - metabolism phosphorus Phosphorus - metabolism phosphorus-acquisition efficiency Plant Leaves - metabolism Plant Physiological Phenomena - genetics soil Soil - chemistry carboxylates exudation manganese phosphorus-acquisition efficiency phosphorus
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Abstract	•Plants that use a phosphorus (P)-mobilising strategy based on carboxylate release tend to have high leaf manganese concentrations ([Mn]).•This occurs because the carboxylates mobilise not only soil inorganic and organic P, but also a range of micronutrients, including Mn.•We propose that leaf [Mn] can be used to select for genotypes that are more efficient at acquiring P, when soil P availability is low.•Likewise, leaf [Mn] can be used to screen for belowground functional traits related to nutrient-acquisition strategies among species in low-P habitats. Plants that deploy a phosphorus (P)-mobilising strategy based on the release of carboxylates tend to have high leaf manganese concentrations ([Mn]). This occurs because the carboxylates mobilise not only soil inorganic and organic P, but also a range of micronutrients, including Mn. Concentrations of most other micronutrients increase to a small extent, but Mn accumulates to significant levels, even when plants grow in soil with low concentrations of exchangeable Mn availability. Here, we propose that leaf [Mn] can be used to select for genotypes that are more efficient at acquiring P when soil P availability is low. Likewise, leaf [Mn] can be used to screen for belowground functional traits related to nutrient-acquisition strategies among species in low-P habitats.
AbstractList	•Plants that use a phosphorus (P)-mobilising strategy based on carboxylate release tend to have high leaf manganese concentrations ([Mn]).•This occurs because the carboxylates mobilise not only soil inorganic and organic P, but also a range of micronutrients, including Mn.•We propose that leaf [Mn] can be used to select for genotypes that are more efficient at acquiring P, when soil P availability is low.•Likewise, leaf [Mn] can be used to screen for belowground functional traits related to nutrient-acquisition strategies among species in low-P habitats. Plants that deploy a phosphorus (P)-mobilising strategy based on the release of carboxylates tend to have high leaf manganese concentrations ([Mn]). This occurs because the carboxylates mobilise not only soil inorganic and organic P, but also a range of micronutrients, including Mn. Concentrations of most other micronutrients increase to a small extent, but Mn accumulates to significant levels, even when plants grow in soil with low concentrations of exchangeable Mn availability. Here, we propose that leaf [Mn] can be used to select for genotypes that are more efficient at acquiring P when soil P availability is low. Likewise, leaf [Mn] can be used to screen for belowground functional traits related to nutrient-acquisition strategies among species in low-P habitats. Plants that deploy a phosphorus (P)-mobilising strategy based on the release of carboxylates tend to have high leaf manganese concentrations ([Mn]). This occurs because the carboxylates mobilise not only soil inorganic and organic P, but also a range of micronutrients, including Mn. Concentrations of most other micronutrients increase to a small extent, but Mn accumulates to significant levels, even when plants grow in soil with low concentrations of exchangeable Mn availability. Here, we propose that leaf [Mn] can be used to select for genotypes that are more efficient at acquiring P when soil P availability is low. Likewise, leaf [Mn] can be used to screen for belowground functional traits related to nutrient-acquisition strategies among species in low-P habitats. Plants that deploy a phosphorus (P)-mobilising strategy based on the release of carboxylates tend to have high leaf manganese concentrations ([Mn]). This occurs because the carboxylates mobilise not only soil inorganic and organic P, but also a range of micronutrients, including Mn. Concentrations of most other micronutrients increase to a small extent, but Mn accumulates to significant levels, even when plants grow in soil with low concentrations of exchangeable Mn availability. Here, we propose that leaf [Mn] can be used to select for genotypes that are more efficient at acquiring P when soil P availability is low. Likewise, leaf [Mn] can be used to screen for belowground functional traits related to nutrient-acquisition strategies among species in low-P habitats.Plants that deploy a phosphorus (P)-mobilising strategy based on the release of carboxylates tend to have high leaf manganese concentrations ([Mn]). This occurs because the carboxylates mobilise not only soil inorganic and organic P, but also a range of micronutrients, including Mn. Concentrations of most other micronutrients increase to a small extent, but Mn accumulates to significant levels, even when plants grow in soil with low concentrations of exchangeable Mn availability. Here, we propose that leaf [Mn] can be used to select for genotypes that are more efficient at acquiring P when soil P availability is low. Likewise, leaf [Mn] can be used to screen for belowground functional traits related to nutrient-acquisition strategies among species in low-P habitats.
Author	Lambers, Hans Turner, Benjamin L. Hayes, Patrick E. Laliberté, Etienne Oliveira, Rafael S.
Author_xml	– sequence: 1 givenname: Hans surname: Lambers fullname: Lambers, Hans email: hans.lambers@uwa.edu.au organization: School of Plant Biology, The University of Western Australia, Stirling Highway, Crawley (Perth), WA 6009, Australia – sequence: 2 givenname: Patrick E. surname: Hayes fullname: Hayes, Patrick E. organization: School of Plant Biology, The University of Western Australia, Stirling Highway, Crawley (Perth), WA 6009, Australia – sequence: 3 givenname: Etienne surname: Laliberté fullname: Laliberté, Etienne organization: School of Plant Biology, The University of Western Australia, Stirling Highway, Crawley (Perth), WA 6009, Australia – sequence: 4 givenname: Rafael S. surname: Oliveira fullname: Oliveira, Rafael S. organization: School of Plant Biology, The University of Western Australia, Stirling Highway, Crawley (Perth), WA 6009, Australia – sequence: 5 givenname: Benjamin L. surname: Turner fullname: Turner, Benjamin L. organization: School of Plant Biology, The University of Western Australia, Stirling Highway, Crawley (Perth), WA 6009, Australia
BackLink	https://www.ncbi.nlm.nih.gov/pubmed/25466977$$D View this record in MEDLINE/PubMed
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Keywords	carboxylates exudation manganese phosphorus-acquisition efficiency phosphorus
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Snippet	•Plants that use a phosphorus (P)-mobilising strategy based on carboxylate release tend to have high leaf manganese concentrations ([Mn]).•This occurs because... Plants that deploy a phosphorus (P)-mobilising strategy based on the release of carboxylates tend to have high leaf manganese concentrations ([Mn]). This...
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SubjectTerms	carboxylates Carboxylic Acids - metabolism Ecosystem exudation Genotype habitats leaves manganese Manganese - metabolism phosphorus Phosphorus - metabolism phosphorus-acquisition efficiency Plant Leaves - metabolism Plant Physiological Phenomena - genetics soil Soil - chemistry
Title	Leaf manganese accumulation and phosphorus-acquisition efficiency
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